56results about "Modulation transference by distributed inductance and capacitance" patented technology

A mixing method and mixer structure provide a circuit topology suitable for use in radio receivers, transmitters, tuners, instrumentation systems, telemetry systems, and other systems and devices performing frequency conversion in either homodyne or heterodyne implementations. The inventive mixer may be used for wireless communication devices including radios, cellular telephones, and telemetry systems whether land, sea, airborne, or space based, and whether fixed or mobile. The mixer provides superior intermodulation and harmonic distortion suppression and features excellent conversion loss, noise figure, port match, and port isolation as a result of its circuit topology. The mixer device circuit combines the advantages of series mixing FETs, a triple balanced design using a balanced passive reflection transformer, a precise local oscillator phase splitter, and square wave gate drive having high slew rate signal characteristics to achieve high levels of performance. It is power conservative and offers the advantage of long battery life in portable devices such as portable radios and cellular telephones as it requires only a modest amount of DC and local oscillator drive power, and is useful for operation over at least a multi-decade bandwidth.

A wideband distributed mixer capable of operation over a wide range of frequencies is provided. The mixer can include a plurality of N mixer stages and monolithic transmission lines integrated together on a common semiconductor substrate. The length of each transmission line between adjacent stages can be predetermined such that an IF signal output from each stage is in-phase with the IF signal output from any preceding stage, allowing the mixer to output a mixed IF signal that is a constructive sum of the IF output signals from each constituent stage. The number of mixer stages as well as the design architectures and topologies for each stage can be varied according to the needs of the application.

The invention relates to a method for detecting and processing the amplitude and phase of signal waves. A Modulated signal source generates the signal waves which are modified by transmission medium or by reflection and scattering by at least one object. The modified signal waves are received and demodulated using a modulation signal. The amplitude of the modulated signal waves and their phase relationship to the modulation signal are measured and evaluated. The demodulated signal wave is converted into an electrical charge or charge displacement in the receiving medium and is distributed in accordance with a modulation signal to at least two readout outputs and fed to an evaluation unit. The evaluation unit produces the sum and difference of the output signals thus applying the value of the intensity and the phase position of the signal wave that has been scattered, reflected or delayed by the object.

A microwave broadside coupled balun integral in a multi-layer printed wiring board formed by broadside coupled conductors embedded in the multi-layer printed wiring board. The balun may be used to form components which are integrated into the multi-layer printed wiring board, such as a microwave mixer formed by two of said broadside coupled baluns embedded in a multi-layer printed wiring board and connected to a diode ring quad.

An apparatus comprising an amplifier circuit, a tuning circuit and a mixer circuit. The amplifier circuit may be configured to generate an output signal at a first node in response to an input signal received through a second node. A tuning circuit may be (i) coupled between said second node of the amplifier circuit and third node and (ii) configured to adjust an impedance presented to the third node in response to a tuning voltage. A mixer circuit may have a center tap coupled to the third node.

A wide band mixer is provided that mitigates local oscillator leakage. A LO signal is provided to a 180 degree splitter that provides a first intermediate LO signal and a second intermediate LO signal 180° out of phase from one another. Since both the first and second intermediate LO signals are 180° out of phase, the fundamental LO leakage is mitigated at the RF port by the in-phase combination of the 180° out of phase LO tones canceling one another out and providing strong LO / RF rejection. An RF or microwave input signal is provided to a power splitter to provide a first intermediate RF signal and a second intermediate RF signal. The first intermediate LO signal is mixed with the first intermediate RF signal and the second intermediate LO signal is mixed with the second intermediate RF signal to provide an intermediate frequency signal at the output of the mixer.

A low-noise amplifier in a receiver has a differential mode of operation and at least one single-ended mode of operation. A control signal is used to select between or among the modes and the switching between differential and single-ended operations may be performed on the fly.

A method and system for improving sensitivity of microwave and millimeter phase discriminators is disclosed. An exemplary embodiment of a phase discriminator includes two mixers inserted between two 90 degree hybrids. One hybrid splits the reference or LO signal into two signals of equal magnitude with a phase difference of 90 degrees. Similarly, the other hybrid splits the received RF signal into equal signals shifted 90 degrees in phase. One mixer receives an input set (e.g., LO and RF signals) with a zero-degree phase shift, and the other mixer receives the input set shifted in phase by 90 degrees. Thus, the leakage signals at the output of each mixer have the same magnitude but are 180 degrees apart in phase. The IF ports of the mixers are tied together, allowing the leakage signals of the mixers to combine destructively, thereby increasing isolation and sensitivity.

