RU2792280C2 - Communication device - Google Patents

Abstract

FIELD: wireless communication.

SUBSTANCE: technical result is achieved by the communication device other than the AP/PCP device receiving a measurement request from the AP/PCP communication device. In response to the measurement request, the communication device performs a measurement during an active service period (actual SP) other than a potential service period (potential SP) to which the communication device belongs and another communication device other than the AP/PCP device. The communication device transmits a report that includes the measurement result, and in response to the AP/PCP communication device scheduling a potential SP that overlaps the actual SP in time after receiving the report, receives a frame containing a recommended transmission scheme field indicating a recommended transmission scheme to be applied for potential SP.

EFFECT: technical result is to increase the throughput and efficiency of the use of radio resources.

28 cl, 16 dwg

Description

FIELD OF TECHNOLOGY

[0001] The present invention relates to a communication device.

BACKGROUND OF THE INVENTION

[0002] The present invention relates to wireless communication, and more specifically, to a method for achieving "spatial sharing" (Spatial Sharing, SPSH) in a directed wireless local area network (Wireless Local Area Network, WLAN). The IEEE 802.11ay standard (referred to as the "11ay standard") was developed as a system for providing high-speed data transmission using millimeter wave SPSH (see non-patent literature references (hereinafter referred to as NPL) 1 and 2).

List of opposed materials

Non-Patent Literature

[0003]

NPL 1

IEEE 802.11-2016 p. 1870-1872

NPL 2

IEEE 802.11-16/1609r3

DISCLOSURE OF THE INVENTION

TECHNICAL PROBLEM

[0004] Meanwhile, the method for implementing SPSH disclosed in NLT 1 does not take into account the case where the communication scheme (SISO communications and/or SU-MIMO communications) used in the measurement for SPSH and the communication scheme performing SPSH are different from each other. friend; whereby, thus, it is difficult to carry out the measurement to perform the SPSH properly.

[0005] In one embodiment, the present invention provides a communication device capable of measuring to perform SPSH properly.

THE SOLUTION OF THE PROBLEM

[0006] A communication device other than an AP/PCP device according to one aspect of the present invention comprises: a receiving circuit that, in operation, receives a measurement request transmitted from an AP/PCP communication device and requests a measurement used to determine whether whether the implementation of SPSH; and a transmission scheme that, in operation, transmits the measurement result based on the measurement request to the AP/PCP communication device, using a first communication period during which communication is carried out with a first communication device other than the AP/PCP device, which represents another communication device other than the AP/PCP device, and represents a communication partner for said communication device other than the AP/PCP device, wherein the transmit circuit and the receive circuit communicate with the first communication device other than the AP /PCP device using the first communication scheme, and during the second communication period during which communication is not performed with the first communication device other than the AP/PCP device and which is included in the measurement request, the receiving circuit executes using of the first communication scheme, the measurement of the received signal, and the result of the specified measurement includes information about the measurement of the received signal and information about the first connection scheme.

[0007] It should be noted that general or specific embodiments may be implemented as a system, method, integrated circuit, computer program, or storage medium, or any selective combination of a system, device, method, integrated circuit, computer program, and storage medium. data storage.

ADVANTAGES OF THE INVENTION

[0008] According to one embodiment of the present invention, there is provided a communication device capable of performing a measurement to perform SPSH properly.

[0009] Additional benefits and advantages of one aspect of the disclosed embodiments will become apparent from the description and drawings. Benefits and/or advantages may be obtained separately using various embodiments and features from the description and drawings, which need not all be provided to obtain one or more benefits and/or advantages.

BRIEF DESCRIPTION OF THE DRAWINGS

[0010]

FIG. 1 shows a configuration example of a communication system according to the present embodiment;

in FIG. 2 shows an example of scheduling performed by a communication device according to the present embodiment;

in FIG. 3 shows an example of scheduling an (n+1) beacon interval (described as BI #n+1) obtained by changing the scheduling of the nth beacon interval (described as BI #n) of FIG. 2, to implement SPSH;

in FIG. 4A shows a procedure for performing SPSH by a communication device according to the present embodiment;

in FIG. 4B shows a procedure for performing SPSH by a communication device according to the present embodiment;

in FIG. 5 shows an example configuration of a communication system that includes a communication device equipped with one or more antenna arrays;

in FIG. 6A shows a configuration example of a communication device according to the present embodiment;

in FIG. 6B shows a configuration example of a communication device according to the present embodiment;

in FIG. 7A shows a procedure for performing SPSH by a communication device according to the present embodiment;

in FIG. 7B shows a procedure for performing SPSH by a communication device according to the present embodiment;

FIG. 8 illustrates a measurement request transmitted by an AP/PCP communication device;

in FIG. 9 shows an example of a measurement report element format to be included in a measurement report transmitted by a communication device other than an AP/PCP device;

in FIG. 10 shows an example of the measurement configuration sub-item format;

in FIG. 11 shows an example of the format of an extended measurement configuration sub-element;

in FIG. 12 shows an example format for an extended measurement report sub-element; And

FIG. 13 illustrates an exemplary EDMG scheduling element format.

IMPLEMENTATION OF THE INVENTION

[0011] The SPSH procedure according to the IEEE 802.11-2016 standard will be described with reference to the drawings.

[0012] FIG. 1 shows a configuration example of a communication system according to the present embodiment. Each communication device 100a, 100b, 100c, 100d, and 200 includes one or more antenna arrays. Each of the antenna arrays contains one or more antenna elements.

[0013] At least one of the communication devices 100a, 100b, 100c, 100d, and 200 may be a communication device having a Personal Basic Service Set (PBSS) control point (PBSS Control Point, PCP) function or access (Access Point, AP), which is indicated as PCP / AP or AP / PCP. In one example, communication device 200 is a PCP and communication devices 100a, 100b, 100c, and 100d are devices other than AP/PCP devices. A device other than an AP/PCP device is a communication device that is neither a PCP device nor an AP device.

[0014] The communication device 100a communicates with the communication device 100b. The communication device 200 is configured to determine the communication time between the communication device 100a and the communication device 100b as a service period SP1100 and notify the communication devices 100a, 100b, 100c and 100d of the service period.

[0015] The communication device 100c communicates with the communication device 100d. The communication device 200 is configured to determine the communication time between the communication device 100c and the communication device 100d as a service period SP1200 and notify the communication devices 100a, 100b, 100c, and 100d of the service period.

[0016] FIG. 2 shows an example of scheduling (scheduling 1000) performed by the communication device 200 according to the present embodiment. The communication device 200 determines the period from time t1 to time t8 as a beacon interval, and also determines the period from time t1 to time t4 as a Beacon Header Interval (BHI). BHI includes a Beacon Transmission Interval (BTI) from time t1 to time t2, Association Beamforming Training (A-BFT) from time t2 to time t3, and an Announcement Transmission Interval , ATI) from time t3 to time t4.

[0017] In addition, the period from the time t1 to the time t8 is defined as the offset time from the start of the beacon interval. In other words, at time t1, the offset time is 0.

[0018] The period in which the BHI is excluded from the signal interval is called the data transfer interval (Data Transfer Interval, DTI). The communication device 200 may include one or more Content Based Access Periods (CBAP) and/or one or more service periods in the DTI. FIG. 2, as an example, the communication device 200 defines the time period from time t4 to time t5 as CBAP 1, the time period from time t5 to time t6 as SP1 (SP1100), the time period from time t6 to time t7 as SP2 (SP1200), and the time period from time t7 to time t8 as CBAP 2.

[0019] FIG. 3 shows an example of scheduling an (n+1) beacon interval (described as BI #n+1) obtained by changing the scheduling of the nth beacon interval (described as BI #n) of FIG. 2 to implement SPSH.

