KR20230128239A - Multi-mode wireless transmission method and apparatus - Google Patents

Abstract

A communication method of a next-generation WLAN frame according to an embodiment, comprising: modulating a first symbol of SIG-A of the next-generation WLAN frame with a first modulation method; modulating the second symbol of the SIG-A of the next-generation wireless LAN frame with a second modulation method; and modulating the STF signal of the next-generation WLAN frame in correspondence with the next-generation WLAN mode.

Description

Multi-mode wireless communication transmission method and apparatus {MULTI-MODE WIRELESS TRANSMISSION METHOD AND APPARATUS}

The following description relates to wireless communication technology, and relates to a method and apparatus for transmitting multi-mode wireless communication.

With the recent development of information and communication technology, various wireless communication technologies are being developed. Among them, wireless LAN (WLAN) is based on radio frequency technology and uses portable terminals such as Personal Digital Assistant (PDA), laptop computer, and Portable Multimedia Player (PMP) for home or business or It is a technology that enables wireless access to the Internet in a specific service area. Since the Institute of Electrical and Electronics Engineers (IEEE) 802, a standardization organization for WLAN technology, was established in February 1980, many standardization tasks have been performed.

BACKGROUND ART Wireless communication systems are developing in a direction for transmitting large amounts of data at high speed. Types of these wireless communication systems include a Wibro wireless communication system, a 3GPP LTE system, and a WLAN Very High Throughput (VHT) system. Accordingly, a transmission method for high efficiency/high performance while maintaining compatibility with the existing IEEE 802.11a/n/ac is required for next-generation wireless LAN (NGW) frame transmission, which is a next-generation wireless LAN standard.

An embodiment provides a high-performance frame transmission method and apparatus while maintaining compatibility with existing wireless LAN standards.

A communication method of a next-generation WLAN frame according to an embodiment includes modulating a first symbol of SIG-A of the next-generation WLAN frame with a first modulation method; modulating the second symbol of the SIG-A of the next-generation wireless LAN frame with a second modulation method; and modulating the STF signal of the next-generation WLAN frame in correspondence with the next-generation WLAN mode.

According to one side, the step of modulating the first symbol of SIG-A of the next-generation WLAN frame with a first modulation method modulates the first symbol of SIG-A of the next-generation WLAN frame with BPSK ( modulating), wherein the step of modulating the second symbol of the SIG-A of the next-generation WLAN frame with a second modulation method comprises the step of modulating the second symbol of the SIG-A of the next-generation WLAN frame by Q -Modulating with BPSK, wherein the step of modulating the STF signal of the next-generation WLAN frame corresponding to the next-generation WLAN mode has a phase difference of 90 degrees between the STF signal of the next-generation WLAN frame and VHT-STF. It may include the step of modulating to have.

According to another aspect, the step of modulating the first symbol of SIG-A of the next-generation WLAN frame with a first modulation method comprises BPSK for the first symbol of SIG-A of the next-generation WLAN frame. and modulating the second symbol of the SIG-A of the next-generation WLAN frame with a second modulation method, wherein the step of modulating the second symbol of the SIG-A of the next-generation WLAN frame The step of modulating the STF signal of the next-generation WLAN frame in accordance with the next-generation WLAN mode comprises modulating the STF signal of the next-generation WLAN frame with Q-BPSK. can include

According to another aspect, in the next-generation wireless LAN frame communication method, the STF signal may be mapped to a BPSK signal at positions of (-1, 1) and (1, -1).

A communication method of a next-generation wireless LAN frame according to an embodiment includes receiving a communication signal; verifying the first symbol and the second symbol of SIG-A of the communication signal; checking an STF signal of the communication signal when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal; and identifying a communication mode of the wireless LAN frame according to the STF signal.

According to one side, the step of identifying the communication mode of the wireless LAN frame according to the STF signal, when the STF signal has a phase difference of 90 degrees from the VHT-STF, the communication mode is set as a next-generation wireless LAN mode. It may include a decision-making step.

A communication method of a next-generation wireless LAN frame according to an embodiment includes receiving a communication signal; verifying the first symbol and the second symbol of SIG-A of the communication signal; checking an STF signal of the communication signal when the first symbol is a BPSK signal and the second symbol is a BPSK signal; and identifying a communication mode of the wireless LAN frame according to the STF signal.

According to one side, identifying the communication mode of the WLAN frame according to the STF signal includes determining the communication mode as a next-generation WLAN mode when the STF signal is a Q-BPSK signal. can do.

A communication method of a next-generation WLAN frame according to an embodiment, comprising: modulating a first symbol of SIG-A of the next-generation WLAN frame by a first modulation method; modulating the second symbol of the SIG-A of the next-generation wireless LAN frame with a second modulation method; and modulating the third symbol of the SIG-A of the next-generation WLAN frame in response to a next-generation WLAN mode.

According to one side, the step of modulating the first symbol of SIG-A of the next-generation WLAN frame with a first modulation method comprises: modulating the first symbol of SIG-A of the next-generation WLAN frame with BPSK and modulating the second symbol of the SIG-A of the next-generation WLAN frame with a second modulation method, wherein the step of modulating the second symbol of the SIG-A of the next-generation WLAN frame The step of modulating the third symbol of the SIG-A of the next-generation WLAN frame in correspondence with the next-generation WLAN mode includes the step of modulating the SIG-A of the next-generation WLAN frame. Modulating the third symbol to have a phase difference of 90 degrees from the VHT-STF may be included.

