JP2014090336A - Method to transmit control variable as signal in wlan system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication method for permitting many unused entries for future expansion in an MCS table.SOLUTION: In the radio communication method, one of parameters includes: a step of signaling one of a modulation and coding scheme (MCS), the number of space-time stream (N), and indicators (STBC) that indicates whether a space-time block coding can be applied to each space stream; and a step of transmitting a preamble in a frame. A value of the parameter represents an index for a signaling table, and the signaling table includes unused entry and entries corresponding to combinations of every effective value of one of MCS, N, and STBC. Total number of the entries in the signaling table is 2, where n is a positive integer in which the number of the entries corresponding to the combinations of every effective value in at least one of the MCS, Nand STBC is larger than 2.

Description

  The present invention relates generally to wireless communications, and more particularly to a method for signaling control variables in a WLAN (Wireless Local Area Network) system.

  The IEEE (Institute of Electrical and Electronics Engineers) 802.11ah task group has unlicensed bands below 1 GHz, such as 868 MHz to 868.6 MHz (Europe), 920.6 MHz to 928 MHz (Japan), and 902 MHz to 928 MHz (United States). The specification that defines the OFDM (Orthogonal Frequency Division Multiplexing) PHY (physical layer) that operates in (license-exempt band), and the functional extension to the IEEE 802.11 MAC (Media Access Control) that supports this PHY ing. IEEE 802.11ah intends to support multiple channel bandwidths, such as 1 MHz, 2 MHz, 4 MHz, 8 MHz, and 16 MHz, to accommodate different channel assignments assigned under national legislation.

  IEEE 802.11ah usage applications can generally be categorized into sensor and data applications. Sensor applications require low data rates and low duty cycle operation. The IEEE 802.11ah MAC needs to be customized to save battery-powered sensor device power. Data applications demand similar requirements to IEEE 802.11n / 11ac applications that require high data rates, and traffic in data applications is inherently bursty.

  Like IEEE 802.11n / 11ac, IEEE 802.11ah also uses MIMO (Multiple Input Multiple Output) technology, eg, Spatial Multiplexing and STBC (Space Time Block Coding) and higher throughput. And / or achieve greater reliability. Spatial multiplexing is a scheme used in wireless communications to transmit multiple independent and separately encoded data streams from multiple antennas to achieve higher data transfer throughput. Aside from the spatial multiplexing scheme, STBC aims to improve communication reliability by a coding scheme that combines time domain coding of data order exchange and spatial domain coding that changes a signal for each of a plurality of antennas. Used in wireless communication. It is possible to use a combination of both spatial multiplexing and STBC to achieve a trade-off between higher throughput and improved reliability in data transfer.

IEEE 802.11-11 / 1137r11, Proposed Specification Framework for TGah (Proposed Specification Framework for TGah), September 2012

  An object of the present disclosure is to provide a method for wireless communication in which more unused entries can be used for future expansion in a lookup table.

In accordance with this disclosure, a method for wireless communication generates a preamble with a SIG (signal) field in a portion of the preamble to indicate a control variable that includes a plurality of parameters for a particular device. Where one of the plurality of parameters includes a modulation and coding scheme (“MCS”), and a number of space-time streams (“N _sts ”) and space-time block coding for each of the spatial streams Signaling at least one of the indicators (“STBC”) indicating whether or not is applied and transmitting a preamble to the device in the frame.

One value of the parameter indicates an index to the signaling table, which is an unused entry and a combination of all valid values of at least one of “MCS” and “N _sts ” and “STBC”. Including the corresponding entry, the total number of entries in the signaling table is 2 ⁿ , where n is the value of all valid values of at least one of “MCS” and “N _sts ” and “STBC” It is assumed that the number of entries corresponding to the combination is a positive integer that is greater than 2 ⁿ⁻¹ .

  According to the method for wireless communication, entries in a signaling table are ordered based on the complexity of at least one of a MIMO and MCS scheme.

  According to the method for wireless communication, an entry related to at least one of simpler MIMO and MCS schemes is placed at the head of the signaling table.

According to the method for wireless communication, when the parameters signal “MCS” and “N _sts ”, a predetermined number of unused entries and a single space-time stream (ie, N _sts = 1). ) Is placed at the top of the signaling table.

According to the method for wireless communication, if the parameters signal “MCS” and “N _sts ”, a predetermined number of unused entries and entries associated with a single spatial stream are signaled. Located at the top of the table.

According to the method for wireless communication, when the parameters signal “MCS” and “N _sts ”, a predetermined number of unused entries and low-order modulation and single space-time streams (ie, An entry related to both of N _sts = 1) is placed at the top of the signaling table.

According to the method for wireless communication, when the parameters signal “MCS” and “N _sts ”, they are associated with a predetermined number of unused entries and lower-order modulation and single spatial streams. An entry is placed at the top of the signaling table.

  According to the method for wireless communication, when the parameters signal “MCS” and “STBC”, a predetermined number of unused entries and STBC are not applied to any spatial stream. The entry associated with the display (ie “STBC” = 0) is placed at the beginning of the signaling table.

  According to the method for wireless communication, when the parameters signal “MCS” and “STBC”, a predetermined number of unused entries and entries related to low-order modulation are stored in the signaling table. Placed at the beginning of

  According to the method for wireless communication, when the parameters signal “MCS” and “STBC”, a predetermined number of unused entries, low-order modulation, and STBC are in any spatial stream. Is also placed at the top of the signaling table that is associated with both indications that do not apply to (ie, “STBC” = 0).

According to the method for wireless communication, when the parameters signal “MCS”, “STBC”, and “N _sts ”, a predetermined number of unused entries and low-order modulation and single time are used. An entry associated with the spatial stream (ie, N _sts = 1) is placed at the beginning of the signaling table.

According to the method for wireless communication, when the parameters signal “MCS”, “STBC”, and “N _sts ”, a predetermined number of unused entries and lower-order modulation and single space are used. An entry associated with both of the streams is placed at the beginning of the signaling table.

  A better understanding of the features and advantages of the present disclosure will be obtained from the following detailed description of the disclosure, taken in conjunction with the accompanying drawings, and from the claims.

In this disclosure, the signaling bits required for “N _sts ”, “STBC”, and “MCS” in the SIG field should be as small as possible or not in the MCS table. The control variable information included in the SIG field, in particular, MCS and MIMO information, is transmitted as a signal so as to increase the number of bits used for the use entry as much as possible (configures a preamble signal). Furthermore, the order of entries in the combined signaling table is determined based on the complexity of the MIMO scheme, ie the number of spatial streams, or the complexity of the MCS scheme, the number of modulation multi-levels and the coding rate.

  This allows more unused entries in the MCS table to be used for future expansion.

A diagram showing an example of a MIMO (multiple input multiple output) WLAN (wireless local area network) system The figure which shows an example of AP (access point) and two UTs (user terminal) The figure which shows TX processor of the 1st example The figure which shows TX processor of the 2nd example The figure which shows an example of the structure of a PHY frame The figure which shows an example of the SIG (signal) field of a PHY frame FIG. 4 is a diagram illustrating an example of a 4-bit MCS (modulation and coding scheme) table. The figure which shows an example of the SIG field of the PHY frame in 1st Embodiment of this indication The figure which shows an example of the 6-bit MCS-N _sts table in the 1st aspect of 1st Embodiment of this indication The figure which shows an example of the 6-bit MCS-N _sts table in the 2nd aspect of 1st Embodiment of this indication 7 is a flowchart illustrating a method for determining the number of unused entries arranged at the head of a 6-bit MCS-N _sts table according to the first embodiment of the present disclosure. The figure which shows an example of the 6-bit MCS-N _sts table in the 3rd aspect of 1st Embodiment of this indication The figure which shows an example of the 6-bit MCS-N _sts table in the 4th aspect of 1st Embodiment of this indication The figure which shows an example of the 6-bit MCS-N _sts table in the 5th aspect of 1st Embodiment of this indication The figure which shows an example of the SIG field of the PHY frame in 2nd Embodiment of this indication The figure which shows an example of a 5-bit MCS-STBC table in the 1st aspect of 2nd Embodiment of this indication The figure which shows an example of a 5-bit MCS-STBC table in the 2nd aspect of 2nd Embodiment of this indication 9 is a flowchart illustrating a method for determining the number of unused entries arranged at the beginning of a 5-bit MCS-STBC table according to the second embodiment of the present disclosure. The figure which shows an example of a 5-bit MCS-STBC table in the 3rd aspect of 2nd Embodiment of this indication The figure which shows an example of a 5-bit MCS-STBC table in the 4th aspect of 2nd Embodiment of this indication The figure which shows an example of the SIG field of the PHY frame in the third embodiment of the present disclosure. The figure which shows an example of 6-bit MCS-STBC-N _sts table in the 1st aspect of 3rd Embodiment of this indication. The figure which shows an example of the 6-bit MCS-STBC-N _sts table in the 2nd aspect of 3rd Embodiment of this indication 9 is a flowchart illustrating a method for determining the number of unused entries arranged at the beginning of a 6-bit MCS-STBC-N _sts table according to the third embodiment of the present disclosure. The figure which shows an example of the 6-bit MCS-STBC-N _sts table in the 3rd aspect of 3rd Embodiment of this indication

  Hereinafter, various embodiments of the present disclosure will be described in detail with reference to the accompanying drawings. In the following description, detailed descriptions of well-known functions and configurations incorporated therein are omitted for clarity and brevity.

