Coherent electrical serdes in the THZ range
By up-converting baseband signals to THz frequencies with coherent signaling and 4QAM/QPSK modulation, the technology addresses bandwidth and power limitations in optical networking and THz wireless communications, enhancing integration and efficiency in ICs.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- ATTOTUDE INC
- Filing Date
- 2026-01-02
- Publication Date
- 2026-07-09
AI Technical Summary
Optical networking systems face limitations in power dissipation, thermal management, mechanical tolerances, and bandwidth constraints, while THz wireless communications struggle with complexity, cost, and power consumption due to reliance on optical components.
The technology employs up-conversion of baseband signals to THz carrier frequencies using coherent signaling techniques, integrating 4-state Quadrature Amplitude Modulation (4QAM) or Quadrature Phase Shift Keying (QPSK) modulation schemes, and utilizes hollow waveguides for reduced transmission loss and power efficiency.
This approach achieves reduced transmission loss, higher IO bandwidth, lower power consumption, and cost-effectiveness, seamlessly integrating with ICs like Switches and GPUs, surpassing conventional SerDes stages.
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Figure US2026010056_09072026_PF_FP_ABST
Abstract
Description
ELECTRONICALLY TRANSMITTED: JANUARY 2, 2026 PATENT INVENTION TITLE COHERENT ELECTRICAL SERDES IN THE THZ RANGE BACKGROUND ART
[0001] Optical networking is a means of communication that uses signals encoded in light to transmit information in various types of telecommunications networks, including limited range local-area networks (LANs) or wide-area networks (WANs). It is a form of optical communication that relies on optical amplifiers, lasers, or LEDs and wavelength-division multiplexing (WDM) to transmit large quantities of data, generally across fiber-optic cables. Because it is capable of achieving extremely high bandwidth, it is an enabling technology for the Internet and telecommunication networks that transmit the vast majority of all human and machine-to-machine information. However, further development and optimization of optical networking systems face certain limiting factors, namely, power dissipation, thermal requirements, and mechanical tolerances.
[0002] Optical components generate photons by exciting electrons in a gain medium, and the electrons emit photons as they return to lower energy levels. Despite efforts to improve efficiency, optical components generate some amount of heat during the electron excitation process, and such heat is referred to as power dissipation. Excessive power dissipation may lead to thermal management problems and may affect the performance and longevity of the optical components.
[0003] Optical components are sensitive to temperature fluctuationsand often require lower operating temperatures than purely electronic components to maintain optimal performance. Elevated temperatures may result in increased signal noise, diminished signal quality, and reduced service life for optical components. Accordingly, optical components often require cooling systems (e.g., heat sinks, fans, or thermoelectric devices) to dissipate excess heat and maintain the optical components within a safe temperature range.
[0004] Optical networking systems typically operate in micrometer wavelengths, demanding extreme precision in component fabrication, assembly, and alignment. Even slight deviations from the required mechanical tolerances may lead to signal degradation, loss, orthe introduction of optical crosstalk, negatively impacting network performance. Achieving and maintaining the necessary mechanical tolerances necessitates advanced manufacturing techniques and stringent quality control measures.
[0005] Terahertz (THz) wireless communications in a frequency range between 300 Gigahertz (GHz) and 10 THz offer the potential for extremely high data rates, but face significant technical challenges. Existing approaches for transmitting and receiving dual-polarized THz signals have relied heavily on optical components, increasing complexity, cost, and power consumption.
[0006] In modern integrated circuit (IC) design, a Serializer / Deserializer (SerDes) is an ICthat facilitates conversion between serial and parallel data interfaces. SerDes circuits serve as components in chip Input / Output (IO) architectures, enabling inter-chip communication. Contemporary ICs, including Switches and Graphics Processing Units (GPUs), have experienced substantial increases in processing capabilities, necessitating corresponding advancements in IO bandwidth. Conventional interconnection methodologies predominantly utilize copper or similar electrically conductive materials for IC-to-IC communication. However, these conductive materials exhibit inherent limitations in electrical bandwidth and manifest transmission losses that effectively constrain the maximum achievable symbol rate of serialized signals.
[0007] While implementing higher-order baseband Pulse Amplitude Modulation (PAM) schemes to increase the number of bits transmitted per symbol offers potential throughput improvements, this approach encounters fundamental limitations. Specifically, the elevation in Signal-to-Noise Ratio (SNR) requirements necessary to maintain the targeted Bit Error Ratio (BER) imposes practical constraints on the achievable data transmission rates through conventional conductive interconnects.SUMMARY
[0008] The present disclosure provides solutions for overcoming bandwidth limitations inherent in conventional electrical transmission lines. The disclosed technology employs up-conversion of baseband signals to THz carrier frequencies, where waveguide transmission losses— whether in fiber or cable implementations— are substantially reduced compared to baseband transmission. Furthermore, the technology implements coherent signaling techniques, utilizing both amplitude and phase-sensitive detection, thereby achieving significant reductions in required Signal-to-Noise Ratio (RSNR) compared to traditional Pulse Amplitude Modulation (PAM) approaches.
[0009] The electrical nature of the disclosed technology facilitates seamless integration with host ICs, such as Switches and Graphics Processing Units (GPUs), effectively supplanting conventional SerDes input / output stages. The technology exploits the inherently digital architecture of these host ICs by implementing 4-state Quadrature Amplitude Modulation (4QAM) or Quadrature Phase Shift Keying (QPSK) modulation schemes, which can be directlydriven by binary signals from the IC. This approach eliminates the need for power-intensive conversion to multi-level PAM schemes, such as PAM4. Additional power efficiencies are realized through the implementation of limiting drivers in place of linear drivers.
[0010] The disclosed technology offers several advantages over existing solutions, including full integration capability, reduced transmission loss, scalability to higher IO bandwidths, and reduced power consumption and cost metrics. These benefits represent significant improvements over competing technologies, particularly optical solutions, which face limitations in terms of integration capabilities, power efficiency, cost-effectiveness, and reliability.
[0011] In a first aspect, the present disclosure includes a network element, comprising: one or more serializers operable to receive a plurality of parallel baseband signals and multiplex the plurality of parallel baseband signals to generate one or more pairs of serial baseband signals, each of the plurality of parallel baseband signals having client data encoded therein, each of the one or more pairs of serial baseband signals including a first serial baseband signal and a second serial baseband signal; one or more modulators operable to: receive the one or more pairs of serial baseband signals from the one or more serializers; up-convert the first serial baseband signal and the second serial baseband signal of each of the one or more pairs of serial baseband signals to generate one or more pairs of intermediate signals, each of the one or more pairs of intermediate signals including a first intermediate signal based on the first serial baseband signal and a second intermediate signal based on the second serial baseband signal; and combine the first intermediate signal and the second intermediate signal of each of the one or more pairs of intermediate signals into one or more antenna feed signals, each of the one or more antenna feed signals having an in-phase (I) component based on the first intermediate signal and a quadrature (Q) component based on the second intermediate signal; and one or more antennas operable to receive the one or more antenna feed signals from the one or more modulators, generate one or more radiated signals based on the one or more antenna feed signals, and couple the one or more radiated signals into one or more hollow waveguides, each of the one or more radiated signals being radiated electromagnetic waves and having a frequency in a range between 300 Gigahertz (GHz) and 10 Terahertz (THz).
[0012] In a second aspect, the present disclosure includes a network element, comprising: one or more antennas operable to detect one or more radiated signals received from one or more hollow waveguides and generate one or more antenna output signals based on the one or more radiated signals, each of the one or more radiated signals being radiated electromagnetic waves operable for coherent detection and having client data encoded therein and a frequencyin a range between 300 Gigahertz (GHz) and 10 Terahertz (THz), each of the one or more antenna output signals having an in-phase (I) component and a quadrature (Q) component; one or more demodulators operable to: receive the one or more antenna output signals from the one or more antennas; split each of the one or more antenna output signals into one or more pairs of intermediate signals, each of the one or more pairs of intermediate signals including a first intermediate signal based on a particular antenna output signal of the one or more antenna output signals and a second intermediate signal based on the particular antenna output signal; and down-convert the first intermediate signal and the second intermediate signal of each of the one or more pairs of intermediate signals to generate one or more pairs of serial baseband signals, each of the one or more pairs of serial baseband signals including a first serial baseband signal based on the first intermediate signal and a second serial baseband signal based on the second intermediate signal; and one or more deserializers operable to receive the one or more pairs of serial baseband signals from the one or more demodulators and de-multiplex the one or more pairs of serial baseband signals to generate a plurality of parallel baseband signals.
[0013] In a third aspect, the present disclosure includes a network element, comprising: one or more serializers operable to receive a plurality of outbound parallel baseband signals and multiplex the plurality of outbound parallel baseband signals to generate one or more pairs of outbound serial baseband signals, each of the plurality of outbound parallel baseband signals having outbound client data encoded therein, each of the one or more pairs of outbound serial baseband signals including a first outbound serial baseband signal and a second outbound serial baseband signal; one or more modulators operable to: receive the one or more pairs of outbound serial baseband signals from the one or more serializers; up-convert the first outbound serial baseband signal and the second outbound serial baseband signal of each of the one or more pairs of outbound serial baseband signals to generate one or more pairs of outbound intermediate signals, each ofthe one or more pairs of outbound intermediate signals including a first outbound intermediate signal based on the first outbound serial baseband signal and a second outbound intermediate signal based on the second outbound serial baseband signal; and combine the first outbound intermediate signal and the second outbound intermediate signal of each of the one or more pairs of outbound intermediate signals into one or more antenna feed signals, each of the one or more antenna feed signals having an outbound in-phase (I) component based on the first outbound intermediate signal and an outbound quadrature (Q) component based on the second outbound intermediate signal; and one or more transmitter antennas operable to receive the one or more antenna feed signals from the one or more modulators, generate one or moreoutbound radiated signals based on the one or more antenna feed signals, and couple the one or more outbound radiated signals into one or more first hollow waveguides, each of the one or more outbound radiated signals being radiated electromagnetic waves and having a first frequency in a range between 300 Gigahertz (GHz) and 10 Terahertz (THz); one or more receiver antennas operable to detect one or more inbound radiated signals received from one of the one or more first hollow waveguides and one or more second hollow waveguides and generate one or more antenna output signals based on the one or more inbound radiated signals, each of the one or more inbound radiated signals being radiated electromagnetic waves and having inbound client data encoded therein and a second frequency in the range between 300 GHz and 10 THz, each of the one or more antenna output signals having an inbound I component and an inbound Q. component; one or more demodulators operable to: receive the one or more antenna output signals from the one or more receiver antennas; split each of the one or more antenna output signals into one or more pairs of inbound intermediate signals, each of the one or more pairs of inbound intermediate signals including a first inbound intermediate signal based on a particular antenna output signal of the one or more antenna output signals and a second inbound intermediate signal based on the particular antenna output signal; and down-convert the first inbound intermediate signal and the second inbound intermediate signal of each of the one or more pairs of inbound intermediate signals to generate one or more pairs of inbound serial baseband signals, each of the one or more pairs of inbound serial baseband signals including a first inbound serial baseband signal based on the first inbound intermediate signal and a second inbound serial baseband signal based on the second inbound intermediate signal; and one or more deserializers operable to receive the one or more pairs of inbound serial baseband signals from the one or more demodulators and de-multiplex the one or more pairs of inbound serial baseband signals to generate a plurality of inbound parallel baseband signals.
[0014] The foregoing summary provides an overview of certain selected embodiments or embodiments disclosed herein, and is not intended to describe every aspect, embodiment, embodiment, feature, or advantage of the disclosure exhaustively or comprehensively. Therefore, this Summary should not be construed in such a way to limit the scope of this disclosure or to limit the scope of the claims. The details of one or more embodiment or embodiment disclosed herein are set forth in the accompanying drawings and descriptions below. Other aspects, features, embodiments, embodiments, and advantages will become readily apparent in view of the description, the drawings, and the claims set forth herein.BRIEF DESCRIPTION OF THE DRAWINGS
[0015] The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate one or more embodiment described herein and, together with the description, explain these embodiments. The drawings are not intended to be drawn to scale, and certain features and certain views of the figures may be shown exaggerated, to scale or in schematic in the interest of clarity and conciseness. Not every component may be labeled in every drawing. Like reference numerals in the figures may represent and refer to the same or similar element or function. In the drawings:
[0016] FIG. 1 is a diagrammatic view of an electromagnetic (EM) spectrum;
[0017] FIG. 2 is a block diagram of an exemplary embodiment of a transport network constructed in accordance with the present disclosure;
[0018] FIG. 3A is a cross-sectional view of an exemplary embodiment of a first hollow waveguide shown in FIG. 2, taken alongthe line 3-3' and in the direction of the arrows;
[0019] FIG. 3B is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken alongthe line 3-3' and in the direction of the arrows, wherein the first hollow waveguide lacks an optional dielectric layer;
[0020] FIG. 3C is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide lacks an optional support layer;
[0021] FIG. 3D is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide lacks the optional dielectric layer and the optional support layer;
[0022] FIG. 3E is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a photonic-bandgap fiber;
[0023] FIG. 3F is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide has a hollow waveguide core with an elliptical cross-section;
[0024] FIG. 3G is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the hollow waveguide core of the first hollow waveguide has a rectangular cross-section;
[0025] FIG. 3H is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the hollow waveguide core of the first hollow waveguide has a square cross-section;
[0026] FIG. 31 is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the hollow waveguide core of the first hollow waveguide has a cross-shaped cross-section;
[0027] FIG. 3J is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a solid rod fiber;
[0028] FIG. 3K is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a microstructured optical fiber;
[0029] FIG. 3L is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a porous fiber;
[0030] FIG.3M is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a suspended porous-core fiber;
[0031] FIG. 3N is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a suspended slotted core fiber;
[0032] FIG. 30 is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a hollow-core bandgap fiber;
[0033] FIG. 3P is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a hollow-core tube fiber;
[0034] FIG. 3Q is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a hollow-core fiber with negative curvature;
[0035] FIG. 3R is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, whereinthe first hollow waveguide is a hollow-core fiber based on anti-resonances and inhibited coupling;
[0036] FIG. 3S is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a hollow-core nested anti-resonant nodeless fiber;
[0037] FIG. 3T is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a 3D-printed hollow-core fiber based on anti-resonances and inhibited coupling;
[0038] FIG. 3U is a cross-sectional view of another exemplary embodiment of the first hollow waveguide shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows, wherein the first hollow waveguide is a Bragg fiber;
[0039] FIG. 4A is a block diagram of an exemplary embodiment of a first transmitter shown in FIG. 2;
[0040] FIG. 4B is a block diagram of another exemplary embodiment of the first transmitter shown in FIG. 2, wherein the first transmitter comprises a serializer;
[0041] FIG. 4C is a block diagram of another exemplary embodiment of the first transmitter shown in FIG. 2, wherein the first transmitter comprises a deserializer;
[0042] FIG.4D is a block diagram of an exemplary embodiment of transmitter circuitry shown in FIG. 4A;
[0043] FIG. 4E is a block diagram of another exemplary embodiment of the transmitter circuitry shown in FIG. 4A, wherein the transmitter circuitry comprises a combiner;
[0044] FIG. 4F is a block diagram of another exemplary embodiment of the first transmitter shown in FIG. 2;
[0045] FIG. 4G is a block diagram of another exemplary embodiment of the first transmitter shown in FIG. 2;
[0046] FIG. 5A is a block diagram of an exemplary embodiment of a first receiver shown in FIG. 2;
[0047] FIG. 5B is a block diagram of another exemplary embodiment of the first receiver shown in FIG. 2, wherein the first receiver comprises a deserializer;
[0048] FIG. 5C is a block diagram of another exemplary embodiment of the first transmitter shown in FIG. 2, wherein the first transmitter comprises a serializer;
[0049] FIG. 5D is a block diagram of an exemplary embodiment of receiver circuitry shown in FIG. 5A;
[0050] FIG. 5E is a block diagram of another exemplary embodiment of the receiver circuitry shown in FIG. 5A, wherein the receiver circuitry comprises a splitter;
[0051] FIG. 5F is a block diagram of another exemplary embodiment of the first receiver shown in FIG. 2;
[0052] FIG. 5G is a block diagram of another exemplary embodiment of the first receiver shown in FIG. 2;
[0053] FIG. 6A is a block diagram of an exemplary embodiment of a transceiver shown in FIG.2;
[0054] FIG.6B is a block diagram of another exemplary embodiment of the transceiver shown in FIG. 2;
[0055] FIG. 7 is a schematic diagram of a folded modulator constructed in accordance with the present disclosure;
[0056] FIG. 8 is a schematic diagram of a rectifying detector constructed in accordance with the present disclosure;
[0057] FIG. 9A is a side view of an exemplary embodiment of an antenna constructed in accordance with the present disclosure for generating circularly polarized signals;
[0058] FIG. 9B is a side view of another exemplary embodiment of the antenna shown in FIG.9A;
[0059] FIG. 10 is a perspective view of another exemplary embodiment of the antenna shown in FIG. 9A, wherein the antenna is a bifilar helix antenna;
[0060] FIG. 11 is a perspective view of another exemplary embodiment of the bifilar helix antenna shown in FIG. 10, wherein the bifilar helix antenna is enclosed within a conductive cone;
[0061] FIG. 12 is a partial cross-sectional view of the bifilar helix antenna shown in FIG. 11, taken from the line 12-12' and in the direction of the arrows;
[0062] FIG. 13 is a diagrammatic view of an electric field produced by the bifilar helix antenna enclosed within the conductive cone shown in FIG. 12;
[0063] FIG. 14 is a diagrammatic view of a radiation pattern of the bifilar helix antenna enclosed within the conductive cone shown in FIG. 12;
[0064] FIG. 15 is a side view of an exemplary embodiment of a non-uniform bifilar helix antenna constructed in accordance with the present disclosure;
[0065] FIG. 16 is a side view of another exemplary embodiment of the non-uniform bifilar helix antenna;
[0066] FIG. 17 is a graphical view of a polarization discrimination of the non-uniform bifilar helix antenna shown in FIG. 15;
[0067] FIG. 18 is a graphical view of a polarization discrimination of the non-uniform bifilar helix antenna shown in FIG. 16;
[0068] FIG 19 is a side view of another exemplary embodiment of the non-uniform bifilar helix antenna;
[0069] FIG. 20 is a side view of another exemplary embodiment of the non-uniform bifilar helix antenna;
[0070] FIG. 21A is a diagrammatic front view of an exemplary embodiment of a differential waveguide probe antenna constructed in accordance with the present disclosure;
[0071] FIG. 21B is a diagrammatic side view of the differential waveguide probe antenna shown in FIG. 21A;
[0072] FIG. 22A is a partial cross-sectional view of the differential waveguide probe antenna shown in FIG. 21A, taken from the line 22-22' and in the direction of the arrows;
[0073] FIG. 22B is another partial cross-sectional view of the differential waveguide probe antenna shown in FIG. 22A, taken from the line 23-23' and in the direction of the arrows;
[0074] FIG. 22C is another partial cross-sectional view of the differential waveguide probe antenna shown in FIG. 22B, taken from the line 24-24' and in the direction of the arrows;
[0075] FIG. 22D is a graphical view of a polarization discrimination of the differential waveguide probe antenna shown in FIG. 21A;
[0076] FIG. 23 a diagrammatic view of an exemplary embodiment of a differential tapered antenna constructed in accordance with the present disclosure;
[0077] FIG. 24A is a partial cross-sectional view of the differential tapered antenna shown in FIG. 23, taken from the line l-TT and in the direction of the arrows;
[0078] FIG. 24B is another partial cross-sectional view of the differential tapered antenna shown in FIG. 24A, taken from the line 28-28' and in the direction of the arrows;
[0079] FIG. 24C is a graphical view of a polarization discrimination of the differential tapered antenna shown in FIG. 23;
[0080] FIG. 25A is a diagrammatic front view of an exemplary embodiment of a microstrip patch antenna array constructed in accordance with the present disclosure;
[0081] FIG. 25B is a diagrammatic side view of the microstrip patch antenna array shown in FIG. 25A;
[0082] FIG. 26A is a diagrammatic front view of an exemplary embodiment of a single-ended waveguide probe antenna constructed in accordance with the present disclosure;
[0083] FIG. 26B is a diagrammatic side view of the single-ended waveguide probe antenna shown in FIG. 26A;
[0084] FIG. 27A is a cross-sectional view of the single-ended waveguide probe antenna shown in FIG. 26A, taken along the line 55-55' and in the direction of the arrows;
[0085] FIG. 27B is another cross-sectional view of the single-ended waveguide probe antenna shown in FIG. 26A, taken along the line 56-56' and in the direction of the arrows;
[0086] FIG. 27C is a partial cross-sectional view of the single-ended waveguide probe antenna shown in FIG. 27B, taken along the line 57-57' and in the direction of the arrows;
[0087] FIG. 28A is a diagrammatic front view of an exemplary embodiment of a slot antenna constructed in accordance with the present disclosure;
[0088] FIG. 28B is a diagrammatic side view of the slot antenna shown in FIG. 28A;
[0089] FIG. 29A is a cross-sectional view of the slot antenna shown in FIG. 28A, taken along the line 59-59' and in the direction of the arrows;
[0090] FIG. 29B is a partial cross-sectional view of the slot antenna shown in FIG. 29A, taken along the line 60-60' and in the direction of the arrows;
[0091] FIG. 29C is another partial cross-sectional view of the slot antenna shown in FIG. 29A, taken along the line 61-61' and in the direction of the arrows;
[0092] FIG. 30A is a cross-sectional view of another embodiment of the slot antenna shown in FIG. 28A, taken along the line 59-59' and in the direction of the arrows, wherein the slot antenna is a double slot antenna;
[0093] FIG. SOB is a partial cross-sectional view of the slot antenna shown in FIG. 30A, taken along the line 63-63' and in the direction of the arrows;
[0094] FIG. 30C is another partial cross-sectional view of the slot antenna shown in FIG. 30A, taken along the line 64-64' and in the direction of the arrows;
[0095] FIG. 31A is a block diagram of a transport network constructed in accordance with the prior art;
[0096] FIG. 31B is an eye diagram representing a single symbol period of a feed signal in the transport network shown in FIG. 31A;
[0097] FIG. 32A is a block diagram of an exemplary embodiment of a transport network constructed in accordance with the present disclosure;
[0098] FIG. 32B is a block diagram of an exemplary embodiment of a first modulator shown in FIG. 32A;
[0099] FIG.32C is a block diagram of an exemplary embodiment of a first demodulator shown in FIG. 32A;
[0100] FIG. 32D is a constellation diagram representing a plurality of symbol states of an antenna feed signal in the transport network shown in FIG. 32A; and
[0101] FIG.33 is a block diagram of another exemplary embodiment of the transport network shown in FIG. 32A.DETAILED DESCRIPTION
[0102] The following detailed description refers to the accompanying drawings. The same reference numbers in different drawings may identify the same or similar elements.
[0103] As used herein, the terms "comprises," "comprising," "includes," "including," "has," "having" or any other variation thereof, are intended to cover a non-exclusive inclusion. For example, a process, method, article, or apparatus that comprises a list of elements is not necessarily limited to only those elements but may include other elements not expressly listed or inherentto such process, method, article, or apparatus. Further, unless expressly stated to the contrary, "or" refers to an inclusive or and not to an exclusive or. For example, a condition A or B is satisfied by anyone of the following: A is true (or present) and B is false (or not present), A is false (or not present) and B is true (or present), and both A and B are true (or present).
[0104] In addition, use of the "a" or "an" are employed to describe elements and components of the embodiments herein. This is done merely for convenience and to give a general sense of the inventive concept. This description should be read to include one or more and the singular also includes the plural unless it is obvious that it is meant otherwise.
[0105] Further, use of the term "plurality" is meant to convey "more than one" unless expressly stated to the contrary.
[0106] As used herein, qualifiers like "substantially," "about," "approximately," and combinations and variations thereof, are intended to include not only the exact amount or value that they qualify, but also some slight deviations therefrom, which may be due to manufacturing tolerances, measurement error, wear and tear, stresses exerted on various parts, and combinations thereof, for example.
[0107] The use of the term "at least one" or "one or more" will be understood to include one as well as any quantity more than one. In addition, the use of the phrase "at least one of X, V, and Z" will be understood to include X alone, V alone, and Z alone, as well as any combination of X, V, and Z.
[0108] The use of ordinal number terminology (i.e., "first", "second", "third", "fourth", etc.) is solely for the purpose of differentiating between two or more items and, unless explicitly stated otherwise, is not meant to imply any sequence or order or importance to one item over another or any order of addition.
[0109] Finally, as used herein any reference to "one embodiment" or "an embodiment" means that a particular element, feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment.
