WO2016148411A1 - Method for multiple user transmission and reception in wireless communication system, and apparatus therefor - Google Patents

Abstract

A method for sending a physical protocol data unit (PPDU) of a station (STA) apparatus in a wireless LAN (WLAN) system according to one embodiment of the present invention comprises: a step of generating a high efficiency-short training field (HE-STF) sequence; a step of generating a PPDU including an HE-STF field configured on the basis of the HE-STF sequence; and a step of sending the PPDU, wherein the HE-STF field included in the PPDU uses frequency resource unit, the HE-STF sequence is mapped to tones included in the frequency resource unit, and any one predefined value from among 1+j, 1-j, -1+j, and -1-j values may be mapped to specific tones having a predetermined index among the tones to which the HE-STF sequence is mapped.

Description

Method for multi-user transmission / reception in wireless communication system and apparatus therefor

The present invention relates to a wireless communication system, and more particularly, proposes an efficient HE-STF sequence that can be applied to a new frame and numerology of a next-generation WirelessLAN system and can minimize PAPR.

Wi-Fi is a Wireless Local Area Network (WLAN) technology that allows devices to access the Internet in the 2.4 GHz, 5 GHz, or 60 GHz frequency bands.

WLANs are based on the Institute of Electrical and Electronic Engineers (IEEE) 802.11 standard. The Wireless Next Generation Standing Committee (WNG SC) of IEEE 802.11 is an ad hoc committee that considers the next generation wireless local area network (WLAN) in the medium to long term.

IEEE 802.11n aims to increase the speed and reliability of networks and to extend the operating range of wireless networks. More specifically, IEEE 802.11n supports High Throughput (HT), which provides up to 600 Mbps data rate, and also supports both transmitter and receiver to minimize transmission errors and optimize data rates. It is based on Multiple Inputs and Multiple Outputs (MIMO) technology using multiple antennas.

As the popularity of WLAN and the applications diversify using it, the next generation WLAN system supporting Very High Throughput (VHT) is the next version of the IEEE 802.11n WLAN system. IEEE 802.11ac supports data processing speeds of 1 Gbps and higher via 80 MHz bandwidth transmission and / or higher bandwidth transmission (eg 160 MHz) and operates primarily in the 5 GHz band.

Recently, there is a need for a new WLAN system to support higher throughput than the data throughput supported by IEEE 802.11ac.

The scope of IEEE 802.11ax, often discussed in the next-generation WLAN task group, also known as IEEE 802.11ax or High Efficiency (HEW) WLAN, includes: 1) 802.11 physical layer and MAC in the 2.4 GHz and 5 GHz bands; (medium access control) layer enhancement, 2) spectral efficiency and area throughput improvement, 3) environments with interference sources, dense heterogeneous network environments, and high user loads. Such as improving performance in real indoor environments and outdoor environments, such as the environment.

Scenarios considered mainly in IEEE 802.11ax are dense environments with many access points (APs) and stations (STAs), and IEEE 802.11ax discusses spectral efficiency and area throughput improvement in such a situation. . In particular, there is an interest in improving the performance of the indoor environment as well as the outdoor environment, which is not much considered in the existing WLAN.

In IEEE 802.11ax, we are interested in scenarios such as wireless office, smart home, stadium, hotspot, and building / apartment. There is a discussion about improving system performance in dense environments with many STAs.

In the future, IEEE 802.11ax improves system performance in outdoor basic service set (OBSS) environment, outdoor environment performance, and cellular offloading rather than single link performance in one basic service set (BSS). Discussion is expected to be active. The directionality of IEEE 802.11ax means that next-generation WLANs will increasingly have a technology range similar to that of mobile communication. Considering the situation where mobile communication and WLAN technology are recently discussed in the small cell and direct-to-direct communication area, the technical and business of next-generation WLAN and mobile communication based on IEEE 802.11ax Convergence is expected to become more active.

If the 802.11ax system uses an FFT size four times larger than a legacy WLAN system, it becomes difficult to apply the STF sequence of the 802.11ac system as it is. Accordingly, the present invention proposes an efficient (2x) HE-STF sequence suitable for the numerology of the 802.11ax system and minimizing the PAPR.

In a method of transmitting a physical protocol data unit (PPDU) of a station (STA) device in a wireless LAN (WLAN) system according to an embodiment of the present invention, generating a high efficiency-short training field (HE-STF) sequence step; Generating a PPDU including a HE-STF field configured based on the HE-STF sequence; And transmitting the PPDU, wherein the HE-STF field included in the PPDU is transmitted using a frequency resource unit. Wherein the HE-STF sequence is mapped to tones included in the frequency resource unit, and the specific tones having a predetermined index among the tones to which the HE-STF sequence is mapped are 1 + j, 1-j, − Any one of predefined values of 1 + j and -1-j may be mapped.

In addition, when the frequency resource unit is a 26 tone resource unit composed of 26 tones, the 26 tones sequentially have an index of 1 to 26, and the HE-STF sequence may be mapped to the 26 tones.

In addition, the predefined value is mapped to three specific tones of the 26 tones to which the HE-STF sequence is mapped, and the predetermined indexes of the three specific tones are (3, 11, 19), (4, 12,20), (5,13,21), (6,14,22), (7,15,23), or (8,16,24).

In addition, each of the three specific tones, {1 + j, 1 + j, -1-j}, {1 + j, 1-j, 1 + j}, {1 + j, -1 + j, 1 + j}, {1 + j, -1-j, -1-j}, {1-j, 1 + j, 1-j}, {1-j, 1-j, -1 + j}, { 1-j, -1 + j, -1 + j}, {1-j, -1-j, 1-j}, {-1 + j, 1 + j, -1 + j}, {-1+ j, 1-j, 1-j}, {-1 + j, -1 + j, 1-j}, {-1 + j, -1-j, -1 + j}, {-1-j, 1 + j, 1 + j}, {-1-j, 1-j, -1-j}, {-1-j, -1 + j, -1-j}, or {-1-j, − 1-j, 1 + j} values may be mapped sequentially.

In addition, the predefined value is mapped to four specific tones of the 26 tones to which the HE-STF sequence is mapped, and the predetermined index of the four specific tones is (1,9,17,25) or ( 2,10,18,26).

In addition, each of the four specific tones, {1 + j, 1 + j, 1 + j, -1-j}, {1 + j, 1 + j, -1-j, 1 + j}, {1 + j, 1-j, 1 + j, -1 + j}, {1 + j, 1-j, -1-j, 1-j}, {1 + j, -1 + j, 1 + j, 1-j}, {1 + j, -1 + j, -1-j, -1 + j}, {1 + j, -1-j, 1 + j, 1 + j}, {1 + j, -1-j, -1-j, -1-j}, {1-j, 1 + j, 1-j, -1-j}, {1-j, 1 + j, -1 + j, 1 + j}, {1-j, 1-j, 1-j, -1 + j}, {1-j, 1-j, -1 + j, 1-j}, {1-j, -1+ j, 1-j, 1-j}, {1-j, -1 + j, -1 + j, -1 + j}, {1-j, -1-j, 1-j, 1 + j} , {1-j, -1-j, -1 + j, -1-j}, {-1 + j, 1 + j, 1-j, 1 + j}, {-1 + j, 1 + j , -1 + j, -1-j}, {-1 + j, 1-j, 1-j, 1-j}, {-1 + j, 1-j, -1 + j, -1 + j }, {-1 + j, -1 + j, 1-j, -1 + j}, {-1 + j, -1 + j, -1 + j, 1-j}, {-1 + j, -1-j, 1-j, -1-j}, {-1 + j, -1-j, -1 + j, 1 + j}, {-1-j, 1 + j, 1 + j, 1 + j}, {-1-j, 1 + j, -1-j, -1-j}, {-1-j, 1-j, 1 + j, 1-j}, {-1-j , 1-j, -1-j, -1 + j}, {-1-j, -1 + j, 1 + j, -1 + j}, {-1-j, -1 + j, -1 -j, 1-j}, {-1-j, -1-j, 1 + j, -1-j}, or {-1-j, -1-j, -1-j, 1 + j} Values can be mapped sequentially.

In addition, when the frequency resource unit is a 52-tone resource unit composed of 52 tones, the 52 tones sequentially have an index of 1 to 52, and the HE-STF sequence may be mapped to the 52 tones.

In addition, the predefined value is mapped to six specific tones of the 52 tones to which the HE-STF sequence is mapped, and the predetermined index of the six specific tones is (5, 13, 21, 29, 37, 45), (6,14,22,30,38,46), (7,15,23,31,39,47), or (8,16,24,32,40,48).

In addition, each of the six specific tones, {1 + j, 1 + j, 1-j, 1 + j, 1-j, -1 + j}, {1 + j, 1 + j, -1 + j , 1 + j, -1 + j, 1-j}, {1 + j, 1-j, 1-j, -1 + j, -1 + j, -1-j}, {1 + j, 1 -j, -1 + j, -1 + j, 1-j, 1 + j}, {1 + j, -1 + j, 1-j, 1-j, -1 + j, 1 + j}, {1 + j, -1 + j, -1 + j, 1-j, 1-j, -1-j}, {1 + j, -1-j, 1-j, -1-j, 1- j, 1-j}, {1 + j, -1-j, -1 + j, -1-j, -1 + j, -1 + j}, {1-j, 1 + j, 1 + j , -1-j, -1-j, -1 + j}, {1-j, 1 + j, -1-j, -1-j, 1 + j, 1-j}, {1-j, 1-j, 1 + j, 1-j, 1 + j, -1-j}, {1-j, 1-j, -1-j, 1-j, -1-j, 1 + j}, {1-j, -1 + j, 1 + j, -1 + j, 1 + j, 1 + j}, {1-j, -1 + j, -1-j, -1 + j, -1 -j, -1-j}, {1-j, -1-j, 1 + j, 1 + j, -1-j, 1-j}, {1-j, -1-j, -1- j, 1 + j, 1 + j, -1 + j}, {-1 + j, 1 + j, 1 + j, -1-j, -1-j, 1-j}, {-1 + j , 1 + j, -1-j, -1-j, 1 + j, -1 + j}, {-1 + j, 1-j, 1 + j, 1-j, 1 + j, 1 + j }, {-1 + j, 1-j, -1-j, 1-j, -1-j, -1-j}, {-1 + j, -1 + j, 1 + j, -1+ j, 1 + j, -1-j}, {-1 + j, -1 + j, -1-j, -1 + j, -1-j, 1 + j}, {-1 + j, − 1-j, 1 + j, 1 + j, -1-j, -1 + j}, {-1 + j, -1-j, -1-j, 1 + j, 1 + j, 1-j }, {-1-j, 1 + j, 1-j, 1 + j, 1-j, 1-j}, {-1-j, 1 + j, -1 + j, 1 + j, -1 + j, -1 + j}, {-1-j, 1-j, 1-j, -1 + j, -1 + j, 1 + j}, {-1-j, 1- j, -1 + j, -1 + j, 1-j, -1-j}, {-1-j, -1 + j, 1-j, 1-j, -1 + j, -1-j }, {-1-j, -1 + j, -1 + j, 1-j, 1-j, 1 + j}, {-1-j, -1-j, 1-j, -1-j , 1-j, -1 + j}, or {-1-j, -1-j, -1 + j, -1-j, -1 + j, 1-j} values may be sequentially mapped .

In addition, the predefined value is mapped to 7 specific tones of the 52 tones to which the HE-STF sequence is mapped, and the predetermined index of the 7 specific tones is (1, 9, 17, 25, 33, 41,49), (2,10,18,26,34,42,50), (3,11,19,27,35,43,51), or (4,12,20,28,36,44 , 52).

In addition, each of the seven specific tones, {1 + j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, -1-j}, {1 + j, 1- j, -1-j, 1-j, -1-j, 1-j, 1 + j}, {1 + j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, 1 + j}, {1 + j, -1-j, 1 + j, 1 + j, -1-j, -1-j, -1-j}, {1-j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, 1-j}, {1-j, 1-j, 1-j, -1 + j, -1 + j, 1 -j, -1 + j}, {1-j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, -1 + j}, {1-j, -1 -j, -1 + j, -1-j, -1 + j, -1-j, 1-j}, {-1 + j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, -1 + j}, {-1 + j, 1-j, -1 + j, -1 + j, 1-j, 1-j, 1-j}, {-1 + j,- 1 + j, -1 + j, 1-j, 1-j, -1 + j, 1-j}, {-1 + j, -1-j, 1-j, -1-j, 1-j , -1-j, -1 + j}, {-1-j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, 1 + j}, {-1-j , 1-j, 1 + j, 1-j, 1 + j, 1-j, -1-j}, {-1-j, -1 + j, 1 + j, -1 + j, 1 + j , -1 + j, -1-j}, or {-1-j, -1-j, -1-j, 1 + j, 1 + j, -1-j, 1 + j} values sequentially Can be mapped.

Further, when the frequency resource unit is a 106 tone resource unit composed of 106 tones, the 106 tones sequentially have an index of 1 to 106, and the HE-STF sequence may be mapped to the 106 tones.

In addition, the predefined value is mapped to 13 specific tones of the 106 tones to which the HE-STF sequence is mapped, and the predetermined index of the 13 specific tones is (3, 11, 19, 27, 35, 43,51,59,67,75,83,91,99), (4,12,20,28,36,44,52,60,68,76,84,92,100), (5,13,21, 29,37,45,53,61,69,77,85,93,101), (6,14,22,30,38,46,54,62,70,78,86,94,102), (7,15, 23,31,39,47,55,63,71,79,87,95,103), or (8,16,24,32,40,48,56,64,72,80,88,96,104) .

Further, in each of the 13 specific tones, {1 + j, 1 + j, 1 + j, -1-j, -1-j, -1-j, 1 + j, 1 + j, -1-j , 1 + j, 1 + j, -1-j, 1 + j}, {1 + j, 1-j, -1-j, 1-j, -1-j, -1 + j, -1- j, -1 + j, -1-j, 1-j, -1-j, 1-j, 1 + j}, {1 + j, -1 + j, -1-j, -1 + j, -1-j, 1-j, -1-j, 1-j, -1-j, -1 + j, -1-j, -1 + j, 1 + j}, {1 + j, -1 -j, 1 + j, 1 + j, -1-j, 1 + j, 1 + j, -1-j, -1-j, -1-j, 1 + j, 1 + j, 1 + j }, {1-j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, 1 + j,- 1 + j, 1 + j, 1-j}, {1-j, 1-j, 1-j, -1 + j, -1 + j, -1 + j, 1-j, 1-j,- 1 + j, 1-j, 1-j, -1 + j, 1-j}, {1-j, -1 + j, 1-j, 1-j, -1 + j, 1-j, 1 -j, -1 + j, -1 + j, -1 + j, 1-j, 1-j, 1-j}, {1-j, -1-j, -1 + j, -1-j , -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j, -1 + j, -1-j, 1-j}, {-1 + j, 1 + j, 1-j, 1 + j, 1-j, -1-j, 1-j, -1-j, 1-j, 1 + j, 1-j, 1 + j, -1 + j }, {-1 + j, 1-j, -1 + j, -1 + j, 1-j, -1 + j, -1 + j, 1-j, 1-j, 1-j, -1 + j, -1 + j, -1 + j}, {-1 + j, -1 + j, -1 + j, 1-j, 1-j, 1-j, -1 + j, -1+ j, 1-j, -1 + j, -1 + j, 1-j, -1 + j}, {-1 + j, -1-j, 1-j, -1-j, 1-j, 1 + j, 1-j, 1 + j, 1-j, -1-j, 1-j, -1-j, -1 + j}, {-1-j, 1 + j, -1-j , -1-j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, 1+ j, -1-j, -1-j, -1-j}, {-1-j, 1-j, 1 + j, 1-j, 1 + j, -1 + j, 1 + j,- 1 + j, 1 + j, 1-j, 1 + j, 1-j, -1-j}, {-1-j, -1 + j, 1 + j, -1 + j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j}, or {-1-j, -1-j, -1 -j, 1 + j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, -1-j, -1-j, 1 + j, -1-j} May be mapped sequentially.

In addition, the predefined value is mapped to 14 specific tones of the 106 tones to which the HE-STF sequence is mapped, and the predetermined indices are (1, 9, 17, 25, 33, 41,49,57,65,73,81,89,97,105), or (2,10,18,26,34,42,50,58,66,74,82,90,98,106).

Further, in each of the 14 specific tones, {1 + j, 1 + j, 1 + j, 1 + j, -1-j, 1 + j, -1-j, 1 + j, 1 + j, − 1-j, -1-j, 1 + j, 1 + j, -1-j}, {1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, -1-j, -1-j, -1-j, 1 + j, -1-j, 1 + j}, {1 + j, 1-j, 1+ j, 1-j, 1 + j, 1-j, 1 + j, 1-j, -1-j, -1 + j, 1 + j, -1 + j, -1-j, 1-j} , {1 + j, 1-j, -1-j, -1 + j, -1-j, 1-j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j , -1 + j, 1 + j, -1 + j}, {1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j, 1-j, 1 + j, 1-j, -1-j, -1 + j}, {1 + j, -1 + j, -1-j, 1-j, -1-j, -1 + j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j}, {1 + j, -1 -j, 1 + j, -1-j, -1-j, -1-j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j}, {1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, -1-j , 1 + j, -1-j, -1-j, -1-j, -1-j}, {1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j , 1-j, 1 + j, -1 + j, -1-j, 1-j, -1-j, -1 + j, 1 + j}, {1-j, 1 + j, -1+ j, -1-j, -1 + j, 1 + j, 1-j, -1-j, 1-j, -1-j, 1-j, -1-j, 1-j, -1- j}, {1-j, 1-j, 1-j, 1-j, -1 + j, 1-j, -1 + j, 1-j, 1-j, -1 + j, -1+ j, 1-j, 1-j, -1 + j}, {1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, -1 + j, -1 + j, -1 + j, 1-j, -1 + j, 1- j}, {1-j, -1 + j, 1-j, -1 + j, -1 + j, -1 + j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j}, {1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1+ j, 1-j, -1 + j, 1-j, -1 + j, -1 + j, -1 + j, -1 + j}, {1-j, -1-j, 1-j, -1-j, 1-j, -1-j, 1-j, -1-j, -1 + j, 1 + j, 1-j, 1 + j, -1 + j, -1-j} , {1-j, -1-j, -1 + j, 1 + j, -1 + j, -1-j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j}, {-1 + j, 1 + j, 1-j, -1-j, 1-j, 1 + j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j}, {-1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, 1-j, -1-j, -1 + j, -1-j, 1-j, 1 + j}, {-1+ j, 1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, 1-j, -1 + j, 1-j, 1-j, 1-j, 1-j}, {-1 + j, 1-j, -1 + j, 1-j, 1-j, 1-j, 1-j, 1-j, -1 + j,- 1 + j, 1-j, 1-j, -1 + j, -1 + j}, {-1 + j, -1 + j, 1-j, 1-j, -1 + j, -1+ j, 1-j, 1-j, 1-j, 1-j, 1-j, -1 + j, 1-j, -1 + j}, {-1 + j, -1 + j, -1 + j, -1 + j, 1-j, -1 + j, 1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, 1 -j}, {-1 + j, -1-j, 1-j, 1 + j, 1-j, -1-j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j}, {-1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, 1-j, 1 + j, -1 + j, 1 + j, 1-j, -1-j}, {-1-j, 1 + j, 1 + j , -1-j, -1-j, 1+ j, 1 + j, -1-j, 1 + j, -1-j, 1 + j, 1 + j, 1 + j, 1 + j}, {-1-j, 1 + j, -1- j, 1 + j, 1 + j, 1 + j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j} , {-1-j, 1-j, 1 + j, -1 + j, 1 + j, 1-j, -1-j, -1 + j, -1-j, -1 + j, -1 -j, -1 + j, -1-j, -1 + j}, {-1-j, 1-j, -1-j, 1-j, -1-j, 1-j, -1- j, 1-j, 1 + j, -1 + j, -1-j, -1 + j, 1 + j, 1-j}, {-1-j, -1 + j, 1 + j, 1 -j, 1 + j, -1 + j, -1-j, 1-j, -1-j, 1-j, -1-j, 1-j, -1-j, 1-j}, { -1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, 1 + j, 1-j, -1 -j, 1-j, 1 + j, -1 + j}, {-1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, 1 + j, 1 + j, 1 + j, -1-j, 1 + j, -1-j}, or {-1-j, -1-j, -1-j, −1 -j, 1 + j, -1-j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, 1 + j} May be mapped sequentially.