[0020] When performing SPSH between SP1100 and SP1200, communication device 200 determines one of SP1100 and SP1200 as a valid SP and the other one as a potential SP. In other words, the communication device 200 performs SPSH by changing the scheduling for the potential SP (allocation start time t6) so that the allocated periods of the actual SP and the potential SP overlap each other.

[0021] As shown in FIG. 3, the communication device 200 determines the current SP1100 as an allocation of SP1300 to SPSH without changing the allocated time (t5 to t6), and determines SP1200 to be the allocation of SP1400 to SPSH by changing the allocated time (t9 to t10) to provide overlap with SP1300.

[0022] Performing SPSH between SP1300 and SP1400 allows one more period (eg, CBAP3) to be allocated from t6 to t7, thus improving RF efficiency and thus transmitting more data.

[0023] When performing SPSH with scheduling change 1000 of FIG. 2 for planning 1500 in FIG. 3, the communication device 200 estimates interference between SP1100 and SP1200 in the nth beacon period of FIG. 2 and determines whether the SPSH of FIG. 3. Next, the SPSH procedure including interference evaluation will be described in detail.

[0024] FIG. 4A and 4B show a procedure for SPSH devices 100a, 100b, 100c, and 100d to communicate under the control of communication device 200.

[0025] As shown in FIG. 4A, in the BTI of the nth beacon interval, the communication device 200 includes the scheduling information 1000 in one or more beacon frames, and transmits the beacon frames (step S2001).

[0026] Communication devices 100a, 100b, 100c, and 100d receive signal frames.

[0027] The communication device 200 transmits measurement requests to communication devices (communication devices 100a and 100b) for which a valid SP is allocated. In one example, the measurement request is a MAC frame including a measurement request element. The measurement request contains command information for the communication device 100a and the communication device 100b to measure the interference in the allocated period in the potential period SP1200. The command information includes start time information, period information, and interference measurement method information, and communication partner information. As an example of the interference measurement method, an Average Noise Plus Interference Power Indicator (ANIPI) and a Receive Signal to Noise Ratio Indicator (RSNI) are indicated (step S2002).

[0028] The communication partner information is the identification number of the communication device to which the valid SP is allocated (an association identifier (AID) is one example). The communication device 200 may transmit the AID of the communication device 500b as communication partner information when transmitting a measurement request to the communication device 100a. In other words, the communication partner information included in the measurement request is the effective SP information, while the start time information and the interference measurement period information are the time information of the potential SP, since the measurement is performed at potential SP current (see step S2207b described below).

[0029] The communication device 200 transmits measurement requests to the communication devices (communication devices 100c and 100d) for which potential SPs are allocated (step S2003).

[0030] The transmission order of the communication device 200, namely the transmission of measurement requests to the communication devices 100a, 100b, 100c, and 100d in steps S2002 and S2003, is not limited to the order shown in FIG. 3. In addition, the communication device 200 may transmit measurement requests addressed to the communication device 100a, the communication device 100b, the communication device 100c, and the communication device 100d, respectively, in separate frames.

[0031] Communication devices 100a and 100b transmit and receive data frames in allocated period SP1100 (step S2004).

[0032] The communication devices 100c and 100d measure the amount of interference power (ANIPI or RSNI) in the assigned period SP1100 based on the information in the measurement request received in step S2003 (steps S2005a, S2005b).

[0033] Communication devices 100c and 100d transmit and receive data frames in allocated period SP1200 (step S2006).

[0034] The communication devices 100a and 100b measure the amount of interference power (ANIPI or RSNI) in the allocated period SP1200 based on the information in the measurement request received in step S2002 (steps S2007a, S2007b).

[0035] The communication device 100a transmits a measurement report including the amount of interference power measured in step S2007a to the communication device 200. In one example, the measurement report is a MAC frame including a measurement report element (step S2008a).

[0036] Similarly, the communication devices 100b, 100c, and 100d also transmit measurement reports including the interference power values measured in steps S2007b, S2005a, and S2005b to the communication device 200 (steps S2008b, S2008c, and S2008d).

[0037] Steps S2008a, S2008b, S2008c, and S2008d may be performed in a different order than illustrated. In addition, as an example, in FIG. 3, extraction of SP1200 (step S2006) occurs after SP1100 (step S2004), so that steps S2008c and S2008d are performed after steps S2006, S2008a and S2008b. If a different period (eg, CBAP (not shown)) is allocated between SP1100 and SP1200 than that shown in FIG. 3, communication devices 100c and/or 100d may perform steps S2008c and/or S2008d before step S2006.

[0038] The communication device 200 determines whether SPSH can be performed between the actual SP1100 and the potential SP1200 after receiving the measurement reports from the communication devices 100a, 100b, 100c, and 100d (step S2009).

[0039] For example, communication device 200 determines that SPSH can be performed if any of the interference power values reported from communication devices 100a, 100b, 100c, 100d do not exceed a reference value. The reference value, as an example, may be the power at the sensitivity point of the modulation and coding scheme 1 (MCS 1).

[0040] As shown in FIG. 4B, when determining that SPSH can be performed between the current SP1100 and the potential SP1200 in step S2009, the AP/PCP communication device 200 includes scheduling information 1500 allowing SPSH in a beacon frame, and transmits the beacon frame to the BTI of the next BI (n+ 1st beep interval) (step S2010).

[0041] Communication devices 100a and 100b other than AP/PCP devices transmit and receive data frames in a dedicated period SP1300 (step S2004a).

[0042] Communication devices 100c and 100d transmit and receive data frames in a dedicated period SP1400. According to scheduling information 1500, allocated time SP1400 may overlap with allocated time SP1300 (step S2006a).

[0043] Thus, the communication between the communication device 100a and the communication device 100b, and the communication between the communication device 100c and the communication device 100d occur simultaneously (referred to as "spatial separation: SPSH"), which can improve throughput and utilization efficiency. radio resource.

[0044] However, the SPSH standard of the IEEE 802.11-2016 common standard (see NFL 1) does not consider a procedure for performing SPSH when each communication device has a plurality of antenna arrays and performs diversity reception or communicates using a plurality of inputs and multiple outputs (Multi -Input Multi-Output, MIMO), simultaneously using antenna arrays.

[0045] In addition, NLT 2 describes a method in which a communication device having a plurality of antenna arrays performs SPSH. However, NLT 2 does not take into account that each communication device can communicate by changing the configuration of the receiving antenna (ie, setting the number of antennas and their directivity) depending on the characteristics of the opposed communication device and the type of frames transmitted.

[0046] Accordingly, it is difficult for the communication device 200 to estimate the amount of interference power received when communicating in the SPSH mode (steps S2004a, S2006a) based on the amount of interference power determined in the interference measurement (steps S2005a, S2005b, S2007a, and S2007b), and it is also difficult to accurately determine whether SPSH can be performed in step S2009.

[0047] Thus, the communication device 200 can determine that SPSH cannot be performed if the amount of interference power during communication is small, or can determine that SPSH can be performed if the amount of interference power during communication is large, which may result in reduced radio frequency efficiency and increased communication error rates.

[0048] (Embodiment 1)

FIG. 5 shows an example of a communication system configuration that includes communication devices 500a, 500b, 500c, 500d, and 600 equipped with one or more antenna arrays.

[0049] In one example, communication devices 500a, 500b, 500c, and 500d are communication devices other than AP/PCP devices, while communication device 600 is an AP/PCP communication device. Communication devices 500a and 500b implement SISO communication and Single User MIMO (SU-MIMO) communication in the SP1100. Communication devices 500c and 500d implement SISO communication and single user MIMO (SU-MIMO) communication in the SP1200.