[0110] As used herein, all numerical values or ranges include fractions of the values and integers within such ranges and fractions of the integers within such ranges unless the context clearly indicates otherwise. Thus, to illustrate, reference to a numerical range, such as 1-10 includes 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, as well as 1.1, 1.2, 1.3, 1.4, 1.5, etc., and so forth. Reference to a range of 1-50 therefore includes 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, etc., up to and including 50, as well as 1.1, 1.2, 1.3, 1.4, 1.5, etc., 2.1, 2.2, 2.3, 2.4, 2.5, etc., and so forth. Reference to a series of ranges includes ranges which combine the values of the boundaries of different ranges within the series. Thus, to illustrate reference to a series of ranges, for example, of 1-10, 10-20, 20-30, 30-40, 40-50, 50-60, 60-75, 75-100, 100-150, 150-200, 200-250, 250-300, 300-400, 400-500, 500-750, 750-1,000, includes ranges of 1-20, 10-50, 50-100, 100-500, and 500-1,000, for example.
[0111] As used herein, "circuitry" may refer to analog and / or digital components, or one or more suitably programmed processor (e.g., a microprocessor) and associated hardware and software, or hardwired logic. Also, "circuitry" may perform one or more function. The term "circuitry" may include hardware, such as a processor (e.g., microprocessor), a combination of hardware and software, and / orthe like. Software may include one or more processor-executable instruction that when executed by one or more processor cause the one or more processor to perform a specified function. It should be understood that the algorithms described herein may be stored on one or more non-transitory memory. Exemplary non-transitory memory mayinclude random access memory, read only memory, flash memory, and / or the like. Such non-transitory memory may be electrically based, optically based, and / or the like.
[0112] As used herein, a "mode" refers to a unique distribution of electric and magnetic fields which repeat along the length of a hollow waveguide by which electromagnetic energy may be transported through the hollow waveguide. "Single-mode" refers to a hollow waveguide designed to carry only one mode of electromagnetic wave. This is achieved by having a narrow core diameter, which allows only one mode of light to propagate at a time. On the other hand, "multi-mode" refers to a hollow waveguide designed to carry multiple modes of electromagnetic waves simultaneously. This is possible due to its larger core diameter, which enables multiple modes to be propagated.
[0113] As used herein, "Amplitude Modulation" (AM) refers to a form of signal modulation in which data is encoded in an amplitude of a carrier signal.
[0114] As used herein, "Amplitude-Shift Keying" (ASK) refers to a form of AM in which digital data is encoded in an amplitude of a carrier signal, and each symbol (i.e., representing one or more data bit) is sent by transmitting a fixed-amplitude carrier wave at a fixed frequency for a specific time period.
[0115] As used herein, "Phase-Shift Keying" (PSK) is a form of signal modulation in which signal data is encoded in a phase of a carrier signal having a constant frequency. "Quadrature PSK" (PSK) Is a form of PSK in which two data bits (i.e., 00, 01, 10, or 11) are modulated at once, selecting one of four possible carrier phase shifts (i.e., 0°, 90°, 180°, or 270°).
[0116] As used herein, "Pulse-Amplitude Modulation" (PAM) refers to a form of AM in which a data signal is encoded in an amplitude of a series of carrier signal pulses. "PAM4" refers to a form of PAM in which a data signal is encoded in an amplitude of a series of carrier signal pulses, in which the amplitude of the carrier signal pulses may be one of four discrete values (i.e., 0, 1, 2, or 3) and each carrier signal pulse represents two data bits (i.e., 00, 01, 10, or 11).
[0117] As used herein, "Non-Return-to-Zero" (NRZ) refers to a form of signal modulation in which a binary data signal is encoded in a carrier signal such that ones are represented by a first significant condition (e.g., a positive voltage) and zeroes are represented by a second significant condition (e.g., a negative voltage). "Non-return-to-Zero, Inverted" (NRZI) refers to a form of signal modulation in which the data bits are represented by the presence or absence of a transition at a clock boundary.
[0118] As used herein, "Quadrature Amplitude Modulation" (QAM) refers to a form of AM in which two analog message signals or two digital bit streams are encoded in amplitudes of twocarrier waves, using either ASK or AM, and the two carrier signals are out of phase with each other by 90°. "QAM16" refers to a form of QAM in which the carrier signals may exist in one of sixteen discrete states (i.e., symbols) having one of sixteen different amplitude and phase levels representing four data bits (i.e., from 0000 to 1111).
[0119] As used herein, "Trellis Coded Modulation" (TCM) refers to a form of signal modulation in which a binary data signal is encoded in a phase of a constant amplitude carrier signal. The transmitted signal is created by convolutionally encoding the binary data signal and mapping the result to a signal constellation.
[0120] As used herein, "Rayleigh range" refers to the distance along the propagation direction of a beam from the waist to the place where the area of the cross section is doubled.
[0121] As used herein, "hollow waveguide" refers to a structure that guides waves by restricting transmission of energy in a particular direction. In the context of the present disclosure, "hollow waveguide" may refer to a fiber having a waveguide core operable to propagate RF (i.e., radiated) signals comprising electromagnetic waves in the THz frequency band or a routed waveguide operable to propagate such signals in the THz frequency band.
[0122] As used herein, "diameter" refers to a straight line passing from side to side through the center of a body or figure. In some embodiments, the body or figure has a circular shape having a uniform diameter or an elliptical shape having multiple different diameters.
[0123] As used herein, "data" refers to quantities, characters, or symbols on which operations are performed by a computer. Data can be recorded on a non-transitory computer readable medium, such as random-access memory and / or read only memory. The randomaccess memory and / or read only memory may be implemented on semiconductor, magnetic, optical, or mechanical recording media. An example of data is client data, e.g., data provided by a client in connection with a telecommunication service and / or a storage service.
[0124] Referring now to the drawings, and in particular to FIG. 1, shown therein is a diagrammatic view of an electromagnetic (EM) spectrum 100 in accordance with the present disclosure. The present disclosure is generally related to network elements that communicate using radiated signals comprising radiated electromagnetic waves coupled into hollow waveguides. The radiated signals described herein generally have a transmission frequency in what is referred to as a Terahertz (THz) frequency band 104 (i.e., frequencies between 0.1 THz and 10 THz corresponding to wavelengths between 3 millimeters (mm) and 30 micrometers (pm)). However, in some embodiments described herein, the transmission frequency of the radiated signals is in a range between 300 Gigahertz (GHz) and 10 THz. The radiated signalsdescribed herein generally have a bandwidth in a range between 10% and 40% of the transmission frequency.
[0125] Referring now to FIG. 2, shown therein is a block diagram of an exemplary embodiment of a transport network 200 (hereinafter, the "transport network 200") constructed in accordance with the present disclosure. The transport network 200 is depicted as comprising a plurality of network elements 204a-n (hereinafter, the "network elements 204") (e.g., a first network element 204a, a second network element 204b, a third network element 204c, and a fourth network element 204d shown in FIG. 2). While only four of the network elements 204 are shown in FIG. 2 for exemplary purposes, it should be understood that the transport network 200 may comprise a number of the network elements 204 that may be greater or fewer than four.
[0126] The transport network 200 may further comprise one or more hollow waveguides 208a-n (hereinafter, the "hollow waveguides 208") (e.g., a first hollow waveguide 208a, a second hollow waveguide 208b, a third hollow waveguide 208c, and a fourth hollow waveguide 208d shown in FIG. 2). While only four of the hollow waveguides 208 are shown in FIG. 2 for exemplary purposes, it should be understood that the transport network 200 may comprise a number of the hollow waveguides 208 that may be greater or fewer than four.
[0127] Radiated signals transmitted within the transport network 200 from the first network element 204a to the fourth network element 204d or vice versa may travel along (1) a first path formed by the first hollow waveguide 208a, the second network element 204b, and the second hollow waveguide 208b or (2) a second path formed by the third hollow waveguide 208c, the third network element 204c, and the fourth hollow waveguide 208d.
[0128] In some embodiments, each of the hollow waveguides 208 is configured to support propagation of radiated signals in only a single direction. However, in other embodiments, one or more of the hollow waveguides 208 may be configured to support propagation of radiated signals in a plurality of directions (i.e., two opposing directions). In embodiments where one or more of the hollow waveguides 208 are configured to support propagation of radiated signals in a plurality of directions, a first radiated signal being propagated through the hollow waveguide 208 in a first direction may be differentiated from a second radiated signal being propagated through the hollow waveguide 208 in a second direction opposite the first direction by being provided with a different polarization, frequency, etc. In some such embodiments, one or more circulator may be included to achieve such differentiation.
[0129] Each of the network elements 204 may comprise one or more of a transmitter 212 (e.g., a first transmitter 212a and a second transmitter 212b shown in FIG. 2) operable to transmitradiated signals comprising radiated electromagnetic waves having client data encoded therein via the hollow waveguides 208, a receiver 216 (e.g., a first receiver 216a and a second receiver 216b shown in FIG. 2) operable to receive radiated signals comprising radiated electromagnetic waves having client data encoded therein via the hollow waveguides 208, and / or a transceiver 220 (e.g., a first transceiver 220a shown in FIG. 2 and a second transceiver 220b shown in FIG.6B) operable to transmit first radiated signals comprising first radiated electromagnetic waves having first client data encoded therein via particular ones of the hollow waveguides 208 and / or receive second radiated signals comprising second radiated electromagnetic waves having second client data encoded therein via other ones of the hollow waveguides 208.
[0130] Each of the network elements 204 may further comprise a control module 224 (e.g., a first control module 224a, a second control module 224b, a third control module 224c, and a fourth control module 224d shown in FIG. 2) (collectively, the "control modules 224") operable to regulate one or more operating parameter of the network element 204 to which the control module 224 is coupled.
[0131] In some embodiments, one or more of the network elements 204 may communicate with each other via a communication network 228. The communication network 228 may permit bidirectional communication of information and / or data between one or more of the network elements 204 of the transport network 200. The communication network 228 may interface with one or more of the network elements 204 in a variety of ways. For example, in some embodiments, the communication network 228 may interface by optical and / or electronic interfaces, and / or may use a plurality of network topographies and / or protocols including, but not limited to, Ethernet, TCP / IP, circuit switched path, combinations thereof, and / orthe like. The communication network 228 may utilize a variety of network protocols to permit bidirectional interface and / or communication of data and / or information between one or more of the network elements 204.
[0132] The communication network 228 may be almost any type of network. For example, in some embodiments, the communication network 228 may be a version of an Internet network (e.g., exist in a TCP / IP-based network). In one embodiment, the communication network 228 is the Internet. It should be noted, however, that the communication network 228 may be almost any type of network and may be implemented as the World Wide Web (i.e., the Internet), a local area network (LAN), a wide area network (WAN), a metropolitan network, a wireless network, a cellular network, a Bluetooth network, a Global System for Mobile Communications (GSM) network, a code division multiple access (CDMA) network, a 3G network, a 4G network, an LTE1network, a 5G network, a satellite network, a radio network, an optical network, a cable network, a public switched telephone network, an Ethernet network, combinations thereof, and / or the like.
[0133] If the communication network 228 is the Internet, a primary user interface of the transport network 200 may be delivered through a series of web pages or private internal web pages of a company or corporation, which may be written in hypertext markup language, JavaScript, or the like, and accessible by the user. It should be noted that the primary user interface of thetransport network 200 may be anothertype of interface including, but not limited to, a Windows-based application, a tablet-based application, a mobile web interface, a VR-based application, an application running on a mobile device, and / orthe like. In one embodiment, the communication network 228 may be connected to one or more of the network elements 204.
[0134] The number of devices and / or networks illustrated in FIG. 2 is provided for exemplary purposes. In practice, there may be additional devices and / or networks, fewer devices and / or networks, different devices and / or networks, or differently arranged devices and / or networks than are shown in FIG. 2. Furthermore, two or more of the devices illustrated in FIG. 2 may be implemented within a single device, or a single device illustrated in FIG. 2 may be implemented as multiple, distributed devices. Additionally, or alternatively, one or more of the devices of the transport network 200 may perform one or more functions described as being performed by another one or more of the devices of the transport network 200.
[0135] The network elements 204 may take many different forms. For example, the network elements 204 may be integrated circuits (ICs). In this example, the network elements 204 (e.g., ICs) may communicate via signals comprising radiated electromagnetic waves having client data encoded therein via the hollow waveguides 208 without requiring electrical data busses. In other embodiments, the network elements 204 may be incorporated into components in a data center, such as servers, routers, switches, firewalls, storage systems, application delivery controllers, and / or the like to establish communication between such components in the data center via signals comprising radiated electromagnetic waves having client data encoded therein propagated through the hollow waveguides 208. The hollow waveguides 208 may thus extend from one integrated circuit to another integrated circuit, or from one component to another component, and such may be implemented in a variety of ways, such as IC-to-IC communications, printed circuit board (PCB)-to-PCB communications, component-to-component communications, and / or combinations thereof. In the example of PCB-to-PCB communications, the network elements 204 may each include a PCB.
[0136] Referring now to FIGS. 3A-3U shown therein are cross-sectional views of various exemplary embodiments of the first hollow waveguide 208a shown in FIG. 2, taken along the line 3-3' and in the direction of the arrows. However, it should be understood that the description referring to FIGS. 3A-3U may be applicable to any of the hollow waveguides 208 described herein. In the embodiments shown in FIGS. 3A-3U, the first hollow waveguide 208a is a hollow fiber. However, it should be understood that in other embodiments, the first hollow waveguide 208a may be another form of hollow waveguide, such as a substrate-integrated waveguide, for example.
[0137] The first hollow waveguide 208a (and, therefore, each of the hollow waveguides 208) generally comprises a hollow waveguide core 304 and a tubular sidewall 306 having an inner surface 312 in some embodiments defining the hollow waveguide core 304 or in other embodiments simply surrounding the hollow waveguide core 304.
[0138] Generally, the hollow waveguide core 304 may be composed of any material capable of propagating radiated electromagnetic waves within the THz frequency band 104 or, in some embodiments, in the range between 300 GHz and 10 THz. More particularly, the hollow waveguide core 304 may be composed of any materials having a low absorption loss (i.e., an absorption loss in a range between 1 dB / km and 10,000 dB / km) within the THz frequency band 104, or in some embodiments, in the range between 300 GHz and 10 THz.
[0139] In some embodiments, the hollow waveguide core 304 may be composed of a polymer (e.g., cyclic olefin polymer (COP), cyclic olefin co-polymer (COC), polytetrafluoroethylene (PTFE), high-density polyethylene (HDPE), polymethylpentene (PMP), polypropylene (PP), polystyrene, polycarbonate, poly(methyl methacrylate) (PMMA), Picarin, or ultraviolet (UV) resin) or glass (e.g., silica glass, crown glass, or borosilicate glass).
[0140] In other embodiments, the hollow waveguide core 304 may be composed of a gas, a vacuum, ora porous material (i.e., a material having a porosity in a range between 25% and 99%). In such embodiments, the hollow waveguide core 304 may have a refractive index in a range between 1.0 and 1.4, for example. As discussed in more detail below, the hollow waveguide core 304 may have a refractive index ni.
[0141] In some embodiments, the hollow waveguide core 304 may have a cross-section configured to support propagation of radiated signals having only a single polarization at a given time. However, in other embodiments, the hollow waveguide core 304 may have a cross-section configured to support propagation of radiated signals having a plurality of polarizations at a given time. In either case, the hollow waveguide core 304 may have a cross-section configured tosupport propagation of radiated signals having one or more linear polarizations or one or more circular polarizations.
[0142] In some embodiments, the hollow waveguide core 304 may have a cross-section configured to support propagation of radiated signals having only a single mode at a given time. However, in other embodiments, the hollow waveguide core 304 may have a cross-section configured to support propagation of radiated signals having a plurality of modes at a given time.
[0143] The tubular sidewall 306 of the first hollow waveguide 208a (and, therefore, each of the hollow waveguides 208) may comprise a conductive layer 316 (shown in FIGS. 3A-3I) surrounding the hollow waveguide core 304, a dielectric layer 308 (shown in FIGS. 3A, 3C, and 3F-3I) optionally disposed between the hollow waveguide core 304 and the conductive layer 316, and a support layer 320 (shown in FIGS. 3A, 3B, and 3E-3I) optionally surrounding the conductive layer 316.
[0144] In some embodiments, the tubular sidewall 306 of the first hollow waveguide 208a (and, therefore, each of the hollow waveguides 208) may comprise a plurality of the conductive layer 316 interleaved with a plurality of the dielectric layer 308.
[0145] In some embodiments, the tubular sidewall 306 of the first hollow waveguide 208a (and, therefore, each of the hollow waveguides 208) may further comprise one or more strength members (not shown) (hereinafter, the "strength members") surrounding the conductive layer 316 configured to enhance resilience of the first hollow waveguide 208a. In such embodiments, the support layer 320 may surround the strength members.
[0146] Generally, the conductive layer 316 may be composed of any material having a refractive index ns greater than the refractive index of the hollow waveguide core 304 (i.e., ni). More particularly, the conductive layer 316 may be composed of a non-oxidizing metallic material (e.g., silver, gold, or indium tin oxide (ITO)). Providing the conductive layer 316 with a refractive index greater than the refractive index of the hollow waveguide core 304 may cause an effective index An of the first hollow waveguide 208a to increase, thereby causing more radiated signals to be confined and propagated within the hollow waveguide core 304.
[0147] Generally, in embodiments in which the dielectric layer 308 is disposed between the conductive layer 316 and the hollow waveguide core 304, the dielectric layer 308 may be composed of any material having a refractive index n2 greater than the refractive index of the hollow waveguide core 304 (i.e., ni). More particularly, the dielectric layer 308 may be composed of a polymer (e.g., cyclic olefin polymer (COP), cyclic olefin co-polymer (COC), polytetrafluoroethylene (PTFE), high-density polyethylene (HDPE), polymethylpentene (PMP),polypropylene (PP), polystyrene, polycarbonate, poly(methyl methacrylate) (PMMA), Picarin, or ultraviolet (UV) resin) or glass (e.g., silica glass, crown glass, or borosilicate glass), but particularly a material having a refractive index n? greater than the refractive index of the hollow waveguide core 304 (i.e., ni) in that embodiment. Providing the dielectric layer 308 with a refractive index greaterthan the refractive index of the hollow waveguide core 304 may cause an effective index An of the first hollow waveguide 208a to increase, thereby causing more radiated signals to be confined and propagated within the hollow waveguide core 304.
[0148] The support layer 320 may be configured to shield the inner layers of the first hollow waveguide 208a (and, therefore, any of the hollow waveguides 208) from external environmental factors, provide flexibility to the first hollow waveguide 208a, and / or enhance a tensile strength of the first hollow waveguide 208a. In some embodiments, the support layer 320 may be composed of polymer materials, such as acrylate polymer or polyimide, for example.
[0149] In some embodiments, the cross-section of the hollow waveguide core 304 may have a circular shape (i.e., having a diameter di that is equal along both the x-axis and the y-axis) (shown in FIGS. 3A-3D). In some such embodiments, the diameter di of the hollow waveguide core 304 may be between 30 pm and 6 mm. In some such embodiments, the diameter di of the hollow waveguide core 304 may be between 30 pm and 3 mm. In at least one such embodiment, the diameter di of the hollow waveguide core 304 may be 1 mm.
[0150] In some embodiments, as shown in FIG. 3E, the first hollow waveguide 208a may be a photonic-bandgap fiber comprising a plurality of air channels 324 (hereinafterthe "air channels 324") periodically spaced throughout the conductive layer 316.
[0151] In other embodiments, the cross-section of the hollow waveguide core 304 may have an elliptical shape (i.e., having a first diameter Xi along the x-axis and a second diameter yi along the y-axis, wherein the first diameter is not equal to the second diameter) (shown in FIG. 3F), a rectangular shape (shown in FIG. 3G) (i.e., having a first length xi along the x-axis and a second length yi along the y-axis, wherein the first length is not equal to the second length), a square shape (i.e., having a length li that is equal along both the x-axis and the y-axis) (shown in FIG.3H), or a cross shape (i.e., having a length h that is equal along both the x-axis and the y-axis) (shown in FIG. 31), for example.
[0152] In other embodiments, the first hollow waveguide 208a (and, therefore, any of the hollow waveguides 208) may be implemented as a solid rod fiber (shown in FIG. 3J), a microstructured optical fiber (shown in FIG. 3K), a porous fiber (shown in FIG. 3L), a suspended porous-core fiber (shown in FIG. 3M), a suspended slotted core fiber (shown in FIG. 3N), a hollow-core bandgap fiber (shown in FIG. 30), a hollow-core tube fiber (shown in FIG. 3P), a hollow-core fiber with negative curvature (shown in FIG. 3Q), a hollow-core fiber based on anti-resonances and inhibited coupling (shown in FIG. 3R), a hollow-core nested anti-resonant nodeless fiber (shown in FIG. 3S), a 3D-printed hollow-core fiber based on anti-resonances and inhibited coupling (shown in FIG. 3T), or a Bragg fiber (shown in FIG. 3U), for example.
[0153] In some embodiments, such as in the suspended porous-core fiber implementation shown in FIG. 3M and the suspended slotted core fiber implementation shown in FIG. 3N, the first hollow waveguide 208a (and, therefore, any of the hollow waveguides 208) may have a waveguide core 328 and a sheathing 332 surrounding the waveguide core 328.
[0154] The waveguide core 328 may comprise a dielectric material or a semiconductor material depending upon variables such as temperature, impurities (doping) and applied voltage, if any. The dielectric material or a semiconductor material may have a monocrystalline, polycrystalline, or amorphous structure. In some embodiments, the dielectric material or the semiconductor material may be selected from a group consisting of silicon (Si), germanium (Ge), and carbon (C). In some embodiments in which the dielectric material comprises silicon, the dielectric material may be further defined as high-resistivity (e.g., in a range between 2 kQ-cm and 400 kQ-cm) float zone silicon (HRFZ-Si). In some embodiments in which the dielectric material comprises carbon, the dielectric material may be further defined as graphene (e.g., graphene Oxide, Fluorographene), single-crystal carbon, such as diamond, or diamond-like carbon (DLC), for example.
[0155] At least a portion of the sheathing 332 may be spaced a distance from the waveguide core 328, for example, in FIG. 3M and FIG. 3N to form a cladding region 336 between the waveguide core 328 and the sheathing 332. In some embodiments, the sheathing 332 may comprise a low-refractive-index (e.g., having a refractive index of < 2) material such as a glass, polymeric material, or plastic material. In some such embodiments, the sheathing 332 may further comprise a metal material (e.g., as a coating) configured to confine the electromagnetic waves. In some embodiments, the sheathing 332 may be opaque (e.g., to prevent light from interacting with the waveguide core 328).
[0156] The cladding region 336 may comprise a material having a lower refractive index than the refractive index of the suspended waveguide core 328, thereby resulting in the waveguide core 328 having an effective index contrast configured to confine electromagnetic waves within the waveguide core 328 and thereby guide the electromagnetic waves. In some embodiments, the cladding region 336 may comprise a gas (e.g., air), vacuum, or foam.
[0157] In some embodiments, such as in the embodiments shown in FIG. 3M and FIG. 3N, the waveguide core 328 may be suspended. In these embodiments, the waveguide core 328 may be suspended by support members 340a-n (hereinafter the "support members 340") extending between the waveguide core 328 and the sheathing 332 to support the waveguide core 328 centrally within the sheathing 332. While three of the support members 340 (i.e., a first support member 340a, a second support member 340b, and a third support member 340c) are shown in FIGS. 3M and 3N, it should be understood that the first hollow waveguide 208a may have two or more support members 340.
[0158] Referring now to FIG. 4A, shown therein is a block diagram of an exemplary embodiment of the first transmitter 212a shown in FIG. 2. However, it should be understood that the description of any particular one of the transmitter 212 may be applicable to any of the transmitters 212 described herein. The first transmitter 212a (and, therefore, each of the transmitters 212) generally comprises a client-side input 400 configured to receive one or more baseband signals 404 (hereinafter, the "baseband signals 404") having client data encoded therein from one or more external component (e.g., a control module 224), transmitter circuitry 408 configured to receive the baseband signals 404 from the client-side input 400 and generate one or more antenna feed signals 412 (hereinafter, the "antenna feed signals 412") based on the baseband signals 404, and one or more first antennas 416 configured to receive the antenna feed signals 412 from the transmitter circuitry 408, generate one or more radiated signals 420 (hereinafter, the "radiated signals 420") based on the antenna feed signals 412, and couple the radiated signals 420 into the first hollow waveguide 208a.
[0159] In some embodiments, the client-side input 400 is a pair of inputs configured to receive a differential signal. In some such embodiments, the client-side input 400 may be a low voltage differential signaling (LVDS) link configured to receive LVDS signals, and the baseband signals 404 may be LVDS signals indicative of client data.