In addition, the HE-STF field may have a period of 1.6 ms.

In addition, STA (Station) device in a wireless LAN (WLAN) system according to another embodiment of the present invention, RF (Radio Frequency) unit for transmitting and receiving radio signals; And a processor controlling the RF unit; The processor may include generating a High Efficiency-Short Training Field (HE-STF) sequence, generating a PPDU including an HE-STF field configured based on the HE-STF sequence, and transmitting the PPDU. The HE-STF field included in the PPDU is transmitted using a frequency resource unit, and the HE-STF sequence is mapped to tones included in the frequency resource unit, and the HE-STF sequence is A predetermined value among 1 + j, 1-j, -1 + j, and -1-j values may be mapped to specific tones having a predetermined index among the mapped tones.

The present invention aims to propose an efficient (2x) HE-STF sequence that is suitable for the neurology of 802.11ax system and can minimize the PAPR. In addition to the various effects of the present invention will be described later in detail with reference to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, included as part of the detailed description in order to provide a thorough understanding of the present invention, provide embodiments of the present invention and together with the description, describe the technical features of the present invention.

1 is a diagram illustrating an example of an IEEE 802.11 system to which the present invention can be applied.

2 is a diagram illustrating a structure of a layer architecture of an IEEE 802.11 system to which the present invention may be applied.

3 illustrates a non-HT format PPDU and a HT format PPDU of a wireless communication system to which the present invention can be applied.

4 illustrates a VHT format PPDU format of a wireless communication system to which the present invention can be applied.

5 is a diagram illustrating a constellation for distinguishing a format of a PPDU of a wireless communication system to which the present invention can be applied.

6 illustrates a MAC frame format of an IEEE 802.11 system to which the present invention can be applied.

7 illustrates the HT format of the HT Control field in a wireless communication system to which the present invention can be applied.

8 illustrates the VHT format of the HT Control field in a wireless communication system to which the present invention can be applied.

FIG. 9 is a diagram illustrating a general link setup procedure in a wireless communication system to which the present invention can be applied.

FIG. 10 is a diagram illustrating an arbitrary backoff period and a frame transmission procedure in a wireless communication system to which the present invention can be applied.

FIG. 11 is a diagram for explaining a hidden node and an exposed node in a wireless communication system to which the present invention can be applied.

12 is a view for explaining the RTS and CTS in a wireless communication system to which the present invention can be applied.

13 to 15 are diagrams for explaining in detail the operation of the STA receiving the TIM in a wireless communication system to which the present invention can be applied.

FIG. 16 is a diagram for explaining a group-based AID in a wireless communication system to which the present invention can be applied.

17 through 20 are diagrams illustrating a High Efficiency (HE) format PPDU according to an embodiment of the present invention.

21 through 23 are diagrams illustrating a resource allocation unit in an OFDMA multi-user transmission scheme according to an embodiment of the present invention.

24 is a table showing values of pilot tones according to the number of streams according to an embodiment of the present invention.

25 illustrates the location of 2x HE-STF tones in a 26-tone resource unit in accordance with an embodiment of the present invention.

Figure 26 illustrates the location of 2x HE-STF tones in a 52-tone resource unit according to an embodiment of the present invention.

27 illustrates the location of 2 × HE-STF tones in a 106 ton (or 107, 108 ton) resource unit in accordance with an embodiment of the present invention.

28 is a flowchart illustrating a PPDU transmission method of an STA device according to an embodiment of the present invention.

29 is a block diagram of each STA apparatus according to an embodiment of the present invention.

The terminology used herein is a general term that has been widely used as far as possible in consideration of the functions in the present specification, but may vary according to the intention of a person skilled in the art, convention or the emergence of a new technology. In addition, in certain cases, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in the description of the corresponding embodiment. Therefore, it is to be understood that the terminology used herein is to be interpreted based not on the name of the term but on the actual meaning and contents throughout the present specification.

Moreover, although the embodiments will be described in detail with reference to the accompanying drawings and the contents described in the accompanying drawings, the present invention is not limited or restricted to the embodiments.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The following techniques are code division multiple access (CDMA), frequency division multiple access (FDMA), time division multiple access (TDMA), orthogonal frequency division multiple access (OFDMA), single carrier frequency division multiple access (SC-FDMA), and NOMA It can be used in various radio access systems such as non-orthogonal multiple access. CDMA may be implemented by a radio technology such as universal terrestrial radio access (UTRA) or CDMA2000. TDMA may be implemented with wireless technologies such as global system for mobile communications (GSM) / general packet radio service (GPRS) / enhanced data rates for GSM evolution (EDGE). OFDMA may be implemented with wireless technologies such as Institute of Electrical and Electronics Engineers (IEEE) 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802-20, evolved UTRA (E-UTRA), and the like. UTRA is part of a universal mobile telecommunications system (UMTS). 3rd generation partnership project (3GPP) long term evolution (LTE) is a part of evolved UMTS (E-UMTS) using E-UTRA, and employs OFDMA in downlink and SC-FDMA in uplink. LTE-A (advanced) is the evolution of 3GPP LTE.

Embodiments of the present invention may be supported by standard documents disclosed in at least one of the wireless access systems IEEE 802, 3GPP and 3GPP2. That is, steps or parts which are not described to clearly reveal the technical spirit of the present invention among the embodiments of the present invention may be supported by the above documents. In addition, all terms disclosed in the present document can be described by the above standard document.

For clarity, the following description focuses on IEEE 802.11 systems, but the technical features of the present invention are not limited thereto.

System general

1 is a diagram illustrating an example of an IEEE 802.11 system to which the present invention can be applied.

The IEEE 802.11 structure may be composed of a plurality of components, and a wireless communication system supporting a station (STA) station mobility that is transparent to a higher layer may be provided by their interaction. . A basic service set (BSS) may correspond to a basic building block in an IEEE 802.11 system.

In FIG. 1, there are three BSSs (BSS 1 to BSS 3) and two STAs are included as members of each BSS (STA 1 and STA 2 are included in BSS 1, and STA 3 and STA 4 are BSS 2. Included in, and STA 5 and STA 6 are included in BSS 3) by way of example.

In FIG. 1, an ellipse representing a BSS may be understood to represent a coverage area where STAs included in the BSS maintain communication. This area may be referred to as a basic service area (BSA). When the STA moves out of the BSA, the STA cannot directly communicate with other STAs in the BSA.

The most basic type of BSS in an IEEE 802.11 system is an independent BSS (IBSS). For example, the IBSS may have a minimal form consisting of only two STAs. In addition, BSS 3 of FIG. 1, which is the simplest form and other components are omitted, may correspond to a representative example of the IBSS. This configuration is possible when STAs can communicate directly. In addition, this type of LAN may not be configured in advance, but may be configured when a LAN is required, which may be referred to as an ad-hoc network.

The membership of the STA in the BSS may be dynamically changed by turning the STA on or off, the STA entering or exiting the BSS region, or the like. In order to become a member of the BSS, the STA may join the BSS using a synchronization process. In order to access all services of the BSS infrastructure, the STA must be associated with the BSS. This association may be set up dynamically and may include the use of a Distribution System Service (DSS).

The direct STA-to-STA distance in an 802.11 system may be limited by physical layer (PHY) performance. In some cases, this distance limit may be sufficient, but in some cases, communication between STAs over longer distances may be required. A distribution system (DS) may be configured to support extended coverage.

DS refers to a structure in which BSSs are interconnected. Specifically, instead of the BSS independently as shown in FIG. 1, the BSS may exist as an extended type component of a network composed of a plurality of BSSs.

DS is a logical concept and can be specified by the characteristics of the Distribution System Medium (DSM). In this regard, the IEEE 802.11 standard logically distinguishes between wireless medium (WM) and distribution system medium (DSM). Each logical medium is used for a different purpose and is used by different components. The definition of the IEEE 802.11 standard does not limit these media to the same or to different ones. In this way, the plurality of media are logically different, and thus the flexibility of the structure of the IEEE 802.11 system (DS structure or other network structure) can be described. That is, the IEEE 802.11 system structure can be implemented in various ways, the corresponding system structure can be specified independently by the physical characteristics of each implementation.

The DS may support mobile devices by providing seamless integration of multiple BSSs and providing logical services for handling addresses to destinations.

The AP means an entity that enables access to the DS through the WM to the associated STAs and has STA functionality. Data movement between the BSS and the DS may be performed through the AP. For example, STA 2 and STA 3 illustrated in FIG. 1 have a functionality of STA, and provide a function of allowing associated STAs STA 1 and STA 4 to access the DS. In addition, since all APs basically correspond to STAs, all APs are addressable entities. The address used by the AP for communication on the WM and the address used by the AP for communication on the DSM need not necessarily be the same.

Data transmitted from one of the STAs associated with an AP to the STA address of that AP may always be received at an uncontrolled port and processed by an IEEE 802.1X port access entity. In addition, when a controlled port is authenticated, transmission data (or frame) may be transmitted to the DS.

A wireless network of arbitrary size and complexity may be composed of DS and BSSs. In an IEEE 802.11 system, this type of network is referred to as an extended service set (ESS) network. The ESS may correspond to a set of BSSs connected to one DS. However, the ESS does not include a DS. The ESS network is characterized by what appears to be an IBSS network at the Logical Link Control (LLC) layer. STAs included in the ESS may communicate with each other, and mobile STAs may move from one BSS to another BSS (within the same ESS) transparently to the LLC.

In the IEEE 802.11 system, nothing is assumed about the relative physical location of the BSSs in FIG. 1, and all of the following forms are possible.

Specifically, BSSs can be partially overlapped, which is the form generally used to provide continuous coverage. Also, the BSSs may not be physically connected, and logically there is no limit to the distance between the BSSs. In addition, the BSSs can be located at the same physical location, which can be used to provide redundancy. In addition, one (or more) IBSS or ESS networks may be physically present in the same space as one or more ESS networks. This may be necessary if the ad-hoc network is operating at the location of the ESS network, if the IEEE 802.11 networks are physically overlapped by different organizations, or if two or more different access and security policies are required at the same location. It may correspond to an ESS network type in a case.

In a WLAN system, an STA is a device that operates according to Medium Access Control (MAC) / PHY regulations of IEEE 802.11. As long as the function of the STA is not distinguished from the AP individually, the STA may include an AP STA and a non-AP STA. However, when communication is performed between the STA and the AP, the STA may be understood as a non-AP STA. In the example of FIG. 1, STA 1, STA 4, STA 5, and STA 6 correspond to non-AP STAs, and STA 2 and STA 3 correspond to AP STAs.

Non-AP STAs generally correspond to devices that users directly handle, such as laptop computers and mobile phones. In the following description, a non-AP STA includes a wireless device, a terminal, a user equipment (UE), a mobile station (MS), a mobile terminal, and a wireless terminal. ), A wireless transmit / receive unit (WTRU), a network interface device (network interface device), a machine-type communication (MTC) device, a machine-to-machine (M2M) device, or the like.

In addition, the AP is a base station (BS), Node-B (Node-B), evolved Node-B (eNB), and Base Transceiver System (BTS) in other wireless communication fields. , A concept corresponding to a femto base station (Femto BS).

Hereinafter, in the present specification, downlink (DL) means communication from the AP to the non-AP STA, and uplink (UL) means communication from the non-AP STA to the AP. In downlink, the transmitter may be part of an AP and the receiver may be part of a non-AP STA. In uplink, a transmitter may be part of a non-AP STA and a receiver may be part of an AP.

2 is a diagram illustrating a structure of a layer architecture of an IEEE 802.11 system to which the present invention may be applied.

2, a layer architecture of an IEEE 802.11 system may include a MAC (Medium Access Control) sublayer / layer and a PHY sublayer / layer.

The PHY may be classified into a Physical Layer Convergence Procedure (PLCP) entity and a Physical Medium Dependent (PMD) entity. In this case, the PLCP entity plays a role of connecting a MAC and a data frame, and the PMD entity plays a role of wirelessly transmitting and receiving data with two or more STAs.

Both the MAC and the PHY may include a management entity, and may be referred to as a MAC sublayer management entity (MLME) and a PHY sublayer management entity (PLME), respectively. These management entities provide layer management service interfaces through the operation of layer management functions. The MLME may be connected to the PLME to perform management operations of the MAC, and likewise, the PLME may be connected to the MLME to perform management operations of the PHY.

In order to provide correct MAC operation, a Station Management Entity (SME) may be present in each STA. The SME is a management entity independent of each layer. The SME collects layer-based state information from MLME and PLME or sets values of specific parameters of each layer. The SME can perform these functions on behalf of general system management entities and implement standard management protocols.

MLME, PLME and SME can interact in a variety of ways based on primitives. Specifically, the XX-GET.request primitive is used to request the value of a Management Information Base attribute (MIB attribute), and the XX-GET.confirm primitive, if the status is 'SUCCESS', returns the value of that MIB attribute. Otherwise, it returns with an error indication in the status field. The XX-SET.request primitive is used to request that a specified MIB attribute be set to a given value. If the MIB attribute is meant for a particular action, this request requests the execution of that particular action. And, if the state is 'SUCCESS' XX-SET.confirm primitive, it means that the specified MIB attribute is set to the requested value. In other cases, the status field indicates an error condition. If this MIB attribute means a specific operation, this primitive can confirm that the operation was performed.

The PHY provides an interface to the MAC through TXVECTOR, RXVECTOR, and PHYCONFIG_VECTOR. TXVECTOR supports PPDU specific transmission parameters to PHY. Using RXVECTOR, the PHY informs the MAC of the PPDU parameter received. TXVECTOR is delivered from the MAC to the PHY via the PHY-TXSTART.request primitive, and RXVECTOR is delivered from the PHY to the MAC via the PHY-RXSTART.indication primitive.

Using PHYCONFIG_VECTOR, the MAC configures the PHY's behavior regardless of frame transmission or reception.

The operation in each sub-layer (or layer) will be briefly described as follows.

MAC is a MAC header and a frame check sequence (FCS) in a MAC Service Data Unit (MSDU) or a fragment of an MSDU received from an upper layer (eg, LLC). Attach to create one or more MAC Protocol Data Units (MPDUs). The generated MPDU is delivered to the PHY.

When an aggregated MSDU (A-MSDU) scheme is used, a plurality of MSDUs may be merged into a single A-MSDU (aggregated MSDU). The MSDU merging operation may be performed at the MAC upper layer. The A-MSDU is delivered to the PHY as a single MPDU (if it is not fragmented).

The PHY generates a physical protocol data unit (PPDU) by adding an additional field including information required by a physical layer transceiver to a physical service data unit (PSDU) received from the MAC. PPDUs are transmitted over wireless media.

The PSDU is substantially the same as the MPDU because the PSD is received by the PHY from the MAC and the MPDU is sent by the MAC to the PHY.

When an aggregated MPDU (A-MPDU) scheme is used, a plurality of MPDUs (where each MPDU may carry an A-MSDU) may be merged into a single A-MPDU. The MPDU merging operation may be performed at the MAC lower layer. A-MPDUs may be merged with various types of MPDUs (eg, QoS data, Acknowledge (ACK), Block ACK (BlockAck), etc.). The PHY receives the A-MPDU as a single PSDU to the MAC. That is, the PSDU is composed of a plurality of MPDUs. Thus, A-MPDUs are transmitted over the wireless medium in a single PPDU.

PPDU Physical Protocol Data Unit Format

Physical Protocol Data Unit (PPDU) refers to a block of data generated at the physical layer. Hereinafter, a PPDU format will be described based on an IEEE 802.11 WLAN system to which the present invention can be applied.

3 illustrates a non-HT format PPDU and a HT format PPDU of a wireless communication system to which the present invention can be applied.

3A illustrates a non-HT format PPDU for supporting an IEEE 802.11a / g system. Non-HT PPDUs may also be referred to as legacy PPDUs.

Referring to (a) of FIG. 3, the non-HT format PPDU includes an L-STF (Legacy (or Non-HT) Short Training field), L-LTF (Legacy (or, Non-HT) Long Training field) and It consists of a legacy format preamble and a data field composed of L-SIG (Legacy (or Non-HT) SIGNAL) field.

The L-STF may include a short training orthogonal frequency division multiplexing symbol. L-STF can be used for frame timing acquisition, automatic gain control (AGC), diversity detection, and coarse frequency / time synchronization. .

The L-LTF may include a long training orthogonal frequency division multiplexing symbol. L-LTF may be used for fine frequency / time synchronization and channel estimation.

The L-SIG field may be used to transmit control information for demodulation and decoding of the data field. The L-SIG field may include information about a data rate and a data length.

3B illustrates an HT-mixed format PPDU (HTDU) for supporting both an IEEE 802.11n system and an IEEE 802.11a / g system.

Referring to FIG. 3B, the HT mixed format PPDU includes a legacy format preamble including an L-STF, L-LTF, and L-SIG fields, an HT-SIG (HT-Signal) field, and an HT-STF (HT Short). Training field), HT-formatted preamble and data field including HT-LTF (HT Long Training field).

Since the L-STF, L-LTF, and L-SIG fields mean legacy fields for backward compatibility, they are the same as non-HT formats from L-STF to L-SIG fields. Even if the L-STA receives the HT mixed PPDU, the L-STA may interpret the data field through the L-LTF, L-LTF and L-SIG fields. However, the L-LTF may further include information for channel estimation that the HT-STA performs to receive the HT mixed PPDU and demodulate the L-SIG field and the HT-SIG field.

The HT-STA may know that it is an HT-mixed format PPDU using the HT-SIG field following the legacy field, and may decode the data field based on the HT-STA.

The HT-LTF field may be used for channel estimation for demodulation of the data field. Since IEEE 802.11n supports Single-User Multi-Input and Multi-Output (SU-MIMO), a plurality of HT-LTF fields may be configured for channel estimation for each data field transmitted in a plurality of spatial streams.

The HT-LTF field includes data HT-LTF used for channel estimation for spatial streams and extension HT-LTF (additional used for full channel sounding). It can be configured as. Accordingly, the plurality of HT-LTFs may be equal to or greater than the number of spatial streams transmitted.

In the HT-mixed format PPDU, the L-STF, L-LTF, and L-SIG fields are transmitted first in order to receive the L-STA and acquire data. Thereafter, the HT-SIG field is transmitted for demodulation and decoding of data transmitted for the HT-STA.

The HT-SIG field is transmitted without performing beamforming so that the L-STA and HT-STA can receive the corresponding PPDU to acquire data, and then the HT-STF, HT-LTF and data fields transmitted are precoded. Wireless signal transmission is performed through. In this case, the HT-STF field is transmitted to allow the STA to perform precoding to take into account the variable power due to precoding, and then the plurality of HT-LTF and data fields after that.

3 (c) illustrates an HT-GF format PPDU (HT-GF) for supporting only an IEEE 802.11n system.

Referring to FIG. 3C, the HT-GF format PPDU includes HT-GF-STF, HT-LTF1, HT-SIG field, a plurality of HT-LTF2 and data fields.

HT-GF-STF is used for frame timing acquisition and AGC.

HT-LTF1 is used for channel estimation.

The HT-SIG field is used for demodulation and decoding of the data field.

HT-LTF2 is used for channel estimation for demodulation of data fields. Similarly, since HT-STA uses SU-MIMO, channel estimation is required for each data field transmitted in a plurality of spatial streams, and thus HT-LTF2 may be configured in plural.

The plurality of HT-LTF2 may be configured of a plurality of Data HT-LTF and a plurality of extended HT-LTF similarly to the HT-LTF field of the HT mixed PPDU.

In (a) to (c) of FIG. 3, the data field is a payload, and includes a service field, a SERVICE field, a scrambled PSDU field, tail bits, and padding bits. It may include. All bits of the data field are scrambled.

3D illustrates a service field included in a data field. The service field has 16 bits. Each bit is assigned from 0 to 15, and transmitted sequentially from bit 0. Bits 0 to 6 are set to 0 and used to synchronize the descrambler in the receiver.

The IEEE 802.11ac WLAN system supports downlink multi-user multiple input multiple output (MU-MIMO) transmission in which a plurality of STAs simultaneously access a channel in order to efficiently use a wireless channel. According to the MU-MIMO transmission scheme, the AP may simultaneously transmit packets to one or more STAs that are paired with MIMO.