<Background to this disclosure>

  FIG. 1 illustrates an example MIMO WLAN system 100 with access points and user terminals. For simplicity, only one AP (Access Point) 110 is shown in FIG. An AP is generally a fixed station that communicates with user terminals. A UT (user terminal) can be a fixed terminal or a mobile terminal. Some of the UTs, such as 120b, 120d, 120e, and 120f, can be specialized for data application usage. Other UTs, such as 120a and 120c, can be specialized for sensor applications.

  When operating as SU-MIMO (Single User-MIMO), the AP 110 can communicate with one UT 120 at a given time in the downlink and uplink. Here, the downlink is a communication line from the AP 110 to the UT 120, and the uplink is a communication line from the UT 120 to the AP 110. On the other hand, during MU-MIMO (multi-user-MIMO) operation, the AP 110 can communicate with more than one UT 120 at a given time in the downlink and uplink.

  Note that in this disclosure, SU-MIMO is considered. As shown in FIG. 1, a UT may also perform peer-to-peer communication with another UT, such as 120e and 120f. A controller 130 is associated with the AP and provides coordination and control information for the AP.

  To perform downlink and uplink data transmission using SU-MIMO, AP 110 is equipped with multiple antennas. A UT may be equipped with multiple antennas or a single antenna, depending on the type of UT.

  A UT used for data application applications, such as 120b, 120d, 120e, or 120f, may have multiple antennas, and a UT used for sensor application applications, such as UT 120a or UT 120c, is a single There may be an antenna. For UTs equipped with multiple antennas, both spatial multiplexing and STBC can be used for both downlink and uplink. However, for UTs equipped with a single antenna, STBC can be used for the downlink.

FIG. 2 is a block diagram illustrating the AP 110 and the two UTs 120 a and 120 d in the MIMO WLAN system 100. The _AP110, antenna 232a~232b of _{N ap} number _(N ap> 1) is equipped. UT120d is configured for data _{applications, N} antenna 282da~282db of _ut number _(N ut> 1) is equipped.

The UT 120a is configured for sensor applications and includes a single antenna 282a (ie, N _ut = 1). The AP 110 includes a downlink transmission device and an uplink reception device. The UT 120 includes an uplink transmission device and a downlink reception device.

  On the uplink, at the UT 120 where the uplink transmitter is selected, the TX processor 254 receives traffic data from the data source 252 and the preamble from the controller 260. The preamble consists of control variable information about transmission traffic data, such as MCS (modulation and coding scheme) and MIMO information. Both traffic data and preamble are transmitted from the UT 120 to the AP 110 in the form of a PHY frame.

TX processor 254 generates _{N ut} number of transmitting control symbol stream for _{N ut} antennas processing is performed in the preamble portion of the PHY frame. TX processor 254 also generates N _ut number of transmitting data symbol streams for the N _ut antennas by performing the processing of the data portion of the PHY frame based on the control variable information.

A TU (Transmitter Unit) 280 receives and processes (eg, converts to analog, amplifies, filters, and frequency upconverts) each transmission control or data symbol stream and generates an uplink signal. N _ut TUs 280 provide N _ut uplink signals for transmission from N _ut antennas 282 to AP 110.

In the AP 110, N _ap antennas 232 a to 232 b receive N _ut uplink signals from the UT 120. Each antenna 232 provides a received signal to a respective RU (receiver unit) 230. Each RU 230 performs a complementary process to that performed by TU 280 and provides a receive control or data symbol stream. RX processor 224, _first, performs receiver processing on the _{N ap} number of the received control symbol streams from _{N ap} number of RU 230, to acquire the control variable information. RX processor 224 proceeds to execute the processing receiver for _{N ap} number of received data symbol streams from _{N ap} number of RU 230 in accordance with acquired control variable information, the decoded data portion of the PHY frame for the UT120 Acquire, which may be provided to the data sink 222 for data retention and / or provided to the controller 210 for further processing.

  On the downlink, at the AP 110, the TX processor 204 receives traffic data for the UT 120 scheduled for downlink transmission from the data source 202, a preamble from the controller 210, and possibly other data from the scheduler 212. . The preamble includes control variable information for transmitting traffic data, such as MCS and MIMO information. Both traffic data and preamble are transmitted from the AP 110 to the UT 120 in the form of a PHY frame.

TX processor 204 generates an _{N ap} number of transmitting control symbol stream for _{N ap} antennas by performing the processing of the preamble portion of the PHY frame. TX processor 204 also generates N _ap number of transmitting data symbol streams for the N _ap antennas performs processing of the data portion of the PHY frame based on the control variable information. Each TU 230 receives and processes a respective transmission control or data symbol stream to generate a downlink signal. N _ap TUs 230 provide N _ap downlink signals for transmission from N _ap antennas 232 to UT 120.

In the UT 120, N _ut antennas 282 receive N _ap downlink signals from the AP 110. Each RU 280 performs a complementary process to that performed by TU 230 and provides a receive control or data symbol stream. RX processor 274, _first, performs receiver processing on the _{N ut} number of received control symbol streams from _{N ut} number of RU 280, to acquire the control variable information. RX processor 274 proceeds to perform receiver processing for _{N ut} pieces of received data symbol streams from _{N ut} number of RU 280 on the basis of the acquired control variable information, decoded data portion of the PHY frame for the UT120 Which may be provided to the data sink 272 for data retention and / or provided to the controller 260 for further processing.

  Note that the TX processor 204 or 254 in FIG. 2 can employ different processing architectures for the preamble portion and the data portion of the PHY frame. Also, the processing architecture adopted by the TX processor 204 or 254 for the data portion of the PHY frame may have a function that can be changed according to changes in rate dependent parameters such as MCS and MIMO information.

  According to the IEEE 802.11ah specification framework document (Non-Patent Document 1), a plurality of MCSs (Modulation and Coding Schemes), that is, MCS0 to MCS10 are supported. FIG. 3 is a block diagram illustrating a first example TX processor 300 for processing the data portion of a PHY frame, which is in accordance with the IEEE 802.11ah specification framework document (Non-Patent Document 1). It is applicable to MCS0 to MCS9. The TX processor 300 refers to the TX processor 204 or the TX processor 254 shown in FIG.

  TX processor 300 includes a scrambler 302 that scrambles the information bit stream of the data portion of the PHY frame to reduce the occurrence of long sequences of 1s or 0s.

  Coupled to the scrambler 302 is an encoder parser 304 that demultiplexes the information bit stream into one or two encoder input streams corresponding to one or two FEC (forward error correction) encoders 306. Turn into.

  The number of FEC encoders is determined by rate dependent parameters. Each FEC encoder 306 encodes a corresponding input stream to generate a corresponding encoded stream. The FEC encoder 306 is, for example, a BCC (binary convolutional code) encoder.

The stream parser 308 splits one or two encoded streams into N _ss spatial streams for independent interleaving and mapping to constellation points.

A spatial stream is a stream of bits or modulation symbols transmitted towards US 120 by multiple spatial dimensions generated using multiple antennas at both ends of the communication link, ie, AP 110. Note that the maximum number of spatial streams is determined in advance, for example, N _ss ≦ 4.

  Corresponding to each spatial stream, the interleaver 310 interleaves the bits of that spatial stream (ie, changes the order of the bits) and ensures that a continuous long sequence of bits with error components enter the receiver's decoder. To prevent. Corresponding to each spatial stream, the constellation mapper 312 maps the interleaved bit sequence to constellation points corresponding to different subcarriers in the OFDM symbol.

The STBC unit 314 receives constellation points corresponding to N _ss spatial streams and spreads the spatial streams into N _sts space-time streams. A spatio-temporal stream is a stream of modulation symbols generated by applying a combination of spatial processing and temporal processing to one or more modulation symbol spatial streams.

The STBC unit 314 can omit the STBC process and simply pass the spatial stream. The relationship between N _ss and N _sts depends on whether STBC is performed. For example, when STBC is applied to N _ss spatial streams, N _sts = 2 × N _ss . When not applicable, N _sts = N _ss . That is, when STBC is applied to N _ss spatial streams, N _ss is either 1 or 2, and N _sts is either 2 or 4. If not applicable, N _ss or N _sts will be one of 1, 2, 3, and 4.

  Multiple cyclic shift diversity (CSD) units 316 insert a cyclic shift into all but one of the space-time streams (if there are more than one space-time streams). The cyclic shift prevents unintended beamforming.

Spatial mapping unit 318 maps N _sts space-time streams to N _tx transmission chains. Spatial mapping is
(1) a direct mapping in which constellation points from each space-time stream are mapped directly onto the transmit chain (ie, a one-to-one mapping);
(2) Spatial expansion where vectors of constellation points from all spatio-temporal streams are expanded via matrix multiplication to create an input to the transmit chain;
And (3) each vector of constellation points from all spatio-temporal streams is multiplied by a matrix of steering vectors to include one or more of the beamformings that create the input to the transmit chain.

