Method for establishing communication for wireless device, and wireless device
The method enhances wireless communication by using omnidirectional and directional antennas to estimate signal direction, reducing overhead and power consumption in cellular systems.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- NAT INST OF INFORMATION & COMM TECH
- Filing Date
- 2025-12-12
- Publication Date
- 2026-07-02
AI Technical Summary
Cellular wireless communication systems face high communication overhead and power consumption due to the need to transmit signals in multiple directions to detect the location of wireless terminals, as directional antennas cannot accurately determine the terminal's direction.
A communication establishment method using an omnidirectional or quasi-omnidirectional antenna for initial signal transmission, followed by signal direction estimation with an array antenna, and subsequent directional transmission of system information using a directional antenna, reducing unnecessary signal transmissions.
Significantly reduces communication overhead and power consumption by minimizing redundant signal transmissions and optimizing directional communication.
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Figure JP2025043477_02072026_PF_FP_ABST
Abstract
Description
Method for establishing communication in a wireless device and wireless device
[0001] This disclosure relates to communication establishment technology in wireless devices.
[0002] Currently, cellular wireless communication systems are used not only for voice calls but also for a wide variety of services that utilize information and communication. Furthermore, cellular wireless communication systems are also used in industrial fields for applications such as remote control of various sensors and industrial machinery. On the other hand, wireless LANs (Local Area Networks), which were developed to easily connect personal computers and other devices to a network, are also used for a wide variety of services. Thus, although there are differences in the location and application of use, cellular wireless communication systems and wireless LANs have become indistinguishable in terms of the use of services that utilize information and communication.
[0003] Regarding cellular wireless communication systems, "NR Physical Layer Specifications in 5G" (Non-Patent Document 1) and "5G Textbook - From LTE / IoT to 5G -" (Non-Patent Document 2) disclose the standard specifications for cellular wireless communication defined by 3GPP®. In these standard specifications for cellular wireless communication, a radio base station uses a directional antenna to transmit a signal containing a synchronization signal and information for connecting to the radio base station in various directions where a terminal may be located. A terminal that receives the signal containing the synchronization signal and information for connecting to the radio base station transmits a connection request signal. When a radio base station receives a connection request signal and determines that it is appropriate for the terminal to connect, it is stipulated that it will perform a connection procedure with the terminal and enable the transmission and reception of communication data.
[0004] Takeda, et al., "NR Physical Layer Specifications in 5G," NTT DoCoMo Technical Journal, vol. 26, no. 3, pp. 4758, Nov. 2018. (https: / / www.docomo.ne.jp / binary / pdf / corporate / technology / rd / technical_journal / bn / vol26_3 / vol26_3_008jp.pdf) Hattori, Fujioka, "5G Textbook - From LTE / IoT to 5G," Impress Publishing, 2018.
[0005] According to the technologies disclosed in Non-Patent Documents 1 and 2, wireless devices such as wireless base stations and access points can detect the presence of a terminal by receiving a connection request signal, but cannot detect the direction in which the terminal exists as seen from the wireless device. Therefore, the wireless device needs to sequentially transmit signals including information for connecting to the wireless device to various directions in which the terminal may exist by using a directional antenna. As a result, the wireless device will transmit signals many times using the directional antenna. Accordingly, the communication overhead and power consumption in the wireless device also increase. Therefore, there is a need for a technology for reducing the communication overhead and power consumption in the wireless device.
[0006] The present disclosure has been made in view of the above background, and an object in one aspect is to provide a technology for reducing the communication overhead and power consumption in a wireless device.
[0007] According to an embodiment, a communication establishment method between a first wireless device and a second wireless device is provided. The communication establishment method includes: the first wireless device transmitting a first signal including a synchronization signal using an omnidirectional or quasi-omnidirectional antenna; the second wireless device transmitting a second signal based on receiving the first signal; the first wireless device estimating the arrival direction of the second signal based on receiving the second signal using an array antenna; the first wireless device transmitting a third signal including system information toward the arrival direction of the second signal using a directional antenna; and the second wireless device transmitting a fourth signal for establishing wireless communication between the first wireless device and the second wireless device based on receiving the third signal.
[0008] In one aspect, the second wireless device transmitting a second signal based on receiving the first signal includes: receiving the first signal using an array antenna and estimating the arrival direction of the first signal; and transmitting the second signal toward the arrival direction of the first signal using a directional antenna.
[0009] In a certain scenario, receiving a second signal using an array antenna by a first radio device includes performing a detection process for the reception of the second signal within a predetermined period after the transmission of the first signal.
[0010] In certain situations, the first and second signals are signals generated by modulating a baseband signal based on a pseudo-random sequence.
[0011] According to one embodiment, a wireless device is provided. The wireless device comprises an omnidirectional or quasi-omnidirectional first antenna for transmitting a first signal including a synchronization signal; a second antenna which is an array antenna for receiving a second signal from a wireless terminal; a signal detection unit for estimating the direction of arrival of the second signal; and a third antenna which is a directional antenna for transmitting a third signal including system information in the direction of arrival of the second signal and receiving a fourth signal for establishing wireless communication from a wireless terminal.
[0012] In a certain scenario, receiving a second signal from a wireless terminal includes performing a detection process for the reception of the second signal within a predetermined period after the transmission of the first signal.
[0013] According to one embodiment, it is possible to reduce the communication overhead and power consumption in wireless devices.
[0014] The above and other purposes, features, aspects and advantages of this disclosure will become apparent from the following detailed description of this disclosure, which will be understood in conjunction with the attached drawings.