A mixer converts input power at high-frequency RF into output power at a different and much lower frequency IF, with the assistance of another high-frequency oscillator (LO). Typically, a very low IF frequency requires an LO that approximates the RF frequency. However, a subharmonic mixer facilitates low IF with LO frequencies significantly lower than the RF frequency. This balanced odd-subharmonic mixer consists primarily of a four-port BALUN and a pair of diodes. The diodes terminate two ports of the BALUN connecting in series and in anti-parallel to the remaining external BALUN ports. The external BALUN ports constitute the RF and the LO high-frequency mixer ports. The mixer's lower-frequency IF port also connects to the diodes, comprising a separate channel that is co-linear with one BALUN external port, and coupling capacitively to the other. All three mixer ports meet at a mixing chamber (part of the BALUN) where the diodes are located.

A normal NRD guide is constituted in the part to be coupled with a dielectric resonator, a hyper NRD guide for simply transmitting the LSM01 mode is constituted in a multipoints circulator part, the normal NRD guide is constituted in a coupler part, the hyper NRD guide is constituted in the mixer part, and the normal NRD guides are constituted in a dielectric line switch part and in a connection unit between components.

Configuration of a connection between an even-harmonic mixer and a filter is simplified, thereby enabling size reduction. An even-harmonic mixer (21) and a high-frequency bandpass filter (23) are connected to each other via a transmission line (22), thereby forming a filter-integrated even-harmonic mixer. The length of the transmission line (22) is set so that impedance on the transmission line side as viewed from a connection point (24) between the even-harmonic mixer (21) and the transmission line (22) is approximately 0 for a frequency fLO of a local oscillation signal. This allows elimination of an open stub which is used in a conventional even-harmonic mixer and of which the line length to provide equivalent grounding for the frequency fLO is about 1 mm. Thus, the connection portion between the even-harmonic mixer and the high-frequency bandpass filter is simplified and a compact circuit layout for the filter-integrated even-harmonic mixer is obtainable.

A phase detector and method of phase detection. The detector includes a substrate; an impulse generator fabricated on the substrate; and a sampling circuit operationally coupled to the generator and disposed on the substrate. In the best mode, the impulse generator and the sampling circuit are fabricated on the substrate using grounded slotline technology and coplanar waveguide technology. In more specific embodiments, the generator is a slotline impulse generator with a step recovery diode. In this embodiment, the impulse generator further includes a coplanar waveguide to slotline transition at an input port thereof and a slotline to coplanar waveguide at an output port thereof. In addition, in the illustrative embodiment, the sampling circuit further includes a slotline hybrid T junction. In accordance with the present teachings, the junction is an ultra-wideband grounded slotline hybrid T junction. The sampling circuit further includes a phase bridge coupled to the hybrid T junction and a grounded slotline coupled delay. In the specific embodiment, the sampling circuit also includes a broadband transition from coplanar waveguide to coupled slotline.

Configuration of a connection between an even-harmonic mixer and a filter is simplified, thereby enabling size reduction. An even-harmonic mixer and a high-frequency bandpass filter are connected to each other via a transmission line, thereby forming a filter-integrated even-harmonic mixer. The length of the transmission line is set so that impedance on the transmission line side as viewed from a connection point between the even-harmonic mixer and the transmission line is approximately 0 for a frequency fLO of a local oscillation signal. This allows elimination of an open stub which is used in a conventional even-harmonic mixer and of which the line length to provide equivalent grounding for the frequency fLO is about 1 mm. Thus, the connection portion between the even-harmonic mixer and the high-frequency bandpass filter is simplified and a compact circuit layout for the filter-integrated even-harmonic mixer is obtainable.

A first narrow rectangular groove having a rectangular cross section and a second narrow rectangular groove substantially orthogonal to the first narrow rectangular groove and having a rectangular cross section are formed in a first silicon substrate. A third narrow rectangular groove located at a position facing the first narrow rectangular groove and having a rectangular cross section is formed on a second silicon substrate. A device substrate including a frequency conversion device is provided in the second narrow rectangular groove, so that the frequency conversion device is located where the first and second narrow rectangular grooves are orthogonal to each other. Further, the first silicon substrate on which the device substrate is located is bonded to the second silicon substrate, so that the first narrow rectangular groove opposes the third narrow rectangular groove, forming a rectangular waveguide which includes the first narrow rectangular groove and the third narrow rectangular groove, and in which a received high frequency signal propagates and is incident on the frequency conversion device.