  Each output of the spatial mapping unit 318 corresponds to a transmission chain, and an IDFT (Inverse Discrete Fourier Transform) unit that converts a block of constellation points into a time-axis signal is converted to each output of the spatial mapping unit 318. An operation according to 320 is performed.

The output of the IDFT unit 320 is input to a GI (Guard Interval) insertion and window unit 322, and for each OFDM symbol, the OFDM symbol is temporally extended to have the same code state, and the smoothing of the edge of each symbol is performed. A process is performed to increase spectral attenuation.
The output of the GI insertion and window unit 322 is converted to an analog signal at TU 230 or 280 in FIG. 2 and further upconverted to an RF frequency for transmission.

  FIG. 4 is a diagram illustrating a second example TX processor 400 for processing the data portion of a PHY frame, and modulation and encoding according to the IEEE 802.11ah specification framework document (Non-Patent Document 1). It can be applied to MCS 10 which is one of the methods. The TX processor 400 refers to the TX processor 204 or the TX processor 254 shown in FIG.

  TX processor 400 includes a scrambler 402 that scrambles the information bit stream of the data portion of the PHY frame to reduce the occurrence of long sequences of ones or zeros. For example, a BCC encoder is coupled to the scrambler 402 as the FEC encoder 406, and an input stream is encoded to generate an encoded stream.

  The repetition unit 408 performs 2 × block unit repetition on the encoded stream on a per OFDM symbol basis and outputs a single spatial stream for subsequent interleaving and mapping to constellation points.

Since the TX processor 400 does not include STBC units, the spatial stream is actually equal to the spatio-temporal stream, ie N _ss = N _sts = 1. Interleaver 410 interleaves the bits of the spatial stream and prevents long sequences of adjacent noisy bits from entering the receiver's decoder. The constellation mapper 412 then maps the interleaved bit sequence to constellation points corresponding to different subcarriers of the OFDM symbol.

Spatial mapping unit 418 maps the N _tx transmission chains to constellation points corresponding to the spatial stream.

Each output of the spatial mapping unit 418 corresponds to a transmission chain and is input to the respective IDFT unit 420.
Each IDFT unit 420 converts each constellation point into a time axis signal.

The output of the IDFT unit 420 is input to the GI insertion and window unit 422.
The GI insertion and window unit 422 extends each OFDM symbol in the time direction while maintaining the symbol characteristics of the OFDM symbol, and smoothes the edge of each OFDM symbol to increase the spectrum attenuation.

  The output of the GI insertion and window unit 422 is output to the TU 230 or 280 in FIG. The TU 230 or 280 converts the output of the GI insertion and window unit 422 to an analog signal and further upconverts it to an RF frequency for transmission.

  FIG. 5 is an example of the structure of a PHY frame 500 that can be used for SU-MIMO transmission according to the IEEE 802.11ah specification framework document (Non-Patent Document 1). The PHY frame 500 is transmitted, for example, from the AP 110 to the UT 120 in the downlink of the MIMO WLAN system 100 illustrated in FIG. 1 or from the UT 120 to the AP 110 in the uplink.

  The PHY frame 500 includes a preamble 510 and a data portion 508. The preamble 510 further includes an STF (short training field) 502, a plurality of LTFs (long training field) 504, and an SIG (signal) field 506.

  The STF 502 and the first LTF 504a are used to assist the receiver in performing packet detection and in determining the format of the SIG field 506, respectively.

  The remaining LTF 504b is used by the receiver to evaluate the MIMO channel for receiving the data portion 508 of the PHY frame 500. SIG field 506 includes control variable information for transmitting data portion 508 of frame 500. Regarding the transmission processing architecture of the STF 502, the LTF 504, and the SIG field 506, the IEEE 802.11ah specification framework document (Non-patent Document 1) can be referred to.

  FIG. 6 shows an example of a format of the SIG field 506 that can be used for SU-MIMO transmission according to the IEEE 802.11ah specification framework document (Non-Patent Document 1).

In FIG. 6, the SIG field 506 includes STBC (1 bit), smoothing (1 bit), N _sts (2 bits), MCS (4 bits), length (9 bits), aggregation (1 bit), coding (2 Bit), short GI (1 bit), and Ack indication (2 bits). The SIG field 506 also includes 4 CRC (Cyclic Redundancy Check) bits, 6 tail bits, and 3 unused bits.

  Referring to the TX processor 300 shown in FIG. 3 and the TX processor 400 shown in FIG. 4, the 1-bit SIG parameter “STBC” indicates whether STBC is applied to all spatial streams. Indicates. When STBC is not applied to any spatial stream, “STBC” is set to 0. When STBC is applied to each spatial stream, “STBC” is set to 1.

  As shown in FIG. 4, since STBC is not applied to MCS 10, “STBC” is set to 0 for MCS 10.

“N _sts ”, which is a 2-bit SIG parameter, specifies the number of space-time streams. For MCS0 to MCS9, N _sts can be 1, 2, 3, or 4. However, for MCS 10, N _sts needs to be 1 as shown in FIG.

  “MCS”, which is a 4-bit SIG parameter, indicates an index to the MCS table that specifies the MCS used by the data portion 508 of the PHY frame 500.

  FIG. 7 shows an example of a 4-bit MCS table. The definition of the remaining SIG parameters can be referred to by the IEEE 802.11ah specification framework document (Non-Patent Document 1).

  In FIG. 7, MCS0 and MCS10 correspond to modulation using BPSK (binary phase shift keying), MCS1 to MCS2 correspond to modulation using QPSK (quadrature phase shift keying), and MCS3 to MCS4 are 16−. Corresponding to modulation using QAM (Quadrature Amplitude Modulation), MCS5 to MCS7 correspond to modulation using 64-QAM, and MCS8 to MCS9 correspond to modulation using 256-QAM.

  BPSK and QPSK can be classified as low-order modulation, and 16-QAM, 64-QAM, and 256-QAM can be classified as high-order modulation. Lower order modulation (eg, MCS10 and MCS0 to MCS2) requires lower power operation when compared to higher order modulation (eg, MCS3 to MCS9) because lower order modulation is more power efficient than higher order modulation Suitable for UTs aimed at sensor applications.

According to FIGS. 6 and 7, 7 bits are used for signaling of the MIMO and MCS related control variables “N _sts ”, “STBC”, and “MCS” in the SIG field 506, and in the MCS table There are five unused entries.

That is, if fewer signaling bits are used for “N _sts ”, “STBC”, and “MCS”, signaling overhead can be reduced by making SIG field 506 shorter.

  It is also possible to use five unused entries in the MCS table and introduce other PHY / MAC features in the SIG field 506 for future expansion.

For example, several unused entries in the MCS table can be used to display NDP (Null Data Packet) frame types. Therefore, having as few signaling bits as needed for the fewest possible “N _sts ”, “STBC”, and “MCS” in the SIG field 506, or as many as possible in the MCS table. It is preferable to have unused entries.

<Outline of this disclosure>
Referring to FIGS. 3, 4, and 6, it can be seen that several SIG parameters such as “MCS”, “N _sts ”, and “STBC” are interrelated.

For example, the MCS 10 shown in FIG. 7 is valid in the case of a single space-time stream (ie, N _sts = 1 and “STBC” = 0), so “MCS” is actually “N _sts ” and “ Correlation with STBC ". Furthermore, “N _sts ” and “STBC” are also correlated with each other. This is because N _sts is either 2 or 4 when STBC is applied to each of the spatial streams (ie, “STBC” = 1).

Based on the above observations, the present disclosure is combined with at least one of “MCS” and “N _sts ” and “STBC” instead of individually performing their signaling (determination of parameters). I got the basic idea of signaling in the form.

Since correlation exists between the "MCS", _{"N sts",} and "STBC" actually used "MCS", by variable by combining the _{"N sts",} and "STBC" The number of unused entries can be increased.

As a result, the number of bits required to signal and transmit the control variables “MCS”, “N _sts ”, and “STBC” is reduced or the number of unused entries in the combined signaling table is increased. it can.

(First embodiment)
According to the first embodiment of the present disclosure, the basic idea of the method of signaling control variables in the SIG field 506, in particular MCS and MIMO information, combines both SIG parameters “MCS” and “N _sts ”. This is different from the prior art signaling method shown in FIG. 6 in which both “MCS” and “N _sts ” are signaled independently.

FIG. 8 illustrates an example of the SIG field 506 according to the first embodiment of the present disclosure. In FIG. 8, the 6-bit SIG parameter “MCS-N _sts ” is used instead of the 4-bit “MCS” and the 2-bit “N _sts ” illustrated in FIG. 6.

The value indicated by the 6-bit “MCS-N _sts ” indicates an index into the 6-bit MCS-N _sts table and is associated with a specific combination of “MCS” and “N _sts ”.

Note that the 6-bit SIG parameter “MCS-N _sts ” shown in FIG. 8 is the same number of signaling bits as the 4-bit SIG parameter “MCS” and the 2-bit SIG parameter “N _sts ” shown in FIG. 6. Accordingly, the first embodiment of the present disclosure has the same number of unused bits in the SIG field 506 as the prior art of FIG.

An example of a 6-bit MCS-N _sts table according to the first aspect of the first embodiment of the present disclosure is shown in FIG. The entry of the 6-bit MCS-N _sts table includes all valid combinations of “MCS” and “N _sts ”.