According to another aspect, the step of modulating the first symbol of SIG-A of the next-generation WLAN frame with a first modulation method comprises BPSK for the first symbol of SIG-A of the next-generation WLAN frame. and modulating the second symbol of the SIG-A of the next-generation WLAN frame with a second modulation method, wherein the step of modulating the second symbol of the SIG-A of the next-generation WLAN frame A step of modulating a symbol into BPSK, wherein the step of modulating a third symbol of the SIG-A of the next-generation WLAN frame in response to a next-generation WLAN mode comprises: Modulating the third symbol with Q-BPSK.

A communication method of a next-generation wireless LAN frame according to an embodiment includes receiving a communication signal; verifying the first symbol and the second symbol of SIG-A of the communication signal; checking a third symbol of SIG-A when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal; and identifying a communication mode of the wireless LAN frame according to the third symbol.

According to one side, the step of identifying the communication mode of the wireless LAN frame according to the third symbol, when the third symbol has a phase difference of 90 degrees from the VHT-STF, the communication mode is selected as the next-generation wireless LAN. A step of determining the mode may be included.

A communication method of a next-generation wireless LAN frame according to an embodiment includes receiving a communication signal; verifying the first symbol and the second symbol of SIG-A of the communication signal; checking a third symbol of the SIG-A when the first symbol is a BPSK signal and the second symbol is a BPSK signal; and identifying a communication mode of the wireless LAN frame according to the third symbol of the SIG-A.

According to one side, the step of identifying the communication mode of the wireless LAN frame according to the third symbol of the SIG-A, when the third symbol of the SIG-A is a Q-BPSK signal, the communication A step of determining the mode as the next-generation WLAN mode may be included.

A method of communicating a next-generation WLAN frame according to an embodiment includes generating a signal field of the next-generation WLAN frame having the same length as a signal field of a very high throughput (VHT) frame; and inputting a predetermined reserved bit among reserved bits of a signal field structure of the VHT frame as a first value.

According to one side, modulating the first symbol of SIG-A of the next-generation WLAN frame with BPSK; and modulating the second symbol of the SIG-A of the next-generation WLAN frame with Q-BPSK.

According to another aspect, the step of inputting a predetermined reserved bit among reserved bits of the signal field structure of the VHT frame as a first value, in the case of a next-generation wireless LAN mode, the predetermined reserved bit as the first value. input as a value; and inputting the predetermined reserved bit as a second value in case of the VHT mode.

A method of communicating a next generation wireless LAN frame according to an embodiment includes receiving a wireless LAN frame; verifying a predetermined reserved bit among reserved bits of a signal field structure of a VHT frame among the wireless LAN frames; and identifying a communication mode of the wireless LAN frame according to the identified reserved bits.

According to one side, identifying the communication mode of the WLAN frame according to the identified reserved bits may include determining the communication mode as a next-generation WLAN mode when the identified reserved bits have a first value; and determining the communication mode as a VHT mode when the identified reserved bits have a second value.

A method of communicating a next-generation WLAN frame according to an embodiment includes generating a signal field of the next-generation WLAN frame having the same length as a signal field of a high throughput (HT) frame; and inputting a reserved bit of the signal field structure of the HT frame as a first value in case of the next-generation wireless LAN mode.

A method of communicating a next generation wireless LAN frame according to an embodiment includes receiving a wireless LAN frame; verifying reserved bits of a signal field structure of an HT frame among the wireless LAN frames; and identifying a communication mode of the wireless LAN frame according to the identified reserved bits.

In one embodiment, NGW frame transmission capable of maintaining compatibility with IEEE 802.11a/n/ac and high performance determination is possible.

1 is a diagram showing a conventional WLAN frame structure.
2 is a diagram illustrating a next-generation WLAN frame structure according to an embodiment.
3 is a diagram illustrating a conventional wireless LAN frame transmission method.
4 is a diagram illustrating a transmission method of a next-generation WLAN frame according to an embodiment.
5 is another example illustrating a method of transmitting a next-generation WLAN frame according to an embodiment.
6 is a diagram illustrating a method of transmitting including frame type information in a signal field according to an embodiment.
7 is a diagram illustrating a method of detecting a VHT frame according to an embodiment.
8 is another example illustrating a method of transmitting a next-generation WLAN frame according to an embodiment.
9 is a diagram illustrating a method of detecting an HT frame according to an embodiment.
10 to 21 are diagrams illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.
22 is a diagram showing the physical layer structure of IEEE 802.11.
23 is a diagram showing the structure of a communication device of a next-generation wireless LAN frame according to an embodiment.

Hereinafter, an embodiment will be described in detail with reference to the accompanying drawings.

1 is a diagram showing a conventional WLAN frame structure.

An existing wireless LAN may include 11a/b/g, which is a legacy standard, 11n, which is a high throughput (HT) standard, and very high throughput (VHT) in the IEEE 802.11 group. A frame structure of a wireless LAN PLCP protocol data unit (PPDU) may be shown in FIG. 1 .

The wireless LAN may support legacy, high throughput (HT) and very high throughput (VHT) transmission modes. IEEE 802.11a/g is classified as a legacy type, IEEE 802.11n is classified as an HT mode, and IEEE 802.11ac is classified as a VHT mode.

When transmitting a PPDU, the wireless LAN system may transmit signal information including signal information for a receiver to correctly recover the PPDU in a header field. Since this signal information is very important to recover PPDU data, it is transmitted with the lowest MCS to be strong against channel change and noise. Legacy PPDU 110 can be divided into L-STF, L-LTF, L-SIG, and data (DATA). The HT PPDU 120 may be classified into L-STF, L-LTF, L-SIG, HT-SIG, HT-STF, HT-LTF, and data, and the VHT PPDU 130 may be classified into L-STF, L-LTF , L-SIG, VHT-SIGA, VHT-STF, VHT-LTF, VHT-SIGB and data.