DL MU transmission (downlink multi-user transmission) refers to a technology in which an AP transmits a PPDU to a plurality of non-AP STAs through the same time resource through one or more antennas.

Hereinafter, the MU PPDU refers to a PPDU that delivers one or more PSDUs for one or more STAs using MU-MIMO technology or OFDMA technology. The SU PPDU means a PPDU having a format in which only one PSDU can be delivered or in which no PSDU exists.

The size of control information transmitted to the STA may be relatively large compared to the size of 802.11n control information for MU-MIMO transmission. An example of control information additionally required for MU-MIMO support includes information indicating the number of spatial streams received by each STA, information related to modulation and coding of data transmitted to each STA, and the like. Can be.

Therefore, when MU-MIMO transmission is performed to simultaneously provide data services to a plurality of STAs, the size of transmitted control information may be increased according to the number of receiving STAs.

In order to efficiently transmit the increased size of the control information, a plurality of control information required for MU-MIMO transmission is required separately for common control information common to all STAs and specific STAs. The data may be transmitted by being divided into two types of information of dedicated control information.

4 illustrates a VHT format PPDU format of a wireless communication system to which the present invention can be applied.

4 illustrates a VHT format PPDU (VHT format PPDU) for supporting an IEEE 802.11ac system.

Referring to FIG. 4, the VHT format PPDU includes a legacy format preamble consisting of L-STF, L-LTF, and L-SIG fields, a VHT-SIG-A (VHT-Signal-A) field, and VHT-STF (VHT Short Training). field), VHT Long Training field (VHT-LTF) and VHT-SIG-B (VHT-Signal-B) field.

Since L-STF, L-LTF, and L-SIG mean legacy fields for backward compatibility, they are the same as non-HT formats from L-STF to L-SIG fields. However, the L-LTF may further include information for channel estimation to be performed to demodulate the L-SIG field and the VHT-SIG-A field.

The L-STF, L-LTF, L-SIG field, and VHT-SIG-A field may be repeatedly transmitted in 20 MHz channel units. For example, when a PPDU is transmitted on four 20 MHz channels (i.e., 80 MHz bandwidth), the L-STF, L-LTF, L-SIG field, and VHT-SIG-A field are repeatedly transmitted on every 20 MHz channel. Can be.

The VHT-STA may know that it is a VHT format PPDU using the VHT-SIG-A field following the legacy field, and may decode the data field based on the VHT-STA.

In the VHT format PPDU, the L-STF, L-LTF and L-SIG fields are transmitted first in order to receive the L-STA and acquire data. Thereafter, the VHT-SIG-A field is transmitted for demodulation and decoding of data transmitted for the VHT-STA.

The VHT-SIG-A field is a field for transmitting control information common to the AP and the MIMO paired VHT STAs, and includes control information for interpreting the received VHT format PPDU.

The VHT-SIG-A field may include a VHT-SIG-A1 field and a VHT-SIG-A2 field.

The VHT-SIG-A1 field includes information on channel bandwidth (BW) used, whether space time block coding (STBC) is applied, and group identification information for indicating a group of STAs grouped in MU-MIMO. Group ID (Group Identifier), information about the number of space-time streams (NSTS) / Partial AID (Partial Association Identifier) and Transmit power save forbidden information. can do. Here, the Group ID means an identifier assigned to the STA group to be transmitted to support MU-MIMO transmission, and may indicate whether the currently used MIMO transmission method is MU-MIMO or SU-MIMO.

Table 1 is a table illustrating the VHT-SIG-A1 field.

The VHT-SIG-A2 field contains information on whether a short guard interval (GI) is used, forward error correction (FEC) information, information on modulation and coding scheme (MCS) for a single user, and multiple information. Information on the type of channel coding for the user, beamforming-related information, redundancy bits for cyclic redundancy checking (CRC), tail bits of convolutional decoder, and the like. Can be.

Table 2 is a table illustrating the VHT-SIG-A2 field.

VHT-STF is used to improve the performance of AGC estimation in MIMO transmission. The VHT-STF field duration is 4 ms. The frequency domain sequence used to configure the VHT-STF in the 20 MHz transmission band may be the same as the L-STF. The VHT-STF in the 40 MHz / 80 MHz transmission band may be configured by duplicating the frequency domain sequence in the 20 MHz transmission band in 20 MHz units and performing phase rotation in the replicated 20 MHz units.

VHT-LTF is used by the VHT-STA to estimate the MIMO channel. Since the VHT WLAN system supports MU-MIMO, the VHT-LTF may be set as many as the number of spatial streams in which a PPDU is transmitted. In addition, if full channel sounding is supported, the number of VHT-LTFs may be greater.

The VHT-SIG-B field includes dedicated control information required for a plurality of MU-MIMO paired VHT-STAs to receive a PPDU and acquire data. Therefore, the VHT-STA may be designed to decode the VHT-SIG-B field only when the common control information included in the VHT-SIG-A field indicates the MU-MIMO transmission currently received. . On the other hand, if the common control information indicates that the currently received PPDU is for a single VHT-STA (including SU-MIMO), the STA may be designed not to decode the VHT-SIG-B field.

The VHT-SIG-B field includes information on modulation, encoding, and rate-matching of each VHT-STA. The size of the VHT-SIG-B field may vary depending on the type of MIMO transmission (MU-MIMO or SU-MIMO) and the channel bandwidth used for PPDU transmission.

In order to transmit a PPDU of the same size to STAs paired to an AP in a system supporting MU-MIMO, information indicating a bit size of a data field constituting the PPDU and / or indicating a bit stream size constituting a specific field May be included in the VHT-SIG-A field.

However, the L-SIG field may be used to effectively use the PPDU format. In order to transmit the same size PPDU to all STAs, a length field and a rate field included in the L-SIG field and transmitted may be used to provide necessary information. In this case, since the MAC Protocol Data Unit (MPDU) and / or Aggregate MAC Protocol Data Unit (A-MPDU) are set based on the bytes (or octets) of the MAC layer, additional padding is applied at the physical layer. May be required.

In FIG. 4, the data field is a payload and may include a service field, a scrambled PSDU, tail bits, and padding bits.

Since the formats of various PPDUs are mixed and used as described above, the STA must be able to distinguish the formats of the received PPDUs.

Here, the meaning of distinguishing a PPDU (or meaning of distinguishing a PPDU format) may have various meanings. For example, the meaning of identifying the PPDU may include determining whether the received PPDU is a PPDU that can be decoded (or interpreted) by the STA. In addition, the meaning of distinguishing the PPDU may mean determining whether the received PPDU is a PPDU supported by the STA. In addition, the meaning of distinguishing the PPDU may also be interpreted to mean what information is transmitted through the received PPDU.

This will be described in more detail with reference to the drawings below.

5 is a diagram illustrating a constellation for distinguishing a format of a PPDU of a wireless communication system to which the present invention can be applied.

FIG. 5A illustrates a constellation of an L-SIG field included in a non-HT format PPDU, and FIG. 5B illustrates a phase rotation for HT mixed format PPDU detection. 5C illustrates phase rotation for VHT format PPDU detection.

Constellation of OFDM symbols transmitted after the L-SIG field and the L-SIG field in order for the STA to classify non-HT format PPDUs, HT-GF format PPDUs, HT mixed format PPDUs, and VHT format PPDUs. Phase is used. That is, the STA may distinguish the PPDU format based on the phase of the constellation of the OFDM symbol transmitted after the L-SIG field and / or the L-SIG field of the received PPDU.

Referring to FIG. 5A, binary phase shift keying (BPSK) is used for an OFDM symbol constituting an L-SIG field.

First, in order to distinguish the HT-GF format PPDU, when the first SIG field is detected in the received PPDU, the STA determines whether it is an L-SIG field. That is, the STA attempts to decode based on the constellation as illustrated in (a) of FIG. 5. If the STA fails to decode, it may be determined that the corresponding PPDU is an HT-GF format PPDU.

Next, in order to classify non-HT format PPDUs, HT mixed format PPDUs, and VHT format PPDUs, the phase of the constellation of OFDM symbols transmitted after the L-SIG field may be used. That is, the modulation method of OFDM symbols transmitted after the L-SIG field may be different, and the STA may distinguish the PPDU format based on the modulation method for the field after the L-SIG field of the received PPDU.

Referring to FIG. 5B, in order to distinguish the HT mixed format PPDU, the phase of two OFDM symbols transmitted after the L-SIG field in the HT mixed format PPDU may be used.

More specifically, the phases of OFDM symbol # 1 and OFDM symbol # 2 corresponding to the HT-SIG field transmitted after the L-SIG field in the HT mixed format PPDU are rotated by 90 degrees in the counterclockwise direction. That is, quadrature binary phase shift keying (QBPSK) is used as a modulation method for OFDM symbol # 1 and OFDM symbol # 2. The QBPSK constellation may be a constellation rotated by 90 degrees in a counterclockwise direction based on the BPSK constellation.

The STA attempts to decode the first OFDM symbol and the second OFDM symbol corresponding to the HT-SIG field transmitted after the L-SIG field of the received PPDU based on the properties as shown in FIG. If the STA succeeds in decoding, it is determined that the corresponding PPDU is an HT format PPDU.

Next, in order to distinguish between the non-HT format PPDU and the VHT format PPDU, the phase of the constellation of the OFDM symbol transmitted after the L-SIG field may be used.

Referring to FIG. 5C, in order to classify the VHT format PPDU, the phase of two OFDM symbols transmitted after the L-SIG field in the VHT format PPDU may be used.

More specifically, the phase of the OFDM symbol # 1 corresponding to the VHT-SIG-A field after the L-SIG field in the VHT format PPDU is not rotated, but the phase of the OFDM symbol # 2 is rotated by 90 degrees counterclockwise. . That is, BPSK is used for the modulation method for OFDM symbol # 1 and QBPSK is used for the modulation method for OFDM symbol # 2.

The STA attempts to decode the first OFDM symbol and the second OFDM symbol corresponding to the VHT-SIG field transmitted after the L-SIG field of the received PPDU based on the properties as shown in the example of FIG. If the STA succeeds in decoding, it may be determined that the corresponding PPDU is a VHT format PPDU.

On the other hand, if decoding fails, the STA may determine that the corresponding PPDU is a non-HT format PPDU.

MAC frame format

6 illustrates a MAC frame format of an IEEE 802.11 system to which the present invention can be applied.

Referring to FIG. 6, a MAC frame (ie, an MPDU) includes a MAC header, a frame body, and a frame check sequence (FCS).

MAC Header includes Frame Control field, Duration / ID field, Address 1 field, Address 2 field, Address 3 field, Sequence control It is defined as an area including a Control field, an Address 4 field, a QoS Control field, and an HT Control field.

The Frame Control field includes information on the MAC frame characteristic. A detailed description of the Frame Control field will be given later.

The Duration / ID field may be implemented to have different values depending on the type and subtype of the corresponding MAC frame.

If the type and subtype of the corresponding MAC frame is a PS-Poll frame for power save (PS) operation, the Duration / ID field is an AID (association identifier) of the STA that transmitted the frame. It may be set to include. Otherwise, the Duration / ID field may be set to have a specific duration value according to the type and subtype of the corresponding MAC frame. In addition, when the frame is an MPDU included in an A-MPDU format, the Duration / ID fields included in the MAC header may be set to have the same value.

The Address 1 to Address 4 fields include a BSSID, a source address (SA), a destination address (DA), a transmission address (TA) indicating a transmission STA address, and a reception address indicating a destination STA address (TA). RA: It is used to indicate Receiving Address.

Meanwhile, the address field implemented as a TA field may be set to a bandwidth signaling TA value, in which case, the TA field may indicate that the corresponding MAC frame contains additional information in the scrambling sequence. The bandwidth signaling TA may be represented by the MAC address of the STA transmitting the corresponding MAC frame, but the Individual / Group bit included in the MAC address may be set to a specific value (for example, '1'). Can be.

The Sequence Control field is set to include a sequence number and a fragment number. The sequence number may indicate a sequence number allocated to the corresponding MAC frame. The fragment number may indicate the number of each fragment of the corresponding MAC frame.

The QoS Control field contains information related to QoS. The QoS Control field may be included when indicating a QoS data frame in a subtype subfield.

The HT Control field includes control information related to the HT and / or VHT transmission / reception schemes. The HT Control field is included in the Control Wrapper frame. In addition, it exists in the QoS data frame and the management frame in which the order subfield value is 1.

The frame body is defined as a MAC payload, and data to be transmitted in a higher layer is located, and has a variable size. For example, the maximum MPDU size may be 11454 octets, and the maximum PPDU size may be 5.484 ms.

FCS is defined as a MAC footer and is used for error detection of MAC frames.

The first three fields (Frame Control field, Duration / ID field and Address 1 field) and the last field (FCS field) constitute the minimum frame format and are present in every frame. Other fields may exist only in a specific frame type.

7 illustrates the HT format of the HT Control field in a wireless communication system to which the present invention can be applied.

Referring to FIG. 7, the HT Control field includes a VHT subfield, an HT Control Middle subfield, an AC Constraint subfield, and a Reverse Direction Grant (RDG) / More PPDU (More PPDU). It may consist of subfields.

The VHT subfield indicates whether the HT Control field has the format of the HT Control field for the VHT (VHT = 1) or has the format of the HT Control field for the HT (VHT = 0). In FIG. 7, it is assumed that the HT Control field (that is, VHT = 0) for HT.

The HT Control Middle subfield may be implemented to have a different format according to the indication of the VHT subfield. A more detailed description of the HT Control Middle subfield will be given later.

The AC Constraint subfield indicates whether a mapped AC (Access Category) of a reverse direction (RD) data frame is limited to a single AC.

The RDG / More PPDU subfield may be interpreted differently depending on whether the corresponding field is transmitted by the RD initiator or the RD responder.

When transmitted by the RD initiator, the RDG / More PPDU field is set to '1' if the RDG exists, and set to '0' if the RDG does not exist. When transmitted by the RD responder, it is set to '1' if the PPDU including the corresponding subfield is the last frame transmitted by the RD responder, and set to '0' when another PPDU is transmitted.

The HT Control Middle subfield of the HT Control field for the HT includes a link adaptation subfield, a calibration position subfield, a calibration sequence subfield, a reserved subfield, and channel state information. And / or (CSI / Steering: Channel State Information / Steering) subfield, HT NDP Announcement (HT NDP Announcement) subfield, and Reserved subfield.

The Link Adaptation subfield is a training request (TRQ) subfield, an MCS request or antenna selection indication (MAI: MCS (Modulation and Coding Scheme) Request or ASEL (Antenna Selection) Indication) subfield, and an MCS feedback sequence indication (MFSI). MCS Feedback and Antenna Selection Command / data (MFB / ASELC) subfields.

The TRQ subfield is set to 1 when the responder requests sounding PPDU transmission and is set to 0 when the responder does not request sounding PPDU transmission.

If the MAI subfield is set to 14, this indicates an ASEL indication, and the MFB / ASELC subfield is interpreted as an antenna selection command / data. Otherwise, the MAI subfield indicates an MCS request and the MFB / ASELC subfield is interpreted as MCS feedback.

When the MAI subfield indicates an MCS Request (MRQ: MCS Request), it is interpreted that the MAI subfield is composed of an MRQ (MCS request) and an MSI (MRQ sequence identifier). The MRQ subfield is set to '1' if MCS feedback is requested and set to '0' if MCS feedback is not requested. When the MRQ subfield is '1', the MSI subfield includes a sequence number for specifying an MCS feedback request. When the MRQ subfield is '0', the MSI subfield is set to a reserved bit.

Each of the above-described subfields corresponds to an example of subfields that may be included in the HT control field, and may be replaced with another subfield or may further include additional subfields.

8 illustrates the VHT format of the HT Control field in a wireless communication system to which the present invention can be applied.

Referring to FIG. 8, the HT Control field includes a VHT subfield, an HT Control Middle subfield, an AC Constraint subfield, and a Reverse Direction Grant (RDG) / More PPDU (More PPDU). It may consist of subfields.

In FIG. 8, it is assumed that the HT Control field (that is, VHT = 1) for VHT. The HT Control field for the VHT may be referred to as a VHT Control field.

Since the description of the AC Constraint subfield and the RDG / More PPDU subfield is the same as the description of FIG. 7, the description thereof is omitted.

As described above, the HT Control Middle subfield may be implemented to have a different format according to the indication of the VHT subfield.

The HT Control Middle subfield of the HT Control field for VHT includes a reserved bit, a Modulation and Coding Scheme feedback request (MRQ) subfield, and an MRQ Sequence Identifier (MSI). Space-time block coding (STBC) subfield, MCS feedback sequence identifier (MFSI) / Least Significant Bit (LSB) of Group ID (LSB) subfield, MCS Feedback (MFB) Subfield, Group ID Most Significant Bit (MSB) of Group ID (MSB) Subfield, Coding Type Subfield, Feedback Transmission Type (FB Tx Type: Feedback transmission type) subfield and a voluntary MFB (Unsolicited MFB) subfield.

Table 3 shows a description of each subfield included in the HT Control Middle subfield of the VHT format.

In addition, the MFB subfield may include a VHT number of space time streams (NUM_STS) subfield, a VHT-MCS subfield, a bandwidth (BW) subfield, and a signal to noise ratio (SNR). It may include subfields.

The NUM_STS subfield indicates the number of recommended spatial streams. The VHT-MCS subfield indicates a recommended MCS. The BW subfield indicates bandwidth information related to the recommended MCS. The SNR subfield indicates the average SNR value on the data subcarrier and spatial stream.

Information included in each field described above may follow the definition of the IEEE 802.11 system. In addition, each field described above corresponds to an example of fields that may be included in the MAC frame, but is not limited thereto. That is, each field described above may be replaced with another field or additional fields may be further included, and all fields may not be necessarily included.

link set up  Procedure (Link Setup Procedure)

FIG. 9 is a diagram illustrating a general link setup procedure in a wireless communication system to which the present invention can be applied.

In order for an STA to set up a link and transmit / receive data with respect to a network, a STA must first undergo a scanning procedure, an authentication procedure, an association procedure, and the like for discovering the network. The link setup procedure may also be referred to as session initiation procedure and session setup procedure. In addition, the linking procedure may be collectively referred to as the scanning, authentication, and association procedure of the link setup procedure.

In the WLAN, a scanning procedure includes a passive scanning procedure and an active scanning procedure.

FIG. 9 (a) illustrates a link setup procedure according to passive scanning, and FIG. 9 (b) illustrates a link setup procedure according to active scanning.

As shown in FIG. 9A, the passive scanning procedure is performed through a beacon frame broadcasted periodically by the AP. A beacon frame is one of management frames in IEEE 802.11, which informs the existence of a wireless network and periodically (eg, allows a non-AP STA that performs scanning to find a wireless network and participate in the wireless network). , 100msec intervals). The beacon frame contains information about the current network (for example, information about the BSS).

In order to obtain information about the network, the non-AP STA passively moves channels and waits for reception of a beacon frame. The non-AP STA that receives the beacon frame may store information about a network included in the received beacon frame, move to the next channel, and perform scanning on the next channel in the same manner. The non-AP STA receives the beacon frame to obtain information about the network, thereby completing the scanning procedure on the corresponding channel.

As described above, the passive scanning procedure has the advantage that the overall overhead is small since the procedure is completed only when the non-AP STA receives the beacon frame without having to transmit another frame. However, there is a disadvantage in that the scanning execution time of the non-AP STA increases in proportion to the transmission period of the beacon frame.

On the other hand, the active scanning procedure as shown in Figure 9 (b) by the non-AP STA to broadcast the probe request frame (probe request frame) by actively moving the channel to discover what AP exists in the vicinity, Request network information from the AP.

In response to receiving the probe request frame, the responder waits for a random time in order to prevent frame collision, and transmits network information in a probe response frame to the corresponding non-AP STA. Upon receiving the probe response frame, the STA may store network related information included in the received probe response frame and move to the next channel to perform scanning in the same manner. The scanning procedure is completed by the non-AP STA receiving the probe response frame to obtain network information.

The active scanning procedure has an advantage that scanning can be completed in a relatively quick time compared to the passive scanning procedure. However, since an additional frame sequence is required, the overall network overhead is increased.

After completing the scanning procedure, the non-AP STA selects a network according to its own criteria and performs an authentication procedure with the corresponding AP.