Here, the maximum number of spatio-temporal streams is 4 (ie, N _sts ≦ 4), the total number of MCSs is 11, and for N _sts = 1, one of the MCSs (ie, MCS 10) is Correspond.

Therefore, the total number of valid combinations of “MCS” and “N _sts ” is 41. When k = 6, the total number of combinations is larger than 2 ^k−1 and smaller than 2 ^k . Therefore, 6-bit “MCS-N _sts ” is a sufficient number of bits for signaling “MCS” and “N _sts ”.

Further, in the 6-bit MCS-N _sts table, there are 23 (= 64-41) unused entries with respect to 5, which is the number of unused entries in the prior art MCS table shown in FIG. Exists.

An example of the 6-bit MCS-N _sts table in the second mode of the first embodiment of the present disclosure is shown in FIG. In FIG. 10, the entries in the 6-bit MCS-N _sts table are ordered based on the complexity of the MIMO scheme, ie the number of space-time streams, and the entries associated with the simpler MIMO scheme are It is arranged at the head of the 6-bit MCS-N _sts table.

That is, a predetermined number of unused entries and entries associated with a single space-time stream (ie, N _sts = 1) are arranged at the top of the 6-bit MCS-N _sts table. Note that the implementation of the UT 120 becomes easier as the number of space-time streams decreases.

A method 1100 for determining the number of unused entries placed at the beginning of the 6-bit MCS-N _sts table is shown in FIG. Method 1100 begins at step 1102. In step 1104, a positive integer k is determined in which the number of entries associated with a single space-time stream is greater than 2 ^k-1 and not greater than 2 ^k .

That is, the positive integer k can be set up to a maximum of 5. Since the number of entries used is 11, the positive integer k is 3 or more and 5 or less. Here, if k = 3, the number of bits in the MCS-N _sts table can be reduced, and if k = 4 or 5, the number of unused entries can be increased.

Step 1106 checks whether the difference between the number of 2 ^k entries are related to a single space-time stream is less than the number of unused entries.

Single spatiotemporal number of entries to be associated with the stream (11) and ^{2 k (2 3 = 8,2 4} = 16,2 5 = 32,2 6 = 64) difference between (3,5,21,53 ) Is not smaller than the number of unused entries (index 41-63 = 23 unused entries in FIG. 9) (53), all unused entries (at the beginning of the 6-bit MCS-N _sts table) Index 41-63 = 23 unused entries in FIG. 9 can be placed, and the method 1100 ends at step 1108.

If the number is smaller than the number of unused entries (index 41-63 = 23 in FIG. 9), in step 1110, the number of unused entries arranged at the top of the 6-bit MCS-N _sts table is set to a single time. it equal to the difference between the number of 2 ^k entries are related to the spatial streams.

That is, if 2 ⁵ = 32, there are 21 differences, so 21 out of 23 can be set as the index 11-31, and the rest are arranged as the index 62-63 at the end of the table.

  In step 1112, k is incremented by 1 (increased by 1).

Step 1114 checks whether k is less than 6. If k is smaller than 6, the process returns to step 1106 to examine other k values for the number of unused entries arranged at the head of the 6-bit MCS-N _sts table. If k is not less than 6, method 1100 ends at step 1116.

As can be seen from FIG. 11, the number of unused entries arranged at the head of the 6-bit MCS-N _sts table depends on the value of k. For example, in the 6-bit MCS-N _sts table shown in FIG. 9, the number of entries related to a single space-time stream is eleven. That is, INDEX0 to INDEX10 correspond.

According to the method 1100 shown in FIG. 11, the positive integer k is 4 because 2 ^k−1 <11 <2 ^k . Here, if k = 5, the number of unused entries arranged at the top of the k-bit MCS-N _sts table is 21 depending on the difference between the number of entries related to the single space-time stream and 2 ^k. It becomes a piece.

In the example of the 6-bit MCS-N _sts table shown in FIG. 10, the number of entries related to a single space-time stream is 11. According to the method shown in FIG. 11, if k = 5 (2 ⁵ = 32), the number of unused entries arranged at the head of the 6-bit MCS-N _sts table is 21 (= 32− 11). In the example of the 6-bit MCS-N _sts table shown in FIG. 10, 21 unused entries are arranged at the head of the 6-bit MCS-N _sts table.

In FIG. 10, an unused entry arranged at the head of the 6-bit MCS-N _sts table is arranged after an entry related to a single space-time stream.

In place of the 6-bit MCS-N _sts table shown in FIG. 10, an unused entry can be arranged before an entry related to a single space-time stream. Also, unused entries may be mixed with entries associated with a single space-time stream.

Thus, according to the second aspect of the first embodiment of the present disclosure, some UTs 120, eg, battery-powered sensor devices in the WLAN system 100 are a single antenna, so Of the 6-bit MCS-N _sts lookup table shown in FIG. 10, even if a single space-time stream is supported for uplink transmission, but a multi-space-time stream is not supported, The k-bit MCS-N _sts lookup table 1002 may be maintained and checked. K may be 4, 5 or 6.

Here, if the MCS-N _sts lookup table is k = 4 or 5, the UT 120 supporting a single space-time stream for downlink and uplink transmission can reduce memory capacity and power consumption. .

When the memory capacity of the UT 120 is reduced, an unused entry arranged at the top of the k-bit MCS-N _sts lookup table is a new PHY / MAC feature in the SIG field 506 for future expansion. Can be used for the introduction of.

In the second aspect of the first embodiment of the present disclosure, the positive integer is 4 or 5. When using smaller k values, a UT 120 that supports a single space-time stream for downlink and uplink transmissions may have a smaller capacity MCS-N _sts lookup table.

Note that by using smaller k, the number of unused entries that are arranged at the head of the MCS-N _sts lookup table and can be used for future expansion becomes smaller.

That is, in the UT 120 that supports a single space-time stream for downlink and uplink transmission, it is more than the number of unused entries placed at the top of the k-bit MCS-N _sts lookup table. In order to use a small capacity MCS-N _sts lookup table, k is set to 4.

In order to increase the number of unused entries placed at the top of the k-bit MCS-N _sts lookup table, k is set to 5.

An example of the 6-bit MCS-N _sts table in the third mode of the first embodiment of the present disclosure is shown in FIG. In FIG. 12, the entries in the 6-bit MCS-N _sts table are based on the complexity of the MIMO scheme, i.e. the number of space-time streams, and the complexity of the MCS scheme, i.e. the modulation multi-level number and the coding rate. The entries that are ordered and associated with simpler MIMO and MCS schemes are placed at the beginning of the 6-bit MCS-N _sts table.

That is, according to the third aspect of the first embodiment of the present disclosure, a predetermined number of unused entries, and low-order modulation (ie, MCS is based on either BPSK or QPSK) and single Entries associated with both space-time streams (ie, when N _sts = 1) are placed at the beginning of the 6-bit MCS-N _sts table.

  Note that the complexity of the UT 120 implementation becomes smaller as the number of space-time streams and the modulation order decrease.

The number of unused entries arranged at the head of the 6-bit MCS-N _sts table shown in FIG. 12 is the same as the “entries associated with a single space-time stream” shown in FIG. Can be determined using a method similar to the method 1100 shown in FIG.

In the example of the 6-bit MCS-N _sts table shown in FIG. 12, the number of entries related to both the low-order modulation and the single space-time stream is four. According to FIG. 11, the positive integer k can be set to 3 or 4 (2 ³ = 8, 2 ⁴ = 16).

In k = 3 or 4, the number of unused entries placed at the beginning of the k bits of the MCS-N _sts table, the number of is related entries in both the 2 ^k and low-order modulation and a single space-time stream Depends on the difference. For this reason, it can be set to 4 (= 8-4) and 12 (= 16-4).

  The case where k = 5 will be described below.

In FIG. 12, the number of entries used is 41, index0-3 and 16-52. Therefore, the number of unused entries in the 6-bit table is 2 ⁶ −41 = 23.

Here, in step 1106 of FIG. 11, when k = 5, the number of unused entries (23) in the 6-bit MCS-N _sts table is related to both 2 ^k and low-order modulation and single space-time stream. Since it is smaller than the difference (28) from the number of entries to be added, the process proceeds to step 1108.

Therefore, the number of unused entries arranged at the top of the k-bit MCS-N _sts table is 23 when k = 5, and all unused entries can be arranged at the top of the table.

In the example of the 6-bit MCS-N _sts table shown in FIG. 12, twelve unused entries (index 4-15) at k = 4 are arranged at the head of the 6-bit MCS-N _sts table, and the remaining The unused entry (index 53-63) is arranged at the end.

In the 6-bit MCS-N _sts table shown in FIG. 12, the unused entry placed at the beginning of the 6-bit MCS-N _sts table is after the entry related to both the low-order modulation and the single space-time stream. Has been placed.

  Note that unused entries may be placed before entries associated with both low-order modulation and single space-time streams. Unused entries may also be placed mixed with entries associated with both low-order modulation and single space-time streams.