[0160] In some embodiments, the antenna feed signals 412 are provided to the first antennas 416 on one or more transmission lines (not shown) (hereinafter, the "transmission lines"), wherein each of the transmission lines has two or more conductors (not shown) (hereinafter, the "conductors"). In some embodiments, the transmission lines have a first transmission loss and the first hollow waveguide 208a has a second transmission loss that is less than the first transmission loss. In some embodiments, the second transmission loss is in a range between 0.001 and 20.00 decibels (dB) per meter (m) per Terabit (Tb) per second (s).
[0161] In some embodiments, as shown in FIG. 4A, each of the client-side input 400, the transmitter circuitry 408, and the first antennas 416 may be disposed on a substrate 424. However, in other embodiments, one or more of the client-side input 400, the transmitter circuitry 408, and the first antennas 416 may be disposed on a first substrate (not shown), and one or more of the client-side input 400, the transmitter circuitry 408, and the first antennas 416 may not be disposed on the first substrate. For example, the one or more of the client-side input 400, the transmitter circuitry 408, and the first antennas 416 may be disposed on a second substrate (not shown). In such embodiments, the first substrate and the second substrate may be in a stacked arrangement.
[0162] In some embodiments, the substrate 424 may have a plurality of layers (not shown). In such embodiments, one or more of the client-side input 400, the transmitter circuitry 408, and the first antennas 416 may be disposed on a first layer (not shown), and one or more of the clientside input 400, the transmitter circuitry 408, and the first antennas 416 may be disposed on a second layer (not shown).
[0163] In some embodiments, one or more of the client-side input 400, the transmitter circuitry 408, and the first antennas 416 may be integrated into a monolithic semiconductor die (not shown). In some embodiments, one or more of the client-side input 400, the transmitter circuitry 408, and the first antennas 416 may implemented using one or more of complementary metal-oxide semiconductor (CMOS) technology, silicon-germanium (SiGe) semiconductor technology, and lll-V compound semiconductor technology.
[0164] In some embodiments, the baseband signals 404 are digital bitstreams. In some embodiments, the client data may be encoded in the baseband signals 404 using an encoding protocol conforming to requirements of one or more of return-to-zero (RZ) code, non-return-to-zero (NRZ) code, pulse-amplitude modulation (PAM), and quadrature-amplitude modulation (QAM). In some embodiments, the client data may be encoded in the radiated signals 420 using an encoding protocol conforming to requirements of one or more of RZ, NRZ, quadrature phaseshift keying (QPSK), QAM, trellis coded modulation (TCM), and Bose-Chaudhuri-Hocquenghem (BCH) code.
[0165] In some embodiments, the radiated signals 420 include a first complementary radiated signal (not shown) having a first polarization and a second complementary radiated signal (not shown) having a second polarization different from the first polarization. In such embodiments, the first antennas 416 may be configured to generate the radiated signals 420 including the first complementary radiated signal and the second complementary radiated signalbased on the antenna feed signals 412. The first polarization and the second polarization may be orthogonal to each other.
[0166] In some embodiments, each of the first polarization and the second polarization may be a linear polarization. In such embodiments, the first antennas 416 may include one or more of a differential waveguide probe antenna, a differential tapered antenna, and a differential patch antenna. In other embodiments, each of the first polarization and the second polarization may be a circular polarization. In such embodiments, the first antennas 416 may include one or more of a helix antenna and a spiral antenna.
[0167] In some embodiments, the radiated signals 420 include a first complementary radiated signal (not shown) having a first polarization and a second complementary radiated signal (not shown) having a second polarization different from the first polarization, and the first antennas 416 are further configured to couple the first complementary radiated signal and the second complementary radiated signal into the first hollow waveguide 208a such that the first complementary radiated signal and the second complementary radiated signal interact in the first hollow waveguide 208a to form the combined radiated signal (not shown) having a third polarization different from the first polarization and the second polarization. In such embodiments, the first antennas 416 may include an antenna array.
[0168] Referring now to FIG. 4B, in some embodiments, the first transmitter 212a (and, therefore, any of the transmitters 212) further comprises a first serializer 426 configured to receive a plurality of parallel baseband signals 428a-n (hereinafter, the "parallel baseband signals 428") and combine the parallel baseband signals 428 into a serial baseband signal (i.e., the baseband signals 404). In such embodiments, the client-side input 400 may be configured to receive the baseband signals 404 from the first serializer 426. In some such embodiments, combining the parallel baseband signals 428 into the baseband signals 404 utilizes at least one of polarization division multiplexing (PDM), time division multiplexing (TDM), and wavelength division multiplexing (WDM).
[0169] Referring now to FIG. 4C, in some embodiments, the first transmitter 212a (and, therefore, any of the transmitters 212) further comprises a first deserializer 432 configured to receive a serial baseband signal (i.e., the baseband signals 404) and split the baseband signals 404 into parallel baseband signals 428. In such embodiments, the client-side input 400 may be configured to receive the parallel baseband signals 428 from the first deserializer 432. In some such embodiments, splitting the baseband signals 404 into the parallel baseband signals 428 utilizes at least one of PDM, TDM, and WDM.
[0170] Referring now to FIG. 4D, shown therein is an exemplary embodiment of the transmitter circuitry 408 shown in FIGS. 4A-4C. In some embodiments, the transmitter circuitry 408 comprises one or more local oscillators 436a-n (hereinafter, the "LO 436") configured to generate one or more carrier signals 440 (hereinafter, the "carrier signals 440") having a baseband frequency less than the transmission frequency, one or more modulation circuits 444 (hereinafter, the "modulator 444") configured to receive the baseband signals 404 from the client-side input 400 and the carrier signals 440 from the LO 436 and modulate the baseband signals 404 onto the carrier signals 440 to generate one or more modulated signals 448 (hereinafter, the "modulated signals 448"), and one or more up-conversion circuits 452 (hereinafter, the "up-convertor 452") configured to receive the modulated signals 448 from the modulator 444 and up-convert the modulated signals 448 (i.e., raise a frequency of the modulated signals 448 from the baseband frequency to the transmission frequency) to generate the antenna feed signals 412.
[0171] Referring now to FIG. 4E, in embodiments in which the client-side input 400 is configured to receive the parallel baseband signals 428, the transmitter circuitry 408 may be configured to receive the parallel baseband signals 428 from the client-side input 400. In such embodiments, the modulator 444 may be configured to receive the parallel baseband signals 428 from the client-side input 400 and the carrier signals 440 from first LO 436 and modulate the parallel baseband signals 428 onto the carrier signals 440 to generate the modulated signals 448. In such embodiments, the up-converter 452 may be configured to receive the modulated signals 448 from the modulator 444 and up-convert the modulated signals 448 to generate one or more up-converted signals 460 (hereinafter, the "up-converted signals 460").
[0172] In some embodiments, the transmitter circuitry 408 may further comprise a combiner 456 configured to receive the up-converted signals 460 from the up-converter 452 and combine the up-converted signals 460 into the antenna feed signals 412. However, in other embodiments, the first antennas 416 may be configured to receive the antenna feed signals 412 from the up-converter 452, generate the radiated signals 420 based on the antenna feed signals 412, and couple the radiated signals 420 into the first hollow waveguide 208a such that the radiated signals 420 interact in the first hollow waveguide 208a to form a combined radiated signal (not shown).
[0173] In some embodiments, coupling the radiated signals 420 into the first hollow waveguide 208a such that the radiated signals 420 interact in the first hollow waveguide 208a to form the combined radiated signal utilizes at least one of PDM, TDM, and WDM.
[0174] Referring now to FIG. 4F, shown therein is a block diagram of another exemplary embodiment of the first transmitter 212a shown in FIG. 2. However, it should be understood that the description of any particular one of the transmitters 212 may be applicable to any of the transmitters 212 described herein.
[0175] In the embodiment shown in FIG. 4F, the first transmitter 212a comprises the clientside input 400 configured to receive the baseband signals 404 from one or more external component (e.g., a control module 224) and send the baseband signals 404 to the transmitter circuitry 408, the transmitter circuitry 408 configured to receive the baseband signals 404 from the client-side input 400, generate the antenna feed signals 412 based on the baseband signals 404, and send the antenna feed signals 412 to an RF interface 464 configured to receive the antenna feed signals 412 from the transmitter circuitry 408 and transmit the antenna feed signals 412, and a digital enhancement and control unit 468 configured to provide digital control and / or processing capabilities for one or more of the components of the first transmitter 212a.
[0176] In the embodiment shown in FIG. 4F, the transmitter circuitry 408 comprises one or more modulator 444a (hereinafter, the "modulator 444a"), a frequency synthesizer 472 comprising a phase-locked loop (PLL) 476 and a first LO 436a, a second LO 436b, a first frequency mixer 480a, a second frequency mixer 480b, a first amplifier 484a, and a second amplifier 484b.
[0177] The modulator 444a may be configured to receive the baseband signals 404 from the client-side input 400 and encode the baseband signals 404 in a format suitable for modulation onto a carrier signal. In some embodiments, the modulator 444a may include one or more digital-to-analog converter (DAC), one or more Serializer / Deserializer (SerDes), one or more folded modulator 700 (shown in FIG. 7), and / or circuitry operable to encode the baseband signals 404 in a modulation format, such as AM, ASK, PSK, QAM, QAM16, or variations thereof, for example. In some embodiments, the modulator 444a may include circuitry operable to perform forward error correction (FEC). The modulator 444a may be further configured to send the encoded input signals having the data encoded therein to the second frequency mixer 480b.
[0178] In some embodiments, the modulator 444a is configured to simply receive the baseband signals 404 (i.e., the baseband signals 404 having been previously encoded in a modulation format) from the client-side input 400 and send the baseband signals 404 to the second frequency mixer 480b.
[0179] The second LO 436b may be configured to generate second carrier signals having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency (i.e., an intermediate frequency (IF) frequency). In some embodiments, the predetermined frequency of21the second carrier signals (i.e., the IF frequency) is in an RF band (i.e., in a range between 30 Hertz (Hz) and 300 GHz). In some embodiments, the predetermined frequency of the second carrier signals (i.e., the IF frequency) is in a range between 1 Megahertz (MHz) and 300 GHz. In some embodiments, the predetermined frequency of the second carrier signals (i.e., the IF frequency) is in a range between 5 GHz and 30 GHz. The second LO 436b may be further configured to send the second carrier signals to the second frequency mixer 480b.
[0180] The second frequency mixer 480b may be configured to receive the encoded baseband signals from the modulator 444a, receive the second carrier signals from the second LO 436b, up-convert the encoded baseband signals with the second carrier signals to produce first modulated signals having client data encoded therein and having the predetermined frequency of the second carrier signals (i.e., the IF frequency), and send the first modulated signals to the third amplifier 484c.
[0181] The third amplifier 484c may be configured to receive the first modulated signals from the second frequency mixer 480b, adjust an amplitude of the first modulated signals such that the amplified first modulated signals can drive the first frequency mixer 480a, and send the amplified first modulated signals to the first frequency mixer 480a.
[0182] The frequency synthesizer 472 (i.e., the first LO 436a and the PLL 476) may be configured to generate first carrier signals having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency (e.g., within the THz frequency band 104 or, in some embodiments, in a range between 300 GHz and 10 THz). In some embodiments, the predetermined frequency of the first carrier signals is in a range between 30 GHz and 300 GHz. In some such embodiments, the predetermined frequency of the first carrier signals is 240 GHz. In other embodiments, the predetermined frequency of the first carrier signals is in a range between 300 GHz and 3 THz. The frequency synthesizer 472 may be further configured to send the first carrier signals to the second amplifier 484b.
[0183] The second amplifier 484b may be configured to receive the first carrier signals from the first LO 436a, adjust an amplitude of the first carrier signals to generate amplified carrier signals that can drive the first frequency mixer 480a, and send the amplified carrier signals to the first frequency mixer 480a.
[0184] The first frequency mixer 480a may be configured to receive the amplified carrier signals from the second amplifier 484b, receive the amplified first modulated signals from the third amplifier 484c, up-convert the amplified first modulated signals with the amplified carrier signals to produce second modulated signals having the client data encoded therein and havingthe predetermined frequency of the amplified carrier signals (i.e., within the THz frequency band 104 or, in some embodiments, in a range between 300 GHz and 10 THz), and send the second modulated signals to the first amplifier 484a.
[0185] The first amplifier 484a may be configured to receive the second modulated signals from the first frequency mixer 480a, adjust an amplitude of the second modulated signals such that the amplified second modulated signals can be transmitted by the RF interface 464, and send the amplified second modulated signals to the RF interface 464. The first amplifier 484a may be configured to generate the amplified second modulated signals to have a power in a range between 0.05 watts (W) and 0.4 W, for example.
[0186] The RF interface 464 may be configured to receive the amplified second modulated signals with the client data encoded therein from the first amplifier 484a and send the amplified second modulated signals as the antenna feed signals 412 (i.e., having the client data encoded therein) within a predetermined frequency range (e.g., the THz frequency band 104 or, in some embodiments, in a range between 300 GHz and 10 THz). In some embodiments, the RF interface 464 may be electrically connected to one of the first antennas 416 and configured to send the antenna feed signals 412 to the first antenna 416. In other embodiments, however, the first antennas 416 may be included in place of the RF interface 464.
[0187] Referring now to FIG. 4G, shown therein is a block diagram of another exemplary embodiment of the first transmitter 212a shown in FIG. 2. In the embodiment shown in FIG. 5B, the first transmitter 212a comprises a plurality of inputs including an in-phase (l)-BB client-side input 400a and a quadrature (Q)-BB client-side input 400b configured to receive l-BB baseband signals 404a and Q-BB baseband signals 404b, respectively, from one or more external component (e.g., a control module 224) and an LO input 400c configured to receive one or more carrier signals 488 (hereinafter, the "carrier signals 488") from an external LO, the transmitter circuitry 408 configured to generate the antenna feed signals 412 based on the l-BB baseband signals 404a, the Q-BB baseband signals 404b, and the carrier signals 488, and the RF interface 464 configured to transmit the antenna feed signals 412.
[0188] In the embodiment shown in FIG. 4G, the transmitter circuitry 408 comprises a balancing unit (Balun) 492, a third frequency mixer 480c, a fourth frequency mixer 480d, a fifth frequency mixer 480e, and a sixth frequency mixer 480f, a fourth amplifier 484d, a fifth amplifier 484e, a sixth amplifier 484f, a seventh amplifier 484g, and eighth amplifier 484h, a quadrature coupler (e.g., branchline coupler) 494, and a power combiner (e.g., Wilkinson power combiner) 498.
[0189] The l-BB baseband signals 404a and the Q-BB baseband signals 404b may be I and Q components of baseband signals 404 having client data encoded therein. The l-BB client-side input 400a may be configured to send the l-BB baseband signals 404a to the sixth amplifier 484f. The Q-BB client-side input 400b may be configured to send the Q-BB baseband signals 404b to the seventh amplifier 484g.
[0190] The LO input 400c may be configured to receive the carrier signals 488 from an external LO, the carrier signals 488 having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency. The LO input 400c may be further configured to send the carrier signals 488 to the Balun 492.
[0191] The Balun 492 may be configured to isolate and / or maintain impedance differences between balanced transmission lines and unbalanced transmission lines. The Balun 492 may be further configured to send the carrier signals 488 to the third frequency mixer 480c.
[0192] The third frequency mixer 480c may be configured to receive the carrier signals 488 from the Balun 492, multiply the carrier signals 488 (e.g., by a multiple of four), and send the multiplied carrier signals to the fourth amplifier 484d.
[0193] The fourth amplifier 484d may be configured to receive the multiplied carrier signals from the third frequency mixer 480c, adjust an amplitude of the multiplied carrier signals such that the amplified carrier signals can drive the fourth frequency mixer 480d, and send the amplified carrier signals to the fourth frequency mixer 480d.
[0194] The fourth frequency mixer 480d may be configured to receive the amplified carrier signals from the fourth amplifier 484d, multiply the amplified carrier signals (e.g., by a multiple of two), and send the remultiplied carrier signals to the fifth amplifier 484e.
[0195] The fifth amplifier 484e may be configured to receive the remultiplied carrier signals from the fourth frequency mixer 480d, adjust an amplitude of the remultiplied carrier signals such that the reamplified carrier signals can drive the quadrature coupler 494, and send the reamplified carrier signals to the quadrature coupler 494.
[0196] The sixth amplifier 484f may be configured to receive the l-BB baseband signals 404a from the l-BB client-side input 400a, adjust an amplitude of the l-BB baseband signals 404a such that the amplified l-BB input signals can drive the fifth frequency mixer 480e, and send the amplified l-BB signals to the fifth frequency mixer 480e.
[0197] The seventh amplifier 484g may be configured to receive the Q-BB baseband signals 404b from the Q-BB client-side input 400b, adjust an amplitude of the Q-BB baseband signals404b such that the amplified Q-BB baseband signals 404b can drive the sixth frequency mixer 480f, and the amplified Q-BB signals to the sixth frequency mixer 480f.
[0198] The quadrature coupler 494 may be configured to receive the reamplified carrier signals from the fifth amplifier 484e, split the reamplified carrier signals into first carrier signals and second carrier signals, send the first carrier signals to the fifth frequency mixer 480e, and send the second carrier signals to the sixth frequency mixer 480f, wherein the first carrier signals and the second carrier signals are out of phase by 90°.
[0199] The fifth frequency mixer 480e may be configured to receive the amplified l-BB signals from the sixth amplifier 484f, receive the first carrier signals from the quadrature coupler 494, up-convert the amplified l-BB signals with the first carrier signals to produce I antenna feed signals having the I component of the client data encoded therein and havingthe predetermined frequency of the carrier signals 488, and send the I antenna feed signals to the power combiner 498.
[0200] The sixth frequency mixer 480f may be configured to receive the amplified Q-BB signals from the seventh amplifier 484g, receive the second carrier signals from the quadrature coupler 494, up-convert the amplified Q-BB signals with the second carrier signals to produce Q antenna feed signals having the Q component of the client data encoded therein and having the predetermined frequency of the carrier signals 488, and send the Q antenna feed signals to the power combiner 498.
[0201] The power combiner 498 may be configured to receive the I antenna feed signals from the fifth frequency mixer 480e, receive the Q antenna feed signals from the sixth frequency mixer 480f, combine the I antenna feed signals and the Qantenna feed signals to produce the antenna feed signals 412, and send the antenna feed signals 412 to the RF interface 464. In some embodiments, the RF interface 464 may be electrically connected to one of the first antennas 416 and configured to send the antenna feed signals 412 to the first antenna 416. In other embodiments, however, one of the first antennas 416 may be included in place of the RF interface 464.
[0202] Referring now to FIG. 5A, shown therein is a block diagram of an exemplary embodiment of the first receiver 216a (hereinafter, the "first receiver 216a") shown in FIG. 2. However, it should be understood that the description of any particular one of the receivers 216 may be applicable to any of the receivers 216 described herein. The first receiver 216a (and, therefore, each of the receiver 216) generally comprises one or more second antennas 516 configured to coherently detect the radiated signals 420 received from the first hollowwaveguide 208a and generate one or more antenna output signals 512 (hereinafter, the "antenna output signals 512") based on the radiated signals 420, receiver circuitry 508 configured to receive the antenna output signals 512 from the second antennas 516 and generate the baseband signals 404 based on the antenna output signals 512, and a client-side output 500 configured to receive the baseband signals 404 from the receiver circuitry 508 and transmit the baseband signals 404 to one or more external component (e.g., a control module 224).
[0203] In some embodiments, the antenna output signals 512 are received from the second antennas 516 on one or more transmission lines (not shown) (hereinafter, the "transmission lines"), wherein each of the transmission lines has two or more conductors (not shown) (hereinafter, the "conductors"). In some embodiments, the transmission lines have a first transmission loss and the first hollow waveguide 208a has a second transmission loss that is less than the first transmission loss. In some embodiments, the second transmission loss is in a range between 0.001 and 20.00 dB / m / Tb / s.
[0204] In some embodiments, as shown in FIG. 5A, each of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may be disposed on a substrate 524. However, in other embodiments, one or more of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may be disposed on a first substrate (not shown), and one or more of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may not be disposed on the first substrate. For example, the one or more of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may be disposed on a second substrate (not shown). In such embodiments, the first substrate and the second substrate may be in a stacked arrangement.
[0205] In some embodiments, the substrate 524 may have a plurality of layers (not shown). In such embodiments, one or more of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may be disposed on a first layer (not shown), and one or more of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may be disposed on a second layer (not shown).
[0206] In some embodiments, one or more of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may be integrated into a monolithic semiconductor die (not shown). In some embodiments, one or more of the second antennas 516, the receiver circuitry 508, and the client-side output 500 may implemented using one or more of CMOS technology, SiGe semiconductor technology, and lll-V compound semiconductor technology.
[0207] In some embodiments, the radiated signals 420 include a first complementary radiated signal (not shown) having a first polarization and a second complementary radiated signal (not shown) having a second polarization different from the first polarization. In such embodiments, the second antennas 516 may be configured to generate the antenna output signals 512 based on the radiated signals 420 including the first complementary radiated signal and the second complementary radiated signal. The first polarization and the second polarization may be orthogonal to each other.
[0208] In some embodiments, the radiated signals 420 may be formed by a first complementary radiated signal (not shown) having a first polarization and a second complementary radiated signal (not shown) having a second polarization different from the first polarization interacting in the first hollow waveguide 208a. In such embodiments, the radiated signals 420 may have a third polarization different from the first polarization and the second polarization. In such embodiments, the second antennas 516 may be configured generate the antenna output signals 512 based on the radiated signals 420 formed by the first complementary radiated signal and the second complementary radiated signal.
[0209] Referring now to FIG. 5B, in some embodiments, the client-side output 500 is configured to receive a serial baseband signal (i.e., the baseband signals 404) from the receiver circuitry 508. In such embodiments, the first receiver 216a (and, therefore, any of the receivers 216) may further comprise a second deserializer 526 configured to receive the baseband signals 404 from the client-side output 500, split the serial baseband signal into the parallel baseband signals 428, and transmit the parallel baseband signals 428 to one or more external component (e.g., a control module 224). In some such embodiments, splitting the serial baseband signal into the parallel baseband signals 428 utilizes at least one of PDM, TDM, and WDM.
[0210] Referring now to FIG. 5C, in some embodiments, the client-side output 500 is configured to receive the parallel baseband signals 428 from the receiver circuitry 508. In such embodiments, the first receiver 216a (and, therefore, any of the receivers 216) may further comprise a second serializer 532 configured to receive the parallel baseband signals 428 from the client-side output 500 and combine the parallel baseband signals 428 into the serial baseband signal (i.e., the baseband signals 404). In some such embodiments, combining the parallel baseband signals 428 into the baseband signals 404 utilizes at least one of PDM, TDM, and WDM.
[0211] Referring now to FIG. 5D, shown therein is an exemplary embodiment of the receiver circuitry 508 shown in FIGS. 5A-5C. In some embodiments, the receiver circuitry 508 comprises one or more LOs 536 (hereinafter, the "LO 536") configured to generate one or more referencesignals 540 (hereinafter, the "reference signals 540") having a baseband frequency less than the transmission frequency, one or more down-conversion circuits 552 (hereinafter, the "downconverter 552") configured to receive the antenna output signals 512 from the second antennas 516 and the reference signals 540 from the LO 536 and down-convert the antenna output signals 512 (i.e., lower a frequency of the antenna output signals 512 from the transmission frequency to the baseband frequency) using the reference signals 540 to generate one or more modulated signals 548 (hereinafter, the "modulated signals 548"), and one or more demodulation circuits 544 (hereinafter, the "demodulator 544") configured to receive the modulated signals 548 from the down-converter 552 and demodulate the modulated signals 548 to generate the baseband signals 404.
[0212] Referring now to FIG. 5E, in embodiments in which the second antennas 516 are configured to receive the radiated signals 420 formed by a first complementary radiated signal (not shown) having a first polarization and a second complementary radiated signal (not shown) having a second polarization different from the first polarization interacting in the first hollow waveguide 208a, the receiver circuitry 508 may be configured to receive the antenna output signals 512 from the second antennas 516. In such embodiments, the demodulator 544 may be configured to receive the modulated signals 548 from the down-converter 552 and demodulate the modulated signals 548 to generate the parallel baseband signals 428.
[0213] In some embodiments, the receiver circuitry 508 may further comprise a splitter 556 configured to receive the antenna output signals 512 from the second antennas 516 and split the antenna output signals 512 into a plurality of parallel antenna output signals 560 (hereinafter, the "parallel antenna output signals 560"). However, in other embodiments, the second antennas 516 may be configured to coherently detect the first complementary radiated signal and the second complementary radiated signal based on the radiated signals 420 received from the first hollow waveguide 208a and generate the antenna output signals 512 based on the first complementary radiated signal and the second complementary radiated signal.