[0015] This figure shows a first example of a procedure for establishing communication between a first wireless device 10 and a second wireless device 20 according to this embodiment. This figure shows an example of a pseudo-random sequence. This figure shows an example of the detection process for a pseudo-random sequence included in the first signal 102 in the second wireless device 20. This figure shows an example of the reception process for the first signal 102 and the transmission process for the second signal 104 in the second wireless device 20. This figure shows an example of the estimation process for the direction of arrival 106 of the second signal 104 in the first wireless device 10. This figure shows an example of a procedure for establishing communication including a fourth signal 110. This figure shows a second example of a procedure for establishing communication between a first wireless device 10 and a second wireless device 20. This figure shows an example of the configuration of the first wireless device 10. This figure shows an example of the configuration of the second wireless device 20. This figure shows an example of the configuration of the array antenna 500 of the first wireless device 10. This figure shows an example of the pseudo-random sequence generator 1100 provided in the first wireless device 10 and the second wireless device 20. This figure shows an example of the operation flow of the first wireless device 10. This figure shows an example of the operation flow of the second wireless device 20.
[0016] The embodiments of the technical concept relating to this disclosure will be described below with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed descriptions of them will not be repeated. Furthermore, each embodiment, each modification, each software or program configuration, each hardware configuration, each function, and each process may be selectively combined as appropriate.
[0017] <Application Example> Figure 1 shows a first example of a procedure for establishing communication between a first wireless device 10 and a second wireless device 20 according to this embodiment. The technology of this disclosure can reduce the communication overhead in at least one wireless device when establishing communication between wireless devices. Furthermore, the technology of this disclosure can reduce the power consumption in at least one wireless device when establishing communication between wireless devices.
[0018] The technologies disclosed herein are applicable to cellular wireless communication systems, wireless LAN systems, and any other wireless systems. In this specification, “wireless device” includes base stations in cellular wireless communication systems, access points, routers, and any other wireless relay devices in wireless LANs. “Wireless device” also includes any information processing terminals such as personal computers, smartphones, tablets, wearable computers, and IoT (Internet of Things) devices.
[0019] Referring to Figure 1, the technology of this disclosure will be explained using the procedure for establishing communication between the first wireless device 10 and the second wireless device 20 as an example. The first wireless device 10 is a signal relay device such as a base station or access point. The second wireless device 20 is an information processing terminal such as a smartphone.
[0020] In step S110, the first radio device 10 periodically transmits a first signal 102. More specifically, the first radio device 10 transmits the first signal 102 using an omnidirectional or semi-omnidirectional antenna. That is, the first radio device 10 transmits the first signal 102 in all directions. As another example, the first radio device 10 may transmit the first signal 102 over a wider range than that covered by a directional antenna, rather than in all directions. The first signal 102 includes a signal called a pseudo-random sequence. The pseudo-random sequence will be explained in detail with reference to Figure 2. The first signal 102 can notify other radio devices present around the first radio device 10 of its presence. The first signal 102 is sometimes called a synchronization signal. If other radio devices are present within range of the first signal 102, the first radio device 10 may receive a response signal from the other radio devices.
[0021] In step S120, the second radio device 20 transmits the second signal 104 based on having received the first signal 102. The second signal 104 is a response signal to the first signal 102. More specifically, the second radio device 20 transmits the second signal 104 via an omnidirectional or quasi-omnidirectional antenna. The second signal 104 also includes a pseudo-random sequence. The second signal 104 is sometimes called a discovery signal. Next, the first radio device 10 receives the second signal 104. More specifically, the first radio device 10 receives the second signal 104 via an array antenna 500 (see Figures 5 and 10). The first radio device 10 then analyzes the second signal 104 received by the array antenna 500 and estimates the direction of arrival 106 of the second signal 104. The direction of arrival 106 of the second signal 104 is the direction from which the second radio device 20 is presumed to be located, as viewed from the first radio device 10.
[0022] In step S130, the first radio device 10 transmits the third signal 108 in the direction 106 from which the second signal 104 is coming. More specifically, the first radio device 10 transmits the third signal 108 in the direction 106 from which the second signal 104 is coming via a directional antenna. The first radio device 10 includes a plurality of directional antennas facing in different directions from each other. Each directional antenna covers a range within a certain angle from the center of the signal transmission direction of each directional antenna as the transmission range, reception range, or transmission / reception range of radio waves. The coverage range of each directional antenna is determined based on the hardware design, program design, or both of the directional antenna. Generally, directional antennas emit stronger radio waves in a specific direction compared to omnidirectional antennas. By including a plurality of directional antennas facing in different directions from each other, the first radio device 10 can cover a wide and long-distance communication range. The third signal 108 may contain information called a System Information Block (SIB). SIB may include base station ID (Identifier) and radio frame information, etc.
[0023] In step S140, the second radio device 20 transmits a fourth signal 110 based on having received the third signal 108. The fourth signal 110 is a signal for initial connection setup. The second radio device 20 may transmit the fourth signal 110 via an omnidirectional antenna. Alternatively, the second radio device 20 may transmit the fourth signal 110 via a directional antenna. Based on having received the fourth signal 110, the first radio device 10 establishes communication with the second radio device 20 by exchanging further signals.
[0024] In conventional cellular wireless communication systems, base stations had to transmit signals including SIB (corresponding to the third signal 108) multiple times. For example, suppose a base station (corresponding to the first radio device 10) receives a discovery signal (corresponding to the second signal 104) from a terminal (corresponding to the second radio device 20). In this case, the base station could not detect the direction of arrival of the discovery signal or the location of the terminal. Therefore, the base station activated each of its multiple directional antennas in sequence and transmitted signals including SIB in multiple directions. For example, suppose a base station is equipped with first to tenth directional antennas. In this case, the base station activates the first to tenth directional antennas in sequence and repeatedly transmits signals including SIB. That is, the base station transmits signals including SIB many times while changing the transmission direction of the signals including SIB. Therefore, the communication overhead and power consumption at the base station were large when transmitting signals including SIB.
[0025] In contrast, in the technology of this disclosure, the first wireless device 10 estimates the direction of arrival of the second signal 104 by analyzing the second signal 104 received by the array antenna 500. Therefore, the first wireless device 10 only needs to transmit the third signal 108, including the SIB, once in the direction of arrival of the second signal 104. As a result, the communication overhead and power consumption of the first wireless device 10 can be significantly reduced compared to the prior art.