L-STF (Legacy short training field) is a carrier sensing method for detecting that a signal exists on a channel currently used, and a radio signal input to an antenna is converted into an analog circuit and an analog-to-digital converter (Analog-to-Digital converter). ) can be used for automatic gain control to match the operating range and coarse carrier frequency offset correction.

L-LTF (Legacy long training field) can be used for fine carrier frequency offset correction and symbol synchronization, and channel response estimation for demodulation of L-SIG field, HT-SIG field or VHT-SIG field. can be used for In addition, the signal-to-noise ratio can be estimated using the principle of repeating two symbols.

Using repetitive sequences such as L-STF and L-LTF, it is possible to estimate various channel characteristics such as interference, Doppler, and delay spread.

Signal fields such as L-SIG (Legacy signal field), HT-SIG (HT signal field), and VHT-SIG (VHT signal field) are control information necessary for the UE or AP receiving the PPDU to demodulate the received PPDU can include For example, there are packet length, MCS, bandwidth and channel encoding method, beamforming, STBC, smoothing, MU-MIMO, and a supported transmission technology such as short guard interval mode. In the case of VHT-SIG, it is divided into common control information and dedicated information required for a specific MU group, and is divided into a VHT-SIGA field and a VHT-SIGB field and transmitted. ID information such as group ID and partial association ID (PAID) can also be included.

In addition, L-SIG, HT-SIG, and VHT-SIG may be used as a means for informing the frame type. Transmission symbols of L-SIG, HT-SIG, and VHT-SIG are transmitted in BPSK or Q-BPSK (Quadrature BPSK) so that a terminal receiving a frame can know what type of frame it has received. Q-BPSK is a signal obtained by phase-rotating a BPSK signal by 90 degrees, and is a modulation scheme that guarantees maximum orthogonality compared to BPSK.

In the case of an 802.11n frame, both HT-SIG symbols are transmitted in Q-BPSK, and two symbols phase-rotated by 90 degrees compared to the BPSK of the legacy frame can be detected and recognized as an 802.11n frame. When transmitting an 802.11n frame, the L-SIG rate is set to 6Mbps, and the length is specified so that the frame occupies the channel to be transmitted. One of Q-BPSK can be determined.

In the case of 802.11ac frames, the first symbol of VHT-SIG is transmitted in BPSK, and the second symbol is transmitted in Q-BPSK. Since the first symbol is BPSK, 11n devices recognize it as a legacy frame, and 11ac devices recognize Q-BPSK of the second symbol and recognize it as a VHT frame.

HT-STF (HT short training field) or VHT-STF (VHT short training field) is used to improve gain control performance of AGC, and additional gain control is absolutely necessary when beamforming technology is used.

HT-LTF (HT long training field) or VHT-LTF (VHT long training field) may be used by the UE or AP to estimate the channel. Unlike the legacy standards, the 11n or 11ac standard increases throughput by increasing the number of subcarriers used, so a new LTF is defined for data recovery in addition to the L-LTF. In the case of VHT-LTF, a pilot signal for offset correction may also be included.

The data field includes data information to be transmitted. This field can be transmitted by converting the MPDU of the MAC layer into PSDU and including the service field and tail bit.

2 is a diagram illustrating a frame structure of a Next Generation Wireless LAN according to an embodiment.

210, it shows the frame structure of NGW, which is the next-generation wireless LAN transmission standard, and includes L-STF, L-LTF, and L-SIG to maintain backward compatibility with the existing wireless LAN standard transmission method. , NGW signal field and preamble, so that signaling information for restoring NGW DATA can be transmitted. After the signal field and the preamble, variable length DATA information may be included.

The DATA of the NGW frame may include data tones and pilot tones, and the pilot may maintain Doppler robust performance by changing its location for each symbol using a traveling pilot. Alternatively, midambles of the NGW-LTF structure may be periodically included between data symbols. Since midamble allows a wireless terminal to more quickly adapt to channel change and phase change, it can be used for the purpose of improving performance in outdoor environments. In addition, since the length of the guard interval of the DATA frame is variable, the length of the guard interval can be variably adjusted according to the conditions of the channel environment by the indicator of the signal field to be robust to the delay spread.

220, another example of the NGW frame structure is shown, after L-STF, L-LTF and L-SIG, NGW-SIG-A, NGW-STF, NGW-LTF, NGW-SIG-B and DATA may be included.

NGW-SIG-A provides a single user with packet length, MCS, bandwidth and channel encoding method capable of decoding packets, beamforming, STBC, smoothing, MU-MIMO, short guard interval mode, delay spread status, channel quality, group Information such as group identification and partial association identification can be provided.

The NGW-STF enables fine gain control when beamforming transmission or multi-antenna transmission is used. NGW-LTF may be used for channel estimation and phase tracking for NGW data frame recovery.

DATA may include a data value transmitted in a manner suitable for the signal information. The DATA field may include a periodic pilot sequence as a reference signal for tracking and compensating phase, signal amplitude, residual frequency offset, etc. in restoring transmitted data according to information described in the signal field. The pilot sequence can operate in a traveling pilot mode or a fixed point mode according to the pilot sequence mode information described in the signal field. In the fixed pilot mode, the position of the pilot is fixed and the pilot exists at the same position in every data symbol, whereas in the traveling pilot mode, the position of the pilot is periodically rotated in every symbol and restored to the original position after a certain symbol. has a structure that In the case of using the traveling pilot, even if the channel state varies greatly according to the Doppler shift or delay spread, it can help overcome the change in the channel.

3 is a diagram illustrating a conventional wireless LAN frame transmission method.

Legacy 310 frame transmission method may transmit the first symbol of the signal field by QPSK and the second symbol by QPSK modulation.

The HT 320 frame transmission method may transmit the first symbol of the signal field by Q-BPSK and the second symbol by Q-BPSK modulation.