[0214] In some embodiments, detecting the first complementary radiated signal and the second complementary radiated signal based on the radiated signals 520 received from the first hollow waveguide 208a utilizes at least one of PDM, TDM, and WDM.
[0215] Referring now to FIG. 5F, shown therein is a block diagram of another exemplary embodiment of the first receiver 216a shown in FIG. 2. In the embodiment shown in FIG. 5F, the first receiver 216a comprises an RF interface 564 configured to receive the antenna output signals 512, the receiver circuitry 508 configured to generate the baseband signals 404 based onthe antenna output signals 512, the client-side output 500 configured to transmit the baseband signals 404 to one or more external component (e.g., a control module 224), and a digital enhancement and control unit 568 configured to provide digital control and / or processing capabilities for one or more of the components of the first receiver 216a.
[0216] In the embodiment shown, the receiver circuitry 508 comprises one or more demodulator 544a (hereinafter, the "demodulator 544a"), a frequency synthesizer 572 comprising a PLL 576 and a first LO 536a, a second LO 536b, a first frequency mixer 580a, a second frequency mixer 580b, a first amplifier 584a, a second amplifier 584b, and a third amplifier 584c.
[0217] The RF interface 564 may be configured to send the antenna output signals 512 to the first amplifier 584a. In some embodiments, the RF interface 564 may be configured to receive the antenna output signals 512 from one of the second antennas 516. In other embodiments, one of the second antennas 516 may be included in place of the RF interface 564.
[0218] The first amplifier 584a may be configured to receive the antenna output signals 512 from the RF interface 564, adjust an amplitude of the antenna output signals 512 such that the amplified transmission signals can drive the first frequency mixer 580a, and send the amplified transmission signals to the first frequency mixer 580a.
[0219] The frequency synthesizer 572 (i.e., the first LO 536a and the PLL 576) may be configured to generate first carrier signals having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency (e.g., within the THz frequency band 104 or, in some embodiments, in a range between 300 GHz and 10 THz). In some embodiments, the predetermined frequency of the first carrier signals is in a range between 30 GHz and 300 GHz. In some such embodiments, the predetermined frequency of the first carrier signals is 240 GHz. In other embodiments, the predetermined frequency of the first carrier signals is in a range between 300 GHz and 3 THz. The first LO 536a may be further configured to send the first carrier signals to the second amplifier 584b.
[0220] The second amplifier 584b may be configured to receive the first carrier signals from the first LO 536a, adjust an amplitude of the first carrier signals to generate amplified carrier signals that can drive the first frequency mixer 580a, and send the amplified carrier signals to the first frequency mixer 580a.
[0221] The first frequency mixer 580a may be configured to receive the antenna output signals 512 from the first amplifier 584a, receive the amplified carrier signals from the second amplifier 584b, down-convert the antenna output signals 512 with the amplified carrier signalsto produce modulated signals having the client data encoded therein and having the IF frequency, and send the modulated signals to the third amplifier 584c.
[0222] The third amplifier 584c may be configured to receive the modulated signals from the first frequency mixer 580a, adjust an amplitude of the modulated signals such that the amplified modulated signals can drive the second frequency mixer 580b, and send the amplified modulated signals to the second frequency mixer 580b.
[0223] The second LO 536b may be configured to generate second carrier signals having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency (i.e., the IF frequency). In some embodiments, the predetermined frequency of the second carrier signals (i.e., the IF frequency) is in a range between 8 GHz and 10 GHz. The second LO 536b may be further configured to send the second carrier signals to the second frequency mixer 580b.
[0224] The second frequency mixer 580b may be configured to receive the amplified modulated signals from the third amplifier 584c, receive the second carrier signals from the second LO 536b, down-convert the amplified modulated signals with the second carrier signals to produce encoded signals having the client data encoded therein and having the predetermined frequency of the second carrier signals (i.e., IF BB frequency), and send the encoded signals to the demodulator 544a.
[0225] The demodulator 544a may be configured to receive the encoded signals from the second frequency mixer 580b and decode the encoded signals in a format suitable for transmission to one or more external component (e.g., a control module 224) to generate the baseband signals 404.
[0226] In some embodiments, the demodulator 544a may include one or more analog-to-digital converter (ADC), one or more Serializer / Deserializer (SerDes), one or more rectifying detector 800 (shown in FIG. 8), and / or circuitry operable to decode the encoded output signals from a modulation format, such as AM, ASK, PSK, QAM, or QAM16, or variations thereof, for example, to produce the baseband signals 404 with the client data encoded therein. In some embodiments, the demodulator 544a may include circuitry operable to perform forward error correction (FEC). The demodulator 544a may be further configured to send the baseband signals 404 to the client-side output 500. In some embodiments, the demodulator 544a is configured to simply receive the encoded signals from the second frequency mixer 580b and send the encoded signals as the baseband signals 404 to the client-side output 500.
[0227] In some embodiments, the client-side output 500 is a pair of output interfaces. In some such embodiments, the client-side output 500 is an LVDS link configured to transmit LVDS signals, and the baseband signals 404 are LVDS signals with the client data encoded therein.
[0228] Referring now to FIG. 5G, shown therein is a block diagram of another exemplary embodiment of the first receiver 216a shown in FIG. 2. In the embodiment shown in FIG. 5G, the first receiver 216a comprises the RF interface 564 configured to receive the antenna output signals 512, an LO input 500c configured to receive carrier signals 588 from an external LO, the receiver circuitry 508 configured to generate Q-BB baseband signals 404b and l-BB baseband signals 404a based on the antenna output signals 512 and the carrier signals 588, and a Q-BB client-side output 500a and an l-BB client-side output 500b configured to transmit the Q-BB baseband signals 404b and the l-BB baseband signals 404a, respectively.
[0229] In the embodiment shown, the receiver circuitry 508a comprises a third frequency mixer 580c, a fourth frequency mixer 580d, a fifth frequency mixer 580e, a sixth frequency mixer 580f, a fourth amplifier 584d, a fifth amplifier 584e, a sixth amplifier 584f, a seventh amplifier 584g, an eighth amplifier 584h, a ninth amplifier 584i, a tenth amplifier 584j, an eleventh amplifier 584k, a twelfth amplifier 5841, a Balun 592, a quadrature coupler (e.g., branchline coupler) 594, and a power divider (e.g., Wilkinson power divider) 598.
[0230] The fourth amplifier 584d may be configured to receive the antenna output signals 512 from the RF interface 564, adjust an amplitude of the antenna output signals 512 such that the amplified transmission signals can drive the power divider 598, and send the amplified transmission signals to the power divider 598. In some embodiments, the fourth amplifier 584d is a low-noise amplifier (LNA).
[0231] The power divider 598 may be configured to receive the amplified transmission signals from the fourth amplifier 584d, split the amplified transmission signals into I antenna output signals having the I component of the client data encoded therein and Q antenna output signals having the Q component of the client data encoded therein, send the Q antenna output signals to the third frequency mixer 580c, and send the I antenna output signals to the fourth frequency mixer 580d.
[0232] The LO input 500c may be configured to receive carrier signals 588 from an external LO, the carrier signals 588 having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency. The LO input 500c may be further configured to send the carrier signals 588 to the Balun 592.
[0233] The Balun 592 may be configured to isolate and / or maintain impedance differences between balanced transmission lines and unbalanced transmission lines. The Balun 492 may be further configured to send the carrier signals 588 to the sixth frequency mixer 580f.
[0234] The sixth frequency mixer 580f may be configured to receive the carrier signals 588 from the Balun 592, multiply the carrier signals 588 (e.g., by a multiple of four), and send the multiplied carrier signals to the twelfth amplifier 5841.
[0235] The twelfth amplifier 5841 may be configured to receive the multiplied carrier signals from the sixth frequency mixer 580f, adjust an amplitude of the multiplied carrier signals to generate amplified carrier signals that can drive the fifth frequency mixer 580e, and send the amplified carrier signals to the fifth frequency mixer 580e.
[0236] The fifth frequency mixer 580e may be configured to receive the amplified carrier signals from the twelfth amplifier 5841, multiply the amplified carrier signals (e.g., by a multiple of two), and send the remultiplied carrier signals to the eleventh amplifier 584k.
[0237] The eleventh amplifier 584k may be configured to receive the remultiplied carrier signals from the fifth frequency mixer 580e, adjust an amplitude of the remultiplied carrier signals to generate reamplified carrier signals that can drive the quadrature coupler 594, and send the reamplified carrier signals to the quadrature coupler 594.
[0238] The quadrature coupler 594 may be configured to receive the reamplified carrier signals from the eleventh amplifier 584k, split the reamplified carrier signals into first carrier signals and second carrier signals, send the first carrier signals to the third frequency mixer 580c, and send the second carrier signals to the fourth frequency mixer 580d, wherein the first carrier signals and the second carrier signals are out of phase by 90°.
[0239] The third frequency mixer 580c may be configured to receive the Q antenna output signals from the power divider 598, receive the first carrier signals from the quadrature coupler (e.g., branchline coupler) 566, down-convert the Q antenna output signals with the first carrier signals to generate Q-BB intermediate signals havingthe Q component ofthe client data encoded therein and havingthe IF frequency, and send the Q-BB intermediate signals to the fifth amplifier 584e.
[0240] The fifth amplifier 584e, the sixth amplifier 584f, and the seventh amplifier 584g may be configured to receive the Q-BB intermediate signals from the third frequency mixer 580c, down-convert the Q-BB intermediate signals to generate the Q-BB baseband signals 404b, and send the Q-BB baseband signals 404b to the Q-BB client-side output 500a. In some embodiments,the fifth amplifier 584e is a transimpedance amplifier (TIA), and the sixth amplifier 584f is a variable-gain amplifier (VGA).
[0241] The fourth frequency mixer 580d may be configured to receive the I antenna output signals from the power divider 598, receive the second carrier signals from the quadrature coupler 594, down-convert the I antenna output signals with the second carrier signals to produce l-BB intermediate signals havingthe I component ofthe client data encoded therein and having the IF frequency, and send the l-BB intermediate signals to the eighth amplifier 584h.
[0242] The eighth amplifier 584h, the ninth amplifier 584i, and the tenth amplifier 584j may be configured to receive the l-BB intermediate signals from the fourth frequency mixer 580d, down-convert the l-BB intermediate signa Is to generate the l-BB baseband signals 404a, and send the l-BB baseband signals 404a to the l-BB client-side output 500b. In some embodiments, the eighth amplifier 584h is a TIA, and the ninth amplifier 584i is VGA.
[0243] Referring now to FIG. 6A, shown therein is a block diagram of an exemplary embodiment ofthe first transceiver 220a (hereinafter, the "first transceiver 220a") shown in FIG.2. However, it should be understood that the description of any particular one ofthe transceivers 220 may be applicable to any ofthe transceivers 220 described herein. The first transceiver 220a (and, therefore, each ofthe transceivers 220) generally comprises a third transmitter 212c and a third receiver 216c.
[0244] The third transmitter 212c generally comprises a client-side input 600a configured to receive one or more first baseband signals 604a (hereinafter, the "first baseband signals 604a") having first client data encoded therein from one or more external component (e.g., a control module 224), transmitter circuitry 608a configured to receive the first baseband signals 604a from the client-side input 600a and generate one or more antenna feed signals 612a (hereinafter, the "antenna feed signals 612") based on the first baseband signals 604a, and one or more first antennas 616a (hereinafter, the "first antennas 616") configured to receive the antenna feed signals 612a from the transmitter circuitry 608a, generate one or more first radiated signals 420a (hereinafter, the "first radiated signals 420a") based on the antenna feed signals 612a, and couple the first radiated signals 420a into the fourth hollow waveguide 208d.
[0245] The third receiver 216c generally comprises one or more second antennas 616b (hereinafter, the "antennas 616b") configured to coherently detect one or more second radiated signals 620b (hereinafter, the "second radiated signals 620b") received from the third hollow waveguide 208c and generate one or more antenna output signals 612b (hereinafter, the "antenna output signals 612b") based on the second radiated signals 620b, receiver circuitry608b configured to receive the antenna output signals 612b from the second antennas 616b and generate the second baseband signals 604b based on the antenna output signals 612b, and a client-side output 600b configured to receive the second baseband signals 604b from the receiver circuitry 608b and transmit the second baseband signals 604b to one or more external component (e.g., a control module 224).
[0246] Each of the components of the first transceiver 220a (and, therefore, each of the transceivers 220) may be the same or similar to one or more of the components of the first transmitter 212a and the first receiver 216a as described herein.
[0247] Referring now to FIG. 6B, shown therein is a block diagram of another exemplary embodiment of the first transceiver 220a shown in FIG. 2. In the embodiment shown in FIG. 6B, the first transceiver 220a comprises the client-side input 600a configured to receive the first baseband signals 604a from one or more external component (e.g., a control module 224), the transmitter circuitry 608a configured to generate the antenna feed signals 612a based on the input signals 640a, a first RF interface 664a configured to transmit the antenna feed signals 612a, a second RF interface 664b configured to receive the antenna output signals 612b, the receiver circuitry 608b configured to generate the second baseband signals 604b based on the antenna output signals 612b, the client-side output 600b configured to transmit the second baseband signals 604b to one or more external component, and a digital enhancement and control unit 668 configured to provide digital control and / or processing capabilities for one or more of the components of the first transceiver 220a.
[0248] In some embodiments, the first transceiver 220a comprises the first RF interface 664a, but lacks the second RF interface 664b. In such embodiments, the first RF interface 664a may be configured to transmit antenna feed signals 612a and receive antenna output signals 612b. In some embodiments, the first transceiver 220a may have a number of RF interfaces that is greater than two.
[0249] In the embodiment shown, the transmitter circuitry 608a comprises a frequency synthesizer 672 comprising a PLL 676, a first LO 636a, and a signal distribution block (e.g., splitter) 698, one or more modulator 644a (hereinafter, the "modulator 644a"), a second LO 636b, a first frequency mixer 680a, a third frequency mixer 680c, a first amplifier 684a, a third amplifier 684c, and a fifth amplifier 684e.
[0250] In the embodiment shown, the receiver circuitry 608b comprises the frequency synthesizer 672 comprising the PLL 676, the first LO 636a, and the signal distribution 698, themodulator 644a, a third LO 636c, a second frequency mixer 680b, a fourth frequency mixer 680d, a second amplifier 684b, a fourth amplifier 684d, and a sixth amplifier 684f.
[0251] In some embodiment shown in FIG. 6B, each of the components of the first transceiver 220a are disposed on a single substrate 624, which may be a portion of a semiconductor wafer.
[0252] The modulator 644a may be configured to: (1) receive the first baseband signals 604a from the client-side input 600a, encode the first baseband signals 604a in a format suitable for modulation onto a carrier signal, and send the encoded input signals the third frequency mixer 680c; and (2) receive the encoded output signals from the fourth frequency mixer 680d, decode the encoded output signals in a format suitable for transmission to one or more external component (e.g., a control module 224), and send the second baseband signals 604b to the client-side output 600b.
[0253] In some embodiments, the modulator 644a may include one or more DAC, one or more ADC, one or more Serializer / Deserializer (SerDes), one or more folded modulator 700 (shown in FIG. 7), one or more rectifying detector 800 (shown in FIG. 8) and / or circuitry operable to encode the first baseband signals 604a in a modulation format, such as AM, ASK, PSK, QAM, or QAM16, or variations thereof, for example, and decode encoded output signals from the modulation format to produce second baseband signals 604b having the client data encoded therein. In some embodiments, the modulator 644a may include circuitry operable to perform forward error correction (FEC).
[0254] The frequency synthesizer 672 may be configured to generate first carrier signals having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency (e.g., within the THz frequency band 104 or in some embodiments, a range between 300 GHz and 10 THz). In some embodiments, the predetermined frequency of the first carrier signals is in a range between 30 GHz and 300 GHz. In some such embodiments, the predetermined frequency of the first carrier signals is 240 GHz. In other embodiments, the predetermined frequency of the first carrier signals is in a range between 300 GHz and 3 THz. The frequency synthesizer 672 may be further configured to send the first carrier signals to the signal distribution block 698.
[0255] The signal distribution block 698 may be configured to receive the first carrier signals from the first LO 636a and distribute the first carrier signals to the third amplifier 684c and the fourth amplifier 684d.
[0256] Referring nowto the transmitter circuitry 608a, in some embodiments, the client-side input 600a is a pair of input interfaces. In some such embodiments, the client-side input 600a isan LVDS link configured to receive LVDS signals, and the first baseband signals 604a are LVDS signals having the client data encoded therein. The client-side input 600a may be further configured to send the first baseband signals 604a to the modulator 644a.
[0257] The second LO 636b may be configured to generate second carrier signals having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency (i.e., the IF frequency). In some embodiments, the predetermined frequency of the second carrier signals (i.e., the IF frequency) is in a range between 200 GHz and 500 GHz. The second LO 636b may be further configured to send the second carrier signals to the third frequency mixer 680c.
[0258] The third frequency mixer 680c may be configured to receive the encoded input signals from the modulator 644a, receive the second carrier signals from the second LO 636b, up-convert the encoded input signals with the second carrier signals to produce first modulated signals having the client data encoded therein and having the predetermined frequency of the second carrier signals (i.e., the IF frequency), and send the first modulated signals to the fifth amplifier 684e.
[0259] The fifth amplifier 684e may be configured to receive the first modulated signals from the third frequency mixer 680c, adjust an amplitude of the first modulated signals such that the amplified first modulated signals can drive the first frequency mixer 680a, and send the amplified first modulated signals to the first frequency mixer 680a.
[0260] The third amplifier 684c may be configured to receive the first carrier signals from the signal distribution block 698, adjust an amplitude of the first carrier signals to generate amplified carrier signals that can drive the first frequency mixer 680a, and send the amplified carrier signals to the first frequency mixer 680a.
[0261] The first frequency mixer 680a may be configured to receive the amplified carrier signals from the third amplifier 684c, receive the amplified first modulated signals from the fifth amplifier 684e, up-convertthe amplified first modulated signals with the amplified carrier signals to produce second modulated signals having the data encoded therein and having the predetermined frequency of the amplified carrier signals (i.e., within the THz frequency band 104 or, in some embodiments, in a range between 300 GHz and 10 THz), and send the second modulated signals to the first amplifier 684a.
[0262] The first amplifier 684a may be configured to receive the second modulated signals from the first frequency mixer 680a, adjust an amplitude of the second modulated signals such that the amplified second modulated signals can be transmitted by the first RF interface 664a, and send the amplified second modulated signals to the first RF interface 664a.
[0263] The first RF interface 664a may be configured to receive the amplified second modulated signals from the first amplifier 684a and send the amplified second modulated signals as antenna feed signals 612a (i.e., having the data encoded therein) having a frequency within a predetermined frequency range (e.g., the THz frequency band 104 or, in some embodiments, in a range between 300 GHz and 10 THz). In some embodiments, the first RF interface 664a may be connected to one of the antennas 616 and configured to send the antenna feed signals 612a to the antenna 616. In other embodiments, however, one of the antennas 616 may be included in place of the first RF interface 664a.
[0264] Referring now to the receiver circuitry 608b, the second RF interface 664b may be configured to receive the antenna output signals 612b (i.e., having client data encoded therein) within a predetermined frequency range (e.g., the THz frequency band 104 or, in some embodiments, in a range between 300 GHz and 10 THz) and send the antenna output signals 612b to the second amplifier 684b. As described in further detail below, the second RF interface 664b may be configured to receive the antenna output signals 612b from one of the antennas 616. In other embodiments, however, one of the antennas 616 may be included in place of the second RF interface 664b.
[0265] The second amplifier 684b may be configured to receive the antenna output signals 612b from the second RF interface 664b, adjust an amplitude of the antenna output signals 612b to generate amplified second transmission signals that can drive the second frequency mixer 680b, and send the amplified second transmission signals to the second frequency mixer 680b.
[0266] The fourth amplifier 684d may be configured to receive the first carrier signals from the signal distribution block 698, adjust an amplitude of the first carrier signals to generate amplified carrier signals that can drive the second frequency mixer 680b, and send the amplified carrier signals to the second frequency mixer 680b.
[0267] The second frequency mixer 680b may be configured to receive the amplified second transmission signals from the second amplifier 684b, receive the amplified carrier signals from the fourth amplifier 684d, down-convert the amplified second transmission signals with the amplified carrier signals to produce third modulated signals having the data encoded therein and having the IF frequency, and send the third modulated signals to the sixth amplifier 684f.
[0268] The sixth amplifier 684f may be configured to receive the third modulated signals from the second frequency mixer 680b, adjust an amplitude of the third modulated signals such that the amplified third modulated signals can drive the fourth frequency mixer 680d, and send the amplified third modulated signals to the fourth frequency mixer 680d.
[0269] The third LO 636c may be configured to generate reference signals having a continuous waveform (e.g., a sinusoidal waveform) having a predetermined frequency (i.e., the IF frequency). In some embodiments, the predetermined frequency of the reference signals (i.e., the IF frequency) is in a range between 200 GHz and 500 GHz. The third LO 636c may be further configured to send the reference signals to the fourth frequency mixer 680d.
[0270] The fourth frequency mixer 680d may be configured to receive the amplified third modulated signals from the sixth amplifier 684f, receive the reference signals from the third LO 636c, down-convert the amplified third modulated signals with the reference signals to produce encoded output signals having the client data encoded therein and having the predetermined frequency of the reference signals (i.e., the IF frequency), and send the encoded output signals to the modulator 644a.
[0271] The client-side output 600b may be configured to transmit the second baseband signals 604b having the client data encoded therein to one or more external component (e.g., a control module 224). In some embodiments, the client-side output 600b is a pair of output interfaces. In some such embodiments, the client-side output 600b is an LVDS link configured to transmit LVDS signals, and the second baseband signals 604b are LVDS signals having the client data encoded therein.
[0272] Referring now to FIG. 7, shown therein is a schematic diagram of an exemplary embodiment of a folded modulator 700 constructed in accordance with the present disclosure. The folded modulator 700 may be configured to perform broadband direct modulation to generate the encoded signals and to minimize distortion while doing so. The folded modulator 700 may employ a cascade architecture (e.g., a cascaded circuit drive that is "stacked" or "folded") in order to produce a linear or near-linear modulated output (i.e., the encoded signals). In embodiments in which the folded modulator 700 employs a cascade architecture, the size of the stack may be directly proportional to the bandwidth.
[0273] Referring now to FIG. 8, shown therein is a schematic diagram of an exemplary embodiment of a rectifying detector 800 constructed in accordance with the present disclosure. The rectifying detector 800 may be configured to perform direct detection of incoming signals (i.e., the encoded signals). The rectifying detector 800 may be further configured to detect an envelope of the encoded signals or one or more amplitude transition of the encoded signals to generate the output signals.
[0274] Referring now to FIG. 9A, shown therein is a side view of an exemplary embodiment of an antenna 900 coupled with a fifth hollow waveguide 208e constructed in accordance withthe present disclosure. However, it should be understood that the description referring to any particular one of the antennas 416, 516, 616, 900 may refer to any of the antennas 416, 516, 616, 900 described herein. As shown in FIG. 8A, the antenna 900 generally comprises a ground plane 904, a radiator 908 mounted on the ground plane 904, and a coaxial feedline 912 electrically connected to the radiator 908. In some embodiments, the antenna 900 may lack the ground plane 904. In some embodiments, the antenna 900 further comprises a casing (not shown) enclosingthe radiator 908. The antenna 900 may be a vertical antenna (i.e., an antenna extending orthogonally from a substrate) or a horizontal antenna (i.e., an antenna extending laterally from a substrate).
[0275] The radiator 908 may be configured to transmit and detect radiated signals configured for coherent detection. In the embodiment shown, the radiator 908 is a helical radiator configured to transmit and detect radiated signals having a circular polarization. In this embodiment, the radiator 908 has a length lradiator>adiameter dradlator, and a spacingsradiator between adjacent turns of the radiator 908. The radiator 908 is preferably disposed at a distance dgapfrom the fifth hollow waveguide 208e.
[0276] The radiator 908 may be wound in a predetermined direction, such as clockwise (i.e., a left-hand wind) or counter-clockwise (i.e., a right-hand wind). While the radiator 908 of the antenna 900 is depicted in FIG. 9A as having a right-hand wind or a counter-clockwise rotational direction, it should be understood that the radiator 908 of the antenna 900 may be provided with a left-hand wind or a clockwise rotational direction.
[0277] In some embodiments, signals for transmission may be sent to the antenna 900 via the coaxial feedline 912. In other embodiments, received RF signals may be sent from the antenna 900 via the coaxial feedline 912.