Thus, according to the third aspect of the first embodiment of the present disclosure, several UTs 120 in the WLAN system 100, such as battery-powered sensor devices, can operate at a single time for downlink and uplink transmissions. Supports spatial streams but does not support multi-space-time streams, and for power saving purposes, supports low-order modulation for downlink and uplink transmission, but does not support high-order modulation Even if it is not supported, the k-bit MCS-N _sts lookup table 1202 in the 6-bit MCS-N _sts lookup table shown in FIG. 12 may be maintained and checked. K is 3, 4, or 5.

Thus, a UT 120 that supports both low order modulation and a single space-time stream for downlink and uplink transmissions can reduce memory capacity and power consumption. Note that an unused entry located at the beginning of the 6-bit MCS-N _sts lookup table can be used to introduce new PHY / MAC features in the SIG field 506 for future extensions.

  From the above, the positive integer k can be set to 3, 4 or 5.

In the third aspect of the first embodiment, when a smaller value of k is used, the UT 120 that supports a single space-time stream for downlink and uplink transmissions has a smaller MCS-N _sts lookup Maintain and check the table.

  However, the number of unused entries that are arranged at the top of the table and can be used for future expansion becomes smaller.

By setting a positive integer k to 3, the UT 120 supporting both low-order modulation and single space-time streams for downlink and uplink transmissions maintains the smallest possible MCS-N _sts lookup table can do.

Also, by setting a positive integer to k = 5, the UT 120 can place a larger number of unused entries at the beginning of the 6-bit MCS-N _sts lookup table.

Also, a positive integer k is by setting the 4, UT120 on the size of the _{MCS-N sts} lookup table suitable for the maintenance, it can be placed at the beginning of the 6-bit _{MCS-N sts} lookup table This is compatible with the number of unused entries.

FIG. 13 illustrates an example of a 6-bit MCS-N _sts table according to the fourth aspect of the first embodiment of the present disclosure. In FIG. 13, the entries in the 6-bit MCS-N _sts table are ordered based on the complexity of the MIMO scheme, ie the number of spatial streams, and the entries associated with the simpler MIMO scheme are 6-bit. Arranged at the head of the MCS-N _sts table.

According to the fourth aspect of the first embodiment of the present disclosure, it relates to a predetermined number of unused entries and a single spatial stream (ie, when N _sts = 1 or N _sts = 2). The entry to be attached is arranged at the head of the 6-bit MCS-N _sts table. Note that the implementation of the UT 120 becomes easier as the number of spatial streams decreases.

Further, in this aspect, when the UT 120 is configured using a single antene, even if N _sts = 2, the reception processing is performed assuming that it is a single spatial stream.

The number of unused entries arranged at the top of the 6-bit MCS-N _sts table shown in FIG. 13 is “entries related to a single space-time stream” in the 6-bit MCS-N _sts table shown in FIG. , “Entries associated with a single spatial stream” and can be determined using a method similar to the method 1100 shown in FIG.

For example, in FIG. 13, the number of entries associated with a single spatial stream is 21 in a 6-bit MCS-N _sts lookup table.

The positive integer k can be set to 5 by the method of FIG. For this reason, as shown in FIG. 13, the number of unused entries arranged at the beginning of the 6-bit MCS-N _sts lookup table is 11 depending on the difference between 2 ^k and the number of entries related to the single stream. Can be. (Index21-31 is supported)

In the example of the 6-bit MCS-N _sts table illustrated in FIG. 13, the number of entries related to a single spatial stream is 21. Accordingly, the number of unused entries arranged at the top of the 6-bit MCS-N _sts table is 11, corresponding to index 21-331 in FIG.

In the 6-bit MCS-N _sts table shown in FIG. 13, the unused entry arranged at the head of the 6-bit MCS-N _sts table is arranged after the entry related to the single spatial stream. The unused entry can be arranged before the entry related to the single spatial stream, or may be arranged mixed with the entry related to the single spatial stream.

Thus, according to the fourth aspect of the first embodiment of the present disclosure, some UTs 120 in the WLAN system 100, eg, battery-powered sensor devices, are single antennas, so Of the 6-bit MCS-N _sts look-up table shown in FIG. 13, even if a single spatial stream is supported for uplink transmission, but a multi-space-time stream is not supported, The bit MCS-N _sts lookup table 1302 may be maintained and checked. Here, k is 5.

Thus, a UT 120 that supports a single spatial stream for downlink and uplink transmissions can reduce memory capacity and power consumption. Note that an unused entry located at the beginning of the 6-bit MCS-N _sts lookup table can be used to introduce new PHY / MAC features in the SIG field 506 for future extensions.

FIG. 14 illustrates an example of a 6-bit MCS-N _sts table according to the fifth aspect of the first embodiment of the present disclosure. In FIG. 14, the entries in the 6-bit MCS-N _sts table are ordered based on the complexity of the MIMO scheme, ie, the number of spatial streams, and the complexity of the MCS scheme, and the simpler MIMO and An entry related to the MCS scheme is arranged at the head of the 6-bit MCS-N _sts table.

According to the fifth aspect of the first embodiment of the present disclosure, a predetermined number of unused entries, and low order modulation (ie, MCS is BPSK or QPSK) and a single spatial stream (ie , N _sts = 1 or N _sts = 2) is placed at the head of the 6-bit MCS-N _sts table. Note that the complexity of the UT 120 implementation becomes smaller as the number of spatial streams and the modulation order decreases.

Here, the number of unused entries arranged at the head of the 6-bit MCS-N _sts table shown in FIG. 14 is the same as the 6-bit MCS-N _sts table “entries related to a single space-time stream”. Can be determined using a method similar to the method 1100 shown in FIG. 11, replacing “entries associated with both low order modulation and single spatial stream”.

For example, in the 6-bit MCS-N _sts table shown in FIG. 14, the number of entries related to both the low-dimensional modulation and the single spatial stream is 7.

According to the method of FIG. 11, the positive integer k can be set to 3, 4 or 5. When k is 3 or 4, the number of unused entries to be arranged at the head of the k-bit MCS-N _sts table is determined by the difference between 2 ^k , the number of low-dimensional modulation, and the number related to the single-space outreach. For this reason, 1 (= 8-7) when k = 3, and 9 (= 16-7) when k = 4.

When k is 5, the number of unused entries (index 41-63 = 23) in FIG. 9 is the difference between 2 ^k and entries related to both the low-dimensional modulation and the single spatial stream (2 ⁵ = 32). And 7 = 25). Therefore, the 23 unused entries can be arranged at the head of the 6-bit MCS-N _sts table. That is, the index 45-63 in FIG.

In the example of the 6-bit MCS-N _sts table shown in FIG. 14, the number of entries related to both the low-order modulation and the single spatial stream is seven. Therefore, the number of unused entries arranged at the top of the 6-bit MCS-N _sts table can be set to 1, 9, or 23.

In the example of the 6-bit MCS-N _sts table shown in FIG. 14, at k = 4, 9 unused entries (INDEX7-15) are arranged at the head of the 6-bit MCS-N _sts table. Yes.

In the 6-bit MCS-N _sts table shown in FIG. 14, the unused entry placed at the beginning of the 6-bit MCS-N _sts table is placed after the entry related to both the low-order modulation and the single spatial stream. Has been.

  Note that unused entries may be placed before entries associated with both low-order modulation and single spatial streams, or mixed with entries associated with both low-order modulation and single spatial streams. May be.

Thus, according to the fifth aspect of the first embodiment of the present disclosure, some UTs 120 in the WLAN system 100, eg, battery-powered sensor devices, are single antennas, so Supports single spatial stream for uplink transmission but does not support multi-space-time stream, and supports lower order modulation for downlink and uplink transmission for power saving purposes Even in the case of not supporting higher-order modulation, the k-bit MCS-N _sts lookup table 1402 is maintained in the 6-bit MCS-N _sts lookup table shown in FIG. Just check. Note that k is 3, 4 or 5.

Thus, a UT 120 that supports both low order modulation and a single spatial stream for downlink and uplink transmissions can reduce memory capacity and power consumption. Note that an unused entry located at the beginning of the 6-bit MCS-N _sts lookup table can be used to introduce new PHY / MAC features in the SIG field 506 for future extensions.

Therefore, the positive integer k is 3, 4, or 5. In the fifth aspect of the first embodiment, when using a smaller value of k, the UT 120 that supports a single space-time stream for downlink and uplink transmissions has a smaller capacity MCS-N _sts look. Can be configured using an up table. Note that the number of unused entries that are arranged at the top of the table and can be used for future expansion becomes smaller.

That is, in the UT 120 that supports a single space-time stream for downlink and uplink transmission, it is more than the number of unused entries placed at the top of the k-bit MCS-N _sts lookup table. In order to use a small capacity MCS-N _sts lookup table, k is set to 4.

In order to increase the number of unused entries placed at the top of the k-bit MCS-N _sts lookup table, k is set to 5.

  Thereby, the signaling overhead of the SIG field 506 can be reduced, that is, a smaller-capacity lookup table can be used. Alternatively, more unused entries can be used for future expansion in the lookup table. Further, it is possible to more easily configure the UT 120, for example, a sensor device.

(Second Embodiment)
According to the second embodiment of the present disclosure, the basic idea of the method of signaling control variables, particularly MCS and MIMO information, is to combine and signal both SIG parameters “MCS” and “STBC”. Yes, unlike the prior art signaling method shown in FIG. 6 where both “MCS” and “STBC” are signaled independently.