The VHT 330 frame transmission method may transmit the first symbol of the signal field by BPSK and the second symbol by Q-BPSK modulation.

4 is a diagram illustrating a transmission method of a next-generation WLAN frame according to an embodiment.

Referring to the NGW (Type-1a) 410 frame transmission method, the first symbol of NGW-SIG-A may be modulated with BPSK and the second symbol with Q-BPSK. As described in FIG. 3, since it is the same modulation scheme as VHT-SIG-A, spoofing or power saving of the VHT device can be made possible by making the information of NGW-SIG-A compatible with the VHT device. Spoofing refers to a function that prevents terminals using an existing standard from accessing a channel for a time calculated from rate and length information described in a signal field by recognizing that an existing frame has been received. The power save refers to a function of stopping subsequent processing and entering a power save mode if the receiving terminal is not receiving a frame based on the ID information of the signal field. When this frame is received, the NGW-STF is transmitted in BPSK rotated by 135 degrees counterclockwise from the X axis so that the receiving end can determine the packet type by making it 90 degrees different from the existing VHT-STF. In VHT-STF, BPSK signals are mapped and transmitted at (1, 1) and (-1, -1) positions, whereas NGW-STF has BPSK signals at (-1, 1) and (1, -1) positions. Mapped and transmitted, the two signals have a phase difference of 90 degrees. Based on the BPSK and Q-BPSK signals in the signal field before the VHT-STF or NGW-STF, it is recognized as a VHT or NGW frame, and the frame mode is recognized by recognizing the phase of the next STF signal. The VHT device performs spoofing based on the signal field information recognized as L-SIG and VHT-SIG-A, and the NGW device simultaneously performs frame type detection and automatic gain control in the NGW-STF.

In the NGW (Type-1b) 420 frame transmission method, both symbols of NGW-SIG-A are transmitted in BPSK modulation, and NGW-STF is transmitted in Q-BPSK to distinguish it from legacy frame format. In this way, when both symbols coming after L-SIG are transmitted by BPSK, legacy terminals, HT terminals, and VHT terminals can recognize this frame as a legacy frame. The NGW terminal can determine whether this frame is a legacy frame or an NGW frame by distinguishing BPSK and Q-BPSK at the NGW-STF location to determine the packet type. In the case of an NGW frame, the NGW-STF is transmitted in Q-BPSK, and in the case of a legacy frame, it is transmitted in a BPSK signal, so that the frame mode can be distinguished by the 90 degree phase difference of the signal. The reason why only the BPSK signal needs to be considered in the case of the legacy frame is that the rate is set to 6Mbps and transmitted in the case of the NGW frame.

The NGW (Type 2) frame transmission method shows a method of transmitting NGW-SIG-A symbols with a length of three symbols to include more signal field information than the NGW (Type 1) method.

In the NGW (Type-2a) 430 frame transmission method, the first symbol of NGW-SIG-A is transmitted in BPSK and the second symbol is transmitted in Q-BPSK, so that both the VHT terminal and the NGW terminal can utilize the corresponding signal field and the third symbol is rotated by 135 degrees counterclockwise on the X axis and transmitted, thereby discriminating between the VHT frame and the NGW frame. The third symbol of the NGW-SIG-A of the NGW frame has a phase difference of 90 degrees from the VHT-STF of the VHT frame, so that the VHT frame and the NGW frame can be discriminated from the received frame.

The NGW (Type-2b) 440 frame transmission method transmits the first symbol and the second symbol of NGW-SIG-A by BPSK, and transmits the third symbol by Q-BPSK to determine legacy frame and NGW frame. there is. In this case, since the first symbol and the second symbol of NGW-SIG-A are BPSK, legacy terminals, HT terminals, and VHT terminals determine that this frame is a legacy frame, and spoof based on the rate and length information of the signal field will do On the other hand, the NGW terminal detects that the first symbol and the second symbol are BPSK and the third symbol is Q-BPSK, and determines that it is an NGW frame. Since the NGW terminal only needs to determine whether it is a legacy frame or an NGW frame when the rate is 6Mbps, it only needs to determine whether BPSK and Q-BPSK are located at the third symbol position of NGW-SIG-A.

In the next-generation wireless LAN frame communication method according to an embodiment, a frame type may be determined by modulating and transmitting a symbol. In addition, in the next-generation wireless LAN frame communication method, a method of transmitting including frame type information in a signal field will be referred to FIGS. 5 and 7.

5 is another example illustrating a method of transmitting a next-generation WLAN frame according to an embodiment.

5 shows a method of transmitting including frame type information in a signal field. The modulation method of the signal field is maintained the same as that of a VHT mode frame, but a reserved bit is used so that the NGW device can recognize that it is in the NGW frame mode. can

As described in FIG. 3, the legacy 510 frame transmission method can transmit the first symbol of the signal field by QPSK and the second symbol by QPSK modulation. The HT 520 frame transmission method may transmit the first symbol of the signal field by Q-BPSK and the second symbol by Q-BPSK modulation. The VHT 530 frame transmission method may transmit the first symbol of the signal field by BPSK and the second symbol by Q-BPSK modulation.

In the NGW (Type-3) 540 frame transmission method, the modulation scheme of the signal field may be maintained the same as that of the VHT mode frame, as described in 530 . At this time, the VHT frame can be distinguished using the reserved bit. A method of distinguishing between VHT mode and NGW using reserved bits will be described in detail with reference to FIGS. 6 and 7 .

6 is a diagram illustrating a method of transmitting including frame type information in a signal field according to an embodiment.