[0278] In some embodiments, the length lradtator of the radiator 908 may be proportional to the wavelength of the signals being transmitted and / or received. In some embodiments, the length lradiator of the radiator 908 is in a range between 10 microns and 10 mm. In some embodiments, the diameter dradiatorof the radiator 908 may be proportional to the wavelength of the signals being transmitted and / or received. In some embodiments, the diameter dradiatorof the radiator 908 is in a range between 10 microns and 10 mm. In some embodiments, the spacing sradiatorbetween adjacent turns ofthe radiator 908 may be in a range between 1 micron and 1 mm.
[0279] The predetermined distance dgapat which the antenna 900 is spaced from the hollow waveguide 208 may vary depending upon the carrier frequency ofthe RF signal being transmittedby the antenna 900. In some embodiments, the predetermined distance dgapat which the antenna 900 is spaced from the hollow waveguide 208 is in a range between 3 pm and 3 mm. In one embodiment, the predetermined distance dgapat which the antenna 900 is spaced from the hollow waveguide 208 is 1 mm. In some embodiments, the antenna 900 may be directly connected to the fifth hollow waveguide 208e.
[0280] Referring now to FIG. 9B, shown therein is a top plan view of another exemplary embodiment of the antenna 900 coupled with the fifth hollow waveguide 208e constructed in accordance with the present disclosure. The antenna 900 is similar in construction and function as the antenna 900, with the exception that the antenna 900 includes a first radiator 908a formed of a conductive material having a plurality of coplanar windings. In one embodiment, the first radiator 908a is in the form of a spiral. The first radiator 908a may be wound in a predetermined direction, such as clockwise (i.e., a left-hand wind) or counter-clockwise (i.e., a right-hand wind). While the first radiator 908a of the antenna 900 is depicted in FIG. 9B as having a right-hand wind or a counter-clockwise rotational direction, it should be understood that the first radiator 908a of the antenna 900 may be provided with a left-hand wind or a clockwise rotational direction.
[0281] Other embodiments of the antenna 900 include embodiment as a gain horn antenna, a Cassegrain antenna, an omnidirectional antenna, a horn lens antenna, a spot focus antenna, a waveguide probe antenna, a scalar feed horn antenna, a wide-angle scalar feed horn antenna, a trihedral antenna, and a conical horn antenna.
[0282] Referring now to FIG. 10, shown therein is another exemplary embodiment of the antenna 900. As shown in FIG. 10, the antenna 900 may be implemented as a bifilar helix antenna. The bifilar helix antenna 900 generally comprises a ground plane 904a having a first differential pad 1100a and a second differential pad 1100b and a second radiator 908b mounted on the ground plane 904a. In some embodiments, the bifilar helix antenna 900 may lack the ground plane 904a. The second radiator 908b is generally in the shape of a double helix and may have a first feed point 1104a electrically connected to the first differential pad 1100a and a second feed point 1104b electrically connected to the second differential pad 1100b. A first coaxial feedline 1108a and a second coaxial feedline 1108b may be electrically connected to the first differential pad 1100a and the second differential pad 1100b, respectively.
[0283] In some embodiments, the second radiator 908b may be configured to transmit and detect differential radiated signals. That is, in the transmit direction, the second radiator 908b may receive a first complementary antenna feed signal from the first feed point 1104a and a second complementary antenna feed signal from the second feed point 1104b and transmit theradiated signals based on the first complementary antenna feed signal and the second complementary antenna feed signal. Further, in the receive direction, the second radiator 908b may receive the radiated signals and provide the first complementary antenna output signal to the first feed point 1104a and the second complementary antenna output signal to the second feed point 1104b. In such embodiments, the first complementary antenna output signal and the second complementary antenna output signal may be equal in magnitude but opposite in phase (i.e., out of phase by 180°).
[0284] The second radiator 908b may be wound in a predetermined direction, such as clockwise or counter-clockwise. While the second radiator 908b of the bifilar helix antenna 900 is depicted in FIG. 9 as having a left-hand wind or a clockwise rotational direction, it should be understood that the second radiator 908b of the bifilar helix antenna 900 may be provided with a right-hand wind or a counter-clockwise rotational direction.
[0285] The second radiator 908b may comprise a first radiator portion 1112 and a second radiator portion 1114. The first radiator portion 1112 has a first end formed by the first feed point 1104a and a second end 1116 spaced a distance from the first feed point 1104a. The first radiator portion 1112 is in the form of a spiral (i.e., a helix shape). The second radiator portion 1114 has a third end formed by the second feed point 1104b and a fourth end 1118 spaced a distance from the second feed point 1104b. The second radiator portion 1114 is in the form of a spiral (i.e., a helix shape). The second end 1116 of the first radiator portion 1112 is connected to the fourth end 1118 of the second radiator portion 1114.
[0286] Referring now to FIGS. 11 and 12, shown therein is another exemplary embodiment of the bifilar helix antenna 900 shown in FIG. 10. As shown in FIGS. 11 and 12, in some embodiments, a conductive cone 1200 may be provided surrounding the bifilar helix antenna 900 (i.e., such that the bifilar helix antenna 900 is enclosed within the conductive cone 1200). The second radiator 908b may be wound in a predetermined direction, such as clockwise or counter-clockwise. While the second radiator 908b of the bifilar helix antenna 900 enclosed within the conductive cone 1200 is depicted in FIGS. 11 and 12 as having a left-hand wind or a clockwise rotational direction, it should be understood that the second radiator 908b of the bifilar helix antenna 900 enclosed within the conductive cone 1200 may be provided with a righthand wind or a counter-clockwise rotational direction.
[0287] The conductive cone 1200 may have a first end 1204a, a second end 1204b opposite the first end 1204a, and a sidewall 1208 extending between the first end 1204a and the second end 1204b. The sidewall 1208 may define a first opening 1212a at the first end 1204a and asecond opening 1212b at the second end 1204b. As shown in FIGS. 11 and 12, the first end 1204a of the conductive cone 1200 is generally provided with a diameter d4shorter than a diameter d5of the second end 1204b of the conductive cone 1200.
[0288] The bifilar helix antenna 900 enclosed within the conductive cone 1200 may be configured to transmit circularly polarized signals with a relatively high gain (e.g., more than 6 decibels relative to isotropic (d Bi), such as 10 d Bi, 12 d Bi, 14 d Bi, 15 d Bi, 16 dBi, 18 dBi, or 20 dBi, for example). In the embodiment shown in FIGS. 11 and 12, the bifilar helix antenna 900 enclosed within the conductive cone 1200 may function as an efficient, wide-bandwidth polarizer. That is, the bifilar helix antenna 900 enclosed within the conductive cone 1200 may be configured to transmit circularly polarized RF signals with a high radiation efficiency (e.g., greater than 50%, such as 60%, 70%, 75%, 80%, 85%, 90%, or 95%, for example). Losses in radiation efficiency are generally due to losses in conductors or substrates. Further, the bifilar helix antenna 900 enclosed within the conductive cone 1200 may be configured to transmit circularly polarized signals with a wide bandwidth (e.g., greater than 10% of center frequency, such as 12%, 14%, 15%, 16%, 18%, 20%, 22%, 24%, or 25%, for example).
[0289] The diameter of the bifilar helix antenna 900 may be less than the wavelength of the signals transmitted by the bifilar helix antenna 900. In some embodiments, the conductive cone 1200 may be constructed of a conductive material, such as aluminum, copper, silver, gold, other conductive metals, combinations thereof, and / or the like.
[0290] It will be understood by persons having ordinary skill in the artthat circularly polarized signals transmitted by a radiator 908 of a first particular one of the antennas 900 may be received only by a radiator 908 of a second particular one of the antennas 900 having the same rotational direction. That is, for example, the radiator 908 shown in FIG. 8A and the first radiator 908a shown in FIG. 8B are depicted as having a right-hand wind or a counter-clockwise rotational direction. As a result, circularly polarized RF signals transmitted by the radiator 908 shown in FIG.9A or the first radiator 908a shown in FIG. 9B would have a right-hand circular polarization (RHCP). On the other hand, the second radiator 908b shown in FIGS. 10-12 is depicted as having a left-hand wind or a clockwise rotational direction. As a result, circularly polarized RF signals transmitted by the second radiator 908b shown in FIGS. 10-12 would have a left-hand circular polarization (LHCP).
[0291] Because circularly polarized signals transmitted by a radiator 908 of a first particular one of the antennas 900 may be received only by a radiator 908 of a second particular one of the antennas 900 having the same rotational direction, circularly polarized RF signals transmitted bythe radiator 908 as depicted in FIG. 9A or the first radiator 908a as depicted in FIG. 9B (i.e., RHCP RF signals) could not be received by the second radiator908b asdepicted in FIGS. 10-12. Similarly, circularly polarized signals transmitted by the second radiator 908b as depicted in FIGS. 10-12 (i.e., LHCP RF signals) could not be received by the radiator 908 as depicted in FIG. 9A or the first radiator 908a as depicted in FIG. 9B. However, circularly polarized signals transmitted by the radiator 908 as depicted in FIG. 8A (i.e., RHCP RF signals) could be received by the first radiator 908a as depicted in FIG. 9B, and circularly polarized signals transmitted by the second radiator 908b as depicted in FIG. 10 (i.e., LHCP RF signals) could be received by the second radiator 908b as depicted in FIGS. 11 and 12.
[0292] Referring now to FIG. 13, shown therein is a diagrammatic view of an electric field 1300 produced by the bifilar helix antenna 900 enclosed within the conductive cone 1200 shown in FIGS. 11 and 12. As illustrated in FIG. 13, the bifilar helix antenna 900 enclosed within the conductive cone 1200 may be operable to produce the electric field 1300 such that a near-field region of the electric field 1300 and a far-field region of the electric field 1300 are established with a greater directivity than would be provided by conventional antennas. Further, the bifilar helix antenna 900 enclosed within the conductive cone 1200 may be operable to produce the electric field 1300 in a manner that does not interfere with the circular polarization of the circularly polarized radiated signals transmitted by the second radiator 908b.
[0293] Referring now to FIG. 14, shown therein is a diagrammatic view of a radiation pattern 1400 of the bifilar helix antenna 900 enclosed within the conductive cone 1200 shown in FIGS.11 and 12. The radiation pattern 1400 may correspond to a transmission signal having a frequency of 2,000 GHz and a phase of 0°. As shown in FIG. 14, a first curve 1404 demonstrates an LHCP gain of the bifilar helix antenna 900 enclosed within the conductive cone 1200, while a second curve 1408 demonstrates a total directivity of the bifilar helix antenna 900 enclosed within the conductive cone 1200. A difference between the first curve 1404 and the second curve 1408 may indicate metal and polarization losses. As illustrated in FIG. 14 and as described above in relation to FIG. 13, the bifilar helix antenna 900 enclosed within the conductive cone 1200 may be operable to produce the electric field 1300 such that a near-field region 1304 of the electric field 1300 and a far-field region 1308 of the electric field 1300 are established with a greater directivity than would be provided by conventional antennas.
[0294] Referring now to FIGS. 15 and 16, shown therein are side views of exemplary embodiments of a non-uniform bifilar helix antenna 1500 (hereinafter, the "non-uniform antenna 1500") constructed in accordance with the present disclosure. Providing the antennawith a non-uniform design is effective because the size of the helix determines the frequency of operation. By varying characteristic dimensions of the helix, a wider band of frequencies may be effectively radiated.
[0295] Similar to the bifilar helix antenna 900 described above, the non-uniform antenna 1500 may comprise the ground plane 904a having the first differential pad 1100a and the second differential pad 1100b and a non-uniform third radiator908c mounted on the ground plane 904a. The third radiator 908c may have a plurality of turns 1504a-n including at least a first turn 1504a and a second turn 1504b. For purposes of clarity, only the first turn 1504a and the second turn 1504b are labeled with a reference character. The first turn 1504a may have a first characteristic dimension, while the second turn 1504b may have a second characteristic dimension different from the first characteristic dimension. The first turn 1504a may be adjacent to the second turn 1504b or non-adjacent to (i.e., spaced from) the second turn 1504b.
[0296] In the embodiment shown in FIG. 15, the first turn 1504a has a first pitch pltthe second turn 1504b has a second pitch p2, and the first pitch p is less than the second pitch p2. the embodiment shown in FIG. 15, the first turn 1504a has the first pitch p , the second turn 1504b has the second pitch p2, and the first pitch p is greater than the second pitch p2.
[0297] In some embodiments, the non-uniform antenna 1500 may lack the ground plane 904a. The third radiator 908c is generally in the shape of a double helix and may have the first feed point 1104a electrically connected to the first differential pad 1100a and the second feed point 1104b electrically connected to the second differential pad 1100b. The first coaxial feedline 1108a and the second coaxial feedline 1108b may be electrically connected to the first differential pad 1100a and the second differential pad 1100b, respectively.
[0298] In some embodiments, the third radiator 908c may be configured to emit and receive differential signals. That is, in the transmit direction, the third radiator 908c may receive a first complementary signal from the first feed point 1104a and a second complementary signal from the second feed point 1104b and transmit the transmission signal. Further, in the receive direction, the third radiator 908c may receive the transmission signal and provide the first complementary signal to the first feed point 1104a and the second complementary signal to the second feed point 1104b. In such embodiments, the first complementary signal and the second complementary signal may be equal in magnitude but opposite in phase (i.e., out of phase by 180°).
[0299] Thethird radiator 908c may be wound in a predetermined direction, such as clockwise or counter-clockwise. While the third radiator 908c of the non-uniform antenna 1500 is depictedin FIGS. 15 and 16 as having a right-hand wind or a counter-clockwise rotational direction, it should be understood that the third radiator 908c of the non-uniform antenna 1500 may be provided with a left-hand wind ora clockwise rotational direction.
[0300] The third radiator 908c may comprise the first radiator portion 1112 and the second radiator portion 1114. The first radiator portion 1112 has the first end formed by the first feed point 1104a and the second end 1116 spaced a distance from the first feed point 1104a. The first radiator portion 1112 is in the form of a spiral (i.e., a helix shape). The second radiator portion 1114 has the third end formed by the second feed point 1104b and the fourth end 1118 spaced a distance from the second feed point 1104b. The second radiator portion 1114 is in the form of a spiral (i.e., a helix shape). While the second end 1116 and the fourth end 1118 are shown as being disconnected from each other, it should be understood that, in some embodiments, the second end 1116 of the first radiator portion 1112 is connected to the fourth end 1118 of the second radiator portion 1114.
[0301] The non-uniform antenna 1500 provides a wider frequency response in comparison to uniform antennas existing in the prior art and the uniform bifilar helix antennas discussed herein. A mathematical equation for the helical shape of the non-uniform radiator 908c of the non-uniform antenna 1500 in three-dimensional space is shown in Table 1 below and in a graph 1700 shown in FIG. 17, while the polarization discrimination of a uniform antenna across the frequency range between 0.80 THz and 1.40 THz is shown in a graph 1800 shown in FIG. 18. As shown in FIGS. 17 and 18, the polarization discrimination may be determined by subtracting the left-hand circular polarization directivity (i.e., DirLHCP) from the right-hand circular polarization directivity (i.e., DirRHCP). As shown in Table 1 and FIG. 16, the right-hand circular polarization directivity (i.e., DirRHCP) of the non-uniform antenna 1500 may be relatively constant (i.e., 11.5 d Bi ± 1 dBi) in the frequency range between 0.80 THz and 1.40 THz. Furthermore, as shown in FIG. 17, the polarization discrimination (i.e., DirRHCP — DirLHCP) of the non-uniform antenna 1500 remains above 25 dB across the frequency range between 0.80 THz and 1.40 THz. Conversely, as shown in FIG. 18, the polarization discrimination (i.e., DirRHCP — DirLHCP) of a uniform antenna dips below 25 dB at the band edges and slightly below 25 dB in the midband range.
[0302] Table 1. Mathematical Equation for a Helical Shape of the Non-Uniform Radiator 908c of the Non-Uniform Antenna 1500 in Three-Dimensional Space
[0303] Referring now to FIGS. 18 and 20, shown therein are side views of more exemplary embodiments of the non-uniform antenna 1500 shown in FIGS. 15 and 16. For purposes of clarity, the differential pads 1100 and the feed points 1104 are not labeled with a reference character in FIGS. 18 and 19. In the embodiments shown in FIGS. 19 and 20, the first characteristic dimension and the second characteristic dimension are not pitches, but diameters. In the embodiment shown in FIG. 19, the first turn 1504a has a first diameter dltthe second turn 1504b has a second diameter d2, and the first diameter dris less than the second diameter d2. In the embodiment shown in FIG. 20, the first turn 1504a has the first diameter dltthe second turn 1504b has the second diameter d2, and the first diameter d-^ is greater than the second diameter d2.
[0304] Varying the diameters d-nof the turns 1504 of the third radiator 908c rather than the pitches p-nof the turns 1504 of the third radiator 908c may be advantageous in different bands or with different ground plane dimensions, wire dimensions, etc.
[0305] It should be understood that the third radiator 908c and / or the non-uniform antenna 1500 may be included in place of any of the respective radiators 908 and / or antennas 900 described herein. Further, it should be understood that, while the second turn 1504b is shown as being directly adjacent to the first turn 1504a, there may be one or more turns in between the first turn 1504a and the second turn 1504b. Finally, it should be understood that, while the first turn 1504a is shown as being directly adjacent to the ground plane 904a, there may be one or more turns in between the ground plane 904a and the first turn 1504a.
[0306] Referring now to FIGS. 21A, 21B, and 22A-22C, shown therein is a differential waveguide probe antenna 2100 constructed in accordance with the present disclosure. The differential waveguide probe antenna 2100 is configured to generate and transmit the transmission signal. Conversely, the differential waveguide probe antenna 2100 is further configured to receive the transmission signal. The differential waveguide probe antenna 2100 comprises a pair of waveguide probes 2104 including a first waveguide probe 2104a and a second waveguide probe 2104b.
[0307] In some embodiments, the differential waveguide probe antenna 2100 may further comprise an intermediary waveguide 2108 configured to propagate the transmission signal. In such embodiments, the differential waveguide probe antenna 2100 may be further configured to generate and transmit the transmission signal into the intermediary waveguide 2108.Conversely, in such embodiments, the differential waveguide probe antenna 2100 may be further configured to receive the transmission signal from the intermediary waveguide 2108.
[0308] The intermediary waveguide 2108 may have a first end 2112a, a second end 2112b (the first end 2112a and the second end 2112b, collectively, the "ends 2112") opposite the first end 2112a, and a surface 2116 extending between the ends 2112. In some embodiments, a back reflector 2118 may abut the first end 2112a. The surface 2116 may be constructed of a metal. The intermediary waveguide 2108 may be constructed as such in order to ensure that one or more intended waveguide modes are established. That is, were the intermediary waveguide 2108 to be constructed at a smaller size, the one or more intended waveguide modes may not be able to propagate, and were the intermediary waveguide 2108 to be constructed at a larger size, one or more unintended waveguide modes may be excited. In some embodiments, the one or more intended waveguide modes of the intermediary waveguide 2108 sufficiently matches the one or more intended waveguide modes of the hollow waveguide 208 such that a coupling loss between the intermediary waveguide 2108 and the hollow waveguide 208 is minimized (e.g., the coupling loss is in a range between 0.1 dB and 5.0 d B).
[0309] As shown in FIG. 21A, in a first direction, the intermediary waveguide 2108 may have a first cross-sectional length lagreater than zero and less than two wavelengths of the transmission signal at 10 THz (or a maximum frequency in the frequency band occupied by the transport network 200) (i.e., 60 pm). Further, as shown in FIG. 21B, in a second direction perpendicular to the first direction, the intermediary waveguide 2108 may have a second cross-sectional length lblessthan two wavelengths of the transmission signal at 10 THz (or a maximum frequency in the frequency band occupied by the transport network 200) (i.e., 60 pm) and greater than one-half wavelength at 300 GHz (or a minimum frequency in the frequency band occupied by the transport network 200) (i.e., 0.5 mm).
[0310] The waveguide probes 2104 may be positioned on opposite sides of the surface 2116 of the intermediary waveguide 2108 and may extend into the intermediary waveguide 2108 toward each other, but may be spaced a first distance dafrom each other. The waveguide probes 2104 may thus establish a strong electrical field in line with the one or more intended waveguide modes. Each of the waveguide probes 2104 may be excited with the transmission signal. In some embodiments, each of the waveguide probes 2104 may be excited with the transmission signal at an equal strength and / or an opposite phase. That is, the waveguide probes 2104 may be configured to receive the transmission signal as a differential signal having a first complementary signal and a second complementary signal and generate and transmit the transmission signal inthe electromagnetic wave form. Conversely, the waveguide probes 2104 may be further configured to receive the transmission signal and provide the transmission signal as a differential signal having a first complementary signal and a second complementary signal.
[0311] In some embodiments, the intermediary waveguide 2108 may have a flared end at the second end 2112b configured to facilitate a mode transition between the intermediary waveguide 2108 and the hollow waveguide 208. In such embodiments, as shown in FIG. 21A, in the first direction, the intermediary waveguide 2108 at the flared end may have a third cross-sectional length lcgreater than the first cross-sectional length la. Further, as shown in FIG. 21B, in the second direction perpendicular to the first direction, the intermediary waveguide 2108 at the flared end may have a fourth cross-sectional length ldgreaterthan the second cross-sectional length lb. In some such embodiments, the flared end may be formed integrally with the intermediary waveguide 2108. However, in other such embodiments, the flared end may be constructed as a horn 2120 separate from but coupled to the intermediary waveguide 2108. The horn 2120 may have a first end 2124a abutting the second end 2112b of the intermediary waveguide 2108, a second end 2124b (the first end 2124a and the second end 2124b, collectively, the "ends 2124") opposite the first end 2124a, and a curved surface 2128 extending between the ends 2124.
[0312] As shown in FIG. 21A, in the first direction, the horn 2120 at the first end 2124a may have a fifth cross-sectional length leequal to the first cross-sectional length la. Further, as shown in FIG. 21B, in the second direction perpendicular to the first direction, the horn 2120 at the first end 2124a may have a sixth cross-sectional length If equal to the second cross-sectional length lb-
[0313] The differential waveguide probe antenna 2100 may be configured to transmit the transmission signal with a wide (i.e., greater than 50%) bandwidth into the hollow waveguide 208 at least in part because an energy contribution from each of the waveguide probes 2104 effectively cancels out the higher-order, unintended waveguide modes of the other waveguide probe 2104. A polarization discrimination of the differential waveguide probe antenna 2100 across a frequency range between 0.60 THz and 1.80 THz is shown in a graph 2500 shown in FIG.22D.
[0314] Referring now to FIGS. 23, 24A, and 24B, shown therein is an exemplary embodiment of a differential tapered antenna 2600 constructed in accordance with the present disclosure. The differential tapered antenna 2600 is configured to generate and transmit the transmission signal in the electromagnetic wave form— and, conversely, receive the transmission signal in theelectromagnetic wave form. The differential tapered antenna 2600 may have a first end 2602a and a second end 2602b (the first end 2602a and the second end 2602b, collectively, the "ends 2602") opposite the first end 2602a and may comprise a pair of conductors including a first conductor 2604a and a second conductor 2604b (collectively, the "conductors 2604") spaced a second distance dbfrom the first conductor 2604a at the second end 2602b and a third distance dcat the first end 2602a.
[0315] The differential tapered antenna 2600 may be similar in some respects to a tapered slot antenna and in some respects to a ridged horn antenna. However, the differential tapered antenna 2600 differs from such antennas due to the differential tapered antenna 2600 having a differential launch and being coupled into the intermediary waveguide 2018 which is sized and dimensioned such that the intermediary waveguide 2018 may propagate multiple waveguide modes simultaneously. However, it should be understood that, in some embodiments, the differential tapered antenna 2600 may be configured to excite only a single waveguide mode at a given time.
[0316] The differential tapered antenna 2600 may be configured to generate and transmit the transmission signal into the intermediary waveguide 2108 and receive the transmission signal from the intermediary waveguide 2108. In some embodiments, the differential tapered antenna 2600 may be configured to couple the transmission signal directly into— and receive the transmission signal directly from— the hollow waveguide 208, rather than the intermediary waveguide 2108.
[0317] In the embodiment shown in FIGS. 23, 24A, and 24B, the differential tapered antenna 2600 has a first planar, yet longitudinally directed curved surface 2608a and a second planar, yet longitudinally directed curved surface 2608b (collectively, the "curved surfaces 2608") bordering a space 2612. In some embodiments, the second distance dbbetween the first conductor 2604a and the second conductor 2604b at the second end 2602b is greater than zero and less than two wavelengths of the transmission signal at 10 THz (or the maximum frequency in the frequency band occupied by the transport network 200). The second distance dbmay be selected to establish a single waveguide mode for the frequency of the transmission signal. In some embodiments, a third distance dcbetween the conductors 2604 at the first end 2602a is greater than the second distance db. This tapered shape may establish a continuously scaled geometry which enables an ultra-wide (i.e., greater than 50%) bandwidth. As energy launches down the conductors 2604, the one or more intended waveguide modes are established between the conductors 2604 and subsequently launched into the intermediary waveguide 2108.