The authentication procedure is a process in which a non-AP STA transmits an authentication request frame to the AP, and in response, the AP transmits an authentication response frame to the non-AP STA, that is, 2-way. This is done by handshaking.

An authentication frame used for authentication request / response corresponds to a management frame.

The authentication frame includes an authentication algorithm number, an authentication transaction sequence number, a status code, a challenge text, a Robust Security Network, and a finite cyclic group. Group) and the like. This corresponds to some examples of information that may be included in the authentication request / response frame, and may be replaced with other information or further include additional information.

The non-AP STA may transmit an authentication request frame to the AP. The AP may determine whether to allow authentication for the non-AP STA based on the information included in the received authentication request frame. The AP may provide a result of the authentication process to the non-AP STA through an authentication response frame.

Through the authentication procedure, the non-AP STA and the AP authenticate each other and then establish an association.

The association process is a process in which a non-AP STA transmits an association request frame to an AP, and in response, the AP transmits an association response frame to a non-AP STA, that is, 2-way. This is done by handshaking.

The association request frame includes information related to various capabilities of the non-AP STA, beacon listening interval, service set identifier (SSID), supported rates, supported channels, RSN, and mobility. It may include information on domain, supported operating classes, TIM Broadcast Indication Map Broadcast request, interworking service capability, and the like.

Based on this, the AP determines whether support for the corresponding non-AP STA is possible. After the determination, the AP transmits information on whether to accept the association request, the reason for the association request, and capability information that can be supported in the association response frame to the non-AP STA.

Association response frames include information related to various capabilities, status codes, association IDs (AIDs), support rates, Enhanced Distributed Channel Access (EDCA) parameter sets, Received Channel Power Indicators (RCPI), Received Signal to Noise Indicators (RSNI), mobility Information such as a domain, a timeout interval (association comeback time), an overlapping BSS scan parameter, a TIM broadcast response, and a Quality of Service (QoS) map may be included.

The information that may be included in the aforementioned association request / response frame corresponds to an example, may be replaced with other information, or may further include additional information.

If the non-AP STA successfully establishes an association with the AP, normal transmission / reception is performed. On the other hand, if the association is not successfully established with the AP, based on the reason, the non-AP STA may attempt to reassociate or attempt to associate with another AP.

Media access mechanism

In IEEE 802.11, communication is fundamentally different from the wired channel environment because the communication takes place over a shared wireless medium.

In a wired channel environment, communication is possible based on carrier sense multiple access / collision detection (CSMA / CD). For example, once a signal is transmitted from the transmitter, the channel environment does not change so much that the receiver does not experience significant signal attenuation. At this time, if two or more signals collided, detection was possible. This is because the power sensed by the receiver is instantaneously greater than the power transmitted by the transmitter. However, in a wireless channel environment, a variety of factors (e.g., large attenuation of the signal depending on distance, or instantaneous deep fading) can affect the channel so that the signal actually transmits properly at the receiving end. Whether this has occurred or a collision has occurred, the transmitter cannot accurately perform carrier sensing.

Accordingly, in a WLAN system according to IEEE 802.11, a carrier sense multiple access with collision avoidance (CSMA / CA) mechanism is introduced as a basic access mechanism of a MAC. The CAMA / CA mechanism is also called the Distributed Coordination Function (DCF) of the IEEE 802.11 MAC. It basically employs a “listen before talk” access mechanism. According to this type of access mechanism, the AP and / or STA may sense a radio channel or medium during a predetermined time interval (eg, DCF Inter-Frame Space (DIFS)) prior to starting transmission. Perform Clear Channel Assessment (CCA) sensing. As a result of sensing, if it is determined that the medium is in an idle state, the frame transmission is started through the medium. On the other hand, if the medium is detected to be occupied status, the AP and / or STA does not start its own transmission and assumes that several STAs are already waiting to use the medium. The frame transmission may be attempted after waiting longer for a delay time (eg, a random backoff period) for access.

By applying a random backoff period, assuming that there are several STAs for transmitting a frame, the STAs are expected to have different backoff period values, so that they will wait for different times before attempting frame transmission. This can minimize collisions.

In addition, the IEEE 802.11 MAC protocol provides a hybrid coordination function (HCF). HCF is based on the DCF and Point Coordination Function (PCF). The PCF refers to a polling-based synchronous access scheme in which polling is performed periodically so that all receiving APs and / or STAs can receive data frames. In addition, the HCF has an Enhanced Distributed Channel Access (EDCA) and an HCF Controlled Channel Access (HCCA). EDCA is a competition-based approach for providers to provide data frames to a large number of users, and HCCA is a non-competition-based channel access scheme using a polling mechanism. In addition, the HCF includes a media access mechanism for improving the quality of service (QoS) of the WLAN, and can transmit QoS data in both a contention period (CP) and a contention free period (CFP).

FIG. 10 is a diagram illustrating an arbitrary backoff period and a frame transmission procedure in a wireless communication system to which the present invention can be applied.

When a certain medium changes from occupy or busy to idle, several STAs may attempt to transmit data (or frames). At this time, as a method for minimizing the collision, STAs may select a random backoff count and wait for a slot time corresponding thereto to attempt transmission. The random backoff count has a pseudo-random integer value and may be determined as one of values uniformly distributed in the range of 0 to a contention window (CW). Where CW is a contention window parameter value. The CW parameter is given CW_min as an initial value, but may take a double value when transmission fails (eg, when an ACK for a transmitted frame is not received). If the CW parameter value is CW_max, data transmission can be attempted while maintaining the CW_max value until the data transmission is successful. If the CW parameter value is successful, the CW parameter value is reset to the CW_min value. The CW, CW_min and CW_max values are preferably set to (2 ^ n) -1 (n = 0, 1, 2, ...).

When the random backoff process begins, the STA counts down the backoff slot according to the determined backoff count value and continuously monitors the medium during the countdown. If the media is monitored as occupied, the countdown stops and waits, and when the media is idle the countdown resumes.

In the example of FIG. 10, when a packet to be transmitted to the MAC of the STA 3 arrives, the STA 3 may confirm that the medium is idle as much as DIFS and transmit the frame immediately.

Meanwhile, the remaining STAs monitor and wait for the medium to be busy. In the meantime, data may be transmitted in each of STA 1, STA 2, and STA 5, and each STA waits for DIFS when the medium is monitored in an idle state, and then backoff slots according to a random backoff count value selected by each STA. Counts down.

In the example of FIG. 10, STA 2 selects the smallest backoff count value and STA 1 selects the largest backoff count value. That is, at the time when STA 2 finishes the backoff count and starts frame transmission, the remaining backoff time of STA 5 is shorter than the remaining backoff time of STA 1.

STA 1 and STA 5 stop counting and wait while STA 2 occupies the medium. When the media occupancy of the STA 2 ends and the medium becomes idle again, the STA 1 and the STA 5 resume the stopped backoff count after waiting for DIFS. That is, the frame transmission can be started after counting down the remaining backoff slots by the remaining backoff time. Since the remaining backoff time of STA 5 is shorter than that of STA 1, frame transmission of STA 5 is started.

Meanwhile, while STA 2 occupies the medium, data to be transmitted may also occur in STA 4. At this time, when the medium is in the idle state, the STA 4 waits for DIFS and then counts down the backoff slot according to the random backoff count value selected by the STA.

In the example of FIG. 10, the remaining backoff time of STA 5 coincides with an arbitrary backoff count value of STA 4, and in this case, a collision may occur between STA 4 and STA 5. If a collision occurs, neither STA 4 nor STA 5 receive an ACK, and thus data transmission fails. In this case, STA4 and STA5 select a random backoff count value after doubling the CW value and perform countdown of the backoff slot.

Meanwhile, the STA 1 may wait while the medium is occupied due to the transmission of the STA 4 and the STA 5, wait for DIFS when the medium is idle, and then start frame transmission after the remaining backoff time passes.

The CSMA / CA mechanism also includes virtual carrier sensing in addition to physical carrier sensing in which the AP and / or STA directly sense the medium.

Virtual carrier sensing is intended to compensate for problems that may occur in media access, such as a hidden node problem. For virtual carrier sensing, the MAC of the WLAN system uses a Network Allocation Vector (NAV). The NAV is a value that indicates to the other AP and / or STA how long the AP and / or STA currently using or authorized to use the medium remain until the medium becomes available. Therefore, the value set to NAV corresponds to a period in which the medium is scheduled to be used by the AP and / or STA transmitting the frame, and the STA receiving the NAV value is prohibited from accessing the medium during the period. For example, the NAV may be set according to a value of a duration field of the MAC header of the frame.

The AP and / or STA may perform a procedure of exchanging a request to send (RTS) frame and a clear to send (CTS) frame to indicate that the AP and / or STA want to access the medium. The RTS frame and the CTS frame include information indicating a time interval in which a wireless medium required for transmission and reception of an ACK frame is reserved when substantial data frame transmission and acknowledgment (ACK) are supported. The other STA that receives the RTS frame transmitted from the AP and / or the STA to which the frame is to be transmitted or receives the CTS frame transmitted from the STA to which the frame is to be transmitted during the time period indicated by the information included in the RTS / CTS frame Can be set to not access the medium. This may be implemented by setting the NAV during the time interval.

Method for Uplink Multi-user Transmission

New frames for next-generation WLAN systems, 802.11ax systems, with increasing attention from vendors in various fields for next-generation WiFi and increased demand for high throughput and quality of experience (QoE) after 802.11ac. There is an active discussion of format and numerology.

IEEE 802.11ax is a next-generation WLAN system that supports higher data rates and handles higher user loads. One of the recently proposed WLAN systems is known as high efficiency WLAN (HEW: High). Called Efficiency WLAN).

The IEEE 802.11ax WLAN system may operate in the 2.4 GHz frequency band and the 5 GHz frequency band like the existing WLAN system. It can also operate at higher 60 GHz frequency bands.

In IEEE 802.11ax system, the existing IEEE 802.11 OFDM system (IEEE 802.11a, 802.11n) is used for outdoor throughput transmission for average throughput enhancement and inter-symbol interference in outdoor environment. , 4x larger FFT size for each bandwidth than 802.11ac. This will be described with reference to the drawings below.

Hereinafter, in the description of the HE format PPDU in the present invention, the description of the non-HT format PPDU, the HT-mixed format PPDU, the HT-greenfield format PPDU, and / or the VHT format PPDU described above will be described in HE format unless otherwise noted. May be incorporated into the description of the PPDU.

FIG. 11 is a diagram for explaining a hidden node and an exposed node in a wireless communication system to which the present invention can be applied.

11A illustrates an example of a hidden node, in which STA A and STA B are in communication and STA C has information to transmit. In more detail, although STA A is transmitting information to STA B, it may be determined that the medium is idle when STA C performs carrier sensing before sending data to STA B. This is because transmission of STA A (ie, media occupation) may not be sensed at the location of STA C. In this case, since STA B receives the information of STA A and STA C at the same time, a collision occurs. At this time, STA A may be referred to as a hidden node of STA C.

FIG. 11B is an example of an exposed node, and STA B is a case in which STA C has information to be transmitted from STA D in a situation in which data is transmitted to STA A. FIG. In this case, when STA C performs carrier sensing, it may be determined that the medium is occupied by the transmission of STA B. Accordingly, since STA C is sensed as a medium occupancy state even if there is information to be transmitted to STA D, it must wait until the medium becomes idle. However, since STA A is actually outside the transmission range of STA C, transmission from STA C and transmission from STA B may not collide with STA A's point of view, so STA C is unnecessary until STA B stops transmitting. To wait. At this time, STA C may be referred to as an exposed node of STA B.

12 is a view for explaining the RTS and CTS in a wireless communication system to which the present invention can be applied.

In order to efficiently use a collision avoidance mechanism in the exemplary situation as shown in FIG. 11, short signaling packets such as request to send (RTS) and clear to send (CTS) may be used. . The RTS / CTS between the two STAs may allow the surrounding STA (s) to overhear, allowing the surrounding STA (s) to consider whether to transmit information between the two STAs.

The RTS frame and the CTS frame include information indicating a time interval in which a wireless medium required for transmission and reception of an ACK frame is reserved when substantial data frame transmission and acknowledgment (ACK) are supported. The other STA that receives the RTS frame transmitted from the AP and / or the STA to which the frame is to be transmitted or receives the CTS frame transmitted from the STA to which the frame is to be transmitted during the time period indicated by the information included in the RTS / CTS frame Can be set to not access the medium. This may be implemented by setting the NAV during the time interval.

12A illustrates an example of a method of solving a hidden node problem, and assumes that both STA A and STA C try to transmit data to STA B. FIG. When STA A sends the RTS to STA B, STA B transmits the CTS to both STA A and STA C around it. As a result, STA C waits until data transmission between STA A and STA B is completed, thereby avoiding collision.

12 (b) is an example of a method of solving an exposed node problem, and STA C overhears RTS / CTS transmission between STA A and STA B, so that STA C is a different STA (eg, STA). It may be determined that no collision will occur even if data is transmitted to D). That is, STA B transmits the RTS to all the surrounding terminals, and only STA A having the data to actually transmit the CTS. Since STA C receives only RTS and not STA A's CTS, it can be seen that STA A is out of STC C's carrier sensing.

13 to 15 are diagrams for explaining in detail the operation of the STA receiving the TIM in a wireless communication system to which the present invention can be applied.

Referring to FIG. 13, the STA may switch from the sleep state to the awake state to receive a beacon frame including the TIM from the AP, interpret the received TIM element, and know that there is buffered traffic to be transmitted to the AP. . After contending with other STAs for medium access for PS-Poll frame transmission, the STA may transmit a PS-Poll frame to request an AP to transmit a data frame. After receiving the PS-Poll frame transmitted by the STA, the AP may transmit the frame to the STA. The STA may receive a data frame and transmit an acknowledgment (ACK) frame thereto to the AP. The STA may then go back to sleep.

As shown in FIG. 13, the AP operates according to an immediate response method after transmitting a data frame after a predetermined time (for example, short inter-frame space (SIFS)) after receiving a PS-Poll frame from the STA. Can be. Meanwhile, when the AP fails to prepare a data frame to be transmitted to the STA during the SIFS time after receiving the PS-Poll frame, the AP may operate according to a deferred response method, which will be described with reference to FIG. 14.

In the example of FIG. 14, the STA transitions from the sleep state to the awake state to receive the TIM from the AP and transmits the PS-Poll frame to the AP through contention as in the example of FIG. 13. If the AP does not prepare a data frame during SIFS even after receiving the PS-Poll frame, the AP may transmit an ACK frame to the STA instead of transmitting the data frame. When the data frame is prepared after transmitting the ACK frame, the AP may transmit the data frame to the STA after performing contending. The STA may transmit an ACK frame indicating that the data frame was successfully received to the AP and go to sleep.

15 illustrates an example in which the AP transmits a DTIM. STAs may transition from a sleep state to an awake state to receive a beacon frame containing a DTIM element from the AP. STAs may know that a multicast / broadcast frame will be transmitted through the received DTIM. The AP may transmit data (ie, multicast / broadcast frame) immediately after the beacon frame including the DTIM without transmitting and receiving the PS-Poll frame. The STAs may receive data while continuously awake after receiving the beacon frame including the DTIM, and may switch back to the sleep state after the data reception is completed.

M2M (Machine-to-Machine) communication technology is drawing attention as a next generation communication technology. In IEEE 802.11 WLAN system, a technical standard for supporting M2M communication is being developed as IEEE 802.11ah. M2M communication refers to a communication method that includes one or more machines (Machine), may also be referred to as MTC (Machine Type Communication) or thing communication. Here, a machine refers to an entity that does not require human direct manipulation or intervention. For example, a device such as a meter or a vending machine equipped with a wireless communication module, as well as a user device such as a smartphone that can automatically connect to a network and perform communication without a user's operation / intervention, can be used. This may correspond to an example. The M2M communication may include communication between devices (eg, device-to-device (D2D) communication), communication between a device, and an application server. Examples of device and server communication include communication between vending machines and servers, point of sale devices and servers, and electricity, gas or water meter readers and servers. In addition, applications based on M2M communication may include security, transportation, health care, and the like. Considering the nature of these applications, M2M communication should generally be able to support the transmission and reception of small amounts of data at low speeds in the presence of very many devices.

Specifically, M2M communication should be able to support a large number of STAs. In the currently defined WLAN system, it is assumed that a maximum of 2007 STAs are linked to one AP. However, in M2M communication, methods for supporting a case where a larger number (approximately 6000 STAs) are linked to one AP are provided. Is being discussed. In addition, many applications are expected to support / require low data rates in M2M communication. In order to support this smoothly, for example, in a WLAN system, an STA may recognize whether data to be transmitted to it is based on a TIM (Traffic Indication Map) element, and methods for reducing the bitmap size of the TIM are discussed. It is becoming. In addition, M2M communication is expected to be a lot of traffic with a very long transmission / reception interval. For example, very small amounts of data are required to be sent and received every long period (eg, one month), such as electricity / gas / water use. Accordingly, in the WLAN system, even if the number of STAs that can be associated with one AP becomes very large, it is possible to efficiently support the case where the number of STAs having data frames to be received from the AP during one beacon period is very small. The ways to do this are discussed.

As such, WLAN technology is rapidly evolving and, in addition to the above examples, technologies for direct link setup, media streaming performance improvement, support for high speed and / or large initial session setup, support for extended bandwidth and operating frequency, etc. Is being developed.

In the method of operating a power saving mode based on the TIM (or DTIM) protocol described above with reference to FIGS. 13 to 15, STAs have a data frame to be transmitted for themselves through STA identification information included in the TIM element. You can check. Here, as an example of the STA identification information, an STA may be an association identifier (AID), which is an identifier assigned when the STA is associated with the AP.

The AID is used as a unique identifier for each STA within one BSS. In one example, in the current WLAN system, the AID may be assigned to one of values from 1 to 2007. In the currently defined WLAN system, 14 bits may be allocated for an AID in a frame transmitted by an AP and / or STA, and an AID value may be allocated up to 16383, but in 2008, 16383 is set as a reserved value. have.

The TIM element according to the existing definition is not suitable for the application of M2M application, where a large number of (eg, more than 2007) STAs may be associated with one AP. Extending the existing TIM structure as it is, the TIM bitmap size is so large that it cannot be supported by the existing frame format, and is not suitable for M2M communication considering low transmission rate applications. In addition, in M2M communication, it is expected that the number of STAs in which a received data frame exists during one beacon period is very small. Therefore, considering the application example of the M2M communication as described above, since the size of the TIM bitmap is expected to be large, but most bits have a value of 0, a technique for efficiently compressing the bitmap is required.

As a conventional bitmap compression technique, there is a method of defining an offset (or starting point) value by omitting consecutive zeros in front of a bitmap. However, if the number of STAs in which a buffered frame exists is small but the AID value of each STA is large, the compression efficiency is not high. For example, when only frames to be transmitted to only two STAs having AIDs of 10 and 2000 are buffered, the compressed bitmap has a length of 1990 but all have a value of 0 except at both ends. If the number of STAs that can be associated with one AP is small, the inefficiency of bitmap compression is not a big problem, but if the number of STAs increases, such inefficiency may be a factor that hinders overall system performance. . As a solution to this problem, the AID may be divided into groups to perform more efficient data transmission. Each group is assigned a designated group ID (GID). AIDs allocated on a group basis will be described with reference to FIG. 16.

FIG. 16 is a diagram for explaining a group-based AID in a wireless communication system to which the present invention can be applied.

FIG. 16A illustrates an example of an AID allocated on a group basis. In the example of FIG. 16A, the first few bits of the AID bitmap may be used to indicate a GID. For example, the first two bits of the AID bitmap may be used to represent four GIDs. In the case where the total length of the AID bitmap is N bits, the first two bits (B1 and B2) indicate the GID of the corresponding AID.

FIG. 16B illustrates another example of an AID allocated on a group basis. In the example of FIG. 16B, the GID may be allocated according to the location of the AID. In this case, AIDs using the same GID may be represented by an offset and a length value. For example, if GID 1 is represented by an offset A and a length B, it means that AIDs A through A + B-1 on the bitmap have GID 1. For example, in the example of FIG. 17 (b), it is assumed that all 1 to N4 AIDs are divided into four groups. In this case, AIDs belonging to GID 1 are 1 to N1, and AIDs belonging to this group may be represented by offset 1 and length N1. Next, AIDs belonging to GID 2 may be represented by offset N1 + 1 and length N2-N1 + 1, AIDs belonging to GID 3 may be represented by offset N2 + 1 and length N3-N2 + 1, and GID AIDs belonging to 4 may be represented by an offset N3 + 1 and a length N4-N3 + 1.