  FIG. 15 illustrates an example of the SIG field 506 according to the second embodiment of the present disclosure. In FIG. 15, the 5-bit SIG parameter “MCS-STBC” is replaced with the 4-bit “MCS” and the 1-bit “STBC” in the prior art shown in FIG.

  The value indicated by the 5-bit “MCS-STBC” indicates an index into the 5-bit MCS-STBC table and is associated with a specific combination of “MCS” and “STBC”.

  The 5-bit SIG parameter “MCS-STBC” is the same number of signaling bits as the 4-bit SIG parameter “MCS” and the 1-bit SIG parameter “STBC” in the prior art shown in FIG. Therefore, the second embodiment of the present disclosure has the same number of unused bits in the SIG field 506 as the prior art shown in FIG.

  An example of a 5-bit MCS-STBC table according to the first aspect of the second embodiment of the present disclosure is shown in FIG. In FIG. 16, the 5-bit MCS-STBC table includes all valid combinations of “MCS” and “STBC”.

  Here, “STBC” is either 0 or 1, and the total number of MCS levels is 11. When STBC is not applied to any spatial stream (ie, “STBC” = 0), one of the MCSs (ie, MCS 10) corresponds.

Thus, the total number of valid combinations of the "MCS" and "STBC" is 21, larger than ^{2 4} and ^{2 5} smaller. Therefore, the 5-bit “MCS-STBC” is sufficient for “MCS” and “STBC” signaling.

  Also, in the 5-bit MCS-STBC table shown in FIG. 16, there are 11 unused entries (index 21-31), which are more than the five unused bits in the prior art MCS table shown in FIG. .

  An example of the 5-bit MCS-STBC table in the second mode of the second embodiment of the present disclosure is shown in FIG. In FIG. 17, the entries in the 5-bit MCS-STBC table are ordered based on the complexity of the MIMO scheme, that is, the number of spatial streams, and the entries associated with the simpler MIMO scheme are 5 bits. Is placed at the head of the MCS-STBC table.

  That is, according to the second aspect of the second embodiment of the present disclosure, a predetermined number of unused entries and an entry related to “STBC” = 0 are included in the 5-bit MCS-STBC table. Placed at the beginning. Note that the implementation of the UT 120 is easier when the STBC is not applied to each of the spatial streams.

FIG. 18 shows a method 1800 for determining the number of unused entries arranged at the head of the 5-bit MCS-STBC table. Method 1800 begins at step 1802. In step 1804, a positive integer k is determined such that the number of entries associated with “STBC” = 0 is greater than 2 ^k−1 and not greater than 2 ^k .

Step 1806 determines whether the difference between the number of entries associated with “STBC” = 0 (11 in FIG. 17) and 2 ^k (2 ³ = 16 in FIG. 17) is less than the number of unused entries. To check. If the difference between the number of 2 ^k entries associated with an "STBC" = 0 is not less than the number of unused entries, all unused entries to the beginning of the 5 bit MCS-STBC table (FIG. 16 Now Index 21-31) can be placed and method 1800 ends at step 1808.

In step 1810, if smaller, equal to the difference between the number of unused entries placed at the beginning of the 5 bit MCS-STBC table number and 2 ^k entries associated with an "STBC" = 0 . That is, Index 21-31 in FIG. 16 is divided into Index 11-15 in FIG. 17 and Index 26-31.

  In step 1812, k is incremented by 1 (increased by 1). Step 1814 checks whether k is less than 5. If k is smaller than 5, the process returns to step 1806 to examine other k values for the number of unused entries arranged at the head of the 5-bit MCS-STBC table. If k is not less than 6, method 1800 ends at step 1816.

In the example 5-bit MCS-STBC table shown in FIG. 16, the number of entries related to “STBC” = 0 is eleven. According to the method shown in FIG. 18, the positive integer k is 4 because 2 ^4-1 <11 <2 ⁴ .

The number of unused entries arranged at the top of the 5-bit MCS-STBC table shown in FIG. 17 is determined by the difference between 2 ^k and entries related to STBC = 0, and from 2 ⁴ = 16, 16-11 = 5. index11-15 corresponds.

  In the 5-bit MCS-STBC table shown in FIG. 17, the unused entry placed at the beginning of the 5-bit MCS-STBC table is placed after the entry related to “STBC” = 0. The usage entry may be placed before the entry associated with “STBC” = 0. Unused entries may also be mixed with entries associated with “STBC” = 0.

  Thus, according to the second aspect of the second embodiment of the present disclosure, some UTs 120 in the WLAN system 100, eg, battery-powered sensor devices, use STBC for downlink and uplink transmissions. Even if not supported, the k-bit MCS-STBC lookup table 1702 may be maintained and checked instead of the 5-bit MCS-STBC lookup table shown in FIG. In FIG. 17, k = 4.

  Thus, a UT 120 that does not support STBC for downlink and uplink transmissions can reduce memory capacity and power consumption.

  Note that the unused entry placed at the beginning of the 5-bit MCS-STBC lookup table can be used for the introduction of new PHY / MAC features in the SIG field 506 for future extensions.

  An example of a 5-bit MCS-STBC table in the third mode of the second embodiment of the present disclosure is shown in FIG. In FIG. 19, the entries in the 5-bit MCS-STBC table are ordered based on the complexity of the MIMO scheme and the complexity of the MCS scheme, and the entries associated with the simpler MIMO and MCS scheme are 5 bits. Arranged at the head of the MCS-STBC table.

  That is, according to the third aspect of the second embodiment of the present disclosure, there are 5 entries associated with a predetermined number of unused entries and both low-order modulation and “STBC” = 0. It is arranged at the head of the MCS-STBC table of bits.

  Note that the UT 120 is easier to implement when STBC is not applied to each of the spatial streams and when the modulation order is reduced.

  The number of unused entries arranged at the top of the 5-bit MCS-STBC table shown in FIG. 19 is “low-order modulation and“ STBC ”= 0”, which is “entry related to“ STBC ”= 0” shown in FIG. Can be determined using a method similar to the method 1800 shown in FIG.

  In the example of the 5-bit MCS-STBC table shown in FIG. 19, the number of entries related to both low-order modulation and “STBC” = 0 is four.

  The positive integer k can be set to 4 according to the method shown in FIG.

In step 1806, at k = 4, the number of unused entries (11) corresponding to index 21-31 in FIG. 16 is 2 ^k (2 ⁴ = 16), the low modulation order, and the entry related to STBC = 0. This is less than the difference (12) from the number (4), so all unused entries can be placed at the beginning of the 5-bit table.

  Therefore, at k = 4, the number of unused entries arranged at the top of the 5-bit MCS-STBC table is 11.

  In the example of the 5-bit MCS-STBC table shown in FIG. 19, k = 4, and all 11 unused entries are arranged at the head of the 5-bit MCS-STBC table.

  In the 5-bit MCS-STBC table shown in FIG. 19, the unused entry placed at the beginning of the 5-bit MCS-STBC table is placed after the entry related to both low-order modulation and “STBC” = 0. Although unused entries may be placed before entries associated with both low order modulation and “STBC” = 0, entries associated with both low order modulation and “STBC” = 0 May be mixed with.

  According to the third aspect of the second embodiment of the present disclosure, some UTs 120 in the WLAN system 100, eg, battery powered sensor devices, support STBC for downlink and uplink transmissions. And k-bit MCS-STBC instead of the 5-bit MCS-STBC lookup table shown in FIG. 19, even if low order modulation is supported for downlink and uplink transmissions The lookup table 1902 may be maintained and checked. Note that k can be set to 3 or 4.

  Thus, a UT 120 that does not support STBC for downlink and uplink transmissions and supports low-order modulation can reduce memory capacity and power consumption.

  Note that when the memory capacity of the UT 120 is reduced, an unused entry placed at the top of the 5-bit MCS-STBC lookup table is a new PHY / MAC feature in the SIG field 506 for future expansion. Can be used for introduction.

  From the above, in the third aspect of the second embodiment, the positive integer k can be set to 3 or 4. Note that if smaller k is used, a UT 120 that does not support STBC for downlink and uplink transmissions but supports lower order modulation can be configured with a smaller MCS-STBC lookup table. . Note that the number of entries that are arranged at the head of the MCS-STBC lookup table and can be used for future expansion is reduced.

  In other words, a UT 120 that does not support STBC for downlink and uplink transmissions and supports low-order modulation can have a smaller capacity MCS-STBC lookup table than the number of unused entries. For configuration using k, 3 is preferable, and for configuration using a MCS-STBC lookup table including a larger number of unused entries, k is preferable.

  FIG. 20 illustrates an example of a 5-bit MCS-STBC table in the fourth aspect of the second embodiment of the present disclosure. In FIG. 20, the entries in the 5-bit MCS-STBC table are ordered based on the complexity of the MCS scheme, and the entry associated with the simpler MCS scheme is the head of the 5-bit MCS-STBC table. Is arranged.

  That is, according to the fourth aspect of the second embodiment of the present disclosure, a predetermined number of unused entries and entries related to low-order modulation are placed at the head of the 5-bit MCS-STBC table. Be placed. Note that the implementation of the UT 120 becomes easier as the modulation order decreases.