[0026] As described above, the advantages of the technology disclosed herein over existing cellular wireless communication technologies have been explained. The technology disclosed herein is applicable to any wireless communication system other than cellular wireless communication systems. For example, the technology disclosed herein is applicable to any wireless system that can use a directional antenna, such as a wireless LAN.
[0027] As described above with reference to Figure 1, the present disclosure provides a method for establishing communication between wireless devices. The method for establishing communication includes the first wireless device 10 transmitting a first signal 102, which includes a synchronization signal, using an omnidirectional or quasi-omnidirectional antenna. The method for establishing communication also includes the second wireless device 20 transmitting a second signal 104 based on having received the first signal 102. The method for establishing communication also includes the first wireless device 10 estimating the direction of arrival 106 of the second signal based on having received the second signal 104 using an array antenna. The method for establishing communication also includes the first wireless device 10 transmitting a third signal 108, which includes system information, towards the direction of arrival 106 of the second signal using a directional antenna. Furthermore, the method for establishing communication also includes the second wireless device 20 transmitting a fourth signal 110 to establish wireless communication between the first wireless device 10 and the second wireless device 20 based on having received the third signal 108.
[0028] <Processing performed by each wireless device> Figure 2 shows an example of a pseudo-random sequence. A pseudo-random sequence, also called a pseudo-random signal, is a random number that repeats at a fixed period. That is, a "pseudo-random sequence" is a bit sequence consisting of "0s and 1s" with a finite period. As explained with reference to Figure 1, the first signal 102 and the second signal 104 include pseudo-random sequences. The fourth signal 110 may also include a pseudo-random sequence. Pseudo-random sequences are used to improve the processing gain, which will be explained with reference to Figure 3.
[0029] The pseudo-random sequence is generated by a pseudo-random sequence generator 1100 (see Figure 11). The first radio device 10 and the second radio device 20 are equipped with the pseudo-random sequence generator 1100 as hardware or program. The first radio device 10 can generate the first signal 102 by converting the pseudo-random sequence into a baseband signal and modulating the baseband signal. The second radio device 20 can generate the second signal 104 by a similar procedure. In the example in Figure 2, the first radio device 10 generates the first signal 102 from the pseudo-random sequence 200.
[0030] Pseudorandom sequences can be generated using M sequences, Zadoff-Chu sequences, or other known methods. The pseudorandom sequence generator 1100 shown in Figure 11 is an M sequence generator equipped with 14 shift registers. The first wireless device 10 can obtain a pseudorandom sequence with a repeat length of 16383 bits by assigning initial values (excluding all zeros) to each shift register of the pseudorandom sequence generator 1100 and shifting each shift register. The pseudorandom sequence generator 1100 may be equipped with any number of shift registers other than 14. The pseudorandom sequence generator 1100 may also generate pseudorandom sequences using Zadoff-Chu sequences or other known methods.
[0031] As explained with reference to Figure 2, the first signal 102 and the second signal 104 are signals generated by modulating a baseband signal based on a pseudo-random sequence. The pseudo-random sequences included in the first signal 102 and the second signal 104 may be the same or different.
[0032] Figure 3 shows an example of the detection process for a pseudo-random sequence contained in the first signal 102 in the second wireless device 20. The method for generating the pseudo-random sequence 200 is shared between the first wireless device 10 and the second wireless device 20. Therefore, both the first wireless device 10 and the second wireless device 20 can generate the same pseudo-random sequence.
[0033] The second wireless device 20 compares the first signal 102 received from the first wireless device 10 with the signal 302 generated by the second wireless device 20 and calculates the difference. If the difference is less than or equal to a predetermined threshold, the second wireless device 20 can determine that the first signal 102 is the expected received signal. In other words, the second wireless device 20 can determine that the first signal 102 is the signal from the first wireless device 10. Alternatively, the second wireless device 20 may compare the first signal 102 received from the first wireless device 10 with the signal 302 generated by the second wireless device 20 and calculate the similarity. In this case, if the similarity is greater than or equal to a predetermined threshold, the second wireless device 20 can determine that the first signal 102 is the expected received signal. In other words, the second wireless device 20 can determine that the first signal 102 is the signal from the first wireless device 10. As an example, the second wireless device 20 may perform a sum-of-products operation on the first signal 102 and signal 302. In this case, the second wireless device 20 may multiply the absolute values of the sum-of-products of each bit and compare the multiplication result with a threshold. This comparison process is sometimes called "correlation detection" because it calculates a correlation value. The length 300 of the bit information to be compared is set to a length within a range where the phase shift due to frequency error can be ignored. Correlation detection may also be a comparison of modulated signals. Alternatively, correlation detection may be a comparison of pseudo-random sequences contained in each signal. The length 300 of the bit information may include the signal length, the signal sequence length, and the pseudo-random sequence length.
[0034] Here, we will explain "processing gain." Processing gain refers to improving the signal-to-noise ratio (SNR) between the source signal and the received signal. In the example in Figure 3, the processing gain includes improving the SNR between the first signal 102 and the generated signal 302. Wireless signals are subject to noise during transmission. Therefore, the source signal and the received signal do not necessarily match. In particular, signals transmitted by an omnidirectional antenna are prone to noise because they lack directional gain. Therefore, the first wireless device 10 transmits a first signal 102 containing multiple bits of information (i.e., a pseudo-random sequence). The second wireless device 20 then compares the multiple bits of information contained in the received first signal 102 with the multiple bits of information contained in the signal 302 it generated and performs correlation detection. In this way, even if a part of the first signal 102 changes during transmission, the second wireless device 20 can determine through correlation detection that the first signal 102 is the expected received signal or the signal from the first wireless device 10.
