Contents

IEEE 802.11be

Adopted

Maximum
link rate
(Mb/s)

Radio
frequency
(GHz)

802.11bn

expected 2028^[1]

100 000^[2]

2.4, 5, 6^[3]

802.11be

expected 2024

0.4–23 059

2.4, 5, 6^[4]

802.11ax

2021

0.4–9608^[5]

2.4, 5, 6^[a]

2.4, 5

802.11ac

2013

6.5–6933

5^[b]

802.11n

2009

6.5–600

2.4, 5

802.11g

2003

6–54

2.4

802.11a

1999

5

802.11b

1999

1–11

2.4

802.11

1997

1–2

2.4

IEEE 802.11be, dubbed Extremely High Throughput (EHT), is a wireless networking standard in the IEEE 802.11 set of protocols,^[9][10] which is designated Wi-Fi 7byWi-Fi Alliance.^[11][12][13] It has built upon 802.11ax, focusing on WLAN indoor and outdoor operation with stationary and pedestrian speeds in the 2.4, 5, and 6 GHz frequency bands.^[14]

Throughput is believed to reach a theoretical maximum of 46 Gbit/s, although actual results are much lower.^[15]

Development of the 802.11be amendment is ongoing, with an initial draft in March 2021, and a final version expected by the end of 2024.^[12][16][17] Despite this, numerous products were announced in 2022 based on draft standards, with retail availability in early 2023. On 8 January 2024, the Wi-Fi Alliance introduced its "Wi-Fi Certified 7" program to certify Wi-Fi 7 devices. While final ratification is not expected until the end of 2024, the technical requirements are essentially complete,^[15] and there are already products labeling themselves as "Wi-Fi 7" as of February 2024.^[18][19][20]

The global Wi-Fi 7 market was estimated at US$1 billion in 2023, and is projected to reach US$24.2 billion by 2030.^[21]

Core features[edit]

The following are core features that have been approved as of Draft 3.0:

• 4096-QAM (4K-QAM) enables each symbol to carry 12 bits rather than 10 bits, resulting in 20% higher theoretical transmission rates than WiFi 6's 1024-QAM.
• Contiguous and non-contiguous 320/160+160 MHz and 240/160+80 MHz bandwidth
• Multi-Link Operation (MLO), a feature that increases capacity by simultaneously sending and receiving data across different frequency bands and channels. (2.4 GHz, 5 GHz, 6 GHz)^[22]
• Theoretically as little as 1% the latency of Wi‑Fi 6, through the use of MLO
• 16 spatial streams and Multiple Input Multiple Output (MIMO) protocol enhancements^[22]
• Flexible Channel Utilization – Interference currently can negate an entire Wi-Fi channel. With preamble puncturing, a portion of the channel that is affected by interference can be blocked off while continuing to use the rest of the channel.

Candidate features[edit]

The main candidate features mentioned in the 802.11be Project Authorization Request (PAR) are:^[23]

• Multi-Access Point (AP) Coordination (e.g. coordinated and joint transmission),
• Enhanced link adaptation and retransmission protocol (e.g. Hybrid Automatic Repeat Request (HARQ)),
• If needed, adaptation to regulatory rules specific to 6 GHz spectrum,
• Integrating Time-Sensitive Networking (TSN) IEEE 802.1Q extensions for low-latency real-time traffic:^[24][25][26]
  • IEEE 802.1AS timing and synchronisation
  • IEEE 802.11aa MAC Enhancements for Robust Audio Video Streaming (Stream Reservation Protocol over IEEE 802.11)
  • IEEE 802.11ak Enhancements for Transit Links Within Bridged Networks (802.11 links in 802.1Q networks)
  • Bounded latency: credit-based (IEEE 802.1Qav) and cyclic/time-aware traffic shaping (IEEE 802.1Qch/Qbv), asynchronous traffic scheduling (IEEE 802.1Qcr-2020)
  • IEEE 802.11ax Scheduled Operation extensions for reduced jitter/latency

Additional features[edit]

Apart from the features mentioned in the PAR, there are newly introduced features:^[27]

• Newly introduced 4096-QAM (4K-QAM),
• Contiguous and non-contiguous 320/160+160 MHz and 240/160+80 MHz bandwidth,
• Frame formats with improved forward-compatibility,
• Enhanced resource allocation in OFDMA,
• Optimized channel sounding that requires less airtime,
• Implicit channel sounding,
• More flexible preamble puncturing scheme,
• Support of direct links, managed by an access point.