When the AID allocated based on such a group is introduced, by allowing the channel access to different time intervals according to the GID, the TIM element shortage problem for a large number of STAs can be solved, and an efficient data transmission and reception can be performed. have. For example, channel access may be allowed only to STA (s) corresponding to a specific group during a specific time interval, and channel access may be restricted to other STA (s). As such, a predetermined time period in which only specific STA (s) are allowed to access may be referred to as a restricted access window (RAW).

Channel access based on the GID will be described with reference to FIG. 17 (c) illustrates a channel access mechanism according to a beacon interval when the AID is divided into three groups. The first beacon interval (or the first RAW) is a period in which channel access of an STA corresponding to an AID belonging to GID 1 is allowed, and channel access of STAs belonging to another GID is not allowed.

To implement this, the first beacon includes a TIM element only for AIDs corresponding to GID 1. The second beacon frame includes a TIM element only for AIDs having GID 2, so that only the channel access of the STA corresponding to the AID belonging to GID 2 is allowed during the second beacon interval (or second RAW). The third beacon frame includes a TIM element only for AIDs having GID 3, and thus only channel access of the STA corresponding to the AID belonging to GID 3 is allowed during the third beacon interval (or third RAW). The fourth beacon frame again includes a TIM element for only AIDs having GID 1, and thus only channel access of the STA corresponding to the AID belonging to GID 1 is allowed during the fourth beacon interval (or fourth RAW). Then, even in each of the fifth and subsequent beacon intervals (or fifth and subsequent RAWs), only channel access of the STA belonging to the specific group indicated in the TIM included in the beacon frame may be allowed.

In FIG. 16C, the order of GIDs allowed according to beacon intervals is cyclic or periodic, but the present invention is not limited thereto.

By including only the AID (s) belonging to a particular GID (s) in the TIM element (hereinafter referred to as " separated TIM operation ") as shown in FIG. 16 (d), a specific time interval (e.g., During a specific RAW) may operate in a manner that allows channel access of only the STA (s) corresponding to the specific AID (s) and does not allow channel access of the remaining STA (s). In other words, the information indicating whether the AP buffers data to STAs of the access group by a specific TIM may be limited to the access group by the TIM. To this end, the AP may transmit a corresponding instruction to the terminal so that only the access group can access the channel.

The group-based AID allocation scheme as described above may also be referred to as a hierarchical structure of the TIM. That is, the entire AID space may be divided into a plurality of blocks, and only channel access of STA (s) (that is, STAs of a specific group) corresponding to a specific block having a non-zero value may be allowed. Accordingly, the TIM can be divided into small blocks / groups so that the STAs can easily maintain the TIM information and manage the blocks / groups according to the class, quality of service (QoS), or purpose of the STA.

In the example of FIG. 16, a two-level hierarchy is illustrated, but a TIM having a hierarchical structure may be configured in the form of two or more levels. For example, the entire AID space may be divided into a plurality of page groups, each page group may be divided into a plurality of blocks, and each block may be divided into a plurality of sub-blocks. In this case, as an extension of the example of Fig. 16 (a), in the AID bitmap, the first N1 bits represent a page ID (i.e., PID), the next N2 bits represent a block ID, and the next N3 bits. Indicates a sub-block ID and may be configured in such a way that the remaining bits indicate the STA bit position within the sub-block.

On the other hand, although not shown in Figure 16, the STA is a general beacon (for example, DTIM for transmitting information about the TIM elements (for example, TIM for GID 1, 2, 3) divided for each group described above in a long cycle Beacons, long beacons). For example, information on the TIM elements classified for each group from the beacons transmitted in a long period while the STA performs the association process with the AP (for example, the transmission period / length of the TIM elements classified for each group) , Slot time, etc. in each group access period), and a corresponding TIM element may be received by switching to an awake state in a period in which the TIM element of the group to which the corresponding STA belongs is transmitted. The TIM element divided by each group may be referred to as a TIM segment.

In the examples of the present invention described below, various methods of dividing and managing STAs (or AIDs assigned to each STA) into predetermined hierarchical group units may be applied. It is not limited to the above examples.

17 illustrates a High Efficiency (HE) format PPDU according to an embodiment of the present invention.

Referring to FIG. 17, an HE format PPDU for HEW may be largely composed of a legacy part (L-part) and an HE part (HE-part).

The L-part is composed of an L-STF field, an L-LTF field, and an L-SIG field in the same manner as the conventional WLAN system maintains. The L-STF field, L-LTF field, and L-SIG field may be referred to as a legacy preamble.

The HE-part is a part newly defined for the 802.11ax standard, and may include a HE-SIG field, a HE preamble, and a HE-data field. The HE-preamble may include a HE-STF field and a HE-LTF field. In addition, not only the HE-STF field and the HE-LTF field but also the HE-SIG field may be collectively referred to as HE-preamble.

In FIG. 17, the order of the HE-SIG field, the HE-STF field, and the HE-LTF field is illustrated, but may be configured in a different order.

The L-part, the HE-SIG field, and the HE-preamble may be collectively referred to as a physical preamble (PHY).

The HE-SIG field may include information (eg, OFDMA, UL MU MIMO, enhanced MCS, etc.) for decoding the HE-data field.

L-part and HE-part (particularly, HE-preamble and HE-data) may have different fast fourier transform (FFT) sizes, and may use different cyclic prefixes (CP). That is, the L-part and the HE-part (particularly, the HE-preamble and the HE-data) may have different subcarrier frequency spacings.

The 802.11ax system can use four times larger (4x) FFT size than legacy WLAN systems. That is, the L-part may be configured with a 1x symbol structure, and the HE-part (particularly, HE-preamble and HE-data) may be configured with a 4x symbol structure. Here, 1x, 2x, 4x size FFT refers to the size relative to the legacy WLAN system (eg, IEEE 802.11a, 802.11n, 802.11ac, etc.).

For example, if the FFT size used for the L-part is 64, 128, 256, and 512 at 20 MHz, 40 MHz, 80 MHz, and 160 MHz, respectively, the FFT size used for the HE-part is 256 at 20 MHz, 40 MHz, 80 MHz, and 160 MHz, respectively. , 512, 1024, 2048.

As the FFT size is larger than that of the legacy WLAN system, the number of subcarriers per unit frequency is increased because the subcarrier frequency spacing is smaller, but the OFDM symbol length is longer.

That is, the use of a larger FFT size means that the subcarrier spacing becomes narrower, and similarly, an Inverse Discrete Fourier Transform (IDFT) / Discrete Fourier Transform (DFT) period is increased. Here, the IDFT / DFT period may mean a symbol length excluding the guard period (GI) in the OFDM symbol.

Therefore, if the HE-part (particularly HE-preamble and HE-data) is used with an FFT size four times larger than the L-part, the subcarrier spacing of the HE-part is 1/4 of the subcarrier spacing of the L-part. The ID-FT / DFT period of the HE-part is four times the IDFT / DFT period of the L-part. For example, if the subcarrier spacing of L-part is 312.5kHz (= 20MHz / 64, 40MHZ / 128, 80MHz / 256 and / or 160MHz / 512), the subcarrier spacing of HE-part is 78.125kHz (= 20MHz / 256 , 40MHZ / 512, 80MHz / 1024 and / or 160MHz / 2048). Also, if the IDFT / DFT period of the L-part is 3.2 ms (= 1 / 312.5 kHz), the IDFT / DFT period of the HE-part may be 12.8 ms (= 1 / 78.125 kHz).

Here, the GI can be one of 0.8 ㎲, 1.6 ㎲, 3.2 ㎲, so the OFDM symbol length (or symbol interval) of the HE-part including the GI is 13.6 ㎲, 14.4 ㎲, 16 according to the GI. It can be

Although FIG. 17 illustrates a case in which the HE-SIG field has a 1x symbol structure, the HE-SIG field may also have a 4x symbol structure like HE-preamble and HE-data.

Unlike the example of FIG. 17, the HE-SIG may be divided into an HE-SIG A field and an HE-SIG B field. In this case, the FFT size per unit frequency may be larger after HE-SIG B. That is, after the HE-SIG B, the OFDM symbol length may be longer than the L-part.

The HE format PPDU for the WLAN system to which the present invention can be applied may be transmitted through at least one 20 MHz channel. For example, the HE format PPDU may be transmitted in a 40 MHz, 80 MHz, or 160 MHz frequency band through a total of four 20 MHz channels. This will be described in more detail with reference to the drawings below.

18 is a diagram illustrating an HE format PPDU according to an embodiment of the present invention.

FIG. 18 illustrates a PPDU format when 80 MHz is allocated to one STA (or OFDMA resource units are allocated to a plurality of STAs within 80 MHz) or when different streams of 80 MHz are allocated to a plurality of STAs.

Referring to FIG. 18, L-STF, L-LTF, and L-SIG may be transmitted as OFDM symbols generated based on 64 FFT points (or 64 subcarriers) in each 20MHz channel.

The HE-SIG A field may include common control information transmitted in common to STAs receiving a PPDU. The HE-SIG A field may be transmitted in one to three OFDM symbols. The HE-SIG A field is copied in units of 20 MHz and includes the same information. In addition, the HE-SIG-A field informs the total bandwidth information of the system.

Table 4 is a table illustrating information included in the HE-SIG A field.

Information included in each field illustrated in Table 4 may follow the definition of the IEEE 802.11 system. In addition, each field described above corresponds to an example of fields that may be included in the PPDU, but is not limited thereto. That is, each field described above may be replaced with another field or additional fields may be further included, and all fields may not be necessarily included.

HE-STF is used to improve the performance of AGC estimation in MIMO transmission.

The HE-SIG B field may include user-specific information required for each STA to receive its own data (eg, PSDU). The HE-SIG B field may be transmitted in one or two OFDM symbols. For example, the HE-SIG B field may include information on the modulation and coding scheme (MCS) of the corresponding PSDU and the length of the corresponding PSDU.

The L-STF, L-LTF, L-SIG, and HE-SIG A fields may be repeatedly transmitted in units of 20 MHz channels. For example, when a PPDU is transmitted on four 20 MHz channels (ie, an 80 MHz band), the L-STF, L-LTF, L-SIG, and HE-SIG A fields may be repeatedly transmitted on every 20 MHz channel. .

As the FFT size increases, legacy STAs supporting legacy IEEE 802.11a / g / n / ac may not be able to decode the HE PPDU. In order for the legacy STA and the HE STA to coexist, the L-STF, L-LTF, and L-SIG fields are transmitted through a 64 FFT on a 20 MHz channel so that the legacy STA can receive them. For example, the L-SIG field may occupy one OFDM symbol, one OFDM symbol time is 4 ms, and a GI may be 0.8 ms.

The FFT size for each frequency unit can be made larger from the HE-STF. For example, 256 FFTs may be used in a 20 MHz channel, 512 FFTs may be used in a 40 MHz channel, and 1024 FFTs may be used in an 80 MHz channel. As the FFT size increases, the number of OFDM subcarriers per unit frequency increases because the interval between OFDM subcarriers becomes smaller, but the OFDM symbol time becomes longer. In order to improve the efficiency of the system, the length of the GI after the HE-STF may be set equal to the length of the GI of the HE-SIG A.

The HE-SIG A field may include information required for the HE STA to decode the HE PPDU. However, the HE-SIG A field may be transmitted through a 64 FFT in a 20 MHz channel so that both the legacy STA and the HE STA can receive it. This is because the HE STA can receive not only the HE format PPDU but also the existing HT / VHT format PPDU, and the legacy STA and the HE STA must distinguish between the HT / VHT format PPDU and the HE format PPDU.

19 illustrates an HE format PPDU according to an embodiment of the present invention.

In FIG. 19, it is assumed that 20 MHz channels are allocated to different STAs (eg, STA 1, STA 2, STA 3, and STA 4).

Referring to FIG. 19, the FFT size per unit frequency may be larger from the HE-STF (or HE-SIG B). For example, from the HE-STF (or HE-SIG B), 256 FFTs may be used in a 20 MHz channel, 512 FFTs may be used in a 40 MHz channel, and 1024 FFTs may be used in an 80 MHz channel.

Since information transmitted in each field included in the PPDU is the same as the example of FIG. 12, a description thereof will be omitted.

The HE-SIG B field may include information specific to each STA, but may be encoded over the entire band (ie, indicated by the HE-SIG-A field). That is, the HE-SIG B field includes information on all STAs and is received by all STAs.

The HE-SIG B field may inform frequency bandwidth information allocated to each STA and / or stream information in a corresponding frequency band. For example, in FIG. 13, the HE-SIG-B may be allocated 20 MHz for STA 1, 20 MHz for STA 2, 20 MHz for STA 3, and 20 MHz for STA 4. In addition, STA 1 and STA 2 may allocate 40 MHz, and STA 3 and STA 4 may then allocate 40 MHz. In this case, STA 1 and STA 2 may allocate different streams, and STA 3 and STA 4 may allocate different streams.

In addition, by defining the HE-SIG-C field, the HE-SIG C field may be added to the example of FIG. 13. In this case, in the HE-SIG-B field, information on all STAs may be transmitted over the entire band, and control information specific to each STA may be transmitted in units of 20 MHz through the HE-SIG-C field.

Also, unlike the example of FIGS. 18 and 19, the HE-SIG-B field may be transmitted in units of 20 MHz in the same manner as the HE-SIG-A field without transmitting over the entire band. This will be described with reference to the drawings below.

20 is a diagram illustrating a HE format PPDU according to an embodiment of the present invention.

In FIG. 20, it is assumed that 20 MHz channels are allocated to different STAs (eg, STA 1, STA 2, STA 3, and STA 4).

Referring to FIG. 20, the HE-SIG B field is not transmitted over the entire band, but is transmitted in 20 MHz units in the same manner as the HE-SIG A field. However, at this time, the HE-SIG-B is encoded and transmitted in 20 MHz units differently from the HE-SIG A field, but may not be copied and transmitted in 20 MHz units.

In this case, the FFT size per unit frequency may be larger from the HE-STF (or HE-SIG B). For example, from the HE-STF (or HE-SIG B), 256 FFTs may be used in a 20 MHz channel, 512 FFTs may be used in a 40 MHz channel, and 1024 FFTs may be used in an 80 MHz channel.

Since information transmitted in each field included in the PPDU is the same as the example of FIG. 12, a description thereof will be omitted.

The HE-SIG A field is duplicated and transmitted in units of 20 MHz.

The HE-SIG B field may inform frequency bandwidth information allocated to each STA and / or stream information in a corresponding frequency band. Since the HE-SIG B field includes information about each STA, information about each STA may be included for each HE-SIG B field in units of 20 MHz. In this case, in the example of FIG. 14, 20 MHz is allocated to each STA. For example, when 40 MHz is allocated to the STA, the HE-SIG-B field may be copied and transmitted in units of 20 MHz.

It may be more preferable not to transmit the HE-SIG-B field over the entire band as in the case of allocating a part of the bandwidth having a low interference level from the adjacent BSS to the STA in a situation in which different bandwidths are supported for each BSS. .

17 through 20, the data field may be a payload and may include a service field, a scrambled PSDU, tail bits, and padding bits.

Meanwhile, the HE format PPDU as shown in FIGS. 17 through 20 may be identified through a RL-SIG (Repeated L-SIG) field which is a repetition symbol of the L-SIG field. The RL-SIG field is inserted before the HE SIG-A field, and each STA may identify the format of the received PPDU as the HE format PPDU using the RL-SIG field.

The manner in which an AP operating in a WLAN system transmits data to a plurality of STAs on the same time resource may be referred to as DL MU transmission (downlink multi-user transmission). In contrast, a scheme in which a plurality of STAs operating in a WLAN system transmit data to an AP on the same time resource may be referred to as UL MU transmission (uplink multi-user transmission).

Such DL MU transmission or UL MU transmission may be multiplexed in a frequency domain or a spatial domain.

When multiplexing on the frequency domain, different frequency resources (eg, subcarriers or tones) may be allocated as downlink or uplink resources for each of a plurality of STAs based on orthogonal frequency division multiplexing (OFDMA). Can be. In this same time resource, a transmission scheme using different frequency resources may be referred to as 'DL / UL OFDMA transmission'.

When multiplexing on a spatial domain, different spatial streams may be allocated as downlink or uplink resources for each of the plurality of STAs. In this same time resource, a transmission expression through different spatial streams may be referred to as 'DL / UL MU MIMO' transmission.

21 through 23 are diagrams illustrating a resource allocation unit in an OFDMA multi-user transmission scheme according to an embodiment of the present invention.

When a DL / UL OFDMA transmission scheme is used, a plurality of resource units may be defined in units of n tones (or subcarriers) within a PPDU bandwidth.

The resource unit means an allocation unit of frequency resources for DL / UL OFDMA transmission.

One or more resource units may be allocated to one STA as DL / UL frequency resources, and different resource units may be allocated to the plurality of STAs, respectively.

21 illustrates a case where the PPDU bandwidth is 20 MHz.

Seven DC tones may be located in the center frequency region of the 20 MHz PPDU bandwidth. In addition, six left guard tones and five right guard tones may be located at both sides of the 20 MHz PPDU bandwidth.

According to the resource unit configuration method as shown in FIG. 21A, one resource unit may be configured of 26 tones (26 ton resource units). In this case, four leftover tones may be present in the 20 MHz PPDU bandwidth as shown in FIG. In addition, according to the resource unit configuration method as shown in FIG. 21 (b), one resource unit may be composed of 52 tones (52 ton resource unit) or 26 tones. In this case, four leftover tones may be present in the 20 MHz PPDU bandwidth as shown in FIG. 21 (b) adjacent to the 26 tone / 52 tone resource unit. In addition, according to the resource unit configuration method as shown in FIG. 21C, one resource unit may include 106 tones (106 ton resource units) or 26 tones. In addition, according to the resource unit configuration method as shown in FIG. 21 (d), one resource unit may be configured of 242 tones (242 ton resource unit).

When a resource unit is configured as shown in FIG. 21A, up to nine STAs may be supported for DL / UL OFDMA transmission in a 20 MHz band. In addition, when the resource unit is configured as shown in FIG. 21 (b), up to five STAs may be supported for DL / UL OFDMA transmission in the 20 MHz band. In addition, when the resource unit is configured as shown in FIG. 21 (c), up to three STAs may be supported for DL / UL OFDMA transmission in the 20 MHz band. In addition, when a resource unit is configured as shown in 21 (d), a 20 MHz band may be allocated to one STA.

The resource unit configuration method of FIG. 21 (a) to FIG. 21 (d) may be applied based on the number of STAs participating in DL / UL OFDMA transmission and / or the amount of data transmitted or received by the STA. Alternatively, the resource unit configuration scheme in which FIGS. 21A to 21D are combined may be applied.

22 illustrates a case where the PPDU bandwidth is 40 MHz.

Five DC tones may be located in the center frequency region of the 40 MHz PPDU bandwidth. In addition, 12 left guard tones and 11 light guard tones may be located at both sides of the 40 MHz PPDU bandwidth.

According to the resource unit configuration method as shown in FIG. 22 (a), one resource unit may consist of 26 tones. In this case, 16 leftover tones may be present in the 40 MHz PPDU bandwidth as shown in FIG. 22A adjacent to the 26-tone resource unit. In addition, according to the resource unit configuration method as shown in FIG. 22 (b), one resource unit may consist of 52 tones or 26 tones. In this case, 16 leftover tones may be present in the 40 MHz PPDU bandwidth as shown in FIG. 22 (b) adjacent to the 26 ton / 52 ton resource unit. In addition, according to the resource unit configuration method as shown in FIG. 22C, one resource unit may be composed of 106 tones or 26 tones. In this case, eight leftover tones may be present in the 40 MHz PPDU bandwidth as shown in FIG. 22C adjacent to the 26 tone / 106 tone resource unit. In addition, according to the resource unit configuration method as shown in FIG. 22 (d), one resource unit may be configured with 242 tones. In addition, according to the resource unit configuration method as shown in FIG. 22E, one resource unit may be configured of 484 tones (484 ton resource unit).