  The number of unused entries arranged at the top of the 5-bit MCS-STBC table is replaced with “entries related to low-order modulation” in FIG. 17 by replacing “entries related to“ STBC ”= 0” with FIG. Can be determined using a method similar to the method 1800 shown in FIG.

In the example of the 5-bit MCS-STBC table shown in FIG. 20, the number of entries related to low-order modulation is seven. The positive integer k can be set to 3 (2 ³ = 8) or 4 (2 ⁴ = 16) by the method shown in FIG.

Therefore, the number of unused entries arranged at the head of the 5-bit MCS-STBC table is 1 (= 8-7) or 9 (= 16-7) depending on the difference between ^2k and low-dimensional modulation. ).

  In the example of the 5-bit MCS-STBC table shown in FIG. 20, k = 4, and nine unused entries are arranged at the head of the 5-bit MCS-STBC table.

  In the 5-bit MCS-STBC table shown in FIG. 20, the unused entry arranged at the head of the 5-bit MCS-STBC table is arranged after the entry related to the low-order modulation. May be placed in front of the entry related to, and may be mixed with the entry related to low-order modulation.

  As described above, according to the fourth aspect of the second embodiment of the present disclosure, some UTs 120 in the WLAN system 100, for example, battery-powered sensor devices, have low order for downlink and uplink transmissions. Even when modulation is supported, a k-bit MCS-STBC lookup table 2002 may be maintained and checked instead of the 5-bit MCS-STBC lookup table shown in FIG. Note that k is 3 or 4.

  Thus, a UT 120 that supports low order modulation for downlink and uplink transmissions can reduce memory capacity and power consumption. Note that the unused entry placed at the beginning of the 5-bit MCS-STBC lookup table can be used for the introduction of new PHY / MAC features in the SIG field 506 for future extensions.

  From the above, in the fourth aspect of the second embodiment, the positive integer k can be set to 3 or 4. With a smaller k, a UT 120 that supports low-order modulation for downlink and uplink transmissions will have fewer unused entries that can be expanded in the future.

  That is, to configure a UT 120 that supports low-order modulation for downlink and uplink transmissions with a smaller capacity MCS-STBC lookup table than the number of unused entries. , K is preferably 3, and k is preferably 4 for configuration using an MCS-STBC lookup table containing a larger number of unused entries.

  Thereby, the signaling overhead of the SIG field 506 can be reduced, that is, a smaller-capacity lookup table can be used. Alternatively, more unused entries can be used for future expansion in the lookup table. Further, it is possible to more easily configure the UT 120, for example, a sensor device.

(Third embodiment)
According to the third embodiment of the present disclosure, the basic idea of the signaling method of control variables, particularly MCS and MIMO information, is to be signaled by combining “MCS”, “N _sts ”, and “STBC”. This is different from the prior art shown in FIG. 6 in which “MCS”, “N _sts ”, and “STBC” are signaled independently.

FIG. 21 illustrates an example of the SIG field 506 according to the third embodiment of the present disclosure. In FIG. 21, a 6-bit SIG parameter “MCS-STBC-N _sts ” is used, and the 4-bit “MCS”, the 2-bit “N _sts ”, and the 1-bit “STBC” in the prior art shown in FIG. Has been replaced.

The value indicated by the 6-bit “MCS-STBC-N _sts ” indicates an index into the 6-bit MCS-STBC-N _sts table, and identifies “MCS”, “N _sts ”, and “STBC”. Is related to the combination.

FIG. 22 illustrates an example of a 6-bit MCS-STBC-N _sts table according to the first aspect of the third embodiment of the present disclosure. In FIG. 22, the 6-bit MCS-STBC-N _sts table includes all the valid combinations of “MCS”, “N _sts ”, and “STBC”.

Here, “STBC” is either 0 or 1, and the total number of MCSs is 11. For “STBC” = 0 and N _sts = 1, one of the MCSs (ie, MCS 10) corresponds.

Further, when “STBC” = 1, N _sts is either 2 or 4. Therefore, the total number of valid combinations of “MCS”, “N _sts ”, and “STBC” is 61, which is greater than ²⁵ and less than ²⁶ . Therefore, the 6-bit MCS-STBC-N _sts is sufficient for “MCS”, “N _sts ”, and “STBC” signaling. Furthermore, there are three unused entries in the 6-bit MCS-STBC-N _sts table.

Compared to the prior art in which a total of 7 bits are used for “MCS”, “N _sts ” and “STBC” signaling shown in FIG. 6, according to the third embodiment of the present disclosure, The number of bits used for is 6 bits. For this reason, in the third embodiment of the present disclosure, one less signaling bit is required in the SIG field 506 than the prior art shown in FIG. Therefore, the SIG field 506 can be shortened and the overhead of the SIG field 506 can be reduced.

FIG. 23 illustrates an example of a 6-bit MCS-STBC-N _sts table according to the second aspect of the third embodiment of the present disclosure. In FIG. 23, the entries in the 6-bit MCS-STBC-N _sts table are ordered based on the complexity of the MIMO scheme, that is, the single space-time stream, and the complexity of the MCS scheme. That is, an entry related to a simpler MIMO and MCS scheme is arranged at the head of the 6-bit MCS-STBC-N _sts table.

That is, according to the second aspect of the third embodiment of the present disclosure, a predetermined number of unused entries, and low-order modulation (ie, MCS is BPSK-based or QPSK-based) and single time Entries associated with both spatial streams (ie, when N _sts = 1 and “STBC” = 0) are placed at the beginning of the 6-bit MCS-STBC-N _sts table. Note that it becomes easier as the UT 120 is implemented, the number of spatiotemporal streams, and the modulation order decreases.

FIG. 24 shows a method 2400 for determining the number of unused entries placed at the beginning of the 6-bit MCS-STBC-N _sts table. The method 2400 begins at step 2402. In step 2404, a positive integer k is determined in which the number of entries associated with both the low-order modulation and the single space-time stream is greater than 2 ^k-1 and not greater than 2 ^k .

Step 2406, the difference between the number of entries that are related to both the 2 ^k and low-order modulation and a single space-time stream and checks whether less than the number of unused entries. If the difference between the number of entries that are related to both the 2 ^k and low-order modulation and a single space-time stream is not less than the number of unused entries, the 6-bit to the beginning of the MCS-STBC-N _sts table All unused entries can be placed and method 2400 ends at step 2408. If so, in step 2410, the number of unused entries placed at the beginning of the 6-bit MCS-STBC-N _sts table is 2 ^k and entries associated with both low-order modulation and single space-time streams. Can be equal to the difference between the numbers.

In step 2412, k is incremented by one. Step 2414 checks whether k is less than 6. If k is smaller than 6, the process returns to step 2406 to examine other values of k with respect to the number of unused entries arranged at the head of the 6-bit MCS-STBC-N _sts table. If k is not less than 6, method 2400 ends at step 2416.

  For example, in the 6-bit table shown in FIG.

  According to the method of FIG. 24, the positive integer k is 3, 4 or 5. Note that for k = 3, 4 or 5, the number of entries for low-dimensional modulation and single space-time stream is greater than the number of unused entries for any value of k.

Therefore, since this corresponds to step 2408, an unused entry for k = 3, 4 or 5 can be placed at the head of the 6-bit MCS-STBC-N _sts table.

Here, the 6-bit MCS-STBC-N _sts table in FIG. 23 corresponds to k = 3. All unused entries (index 4-6) are arranged at the head of the 6-bit table.

In the example of the 6-bit MCS-STBC-N _sts table shown in FIG. 23, the number of entries related to both the low-order modulation and the single space-time stream is four. According to the method shown in FIG. 24, the number of unused entries arranged at the beginning of the 6-bit MCS-STBC-N _sts table can be three in FIG.

In the 6-bit MCS-STBC-N _sts table shown in FIG. 23, the unused entry arranged at the head of the 6-bit MCS-STBC-N _sts table is related to both the low-order modulation and the single space-time stream. And may be placed before an entry associated with both the low-order modulation and the single space-time stream, and an entry associated with both the low-order modulation and the single space-time stream. You may mix.

According to the second aspect of the third embodiment of the present disclosure, the configuration of several UTs 120 in the WLAN system 100, eg, battery-powered sensor devices, provides low order modulation for downlink and uplink transmissions. In addition to the 6-bit MCS-STBC-N _sts lookup table shown in FIG. 23, even if it supports single space-time streams for downlink and uplink transmissions. Further, a configuration using a k-bit MCS-STBC-N _sts lookup table 2302 may be used. Note that k is 3, 4 or 5.

Thus, a UT 120 that supports both low order modulation and a single space-time stream for downlink and uplink transmissions can reduce memory capacity and power consumption. Note that when the memory capacity of the UT 120 is reduced, an unused entry placed at the top of the 6-bit MCS-STBC-N _sts lookup table is replaced with a new PHY / SIG field 506 for future expansion. Can be used for the introduction of MAC features.

  From the above, in the second aspect of the third embodiment, the positive integer k can be set to 3, 4 or 5.

Note that if smaller k is used, a UT 120 that supports both low-order modulation and single space-time streams for downlink and uplink transmissions uses a smaller MCS-STBC-N _sts lookup table. Can be configured.