[0035] Figure 4 shows an example of the reception processing of the first signal 102 and the transmission processing of the second signal 104 in the second wireless device 20. The signal detection unit 908 (see Figure 9) performs a detection process for the received signal and determines whether or not it has received or detected the first signal 102. Based on its determination that it has received or detected the first signal 102, the signal detection unit 908 outputs a detection notification 400 for the first signal 102 to the wireless protocol control unit 900 (see Figure 9). The signal detection unit 908 can determine whether or not the received signal is the first signal 102 by correlation detection, as explained with reference to Figure 3.
[0036] Based on the acquisition of the detection notification 400, the wireless protocol control unit 900 outputs a command 410 for generating the second signal 104 to the signal generation unit 910 (see Figure 9). The wireless protocol control unit 900 outputs the command 410 for generating the second signal 104 within a predetermined period 415. The predetermined period 415 may be within a certain period after the reception of the first signal 102. Alternatively, the predetermined period 415 may be set to any period within the interval 418 between the time the second wireless device 20 receives the first signal 102 and the time it receives the first signal 102 again.
[0037] The signal generation unit 910 generates a pseudo-random sequence 420 using a pseudo-random sequence generator 1100. The signal generation unit 910 outputs the pseudo-random sequence 420 to the first baseband signal generation unit 912 (see Figure 9).
[0038] The first baseband signal generation unit 912 converts the pseudo-random sequence 420 into a continuous baseband signal 430 having a predetermined amplitude and phase. The first baseband signal generation unit 912 outputs the generated baseband signal 430 to the radio unit 904.
[0039] The radio unit 904 modulates the acquired baseband signal 430 and includes the baseband signal 430 in the carrier wave 440. The "carrier wave" is a high-frequency signal transmitted and received via the antenna. Hereafter, the carrier wave may also be simply referred to as the signal. In the example in Figure 4, the carrier wave 440 is the second signal 104, which includes the pseudo-random sequence 420. The radio unit 904 transmits the carrier wave 440 as the second signal 104 via the antenna 902. The second signal 104 is a response to the first signal 102. The antenna 902 may be an omnidirectional antenna or a directional antenna.
[0040] The first wireless device 10 performs the reception process for the second signal 104 within a predetermined period 415 after transmitting the first signal 102. That is, the first wireless device 10 activates the configuration related to receiving the second signal 104 within a predetermined period 415. Conversely, at any other time, the first wireless device 10 may disable some or all of the configuration related to receiving the second signal 104. For example, the first wireless device 10 can activate or disable each configuration by controlling the on / off switching of the power supply for each configuration. This allows the first wireless device 10 to reduce the power consumption required for the reception process of the second signal 104. The configuration related to receiving the second signal 104 includes the second wireless unit 812 (see Figure 8), the first baseband signal processing unit 814 (see Figure 8), and the signal detection unit 816 (see Figure 8), etc.
[0041] As explained with reference to Figure 4, the second radio device 20 transmits the second signal 104 within a predetermined period 415 after receiving the first signal 102. In other words, the reception of the second signal 104 by the first radio device 10 using an array antenna includes performing a detection process for the reception of the second signal 104 within a predetermined period 415 after the transmission of the first signal 102.
[0042] Figure 5 shows an example of the estimation process for the direction of arrival 106 of the second signal 104 in the first wireless device 10. The first wireless device 10 receives the second signal 104 via the second antenna 810. The second antenna 810 is an array antenna 500. The first wireless device 10 can estimate the direction of arrival 106 of the second signal 104 using algorithms such as the MUSIC (Multiple Signal Classification) method or the ESPRIT (Estimation of Signal Parameter via Rotational Invariance Techniques) method. The direction of arrival 106 of the second signal 104 is represented by a combination of azimuth angle 502 and elevation angle 504. The first wireless device 10 estimates the direction of arrival 106 of the second signal 104 as a combination of azimuth angle 502 and elevation angle 504 such that the signal strength is above a predetermined threshold. Signal strength refers to the radio wave strength of the wireless signal received by the wireless device.
[0043] Graph 510 shows the signal strength for each arrival direction 106 of the second signal 104 received by the first wireless device 10. More specifically, graph 510 shows the signal strength of the second signal 104 for each combination of azimuth angle 502 and elevation angle 504. According to graph 510, the signal strength from the direction of azimuth angle 502 and elevation angle 504 (25, 40) (referred to as the "first direction") is high compared to the signal strength from other directions. Similarly, the signal strength from the direction of azimuth angle 502 and elevation angle 504 (-20°, 20°) (referred to as the "second direction") is high compared to the signal strength from other directions. For example, assume that a predetermined threshold value is "-19.6 dB". In this case, the signal strength in the first direction and the signal strength in the second direction exceed the predetermined threshold value. Therefore, the first wireless device 10 is receiving the second signal 104 from two directions. If there are multiple second wireless devices 20 within the communication range of the first wireless device 10, the first wireless device 10 may receive the second signal 104 from multiple directions.
[0044] In this way, when receiving the second signal 104, the first wireless device 10 estimates the arrival direction 106 of the second signal 104. Thereby, the first wireless device 10 may transmit the third signal 108 only to the arrival direction 106 of the second signal 104 via the directional antenna. Therefore, the communication method of the present disclosure can reduce the number of transmissions of the third signal 108 compared to the search light method of sequentially transmitting the third signal 108 omnidirectionally, which is a conventional technique. As a result, the communication method of the present disclosure can reduce the communication overhead and power consumption in the transmission of the third signal 108 compared to the search light method. Furthermore, the communication method of the present disclosure can establish communication between the first wireless device 10 and the second wireless device 20 in a shorter time compared to the search light method.
[0045] FIG. 6 is a diagram showing an example of a communication establishment procedure including the fourth signal 110. Based on receiving the third signal 108, the second wireless device 20 transmits the fourth signal 110 for communication establishment to the first wireless device 10. Transmitting the fourth signal 110 to the first wireless device 10 may include the following steps S610 to S650 as an example.