When a resource unit is configured as shown in FIG. 22A, up to 18 STAs may be supported for DL / UL OFDMA transmission in a 40 MHz band. In addition, when a resource unit is configured as shown in FIG. 22 (b), up to 10 STAs may be supported for DL / UL OFDMA transmission in a 40 MHz band. In addition, when the resource unit is configured as shown in FIG. 22 (c), up to six STAs may be supported for DL / UL OFDMA transmission in the 40 MHz band. In addition, when the resource unit is configured as shown in 22 (d), up to two STAs may be supported for DL / UL OFDMA transmission in the 40 MHz band. In addition, when a resource unit is configured as shown in 22 (e), the corresponding resource unit may be allocated to one STA for SU DL / UL transmission in the 40 MHz band.

The resource unit configuration scheme of FIG. 22 (a) to FIG. 22 (e) may be applied based on the number of STAs participating in DL / UL OFDMA transmission and / or the amount of data transmitted or received by the STA. Alternatively, the resource unit configuration method in which FIGS. 22A to 22E are combined may be applied.

23 illustrates a case where the PPDU bandwidth is 80 MHz.

Seven DC tones may be located in the center frequency region of the 80 MHz PPDU bandwidth. However, when 80 MHz PPDU bandwidth is allocated to one STA (that is, when a resource unit composed of 996 tones is allocated to one STA), five DC tones may be located in the center frequency region. In addition, 12 left guard tones and 11 light guard tones may be located at both sides of the 80 MHz PPDU bandwidth.

According to the resource unit configuration method as shown in FIG. 23 (a), one resource unit may consist of 26 tones. In this case, 32 leftover tones may be present in the 80 MHz PPDU bandwidth as shown in FIG. 23 (a) adjacent to the 26-tone resource unit. In addition, according to the resource unit configuration method as shown in FIG. 23 (b), one resource unit may be composed of 52 tones or 26 tones. In this case, 32 leftover tones may be present in the 80 MHz PPDU bandwidth as shown in FIG. 23 (b) adjacent to the 26 ton / 52 ton resource unit. In addition, according to the resource unit configuration method as shown in FIG. 23 (c), one resource unit may be composed of 106 tones or 26 tones. In this case, 16 leftover tones may be present in the 80 MHz PPDU bandwidth as shown in FIG. In addition, according to the resource unit configuration method as shown in FIG. 23 (d), one resource unit may be configured of 242 tones or 26 tones. According to the resource unit configuration method as shown in FIG. 23 (e), one resource unit may consist of 484 tones or 26 tones. According to the resource unit configuration method as shown in FIG. 23 (f), one resource unit may be configured with 996 tones.

When a resource unit is configured as shown in FIG. 23 (a), up to 37 STAs may be supported for DL / UL OFDMA transmission in an 80 MHz band. In addition, when the resource unit is configured as shown in FIG. 23 (b), up to 21 STAs may be supported for DL / UL OFDMA transmission in the 80 MHz band. In addition, when the resource unit is configured as shown in FIG. 23 (c), up to 13 STAs may be supported for DL / UL OFDMA transmission in the 80 MHz band. In addition, when the resource unit is configured as shown in 23 (d), up to five STAs may be supported for DL / UL OFDMA transmission in the 80 MHz band. In addition, when the resource unit is configured as shown in 23 (e), up to three STAs may be supported for DL / UL OFDMA transmission in the 80 MHz band. In addition, when a resource unit is configured as shown in 28 (f), the resource unit may be allocated to one STA for SU DL / UL transmission in the 80 MHz band.

The resource unit configuration method of FIG. 23 (a) to FIG. 23 (f) is applied based on the number of STAs participating in DL / UL OFDMA transmission and / or the amount of data transmitted or received by the STA, or the like. Alternatively, the resource unit configuration method in which FIGS. 23A to 23F are combined may be applied.

In addition, although not shown in the figure, a configuration method of a resource unit when the PPDU bandwidth is 160 MHz may be proposed. In this case, the bandwidth of the 160MHz PPDU may have a structure in which the 80MHz PPDU bandwidth described above in FIG. 32 is repeated twice.

Only some resource units may be used for DL / UL OFDMA transmission among all resource units determined according to the above-described resource unit configuration. For example, when a resource unit is configured as shown in FIG. 23 (a) within 20 MHz, one resource unit may be allocated to less than nine STAs, and the remaining resource units may not be allocated to any STA.

In the case of DL OFDMA transmission, the data field of the PPDU is multiplexed and transmitted in a frequency domain in units of resource units allocated to each STA.

On the other hand, in the case of UL OFDMA transmission, the data field of the PPDU may be configured in units of resource units allocated to each STA and transmitted simultaneously to the AP. As described above, since each STA simultaneously transmits a PPDU, it may be recognized that a data field of a PPDU transmitted from each STA is multiplexed (or frequency multiplexed) in the frequency domain from the viewpoint of the AP.

In addition, when DL / UL OFDMA transmission and DL / UL MU-MIMO transmission are simultaneously supported, one resource unit may consist of a plurality of streams in a spatial domain. In addition, one or more streams may be allocated to one STA as DL / UL spatial resources, and different streams may be allocated to the plurality of STAs, respectively.

For example, a resource unit composed of 106 tones in FIG. 23C may be configured of a plurality of streams in a spatial domain to simultaneously support DL / UL OFDMA and DL / UL MU-MIMO.

Hereinafter, for convenience of description, a resource unit composed of n tones will be referred to as an 'n tone resource unit' (n is a natural number). For example, in the following, a resource unit consisting of 26 tones is referred to as a '26 ton resource unit '.

Pilot tone plan

24 is a diagram illustrating a pilot tone plan of an existing system.

802.11n system

For a 20 MHz bandwidth transmission in an 802.11n system, four pilot tones are inserted into subcarriers and located at indices of {-21, -7, 7, 21}, respectively. For 40 MHz bandwidth transmission, six pilot tones are inserted into the subcarriers and located at indexes {-53, -25, -11, 11, 25, 53}, respectively.

In the 802.11n system, a multi stream pilot (MSP) scheme is used. Here, the multi stream pilot method indicates a method of using different pilot sequences according to the number of streams. Accordingly, in the MSP scheme, a pilot tone value (or pilot value) may be determined according to the number of streams used for data transmission. The 802.11n system supports up to four streams.

In the 20 MHz bandwidth transmission, the pilot tones may be represented by a pilot sequence as shown in Equation 1 below, and the pilot values located at the indexes {-21, -7, 7, 21} are defined as shown in the table of FIG. 24 (a). Can be done. In FIG. 24 (a), NSTS is the number of streams, iSTS is the stream index,

Denotes a pilot value.

For example, when data is transmitted using two streams, values of four pilot tones transmitted through the first stream (iSTS = 1) may be determined to be (1, 1, -1, -1), respectively. The values of four pilot tones transmitted through the second stream (iSTS = 2) may be determined to be (1, -1, -1, 1), respectively.

In addition, the pilot tones in the 40MHz bandwidth transmission can be represented by a pilot sequence as shown in Equation 2 below, the value of the pilot tones located in the index {-53, -25, -11, 11, 25, 53} is shown in Figure 24 It can be determined as shown in the table in (b). In FIG. 24 (b), NSTS is the number of streams, iSTS is the stream index,

Denotes a pilot value.

For example, when data is transmitted using three streams, the values of six pilot tones transmitted on the first stream (iSTS = 1) are respectively (1, 1, -1, -1, -1, 6 pilot tones transmitted through the second stream (iSTS = 2) may be determined to be (1, 1, 1, -1, 1, 1), and the third stream. The values of six pilot tones transmitted through (iSTS = 3) may be determined to be (1, -1, 1, -1, -1, 1), respectively.

802.11ac system

In a 20 MHz bandwidth transmission in an 802.11ac system, four pilot tones are inserted into subcarriers and inserted into indices of {-21, -7, 7, 21}, respectively. For 40 MHz bandwidth transmission, six pilot tones are inserted into the subcarriers and inserted into the indices of {-53, -25, -11, 11, 25, 53}, respectively. For 80 MHz bandwidth transmission, eight pilot tones are inserted into the subcarriers and inserted into the indices {-103, -75, -39, -11, 11, 39, 75, 103}, respectively. For 160 MHz bandwidth transmission, 16 pilot tones are inserted into the subcarriers, {-231, -203, -167, -139, -117, -89, -53, -25, 25, 53, 89, 117 , 139, 167, 203, and 231, respectively.

In an 802.11ac system, a single stream pilot (SSP) scheme is used. Here, the single stream pilot method refers to a method of using a fixed pilot sequence for each stream regardless of the number of streams. For example, the value of each pilot tone (

) May be determined regardless of the number of streams as shown in the table of FIG. 18C.

For 20 MHz bandwidth transmission

To

The pilot values of may be applied. Therefore, in the case of 20 MHz bandwidth transmission, four pilot tones each positioned at an index of {-21, -7, 7, 21} may have values of (1, 1, 1, -1) in order. For 40MHZ Bandwidth Transmission

To

The pilot values of may be applied. Thus, for a 40 MHz bandwidth transmission, six pilot tones, each located at an index of {-53, -25, -11, 11, 25, 53}, are in order (1, 1, 1, -1, -1, 1). It can have a value of). For 80 MHz bandwidth transmission,

To

The pilot values of may be applied. Thus, for 80 MHz bandwidth transmission, eight pilot tones, each located at an index of {-103, -75, -39, -11, 11, 39, 75, 103}, are in order (1, 1, 1, -1). , -1, 1, 1, 1) can each have a value.

In the case of a 160 MHz bandwidth transmission, pilot values in the 80 MHz bandwidth transmission may be duplicated and applied. Thus, for 160 MHz bandwidth transmission, {-231, -203, -167, -139, -117, -89, -53, -25, 25, 53, 89, 117, 139, 167, 203, 231} Each of the 16 pilot tones located in the index has a value of (1, 1, 1, -1, -1, 1, 1, 1, 1, 1, 1, -1, -1, 1, 1, 1) Each can have a.

HE- STF (High Efficiency-Short Training Field) sequence

The present invention proposes a method for configuring a HE-STF sequence and a method for transmitting and receiving a PPDU including a HE-STF field configured based on the HE-STF sequence. In particular, the present invention proposes a method for configuring a 2x HE-STF sequence and a method for transmitting and receiving a PPDU including a 2x HE-STF field.

Prior to the description of the present invention, the HT-STF defined in the 802.11n system and the VHT-STF defined in the 802.11ac system will be described.

First, look at the HT-STF.

HT-STF is used to improve AGC estimation performance in MIMO system. The duration of the HT-STF is 4 ms. For 20 MHz transmission, the frequency domain sequence used to construct the HT-STF is the same as the L-STF. For 40 MHz transmission, the HT-STF consists of a 20 MHz HT-STF sequence being duplicated, frequency shifted and the upper subcarrier rotated 90 degrees.

In a 20 MHz PPDU transmission, an HT-STF sequence (HTS: HT-STF sequence) in a frequency domain is defined as in Equation 2 below.

Referring to Equation 3, HTS_28, 28 illustrates an HT-STF sequence mapped to a subcarrier corresponding to subcarrier (or tone) index -28 to subcarrier index 28.

That is, in the 20 MHz PPDU transmission, in the HT-STF sequence, a non-zero value is mapped to a subcarrier whose subcarrier index is a multiple of 4 from the subcarrier index -28 to the subcarrier index 28. A zero value is mapped to a subcarrier with carrier indexes -28, 0, 28.

In a 40 MHz PPDU transmission, a frequency domain HT-STF sequence is defined as in Equation 4 below.

Referring to Equation 4, HTS_58, 58 illustrates an HT-STF sequence mapped to a subcarrier corresponding to the subcarrier (or tone) index -58 to the subcarrier index 58.

That is, in the 40 MHz PPDU transmission, in the case of the HT-STF sequence, a non-zero value is mapped to a subcarrier whose subcarrier index is a multiple of 4 out of subcarriers index -58 to subcarrier index 58, but A zero value is mapped to a subcarrier with subcarrier indexes -32, -4, 0, 4, 32.

Equations 3 and 4 do not show phase rotation for each 20 MHz subchannel.

In a given bandwidth (i.e., PPDU transmission bandwidth), gamma (gamma, γ) (i.e., phase rotation) is applied to each 20MHz subchannel to the HT-STF sequence defined as Equations 3 and 4.

For 20MHz PPDU transmission, γ is defined as shown in Equation 5 below.

In Equation 5, k represents the index of the subcarrier (or tone). That is, 1 is multiplied by the HT-STF sequence for all subcarriers.

For 40MHz PPDU transmission, γ is defined as shown in Equation 6 below.

In Equation 6, k represents an index of a subcarrier (or tone).

For a 40 MHz channel, 1 is multiplied by the HT-STF sequence if the subcarrier index is less than or equal to 0, and j is multiplied by the HT-STF sequence if the subcarrier index is greater than zero.

Next, look at the VHT-STF.

The VHT-STF field is used to improve AGC estimation performance in MIMO transmission. The duration of the VHT-STF field is 4 ms. For 20 MHz transmission, the frequency domain sequence used to construct the VHT-STF field is the same as the L-STF. For 40MHz and 80MHz transmission, the VHT-STF is a 20MHz VHT-STF sequence is duplicated (duplication) and frequency shifted (frequency shifting) for each 20MHz subchannel, and phase rotation is applied for each 20MHz subchannel.

In a 20 MHz PPDU transmission, a frequency domain VHT-STF sequence (VHTS: VHT-STF Sequence) is defined as in Equation 5 below.

In Equation 7, HTS-28,28 is defined in Equation 1 above.

In the 40 MHz PPDU transmission, a frequency domain VHT-STF sequence is defined as in Equation 8 below.

In Equation 8, HTS_58, 58 are defined in Equation 2 above.

In the 80 MHz PPDU transmission, a frequency domain VHT-STF sequence is defined as in Equation 9 below.

In Equation 9, VHTS_58, 58 are defined in Equation 8 above.

0 is mapped to the DC (direct current) tone, and the VHTS_-58,58 sequence is mapped to both sides of the DC tone.

That is, in the 80 MHz PPDU transmission, in the case of the VHT-STF sequence, a non-zero value is mapped to a subcarrier whose subcarrier index is a multiple of 4 among the subcarriers from the subcarrier index -122 to the subcarrier index 122, but A zero value is mapped to a subcarrier with subcarrier indexes -96, -68, -64, -60, -32, -4, 0, 4, 32, 60, 64, 68, 96.

In the case of noncontiguous 80 + 80MHz PPDU transmission, the 80MHz VHT-STF sequence defined in Equation 9 is used for each 80MHz frequency segment.

In a continuous 160 MHz PPDU transmission, a frequency domain VHT-STF sequence is defined as in Equation 10 below.

In Equation 10, VHTS_122 and 122 are defined in Equation 9 above.

0 is mapped to the DC (direct current) tone, and the VHTS_-122,122 sequence is mapped to both sides of the DC tone.

That is, in a continuous 160 MHz PPDU transmission, for a VHT-STF sequence, a non-zero value for a subcarrier whose subcarrier index is a multiple of 4 among the subcarriers ranging from subcarrier index -250 to subcarrier index 250 Are mapped, but subcarrier indices -224, -196, -192, -188, -160, -132, -128, -124, -96, -68, -64, -60, -32, -4, Zero values are mapped to subcarriers 0, 4, 32, 60, 64, 68, 96, 124, 128, 132, 160, 188, 192, 196, and 224.

In Equations 7 to 10, phase rotation for each 20 MHz subchannel does not appear.

In a given bandwidth (ie, PPDU transmission bandwidth), gamma (γ) (ie, phase rotation) is applied for each 20 MHz subchannel to a VHT-STF sequence defined as Equations 7 to 10.

Hereinafter, γ_k and BW will be described for each PPDU bandwidth. In γ_k, BW, k denotes an index of a subcarrier (or tone), and BW denotes a PPDU transmission bandwidth.

In 20MHz PPDU transmission, γ_k, BW is defined as in Equation 11 below.

For 20 MHz PPDU transmission, all VHT-STF sequences for all subcarriers are multiplied by one.

In 40MHz PPDU transmission, γ_k, BW is defined as in Equation 12 below.

For 40 MHz PPDU transmission, if the subcarrier index is less than 0, 1 is multiplied to the VHT-STF sequence, and if the subcarrier index is equal to or greater than 0, j is multiplied to the VHT-STF sequence.

In the 80MHz PPDU transmission, γ_k, BW is defined as in Equation 13 below.

For 80 MHz PPDU transmission, 1 is multiplied by the VHT-STF sequence if the subcarrier index is less than -64, and -1 is multiplied by the VHT-STF sequence if the subcarrier index is equal to or greater than -64.

For non-contiguous 80 + 80 MHz PPDU transmissions, each 80 MHz frequency segment uses phase rotation as shown in equation (13).

In the continuous (contiguous) 160MHz PPDU transmission, γ_k, BW is defined as in Equation 14 below.

For contiguous 160 MHz PPDU transmissions, if the subcarrier index is less than -192, 1 is multiplied by the VHT-STF sequence; if the subcarrier index is greater than or equal to -192 and less than 0, -1 is VHT-STF If the subcarrier index is greater than or equal to 0 and less than 64, 1 is multiplied to the sequence, and if the subcarrier index is greater than or equal to 64, -1 is multiplied to the VHT-STF sequence.

As illustrated in FIGS. 17 to 20, in the 802.11ax, the HE-STF field needs to be newly defined to improve the AGC estimation performance to conform to the new PPDU format.

In more detail, since each STA transmits data using one resource unit during UL MU transmission, various problems occur when the tone location is used by scaling the STF sequence used in the existing 802.11ac system. . One of them is the problem of peak-to-power average ratio (PAPR). Since the sequence of the existing system is designed considering only the case where each STA transmits UL using full bandwidth (or PPDU bandwidth, Full Bandwidth), STF using only a part of the entire bandwidth (for example, one resource unit) If the sequence is transmitted, the PAPR may be large.

PAPR is generally defined as the peak amplitude of an OFDM signal divided by the root mean square of the amplitude of the OFDM signal.

Since an OFDM signal consists of a combination of many subcarriers (or tones) each having a different amplitude, the PAPR value can be quite large. High PAPR causes distortion of the signal and the like, and as a result, noise and interference between subcarriers may be increased due to signal distortion and the like. In addition, low PAPR can prevent clipping of the signal. Therefore, it is effective to lower the PAPR of each OFDMA signal.

In addition, when each STA transmits a UL MU using a 26-tone resource unit, there is a problem that only one or two STA sequences exist in the 26-tone resource unit.

Accordingly, the present invention proposes a method for generating a HE-STF sequence and a method for transmitting a PPDU to which the HE-STF is mapped to solve the above problems.

In legacy WLAN systems, the FFT size may be 64, 128, 256, and 512 at 20 MHz, 40 MHz, 80 MHz, and 160 MHz, respectively. In this case, in a legacy WLAN system, the subcarrier spacing is 312.5 kHz (= 20 MHz / 64, 40 MHz / 128, 80 MHz / 256 and / or 160 MHz / 512), and the IDFT / DFT period is 3.2 ms (= 1 / 312.5). kHz).

As described above, HT-STF and VHT are mapped to non-zero values in four subcarrier intervals (ie, subcarrier index multiples of 4) in the frequency domain. The -STF has a 0.8 ms (= 3.2 ms / 4) period corresponding to a quarter of the IDFT / DFT period in the time domain.

As described above, an 802.11ax system (ie, a HEW system) may use an FFT size (ie, 4x) four times larger in each bandwidth than existing IEEE 802.11 OFDM systems (IEEE 802.11a, 802.11n, 802.11ac, etc.). .

That is, if the FFT sizes used for legacy WLAN systems are 64, 128, 256, and 512 at 20 MHz, 40 MHz, 80 MHz, and 160 MHz, respectively, the FFT sizes used for the HE-part are 256, 512 at 20 MHz, 40 MHz, 80 MHz, and 160 MHz, respectively. , 1024, 2048. In this case, the subcarrier spacing of the HE-part is 78.125 kHz (= 20 MHz / 256, 40 MHz / 512, 80 MHz / 1024 and / or 160 MHz / 2048), and the ID-FT / DFT period of the HE-part is 12.8 ㎲ ( = 1 / 78.125 kHz).