[0050] FIG. 6A shows an example configuration of communication devices 500a, 500b, 500c, 500d, and 600. Communication devices 500a, 500b, 500c, 500d, and 600 include, for example, host 130, MAC circuit 120, PHY circuit 110, and RF module circuit 109.

[0051] The RF module circuit 109 includes, for example, antenna arrays 101a and 101b, switch circuits (SW) 102a and 102b, radio frequency (RF) transmission circuits 103a and 103b, and RF reception circuits 104a and 104b. It should be noted that the radio frequency (RF) transmission circuits 103a and 103b and the radio frequency reception circuits 104a and 104b may also be referred to as "high frequency transmission circuits" and "high frequency reception circuits".

[0052] Antenna arrays 101a and 101b transmit and receive radio signals. The switching circuits 102a and 102b are circuits for switching connection targets to which the antenna arrays 101a and 101b are connected in time division, and connecting the antenna arrays to the RF transmission circuits 103a and 103b in the transmission mode or to the RF reception circuits 104a and 104b. in the reception operation mode to enable transmission and reception by the time division antenna arrays 101a and 101b. When communicating in the SU-MIMO mode, the antenna arrays 101a and 101b transmit and receive different signals containing different data.

[0053] Communication devices 500a, 500b, 500c, 500d, and 600 may also include transmit antenna arrays (eg, transmit antenna arrays 101a-1 and 101a-2 (not shown)) and receive antenna arrays (eg, receive antenna arrays 102a- 1 and 102a-2 (not shown)) instead of switching circuits 102a and 102b.

[0054] The RF transmission circuits 103a and 103b modulate the baseband transmission signals output by the D/A converter circuits 111a and 111b, convert the baseband transmission signals into high frequency signals (e.g., signals from the 60 GHz band), and output the high frequency signals to the antenna grids 101a and 101b. In addition, the RF transmission circuits 103a and 103b control the phase and/or power of the output signals for each of the antenna elements (not shown) constituting the antenna arrays 101a and 101b, thereby performing transmission directivity control for the antenna arrays 101a and 101b. It should be noted that directionality control provides control of the transmission power of the radio signal depending on the direction of transmission.

[0055] The RF reception circuits 104a and 104b convert the received radio signals output from the antenna arrays 101a and 101b into baseband reception signals and output them to the A/D converters 112a and 112b. The RF reception circuits 104a and 104b control the phase and/or power of the input signals to each of the antenna elements (not shown) constituting the antenna arrays 101a and 101b, thereby effecting reception directivity control for the antenna arrays 101a and 101b. It should be noted that the reception directivity control controls the reception sensitivity of the radio signal depending on the reception direction.

[0056] The PHY circuit 110 includes, for example, digital-to-analog converters 111a and 111b, analog-to-digital converters 112a and 112b, an antenna array pattern control circuit 113, an encoding and modulation circuit 114, and a demodulation and decoding circuit 115.

[0057] The D/A converters 111a and 111b perform D/A conversion of the baseband digital transmission signal output from the coding and modulation circuit 114 and output it to the RF transmission circuits 103a and/or 103b.

[0058] Analog-to-digital converters 112a and 112b perform analog-to-digital conversion of the baseband analog reception signal output from the RF reception circuits 104a and/or 104b, and output the converted signal to the demodulation and decoding circuit 115.

[0059] The antenna array beam control circuit 113 instructs the RF transmission circuits 103a and/or 103b or the RF reception circuits 104a and/or 104b to perform transmission directivity control or receive directivity control based on the command from the beamforming control circuit 124 of the scheme 120 MAC.

[0060] The coding and modulation circuit 114 encodes (for example, using Low Density Parity Check (LDPC) coding) and modulates (for example, using ϖ/2-binary phase shift keying (Binary Phase Shift Keying). , BPSK)) output MAC transmission frame (referred to as the "transmission PHY payload") from the frame generation circuit 122 of the MAC circuit 120 to generate two types of baseband digital transmission signals and output these signals to the digital-to-analog converter 111a or 111b.

[0061] The demodulation and decoding circuit 115 demodulates and decodes two types of baseband digital reception signals output from the analog-to-digital converters 112a and/or 112b, and outputs the decoded PHY data (referred to as a "reception MAC frame") to the reception circuit 123 frame scheme 120 MAC.

[0062] The demodulation processing performed by the demodulation and decoding circuit 115 includes, for example, synchronization processing (preamble detection, frequency synchronization and/or time synchronization), compensation (reception signal distortion correction), and data demodulation (e.g. ϖ/2-BPSK symbol data into bit data and likelihood data). Further, the decoding processing includes, for example, LDPC decoding.

[0063] The MAC circuit 120 includes, for example, an access control circuit 121, a frame generation circuit 122, a frame reception circuit 123, and a beamforming (BF) control circuit 124.

[0064] The access control circuit 121 switches between the transmission mode and the reception mode, and determines the transmission time depending on the user data input at the host 130 and the data received by the receiving antenna, and also controls the frame generation circuit 122, the frame reception circuit 123, and /or the beamforming control circuit 124 . The access control circuit also determines the transmission time and controls the frame generation circuit 122 to transmit user data entered at the host 130. In addition, the access control circuit determines the BFT execution timing and controls the beamforming control circuit 124 to perform beamforming learning (BFT).

[0065] Host 130 includes, for example, a central processing unit (CPU) or a system on a chip (SoC) and controls an operating system (OS) or application software (eg, a web browser or file management software). The host turns the MAC on or off, manages acquisition of MAC status information, requests data transmission from the MAC, and/or receives receive data, eg, in response to an OS or application software request.

[0066] FIG. 6B shows an example configuration of communication device 500e. This figure shows another example other than communication devices 500a, 500b, 500c, 500d, and 600. The communication device 500e includes, for example, a host 130, a MAC circuit 120, a PHY circuit 110a, and an RF module circuit 109a.

[0067] The PHY circuit 110a includes an intermediate frequency (IF) transmission circuit 152. The IF transmission circuit 152 modulates the baseband analog signal (referred to as the "IQ signal") output from the D/A converters 111a and/or 111b to produce a so-called IF transmission signal with an intermediate frequency between the baseband transmission signal and the RF signal frequency, and transmits the modulated signal to the RF module circuit 109a via the IF cable 153. In addition, the IF transmission circuit 152 is configured to modulate the control signal output from the antenna array beam control circuit 113 to obtain an IF control signal, multiplex the modulated signal with the IF band transmission signal, and output the resulting signal to the IF cable 153 .

[0068] The RF module circuit 109a includes an IF transmission circuit 151. The RF module circuitry comprises RF transmission circuits 103c and 103d and RF reception circuits 104c and 104d instead of RF transmission circuits 103a and 103b and RF reception circuits 104a and 104b shown in FIG. 6A.

[0069] The IF transmission circuit 151 separates the control signal in the IF band on the IF cable 153, demodulates the control signal output from the antenna array beam control circuit 113, and outputs the demodulated control signal to the RF transmission circuits 103c and 103d and the RF circuits 104c and 104d reception.

[0070] The IF transmission circuit 151 also separates the IF band transmission signal and outputs it to the RF transmission circuits 103c and/or 103d. RF transmission circuits 103c and 103d modulate and amplify the IF transmission signal to obtain an RF transmission signal. In addition, the RF transmission circuits 103c and 103d control, based on the signal obtained by demodulating the IF band control signal by the IF transmission circuit 151, the amplitude and phase of the RF transmission signal to perform transmission directivity control.

[0071] In addition, while the RF reception circuits 104a and 104b demodulate the RF reception signal into a baseband reception signal (FIG. 6A), the RF reception circuits 104c and 104d demodulate the RF reception signal into an IF reception signal (FIG. .6B). The IF transmission circuit 151 multiplexes the received signal in the IF band with another signal, and outputs the multiplexed signal to the IF cable 153 . The IF transmission circuit 152 demodulates the IF band reception signal, generates the baseband reception signal, and outputs the signal to the A/D converters 112a and 112b.