[0318] In some embodiments, each of the conductors 2604 may be fed with the transmission signal at an equal strength and / or an opposite phase. That is, the conductors 2604 may be configured to receive the transmission signal as a differential signal having a first complementary signal and a second complementary signal and generate and transmit the transmission signal in the electromagnetic wave form. Conversely, the conductors 2604 may be further configured to receive the transmission signal and provide the transmission signal as a differential signal having a first complementary signal and a second complementary signal.
[0319] A thickness and a width of the transmission lines at the feed point may be selected to establish a characteristic impedance matched to the receiver and / or driver. Persons having ordinary skill in the art will understand how to perform such calculations. As shown in FIG. 24B, the differential tapered antenna 2600 may further comprise one or more ground connections, such as a first ground connection 2800a and a second ground connection 2800b. A polarization discrimination of the differential tapered antenna 2600 across a frequency range between 0.50 THz and 2.00 THz is shown in a graph 2900 shown in FIG. 24C.
[0320] Referring now to FIGS. 25A and 25B, shown therein is an exemplary embodiment of a microstrip patch antenna array 3000 constructed in accordance with the present disclosure. The microstrip patch antenna array 3000 is configured to generate and transmit the transmission signal in the electromagnetic wave form and, conversely, receive the transmission signal in the electromagnetic wave form.
[0321] In some embodiments, the microstrip patch antenna array 3000 comprises a pair of microstrip patch antennas 3004 including a first microstrip patch antenna 3004a and a second microstrip patch antenna 3004b (collectively, the "microstrip patch antennas 3004") spaced a third distance dcfrom the first microstrip patch antenna 3004a. However, in other embodiments, the microstrip patch antenna array 3000 may comprise more than two of the microstrip patch antennas 3004.
[0322] In some embodiments, the microstrip patch antenna array 3000 may further comprise the horn 2120 having the first end 2124a proximal to the microstrip patch antennas 3004, the second end 2124b distal to the microstrip patch antennas 3004, and the curved surface 2128 extending between the ends 2124. As shown in FIG. 25A, in a first direction, the horn 2120 at the first end 2124a may have the fifth cross-sectional length le, and the horn 2120 at the second end 2124b may have the third cross-sectional length lcgreater than the fifth cross-sectional length le. Further, as shown in FIG. 25B, in a second direction perpendicular to the first direction, the horn 2120 at the first end 2124a may have the sixth cross-sectional length Z and the horn 2120at the second end 2124b may have the fourth cross-sectional length ldgreater than the sixth cross-sectional length If.
[0323] In some embodiments, each of the microstrip patch antennas 3004 may be fed with the transmission signal at an equal strength and / or an opposite phase. However, in other embodiments, each of the microstrip patch antennas 3004 may be fed with the transmission signal at an equal strength and / or an equal phase. That is, the microstrip patch antennas 3004 may be configured to receive the transmission signal as a differential signal having a first complementary signal and a second complementary signal and generate and transmit the transmission signal in the electromagnetic wave form. Conversely, the microstrip patch antennas 3004 may be further configured to receive the transmission signal and provide the transmission signal as a differential signal having a first complementary signal and a second complementary signal.
[0324] The differential waveguide probe antenna 2100, the differential tapered antenna 2600, and the microstrip patch antenna array 3000 are configured to generate the transmission signal in a linearly polarized form.
[0325] Referring now to FIGS. 26A, 26B, and 27A-27C, shown therein is a diagrammatic view of an exemplary embodiment of a single-ended waveguide probe antenna 3008 constructed in accordance with the present disclosure. In some embodiments, the single-ended waveguide probe antenna 3008 may lack the second waveguide probe 2104b, thereby only comprising the first waveguide probe 2104a. Further, in some embodiments, the surface 2116 of the intermediary waveguide 2108 may define an opening 3012 through which the first waveguide probe 2104a extends. As referenced above, in some embodiments, the first end 2112a of the intermediary waveguide 2108 may serve as a back reflector.
[0326] Referring now to FIGS. 28A, 28B, 29A-29C, and 30A-30C, shown therein are diagrammatic views of exemplary embodiments of a slot antenna 3014 constructed in accordance with the present disclosure. As shown in FIGS. 28A, 28B, 29A-29C, and 30A-30C, the slot antenna 3014 may include the ground plane 904 disposed between the intermediary waveguide 2108 and the back reflectors 2118. In some embodiments, the ground plane 904 may define one or more slots 3016 (e.g., a first slot 3016a shown in FIGS. 29A-C, 30A, and 30C and a second slot 3016b shown in FIGS. 30A-30C) (hereinafter, the "slots 3016").
[0327] Any of the antennas disclosed herein can be used in combination with network elements described above that communicate using radio frequency communications transmitted and received by antennas. The radio frequency (RF) communications have a carrier frequency inwhat is referred to as a Terahertz (THz) frequency band 104 (i.e., frequencies between 0.1 THz and 10 THz and wavelengths between 3 millimeters (mm) and 30 micrometers (pm)). Where certain aspects of the present disclosure are described as relating to "THz", it should be understood that such aspects of the present disclosure relate to the THz frequency band 104.
[0328] Referring now to FIG. 31A, shown therein is a transport network 4000 constructed in accordance with the prior art. The transport network 4000 includes a plurality of network elements 4002a-n (hereinafter, the "network elements 4002") including a first network element 4002a which comprises a transmitter 4004 and a second network element 4002b which comprises a receiver 4006. Each of the network elements 4002 of the transport network 4000 are electrically coupled to one another by one or more transmission lines 4008a-n (hereinafter, the "transmission lines 4008").
[0329] The transmitter 4004 of the first network element 4002a comprises a client-side input 4010 which receives a plurality of outbound parallel baseband signals (hereinafter, the "outbound parallel baseband signals") having client data encoded therein from a remote source, one or more serializers 4012a-n (hereinafter, the "serializers 4012") which receive the outbound parallel baseband signals from the client-side input 4010 and multiplex the outbound parallel baseband signals to generate one or more outbound serial baseband signals (hereinafter, the "outbound serial baseband signals"), one or more modulators 4014a-n (hereinafter, the "modulators 4014") which receive the outbound serial baseband signals from the serializers 4012 and modulate the outbound serial baseband signals to generate one or more feed signals (hereinafter, the "feed signals") having the client data encoded therein, and one or more systemside outputs 4016a-n (hereinafter, the "system-side outputs 4016") which receive the feed signals from the modulators 4014, generate one or more electrical transmission signals (hereinafter, the "transmission signals") based on the feed signals, and couple the transmission signals into the transmission lines 4008.
[0330] The receiver 4006 of the second network element 4002b comprises one or more system-side inputs 4018a-n (hereinafter, the "system-side inputs 4018") which detect the transmission signals coupled into the transmission lines 4008 and generate one or more output signals (hereinafter, the "output signals") based on the transmission signals, one or more demodulators 4020a-n (hereinafter, the "demodulators 4020") which receive the output signals from the system-side inputs 4018 and demodulate the output signals to generate one or more inbound serial baseband signals (hereinafter, the "inbound serial baseband signals"), one or more deserializers 4022a-n (hereinafter, the "deserializers 4022") which receive the inbound serialbaseband signals from the demodulators 4020 and de-multiplex the inbound serial baseband signals to generate a plurality of inbound parallel baseband signals (hereinafter, the "inbound parallel baseband signals"), and a client-side output 4024 which receives the inbound parallel baseband signals from the demodulators 4020 and transmits the inbound parallel baseband signals to a remote destination.
[0331] Referring now to FIG. 31B, shown therein is an eye diagram 4026 representing a symbol period 4028 (i.e., a time duration of a symbol) of the feed signals— and, therefore, the transmission signals and the output signals— in which the client data is encoded using PAM4. As shown in FIG. 31B, the feed signals transition between four distinct amplitudes 4030a-d in order to encode the client data. Because the modulators 4014 encode the client data in the feed signals using PAM4, only two bits of the client data may be encoded in the symbol period 4044.
[0332] Referring back to the present disclosure, and in particular to FIG. 32A, shown therein is an exemplary embodiment of a transport network 4100 constructed in accordance with the present disclosure. The transport network 4100 generally comprises a plurality of network elements 4102a-n (hereinafter, the "network elements 4102"), such as a first network element 4102a comprising a transmitter 4104 and a second networkelement 4102b comprising a receiver 4106 shown in FIG. 32A. While the first network element 4102a and the second network element 4102b are shown in FIG. 11 as comprising a transmitter 4104 and a receiver 4106, respectively, it should be understood that each of the network elements 4102 may comprise one of the transmitter 4104 and the receiver 4106. Further, it should be understood that each of the network elements 4102 may comprise both of the transmitter 4104 and the receiver 4106 (i.e., a transceiver). Each of the network elements 4102 of the transport network 4100 may be coupled to one another by one or more hollow waveguides 4108a-n (hereinafter, the "hollow waveguides 4108") to communicate radiated signals therebetween through a dielectric material (e.g., air) within the hollow waveguides 4108.
[0333] The transmitter 4104 of the first network element 4102a is generally operable to transmit one or more radiated signals (hereinafter, the "radiated signals") to the receiver 4106 of the second network element 4102b via the hollow waveguides 4108, and the receiver 4106 of the second network element 4102b is generally operable to receive the radiated signals from the transmitter 4104 of the first network element 4102a via the hollow waveguides 4108.
[0334] The transmitter 4104 of the first network element 4102a may comprise a client-side input 4110 operable to receive the outbound parallel baseband signals having client data encoded therein from a remote source, one or more serializers 4112a-n (hereinafter, the"serializers 4112") operable to receive the outbound parallel baseband signals from the clientside input 4110 and multiplex the outbound parallel baseband signals to generate the outbound serial baseband signals, one or more modulators 4114a-n (hereinafter, the "modulators 4114") operable to receive the outbound serial baseband signals from the serializers 4114 and modulate the outbound serial baseband signals to generate one or more antenna feed signals (hereinafter, the "antenna feed signals") having the client data encoded therein, and one or more transmitter antennas 4116a-n (hereinafter, the "transmitter antennas 4116") operable to receive the antenna feed signals from the modulators 4114 and generate one or more radiated signals (hereinafter, the "radiated signals") based on the antenna feed signals. In some embodiments, the transmitter antennas 4116 may be further operable to couple the radiated signals into the hollow waveguides 4108.
[0335] In some embodiments, each of the client-side input 4110, the serializers 4112, the modulators 4114, the transmitter antennas 4116, and the first DSP 4125a (described below) may be disposed on a single substrate. However, in other embodiments, at least a first one of the client-side input 4110, the serializers 4112, the modulators 4114, the transmitter antennas 4116, and the first DSP 4125a may be disposed on a first substrate, and at least a second one of the client-side input 4110, the serializers 4112, the modulators 4114, the transmitter antennas 4116, and the first DSP 4125a may be disposed on a second substrate different from the first substrate.
[0336] The receiver 4106 of the second network element 4102b may comprise one or more receiver antennas 4118a-n (hereinafter, the "receiver antennas 4118") operable to detect the radiated signals and generate one or more antenna output signals (hereinafter, the "antenna output signals") based on the radiated signals, one or more demodulators 4120a-n (hereinafter, the "demodulators 4120") operable to receive the antenna output signals from the receiver antennas 4118 and demodulate the antenna output signals to generate the inbound serial baseband signals, one or more deserializers 4122a-n (hereinafter, the "deserializers 4122") operable to receive the inbound serial baseband signals from the demodulators 4120 and demultiplex the inbound serial baseband signals to generate a plurality of inbound parallel baseband signals (hereinafter, the "inbound parallel baseband signals"), and a client-side output 4124 operable to receive the inbound parallel baseband signals from the deserializers 4122 and transmit the inbound parallel baseband signals to a remote destination. In some embodiments, the receiver antennas 4118 may be further operable to receive the radiated signals from the hollow waveguides 4108.
[0337] In some embodiments, each of the receiver antennas 4118, the demodulators 4120, the deserializers 4122, the client-side output 4124, and the second DSP 4125b (described below) may be disposed on a single substrate. However, in other embodiments, at least a first one of the receiver antennas 4118, the demodulators 4120, the deserializers 4122, the client-side output 4124, and the second DSP 4125b may be disposed on a first substrate, and at least a second one of the receiver antennas 4118, the demodulators 4120, the deserializers 4122, the client-side output 4124, and the second DSP 4125b may be disposed on a second substrate different from the first substrate.
[0338] In some embodiments, the transmitter 4104 of the first network element 4102a may be operable to transmit the radiated signa Is to the receiver 4106 of the second network element 4102b via a first hollow waveguide 4108a of the hollow waveguides 4108, for example, and the receiver 4106 of the second network element 4102b may be operable to receive the radiated signals from the transmitter 4104 of the first network element 4102a via the first hollow waveguide 4108a. However, it should be understood that the transmitter 4104 of the first network element 4102a may be operable to transmit the radiated signals to the receiver 4106 of the second network element 4102b via any particular one of the hollow waveguides 4108 (e.g., a second hollow waveguide 4108b of the hollow waveguides 4108), and the receiver 4106 of the second network element 4102b may be operable to receive the radiated signals from the particular one of the hollow waveguides 4108 (e.g., the second hollow waveguide 4108b).
[0339] In some embodiments, the radiated signals are one or more differential pairs of complementary radiated signals (hereinafter, the "differential radiated signal pairs"), wherein each of the differential radiated signal pairs include a first complementary radiated signal and a second complementary radiated signal. In such embodiments, the transmitter 4104 of the first network element 4102a may be operable to transmit the differential radiated signal pairs to the receiver 4106 of the second network element 4102b via any particular two of the hollow waveguides 4108 (e.g., the first hollow waveguide 4108a and the second hollow waveguide 4108b), and the receiver 4106 of the second network element 4102b may be operable to receive the differential radiated signal pairs from the first network element 4102a via the particular two of the hollow waveguides 4108 (e.g., the first hollow waveguide 4108a and the second hollow waveguide 4108b).
[0340] In some embodiments, the serializers 4112 may be operable to receive the outbound parallel baseband signals from the client-side input 4110 and multiplex the outbound parallel baseband signals to generate one or more pairs of outbound serial baseband signals (hereinafter,the "outbound serial baseband signal pairs"), each of the outbound serial baseband signal pairs having a first outbound serial baseband signal and a second outbound serial baseband signal.
[0341] In some embodiments, the modulators 4114 may be operable to receive the outbound serial baseband signals from the serializers 4112 and up-convert the outbound serial baseband signals to generate the antenna feed signals. In embodiments wherein the serializers 4112 are operable to generate the outbound serial baseband signal pairs, the modulators 4114 may be operable to receive the outbound baseband signal pairs from the serializers 4112, up-convert the first outbound serial baseband signal and the second outbound serial baseband signal of each of the outbound serial baseband signal pairs to generate one or more pairs of outbound intermediate signals (hereinafter, the "outbound intermediate signal pairs"), each of the outbound intermediate signal pairs including a first outbound intermediate signal based on the first outbound serial baseband signal and a second outbound intermediate signal based on the second outbound serial baseband signal, and combine the first outbound intermediate signal and the second outbound intermediate signal of each of the outbound intermediate signal pairs into the antenna feed signals. In some such embodiments, each of the antenna feed signals may have an I component based on the first outbound intermediate signal of a particular outbound intermediate signal pair and a Q component based on the second outbound intermediate signal of the particular outbound intermediate signal pair.
[0342] In some embodiments, the modulators 4114 may be operable to generate the antenna feed signals having the client data encoded therein using an encoding scheme conforming to a specification of QAM or QPSK, for example. In some embodiments, the radiated signals are radiated electromagnetic waves having a frequency in a range between 300 GHz and 10 THz. In some embodiments, the radiated signals are configured for coherent detection. However, it should be understood that, in other embodiments, the radiated signals may be configured for direct detection.
[0343] In some embodiments, the demodulators 4120 may be operable to receive the antenna output signals from the receiver antennas 4118 and down-convert the antenna output signals to generate one or more inbound intermediate signals (hereinafter, the "inbound intermediate signals"). In other embodiments, the demodulators 4120 may be operable to receive the antenna output signals from the receiver antennas 4118, split the antenna output signals into one or more pairs of inbound intermediate signals (hereinafter, the "inbound intermediate signal pairs"), each of the inbound intermediate signal pairs including a first inbound intermediate signal based on a particular antenna output signal and a second inboundintermediate signal based on the particular antenna output signal, and down-convert the first inbound intermediate signal and the second inbound intermediate signal of each ofthe inbound intermediate signal pairs to generate one or more pairs of inbound serial baseband signals (hereinafter, the "inbound serial baseband signal pairs"), each of the inbound serial baseband signal pairs including a first inbound serial baseband signal based on the first inbound intermediate signal of a particular inbound intermediate signal pair and a second inbound serial baseband signal based on the second inbound intermediate signal of the particular inbound intermediate signal pair. In some embodiments, the first inbound intermediate signal of each of the inbound intermediate signal pairs may be based on an I component of a particular antenna output signal, and the second inbound intermediate signal of each of the inbound intermediate signal pairs may be based on a Q component ofthe particular antenna output signal.
[0344] In some embodiments, the deserializers 4122 may be operable to receive the inbound serial baseband signals from the demodulators 4120 and de-multiplex the inbound serial baseband signals to generate the inbound parallel baseband signals. In embodiments wherein the demodulators 4120 are operable to generate the inbound serial baseband signal pairs, the deserializers 4122 may be operable to receive the inbound serial baseband signal pairs from the demodulators 4120 and de-multiplex the first inbound serial baseband signal and the second inbound serial baseband signal of each of the inbound serial baseband signal pairs to generate the inbound parallel baseband signals.
[0345] In some embodiments, one or more of the network elements 4102 may further comprise a digital signal processor (DSP) 4125. That is, the transmitter 4104 ofthe first network element 4102a may further comprise a first DSP 4125a and the receiver 4106 of the second network element 4102b may further comprise a second DSP 4125b (the first DSP 4125a and the second DSP 4125b, collectively, the "DSPs 4125"). In such embodiments, the network elements 4102 may be operable to extract and / or recover certain signal parameters (e.g., clock, carrier, equalization, phase, amplitude, data, etc.) in the digital domain. However, in other embodiments, one or more ofthe network elements 4102 may lack the DSPs 4125. In such embodiments, the network elements 4102 may be operable to extract and / or recover certain signal parameters (e.g., clock, carrier, equalization, phase, amplitude, data, etc.) in the analog domain.
[0346] Referring now to FIG. 32B, shown therein is an exemplary embodiment of the first modulator 4114a shown in FIG. 32A. However, it should be understood that the description below may be applicable to any ofthe modulators 4114 described herein.
[0347] A first serializer 4112a of the serializers 4112 may be operable to receive a first plurality of outbound parallel baseband signals (hereinafter, the "first outbound parallel baseband signals") from the client-side input 4110 and multiplex the first outbound parallel baseband signals to generate a first outbound serial baseband signal pair of the outbound serial baseband signal pairs, the first outbound serial baseband signal pair having a first outbound serial baseband signal and a second outbound serial baseband signal.
[0348] The first modulator 4114a may comprise a first electronic oscillator 4126a operable to generate a first carrier signal and a second carrier signal— which may be 90° out of phase with the first carrier signal— having a frequency in the range between 300 GHz and 10 THz, a first up-converter 4128a operable to receive the first outbound serial baseband signal from the first serializer 4112a and the first carrier signal from the first electronic oscillator 4140a and mix the first outbound serial baseband signal with the first carrier signal to generate the first outbound intermediate signal, a second up-converter 4128b operable to receive the second outbound serial baseband signal from the first serializer 4112a and the second carrier signal from the first electronic oscillator 4126a and mix the second outbound serial baseband signal with the second carrier signal to generate the second outbound intermediate signal, a combiner 4130 operable to receive the first outbound intermediate signal from the first up-converter 4128a and the second outbound serial baseband signal from the second up-converter 4128b and combine the first outbound intermediate signal and the second outbound intermediate signal to generate a first antenna feed signal of the antenna feed signals. In some embodiments, the first antenna feed signal may have an I component based on the first outbound intermediate signal and a Q component based on the second outbound intermediate signal.
[0349] In some embodiments, the first up-converter 4128a and the second up-converter 4128b may be operable to receive the first outbound serial baseband signal and the second outbound serial baseband signal, respectively, from the first serializer 4112a as binary signals (i.e., a first binary signal and a second binary signal). That is, in such embodiments, the transmitter 4104 may not convert the first outbound serial baseband signal and the second outbound serial baseband signal into multi-level signals, and the first up-converter4128a and the second up-converter 4128b may be directly driven by the binary signals.
[0350] A first transmitter antenna 4116a of the transmitter antennas 4116 may be operable to receive the first antenna feed signal from the first modulator 4114a and generate a first radiated signal of the radiated signals based on the first antenna feed signal. In someembodiments, first transmitter antenna 4116a of the transmitter antennas 4116 may be further operable to couple the first radiated signal into the first hollow waveguide 4108a.
[0351] In some embodiments, the first modulator 4114a may further comprise a limiting driver 4132 operable to receive the first antenna feed signal from the combiner 4130 and limit the first antenna feed signal to generate a first limited antenna feed signals of one or more limited antenna feed signals (hereinafter, the "limited antenna feed signals"). In such embodiments, the first transmitter antenna 4116a may be operable to receive the first limited antenna feed signal from the first modulator 4114a, generate a first radiated signal of the radiated signals based on the first limited antenna feed signal, and couple the first radiated signal into the first hollow waveguide 4108a.
[0352] In some such embodiments, the first modulator 4114a may further comprise a power amplifier 4134 operable to receive the first limited antenna feed signal from the limiting driver 4132 and amplify the first limited antenna feed signal to generate a first conditioned antenna feed signal of one or more conditioned antenna feed signals (hereinafter, the "conditioned antenna feed signals"). In such embodiments, the first transmitter antenna 4116a may be operable to receive the first conditioned antenna feed signal from the first modulator 4114a, generate a first radiated signal of the radiated signals based on the first conditioned antenna feed signal, and couple the first radiated signal into the first hollow waveguide 4108a.
[0353] In other embodiments, the first modulator 4114a may further comprise a first limiting amplifier (not shown) in place of the limiting driver 4132 and the power amplifier 4134, the first limiting amplifier (not shown) being operable to receive the first antenna feed signal from the combiner 4130, amplify the first antenna feed signal to generate a first amplified antenna feed signal of one or more amplified antenna feed signals (hereinafter, the "amplified antenna feed signals"), and limit the first amplified antenna feed signal to generate the first conditioned antenna feed signal. In such embodiments, the first transmitter antenna 4116a may be operable to receive the first conditioned antenna feed signal from the first modulator 4114a, generate the first radiated signal based on the first conditioned antenna feed signal, and couple the first radiated signal into the first hollow waveguide 4108a.
[0354] Referring now to FIG. 32C, shown therein is an exemplary embodiment of the first demodulator 4120a shown in FIG. 32A. However, it should be understood that the description below may be applicable to any of the demodulators 4120 described herein.
[0355] A first receiver antenna 4118a of the receiver antennas 4118 may be operable to detect the first radiated signal and generate a first antenna output signal of the antenna outputsignals based on the first radiated signal. In some embodiments, the first receiver antenna 4118a of the receiver antennas 4118 may be further operable to receive the first radiated signal from the first hollow waveguide 4108a.
[0356] The first demodulator 4120a may comprise a second electronic oscillator 4126b operable to generate a reference signal having a frequency in the range between 300 GHz and 10 THz, a splitter 4136 operable to receive the first antenna output signal from the first receiver antenna 4118a and split the first antenna output signal into a first inbound intermediate signal pair of the inbound intermediate signal pairs having a first inbound intermediate signal based on the first antenna output signal (e.g., an I component of the first antenna output signal in some embodiments) and a second inbound intermediate signal based on the first antenna output signal (e.g., a Q component of the first antenna output signal in some embodiments), a first downconverter 4138a operable to receive the first inbound intermediate signal from the splitter 4136 and the reference signal from the second electronic oscillator 4126b and mix the first inbound intermediate signal with the reference signal to generate the first inbound serial baseband signal of a first inbound serial baseband signal pair of the inbound serial baseband signal pairs, and a second down-converter 4138b operable to receive the second inbound intermediate signal from the splitter 4136 and the reference signal from the second electronic oscillator 4126b and mix the second inbound intermediate signal with the reference signal to generate the second inbound serial baseband signal of the first inbound serial baseband signal pair.