As such, the subcarrier spacing of the HE-part corresponds to one quarter of the legacy WLAN system, so that non-zero values are mapped to 16 subcarrier spacings (for example, the subcarrier index is a multiple of 16). Once the HE-STF sequence is defined, the HE-STF has the same period (ie 0.8 ms) as the legacy WLAN system. That is, if the legacy WLAN system is 1x, the HE-STF having the same period as that of the legacy WLAN system may be referred to as 1x HE-STF.

In addition, if the HE-STF sequence is defined such that a non-zero value is mapped to eight subcarrier intervals (e.g., the subcarrier index is a multiple of eight), the HE-STF is twice as long as a legacy WLAN system. ) (Ie 1.6 ms). The HE-STF at this time may be referred to as 2x HE-STF.

In addition, if the HE-STF sequence is defined such that a non-zero value is mapped to four subcarrier intervals (e.g., the subcarrier index is a multiple of four), then the HE-STF is four times larger than a legacy WLAN system. ) (Ie, 3.2 μs). The HE-STF at this time may be referred to as 4x HE-STF.

Hereinafter, a 2x HE-STF sequence that can be applied to an 802.11ax system will be proposed, which will be described with reference to the following drawings. In particular, we propose a 2x HE-STF sequence for minimizing PAPR per resource unit (eg, 26 ton resource unit, 52 ton resource unit, and 106 ton resource unit).

The (2x) HE-STF sequence may be mapped to the (data) tones included in the resource unit. (2x) The HE-STF sequence may be configured with a value '0' or a value other than '0' (coefficient). Hereinafter, for convenience of description, a tone (ie, a predetermined coefficient) to which a nonzero value is mapped among tones (ie, tones of a resource unit) among (2x) HE-STF sequences are mapped. Tones are mapped to (2x) HE-STF tones (or subcarriers).

Hereinafter, the coefficient of the 2x HE-STF sequence is the same as the existing 802.11ac system, when using QPSK (i.e., 1 + j, 1-j, -1 + j, -1-j), full search for PAPR for each sequence is performed. We propose a 2x HE-STF sequence with a minimum PAPR value. In this case, the PAPR measured below represents a PAPR value (in dB) for each resource unit used to transmit a 2x HE-STF sequence in a 2x HE-STF sequence transmission of an 802.11ax system using a 4x FFT size. Measured with an additional 4x FFT size (4x upsampling PAPR). For example, the FFT size of the 802.11ax 20MHz is 256, the PAPR below is measured in the case of applying a FFT size of 1024 (256 * 4). However, since the 2x HE-STF sequence proposed below has an optimized 4x upsampling PAPR and a different FFT size is applied to obtain a PAPR similarly, the 2x HE-STF sequence proposed below has a PAPR. Regardless of the FFT size used in the measurement, it can generally be applied in any situation.

1. 2x HE-STF sequence of 26-ton resource unit

25 illustrates the location of 2x HE-STF tones in a 26-tone resource unit in accordance with an embodiment of the present invention.

Referring to FIG. 25, a 26-tone resource unit may include 3 (FIG. 25A) or 4 (FIG. 25B) 2x HE-STF tones. A value other than '0' may be mapped to three or four 2x HE-STF tones in the 26-tone resource unit, and a value of '0' may be mapped to the remaining tones except for the 2x HE-STF tones. Hereinafter, a 2x HE-STF sequence that may be applied in each case by dividing a case that a 26-tone resource unit includes i) three 2x HE-STF tones and ii) a case containing four 2x HE-STF tones Suggest.

(1) 3 coefficients

Referring to FIG. 25A, a 26-tone resource unit may include three 2x HE-STF tones. When the indexes of the 26 tones included in the 26-tone resource unit are 1 to 26 sequentially from the left side, the indexes of the 3 2x HE-STF tones n1, n2 and n3 may be proposed as follows.

-(3,11,19), (4,12,20), (5,13,21), (6,14,22), (7,15,23), or (8,16,24)

When the 26-tone resource unit includes 2x HE-STF tones located in the above-described index, and the corresponding 26-tone resource unit is transmitted through the 20/40/80 MHz channel, a coefficient value for minimizing the PAPR may be proposed as follows. .

-{1,1,4}, {1,2,1}, {1,3,1}, {1,4,4}, {2,1,2}, {2,2,3}, { 2,3,3}, {2,4,2}, {3,1,3}, {3,2,2}, {3,3,2}, {3,4,3}, {4, 1,1}, {4,2,4}, {4,3,4}, or {4,4,1}

Here, the coefficients indicated by each number are as follows.

1: 1 + j, 2: 1-j, 3: -1 + j, 4: -1-j

For example, when the coefficients of the 2x HE-STF tones located at (3, 11, 19) are {1, 1, 4}, the corresponding 2x HE-STF sequence is as follows.

{0 0 1 + j 0 0 0 0 0 0 0 1 + j 0 0 0 0 0 0 0 -1-j 0 0 0 0 0 0 0}

The proposed 4x upsampling PAPR (PAPR) of the 2x HE-STF sequence was measured to be about 2.2185 dB.

(2) 4 coefficients

Referring to FIG. 25B, a 26-tone resource unit may include four 2 × HE-STF tones.

When the indexes of the 26 tones included in the 26-tone resource unit are 1 to 26 sequentially from the left side, the indexes of the 4 2x HE-STF tones n1, n2, n3, and n4 may be proposed as follows.

-(1,9,17,25) or (2,10,18,26)

When the 26-tone resource unit includes 2x HE-STF tones located in the above-described index, and the corresponding 26-tone resource unit is transmitted through the 20/40/80 MHz channel, a coefficient value for minimizing the PAPR may be proposed as follows. .

-{1,1,1,4}, {1,1,4,1}, {1,2,1,3}, {1,2,4,2}, {1,3,1,2} , {1,3,4,3}, {1,4,1,1}, {1,4,4,4}, {2,1,2,4}, {2,1,3,1} , {2,2,2,3}, {2,2,3,2}, {2,3,2,2}, {2,3,3,3}, {2,4,2,1} , {2,4,3,4}, {3,1,2,1}, {3,1,3,4}, {3,2,2,2}, {3,2,3,3} , {3,3,2,3}, {3,3,3,2}, {3,4,2,4}, {3,4,3,1}, {4,1,1,1} , {4,1,4,4}, {4,2,1,2}, {4,2,4,3}, {4,3,1,3}, {4,3,4,2} , {4,4,1,4}, or {4,4,4,1}

Here, the coefficients indicated by each number are as follows.

1: 1 + j, 2: 1-j, 3: -1 + j, 4: -1-j

The proposed 4x upsampling PAPR (PAPR) of the 2x HE-STF sequence was measured as about 2.4763dB for the 20MHz channel and about 2.4792dB for the 40 / 80MHz channel.

2. 2x HE-STF sequence of 52-ton resource unit

Figure 26 illustrates the location of 2x HE-STF tones in a 52-tone resource unit according to an embodiment of the present invention.

Referring to FIG. 26, a 52-tone resource unit may include 6 (FIG. 26A) or 7 (FIG. 26B) 2x HE-STF tones. A value other than '0' may be mapped to six or seven 2x HE-STF tones in the 52-tone resource unit, and a value of '0' may be mapped to the remaining tones except the 2x HE-STF tones. In the following description, a 2x HE-STF sequence that can be applied in each case may be divided into a case where a 52-tone resource unit includes i) six 2x HE-STF tones and ii) seven sevenx 2x HE-STF tones. Suggest.

(1) 6 coefficients

Referring to FIG. 26A, a 52-tone resource unit may include six 2x HE-STF tones. When the indexes of 52 tones included in the 52-tone resource unit are 1 to 52 sequentially from the left side, the indexes of the 6 2x HE-STF tones n1 to n6 may be proposed as follows.

-(5,13,21,29,37,45), (6,14,22,30,38,46), (7,15,23,31,39,47), or (8,16,24 , 32,40,48)

When a 52-tone resource unit includes 2x HE-STF tones located in the above-described index, and the corresponding 52-tone resource unit is transmitted through a 20/40/80 MHz channel, a coefficient value for minimizing PAPR may be proposed as follows. .

-{1,1,2,1,2,3}, {1,1,3,1,3,2}, {1,2,2,3,3,4}, {1,2,3, 3,2,1}, {1,3,2,2,3,1}, {1,3,3,2,2,4}, {1,4,2,4,2,2}, { 1,4,3,4,3,3}, {2,1,1,4,4,3}, {2,1,4,4,1,2}, {2,2,1,2, 1,4}, {2,2,4,2,4,1}, {2,3,1,3,1,1}, {2,3,4,3,4,4}, {2, 4,1,1,4,2}, {2,4,4,1,1,3}, {3,1,1,4,4,2}, {3,1,4,4,1, 3}, {3,2,1,2,1,1}, {3,2,4,2,4,4}, {3,3,1,3,1,4}, {3,3, 4,3,4,1}, {3,4,1,1,4,3}, {3,4,4,1,1,2}, {4,1,2,1,2,2} , {4,1,3,1,3,3}, {4,2,2,3,3,1}, {4,2,3,3,2,4}, {4,3,2, 2,3,4}, {4,3,3,2,2,1}, {4,4,2,4,2,3}, or {4,4,3,4,3,2}

Here, the coefficients indicated by each number are as follows.

1: 1 + j, 2: 1-j, 3: -1 + j, 4: -1-j

The proposed 4x upsampling PAPR (PAPR) of the 2x HE-STF sequence was measured to be about 2.3861 dB for the 20/40 MHz channel and about 2.3873 dB for the 80 MHz channel.

(2) 7 coefficients

Referring to FIG. 26B, a 52 ton resource unit may include seven 2 × HE-STF tones. When the indexes of 52 tones included in the 52-tone resource unit are 1 to 52 sequentially from the left side, the indexes of the 7 2x HE-STF tones n1 to n7 may be proposed as follows.

-(1,9,17,25,33,41,49), (2,10,18,26,34,42,50), (3,11,19,27,35,43,51), or (4,12,20,28,36,44,52)

When a 52-tone resource unit includes 2x HE-STF tones located in the above-described index, and the corresponding 52-tone resource unit is transmitted through a 20/40/80 MHz channel, a coefficient value for minimizing PAPR may be proposed as follows. .

{1,1,1,4,4,1,4}, {1,2,4,2,4,2,1}, {1,3,4,3,4,3,1}, {1 , 4,1,1,4,4,4}, {2,1,3,1,3,1,2}, {2,2,2,3,3,2,3}, {2,3 , 2,2,3,3,3}, {2,4,3,4,3,4,2}, {3,1,2,1,2,1,3}, {3,2,3 , 3,2,2,2}, {3,3,3,2,2,3,2}, {3,4,2,4,2,4,3}, {4,1,4,4 , 1,1,1}, {4,2,1,2,1,2,4}, {4,3,1,3,1,3,4}, or {4,4,4,1, 1,4,1}

Here, the coefficients indicated by each number are as follows.

1: 1 + j, 2: 1-j, 3: -1 + j, 4: -1-j

The proposed 4x upsampling PAPR (PAPR) of the 2x HE-STF sequence was measured as about 1.3846 dB for the 20/40 MHz channel and about 1.3855 dB for the 80 MHz channel.

3. 2x HE-STF sequence of 106 (or 107, 108) tone resource units

27 illustrates the location of 2 × HE-STF tones in a 106 ton (or 107, 108 ton) resource unit in accordance with an embodiment of the present invention.

Referring to FIG. 27, a 106 ton (or 107, 108 ton) resource unit may include 13 (FIG. 27A) or 14 (FIG. 27B) 2x HE-STF tones. 13 or 14 2x HE-STF tones can be mapped to a value other than '0' in a 106 ton (or 107 or 108 ton) resource unit, and a value of '0' to the remaining tones except the 2x HE-STF tones. Can be mapped. In the following, the 106 ton (or 107, 108 ton) resource unit is divided into i) including 13 2x HE-STF tones and ii) including 14 2x HE-STF tones, each case being applied. We propose a 2x HE-STF sequence.

(1) 13 coefficients

Referring to FIG. 27A, a 106-tone resource unit may include thirteen 2x HE-STF tones. When the indexes of the 106 tones included in the 106-tone resource unit are 1 to 106 sequentially from the left, the indexes of the 13 2x HE-STF tones n1 to n13 may be proposed as follows.

-(3,11,19,27,35,43,51,59,67,75,83,91,99), (4,12,20,28,36,44,52,60,68,76, 84,92,100, (5,13,21,29,37,45,53,61,69,77,85,93,101), (6,14,22,30,38,46,54,62,70, 78,86,94,102), (7,15,23,31,39,47,55,63,71,79,87,95,103), or (8,16,24,32,40,48,56,64 , 72,80,88,96,104)

In addition, although not shown in the figure, the 107-ton resource unit may include 13 2x HE-STF tones. When the indexes of the 107 tones included in the 107-tone resource unit are 1 to 107 sequentially from the left side, the indexes of the 13 2x HE-STF tones n1 to n13 may be proposed as follows.

-(4,12,20,28,36,44,52,60,68,76,84,92,100), (5,13,21,29,37,45,53,61,69,77,85, 93,101), (6,14,22,30,38,46,54,62,70,78,86,94,102), (7,15,23,31,39,47,55,63,71,79, 87,95,103), or (8,16,24,32,40,48,56,64,72,80,88,96,104)

In addition, although not shown in the figure, the 108 ton resource unit may include 13 2x HE-STF tones. When the indexes of 108 tones included in the 108-tone resource unit are 1 to 108 sequentially from the left, the indexes of the 13 2x HE-STF tones n1 to n13 may be proposed as follows.

-(5,13,21,29,37,45,53,61,69,77,85,93,101), (6,14,22,30,38,46,54,62,70,78,86, 94,102), (7,15,23,31,39,47,55,63,71,79,87,95,103), or (8,16,24,32,40,48,56,64,72,80 , 88,96,104)

When a 106 ton (or 107, 108 ton) resource unit contains 2x HE-STF tones located in the above-mentioned index, and the corresponding 106 ton (or 107, 108 ton) resource unit is transmitted through a 20/40/80 MHz channel For example, a coefficient value for minimizing PAPR can be proposed as follows.

-{1,1,1,4,4,4,1,1,4,1,1,4,1}, {1,2,4,2,4,3,4,3,4,2, 4,2,1}, {1,3,4,3,4,2,4,2,4,3,4,3,1}, {1,4,1,1,4,1,1, 4,4,4,1,1,1}, {2,1,3,1,3,4,3,4,3,1,3,1,2}, {2,2,2,3, 3,3,2,2,3,2,2,3,2}, {2,3,2,2,3,2,2,3,3,3,2,2,2}, {2, 4,3,4,3,1,3,1,3,4,3,4,2}, {3,1,2,1,2,4,2,4,2,1,2,1, 3}, {3,2,3,3,2,3,3,2,2,2,3,3,3}, {3,3,3,2,2,2,3,3,2, 3,3,2,3}, {3,4,2,4,2,1,2,1,2,4,2,4,3}, {4,1,4,4,1,4, 4,1,1,1,4,4,4}, {4,2,1,2,1,3,1,3,1,2,1,2,4}, {4,3,1, 3,1,2,1,2,1,3,1,3,4}, or {4,4,4,1,1,1,4,4,1,4,4,1,4}

Here, the coefficients indicated by each number are as follows.

1: 1 + j, 2: 1-j, 3: -1 + j, 4: -1-j

The proposed 4x upsampling PAPR (PAPR) of the 2x HE-STF sequence was measured as about 2.0992dB for the 20 / 40MHz channel and about 2.1027dB for the 80MHz channel.

(2) 14 coefficients

Referring to FIG. 27B, a 106-tone resource unit may include 14 2x HE-STF tones. When the indexes of the 106 tones included in the 106-tone resource unit are 1 to 106 sequentially from the left side, the indexes of the 14 2x HE-STF tones n1 to n14 may be proposed as follows.

-(1,9,17,25,33,41,49,57,65,73,81,89,97,105), or (2,10,18,26,34,42,50,58,66,74 , 82,90,98,106)

In addition, although not shown in the figure, the 107-ton resource unit may include 14 2x HE-STF tones. When the indexes of the 107 tones included in the 107-tone resource unit are 1 to 107 sequentially from the left side, the indexes of the 14 2x HE-STF tones n1 to n14 may be proposed as follows.

-(1,9,17,25,33,41,49,57,65,73,81,89,97,105), (2,10,18,26,34,42,50,58,66,74, 82,90,98,106), or (3,11,19,27,35,43,51,59,67,75,83,91,99,107)

In addition, although not shown in the figure, the 108 ton resource unit may include 14 2x HE-STF tones. When the indexes of 108 tones included in the 108-tone resource unit are 1 to 108 sequentially from the left side, the indexes of the 14 2x HE-STF tones n1 to n14 may be proposed as follows.

-(1,9,17,25,33,41,49,57,65,73,81,89,97,105), (2,10,18,26,34,42,50,58,66,74, 82,90,98,106), (3,11,19,27,35,43,51,59,67,75,83,91,99,107), or (4,12,20,28,36,44,52 , 60,68,76,84,92,100,108)

When a 106 ton (or 107, 108 ton) resource unit contains 2x HE-STF tones located in the above-mentioned index, and the corresponding 106 ton (or 107, 108 ton) resource unit is transmitted through a 20/40/80 MHz channel For example, a coefficient value for minimizing PAPR can be proposed as follows.

-{1,1,1,1,4,1,4,1,1,4,4,1,1,4}, {1,1,4,4,1,1,4,4,4, 4,4,1,4,1}, {1,2,1,2,1,2,1,2,4,3,1,3,4,2}, {1,2,4,3, 4,2,1,3,1,3,1,3,1,3}, {1,3,1,3,1,3,1,3,4,2,1,2,4,3} , {1,3,4,2,4,3,1,2,1,2,1,2,1,2}, {1,4,1,4,4,4,4,4,1, 1,4,4,1,1}, {1,4,4,1,1,4,4,1,4,1,4,4,4,4}, {2,1,2,1, 2,1,2,1,3,4,2,4,3,1}, {2,1,3,4,3,1,2,4,2,4,2,4,2,4} , {2,2,2,2,3,2,3,2,2,3,3,2,2,3}, {2,2,3,3,2,2,3,3,3, 3,3,2,3,2}, {2,3,2,3,3,3,3,3,2,2,3,3,2,2}, {2,3,3,2, 2,3,3,2,3,2,3,3,3,3}, {2,4,2,4,2,4,2,4,3,1,2,1,3,4} , {2,4,3,1,3,4,2,1,2,1,2,1,2,1}, {3,1,2,4,2,1,3,4,3, 4,3,4,3,4}, {3,1,3,1,3,1,3,1,2,4,3,4,2,1}, {3,2,2,3, 3,2,2,3,2,3,2,2,2,2}, {3,2,3,2,2,2,2,2,3,3,2,2,3,3} , {3,3,2,2,3,3,2,2,2,2,2,3,2,3}, {3,3,3,3,2,3,2,3,3, 2,2,3,3,2}, {3,4,2,1,2,4,3,1,3,1,3,1,3,1}, {3,4,3,4, 3,4,3,4,2,1,3,1,2,4}, {4,1,1,4,4,1,1,4,1,4,1,1,1,1} , {4,1,4,1,1,1,1,1,4,4,1,1,4,4}, {4,2,1,3,1,2,4,3,4, 3,4,3,4,3}, {4,2,4,2,4,2,4,2,1,3,4,3,1,2}, {4,3,1,2, 1,3,4,2,4,2,4,2,4,2}, {4,3,4,3,4,3,4,3,1,2,4,2,1,3} , {4,4,1,1,4,4,1,1,1,1,1,4,1,4}, or {4,4,4,4,1,4,1,4,4 , 1,1,4,4,1}

Here, the coefficients indicated by each number are as follows.

1: 1 + j, 2: 1-j, 3: -1 + j, 4: -1-j

The proposed 4x upsampling PAPR (PAPR) of the 2x HE-STF sequence was measured to be about 2.1817 dB for the 20 MHz channel and about 2.1999 dB for the 40/80 MHz channel.

28 is a flowchart illustrating a PPDU transmission method of an STA device according to an embodiment of the present invention. The embodiments described above with reference to the flowchart can be equally applied. Therefore, hereinafter, redundant description will be omitted.

Referring to FIG. 28, the STA may generate a HE-STF sequence (S2801). In this case, the HE-STF sequence may be generated such that a non-zero value (coefficient) is mapped to eight subcarrier intervals (for example, the subcarrier index is a multiple of 8). It may be a 2x HE-STF with a period twice as large as a legacy WLAN system (ie 1.6 ms).