[0046] In step S610, the second wireless device 20 transmits a random access signal to the first wireless device 10. In step S620, the first wireless device 10 transmits a response to the random access signal to the second wireless device 20. In step S630, the second wireless device 20 transmits a message including the terminal ID to the first wireless device 10. In step S640, the first wireless device 10 transmits a message including the acknowledgement of the terminal ID and the assignment of the connection ID to the second wireless device 20. In step S650, the first wireless device 10 and the second wireless device 20 exchange messages including information regarding upper layer procedures, authentication, encryption, etc.
[0047] As an example, the fourth signal 110 may be the random access signal in step S610. In this case, the communication processes after step S620 are a series of communication processes following the fourth signal 110. Also, transmitting the fourth signal 110 may include the communication processes in steps S610 to S650.
[0048] FIG. 7 is a diagram showing a second example of the communication establishment procedure between the first wireless device 10 and the second wireless device 20. The second example of the communication establishment procedure is different from the first example of the communication establishment procedure in that the second wireless device 20 estimates the arrival direction of the first signal 102. In the second example of the communication establishment procedure, the second wireless device 20 includes an array antenna and a directional antenna.
[0049] In step S710, the first wireless device 10 periodically transmits the first signal 102. Next, the second wireless device 20 receives the first signal 102 via the array antenna. The second wireless device 20 estimates the arrival direction 702 of the first signal 102. As an example, the second wireless device 20 may estimate the arrival direction 702 using the method described with reference to FIG. 5, etc. The arrival direction 702 of the first signal 102 is the direction in which the first wireless device 10 is presumed to exist as seen from the second wireless device 20.
[0050] In step S720, the second radio device 20 transmits the second signal 104 in the direction of arrival 702 via a directional antenna. Thus, in the communication establishment procedure shown in Figure 7, the second radio device 20 estimates the direction of arrival 702 of the first signal 102 and transmits the second signal 104 in the direction of arrival 702. The processes in steps S730 and S740 are identical to the processes in steps S130 and S140, respectively, and therefore will not be repeated in their description. The second radio device 20 may correspond to either the first example of the communication establishment procedure or the second example of the communication establishment procedure. Alternatively, the second radio device 20 may correspond to both communication establishment procedures.
[0051] As explained with reference to Figure 7, the second radio device 20 transmits a second signal 104 based on the reception of the first signal 102. Transmitting the second signal 104 may include receiving the first signal 102 using an array antenna and estimating the direction of arrival 702 of the first signal 102. Transmitting the second signal 104 may also include transmitting the second signal 104 in the direction of arrival 702 of the first signal 102 using a directional antenna.
[0052] In the second example of the communication establishment procedure, the second radio device 20 transmits the second signal 104 using a directional antenna. As a result, the directional gain of the second signal 104 is higher than when transmitted with an omnidirectional antenna, and it can propagate over longer distances. In addition, since the second radio device 20 transmits the second signal 104 only in the direction of arrival 702, the transmission power of the second signal 104 can be reduced compared to when an omnidirectional antenna is used.
[0053] <Configuration of each wireless device> Figure 8 shows an example of the configuration of the first wireless device 10. Each configuration shown in Figure 8 may be implemented as hardware. In addition, parts of each configuration shown in Figure 8 may be implemented as a program.
[0054] The first wireless device 10 includes a wireless protocol control unit 800. The wireless protocol control unit 800 controls the operation of the entire first wireless device 10 and controls the overall communication as shown in Figures 1 and 7.
[0055] The first wireless device 10 comprises a signal generation unit 802, a first baseband signal generation unit 804, a first wireless unit 806, and a first antenna 808. These components are mainly used for transmitting the first signal 102. More specifically, the signal generation unit 802 generates a pseudo-random sequence to be included in the first signal 102 and outputs the pseudo-random sequence to the first baseband signal generation unit 804. The first baseband signal generation unit 804 converts the acquired pseudo-random sequence into a continuous baseband signal having predetermined amplitude and phase. The first baseband signal generation unit 804 outputs the generated baseband signal to the first wireless unit 806. The first wireless unit 806 modulates the acquired baseband signal and includes the baseband signal in a carrier wave. The first wireless unit 806 transmits the carrier wave as the first signal 102 via the first antenna 808.
[0056] The first wireless device 10 comprises a second antenna 810, a second wireless unit 812, a first baseband signal processing unit 814, and a signal detection unit 816. These components are primarily used for receiving the second signal 104. More specifically, the second wireless unit 812 receives the second signal 104 via the second antenna 810. The second wireless unit 812 demodulates the second signal 104 to generate a baseband signal. The second wireless unit 812 outputs the baseband signal of the second signal 104 to the first baseband signal processing unit 814. The first baseband signal processing unit 814 converts the acquired baseband signal into a pseudo-random sequence. That is, the first baseband signal processing unit 814 converts the acquired baseband signal into bit sequence information. The first baseband signal processing unit 814 outputs the generated pseudo-random sequence to the signal detection unit 816. The signal detection unit 816 determines whether or not the second signal 104 has been received or detected. Based on its determination that it has received or detected the second signal 104, the signal detection unit 816 outputs a detection notification of the second signal 104 to the wireless protocol control unit 800. The signal detection unit 816 may also perform correlation detection by comparing a pseudo-random sequence obtained from the second signal 104 with a pseudo-random sequence generated by the signal detection unit 816. The signal detection unit 816 also estimates the direction of arrival 106 of the second signal 104. The signal detection unit 816 outputs the estimated direction of arrival 106 of the second signal 104 to the wireless protocol control unit 800.