The invention discloses a semi model substrate integrated waveguide double balanced mixer and an implementation method thereof. The double balanced mixer consists of an RF Balun, a local oscillation Balun, an RF waveguide cavity, a local oscillation waveguide cavity, a mixing tube and a low-pass filter. The implementation method comprises the following steps: a) RF signals are caused to go through the RF Balun so as to obtain RF isolation signals, local oscillation signals are caused to go through the local oscillation Balun so as to obtain local oscillation isolation signals and the amplitude of the RF isolation signals is equal to that of the local oscillation isolation signals while the phase difference is 180 degrees; b) the RF isolation signals and the local oscillation isolation signals in the step a are caused to go through the mixing tube so as to obtain mixing signals; and c) the mixing signals in the step b are caused to go through the low-pass filter so as to obtain intermediate-frequency signals. The double balanced mixer provided by the invention reduces the volume of the Balun and has high mixing efficiency, wide bandwidth and simple structure, thus being very easy to be realized in the Balun engineering.

To provide a microwave / milliwave UWB pulse wireless communication device that enables realization of structural simplification, high performance, compact integration, easy design, low power consumption, and low cost. A radiation type oscillator is configured by a radiation type oscillator substrate S1 equipped with a microwave transistor 1 for generating negative resistance by short-duration operation and a resonant cavity structure, a high-frequency pulse signal of an oscillation frequency / frequency bandwidth determined based on negative resistance produced by the short-duration operation of the microwave transistor 1 and the resonant cavity structure is generated as a transmitted RF signal and simultaneously radiated into space, and the radiation type oscillator is caused to perform oscillating operation when a received RF signal arriving from an external wireless communication device enters the radiation type oscillator, whereby a received data signal is established based on acquisition of an IF signal owing to mixing by the radiation type oscillator itself.

The invention belongs to the technical field of nuclear fusion plasma microwave diagnosis and in particular relates to a broadband low-loss high-frequency microwave modulator based on a rectangular waveguide and a broadband amplitude modulation millimeter wave reflection system based on the waveguide modulator. A quartz crystal oscillator B is connected with a power amplifier; the power amplifier is connected with an intermediate frequency input end of the waveguide modulator; a microwave source is connected with a microwave input end of the waveguide modulator; the waveguide modulator is connected with a microwave amplifier; the microwave amplifier is connected with a horn antenna; a microwave detector is connected with a frequency-selecting amplifier; the frequency-selecting amplifier is connected with a down converter A; the quartz crystal oscillator B is also connected with a down converter B; a quartz crystal oscillator A is respectively connected with the down converter A and the down converter B; the down converter A is connected with a band-pass filter A; the band-pass filter A is connected with a phase discriminator; the down converter B is connected with a band-pass filter B; the band-pass filter B is connected with the phase discriminator. According to the system, low-loss ultrahigh-frequency microwave amplitude modulation can be realized.

A reception frequency band is selected at 11.7 GHz–12.2 GHz, the local oscillating frequencies of local oscillators are determined at 10.75 GHz and 13.85 GHz, respectively, and each intermediate frequency band is selected at 950 MHz–1450 MHz and 1650 MHz–2150 MHz, respectively, so that the harmonic component of the frequency difference between local oscillation signals output from each local oscillator is not present in the frequency band of each intermediate frequency signal output from each mixer and in the reception band of polarization signals applied to input terminals.

The invention relates to a method for detecting and / or processing signal waves that produce charge carriers in an article sensitive to the signal waves, said charge carriers inducing a signal current in at least one readout electrode. At least two modulation electrodes are provided, at least one of which is disposed in the proximity of the at least one readout electrode or to another readout electrode in such a manner that, depending on the polarity sign of the modulation volatage of the respective modulation electrode, the current flowing across the associated readout electrode is positive or negative. The invention further relates to a device for detecting and processing signal waves. Said device comprises an OEP article that is sensitive to the signal waves, in which article the signal waves produce charge carriers, and at least one readout electrode (AK) that is linked with the charge carrier range of the article. At least two modulation electrodes (MKa, MKb) are provided, at least one of which is disposed in the proximity of the at least one readout electrode (AK) and the other in the proximity either of the same readout electrode (AK) or of another readout electrode (AK2). The aim of the invention is to provide a method and a device that is capable of interlinking various optical and / or electronic signals in a logically digital or analogous manner or to detect the course of optical signals by scanning (time interval measurements). For this purpose, the modulation electrodes are modulated with relatively freely selectable voltage amplitude and / or phase relation, whereby the readout currents produced by the modulation voltages of the two modulation electrode are additively coupled. The inventive device is characterized in that the modulation electrodes are disposed relative to the readout electrode(s) in such a manner that, depending on the polarity sign of the modulation voltages of the respective modulation electrode, the current flowing across the associated readout electrode is positive or negative and that at least one device is provided by which the relative phase relation and / or the voltage amplitude of the two modulation voltages can be freely adjusted.