6A illustrates a method of transmitting a NGW (Type-3a) frame, and the NGW (Type-3a) NGW frame may have the same signal field structure as the VHT frame format. There are 3 reserved bits in the VHT frame, and at least one of these reserved bits can be used to distinguish between the NGW mode and the VHT mode. Accordingly, the frame format information may be defined using at least one bit value among the reserved bits 611, 612, and 613. For example, if the Reserved bit is 0, it can be defined as NGW mode, if the Reserved bit is 1, it can be defined as VHT mode, or if the Reserved bit is 1, it can be defined as NGW mode, and if the Reserved bit is 0, it can be defined as VHT mode.

NGW (Type-3a) frame transmission method can be transmitted by modulating the first symbol of NGW-SIG-A with BPSK and modulating the second symbol with Q-BPSK, so legacy terminal and HT terminal recognize it as legacy mode It can be, and the VHT terminal can be recognized as a VHT mode. NGW can determine the NGW mode by using the Reserved bit.

6b shows a method of transmitting a NGW (Type-3b) frame. In the NGW (Type-3b) frame, other signal information (signal information 1, 2, 3, 4 ) is a newly defined frame format. The device receiving the frame can distinguish the frame mode using at least one bit value among the reserved bits 651, 652, and 653 like NGW (Type-3a). For example, if the Reserved bit is 0, it can be defined as NGW mode, if the Reserved bit is 1, it can be defined as VHT mode, or if the Reserved bit is 1, it can be defined as NGW mode, and if the Reserved bit is 0, it can be defined as VHT mode.

In the NGW (Type-3b) frame transmission method, the first symbol of NGW-SIG-A is modulated with BPSK and the second symbol is modulated with Q-BPSK, so it is recognized as legacy mode by legacy terminals and HT terminals, It will be recognized as a VHT mode by the VHT terminal, and in the case of NGW, the NGW mode can be determined using the Reserved bit.

7 is a diagram illustrating a method of detecting a VHT frame according to an embodiment.

FIG. 7 is a diagram illustrating an NGW-SIG-A of a NGW (Type-3b) frame to explain an example of detecting a frame mode. In the NGW (Type-3b) frame, other signal information (signal information 1, 2, 3, 4) except for the reserved bit position is a frame format newly defined for NGW. The device receiving the frame may distinguish the frame mode by using at least one bit value among reserved bits for frame format information, such as NGW (Type-3a).

Referring to FIG. 7A, for example, the NGW (Type-3b1) 700 detects the frame mode 710 using the value of the first reserved bit 710 among the reserved bits 710, 711, and 712. can Referring to FIG. 7B, for example, the NGW (Type-3b2) 720 detects the frame mode 731 using the bit value of the second reserved bit 731 among the reserved bits 730, 731, and 732. can do. Referring to FIG. 7C, for example, the NGW (Type-3b3) 740 detects the frame mode 752 using the bit value of the third reserved bit 752 among the reserved bits 750, 751, and 752. can do.

The modulation scheme of the NGW (Type-3a) and NGW (Type-3b) signal fields is maintained the same as that of the VHT mode frame, but a reserved bit is used so that the NGW device can recognize that it is in the NGW frame mode. In the case of the legacy signal field, the parity bit error detection performance is poor, and the reserved bit is already used for other purposes, so it is difficult to use it for frame mode detection. However, in the case of HT-SIG or VHT-SIG, it has a CRC field, so Since it has excellent error detection performance, it can be used for frame mode detection.

8 is another example illustrating a method of transmitting a next-generation WLAN frame according to an embodiment.

The legacy 810 frame may transmit the first symbol of the signal field by QPSK and the second symbol by QPSK modulation. The HT 820 frame may transmit the first symbol of the signal field by Q-BPSK and the second symbol by Q-BPSK modulation. The VHT 830 frame may transmit the first symbol of the signal field in BPSK and the second symbol in Q-BPSK modulation.

The NGW (Type-4) 840 frame transmission method transmits both symbols in the same way as HT-SIG with Q-BPSK modulation, so that HT devices and VHT devices can recognize this frame as an HT frame, and legacy devices can be recognized as a legacy frame. The NGW device can determine whether or not it is an NGW frame by using the Reserved bit. For example, if the Reserved bit is 0, it is an NGW frame, and if the Reserved bit is 1, it can be recognized as an HT frame.

9 is a diagram illustrating a method of detecting an HT frame according to an embodiment.

In FIG. 9A , the NGW (Type-4a) 910 frame transmission method may determine an NGW frame using a reserved bit 911 . NGW (Type-4a) transmits both symbols in the same way as HT-SIG with Q-BPSK modulation, so that the HT device and VHT device recognize the frame as an HT frame, and the legacy device converts the frame into a legacy frame Recognizable. The NGW (Type-4a) device uses the Reserved bit 911 to determine whether it is an NGW frame or not. For example, if the Reserved bit 911 is 0, it is an NGW frame, and if the Reserved bit 911 is 1, it can be recognized as an HT frame.

In FIG. 9B, NGW (Type-4b) 950 is a frame format newly defined for NGW in signal information (signal information 1, 2, 3) except for reserved bit positions. As described in FIG. 9a, the NGW (Type-4b) 950 frame transmission method transmits both symbols in the same way as the HT-SIG with Q-BPSK modulation, so that the HT device and the VHT device recognize the frame as an HT frame and legacy devices can be recognized as legacy frames. The NGW (Type-4b) device uses the Reserved bit 951 to determine whether it is an NGW frame or not. For example, if the Reserved bit 951 is 0, it is an NGW frame, and if the Reserved bit 951 is 1, it can be recognized as an HT frame.

10 is a diagram illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

10 illustrates a method of transmitting a NGW (Type-1a) frame, and the method of transmitting a next-generation WLAN frame may be performed by a communication device of a next-generation WLAN frame. The transmission unit of the next-generation WLAN frame communication device may transmit the next-generation WLAN frame and the reception unit may receive the next-generation WLAN frame, and may be applied to the following embodiments.