[0057] Based on receiving notification of the detection of the second signal 104, the wireless protocol control unit 800 outputs a command to the transmission data generation unit 818 to transmit the third signal 108. This command includes information on the direction of arrival 106 of the second signal 104. The wireless protocol control unit 800 may estimate the direction of arrival 106 of the second signal 104 instead of the signal detection unit 816. The wireless protocol control unit 800 may enable the second antenna 810, the second radio unit 812, the first baseband signal processing unit 814, and the signal detection unit 816 for a predetermined period 415 after the transmission of the first signal 102. For example, the wireless protocol control unit 800 may turn on the power to these components for a predetermined period 415. The wireless protocol control unit 800 may turn off the power to these components or put them into power-saving mode during other periods.
[0058] Furthermore, the first wireless device 10 includes a transmission data generation unit 818, a second baseband signal generation unit 820, a third wireless unit 822, a third antenna 824, a second baseband signal processing unit 826, and a reception data processing unit 828. These components are mainly used for receiving the third signal 108, transmitting the fourth signal, and subsequent communication.
[0059] More specifically, the transmission data generation unit 818 generates data to be included in the third signal 108. The transmission data generation unit 818 also generates arbitrary data to be transmitted to the second radio device 20 after receiving the fourth signal 110. The transmission data generation unit 818 outputs the generated data to the second baseband signal generation unit 820. The second baseband signal generation unit 820 generates a baseband signal from the acquired data based on predetermined frequencies and amplitudes. The second baseband signal generation unit 820 outputs the generated baseband signal to the third radio unit 822. The third radio unit 822 modulates the acquired baseband signal and includes the baseband signal in the carrier wave. The third radio unit 822 transmits the carrier wave via the third antenna 824. The carrier wave includes the third signal 108 or other arbitrary signals.
[0060] Furthermore, the third radio unit 822 acquires a signal via the third antenna 824. The third radio unit 822 demodulates the acquired signal to generate a baseband signal. The third radio unit 822 outputs the generated baseband signal to the second baseband signal processing unit 826. The second baseband signal processing unit 826 converts the acquired baseband signal into a bit sequence. The second baseband signal processing unit 826 outputs the converted bit sequence to the received data processing unit 828. The bit sequence may include a pseudo-random sequence, user data, control data, etc. If the acquired bit sequence is a pseudo-random sequence, the received data processing unit 828 performs a detection process such as correlation detection on the bit sequence and outputs the result of the detection process to the radio protocol control unit 800. If the acquired bit sequence is user data or control data, etc., the received data processing unit 828 outputs the bit sequence to the radio protocol control unit 800.
[0061] The first antenna 808 is an omnidirectional or quasi-omnidirectional antenna. The second antenna 810 is an array antenna. The first antenna 808 may also be an array antenna. The first antenna 808 and the second antenna 810 may be configured as a single transmitting and receiving array antenna. The third antenna 824 is composed of multiple directional antennas or an array antenna capable of forming a desired directivity.
[0062] As described with reference to Figure 8, the first wireless device 10 includes an omnidirectional or quasi-omnidirectional first antenna 808 for transmitting a first signal 102 including a synchronization signal, a second antenna 810 which is an array antenna for receiving a second signal 104 from a wireless terminal, a signal detection unit 816 for estimating the direction of arrival 106 of the second signal 104, and a third antenna 824 which is a directional antenna for transmitting a third signal 108 including system information toward the direction of arrival 106 of the second signal 104 and for receiving a fourth signal 110 for establishing wireless communication from a wireless terminal.
[0063] Furthermore, receiving the second signal 104 from the wireless terminal includes performing a detection process for the reception of the second signal 104 within a predetermined period 415 after the transmission of the first signal 102.
[0064] Figure 9 shows an example of the configuration of the second wireless device 20. The second wireless device 20 comprises an antenna 902, a radio unit 904, and a radio protocol control unit 900. The antenna 902 transmits and receives signals. The radio unit 904 modulates the baseband signal and incorporates it into the carrier wave. The carrier wave is the signal transmitted via the antenna 902. The radio unit 904 also demodulates the signal received via the antenna 902 to generate a baseband signal. The radio protocol control unit 900 controls the overall operation of the second wireless device 20. These configurations are used in all transmission and reception in the second wireless device 20.
[0065] The second wireless device 20 also includes a first baseband signal processing unit 906 and a signal detection unit 908. These configurations are mainly used for receiving the first signal 102. More specifically, the wireless unit 904 receives the first signal 102 via the antenna 902. The wireless unit 904 demodulates the first signal 102 to generate a baseband signal. The wireless unit 904 outputs the baseband signal of the first signal 102 to the first baseband signal processing unit 906. The first baseband signal processing unit 906 converts the acquired baseband signal into a pseudo-random sequence. That is, the first baseband signal processing unit 906 converts the acquired baseband signal into bit sequence information. The first baseband signal processing unit 906 outputs the generated pseudo-random sequence to the signal detection unit 908. The signal detection unit 908 determines whether or not the first signal 102 has been received or detected. Based on its determination that it has received or detected the first signal 102, the signal detection unit 908 outputs a detection notification of the first signal 102 to the wireless protocol control unit 900. The signal detection unit 908 may perform correlation detection by comparing a pseudo-random sequence obtained from the first signal 102 with a pseudo-random sequence generated by the signal detection unit 908. The signal detection unit 908 may also estimate the direction of arrival 702 of the first signal 102. In this case, the signal detection unit 908 outputs the estimated direction of arrival 702 of the first signal 102 to the wireless protocol control unit 900.
[0066] The second wireless device 20 also includes a signal generation unit 910 and a first baseband signal generation unit 912. These configurations are mainly used for the transmission processing of the second signal 104. More specifically, the signal generation unit 910 generates a pseudo-random sequence to be included in the second signal 104 and outputs the pseudo-random sequence to the first baseband signal generation unit 912. The first baseband signal generation unit 912 converts the acquired pseudo-random sequence into a continuous baseband signal having predetermined amplitude and phase. The first baseband signal generation unit 912 outputs the generated baseband signal to the wireless unit 904. The wireless unit 904 modulates the acquired baseband signal and includes the baseband signal in the carrier wave. The wireless unit 904 transmits the carrier wave as the second signal 104 via the antenna 902.