[0072] Because in the configuration shown in FIG. 6B, multiple signals are multiplexed and transmitted to IF cable 153, IF cable 153 may be longer than in the configuration of FIG. 6A so that the PHY circuit 110a and the MAC circuit 120 can be installed separately from the RF module circuit 109a. However, the communication devices 500a, 500b, 500c, 500d, and 600 are considered to have an integrated function even if the PHY circuit 110a and the RF module circuit 109a are separated from each other, because the signal transmitted on the IF cable 153 is designed according to the circuit configurations. 110a PHY and RF module circuits 109a.

[0073] In the SP1100 interval of FIG. 2, the communication device 500a communicates with the communication device 500b. In the interval SP1100 and in or before the nth beacon interval (not shown), the communication devices 500a and 500b can perform SISO beamforming training and SU-MIMO beamforming.

[0074] SISO beamforming is a procedure for determining the configuration of a transmitting and receiving antenna with high communication quality in SISO communication. SU-MIMO beamforming is a procedure for configuring transmitting and receiving antennas with high communication quality in SU-MIMO communication.

[0075] The transmit and receive antenna configuration determined by SISO beamforming may be different from the transmit and receive antenna configuration determined by SU-MIMO beamforming. For example, SU-MIMO beamforming may involve selecting multiple transmit antenna arrays and multiple receive antenna arrays, while SISO beamforming may involve selecting a single transmit antenna array (eg, antenna array 101a).

[0076] In addition, SU-MIMO beamforming can control the directionality of the plurality of receive antenna arrays so that the plurality of receive antenna arrays can receive a signal transmitted from the plurality of transmit antenna arrays at a certain signal strength or greater, respectively. At the same time, in SISO beamforming, a signal can be received by a plurality of receive antenna arrays while the directivity of the plurality of receive antenna arrays is controlled to increase the intensity of a received signal transmitted by one transmitting antenna array.

[0077] After communication devices 500a and 500b complete SISO beamforming training and SU-MIMO beamforming learning, communication device 500a in SP1100a may select SISO communication or SU-MIMO communication for each of the packets and transmit the packet.

[0078] In one example, communication device 500a may transmit a large data packet using SU-MIMO communication and may transmit a small data packet or a packet requiring high communication quality (for example, a control frame, a control frame, and a small data packet) , using SISO communications.

[0079] When performing a transmission using SU-MIMO communication, the communication device 500a transmits a frame (eg, a ready-to-transmit (RTS) frame containing an end control pulse) indicating a SU-MIMO communication request before transmitting a data packet. After receiving a frame indicating a SU-MIMO communication request, the communication apparatus 500b changes the receive antenna configuration to the configuration determined in SU-MIMO beamforming learning and waits for SU-MIMO packets.

[0080] In the event that communication device 500b does not receive a frame indicating a SU-MIMO communication request, communication device 500b changes the receive antenna configuration to that determined in SISO beamforming training and waits for SISO packets.

[0081] In other words, in the interval SP1100, communication devices 500a and 500b can switch receive antenna configurations. The amount of interference power received by the communication devices 500a and 500b may vary according to the switching of the receiving antenna configurations.

[0082] FIG. 7A and 7B show the procedure for SPSH devices 500a, 500b, 500c, and 500d to communicate under the control of communication device 600.

[0083] As shown in FIG. 7A, the communication device 600 includes the scheduling information 1000 in one or more beacon frames, and transmits the beacon frames to the BTI of the nth beacon interval (step S2201).

[0084] Communication devices 500a, 500b, 500c, and 500d receive beacon frames.

[0085] FIG. 8 illustrates a measurement request transmitted by the AP/PCP communication device 600. The communication device 600 transmits the measurement requests to the communication devices (communication devices 500a and 500b) for which a valid SP is allocated. Measurement queries may include sub-elements of the standard extension 11ay in the optional sub-elements field shown in FIG. 8 (step S2202).

[0086] The measurement configuration sub-element 3001 is one of the standard 11ay extension sub-elements shown in FIG. 8. The measurement configuration sub-element 3001 includes information about the measurement channel and how the measurement result report is generated for each antenna.

[0087] The measurement extended configuration sub-element 3002 is another of the standard 11ay extension sub-elements shown in FIG. 8. Sub-element 3002 of the extended measurement configuration includes information about the start time of the measurement and the duration of the measurement for each measurement channel.

[0088] The communication device 600 transmits measurement requests to the communication devices (communication devices 500c and 500d) for which a potential SP is allocated (step S2203).

[0089] In the allocated period SP1100, the communication devices 500a and 500b transmit and receive data frames using SISO communication and SU-MIMO communication (step S2204).

[0090] The communication devices 500c and 500d measure the amount of interference power (ANIPI or RSNI) in the assigned period SP1100 based on the information in the measurement request received in step S2203 (steps S2205a, S2205b). The communication devices 500c and 500d are configured to perform interference measurements using a plurality of antenna arrays.

[0091] In steps 2205a and 2205b, communication devices 500c and 500d may determine whether to perform an interference measurement using a receive antenna configuration based on SISO beamforming learning (referred to as "measurement using SISO configuration"), or to perform an interference measurement using a receive antenna configuration based on SU-MIMO beamforming learning (referred to as "measurement using SU-MIMO configuration").

[0092] As an example, if it is determined that the amount of interference power is large, after measurement using the SU-MIMO configuration (for example, if the interference power level is lower than the SINR required for the modulation and coding scheme (MCS), used in SU-MIMO communication in the SP1200), the communication devices 500c and 500d can be switched to the measurement mode using the SISO configuration and can report each measurement result using the SISO and SU-MIMO configurations in steps 2208c and 2208d described below.

[0093] In the dedicated period SP1200, the communication devices 500c and 500d transmit and receive data frames (step S2206).

[0094] The communication devices 500a and 500b measure the amount of interference power (ANIPI or RSNI) in the assigned period SP1200 based on the information in the measurement request received in step S2202. In steps 2207a and 2207b, communication devices 500a and 500b may determine whether to perform interference measurement using the SISO configuration or perform interference measurement using the SU-MIMO configuration (steps S2207a, S2207b).

[0095] In steps S2202 and S2203, the AP/PCP communication device 600 may send measurement requests including information for determining whether individual communication devices 500a, 500b, 500c, and 500d other than AP/PCP devices perform interference measurement using SISO configurations or perform interference measurements using a MIMO configuration.

[0096] The communication device 500a other than the AP/PCP device transmits a measurement report including the interference power value measured in step S2207a and information determining whether the measured interference power value is obtained by measurement using the SISO configuration or measurement using a MIMO configuration, to the AP/PCP communication device 600 . In one example, the measurement report is a MAC frame including measurement report element 3100 (step S2208a).

[0097] In steps S2202 and S2203, communication device 600 may transmit a measurement request including information specifying which measurement (using SISO communication, SU-MIMO communication, or SISO and SU-MIMO communication) is required by devices 500a, 500b, 500c, and 500d connections. In one example, communication device 600 may include in the measurement request a field similar to receive antenna configuration type field 3116 (FIG. 10) described below.

[0098] In this way, communication devices 500a, 500b, 500c, and 500d can perform measurement in this way, which allows communication device 600 to easily determine whether SPSH can be performed in the case of using SISO communication and SU-MIMO communication, compared to the case where the communication devices perform the measurements, respectively, in different ways.

[0099] FIG. 9 shows an example of the format of a measurement report element 3100 to be included in a measurement report transmitted by a communication device 500 other than an AP/PCP device.