In all values of k, the number of unused entries arranged at the head of the MCS-STBC-N _sts lookup table is the same as the number of entries that can be expanded in the future.

  Thus, a UT 120 that supports both low-order modulation and single space-time streams for downlink and uplink transmissions sets k to 3 to configure with a smaller capacity table. Is preferred.

FIG. 25 illustrates an example of a 6-bit MCS-STBC-N _sts table in the third aspect of the third embodiment of the present disclosure. In FIG. 25, the entries in the 6-bit MCS-STBC-N _sts table are ordered based on the complexity of the MIMO scheme, ie the number of spatial streams, and the complexity of the MCS scheme. For this reason, entries related to simpler MIMO and MCS schemes are placed at the beginning of the 6-bit MCS-STBC-N _sts table.

That is, according to the third aspect of the third embodiment of the present disclosure, a predetermined number of unused entries, and low-order modulation (ie, MCS is BPSK-based or QPSK-based) and single space Entries associated with both streams (ie, when N _sts = 1 and “STBC” = 0 or N _sts = 2 and “STBC” = 1) are in the 6-bit MCS-STBC-N _sts table. Placed at the beginning. Note that the implementation of the UT 120 becomes easier as the number of spatial streams and the modulation order decrease.

The number of unused entries arranged at the head of the 6-bit MCS-STBC-N _sts table is the same as “entries related to both low-order modulation and single space-time stream” in FIG. It can be determined using a method similar to the method 2400 shown in FIG. 24 by replacing “entries associated with both of the single spatial streams”. In the example of the 6-bit MCS-STBC-N _sts table shown in FIG. 25, the number of entries related to both the low-order modulation and the single spatial stream is seven.

According to the method of FIG. 24, the positive integer can be set to 3, 4 or 5. For k = 3, the number of unused entries placed at the beginning of the 6-bit table, the difference between the number of entries associated with the 2 ^k and low-dimensional modulation and single spatial stream, is determined, and one . That is, since 2 ³ = 8 and the number of entries related to the low-dimensional modulation and the single spatial stream is 7, 8−7 = 1.

In k = 4 or 5, than the difference between the number of entries about ^{2 k} and low-dimensional modulation and single spatial stream, (3 Index61-63) number of unused entries in FIG. 22 is reduced.

Therefore, the number of unused entries arranged at the head of the 6-bit MCS-STBC-N _sts table is either one or three.

An example of the 6-bit MCS-STBC-N _sts table shown in FIG. 25 is k = 3, and one unused entry is arranged at the head of the 6-bit MCS-STBC-N _sts table. .

In the 6-bit MCS-STBC-N _sts table shown in FIG. 25, the unused entry arranged at the head of the 6-bit MCS-STBC-N _sts table is related to both the low-order modulation and the single spatial stream. Placed after the entry, but may be placed before the entry associated with both the low order modulation and the single spatial stream, mixed with the entry associated with both the low order modulation and the single spatial stream Also good.

According to a third aspect of the third embodiment of the present disclosure, as a configuration of several UTs 120 in the WLAN system 100, eg, battery powered sensor devices, low order modulation for downlink and uplink transmissions 6-bit MCS-STBC-N _sts look even if it is equipped with a single antenna and supports a single spatial stream for downlink and uplink transmissions. Instead of the up table, a k-bit MCS-STBC-N _sts look-up table 2502 may be used. Note that k is either 3, 4 or 5.

Thus, a UT 120 that supports both low order modulation and a single spatial stream for downlink and uplink transmissions can reduce memory capacity and power consumption. Note that when the memory capacity of the UT 120 is reduced, an unused entry placed at the top of the 6-bit MCS-STBC-N _sts lookup table is replaced with a new PHY / SIG field 506 for future expansion. Can be used for the introduction of MAC features.

  From the above, in the third aspect of the third embodiment, the positive integer k can be set to 3, 4 or 5.

Note that with a smaller k, a UT 120 supporting both low order modulation and single spatial streams for downlink and uplink transmissions uses a smaller MCS-STBC-N _sts lookup table. Can be configured.

When k = 4, the number of unused entries arranged at the head of the MCS-STBC-N _sts lookup table and the number of entries that can be expanded in the future are the same as when k = 5. However, it is more than when k = 3.

A UT 120 that supports both low-order modulation and single spatial streams for downlink and uplink transmissions preferably has k set to 3 to configure with a smaller capacity table. In order to increase the number of unused entries arranged at the beginning of the MCS-STBC-N _sts lookup table, it is preferable to set k to 4.

  Thereby, the signaling overhead of the SIG field 506 can be reduced, that is, a smaller-capacity lookup table can be used. Alternatively, more unused entries can be used for future expansion in the lookup table. Further, it is possible to more easily configure the UT 120, for example, a sensor device.

100 MIMO WLAN system 110 access point, AP
120a User terminal, UT
120b user terminal 120c user terminal 120d user terminal, UT
120e User terminal 120f User terminal 120 UT
130 Controller 202 Data Source 204 TX Processor 210 Controller 212 Scheduler 222 Data Sink 224 RX Processor 230 Receiver Unit, RU, TU
232a Antenna 232b Antenna 232 Antenna 252 Data source 254 TX processor 260 Controller 272 Data sink 274 RX processor 280 Transmitter unit, TU, RU
282a antenna 282da antenna 282db antenna 282 antenna 300 TX processor 302 scrambler 304 encoder parser 306 FEC encoder 308 stream parser 310 interleaver 312 constellation mapper 314 STBC unit 316 CSD unit 318 spatial mapping unit 320 IDFT unit 322 GI insertion And windowing unit 400 TX processor 402 scrambler 406 FEC encoder 408 iteration unit 410 interleaver 412 constellation mapper 418 spatial mapping unit 420 IDFT unit 422 GI insertion and windowing unit 500 PHY frame 502 STF
504a first LTF
504b Remaining LTF
504 LTF
506 SIG field 508 Data portion 510 Preamble 1002 k-bit MCS-N _sts lookup table 1100 Method 1202 k-bit MCS-N _sts lookup table 1302 k-bit MCS-N _sts lookup table 1402 k-bit MCS-N _sts lookup table 1702 k-bit MCS-STBC lookup table 1800 method 1902 k-bit MCS-STBC lookup table 2302 k-bit MCS-STBC-N _sts lookup table 2400 method

Claims (12)

A method for wireless communication comprising:
Generating a preamble with a SIG (signal) field in a portion of the preamble to indicate a control variable that includes a plurality of parameters for a particular device, wherein one of the plurality of parameters is: Modulation and coding scheme (“MCS”) and an indicator (“STBC”) indicating the number of space-time streams (“N _sts ”) and whether space-time block coding is applied to each of the spatial streams ) At least one of
Transmitting the preamble to the device in a frame, and
Wherein, one value of the parameter indicates an index to the signaling table, the signaling table including unused entries and all valid values of at least one of “MCS”, “N _sts ” and “STBC”. Including entries corresponding to combinations, the total number of entries in the signaling table is 2 ⁿ , where n is the valid for all of at least one of “MCS” and “N _sts ” and “STBC” A method for wireless communication in which the number of entries corresponding to a combination of different values is a positive integer such that it is greater than 2 ⁿ⁻¹ . Entries in the signaling table are ordered based on the complexity of at least one of a MIMO and MCS scheme;
The method of claim 1. An entry associated with at least one of the simpler MIMO and MCS schemes is placed at the beginning of the signaling table;
The method of claim 1. If the parameter signals “MCS” and “N _sts ”, the signaling table includes entries associated with a predetermined number of unused entries and a single space-time stream (ie, N _sts = 1). Placed at the beginning of
The method of claim 3. If the parameters signal “MCS” and “N _sts ”, a predetermined number of unused entries and entries associated with a single spatial stream are placed at the top of the signaling table;
The method of claim 3. If the parameter signals “MCS” and “N _sts ”, it is related to both a predetermined number of unused entries and low order modulation and single space-time stream (ie, N _sts = 1). An entry is placed at the top of the signaling table;
The method of claim 3. If the parameters signal “MCS” and “N _sts ”, a predetermined number of unused entries and entries associated with low-order modulation and single spatial streams are placed at the top of the signaling table. The
The method of claim 3. If the parameter signals “MCS” and “STBC”, a predetermined number of unused entries and an indication that STBC does not apply to any spatial stream (ie, “STBC” = 0) Is placed at the top of the signaling table,
The method of claim 3. If the parameters signal “MCS” and “STBC”, a predetermined number of unused entries and entries related to low-order modulation are placed at the top of the signaling table;
The method of claim 3. If the parameter signals “MCS” and “STBC”, a predetermined number of unused entries, and low order modulation and STBC is not applied to any spatial stream (ie, “STBC” = 0) entries associated with both indications are placed at the top of the signaling table,
The method of claim 3. If the parameters signal “MCS”, “STBC”, and “N _sts ”, a predetermined number of unused entries and lower order modulation and single space-time streams (ie, N _sts = 1) An associated entry is placed at the top of the signaling table;
The method of claim 3. If the parameters signal “MCS”, “STBC”, and “N _sts ”, a predetermined number of unused entries and entries associated with both low-order modulation and single spatial streams are included in the signaling. -Placed at the top of the table,
The method of claim 3.

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