[0357] In some embodiments, the first demodulator 4120a may further comprise a carrier and clock recovery circuit 4144 operable to receive the first inbound serial baseband signal pair and extract timing and carrier information from the first inbound serial baseband signal and the second inbound serial baseband signal. That is, the carrier and clock recovery circuit 4144 may be operable to extract a recovered carrier signal (in the analog domain) and / or a recovered clock signal (in the digital domain) from the first inbound serial baseband signal and the second inbound serial baseband signal. The recovered carrier signal and / or the recovered clock signal may have the same phase and / or amplitude as the first inbound serial baseband signal and the second inbound serial baseband signal and may be used by the first demodulator 4120a to control (i.e., synchronize) sampling and processing of the inbound signals (i.e., the first radiated signal, the first antenna output signal, the first inbound intermediate signal pair, and the first inbound serial baseband signal pair).
[0358] In some embodiments, the first down-converter 4138a and the second downconverter 4138b may be operable to receive the first inbound intermediate signal and the secondinbound intermediate signal, respectively, from the splitter 4136 as binary signals (i.e., a third binary signal and a fourth binary signal). That is, in such embodiments, the transmitter 4104 may not convert the first inbound intermediate signal and the second inbound intermediate signal into multi-level signals, and the first down-converter 4138a and the second down-converter 4138b may be directly driven by the binary signals.
[0359] The first deserializer 4122a may be operable to receive the first inbound serial baseband signal and the second inbound serial baseband signal of the first inbound serial baseband signal pair and de-multiplex the first inbound serial baseband signal and the second inbound serial baseband signal to generate a first plurality of inbound parallel baseband signals (hereinafter, the "first inbound parallel baseband signals") of the inbound parallel baseband signals.
[0360] In some embodiments, the first demodulator 4120a may further comprise a low-noise amplifier (LNA) 4133 operable to receive the first antenna output signal from the first antenna 4118a and amplify the first antenna output signal— which may be a dispersed signal— to generate a first amplified antenna output signal of one or more amplified antenna output signals (hereinafter, the "amplified antenna output signals"). In such embodiments, the splitter 4136 may be operable to receive the first amplified antenna output signal from the LNA 4133 and split the first amplified antenna output signal into the first inbound intermediate signal pair having the first inbound intermediate signal based on the first amplified antenna output signal and the second inbound intermediate signal based on the first amplified antenna output signal.
[0361] Referring nowto FIG.32D, shown therein is a constellation diagram 4040 representing a plurality of symbol states 4042a-d (hereinafter, the "symbol states 4042") of the antenna feed signals— and, therefore, the radiated signals and the antenna output signals— in which the client data is encoded using an encoding scheme conforming to a specification of 4QAM. However, it should be understood that the client data may be encoded in the antenna feed signals using an encoding scheme conforming to a specification of any form of QAM (e.g., 16QAM or 64QAM, for example) or QPSK.
[0362] As shown in FIG. 32D, the antenna feed signals may transition between a first symbol state 4042a in which the I component of the antenna feed signals is negative and the Q component of the antenna feed signals is positive (i.e., ( / , Q) = (—1,1)), a second symbol state 4042b in which the I component of the antenna feed signals is positive and the Q component of the antenna feed signals is positive, a third symbol state 4042c in which the I component of the antenna feed signals is negative and the Q component of the antenna feed signals is negative,and a fourth symbol state 4042d in which the I component of the antenna feed signals is positive and the Q component of the antenna feed signals is negative. In some embodiments, the client data may be differentially encoded in the phase information of the antenna feed signals— and, therefore, the radiated signals and the antenna output signals. That is, the client data may be encoded based on relative phase changes between consecutive symbols, rather than absolute phase values.
[0363] Referring now to FIG. 33, shown therein is another exemplary embodiment of the transport network 4100 shown in FIG. 32A. In the embodiment shown in FIG. 33, the transport network 4100 comprises a third network element 4102c comprising a first transmitter 4104-1 and a first receiver 4106-1 and a fourth network element 4102d comprising a second transmitter 4104-2 and a second receiver 4106-2 shown in FIG. 33. The third network element 4102c and the fourth network element 4102d may be electrically coupled to one another by one or more first hollow waveguides 4108a-l - 4108n-l (hereinafter, the "first hollow waveguides 4108-1") and one or more second hollow waveguides 4108a-2 - 4108n-2 (hereinafter, the "second hollow waveguides 4108-2").
[0364] The first transmitter 4104-1 of the third network element 4102c and the second transmitter 4104-2 of the fourth network element 4102d may be similar in form and function to the transmitter 4104 of the first network element 4102a described above, while the first receiver 4106-1 of the third network element 4102c and the second receiver 4106-2 of the fourth network element 4102d may be similar in form and function to the receiver 4106 of the second network element 4102b described above. Similarly, the first hollow waveguides 4108-1 and the second hollow waveguides 4108-2 may be similar in form and function to the hollow waveguides 4108 described above.ILLUSTRATIVE CLAUSES
[0365] Exemplary, non-limiting illustrative clauses are provided in the clauses below. However, the scope of the present inventive concept(s) is to be understood to not be limited in any manner by the clauses presented below.
[0366] Illustrative clause 1. A network element, comprising: one or more serializers operable to receive a plurality of parallel baseband signals and multiplex the plurality of parallel baseband signals to generate one or more pairs of serial baseband signals, each of the plurality of parallel baseband signals having client data encoded therein, each of the one or more pairs of serial baseband signals including a first serial baseband signal and a second serial baseband signal; one or more modulators operable to: receive the one or more pairs of serial baseband signals fromthe one or more serializers; up-convert the first serial baseband signal and the second serial baseband signal of each of the one or more pairs of serial baseband signals to generate one or more pairs of intermediate signals, each of the one or more pairs of intermediate signals including a first intermediate signal based on the first serial baseband signal and a second intermediate signal based on the second serial baseband signal; and combine the first intermediate signal and the second intermediate signal of each of the one or more pairs of intermediate signals into one or more antenna feed signals; and one or more antennas operable to receive the one or more antenna feed signals from the one or more modulators and generate one or more radiated signals based on the one or more antenna feed signals, each of the one or more radiated signals being radiated electromagnetic waves and having a frequency in a range between 300 Gigahertz (GHz) and 10 Terahertz (THz).
[0367] Illustrative clause 2. The network element of illustrative clause 1, wherein each of the one or more antenna feed signals has an in-phase (I) component and a quadrature (Q) component, and wherein the one or more modulators are operable to combine the first intermediate signal and the second intermediate signal of each of the one or more pairs of intermediate signals into the one or more antenna feed signals such that the I component of each of the one or more antenna feed signals is based on the first intermediate signal of a particular pair of the one or more pairs of intermediate signals and the Qcomponent of each of the one or more antenna feed signals is based on the second intermediate signal of the particular pair.
[0368] Illustrative clause 3. The network element of illustrative clause 2, wherein each of the one or more modulators is operable to receive a particular pair of serial baseband signals of the one or more pairs of serial baseband signals from a particular serializer of the one or more serializers and generate a particular antenna feed signal of the one or more antenna feed signals, the particular pair of serial baseband signals having a particular first serial baseband signal and a particular second serial baseband signal, the particular antenna feed signal having a particular I component and a particular Q component, each of the one or more modulators comprising: an electronic oscillator operable to generate a carrier signal having a frequency in the range between 300 GHz and 10 THz; a first up-converter operable to receive the particular first serial baseband signal from the particular serializer and the carrier signal from the electronic oscillator and mix the particular first serial baseband signal with the carrier signal to generate the first intermediate signal; a second up-converter operable to receive the particular second serial baseband signal from the particular serializer and the carrier signal from the electronic oscillator and mix the particular second serial baseband signal with the carrier signal to generate thesecond intermediate signal; and a combiner operable to receive the first intermediate signal from the first up-converter and the second intermediate signal from the second up-converter and combine the first intermediate signal and the second intermediate signal to generate the particular antenna feed signal having the particular I component based on the first intermediate signal and the particular Q component based on the second intermediate signal; wherein each particular antenna of the one or more antennas is operable to receive the particular antenna feed signal from a particular modulator of the one or more modulators and generate a particular radiated signal of the one or more radiated signals based on the particular antenna feed signal.
[0369] Illustrative clause 4. The network element of illustrative clause 3, wherein the one or more modulators are further operable to limit the one or more antenna feed signals to generate one or more limited antenna feed signals, the one or more antennas being further operable to receive the one or more limited antenna feed signals from the one or more modulators and generate the one or more radiated signals based on the one or more limited antenna feed signals, each particular modulator of the one or more modulators further comprising a limiting driver operable to receive the particular antenna feed signal from the combiner and limit the particular antenna feed signal to generate a particular limited antenna feed signal of the one or more limited antenna feed signals, each particular antenna of the one or more antennas being further operable to receive the particular limited antenna feed signal from the particular modulator and generate the particular radiated signal based on the particular limited antenna feed signal.
[0370] Illustrative clause 5. The network element of illustrative clause 4, wherein the one or more modulators are further operable to amplify the one or more limited antenna feed signals to generate one or more conditioned antenna feed signals, the one or more antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising a power amplifier operable to receive the particular limited antenna feed signal from the limiting driver and amplify the particular limited antenna feed signal to generate a particular conditioned antenna feed signal of the one or more conditioned antenna feed signals, each particular antenna of the one or more antennas being further operable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular radiated signal based on the particular conditioned antenna feed signal.
[0371] Illustrative clause 6. The network element of illustrative clause 3, wherein the one or more modulators are further operable to amplify the one or more antenna feed signals togenerate one or more amplified antenna feed signals and limit the one or more amplified antenna feed signals to generate one or more conditioned antenna feed signals, the one or more antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising a limiting amplifier operable to receive the particular antenna feed signal from the combiner, amplify the particular antenna feed signal to generate a particular amplified antenna feed signal of the one or more amplified antenna feed signals, and limit the particular amplified antenna feed signal to generate a particular conditioned antenna feed signal of the one or more conditioned antenna feed signals, each particular antenna of the one or more antennas being further operable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular radiated signal based on the particular conditioned antenna feed signal.
[0372] Illustrative clause 7. The network element of illustrative clause 3, wherein the first up-converter of each of the one or more modulators is operable to receive the particular first serial baseband signal as a first binary signal and the second up-converter of each of the one or more modulators is operable to receive the particular second serial baseband signal as a second binary signal.
[0373] Illustrative clause 8. The network element of illustrative clause 1, wherein the one or more serializers are operable to receive the plurality of parallel baseband signals having the client data encoded therein using an encoding protocol conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
[0374] Illustrative clause 9. The network element of illustrative clause 1, wherein the one or more antennas are further operable to couple the one or more radiated signals into one or more hollow waveguides.
[0375] Illustrative clause 10. The network element of illustrative clause 1, wherein each of the one or more serializers, the one or more modulators, and the one or more antennas are disposed on a single substrate.
[0376] Illustrative clause 11. The network element of illustrative clause 1, wherein at least a first one of the one or more serializers, the one or more modulators, and the one or more antennas are disposed on a first substrate, and at least a second one of the one or more serializers, the one or more modulators, and the one or more antennas are disposed on a second substrate different from the first substrate.
[0377] Illustrative clause 12. The network element of illustrative clause 1, wherein each of the one or more radiated signals are configured for coherent detection.
[0378] Illustrative clause 13. A network element, comprising: one or more antennas operable to detect one or more radiated signals and generate one or more antenna output signals based on the one or more radiated signals, each of the one or more radiated signals being radiated electromagnetic waves having client data encoded therein and a frequency in a range between 300 Gigahertz (GHz) and 10 Terahertz (THz); one or more demodulators operable to: receive the one or more antenna output signals from the one or more antennas; split each of the one or more antenna output signals into one or more pairs of intermediate signals, each of the one or more pairs of intermediate signals including a first intermediate signal based on a particular antenna output signal of the one or more antenna output signals and a second intermediate signal based on the particular antenna output signal; and down-convert the first intermediate signal and the second intermediate signal of each of the one or more pairs of intermediate signals to generate one or more pairs of serial baseband signals, each of the one or more pairs of serial baseband signals including a first serial baseband signal based on the first intermediate signal and a second serial baseband signal based on the second intermediate signal; and one or more deserializers operable to receive the one or more pairs of serial baseband signals from the one or more demodulators and de-multiplex the one or more pairs of serial baseband signals to generate a plurality of parallel baseband signals.
[0379] Illustrative clause 14. The network element of illustrative clause 13, wherein each of the one or more antenna output signals has an in-phase (I) component and a quadrature (Q) component, and wherein the one or more demodulators are operable to split each of the one or more antenna output signals into the one or more pairs of intermediate signals such that the first intermediate signal of each of the one or more pairs of intermediate signals is based on the I component of a particular antenna output signal of the one or more antenna output signals and the second intermediate signal of each of the one or more pairs of intermediate signals is based on the Q component of the particular antenna output signal.
[0380] Illustrative clause 15. The network element of illustrative clause 14, wherein each of the one or more demodulators is operable to receive a particular antenna output signal of the one or more antenna output signals from a particular antenna of the one or more antennas and generate a particular pair of serial baseband signals of the one or more pairs of serial baseband signals, the particular antenna output signal having a particular I component and a particular Q component, the particular pair of serial baseband signals having a particular first serial basebandsignal and a particular second serial baseband signal, each of the one or more demodulators comprising: an electronic oscillator operable to generate a reference signal having a frequency in the range between 300 GHz and 10 THz; a splitter operable to receive the particular antenna output signal from the particular antenna and split the particular antenna output signal into a particular pair of intermediate signals having a particular first intermediate signal based on the particular antenna output signal and a particular second intermediate signal based on the particular antenna output signal; a first down-converter operable to receive the particular first intermediate signal from the splitter and the reference signal from the electronic oscillator and mix the particular first intermediate signal with the reference signal to generate the particular first serial baseband signal; and a second down-converter operable to receive the particular second intermediate signal from the splitter and the reference signal from the electronic oscillator and mix the particular second intermediate signal with the reference signal to generate the particular second serial baseband signal.
[0381] Illustrative clause 16. The network element of illustrative clause 15, wherein the one or more demodulators are further operable to amplify the one or more antenna output signals to generate one or more amplified antenna output signals and split each of the one or more amplified antenna output signals into the one or more pairs of intermediate signals, each of the one or more demodulators further comprising a low-noise amplifier operable to receive the particular antenna output signal from the particular antenna and amplify the particular antenna output signal to generate a particular amplified antenna output signal of the one or more amplified antenna output signals, the splitter of each of the one or more demodulators being operable to receive the particular amplified antenna output signal from the low-noise amplifier and split the particular amplified antenna output signal into the particular pair of intermediate signals.
[0382] Illustrative clause 17. The network element of illustrative clause 15, wherein the first down-converter of each of the one or more demodulators is operable to receive the particular first intermediate signal as a first binary signal and the second down-converter of each of the one or more demodulators is operable to receive the particular second intermediate signal as a second binary signal.
[0383] Illustrative clause 18. The network element of illustrative clause 13, wherein the one or more demodulators are operable to receive the one or more antenna output signals having the client data encoded therein with an encoding protocol conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
[0384] Illustrative clause 19. The network element of illustrative clause 13, wherein the one or more antennas are further operable to receive the one or more radiated signals from one or more hollow waveguides.
[0385] Illustrative clause 20. The network element of illustrative clause 13, wherein each of the one or more antennas, the one or more demodulators, and the one or more deserializers are disposed on a single substrate.
[0386] Illustrative clause 21. The network element of illustrative clause 13, wherein at least a first one of the one or more antennas, the one or more demodulators, and the one or more deserializers are disposed on a first substrate, and at least a second one of the one or more antennas, the one or more demodulators, and the one or more deserializers are disposed on a second substrate different from the first substrate.
[0387] Illustrative clause 22. The network element of illustrative clause 13, wherein each of the one or more radiated signals are configured for coherent detection.
[0388] Illustrative clause 23. A network element, comprising: one or more serializers operable to receive a plurality of outbound parallel baseband signals and multiplex the plurality of outbound parallel baseband signals to generate one or more pairs of outbound serial baseband signals, each of the plurality of outbound parallel baseband signals having outbound client data encoded therein, each of the one or more pairs of outbound serial baseband signals including a first outbound serial baseband signal and a second outbound serial baseband signal; one or more modulators operable to: receive the one or more pairs of outbound serial baseband signals from the one or more serializers; up-convert the first outbound serial baseband signal and the second outbound serial baseband signal of each of the one or more pairs of outbound serial baseband signals to generate one or more pairs of outbound intermediate signals, each of the one or more pairs of outbound intermediate signals including a first outbound intermediate signal based on the first outbound serial baseband signal and a second outbound intermediate signal based on the second outbound serial baseband signal; and combine the first outbound intermediate signal and the second outbound intermediate signal of each of the one or more pairs of outbound intermediate signals into one or more antenna feed signals; and one or more transmitter antennas operable to receive the one or more antenna feed signals from the one or more modulators and generate one or more outbound radiated signals based on the one or more antenna feed signals, each of the one or more outbound radiated signals being radiated electromagnetic waves and having a first frequency in a range between 300 Gigahertz (GHz) and 10 Terahertz (THz); one or more receiver antennas operable to detect one or more inboundradiated signals and generate one or more antenna output signals based on the one or more inbound radiated signals, each of the one or more inbound radiated signals being radiated electromagnetic waves and having inbound client data encoded therein and a second frequency in the range between 300 GHz and 10 THz; one or more demodulators operable to: receive the one or more antenna output signals from the one or more receiver antennas; split each of the one or more antenna output signals into one or more pairs of inbound intermediate signals, each of the one or more pairs of inbound intermediate signals including a first inbound intermediate signal based on a particular antenna output signal of the one or more antenna output signals and a second inbound intermediate signal based on the particular antenna output signal; and downconvert the first inbound intermediate signal and the second inbound intermediate signal of each of the one or more pairs of inbound intermediate signals to generate one or more pairs of inbound serial baseband signals, each ofthe one or more pairs of inbound serial baseband signals including a first inbound serial baseband signal based on the first inbound intermediate signal and a second inbound serial baseband signal based on the second inbound intermediate signal; and one or more deserializers operable to receive the one or more pairs of inbound serial baseband signals from the one or more demodulators and de-multiplex the one or more pairs of inbound serial baseband signals to generate a plurality of inbound parallel baseband signals.
[0389] Illustrative clause 24. The network element of illustrative clause 23, wherein each of the one or more antenna feed signals has an outbound in-phase (I) component and an outbound quadrature (Q) component, wherein the one or more modulators are operable to combine the first outbound intermediate signal and the second outbound intermediate signal of each of the one or more pairs of outbound intermediate signals into the one or more antenna feed signals such that the outbound I component of each of the one or more antenna feed signals is based on the first outbound intermediate signal of a particular pair ofthe one or more pairs of outbound intermediate signals and the outbound Q component of each of the one or more antenna feed signals is based on the second outbound intermediate signal ofthe particular pair, wherein each of the one or more antenna output signals has an inbound I component and an inbound Q component, and wherein the one or more demodulators are operable to split each ofthe one or more antenna output signals into the one or more pairs of inbound intermediate signals such that the first inbound intermediate signal of each of the one or more pairs of inbound intermediate signals is based on the inbound I component of a particular antenna output signal of the one or more antenna output signals and the second inbound intermediate signal of eachof the one or more pairs of inbound intermediate signals is based on the inbound Q component of the particular antenna output signal.
[0390] Illustrative clause 25. The network element of illustrative clause 24, wherein each of the one or more modulators is operable to receive a particular pair of outbound serial baseband signals of the one or more pairs of outbound serial baseband signals from a particular serializer of the one or more serializers and generate a particular antenna feed signal of the one or more antenna feed signals, the particular pair of outbound serial baseband signals having a particular first outbound serial baseband signal and a particular second outbound serial baseband signal, the particular antenna feed signal having a particular outbound I component and a particular outbound Q. component, each of the one or more modulators comprising: an outbound electronic oscillator operable to generate a carrier signal having the first frequency in the range between 300 GHz and 10 THz; a first up-converter operable to receive the particular first outbound serial baseband signal from the particular serializer and the carrier signal from the outbound electronic oscillator and mix the particular first outbound serial baseband signal with the carrier signal to generate the first outbound intermediate signal; a second up-converter operable to receive the particular second outbound serial baseband signal from the particular serializer and the carrier signal from the outbound electronic oscillator and mix the particular second outbound serial baseband signal with the carrier signal to generate the second outbound intermediate signal; and a combiner operable to receive the first outbound intermediate signal from the first up-converter and the second outbound intermediate signal from the second up-converter and combine the first outbound intermediate signal and the second outbound intermediate signal to generate the particular antenna feed signal having the particular outbound I component based on the first outbound intermediate signal and the particular outbound Q component based on the second outbound intermediate signal; wherein each particular transmitter antenna of the one or more transmitter antennas is operable to receive the particular antenna feed signal from a particular modulator of the one or more modulators and generate a particular outbound radiated signal of the one or more outbound radiated signals based on the particular antenna feed signal.
[0391] Illustrative clause 26. The network element of illustrative clause 25, wherein the one or more modulators are further operable to limit the one or more antenna feed signals to generate one or more limited antenna feed signals, the one or more transmitter antennas being further operable to receive the one or more limited antenna feed signals from the one or more modulators and generate the one or more outbound radiated signals based on the one or morelimited antenna feed signals, each particular modulator of the one or more modulators further comprising an outbound limiting driver operable to receive the particular antenna feed signal from the combiner and limit the particular antenna feed signal to generate a particular limited antenna feed signal of the one or more limited antenna feed signals, each particular transmitter antenna of the one or more transmitter antennas being further operable to receive the particular limited antenna feed signal from the particular modulator and generate the particular outbound radiated signal based on the particular limited antenna feed signal.
[0392] Illustrative clause 27. The network element of illustrative clause 26, wherein the one or more modulators are further operable to amplify the one or more limited antenna feed signals to generate one or more conditioned antenna feed signals, the one or more transmitter antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more outbound radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising an outbound power amplifier operable to receive the particular limited antenna feed signal from the outbound limiting driver and amplify the particular limited antenna feed signal to generate a particular conditioned antenna feed signal of the one or more conditioned antenna feed signals, each particular transmitter antenna of the one or more transmitter antennas being further operable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular outbound radiated signal based on the particular conditioned antenna feed signal.
[0393] Illustrative clause 28. The network element of illustrative clause 25, wherein the one or more modulators are further operable to amplify the one or more antenna feed signals to generate one or more amplified antenna feed signals and limit the one or more amplified antenna feed signals to generate one or more conditioned antenna feed signals, the one or more transmitter antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more outbound radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising an outbound limiting amplifier operable to receivethe particularantenna feed signal fromthe combiner, amplify the particularantenna feed signal to generate a particular amplified antenna feed signal of the one or more amplified antenna feed signals, and limit the particular amplified antenna feed signal to generate a particular conditioned antenna feed signal of the one or more conditioned antenna feed signals, each particular transmitter antenna of the one or more transmitter antennas being furtheroperable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular outbound radiated signal based on the particular conditioned antenna feed signal.
[0394] Illustrative clause 29. The network element of illustrative clause 25, wherein the first up-converter of each of the one or more modulators is operable to receive the particular first outbound serial baseband signal as a first binary signal and the second up-converter of each of the one or more modulators is operable to receive the particular second outbound serial baseband signal as a second binary signal.
[0395] Illustrative clause 30. The network element of illustrative clause 23, wherein the one or more demodulators are operable to receive the one or more antenna output signals having the inbound client data encoded therein with an encoding scheme conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
[0396] Illustrative clause 31. The network element of illustrative clause 23, wherein each of the one or more demodulators is operable to receive a particular antenna output signal of the one or more antenna output signals from a particular receiver antenna of the one or more receiver antennas and generate a particular pair of inbound serial baseband signals of the one or more pairs of inbound serial baseband signals, the particular antenna output signal having a particular inbound I component and a particular inbound Q component, the particular pair of inbound serial baseband signals having a particular first inbound serial baseband signal and a particular second inbound serial baseband signal, each of the one or more demodulators comprising: an inbound electronic oscillator operable to generate a reference signal having the second frequency in the range between 300 GHz and 10 THz; a splitter operable to receive the particular antenna output signal from the particular receiver antenna and split the particular antenna output signal into a particular pair of inbound intermediate signals having a particular first inbound intermediate signal based on the particular antenna output signal and a particular second inbound intermediate signal based on the particular antenna output signal; a first downconverter operable to receive the particular first inbound intermediate signal from the splitter and the reference signal from the inbound electronic oscillator and mix the particular first inbound intermediate signal with the reference signal to generate the particular first inbound serial baseband signal; and a second down-converter operable to receive the particular second inbound intermediate signal from the splitter and the reference signal from the inboundelectronic oscillator and mix the particular second inbound intermediate signal with the reference signal to generate the particular second inbound serial baseband signal.