Rate set[edit]

Modulation

type

Coding

rate

Data rate (Mbit/s)^[ii]

40 MHz channels

80 MHz channels

160 MHz channels

320 MHz channels

1600 ns GI

800 ns GI

3200 ns GI

1600 ns GI

800 ns GI

3200 ns GI

1600 ns GI

800 ns GI

3200 ns GI

1600 ns GI

800 ns GI

3200 ns GI

1600 ns GI

800 ns GI

BPSK

1/2

7

8

9

15

16

17

31

34

36

61

68

72

123

136

144

QPSK

1/2

15

16

17

29

33

34

61

68

72

122

136

144

245

272

288

QPSK

3/4

22

24

26

44

49

52

92

102

108

184

204

216

368

408

432

16-QAM

1/2

29

33

34

59

65

69

123

136

144

245

272

282

490

544

577

16-QAM

3/4

44

49

52

88

98

103

184

204

216

368

408

432

735

817

865

64-QAM

2/3

59

65

69

117

130

138

245

272

288

490

544

576

980

1089

1153

64-QAM

3/4

66

73

77

132

146

155

276

306

324

551

613

649

1103

1225

1297

64-QAM

5/6

73

81

86

146

163

172

306

340

360

613

681

721

1225

1361

1441

256-QAM

3/4

88

98

103

176

195

207

368

408

432

735

817

865

1470

1633

1729

256-QAM

5/6

98

108

115

195

217

229

408

453

480

817

907

961

1633

1815

1922

1024-QAM

3/4

110

122

129

219

244

258

459

510

540

919

1021

1081

1838

2042

2162

1024-QAM

5/6

122

135

143

244

271

287

510

567

600

1021

1134

1201

2042

2269

2402

4096-QAM

3/4

131

146

155

263

293

310

551

613

649

1103

1225

1297

2205

2450

2594

4096-QAM

5/6

146

163

172

293

325

344

613

681

721

1225

1361

1441

2450

2722

2882

BPSK-DCM-DUP

1/2

7

8

9

15

17

18

31

34

36

BPSK-DCM

1/2

4

4

4

7

8

9

15

17

18

31

34

36

61

68

72

Comparison[edit]

PHY

Protocol

Release
date ^[28]

Frequency

Bandwidth

Stream
data rate ^[29]

Allowable
MIMO streams

Modulation

Approximate
range

Outdoor

(MHz)

(Mbit/s)

DSSS^[30], FHSS^[A]

802.11-1997

June 1997

2.4

22

1, 2

—

DSSS, FHSS^[A]

20 m (66 ft)

100 m (330 ft)

802.11b

September 1999

2.4

22

1, 2, 5.5, 11

—

CCK, DSSS

35 m (115 ft)

140 m (460 ft)

802.11a

September 1999

5

5, 10, 20

6, 9, 12, 18, 24, 36, 48, 54
(for 20 MHz bandwidth,
divide by 2 and 4 for 10 and 5 MHz)

—

OFDM

35 m (115 ft)

120 m (390 ft)

November 2004

4.9, 5.0
^[B][31]

?

?

November 2008

3.7 ^[C]

?

5,000 m (16,000 ft)^[C]

July 2010

5.9

200 m

1,000 m (3,300 ft)^[32]

December 2022

5.9, 60

500 m

1,000 m (3,300 ft)

802.11g

June 2003

2.4

38 m (125 ft)

140 m (460 ft)

802.11n
(Wi-Fi 4)

October 2009

2.4, 5

20

Up to 288.8^[D]

4

MIMO-OFDM
(64-QAM)

70 m (230 ft)

250 m (820 ft)^[35]

Up to 600^[D]

802.11ac
(Wi-Fi 5)

December 2013

5

20

Up to 693^[D]

8

DL
MU-MIMO OFDM
(256-QAM)

35 m (115 ft)^[36]

?