In step 1010, the transmitter may modulate the first symbol of SIG-A of the next-generation WLAN frame with BPSK.

In step 1020, the transmitter may modulate the second symbol of SIG-A of the next-generation WLAN frame with Q-BPSK.

In step 1030, the transmitter may modulate the STF signal of the next-generation WLAN frame to have a phase difference of 90 degrees from the VHT-STF. The NGW-STF signal may be transmitted with BPSK signals mapped to positions (-1, 1) and (1, -1), and VHT-STF may be transmitted by mapping BPSK signals to positions (1, 1) and (-1, -1). Since the signals are mapped and transmitted, the NGW-STF and VHT-STF signals can be modulated to have a phase difference of 90 degrees.

The next-generation wireless LAN frame communication device according to an embodiment may recognize the frame mode by recognizing the phase of the STF signal after recognizing it as a VHT or NGW frame based on the BPSK and Q-BPSK signals in the signal field.

11 is a diagram illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

11 illustrates a method of receiving a NGW (Type-1a) frame, and the method of receiving a next-generation WLAN frame may be performed by a communication device of a next-generation WLAN frame.

In step 1110, the receiver may receive a communication signal.

In step 1120, the receiver may verify the first symbol and the second symbol of SIG-A of the communication signal.

In step 1130, when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal, the receiver may check the STF signal of the communication signal.

In step 1140, the receiver may identify the communication mode of the wireless LAN frame according to the STF signal. In this case, the receiver may determine the communication mode as the next-generation wireless LAN mode when the NGW-STF signal has a phase difference of 90 degrees from the VHT-STF signal. When the STF signal has no phase difference with the VHT-STF, the communication mode may be determined as the VHT mode.

12 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

12 illustrates a method of transmitting a NGW (Type-1b) frame. In step 1210, the transmitter may modulate the first symbol of SIG-A of the next-generation WLAN frame with BPSK.

In step 1220, the transmitter may modulate the second symbol of SIG-A of the next-generation WLAN frame with BPSK.

In step 1230, the transmitter may modulate the STF signal of the next-generation WLAN frame with Q-BPSK.

13 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

13 illustrates a method of receiving a NGW (Type-1b) frame, and in step 1310, the receiver may receive a communication signal.

In step 1320, the receiver may check the first symbol and the second symbol of SIG-A of the communication signal.

In step 1330, when the first symbol is the BPSK signal and the second symbol is the BPSK signal, the receiving unit may check the STF signal of the communication signal.

In step 1340, the communication mode of the WLAN frame may be identified according to the STF signal. In this case, when the STF signal is a Q-BPSK signal, the communication mode may be determined as the next-generation wireless LAN mode. When the STF signal is a BPSK signal, the communication mode may be determined as a legacy mode.

14 is another example illustrating a communication method of a next-generation WLAN frame according to an embodiment.

14 illustrates a method of transmitting a NGW (Type-2a) frame. In step 1410, the transmitter may modulate the first symbol of SIG-A of the next-generation WLAN frame with BPSK.

In step 1420, the transmitter may modulate the second symbol of SIG-A of the next-generation WLAN frame with Q-BPSK.

In step 1430, the transmitter may modulate the third symbol of SIG-A of the next-generation WLAN frame to have a phase difference of 90 degrees from VHT-STF. In this case, the STF signal may be mapped to a BPSK signal at positions of (-1, 1) and (1, -1).

15 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

15 illustrates a method of receiving a NGW (Type-2a) frame, and in step 1510, the receiver may receive a communication signal.

In step 1520, the receiver may check the first symbol and the second symbol of SIG-A of the communication signal.

In step 1530, when the first symbol is a BPSK signal and the second symbol is a Q-BPSK signal, the receiving unit can check the third symbol of SIG-A.

In step 1540, the receiver may identify the communication mode of the WLAN frame according to the third symbol. When the third symbol has a phase difference of 90 degrees from the VHT-STF, the communication mode may be determined as the next-generation WLAN mode. In addition, when the third symbol has no phase difference with VHT, the communication mode may be determined as the VHT mode.

16 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

16 illustrates a method of transmitting a NGW (Type-2b) frame. In step 1610, the transmitter may modulate the first symbol of SIG-A of the next-generation WLAN frame with BPSK.

In step 1620, the transmitter may modulate the second symbol of SIG-A of the next-generation WLAN frame with BPSK.

In step 1630, the transmitter may modulate the third symbol of SIG-A of the next-generation WLAN frame with Q-BPSK.

17 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

17 illustrates a method of receiving a NGW (Type-2b) frame, and in step 1710, the receiver may receive a communication signal.

In step 1720, the receiver may check the first symbol and the second symbol of SIG-A of the communication signal.

In step 1730, when the first symbol is a BPSK signal and the second symbol is a BPSK signal, the receiving unit may check the third symbol of SIG-A.

In step 1740, the receiver may identify the communication mode of the WLAN frame according to the third symbol of SIG-A. When the third symbol of SIG-A is a Q-BPSK signal, the communication mode may be determined as the next-generation wireless LAN mode. When the third symbol of SIG-A is a BPSK signal, the communication mode may be determined as the legacy mode.

18 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

18 illustrates a method of transmitting NGW (Type-3a) and NGW (Type-3b) frames.

In step 1810, the transmitter may generate the signal field of the next-generation WLAN frame with the same length as the signal field of the VHT frame. In this case, the signal field of the next-generation WLAN frame may be generated in the same manner as the signal field structure of the VHT frame, and the signal field of the next-generation WLAN frame may be generated differently from the signal field structure of the VHT frame.