[0397] Illustrative clause 32. The network element of illustrative clause 31, wherein the one or more demodulators are further operable to amplify the one or more antenna output signals to generate one or more amplified antenna output signals and split each of the one or more amplified antenna output signals into the one or more pairs of inbound intermediate signals, each of the one or more demodulators further comprising a low-noise amplifier operable to receive the particular antenna output signal from the particular receiver antenna and amplify the particular antenna output signal to generate a particular amplified antenna output signal of the one or more amplified antenna output signals, the splitter of each of the one or more demodulators being operable to receive the particular amplified antenna output signal from the low-noise amplifier and split the particular amplified antenna output signal into the particular pair of inbound intermediate signals.
[0398] Illustrative clause 33. The network element of illustrative clause 31, wherein the first down-converter of each of the one or more demodulators is operable to receive the particular first inbound intermediate signal as a first binary signal and the second down -converter of each of the one or more demodulators is operable to receive the particular second inbound intermediate signal as a second binary signal.
[0399] Illustrative clause 34. The network element of illustrative clause 23, wherein the one or more serializers are operable to receive the plurality of outbound parallel baseband signals having the outbound client data encoded therein using an encoding scheme conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
[0400] Illustrative clause 35. The network element of illustrative clause 23, wherein the one or more transmitter antennas are further operable to couple the one or more outbound radiated signals into one or more first hollow waveguides, and wherein the one or more receiver antennas are further operable to receive the one or more inbound radiated signals from one of the one or more first hollow waveguides and one or more second hollow waveguides.
[0401] Illustrative clause 36. The network element of illustrative clause 23, wherein each of the one or more serializers, the one or more modulators, the one or more transmitter antennas, the one or more receiver antennas, the one or more demodulators, and the one or more deserializers are disposed on a single substrate.
[0402] Illustrative clause 37. The network element of illustrative clause 23, wherein at least a first one of the one or more serializers, the one or more modulators, the one or more transmitter antennas, the one or more receiver antennas, the one or more demodulators, and the one or more deserializers are disposed on a first substrate, and at least a second one of the one or more serializers, the one or more modulators, the one or more transmitter antennas, the one or more receiver antennas, the one or more demodulators, and the one or more deserializers are disposed on a second substrate different from the first substrate.
[0403] Illustrative clause 38. The network element of illustrative clause 23, wherein each of the one or more outbound radiated signals and the one or more inbound radiated signals are configured for coherent detection.CONCLUSION
[0404] The foregoing description provides illustration and description, but is not intended to be exhaustive or to limit the inventive concepts to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practice of the methodologies set forth in the present disclosure.
[0405] Even though particular combinations of features are recited in the claims and / or disclosed in the specification, these combinations are not intended to limit the disclosure. In fact, many of these features may be combined in ways not specifically recited in the claims and / or disclosed in the specification. Although each dependent claim listed below may directly depend on only one other claim, the disclosure includes each dependent claim in combination with every other claim in the claim set.
[0406] No element, act, or instruction used in the present application should be construed as critical or essential to the invention unless explicitly described as such outside of the preferred embodiment. Further, the phrase "based on" is intended to mean "based, at least in part, on" unless explicitly stated otherwise.
[0407] Headings are provided for convenience only and are not to be construed to limit the invention in any manner. Embodiments illustrated under any heading or in any portion of the disclosure may be combined with embodiments illustrated underthe same or any other heading or other portion of the disclosure. Any combination of the elements described herein in all possible variationsthereof is encompassed by the invention unless otherwise indicated herein or otherwise clearly contradicted by context.
Claims
What is claimed is:
1. A network element, comprising:one or more serializers operable to receive a plurality of parallel baseband signals and multiplex the plurality of parallel baseband signals to generate one or more pairs of serial baseband signals, each of the plurality of parallel baseband signals having client data encoded therein, each of the one or more pairs of serial baseband signals including a first serial baseband signal and a second serial baseband signal; one or more modulators operable to:receive the one or more pairs of serial baseband signals from the one or more serializers;up-convert the first serial baseband signal and the second serial baseband signal of each ofthe one or more pairs of serial baseband signals to generate one or more pairs of intermediate signals, each of the one or more pairs of intermediate signals including a first intermediate signal based on the first serial baseband signal and a second intermediate signal based on the second serial baseband signal; andcombine the first intermediate signal and the second intermediate signal of each ofthe one or more pairs of intermediate signals into one or more antenna feed signals; andone or more antennas operable to receive the one or more antenna feed signals from the one or more modulators and generate one or more radiated signals based on the one or more antenna feed signals, each ofthe one or more radiated signals being radiated electromagnetic waves and having a frequency in a range between 300 Gigahertz (GHz) and lOTerahertz (THz).
2. The network element of claim 1,wherein each ofthe one or more antenna feed signals has an in-phase (I) component and a quadrature (Q) component, andwherein the one or more modulators are operable to combine the first intermediate signal and the second intermediate signal of each of the one or more pairs of intermediate signals into the one or more antenna feed signals such that the I component of each of the one or more antenna feed signals is based on the first intermediate signal of a particular pair of the one or more pairs of intermediatesignals and the Q. component of each of the one or more antenna feed signals is based on the second intermediate signal of the particular pair.
3. The network element of claim 2, wherein each of the one or more modulators is operable to receive a particular pair of serial baseband signals of the one or more pairs of serial baseband signals from a particular serializer of the one or more serializers and generate a particular antenna feed signal of the one or more antenna feed signals, the particular pair of serial baseband signals having a particular first serial baseband signal and a particular second serial baseband signal, the particular antenna feed signal having a particular I component and a particular Q component, each of the one or more modulators comprising:an electronic oscillator operable to generate a carrier signal having a frequency in the range between 300 GHz and 10 THz;a first up-converter operable to receive the particular first serial baseband signal from the particular serializer and the carrier signal from the electronic oscillator and mix the particular first serial baseband signal with the carrier signal to generate the first intermediate signal;a second up-converter operable to receive the particular second serial baseband signal from the particular serializer and the carrier signal from the electronic oscillator and mix the particular second serial baseband signal with the carrier signal to generate the second intermediate signal; anda combiner operable to receive the first intermediate signal from the first up-converter and the second intermediate signal from the second up-converter and combine the first intermediate signal and the second intermediate signal to generate the particular antenna feed signal having the particular I component based on the first intermediate signal and the particular Q component based on the second intermediate signal;wherein each particular antenna of the one or more antennas is operable to receive the particular antenna feed signal from a particular modulator of the one or more modulators and generate a particular radiated signal of the one or more radiated signals based on the particular antenna feed signal.
4. The network element of claim 3, wherein the one or more modulators are further operable to limit the one or more antenna feed signals to generate one or more limited antenna feed signals, the one or more antennas being further operable to receive the one or more limited antenna feed signals from the one or more modulators and generate the one or more radiated signals based on the one or more limited antenna feed signals, each particular modulator of the one or more modulators further comprising a limiting driver operable to receive the particular antenna feed signal from the combiner and limit the particular antenna feed signal to generate a particular limited antenna feed signal of the one or more limited antenna feed signals, each particular antenna of the one or more antennas being further operable to receive the particular limited antenna feed signal from the particular modulator and generate the particular radiated signal based on the particular limited antenna feed signal.
5. The network element of claim 4, wherein the one or more modulators are further operable to amplify the one or more limited antenna feed signals to generate one or more conditioned antenna feed signals, the one or more antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising a power amplifier operable to receive the particular limited antenna feed signal from the limiting driver and amplify the particular limited antenna feed signal to generate a particular conditioned antenna feed signal ofthe one or more conditioned antenna feed signals, each particular antenna of the one or more antennas being further operable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular radiated signal based on the particular conditioned antenna feed signal.
6. The network element of claim 3, wherein the one or more modulators are further operable to amplify the one or more antenna feed signals to generate one or more amplified antenna feed signals and limit the one or more amplified antenna feed signals to generate one or more conditioned antenna feed signals, the one or more antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising a limiting amplifier operable to receive the particular antenna feed signal from the combiner, amplify theparticular antenna feed signal to generate a particular amplified antenna feed signal of the one or more amplified antenna feed signals, and limit the particular amplified antenna feed signal to generate a particular conditioned antenna feed signal of the one or more conditioned antenna feed signals, each particular antenna of the one or more antennas being further operable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular radiated signal based on the particular conditioned antenna feed signal.
7. The network element of claim 3, wherein the first up-converter of each of the one or more modulators is operable to receive the particular first serial baseband signal as a first binary signal and the second up-converter of each ofthe one or more modulators is operable to receive the particular second serial baseband signal as a second binary signal.
8. The network element of claim 1, wherein the one or more serializers are operable to receive the plurality of parallel baseband signals having the client data encoded therein using an encoding protocol conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
9. The network element of claim 1, wherein the one or more antennas are further operable to couple the one or more radiated signals into one or more hollow waveguides.
10. The network element of claim 1, wherein each ofthe one or more serializers, the one or more modulators, and the one or more antennas are disposed on a single substrate.
11. The network element of claim 1, wherein at least a first one ofthe one or more serializers, the one or more modulators, and the one or more antennas are disposed on a first substrate, and at least a second one of the one or more serializers, the one or more modulators, and the one or more antennas are disposed on a second substrate different from the first substrate.
12. The network element of claim 1, wherein each of the one or more radiated signals are configured for coherent detection.
13. A network element, comprising:one or more antennas operable to detect one or more radiated signals and generate one or more antenna output signals based on the one or more radiated signals, each of the one or more radiated signals being radiated electromagnetic waves having client data encoded therein and a frequency in a range between 300 Gigahertz (GHz) and 10 Terahertz (THz);one or more demodulators operable to:receive the one or more antenna output signals from the one or more antennas; split each of the one or more antenna output signals into one or more pairs of intermediate signals, each of the one or more pairs of intermediate signals including a first intermediate signal based on a particular antenna output signal of the one or more antenna output signals and a second intermediate signal based on the particular antenna output signal; and down-convert the first intermediate signal and the second intermediate signal of each of the one or more pairs of intermediate signals to generate one or more pairs of serial baseband signals, each of the one or more pairs of serial baseband signals including a first serial baseband signal based on the first intermediate signal and a second serial baseband signal based on the second intermediate signal; andone or more deserializers operable to receive the one or more pairs of serial baseband signals from the one or more demodulators and de-multiplex the one or more pairs of serial baseband signals to generate a plurality of parallel baseband signals.
14. The network element of claim 13,wherein each of the one or more antenna output signals has an in-phase (I) component and a quadrature (Q) component, andwherein the one or more demodulators are operable to split each of the one or more antenna output signals into the one or more pairs of intermediate signals such that the first intermediate signal of each of the one or more pairs of intermediate signals is based on the I component of a particular antenna output signal of the one or more antenna output signals and the second intermediate signal of each of the one or more pairs of intermediate signals is based on the Q component of the particular antenna output signal.
15. The network element of claim 14, wherein each of the one or more demodulators is operable to receive a particular antenna output signal of the one or more antenna output signals from a particular antenna of the one or more antennas and generate a particular pair of serial baseband signals of the one or more pairs of serial baseband signals, the particular antenna output signal having a particular I component and a particular Q component, the particular pair of serial baseband signals having a particular first serial baseband signal and a particular second serial baseband signal, each of the one or more demodulators comprising:an electronic oscillator operable to generate a reference signal having a frequency in the range between 300 GHz and 10 THz;a splitter operable to receive the particular antenna output signal from the particular antenna and split the particular antenna output signal into a particular pair of intermediate signals having a particular first intermediate signal based on the particular antenna output signal and a particularsecond intermediate signal based on the particular antenna output signal;a first down-converter operable to receive the particular first intermediate signal from the splitter and the reference signal from the electronic oscillator and mix the particular first intermediate signal with the reference signal to generate the particular first serial baseband signal; anda second down-converter operable to receive the particular second intermediate signal from the splitter and the reference signal from the electronic oscillator and mix the particular second intermediate signal with the reference signal to generate the particularsecond serial baseband signal.
16. The network element of claim 15, wherein the one or more demodulators are further operable to amplify the one or more antenna output signals to generate one or more amplified antenna output signals and split each of the one or more amplified antenna output signals into the one or more pairs of intermediate signals, each of the one or more demodulators further comprising a low-noise amplifier operable to receive the particular antenna output signal from the particular antenna and amplify the particular antenna output signal to generate a particular amplified antenna output signal of the one or more amplified antenna output signals, the splitter of each of the one or more demodulators being operable to receive the particular amplified antenna output signal from the low-noise amplifier and split the particular amplified antenna output signal into the particular pair of intermediate signals.
17. The network element of claim 15, wherein the first down -converter of each of the one or more demodulators is operable to receive the particular first intermediate signal as a first binary signal and the second down-converter of each of the one or more demodulators is operable to receive the particular second intermediate signal as a second binary signal.
18. The network element of claim 13, wherein the one or more demodulators are operable to receive the one or more antenna output signals having the client data encoded therein with an encoding protocol conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
19. The network element of claim 13, wherein the one or more antennas are further operable to receive the one or more radiated signals from one or more hollow waveguides.
20. The network element of claim 13, wherein each of the one or more antennas, the one or more demodulators, and the one or more deserializers are disposed on a single substrate.
21. The network element of claim 13, wherein at least a firstone of the one or more antennas, the one or more demodulators, and the one or more deserializers are disposed on a first substrate, and at least a second one of the one or more antennas, the one or more demodulators, and the one or more deserializers are disposed on a second substrate different from the first substrate.
22. The network element of claim 13, wherein each of the one or more radiated signals are configured for coherent detection.
23. A network element, comprising:one or more serializers operable to receive a plurality of outbound parallel baseband signals and multiplex the plurality of outbound parallel baseband signals to generate one or more pairs of outbound serial baseband signals, each of the plurality of outbound parallel baseband signals having outbound client data encoded therein, each of the one or more pairs of outbound serial basebandsignals including a first outbound serial baseband signal and a second outbound serial baseband signal;one or more modulators operable to:receive the one or more pairs of outbound serial baseband signals from the one or more serializers;up-convert the first outbound serial baseband signal and the second outbound serial baseband signal of each ofthe one or more pairs of outbound serial baseband signals to generate one or more pairs of outbound intermediate signals, each of the one or more pairs of outbound intermediate signals including a first outbound intermediate signal based on the first outbound serial baseband signal and a second outbound intermediate signal based on the second outbound serial baseband signal; andcombine the first outbound intermediate signal and the second outbound intermediate signal of each of the one or more pairs of outbound intermediate signals into one or more antenna feed signals; and one or more transmitter antennas operable to receive the one or more antenna feed signals from the one or more modulators and generate one or more outbound radiated signals based on the one or more antenna feed signals, each of the one or more outbound radiated signals being radiated electromagnetic waves and having a first frequency in a range between 300 Gigahertz (GHz) and 10 Terahertz (THz);one or more receiver antennas operable to detect one or more inbound radiated signals and generate one or more antenna output signals based on the one or more inbound radiated signals, each ofthe one or more inbound radiated signals being radiated electromagnetic waves and having inbound client data encoded therein and a second frequency in the range between 300 GHz and 10 THz;one or more demodulators operable to:receive the one or more antenna output signals from the one or more receiver antennas;split each of the one or more antenna output signals into one or more pairs of inbound intermediate signals, each of the one or more pairs of inbound intermediate signals including a first inbound intermediate signal based on a particular antenna output signal of the one or more antenna outputsignals and a second inbound intermediate signal based on the particular antenna output signal; anddown-convert the first inbound intermediate signal and the second inbound intermediate signal of each of the one or more pairs of inbound intermediate signals to generate one or more pairs of inbound serial baseband signals, each of the one or more pairs of inbound serial baseband signals including a first inbound serial baseband signal based on the first inbound intermediate signal and a second inbound serial baseband signal based on the second inbound intermediate signal; and one or more deserializers operable to receive the one or more pairs of inbound serial baseband signals from the one or more demodulators and de-multiplex the one or more pairs of inbound serial baseband signals to generate a plurality of inbound parallel baseband signals.
24. The network element of claim 23,wherein each of the one or more antenna feed signals has an outbound in-phase (I) component and an outbound quadrature (Q) component,wherein the one or more modulators are operable to combine the first outbound intermediate signal and the second outbound intermediate signal of each of the one or more pairs of outbound intermediate signals into the one or more antenna feed signals such that the outbound I component of each of the one or more antenna feed signals is based on the first outbound intermediate signal of a particular pair of the one or more pairs of outbound intermediate signals and the outbound Q component of each of the one or more antenna feed signals is based on the second outbound intermediate signal of the particular pair, wherein each of the one or more antenna output signals has an inbound I component and an inbound Q component, andwherein the one or more demodulators are operable to split each of the one or more antenna output signals into the one or more pairs of inbound intermediate signals such that the first inbound intermediate signal of each of the one or more pairs of inbound intermediate signals is based on the inbound I component of a particular antenna output signal of the one or more antenna output signals and the second inbound intermediate signal of each of the one or more pairs of inboundintermediate signals is based on the inbound Q component of the particular antenna output signal.
25. The network element of claim 24, wherein each of the one or more modulators is operable to receive a particular pair of outbound serial baseband signals of the one or more pairs of outbound serial baseband signals from a particular serializer of the one or more serializers and generate a particular antenna feed signal of the one or more antenna feed signals, the particular pair of outbound serial baseband signals having a particularfirst outbound serial baseband signal and a particular second outbound serial baseband signal, the particular antenna feed signal having a particular outbound I component and a particular outbound Q component, each of the one or more modulators comprising:an outbound electronic oscillator operable to generate a carrier signal having the first frequency in the range between 300 GHz and 10 THz;a first up-converter operable to receive the particular first outbound serial baseband signal from the particular serializer and the carrier signal from the outbound electronic oscillator and mix the particular first outbound serial baseband signal with the carrier signal to generate the first outbound intermediate signal;a second up-converter operable to receive the particular second outbound serial baseband signal from the particular serializer and the carrier signal from the outbound electronic oscillator and mix the particular second outbound serial baseband signal with the carrier signal to generate the second outbound intermediate signal; anda combiner operable to receive the first outbound intermediate signal from the first up- converter and the second outbound intermediate signal from the second up- converter and combine the first outbound intermediate signal and the second outbound intermediate signal to generate the particular antenna feed signal having the particular outbound I component based on the first outbound intermediate signal and the particular outbound Q. component based on the second outbound intermediate signal;wherein each particular transmitter antenna of the one or more transmitter antennas is operable to receive the particular antenna feed signal from a particular modulator of the one or more modulators and generate a particular outbound radiated signalof the one or more outbound radiated signals based on the particular antenna feed signal.
26. The network element of claim 25, wherein the one or more modulators are further operable to limit the one or more antenna feed signals to generate one or more limited antenna feed signals, the one or more transmitter antennas being further operable to receive the one or more limited antenna feed signals from the one or more modulators and generate the one or more outbound radiated signals based on the one or more limited antenna feed signals, each particular modulator of the one or more modulators further comprising an outbound limiting driver operable to receive the particular antenna feed signal from the combiner and limit the particular antenna feed signal to generate a particular limited antenna feed signal of the one or more limited antenna feed signals, each particular transmitter antenna of the one or more transmitter antennas being further operable to receive the particular limited antenna feed signal from the particular modulator and generate the particular outbound radiated signal based on the particular limited antenna feed signal.
27. The network element of claim 26, wherein the one or more modulators are further operable to amplify the one or more limited antenna feed signals to generate one or more conditioned antenna feed signals, the one or more transmitter antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more outbound radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising an outbound power amplifier operable to receive the particular limited antenna feed signal from the outbound limiting driverand amplify the particular limited antenna feed signalto generate a particular conditioned antenna feed signal of the one or more conditioned antenna feed signals, each particular transmitter antenna of the one or more transmitter antennas being further operable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular outbound radiated signal based on the particular conditioned antenna feed signal.
28. The network element of claim 25, wherein the one or more modulators are further operable to amplify the one or more antenna feed signals to generate one or more amplified antenna feed signals and limit the one or more amplified antenna feed signals to generate oneor more conditioned antenna feed signals, the one or more transmitter antennas being further operable to receive the one or more conditioned antenna feed signals from the one or more modulators and generate the one or more outbound radiated signals based on the one or more conditioned antenna feed signals, each particular modulator of the one or more modulators further comprising an outbound limiting amplifier operable to receive the particular antenna feed signal from the combiner, amplify the particular antenna feed signal to generate a particular amplified antenna feed signal of the one or more amplified antenna feed signals, and limit the particular amplified antenna feed signal to generate a particular conditioned antenna feed signal of the one or more conditioned antenna feed signals, each particular transmitter antenna of the one or more transmitter antennas being further operable to receive the particular conditioned antenna feed signal from the particular modulator and generate the particular outbound radiated signal based on the particular conditioned antenna feed signal.
29. The network element of claim 25, wherein the first up-converter of each of the one or more modulators is operable to receive the particular first outbound serial baseband signal as a first binary signal and the second up-converter of each of the one or more modulators is operable to receive the particular second outbound serial baseband signal as a second binary signal.
30. The network element of claim 23, wherein the one or more demodulators are operable to receive the one or more antenna output signals having the inbound client data encoded therein with an encoding scheme conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
31. The network element of claim 23, wherein each of the one or more demodulators is operable to receive a particular antenna output signal of the one or more antenna output signals from a particular receiver antenna of the one or more receiver antennas and generate a particular pair of inbound serial baseband signals of the one or more pairs of inbound serial baseband signals, the particular antenna output signal having a particular inbound I component and a particular inbound Q component, the particular pair of inbound serial baseband signals having a particular first inbound serial baseband signal and a particular second inbound serial baseband signal, each of the one or more demodulators comprising:an inbound electronic oscillator operable to generate a reference signal having the second frequency in the range between 300 GHz and 10 THz;a splitter operable to receive the particular antenna output signal from the particular receiver antenna and split the particular antenna output signal into a particular pairof inbound intermediate signals having a particularfirst inbound intermediate signal based on the particular antenna output signal and a particular second inbound intermediate signal based on the particular antenna output signal; a first down-converter operable to receive the particularfirst inbound intermediate signal from the splitter and the reference signal from the inbound electronic oscillator and mix the particular first inbound intermediate signal with the reference signal to generate the particular first inbound serial baseband signal; and a second down-converter operable to receive the particular second inbound intermediate signal from the splitter and the reference signal from the inbound electronic oscillator and mix the particular second inbound intermediate signal with the reference signal to generate the particular second inbound serial baseband signal.
32. The network element of claim 31, wherein the one or more demodulators are further operable to amplify the one or more antenna output signals to generate one or more amplified antenna output signals and split each of the one or more amplified antenna output signals into the one or more pairs of inbound intermediate signals, each of the one or more demodulators further comprising a low-noise amplifier operable to receive the particular antenna output signal from the particular receiver antenna and amplify the particular antenna output signal to generate a particular amplified antenna output signal of the one or more amplified antenna output signals, the splitter of each of the one or more demodulators being operable to receive the particular amplified antenna output signal from the low-noise amplifier and split the particular amplified antenna output signal into the particular pair of inbound intermediate signals.
33. The network element of claim 31, wherein the first down-converter of each of the one or more demodulators is operable to receive the particular first inbound intermediate signal as a first binary signal and the second down-converter of each of the one or more demodulators is operable to receive the particular second inbound intermediate signal as a second binary signal.
34. The network element of claim 23, wherein the one or more serializers are operable to receive the plurality of outbound parallel baseband signals having the outbound client dataencoded therein using an encoding scheme conforming to a specification of one or more of quadrature amplitude modulation (QAM) and quadrature phase shift keying (QPSK).
35. The network element of claim 23,wherein the one or more transmitter antennas are further operable to couple the one or more outbound radiated signals into one or more first hollow waveguides, and wherein the one or more receiver antennas are further operable to receive the one or more inbound radiated signals from one of the one or more first hollow waveguides and one or more second hollow waveguides.
36. The network element of claim 23, wherein each of the one or more serializers, the one or more modulators, the one or more transmitter antennas, the one or more receiver antennas, the one or more demodulators, and the one or more deserializers are disposed on a single substrate.
37. The network element of claim 23, wherein at least a first one of the one or more serializers, the one or more modulators, the one or more transmitter antennas, the one or more receiver antennas, the one or more demodulators, and the one or more deserializers are disposed on a first substrate, and at least a second one of the one or more serializers, the one or more modulators, the one or more transmitter antennas, the one or more receiver antennas, the one or more demodulators, and the one or more deserializers are disposed on a second substrate different from the first substrate.
38. The network element of claim 23, wherein each of the one or more outbound radiated signals and the one or more inbound radiated signals are configured for coherent detection.