A mixer, which is a single balanced mixer, includes an LO port for inputting an LO signal, an RF port for inputting an RF signal, an IF port for outputting an IF signal, a balun for converting an unbalanced signal into a balanced signal, and a pair of mixer diodes connected in series. The mixer further includes a high-pass filter for blocking LO and IF signals and passing an RF signal and a low-pass filter for blocking LO and RF signals and passing an IF signal.

A first rectangular groove having a rectangular cross section and a second rectangular groove substantially orthogonal to the first rectangular groove and having a rectangular cross section are formed in a first silicon substrate. A third rectangular groove located at a position facing the first rectangular groove and having a rectangular cross section is formed on a second silicon substrate. A device substrate including a frequency conversion device is provided in the second rectangular groove, so that the frequency conversion device is located where the first and second rectangular grooves are orthogonal to each other. Further, the first silicon substrate on which the device substrate is located is bonded to the second silicon substrate, so that the first rectangular groove opposes the third rectangular groove, forming a rectangular waveguide which includes the first rectangular groove and the third rectangular groove, and in which a received high frequency signal propagates and is incident on the frequency conversion device.

A mixer used in a millimeter-wave band and a microwave band capable of achieving loss reduction, a radar module, and a communication apparatus incorporating the mixer and having high efficiency. The mixer includes two electrodes formed on one main surface of a dielectric substrate and another electrode formed on another main surface thereof such that non-electrode portions on both main surfaces are opposed to each other via the dielectric substrate. Additionally, a diode is connected bridging a slit between the two electrodes on one main surface to constitute a circuit board. The circuit board and a dielectric strip are arranged between upper and lower conductive plates.

Disclosed is a NRD waveguide mixer adopting a ring hybrid coupler applicable to a small-sized and high functional millimeter wave receiving / transmitting device. The NRD waveguide has a housing including two parallel conductive plates. The ring hybrid coupler is installed in the housing and has an annular ring formed with first to fourth ports which are radially extended about the annular ring. An oscillating device is connected to the first port so as to generate a local oscillating signal. A rod antenna is connected to the second port so as to receive / transmit a radio frequency signal. A first balanced mixer mount is connected to the third port and is provided with a first Schottky diode. A second balanced mixer mount is connected to the fourth port and is provided with a second Schottky diode. The radio frequency signal and the oscillating signal inputted from the first and second ports are mixed in the ring hybrid coupler to be transformed into an addition signal and a subtraction signal. The addition and subtraction signals are transmitted to the third and fourth ports to switch the Schottky diodes respectively so that an intermediate signal is generated.

A line coupling structure for coupling a dielectric waveguide to a suspended line has the dielectric waveguide including dielectric strips and two conductor plates that are approximately parallel to each other, the dielectric strips and a circuit board being sandwiched between the conductor plates. The line coupling structure also has the suspended line including the conductor plates and a conductor pattern on the circuit board. The conductor pattern is arranged in a direction that is substantially perpendicular to the dielectric strips. A protruding conductor pattern that extends in the extending direction of the dielectric strips is provided at a crossing position of the conductor pattern and the dielectric strips.

A demodulator for near field communication is provided. The demodulator for near field communication may include: a scale down circuit configured to receive first and second modulated signals from first and second power electrodes, and configured to provide a scale down signal to a first node by scaling down magnitudes of the first and second modulated signals; a current source coupled between the first node and a ground voltage, and configured to generate a constant current flowing from the first node to the ground voltage; a charge store circuit coupled between the first node and ground voltage, and configured to perform charge and discharge operations alternately, based on the scale down signal and constant current, to output an envelope signal, which corresponds to an envelope of the scale down signal; and / or an edge detector configured to generate input data, which correspond to the first and second modulated signals, based on a transition of the envelope signal.

A multifunction high frequency integrated circuit structure and circuit configuration includes a resonator or oscillator circuit coupled to a buffer amplifier by way of a stripline coupler. The resonator circuit includes an input terminating region which is coupled to three input terminating ports. A first one of the input terminating ports is coupled directly to the resonator for either being electrically connected to a selected signal source or load, a second one of the input terminating ports is electrically connected to either a fixed or variable potential source, and the remaining input terminating port is coupled to the resonator input terminating region through another stripline coupler, and is intended to be electrically connected to another selected signal source. Depending upon the choice of circuit components and signal sources connected to the input terminating ports, the multifunction high frequency integrated circuit may serve as a voltage controlled oscillator, low phase noise oscillator, direct up / down frequency signal converter, or injection locked oscillator.