[0100] As shown in FIG. 9, if the value of the measurement type field is set to 13, this indicates that the measurement report frame contains information about the quality of the steered channel.

[0101] The field with optional sub-elements in the measurement report frame includes a measurement configuration sub-element 3101, an extended measurement configuration sub-element 3102, and an extended measurement report sub-element 3103.

[0102] FIG. 10 shows an example of the format of the measurement configuration sub-element 3101.

[0103] The sub-element identifier field 3111a illustrates the type of sub-elements. If the sub-element is a measurement configuration sub-element, the value of the sub-element identifier field is 0. The length field 3112a illustrates the length of the measurement configuration sub-element 3101. Field 3113 bitmap of the measurement channel illustrates the set of channel numbers in which the measurement is performed. The channel measurement report output method field 3114 indicates whether each result for each measured channel of the plurality of channels should be reported or the average of the results should be reported. An antenna measurement report output method field 3115 indicates whether each result for each measured antenna of the plurality of receive antennas should be reported, or whether the average of these results should be reported.

[0104] The receive antenna configuration type field 3116 illustrates the type of measurement results included in sub-element 3103 of the extended measurement report. If the value of the receive antenna configuration type field 3116 is 0, the measurement result is based on a measurement made using SISO. If the value of the receive antenna configuration type field 3116 is 1, the measurement result is based on a measurement made using SU-MIMO. If the receive antenna configuration type field 3116 is 2, the measurement result is based on measurements made using SISO and SU-MIMO. The reserved field 3117 is a reserved field for future extensions, so that in this embodiment, communication devices 500 and 600 perform processing without considering the value of this field.

[0105] FIG. 11 shows an example of the format of an extended measurement configuration sub-element 3102.

[0106] The value of the sub-element identifier field 3111b set to 1 indicates that it is a sub-element of the extended measurement configuration. The length field 3112b shows the length of the extended measurement configuration sub-element 3102.

[0107] When the number of measurement channels is two or more, the measurement start time field 3121-2 for the 2nd reported channel and the 1st receive antenna configuration contains information about the measurement start time in the second measurement channel using the configuration of the first antennas. It should be noted that the measurement start time information in the first measurement channel using the first antenna configuration may be included in the measurement start time field of the measurement report frame (FIG. 9) instead of the extended measurement configuration sub-element 3102.

[0108] Similarly, if the number of measurement channels is Nch, the fields from the measurement start time field 3121-2 for the 2nd reported channel and the 1st receive antenna configuration to the measurement start time field 3121-Nch for Nch- th reported channel and the configuration of the 1st receiving antenna contain information about the start time of measurements using the configuration of the first antenna in each of the measurement channels from the second to Nch.

[0109] In case the number of measurement channels is Nch, the fields from the measurement duration field 3122-2 for the 2nd reported channel and 1st receive antenna configuration to the measurement duration field 3122-Nch for the Nch reported channel and configuration The 1st receiving antenna contains duration information when measured using the configuration of the first antenna in each of the measurement channels from the second to Nch. It should be noted that information about the duration of measurements using the first antenna configuration in the first measurement channel may be included in the measurement duration field of the measurement report frame (FIG. 9) instead of the extended measurement configuration sub-element 3102.

[0110] In case the number of measurement channels is Nch, the fields from the number of time blocks for the 2nd reported channel and the 1st receive antenna configuration field 3123-2 (field value: N _2.1 ) to the field 3123-Nch the number of time blocks for the Nch-th reported channel and the configuration of the 1st receive antenna (field value: N _{Nch, 1} ) contain information about the number of measurement blocks using the configuration of the first antenna in each of the measurement channels from the second to Nch. It should be noted that information on the number of measurement blocks using the first antenna configuration in the first measurement channel may be included in the number of time blocks field (field value: N) of the measurement report frame (FIG. 9) instead of the extended measurement configuration sub-element 3102.

[0111] In case the number of measurement channels is Nch, the fields from the measurement start time field 3124-1 for the 1st reported channel and the 2nd receive antenna configuration to the measurement start time field 3124-Nch for the Nch-th reported channel and the configurations of the 2nd receive antenna contain information about the start time of measurements using the configuration of the second antenna in each of the measurement channels from the first to Nch.

[0112] If the number of measurement channels is Nch, the fields from the measurement duration field 3125-1 for the 1st reported channel and 2nd receive antenna configuration to the measurement duration field 3125-Nch for the Nch reported channel and configuration The 2nd receive antennas contain duration information when measured using the second antenna configuration in each of the measurement channels from the first to Nch.

[0113] In case the number of measurement channels is Nch, the fields from field 3126-1 of the number of time blocks for the 1st reported channel and the configuration of the 2nd receive antenna (field value: N _1.2 ) to the field 3126-Nch the number of time blocks for the Nch-th reported channel and the configuration of the 2nd receive antenna (field value: N _{Nch, 2} ) contain information about the number of measurement blocks using the configuration of the second antenna in each of the measurement channels from the first to Nch.

[0114] FIG. 12 shows an example format for sub-element 3103 of an extended measurement report.

[0115] The value of the sub-item ID field 3111c set to 2 indicates that it is a sub-item of the extended measurement report. The length field 3112c illustrates the length of the sub-item 3103 of the extended measurement report.

[0116] When the number of measurement channels is Nch, in the fields from the field 3131-1 of the receive antennas for the 1st reported channel and the configuration of the 1st receive antenna (field value: N _{RX, 1.1} ) to the field 3131 -Nch number of receive antennas for 1st reported channel and 1st receive antenna configuration (field value: N _{RX, Nch,1} ) indicates the reported number of measuring antennas, which is included in each of the fields from field 3132-1 of the measurements for 1 -th reported channel and 1st receive antenna configuration to field 3132-Nch of measurement results for the 1st reported channel and 1st receive antenna configuration.

[0117] In case the number of measurement channels is Nch, the fields from the measurement results field 3132-1 for the 1st reported channel and configuration of the 1st receive antenna to the measurement results field 3132-Nch for the 1st reported channel and configuration The 1st receive antennas contain information about the interference power (for example, RSNI or ANIPI) when measured using the first antenna configuration in each of the measurement channels from the first to Nch.

[0118] The fields from the field 3132-1 of the measurements for the 1st reported channel and the configuration of the 1st receive antenna to the field 3132-Nch of the measurements for the 1st reported channel and the configuration of the 1st receive antenna may contain a plurality of measured values ( eg RSNI or ANIPI) corresponding to the number of measurement units (field values 3123-2 to 3123-Nch in FIG. 11) and the reported number of measurement antennas (field values 3131-1 to 3131-Nch) separately.

[0119] For example, the measurement results field 3132-Nch for the 1st reported channel and the 1st receive antenna configuration contains N _Nch,1 ×N _{RX, Nch,1} measured values, since the number of measurement units is N _Nch,1 (see . field 3123-Nch in FIG. 11) and the number of reported measuring antennas is N _{RX, Nch,1} .

[0120] If the value of the measurement report output method field 3115 (FIG. 10) is 0, the communication device 500a may perform measurements on each of the antenna arrays 101a and 101b, and may transmit measured values for the respective antenna arrays by including the measured values in the fields 3132-1 to 3132-Nch. In other words, it is possible to set the reported measurement antennas N _{RX, Nch, 1} to the number of receive antennas equipped with the communication device 500a other than the AP/PCP device.

[0121] If the value of the measurement report output method field 3115 (FIG. 10) is 1, the communication device 500a can report the average value of the measurement results for the respective antenna arrays 101a and 101b by including the measurement results in fields 3132-1 to 3132-Nch . In other words, the reported measurement antennas N _{RX, Nch, 1} can be set to 1.