Next, the STA may generate a PPDU including the HE-STF field configured based on the HE-STF sequence (S2802).

Next, the STA may transmit the generated PPDU (S2803). In this case, when the STA transmits the HE-STF field included in the PPDU, the STA may transmit using a frequency resource unit (for example, an n-tone resource unit allocated to the STA). Accordingly, the HE-STF sequence of the HE-STF field may be mapped to tones included in the frequency resource unit, and specific tones among the tones to which the HE-STF sequence is mapped are 1 + j, 1-j, and -1+, respectively. Any one of j, and -1-j may be mapped to a predefined value, and a zero value may be mapped to the remaining tones. Various embodiments related to this have been described above with reference to FIGS. 25 to 27.

In addition, the specific tones may have a predetermined index and exist at a specific position in the frequency resource unit. Various embodiments in this regard are also described above with reference to FIGS. 25-27.

29 is a block diagram of each STA apparatus according to an embodiment of the present invention.

In FIG. 29, the STA apparatus 2910 may include a memory 2912, a processor 2911, and an RF unit 2913. As described above, the STA device may be an AP or a non-AP STA as an HE STA device.

The RF unit 2913 may be connected to the processor 2911 to transmit / receive a radio signal. The RF unit 2913 may up-convert data received from the processor 2911 into a transmission / reception band to transmit a signal.

The processor 2911 may be connected to the RF unit 2913 to implement a physical layer and / or a MAC layer according to the IEEE 802.11 system. The processor 2911 may be configured to perform operations according to various embodiments of the present disclosure according to the above-described drawings and descriptions. In addition, a module that implements the operation of the STA 2910 according to various embodiments of the present disclosure described above may be stored in the memory 2912 and executed by the processor 2911.

The memory 2912 is connected to the processor 2911 and stores various information for driving the processor 2911. The memory 2912 may be included in the processor 2911 or may be installed outside the processor 2911 and may be connected to the processor 2911 by a known means.

In addition, the STA apparatus 2910 may include a single antenna or multiple antennas.

The specific configuration of the STA apparatus 2910 of FIG. 29 may be implemented such that the above-described matters described in various embodiments of the present invention are independently applied or two or more embodiments are simultaneously applied.

For convenience of description, the drawings are divided and described, but the embodiments described in each drawing may be merged to implement a new embodiment. In addition, the display device is not limited to the configuration and method of the embodiments described as described above, the above embodiments are configured by selectively combining all or some of the embodiments so that various modifications can be made May be

In addition, while the preferred embodiments have been shown and described, the present specification is not limited to the above-described specific embodiments, and those skilled in the art without departing from the scope of the claims. Various modifications can be made by the user, and these modifications should not be understood individually from the technical spirit or prospect of the present specification.

Various embodiments have been described in the best mode for carrying out the invention.

In the wireless communication system of the present invention, the data transmission and reception method has been described with reference to the example applied to the IEEE 802.11 system, but it is possible to apply to various wireless communication systems in addition to the IEEE 802.11 system.

Claims (18)

1. In a wireless LAN (WLAN) system, a method of transmitting a physical protocol data unit (PPDU) of a STA (Station) device,

   Generating a High Efficiency-Short Training Field (HE-STF) sequence;

   Generating a PPDU including a HE-STF field configured based on the HE-STF sequence; And

   Transmitting the PPDU, wherein the HE-STF field included in the PPDU is transmitted using a frequency resource unit; Including,

   The HE-STF sequence is mapped to tones included in the frequency resource unit,

   A predetermined value among 1 + j, 1-j, -1 + j, and -1-j values is mapped to specific tones having a predetermined index among the tones to which the HE-STF sequence is mapped. How to send PPDU.
2. The method of claim 1,

   When the frequency resource unit is a 26 tone resource unit composed of 26 tones, the 26 tones sequentially have an index of 1 to 26,

   The HE-STF sequence is mapped to the 26 tones.
3. The method of claim 2,

   The predefined value is mapped to three specific tones of the 26 tones to which the HE-STF sequence is mapped,

   The predetermined indexes of the three specific tones are (3,11,19), (4,12,20), (5,13,21), (6,14,22), (7,15,23) Or, (8,16,24).
4. The method of claim 3, wherein

   In each of the three specific tones,

   {1 + j, 1 + j, -1-j}, {1 + j, 1-j, 1 + j}, {1 + j, -1 + j, 1 + j}, {1 + j,- 1-j, -1-j}, {1-j, 1 + j, 1-j}, {1-j, 1-j, -1 + j}, {1-j, -1 + j,- 1 + j}, {1-j, -1-j, 1-j}, {-1 + j, 1 + j, -1 + j}, {-1 + j, 1-j, 1-j} , {-1 + j, -1 + j, 1-j}, {-1 + j, -1-j, -1 + j}, {-1-j, 1 + j, 1 + j}, { -1-j, 1-j, -1-j}, {-1-j, -1 + j, -1-j}, or {-1-j, -1-j, 1 + j} PPDU transmission method mapped sequentially.
5. The method of claim 2,

   The predefined value is mapped to four specific tones of the 26 tones to which the HE-STF sequence is mapped,

   And the predetermined index of the four specific tones is (1,9,17,25) or (2,10,18,26).
6. The method of claim 5, wherein

   In each of the four specific tones,

   {1 + j, 1 + j, 1 + j, -1-j}, {1 + j, 1 + j, -1-j, 1 + j}, {1 + j, 1-j, 1 + j , -1 + j}, {1 + j, 1-j, -1-j, 1-j}, {1 + j, -1 + j, 1 + j, 1-j}, {1 + j, -1 + j, -1-j, -1 + j}, {1 + j, -1-j, 1 + j, 1 + j}, {1 + j, -1-j, -1-j, -1-j}, {1-j, 1 + j, 1-j, -1-j}, {1-j, 1 + j, -1 + j, 1 + j}, {1-j, 1 -j, 1-j, -1 + j}, {1-j, 1-j, -1 + j, 1-j}, {1-j, -1 + j, 1-j, 1-j} , {1-j, -1 + j, -1 + j, -1 + j}, {1-j, -1-j, 1-j, 1 + j}, {1-j, -1-j , -1 + j, -1-j}, {-1 + j, 1 + j, 1-j, 1 + j}, {-1 + j, 1 + j, -1 + j, -1-j }, {-1 + j, 1-j, 1-j, 1-j}, {-1 + j, 1-j, -1 + j, -1 + j}, {-1 + j, -1 + j, 1-j, -1 + j}, {-1 + j, -1 + j, -1 + j, 1-j}, {-1 + j, -1-j, 1-j,- 1-j}, {-1 + j, -1-j, -1 + j, 1 + j}, {-1-j, 1 + j, 1 + j, 1 + j}, {-1-j , 1 + j, -1-j, -1-j}, {-1-j, 1-j, 1 + j, 1-j}, {-1-j, 1-j, -1-j, -1 + j}, {-1-j, -1 + j, 1 + j, -1 + j}, {-1-j, -1 + j, -1-j, 1-j}, {- 1-j, -1-j, 1 + j, -1-j}, or {-1-j, -1-j, -1-j, 1 + j} values mapped sequentially .
7. The method of claim 1,

   When the frequency resource unit is a 52 tone resource unit composed of 52 tones, the 52 tones sequentially have an index of 1 to 52,

   The HE-STF sequence is mapped to the 52 tones.
8. The method of claim 7, wherein

   The predefined value is mapped to six specific tones of the 52 tones to which the HE-STF sequence is mapped,

   The preset indices of the six specific tones are (5, 13, 21, 29, 37, 45), (6, 14, 22, 30, 38, 46), (7, 15, 23, 31, 39, 47), or (8,16,24,32,40,48).
9. The method of claim 8,

   In each of the six specific tones,

   {1 + j, 1 + j, 1-j, 1 + j, 1-j, -1 + j}, {1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1-j}, {1 + j, 1-j, 1-j, -1 + j, -1 + j, -1-j}, {1 + j, 1-j, -1 + j, -1 + j, 1-j, 1 + j}, {1 + j, -1 + j, 1-j, 1-j, -1 + j, 1 + j}, {1 + j, -1 + j, -1 + j, 1-j, 1-j, -1-j}, {1 + j, -1-j, 1-j, -1-j, 1-j, 1-j}, {1+ j, -1-j, -1 + j, -1-j, -1 + j, -1 + j}, {1-j, 1 + j, 1 + j, -1-j, -1-j , -1 + j}, {1-j, 1 + j, -1-j, -1-j, 1 + j, 1-j}, {1-j, 1-j, 1 + j, 1- j, 1 + j, -1-j}, {1-j, 1-j, -1-j, 1-j, -1-j, 1 + j}, {1-j, -1 + j, 1 + j, -1 + j, 1 + j, 1 + j}, {1-j, -1 + j, -1-j, -1 + j, -1-j, -1-j}, { 1-j, -1-j, 1 + j, 1 + j, -1-j, 1-j}, {1-j, -1-j, -1-j, 1 + j, 1 + j, -1 + j}, {-1 + j, 1 + j, 1 + j, -1-j, -1-j, 1-j}, {-1 + j, 1 + j, -1-j, -1-j, 1 + j, -1 + j}, {-1 + j, 1-j, 1 + j, 1-j, 1 + j, 1 + j}, {-1 + j, 1- j, -1-j, 1-j, -1-j, -1-j}, {-1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1-j }, {-1 + j, -1 + j, -1-j, -1 + j, -1-j, 1 + j}, {-1 + j, -1-j, 1 + j, 1+ j, -1-j, -1 + j}, {-1 + j, -1-j, -1-j, 1 + j, 1 + j, 1-j}, {-1-j, 1+ j, 1-j, 1 + j, 1-j, 1-j}, {-1-j, 1 + j, -1 + j, 1 + j, -1 + j, -1 + j}, { -1-j, 1-j, 1-j, -1 + j, -1 + j, 1 + j}, {-1-j, 1-j, -1 + j, -1 + j, 1- j, -1-j}, {-1-j, -1 + j, 1-j, 1-j,- 1 + j, -1-j}, {-1-j, -1 + j, -1 + j, 1-j, 1-j, 1 + j}, {-1-j, -1-j, 1-j, -1-j, 1-j, -1 + j}, or {-1-j, -1-j, -1 + j, -1-j, -1 + j, 1-j} A method of transmitting a PPDU, in which values are mapped sequentially.
10. The method of claim 7, wherein

    The predefined value is mapped to seven specific tones of the 52 tones to which the HE-STF sequence is mapped,

    The preset indices of the seven specific tones are (1,9,17,25,33,41,49), (2,10,18,26,34,42,50), (3,11,19, 27,35,43,51), or (4,12,20,28,36,44,52).
11. The method of claim 10,

    In each of the seven specific tones,

    {1 + j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, -1-j}, {1 + j, 1-j, -1-j, 1-j , -1-j, 1-j, 1 + j}, {1 + j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, 1 + j}, {1 + j, -1-j, 1 + j, 1 + j, -1-j, -1-j, -1-j}, {1-j, 1 + j, -1 + j, 1+ j, -1 + j, 1 + j, 1-j}, {1-j, 1-j, 1-j, -1 + j, -1 + j, 1-j, -1 + j}, { 1-j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, -1 + j}, {1-j, -1-j, -1 + j, -1 -j, -1 + j, -1-j, 1-j}, {-1 + j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, -1 + j}, {-1 + j, 1-j, -1 + j, -1 + j, 1-j, 1-j, 1-j}, {-1 + j, -1 + j, -1 + j, 1 -j, 1-j, -1 + j, 1-j}, {-1 + j, -1-j, 1-j, -1-j, 1-j, -1-j, -1 + j }, {-1-j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, 1 + j}, {-1-j, 1-j, 1 + j, 1 -j, 1 + j, 1-j, -1-j}, {-1-j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j }, Or {-1-j, -1-j, -1-j, 1 + j, 1 + j, -1-j, 1 + j} values are mapped sequentially.
12. The method of claim 1,

    When the frequency resource unit is a 106 tone resource unit composed of 106 tones, the 106 tones sequentially have an index of 1 to 106,

    The HE-STF sequence is mapped to the 106 tones.
13. The method of claim 12,

    The predefined value is mapped to 13 specific tones of the 106 tones to which the HE-STF sequence is mapped,

    The preset indices of the 13 specific tones are (3,11,19,27,35,43,51,59,67,75,83,91,99), (4,12,20,28,36, 44,52,60,68,76,84,92,100), (5,13,21,29,37,45,53,61,69,77,85,93,101), (6,14,22,30, 38,46,54,62,70,78,86,94,102), (7,15,23,31,39,47,55,63,71,79,87,95,103), or (8,16,24 And, 32,40,48,56,64,72,80,88,96,104.
14. The method of claim 13,

    In each of the 13 specific tones,

    {1 + j, 1 + j, 1 + j, -1-j, -1-j, -1-j, 1 + j, 1 + j, -1-j, 1 + j, 1 + j, − 1-j, 1 + j}, {1 + j, 1-j, -1-j, 1-j, -1-j, -1 + j, -1-j, -1 + j, -1- j, 1-j, -1-j, 1-j, 1 + j}, {1 + j, -1 + j, -1-j, -1 + j, -1-j, 1-j, − 1-j, 1-j, -1-j, -1 + j, -1-j, -1 + j, 1 + j}, {1 + j, -1-j, 1 + j, 1 + j , -1-j, 1 + j, 1 + j, -1-j, -1-j, -1-j, 1 + j, 1 + j, 1 + j}, {1-j, 1 + j , -1 + j, 1 + j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, 1 + j, -1 + j, 1 + j, 1- j}, {1-j, 1-j, 1-j, -1 + j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, 1-j, 1- j, -1 + j, 1-j}, {1-j, -1 + j, 1-j, 1-j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, -1 + j, 1-j, 1-j, 1-j}, {1-j, -1-j, -1 + j, -1-j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j, -1 + j, -1-j, 1-j}, {-1 + j, 1 + j, 1-j, 1+ j, 1-j, -1-j, 1-j, -1-j, 1-j, 1 + j, 1-j, 1 + j, -1 + j}, {-1 + j, 1- j, -1 + j, -1 + j, 1-j, -1 + j, -1 + j, 1-j, 1-j, 1-j, -1 + j, -1 + j, -1 + j}, {-1 + j, -1 + j, -1 + j, 1-j, 1-j, 1-j, -1 + j, -1 + j, 1-j, -1 + j , -1 + j, 1-j, -1 + j}, {-1 + j, -1-j, 1-j, -1-j, 1-j, 1 + j, 1-j, 1+ j, 1-j, -1-j, 1-j, -1-j, -1 + j}, {-1-j, 1 + j, -1-j, -1-j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, 1 + j, -1-j, -1-j, -1-j}, {-1-j, 1-j, 1+ j, 1-j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, 1-j, 1 + j, 1-j, -1-j}, {-1-j, -1 + j, 1 + j,- 1 + j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j}, or {-1-j , -1-j, -1-j, 1 + j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, -1-j, -1-j, 1 + j , -1-j} values are mapped sequentially.
15. The method of claim 12,

    The predefined value is mapped to 14 specific tones of the 106 tones to which the HE-STF sequence is mapped,

    The 14 specific tones are the preset indices (1,9,17,25,33,41,49,57,65,73,81,89,97,105), or (2,10,18,26,34). And, (42,50,58,66,74,82,90,98,106).
16. The method of claim 15,

    In each of the 14 specific tones,

    {1 + j, 1 + j, 1 + j, 1 + j, -1-j, 1 + j, -1-j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j}, {1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, -1-j, -1-j, -1-j, 1 + j, -1-j, 1 + j}, {1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j, -1-j, -1 + j, 1 + j, -1 + j, -1-j, 1-j}, {1 + j, 1-j, -1-j, -1 + j, -1-j, 1-j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j}, {1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, -1 + j, -1-j, 1- j, 1 + j, 1-j, -1-j, -1 + j}, {1 + j, -1 + j, -1-j, 1-j, -1-j, -1 + j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j}, {1 + j, -1-j, 1 + j, -1- j, -1-j, -1-j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j}, { 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, -1-j, 1 + j, -1-j, -1-j, -1-j, -1-j}, {1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, − 1 + j, -1-j, 1-j, -1-j, -1 + j, 1 + j}, {1-j, 1 + j, -1 + j, -1-j, -1+ j, 1 + j, 1-j, -1-j, 1-j, -1-j, 1-j, -1-j, 1-j, -1-j}, {1-j, 1- j, 1-j, 1-j, -1 + j, 1-j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j}, {1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, -1 + j, -1 + j, -1 + j, 1-j, -1 + j, 1-j}, {1-j, -1 + j, 1-j, -1 + j, -1 + j, -1 + j , -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j}, {1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, 1-j, -1 + j, 1-j, -1 + j, -1 + j, -1 + j, -1 + j}, {1-j,- 1-j, 1-j, -1-j, 1-j, -1-j, 1-j, -1-j, -1 + j, 1 + j, 1-j, 1 + j, -1 + j, -1-j}, {1-j, -1-j, -1 + j, 1 + j, -1 + j, -1-j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j, 1-j, 1 + j}, {-1 + j, 1 + j, 1-j, -1-j, 1-j, 1 + j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j}, {-1 + j, 1 + j,- 1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j, 1-j, -1-j, -1 + j, -1-j, 1-j, 1 + j}, {-1 + j, 1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, 1-j, -1 + j, 1-j, 1-j, 1-j, 1-j}, {-1 + j, 1-j, -1 + j, 1-j, 1-j, 1-j, 1-j, 1- j, -1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j}, {-1 + j, -1 + j, 1-j, 1-j, -1 + j, -1 + j, 1-j, 1-j, 1-j, 1-j, 1-j, -1 + j, 1-j, -1 + j}, {-1 + j , -1 + j, -1 + j, -1 + j, 1-j, -1 + j, 1-j, -1 + j, -1 + j, 1-j, 1-j, -1+ j, -1 + j, 1-j}, {-1 + j, -1-j, 1-j, 1 + j, 1-j, -1-j, -1 + j, 1 + j,- 1 + j, 1 + j, -1 + j, 1 + j, -1 + j, 1 + j}, {-1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, 1-j, 1 + j, -1 + j, 1 + j, 1-j, -1-j}, {-1-j , 1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, 1 + j, -1-j, 1 + j, 1 + j, 1 + j, 1 + j}, {-1-j , 1 + j, -1-j, 1 + j, 1 + j, 1 + j, 1 + j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1 -j, -1-j}, {-1-j, 1-j, 1 + j, -1 + j, 1 + j, 1-j, -1-j, -1 + j, -1-j , -1 + j, -1-j, -1 + j, -1-j, -1 + j}, {-1-j, 1-j, -1-j, 1-j, -1-j , 1-j, -1-j, 1-j, 1 + j, -1 + j, -1-j, -1 + j, 1 + j, 1-j}, {-1-j, -1 + j, 1 + j, 1-j, 1 + j, -1 + j, -1-j, 1-j, -1-j, 1-j, -1-j, 1-j, -1- j, 1-j}, {-1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, -1-j, -1 + j, 1+ j, 1-j, -1-j, 1-j, 1 + j, -1 + j}, {-1-j, -1-j, 1 + j, 1 + j, -1-j, − 1-j, 1 + j, 1 + j, 1 + j, 1 + j, 1 + j, -1-j, 1 + j, -1-j}, or {-1-j, -1-j , -1-j, -1-j, 1 + j, -1-j, 1 + j, -1-j, -1-j, 1 + j, 1 + j, -1-j, -1- j, 1 + j} Values are mapped sequentially.
17. The method of claim 1,

    Wherein the HE-STF field has a period of 1.6 ms.
18. In the STA (Station) device in a wireless LAN (WLAN) system,

    An RF unit for transmitting and receiving radio signals; And

    A processor controlling the RF unit; Including,

    The processor,

    Generate a High Efficiency-Short Training Field (HE-STF) sequence,

    Generate a PPDU including a HE-STF field configured based on the HE-STF sequence,

    The PPDU is transmitted, but the HE-STF field included in the PPDU is transmitted using a frequency resource unit.

    The HE-STF sequence is mapped to tones included in the frequency resource unit,

    A predetermined value among 1 + j, 1-j, -1 + j, and -1-j values is mapped to specific tones having a predetermined index among the tones to which the HE-STF sequence is mapped. STA device.

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