[0067] Furthermore, the second wireless device 20 includes a second baseband signal processing unit 914 and a received data processing unit 916. These configurations are mainly used for receiving the third signal 108 and subsequent signals. More specifically, the wireless unit 904 receives signals via the antenna 902. The wireless unit 904 demodulates the received signal to generate a baseband signal. The wireless unit 904 outputs the baseband signal of the received signal to the second baseband signal processing unit 914. The second baseband signal processing unit 914 converts the acquired baseband signal into a bit sequence. The second baseband signal processing unit 914 outputs the converted bit sequence to the received data processing unit 916. The bit sequence may include a pseudo-random sequence, user data, control data, etc. If the acquired bit sequence is a pseudo-random sequence, the received data processing unit 916 performs detection processing such as correlation detection on the bit sequence and outputs the result of the detection processing to the wireless protocol control unit 900. The received data processing unit 916 outputs the bit sequence to the wireless protocol control unit 900 if the acquired bit sequence is user data or control data, etc.
[0068] The second radio device 20 also includes a transmission data generation unit 918 and a second baseband signal generation unit 920. These configurations are mainly used for transmitting the fourth signal 110 and subsequent signals. More specifically, the transmission data generation unit 918 generates data to be included in the fourth signal. The transmission data generation unit 918 can also generate any data to be transmitted to the first radio device 10. The transmission data generation unit 918 outputs the generated data to the second baseband signal generation unit 920. The second baseband signal generation unit 920 generates a baseband signal from the acquired data based on predetermined frequencies and amplitudes. The second baseband signal generation unit 920 outputs the generated baseband signal to the radio unit 904. The radio unit 904 modulates the acquired baseband signal and includes the baseband signal in a carrier wave. The radio unit 904 transmits the carrier wave via the antenna 902. The carrier wave includes the fourth signal 110 or any other signal.
[0069] Antenna 902 may be an omnidirectional antenna or a quasi-omnidirectional antenna. Antenna 902 may be a plurality of directional antennas. Antenna 902 may also include both omnidirectional and directional antennas. Antenna 902 may also be an array antenna.
[0070] Figure 10 shows an example of the configuration of the array antenna 500 of the first wireless device 10. The array antenna 500 includes a plurality of antennas, each of which is connected to the wireless unit. The array antenna 500 comprises at least a second antenna 810. The array antenna 500 may also have the functions of both the first antenna 808 and the second antenna 810. Furthermore, a third antenna 824 may also be configured as an array antenna.
[0071] The first radio unit 806, the second radio unit 812, and the third radio unit 822 may be configured as a single radio unit or as separate radio units. Similarly, the first baseband signal generation unit 804 and the second baseband signal generation unit 820 may be configured as a single baseband signal generation unit or as separate baseband signal generation units. The first baseband signal processing unit 814 and the second baseband signal processing unit 826 may be configured as a single baseband signal processing unit or as separate baseband signal processing units.
[0072] Figure 11 shows an example of a pseudo-random sequence generator 1100 provided in the first wireless device 10 and the second wireless device 20. The first wireless device 10 and the second wireless device 20 can use the pseudo-random sequence generator 1100 to obtain a pseudo-random sequence with a repeat length of 16,383 bits. The pseudo-random sequence generator 1100 can be configured as hardware or software. The pseudo-random sequence generator 1100 may generate the pseudo-random sequence 200 using a Zadoff-Chu sequence or other known method.
[0073] <Operation of Each Wireless Device> Figure 12 is a diagram showing an example of the operation flow of the first wireless device 10. The first wireless device 10 can realize the processing shown in Figure 12 by executing a program. The wireless protocol control unit 800 may include a processor, memory, and storage. Alternatively, the wireless protocol control unit 800 may read a program for performing the processing shown in Figure 12 from storage into memory and execute the program using the processor. Part or all of the processing can also be realized as a combination of circuit elements configured to perform the processing.
[0074] In step S1210, the first radio device 10 transmits the first signal 102. If the second radio device 20 receives the first signal, the second radio device 20 transmits the second signal 104. In step S1220, based on having received the second signal 104, the first radio device 10 detects the second signal 104 and estimates the direction of arrival 106 of the second signal 104. The first radio device 10 may use correlation detection techniques to detect the second signal 104. In step S1230, the first radio device 10 determines whether it has succeeded in detecting the second signal 104 and estimating the direction of arrival 106 of the second signal 104. If the first radio device 10 determines that it has succeeded in detecting the second signal 104 and estimating the direction of arrival 106 of the second signal 104 (YES in step S1230), it moves control to step S1240. Otherwise (NO in step S1230), the first wireless device 10 transfers control to step S1210.
[0075] In step S1240, the first wireless device 10 transmits the third signal 108 in the direction of arrival 106. When the second wireless device 20 receives the third signal 108, the third signal 108 transmits the fourth signal 110. In step S1250, the first wireless device 10 detects the fourth signal 110 based on having received it. The first wireless device 10 may detect the fourth signal 110 using correlation detection techniques. In step S1260, the first wireless device 10 determines whether or not it has detected the fourth signal 110. If the first wireless device 10 determines that it has detected the fourth signal 110 (YES in step S1260), it transfers control to step S1270. Otherwise (NO in step S1260), the first wireless device 10 transfers control to step S1210. In step S1270, the first wireless device 10 performs terminal connection processing. The terminal connection process corresponds to the process shown in Figure 6. Once the terminal connection process is complete, the first wireless device 10 and the second wireless device 20 establish communication with each other.
[0076] Figure 13 shows an example of the operation flow of the second wireless device 20. The second wireless device 20 can realize the processing shown in Figure 13 by executing a program. The wireless protocol control unit 900 may include a processor, memory, and storage. Alternatively, the wireless protocol control unit 900 may read a program for performing the processing shown in Figure 13 from storage into memory and have the processor execute the program. Part or all of the processing can also be realized as a combination of circuit elements configured to perform the processing. The following steps may be executed in any order.