[0122] Similarly, the fields from the receive antenna field 3133-2 for the 1st reported channel and the 2nd receive antenna configuration (field value: N _{RX, 1, 2} ) to the receive antenna number field 3133-Nch for the 1st reported channel and 2nd receive antenna configuration (field value: N _{RX, Nch, 2} ) include the number of reported measurement antennas in each of the fields from field 3134-1 of measurements for the 1st reported channel and 2nd receive antenna configuration to fields 3134-Nch of the measurement results for the 1st reported channel and the configuration of the 2nd receive antenna.

[0123] In case the number of measurement channels is Nch, the fields from the field 3134-1 of the measurements for the 1st reported channel and the configuration of the 2nd receive antenna to the field 3134-Nch of the measurements for the Nch-th reported channel and the configuration The 2nd receive antenna contains information about the interference power measured using the configuration of the second antenna in each of the measurement channels from the first to Nch.

[0124] Thus, in one example, after performing the measurement using the SISO and SU-MIMO configurations, the communication device 500a other than the AP/PCP device sets the receive antenna configuration type value (FIG. 10) to 2 and transmits extended measurement configurations and measurement results by including the extended measurement configuration information in the extended measurement configuration sub-element 3102 (FIG. 11) and the measurement result in the extended measurement report sub-element 3103 (FIG. 12), with the first antenna configuration set as the antenna configuration for SISO communication, and the second antenna configuration is set as the antenna configuration for SU-MIMO communication.

[0125] In yet another example, after performing a measurement using the SISO configuration, the communication device 500a other than the AP/PCP device sets the receive antenna configuration type value (FIG. 10) to 0, and transmits the extended measurement configuration information and the measurement results by including the extended measurement configuration information in the extended measurement configuration sub-element 3102 (FIG. 11) and the measurement result in the extended measurement report sub-element 3103 (FIG. 12), with the first antenna configuration set as the antenna configuration for SISO communications.

[0126] In yet another example, after performing a measurement using the SU-MIMO configuration, the communication device 500a other than the AP/PCP device sets the receive antenna configuration type value (FIG. 10) to 1 and transmits the extended measurement configuration information and results measurements by including the extended measurement configuration information in the extended measurement configuration sub-element 3102 (FIG. 11) and the measurement result in the extended measurement report sub-element 3103 (FIG. 12), with the first antenna configuration set as the antenna configuration for SU-MIMO communication .

[0127] It should be noted that when the receive antenna configuration type value (FIG. 10) is set to 0 or 1, the communication device 500a other than the AP/PCP device performs transmission by omitting the fields related to the configurations of the second antennas in FIG. 11 and FIG. 12 (3124-1 to 3124-Nch, 3125-1 to 3125-Nch, 3126-1 to 3126-Nch, 3133-1 to 3133-Nch, and 3134-1 to 3134-Nch).

[0128] In addition, when the receive antenna configuration type value (FIG. 10) is set to 0 or 1, the communication device 500a other than the AP/PCP device performs measurement in the second to Nch channel under measurement conditions similar to those in the first channel and may transmit measurement report element 3100, omitting the extended measurement configuration sub-element 3102.

[0129] Similarly, communication devices 500b, 500c, and 500d other than the AP/PCP device also transmit measurement reports including the interference power values measured in steps S2207b, S2205a, and S2205b to the communication device 600 (steps S2208b, S2208c and S2208d).

[0130] The AP/PCP communication device 600, in each of the SISO and SU-MIMO cases, determines whether SPSH can be performed between the current SP1100 and the potential SP1200 after receiving measurement reports including measurement report element 3100 (FIG. 9) , from communication devices 500a, 500b, 500c, and 500d other than the AP/PCP device (step S2209).

[0131] For example, if communication devices 500a, 500b, 500c, and 500d other than AP/PCP devices transmit measurement reports by setting the value of the receive antenna configuration type field to 1 or 2 in steps S2207a, S2207b, S2205a, and S2205b, and the transmitted interference power values do not exceed the reference value, the AP/PCP communication device 600 determines that SPSH can be performed in the SU-MIMO communication mode.

[0132] In this case, in steps S2204a and S2206a described below, SPSH is performed between SP1300 and SP1400 as shown in FIG. 3, and communication devices 500a, 500b, 500c, and 500d may perform SU-MIMO communications on SP1300 and SP1400 intervals.

[0133] In addition, if the communication devices 500a and 500b transmit measurement reports by setting the value of the receive antenna configuration type field 3116 to 1 or 2 in steps S2207a and S2207b, while the communication devices 500c and 500d transmit measurement reports by setting the value of the receive antenna configuration type field 3116 to 0 in steps S2205a and S2205b, and any of the transmitted interference power values do not exceed the reference value, the AP/PCP communication device 600 determines that SPSH can be implemented in the case of applying SU-MIMO in SP1300, and specifies that SPSH can be implemented if SISO is used in the SP1400. If the value of the receive antenna configuration type field 3116 is 2 in steps S2207a and S2207b, the AP/PCP communication device 600 may determine that SPSH can be implemented if SISO is applied in SP1300.

[0134] In step S2210 (FIG. 7B), when determining that SPSH can be performed between the current SP1100 and the potential SP1200, the AP/PCP communication device 600 includes scheduling information 1500 enabling SPSH in a beacon frame and transmits the beacon frame in BTI of the next BI (n+1st beacon interval). In the n+1-th signal interval, the current SP1100 and potential SP1200 are replaced by SP1300 and SP1400, and SP1300 and SP1400 are time-multiplexed (perform SPSH).

[0135] In addition, in step S2210, the communication device 600 includes information indicating a recommended communication method (SISO and/or SU-MIMO) in beacon frames for SP1300 and SP1400. The recommended communication method refers to the communication method determined to be executed in step S2209. The communication device 600, as an example, may include information indicating a recommended communication method in an extended EDMG scheduling element 3201, may include an extended EDMG scheduling element 3201 in a beacon frame, and transmit the beacon frame.

[0136] FIG. 13 illustrates an exemplary format of an EDMG Extended Scheduling element 3201. The communication device 600 includes one EDMG extended scheduling element 3201 per signal frame for each assignment (eg, SP1300, SP1400). The allocation key field includes information (source AID, destination AID, allocation identifier) indicating which allocation corresponds to the EDMG advanced scheduling element 3201.

[0137] In one example, if SISO communication in SP1300 is recommended, communication device 600 includes information that indicates SP1300 in the allocation key field of EDMG Extended Scheduling element 3201 and transmits the allocation key field by setting the value of the recommended transmission scheme field to 0.

[0138] In one example, if SU-MIMO communication in SP1400 is recommended, communication device 600 includes information that indicates SP1400 in the allocation key field of EDMG extended scheduling element 3201, and transmits the allocation key field by setting the value of the recommended transmission scheme field to 1.

[0139] In one example, if SISO and SU-MIMO communication in SP1400 is recommended, in other words, when determining that the amount of interference power generated in SP1300 is small even if either of SISO or SU-MIMO communication is performed in SP1400, the communication device 600 includes information that indicates SP1400 in the allocation key field of the EDMG extended scheduling element 3201, and transmits the allocation key field by setting the value of the recommended transmission scheme field to 2.

[0140] In allocated period SP1300, communication devices 500a and 500b other than AP/PCP devices transmit and receive data frames using the recommended communication scheme (SISO communication and/or SU-MIMO communication) assigned by EDMG Extended Scheduling element 3201 ( step S2204a).

[0141] In allocated period SP1400, communication devices 500c and 500d transmit and receive data frames using the recommended communication scheme (SISO communication and/or SU-MIMO communication) assigned by EDMG extended scheduling element 3201. According to scheduling information 1500, allocated time SP1400 may overlap with allocated time SP1300 (step S2206a).