In step 1820, the transmitter may input one of the reserved bits of the signal field structure of the VHT frame as a first value. For example, a predetermined reserved bit among reserved bits of the signal field structure of the VHT frame may be input as a first value. In this case, in the case of the next-generation wireless LAN mode, a predetermined reserved bit may be input as a first value, and in the case of the VHT mode, a predetermined reserved bit may be input as a second value.

In step 1830, the transmitter may modulate the first symbol of NGW-SIG-A of the next-generation WLAN frame with BPSK, and in step 1840, the transmitter modulates the second symbol of NGW-SIG-A of the next-generation WLAN frame. can be modulated with Q-BPSK.

19 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

19 illustrates a method of receiving NGW (Type-3a) and NGW (Type-3b) frames. In step 1910, the receiving unit may receive a WLAN frame.

In step 1920, the receiving unit may check predetermined reserved bits among reserved bits of the signal field structure of the VHT frame in the WLAN frame.

In step 1930, the receiver may identify the communication mode of the WLAN frame according to the identified reserved bits. In this case, when the identified reserved bits have a first value, the communication mode can be determined as the next-generation wireless LAN mode, and when the identified reserved bits have a second value, the communication mode can be determined as the VHT mode. For example, if the identified reserved bit is 0, it can be determined as the next-generation WLAN mode, and if the identified reserved bit is 1, it can be determined as the VHT mode.

20 is another example illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

20 illustrates a method of transmitting NGW (Type-4a) and NGW (Type-4b) frames.

In step 2010, the transmitter may generate the signal field of the next-generation WLAN frame with the same length as the signal field of the HT frame. In the case of the next-generation wireless LAN mode, a predetermined reserved bit may be input as a first value, and in the case of the HT mode, a predetermined reserved bit may be input as a second value. In addition, a signal field of a next-generation WLAN frame may be generated differently from a signal field structure of an HT frame.

In step 2020, the transmitter may input the reserved bits of the signal field structure of the HT frame as a first value.

In step 2030, the transmitter may modulate the first symbol of NGW-SIG-A of the next-generation WLAN frame with Q-BPSK, and in step 2040, the transmitter modulates two symbols of NGW-SIG-A of the next-generation WLAN frame. The th symbol may be modulated with Q-BPSK.

21 is a diagram illustrating a communication method of a next-generation wireless LAN frame according to an embodiment.

21 illustrates a method of receiving NGW (Type-4a) and NGW (Type-4b) frames, and in step 2110, the receiving unit may receive a WLAN frame.

In step 2120, the receiver may check the reserved bits of the signal field structure of the HT frame among the WLAN frames.

In step 2130, the receiver may identify the communication mode of the WLAN frame according to the identified reserved bits. When the identified reserved bits have a first value, the communication mode can be determined as the next-generation wireless LAN mode, and when the identified reserved bits have a second value, the communication mode can be determined as the HT mode.

A communication apparatus for a next-generation wireless LAN frame according to an embodiment can transmit an NGW frame that maintains compatibility with IEEE 802.11a/n/ac and enables high-efficiency and high-performance discrimination.

22 is a diagram showing the physical layer structure of IEEE 802.11.

The physical layer structure of IEEE 802.11 may include a Physical Layer Management Entity (PLME), a Physical Layer Convergence Entity (PLCP) sublayer, and a Physical Medium Dependent (PMD) sublayer. The PLME may provide a management function of the physical layer by serving as an interface between the MAC Layer Management Entity (MLME) and the physical layer. The PLCP sublayer transfers the MPDU (MAC Protocol Data Unit) received from the MAC sublayer according to the signal generated by the control of the MAC layer between the MAC sublayer and the PMD sublayer, or transmits the frame from the PMD sublayer to the MAC sublayer. can be conveyed The PMD sublayer is a PLCP sublayer and can support a physical layer to enable transmission and reception between two terminals through a wireless medium. The MPDU delivered by the MAC sublayer is called PSDU (Physical Service Data Unit) in the PLCP sublayer. At this time, an A-MPDU obtained by aggregating a plurality of MPDUs may be delivered.

The PLCP sublayer can add a field containing information required by the physical layer transceiver in the process of receiving the PSDU from the MAC sublayer and transferring it to the PMD sublayer. In this case, the added field may include a PLCP preamble, a PLCP header, a tail bit for initializing the convolutional encoder, and the like in the PSDU. The PLCP preamble may consist of a periodic and repetitive sequence for allowing the receiver to synchronize the PSDU successfully, control the gain, or know the channel state. The PLCP header may include information necessary for restoring the PSDU. For example, the PLCP header may include packet length, bandwidth, MCS, and technology used for transmission. The data field may include a service field including an initialization sequence for initializing the scrambler and an encoded sequence to which tail bits are attached. The data field may be transmitted after being modulated and encoded according to the transmission type included in the PLCP header. The PLCP sublayer of the transmitting side generates a PPDU and transmits it through the PMD sublayer, and the receiving side receives the PPDU, performs synchronization and gain control with the PLCP preamble, obtains channel state information, and transmits the PPDU through the PLCP header. Information necessary for packet recovery can be obtained and restored.