[0077] In step S1310, the second radio device 20 detects the first signal 102 based on having received it. The second radio device 20 may detect the first signal 102 using correlation detection techniques. Alternatively, the second radio device 20 may estimate the direction of arrival 702 of the first signal 102.
[0078] In step S1320, the second wireless device 20 determines whether or not it has detected the first signal 102. If the second wireless device 20 determines that it has detected the first signal 102 (YES in step S1320), it transfers control to step S1330. Otherwise (NO in step S1320), the second wireless device 20 transfers control to step S1310.
[0079] In step S1330, the second radio device 20 transmits a second signal 104. The second signal 104 may be transmitted via an omnidirectional antenna or a quasi-omnidirectional antenna. Alternatively, the second signal 104 may be transmitted via a directional antenna in the direction of arrival 702 of the first signal. If the first radio device 10 successfully detects the second signal 104 and estimates the direction of arrival 106, it transmits a third signal 108.
[0080] In step S1340, the second wireless device 20 receives the third signal 108. In step S1350, the second wireless device 20 transmits the fourth signal 110 based on having received the third signal 108. In step S1360, the second wireless device 20 performs terminal connection processing. This step is the counterpart to step S1270. In step S1370, the second wireless device 20 determines whether the terminal connection processing was successful. If the second wireless device 20 determines that the terminal connection processing was successful (YES in step S1370), it transfers control to step S1380. Otherwise (NO in step S1370), the second wireless device 20 transfers control to step S1310.
[0081] In step S1380, the second wireless device 20 performs the transmission and reception of communication data with the first wireless device 10. The processing in this step is performed after communication between the first wireless device 10 and the second wireless device has been established.
[0082] <Summary> As explained above, in the technology of this disclosure, the first wireless device 10 estimates the direction of arrival 106 of the second signal 104 by analyzing the second signal 104 received by the array antenna 500. Therefore, the first wireless device 10 only needs to transmit the third signal 108 in the direction of arrival 106 of the second signal 104. As a result, the communication overhead and power consumption in the transmission of the third signal 108 can be significantly reduced compared to the conventional technology.
[0083] Furthermore, the second radio device 20 may estimate the direction of arrival 702 of the first signal 102. In this case, the second radio device 20 transmits the second signal 104 in the direction of arrival 702 of the first signal 102 via a directional antenna. As a result, the second signal 104 can be transmitted with lower transmission power than when transmitted with an omnidirectional antenna, due to the higher directional gain. Therefore, the second radio device 20 can transmit the second signal 104 without consuming extra transmission power.
[0084] The embodiments disclosed herein should be considered in all respects to be illustrative and not restrictive. The scope of this disclosure is indicated by the claims and not by the foregoing description, and all modifications are intended to be included in the sense and scope equivalent to the claims. Furthermore, the disclosures described in the embodiments and each variation are intended to be implemented, as far as possible, individually or in combination.
[0085] 10 First radio device, 20 Second radio device, 102 First signal, 104 Second signal, 106, 702 Direction of arrival, 108 Third signal, 110 Fourth signal, 200, 420 Pseudo-random sequence, 300 Length, 302 Signal, 400 Detection notification, 410 Generation command, 415 Predetermined period, 430 Baseband signal, 440 Carrier wave, 500 Array antenna, 502 Azimuth angle, 504 Elevation angle, 510 Graph, 800, 900 Radio protocol control unit, 802, 910 Signal generation unit, 804, 912 First baseband signal generation unit, 806 First radio unit, 808 First antenna, 810 Second antenna, 812 Second radio unit, 814, 906 First baseband signal processing unit, 816, 908 Signal detection unit, 818, 918; Transmission data generation unit, 820, 920; Second baseband signal generation unit, 822; Third radio unit, 824; Third antenna, 826, 914; Second baseband signal processing unit, 828, 916; Receiving data processing unit, 902; Antenna, 904; Radio unit, 1100; Pseudo-random sequence generator.
Claims
1. A method for establishing communication between a first wireless device and a second wireless device, comprising: the first wireless device transmitting a first signal including a synchronization signal using an omnidirectional or quasi-omnidirectional antenna; the second wireless device transmitting a second signal based on having received the first signal; the first wireless device estimating the direction of arrival of the second signal based on having received the second signal using an array antenna; the first wireless device transmitting a third signal including system information in the direction of arrival of the second signal using a directional antenna; and the second wireless device transmitting a fourth signal for establishing wireless communication between the first wireless device and the second wireless device based on having received the third signal.
2. The method for establishing communication according to claim 1, wherein the second wireless device transmits the second signal based on the reception of the first signal, the method includes receiving the first signal using an array antenna and estimating the direction of arrival of the first signal, and transmitting the second signal in the direction of arrival of the first signal using a directional antenna.
3. The method for establishing communication according to claim 1 or 2, wherein the first wireless device receives the second signal using an array antenna, and the receiving process of the second signal is performed within a predetermined period after the transmission of the first signal.
4. The method for establishing communication according to claim 1 or 2, wherein the first signal and the second signal are signals generated by modulating a baseband signal based on a pseudo-random sequence.
5. A wireless device comprising: an omnidirectional or quasi-omnidirectional first antenna for transmitting a first signal including a synchronization signal; a second antenna which is an array antenna for receiving a second signal from a wireless terminal; a signal detection unit for estimating the direction of arrival of the second signal; and a third antenna which is a directional antenna for transmitting a third signal including system information in the direction of arrival of the second signal and receiving a fourth signal for establishing wireless communication from the wireless terminal.
6. The wireless device according to claim 5, wherein receiving the second signal from the wireless terminal includes performing a detection process for the reception of the second signal within a predetermined period after the transmission of the first signal.