[0142] In this way, the communication between the communication device 500a and the communication device 500b, and the communication between the communication device 500c and the communication device 500d occur simultaneously, which can improve throughput and radio resource efficiency.

[0143] In Embodiment 1, when scheduling SPSH, communication device 600 includes recommended communication scheme information (SISO communication and/or SU-MIMO communication) in EDMG advanced scheduling element 3201 and performs transmission. Thus, the communication devices 500a, 500b, 500c, and 500d are capable of performing SPSH communication using a low interference receive antenna configuration, which can improve radio frequency efficiency and reduce the communication error rate in Embodiment 1.

[0144] In addition, when receiving a communication request, communication devices 500a, 500b, 500c, and 500d measure interference by selecting or switching the receive antenna configuration to perform SISO and/or SU-MIMO communication, include the communication scheme used for measurement in the report element about the measurement and transmit the measurement report. Thus, communication device 600 can determine whether SPSH can be performed in SISO and/or SU-MIMO communication cases. Thus, the ability for the communication device 600 to determine that SPSH can be performed is increased, allowing for more efficient use of the radio frequency.

[0145] The present invention may be implemented in software, hardware, or software in combination with hardware.

[0146] Each functional block used in the description of each embodiment described above may be partially or wholly implemented by an LSI (large-scale integrated circuit) such as an integrated circuit, and each process described in each embodiment may be partially or wholly controlled the same LSI or a combination of LSI. LSI can be separately formed in the form of microcircuits, or one microcircuit can be made in such a way as to include all or part of the functional blocks. The LSI may include an associated data input and output. LSI in this case may be referred to as IC (integrated circuit), system LSI, super-LSI or ultra-LSI depending on the difference in the degree of integration.

[0147] However, the implementation method of the integrated circuit is not limited to the LSI, and may be implemented using a dedicated circuit, a general purpose processor, or a dedicated processor. In addition, an FPGA (Field Programmable Gate Array) can be used, which can be programmed after the manufacture of the LSI, or a configurable processor, in which the connections and settings of the circuit cells located inside the LSI can be reconfigured. The present invention may be implemented as digital processing or analog processing.

[0148] If the future integrated circuit technology replaces the LSI as a result of the development of semiconductor technology or other modified technology, functional blocks can be combined using the future integrated circuit technology. Biotechnology may also be applied.

[0149] The present invention may be implemented using any type of device, device, or system having a communication function and referred to as a communication device. Some non-limiting examples of such a communication device include a telephone (e.g., cellular (mobile) phone, smartphone), tablet, personal computer (PC) (e.g., laptop, desktop, netbook), camera (e.g., digital camera/camcorder), digital player (digital audio/video player), wearable device (e.g., wearable camera, smart watch, tracker), game console, digital book reader, remote medical device (for telehealth), and a vehicle that provides communication functionality (for example, an aircraft, an airplane, a ship), as well as various combinations of them.

[0150] The communication device is not limited to a portable or wearable device, and may also include any type of appliance, device, or system that is non-portable or stationary, such as a "Home Automation" device (e.g., appliance, lighting, smart meter, control panel) , a vending machine and any other devices in the Internet of Things (IoT) network.

[0151] Communication may include data transmission via a cellular system, a basement wireless backlink, a wireless local area network system, a satellite communication system, and the like. or any selective combination of them.

[0152] The communication device may include a device, such as a controller or sensor, that is connected to the communication device that performs the communication function described in this disclosure. For example, the communication device may include a controller or sensor that generates control signals or data signals used by the communication device that performs the communication function of the communication device.

[0153] A communication device may also include an infrastructure entity such as a base station, access point, and any other device, device, or system configured to communicate with or control devices, such as the devices described in the non-limiting examples above.

[0154] (Disclosure)

A communication device other than an AP/PCP device according to one aspect of the present invention comprises: a receiving circuit that, in operation, receives a measurement request transmitted from an AP/PCP communication device and requests a measurement used to determine whether SPSH can be performed ; and a transmission scheme that, in operation, transmits the measurement result based on the measurement request to the AP/PCP communication device, using a first communication period during which communication is carried out with a first communication device other than the AP/PCP device, which represents another communication device other than the AP/PCP device, and represents a communication partner for the communication device other than the AP/PCP device, wherein the transmit circuit and the receive circuit communicate with the first communication device other than the AP/ PCP devices using the first communication scheme, and during the second communication period, during which no communication is performed with the first communication device other than the AP/PCP device, and which is included in the measurement request, the receiving circuit performs, using the first communication schemes, measuring the received signal, wherein the result of said measurement includes information about the measurement of the received signal and information about the first communication scheme.

[0155] An AP/PCP communication device according to the present invention comprises: a transmission circuit that, in operation, transmits a plurality of measurement requests requesting the execution of a measurement used to determine whether SPSH can be performed for a plurality of communication devices other than AP/PCP devices ; and a receiving circuit that, in operation, receives a plurality of measurements taken by a plurality of communication devices other than AP/PCP devices; and a determination circuit that, in operation, determines whether SPSH can be performed based on the plurality of measurement results, wherein each of the plurality of measurement requests includes information about a communication device other than the AP/PCP device that communicates during the first communication period. , and information about the second communication period during which the measurement is performed, and each of the plurality of measurement results includes information about the communication scheme used in the measurement and the measurement result.

[0156] Japanese Patent Application Disclosure No. 2018-211656, filed November 9, 2018, including the description, drawings, and abstract, is incorporated herein by reference in its entirety.

INDUSTRIAL APPLICABILITY

[0157] The present invention is useful as an AP/PCP communication device that performs SPSH scheduling and a communication device other than an AP/PCP device that performs SPSH.

List of reference positions

[0158]

100a, 100b, 100c, 100d, 200, 500a, 500b, 500c, 500d, 500e, 600 Communication device

101a, 101b Antenna array

102a, 102b Switch circuit (SW)

103a, 103b RF transmission scheme

104a, 104b RF receiving circuit

109, 109a RF module diagram

110, 110a PHY scheme

111a, 111b D/A Converter

112a, 112b A/D converter

113 Antenna array beam control scheme

114 Coding and modulation scheme

115 Demodulation and decoding scheme

120 MAC Diagram

121 Access Control Scheme

122 Frame generation scheme

123 Frame reception scheme

124 Beamforming control circuit

Claims (57)