The IEEE 802.11ac standard supports a 20 MHz or 40 MHz bandwidth mode supported by the IEEE 802.11n standard and supports an 80 MHz bandwidth. In addition, transmission using two non-contiguous 80 MHz signals simultaneously (Non-contiguous 160 MHz) or continuous 160 MHz bandwidth signal transmission (Contiguous 160 MHz) is possible. An AP supporting the IEEE 802.11ac standard may simultaneously transmit packets to at least one or more terminals using Multi user MIMO (MU-MIMO) transmission technology. In the basic service set of the wireless LAN, the AP sends data divided into different spatial streams to groups including at least one terminal among several terminals associated with the AP. can be transmitted simultaneously. In addition, the AP may transmit data to only one terminal in a SU-MIMO (Single user MIMO) method. If the beamforming technology is supported between the AP and the UE belonging to the network, it is possible to transmit the signal to a single UE or a group of UEs of a specific target with a high signal gain. In order to support MU-MIMO transmission, a group identifier (Group ID) for a group of terminals is allocated, and the AP transmits a group ID management frame to allocate and distribute the group ID. One terminal may be assigned a plurality of group IDs. A wireless LAN terminal or AP may have different supported functions depending on a vendor that implements a system and manufactures a chip. In addition to mandatory implementation items, the standard stipulates items to be implemented selectively, and supported functions may differ depending on the version of the standard implemented. For example, convolutional encoding technology is a mandatory implementation item, but LDPC (Low Density Parity Check) technology is an optional implementation item, and beamforming, MU-MIMO, and 160 MHz bandwidth support are optional implementation items.

23 is a diagram showing the structure of a communication system of a next-generation wireless LAN frame according to an embodiment.

The wireless communication device of the present invention includes a transmit/receive antenna, a front end module (FEM), a transmitter, a receiver, an analog-to-digital converter (ADC), a digital-to-analog converter (DAC), a baseband processor processor), host interface, radio interface, processor, memory, and input/output interface. Signals may be transmitted and received through one or more antennas. The interface between the transmit/receive antenna and the RF transceiver is handled by the front-end module. The front-end module may include various external elements not included in the RF transceiver or elements for improving performance and expanding functions. For example, an external transmit power amplifier or an external receive low noise amplifier, a switch, and the like may be included. The transmitter functions to modulate and transmit packets to be transmitted, and the receiver functions to demodulate the received packets. Analog-to-digital converters and digital-to-analog converters convert signal types between analog and digital signals. The baseband processor performs a function of generating a frame according to a transmission frame format or extracting information from a received frame, encoding and decoding, and compensating for a signal distorted by a channel or an analog device. A radio interface serves as an interface between a wireless communication modem and a host. The processor may be configured to generate and transmit a PPDU format, and may be configured to receive the transmitted PPDU, obtain control information by interpreting field information in the received packet, and restore data using the same. The processor or transceiver may include an application specific integrated circuit (ASIC), logic circuit, or data processing device. The memory may include read only memory (ROM), read access memory (RAM), flash memory, a memory card, and a storage device. An input device may be a keyboard, a keypad, a microphone, a camera, and the like, and an output device may be a display unit, a speaker, and the like. When the above-described embodiments in the specification of the present invention are implemented as software or hardware, the process and functions for performing the above-described functions may be implemented as modules. This module may be implemented or executed in the form of a chip or logic circuit, data processing device, or processor.

210, 220: NGW frame

Claims (12)

In a method for a terminal to receive a physical layer protocol data unit (PPDU) in a wireless local area network (WLAN),
receiving the PPDU, the PPDU including a first field, a second field, and a third field;
As a step of checking the modulation scheme of the first field and the second field next to the first field, a first modulation scheme or a second modulation scheme is applied to each symbol of the first field and the second field, ; and
Checking a version of the PPDU based on a modulation scheme of a first field and a modulation scheme of a second field;
The second field is a version independent field, the third field is a version dependent field,
The modulation scheme of the first field, the modulation scheme of a first symbol included in the second field, and the modulation scheme of a second symbol included in the second field are the first modulation scheme,
If the PPDU is a first version, a third symbol next to the second symbol included in the second field is modulated based on the first modulation scheme;
If the PPDU is the second version, the third symbol next to the second symbol included in the second field is modulated based on the second modulation method. According to claim 1,
The PPDU version is indicated by the second field, and the PPDU version is indicated based on 3-bit information. According to claim 1,
The first field includes a legacy-signal (L-SIG) field, and the second field includes a next generation wireless LAN-signal field (NGW-SIG). According to claim 1,
The first modulation method is a binary phase-shift keying (BPSK) method. According to claim 1,
The second modulation method is a quadrature BPSK (Q-BPSK) method. According to claim 1,
wherein the PPDU sequentially includes a Legacy-Short Training (L-STF) field, a Legacy-Long Training (L-LTF) field, a first field, and a second field. In a terminal receiving a PPDU (Physical Layer Protocol Data Unit) in a wireless local area network (WLAN),
with transceiver;
Including; processor;
the processor,
Receiving the PPDU through the transceiver, wherein the PPDU includes a first field, a second field, and a third field;
Check the modulation method for the first field and the second field next to the first field, wherein the first modulation method or the second modulation method is applied to each symbol of the first field and the second field, and
Checking the version of the PPDU based on the modulation method of the first field and the modulation method of the second field;
The second field is a version independent field, the third field is a version dependent field,
The modulation scheme of the first field, the modulation scheme of a first symbol included in the second field, and the modulation scheme of a second symbol included in the second field are the first modulation scheme,
If the PPDU is a first version, a third symbol next to the second symbol included in the second field is modulated based on the first modulation scheme;
If the PPDU is the second version, the third symbol next to the second symbol included in the second field is modulated based on the second modulation method. According to claim 7,
The terminal receiving the PPDU, wherein the version of the PPDU is indicated by the second field, and the version of the PPDU is indicated based on 3-bit information. According to claim 7,
The first field includes a legacy-signal (L-SIG) field, and the second field includes a next generation wireless LAN-signal field (NGW-SIG). According to claim 7,
The first modulation method is a binary phase-shift keying (BPSK) method. According to claim 7,
The second modulation method is a quadrature BPSK (Q-BPSK) method. According to claim 7,
The PPDU sequentially includes a Legacy-Short Training (L-STF) field, a Legacy-Long Training (L-LTF) field, a first field, and a second field.