1. A communication device other than an AP/PCP device, comprising: a receiving circuit that, in operation, receives a measurement request from the AP/PCP communication device; And a transmission scheme that, in operation, in response to a measurement request, performs a measurement during an active service period (active SP) other than a potential service period (potential SP) to which a communication device other than an AP/PCP device belongs, and other communication device other than the AP/PCP device, and in operation transmits a report that includes the measurement result, while in response to the AP/PCP communication device scheduling a potential SP that overlaps the actual SP in time after receiving the report, the receiving circuit receives a frame containing a recommended transmission scheme field that indicates the recommended transmission scheme to be applied in the potential SP. 2. The communication device other than the AP/PCP device of claim 1, wherein a measurement request is sent from the AP/PCP communication device to evaluate the spatial separation capability between the current SP and the potential SP. 3. The communication device other than the AP/PCP device of claim 1, wherein the SISO receive antenna configuration or the single user MIMO (SU-MIMO) receive antenna configuration is used in the measurement during the active SP. 4. The communication device other than the AP/PCP device of claim 1, wherein the measurement request includes a receive antenna configuration type field that indicates whether a SISO receive antenna configuration is requested for use in the measurement, or whether a single user MIMO receive antenna configuration is requested (SU- MIMO) for use in measurement. 5. The communication device other than the AP/PCP device of claim 1, wherein the report includes a receive antenna configuration type field that indicates whether the receive antenna configuration used in the measurement is a SISO receive antenna configuration or a single user receive antenna configuration. MIMO (SU-MIMO). 6. The communication device other than the AP/PCP device of claim 1, wherein the recommended transmission scheme indicated by the recommended transmission scheme field is a SISO transmission or a Single User MIMO (SU-MIMO) transmission. 7. The communication device other than the AP/PCP device according to claim 1, wherein the measurement is performed in a first beacon interval in which the active SP and the potential SP are scheduled for different time periods; And the spatial separation is performed in the second beacon interval in which the potential SP is scheduled to overlap the actual SP in time. 8. The communication device other than the AP/PCP device of claim 1, wherein the measurement request includes fields for specifying channel information, measurement result reporting method, measurement start time, measurement duration, and number of time blocks. 9. A communication method for a communication device other than an AP/PCP device, comprising: receiving a measurement request from the AP/PCP communication device; in response to a measurement request, performing a measurement during an active service period (active SP) other than a potential service period (potential SP) that includes a communication device other than the AP/PCP device and another communication device other than the AP/ PCP devices; transmitting a report that includes the measurement result; And in response to the AP/PCP communication device scheduling a potential SP that overlaps the actual SP in time after receiving the report, receiving a frame containing a recommended transmission scheme field that indicates a recommended transmission scheme to be applied in the potential SP. 10. The communication method of claim 9, wherein a measurement request is sent from the AP/PCP communication device to evaluate the spatial separation capability between the current SP and the potential SP. 11. The communication method of claim 9, wherein a SISO receive antenna configuration or a single user MIMO (SU-MIMO) receive antenna configuration is used in the measurement during an active SP. 12. The communication method of claim 9, wherein the measurement request includes a receive antenna configuration type field that indicates whether a SISO receive antenna configuration is requested for use in the measurement, or whether a single-user MIMO (SU-MIMO) receive antenna configuration is requested for use in the measurement. . 13. The communication method of claim 9, wherein the report includes a receive antenna configuration type field that indicates whether the receive antenna configuration used in the measurement is a SISO receive antenna configuration or a single user MIMO (SU-MIMO) receive antenna configuration. 14. The communication method of claim 9, wherein the recommended transmission scheme indicated by the recommended transmission scheme field is a SISO transmission or a Single User MIMO (SU-MIMO) transmission. 15. The communication method according to claim 9, in which the measurement is performed in the first signal interval, in which the current SP and the potential SP are scheduled for different time periods; And the spatial separation is performed in the second beacon interval in which the potential SP is scheduled to overlap the actual SP in time. 16. The communication method of claim 9, wherein the measurement request includes fields for specifying channel information, measurement result reporting method, measurement start time, measurement duration, and number of time blocks. 17. An AP/PCP communication device, comprising: a transmission circuit that, in operation, transmits measurement requests to the first pair of communication devices other than the AP/PCP device and the second pair of communication devices other than the AP/PCP device; And a receiving scheme that, in operation, receives from a first pair of communication devices other than the AP/PCP device a first report that includes a measurement result during a valid service period (valid SP), and receives from a second pair of communication devices other than the AP /PCP Devices, a second report that includes a measurement result during a potential maintenance period (potential SP); And a determination scheme that, in operation, evaluates the possibility of a spatial separation between the current SP and the potential SP based on the received first report and the second report; And in response to determination by the determination scheme that spatial separation is possible, the determination scheme schedules a potential SP that overlaps the actual SP in time, and the transmission scheme transmits to the first pair of communication devices other than the AP/PCP device a frame containing the recommended transmission scheme field , which indicates the recommended transmission scheme to be applied in the potential SP. 18. The AP/PCP communications apparatus of claim 17, wherein the measurement request includes a receive antenna configuration type field that indicates whether a SISO receive antenna configuration is requested for use in the measurement, or whether a Single User MIMO (SU-MIMO) receive antenna configuration is requested for use in measurement. 19. The AP/PCP communication device of claim 17, wherein the recommended transmission scheme indicated by the recommended transmission scheme field is a SISO transmission or a Single User MIMO (SU-MIMO) transmission. 20. The AP/PCP communication device according to claim 17, wherein the measurement by the first pair of communication devices other than the AP/PCP device and the second pair of communication devices other than the AP/PCP device is performed in a first beacon interval in which the current SP and the potential SP are scheduled for different time periods; And the spatial separation is performed in the second beacon interval in which the potential SP is scheduled to overlap the actual SP in time. 21. The AP/PCP communication device of claim 17, wherein the measurement request includes fields for specifying channel information, measurement result reporting method, measurement start time, measurement duration, and number of time blocks. 22. A communication method for an AP/PCP communication device, comprising: transmitting a measurement request to a first pair of communication devices other than the AP/PCP device and a second pair of communication devices other than the AP/PCP device; And receiving from the first pair of communication devices other than the AP/PCP device a first report that includes a measurement result during the valid service period (valid SP) and receiving from the second pair of communication devices other than the AP/PCP device a second report, which includes the measurement result during the potential service period (potential SP); evaluating the possibility of spatial separation between the current SP and the potential SP based on the received first report and the second report; And in response to determining that spatial separation is possible, scheduling a potential SP that overlaps the actual SP in time, and transmitting to the first pair of communication devices other than the AP/PCP device a frame containing a recommended transmission scheme field that indicates the recommended transmission scheme to be applied in a potential SP. 23. The communication method of claim 22, wherein the measurement request includes a receive antenna configuration type field that indicates whether a SISO receive antenna configuration is requested for use in the measurement, or whether a single-user MIMO (SU-MIMO) receive antenna configuration is requested for use in the measurement. . 24. The communication method of claim 22, wherein the recommended transmission scheme indicated by the recommended transmission scheme field is a SISO transmission or a single user MIMO (SU-MIMO) transmission. 25. The communication method of claim 22, wherein the measurement by the first pair of communication devices other than the AP/PCP device and the second pair of communication devices other than the AP/PCP device is performed in the first beacon interval in which the effective SP and potential SP are scheduled for different time periods; And the spatial separation is performed in the second beacon interval in which the potential SP is scheduled to overlap the actual SP in time. 26. The communication method of claim 22, wherein the measurement request includes fields for specifying channel information, measurement result reporting method, measurement start time, measurement duration, and number of time blocks. 27. An integrated circuit containing: at least one input that, in operation, receives an input signal; And a control circuit connected to at least one input, wherein in operation the control circuit controls: receiving a measurement request from the AP/PCP communication device; in response to a measurement request by performing a measurement during an active service period (active SP) other than a potential service period (potential SP) that includes a communication device other than the AP/PCP device and another communication device other than the AP/ PCP devices; sending a report that includes the measurement result; And in response to the AP/PCP communication device scheduling a potential SP that is overlaid by a valid SP in time upon receipt of the report, by receiving a frame containing a recommended transmission scheme field that indicates a recommended transmission scheme to be applied in the potential SP. 28. An integrated circuit containing: control scheme, which in the process controls: transmitting measurement requests to a first pair of communication devices other than the AP/PCP device and a second pair of communication devices other than the AP/PCP device; And receiving from a first pair of communication devices other than the AP/PCP device a first report that includes a measurement result during a valid service period (valid SP), and receiving from a second pair of communication devices other than the AP/PCP device a second report , which includes the measurement result during the potential service period (potential SP); evaluating the possibility of spatial separation between the current SP and the potential SP based on the received first report and the second report; And in response to determining that spatial separation is possible, scheduling a potential SP that overlaps the actual SP in time, and transmitting to the first pair of communication devices other than the AP/PCP device a frame containing a recommended transmission scheme field that indicates the recommended transmission scheme , to be applied in a potential SP; And at least one output connected to the control circuit, said at least one output transmitting an output signal during operation.

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