Up to 1600^[D]

Up to 3467^[D]

Up to 6933^[D]

802.11ax
(Wi-Fi 6,
Wi-Fi 6E)

May 2021

2.4, 5, 6

20

Up to 1147^[E]

8

UL/DL
MU-MIMO OFDMA
(1024-QAM)

30 m (98 ft)

120 m (390 ft) ^[F]

Up to 2294^[E]

Up to 5.5 Gbit/s^[E]

Up to 11.0 Gbit/s^[E]

802.11be
(Wi-Fi 7)

Dec 2024
(est.)

2.4, 5, 6

80

Up to 11.5 Gbit/s^[E]

16

UL/DL
MU-MIMO OFDMA
(4096-QAM)

30 m (98 ft)

120 m (390 ft) ^[F]

Up to 23 Gbit/s^[E]

Up to 35 Gbit/s^[E]

Up to 46.1 Gbit/s^[E]

802.11bn
(Wi-Fi 8)

May 2028
(est.)

2.4, 5, 6,
42, 60, 71

320

Up to
100000
(100 Gbit/s)

16

Multi-link
MU-MIMO OFDM
(8192-QAM)

?

?

802.11ba

October 2021

2.4, 5

4, 20

0.0625, 0.25
(62.5 kbit/s, 250 kbit/s)

—

OOK (multi-carrier OOK)

?

?

DMG ^[37]

802.11ad

December 2012

60

2160
(2.16 GHz)

Up to 8085^[38]
(8 Gbit/s)

—

OFDM^[A], single carrier, low-power single carrier^[A]

3.3 m (11 ft)^[39]

?

April 2018

60^[H]

1080^[40]

Up to 3754
(3.75 Gbit/s)

—

single carrier, low-power single carrier^[A]

?

?

802.11aj

April 2018

45^[H]

540,
1080

Up to 15015^[41]
(15 Gbit/s)

4^[42]

OFDM, single carrier

?

?

802.11ay

July 2021

60

Up to 8640
(8.64 GHz)

Up to 303336^[44]
(303 Gbit/s)

8

OFDM, single carrier

10 m (33 ft)

100 m (328 ft)

TVHT ^[45]

802.11af

February 2014

0.054–
0.79

6, 7, 8

Up to 568.9^[46]

4

MIMO-OFDM

?

?

802.11ah

May 2017

0.7, 0.8,
0.9

1–16

Up to 8.67^[47]
(@2 MHz)

4

?

?

LC
(VLC/OWC)

802.11bb

December 2023
(est.)

800–1000 nm

20

Up to 9.6 Gbit/s

—

O-OFDM

?

?

802.11-1997

June 1997

850–900 nm

?

1, 2

—

PPM^[A]

?

?

802.11-2007 (802.11ma)

March 2007

2.4, 5

Up to 54

DSSS, OFDM

March 2012

2.4, 5

Up to 150^[D]

DSSS, OFDM

December 2016

2.4, 5, 60

Up to 866.7 or 6757^[D]

DSSS, OFDM

December 2020

2.4, 5, 60

Up to 866.7 or 6757^[D]

DSSS, OFDM

September 2024
(est.)

2.4, 5, 6, 60

Up to 9608 or 303336

DSSS, OFDM

802.11be Task Group[edit]

The 802.11be Task Group is led by individuals affiliated with Qualcomm, Intel, and Broadcom. Those affiliated with Huawei, Maxlinear, NXP, and Apple also have senior positions.^[17]

Commercial availability[edit]

Qualcomm announced its FastConnect 7800 series on 28 Feb 2022 using 14 nm chips.^[48][49] As of March 2023, the company claims 175 devices will be using their Wi-Fi 7 chips, including smartphones, routers, and access points.^[50]

Broadcom followed on 12 April 2022 with a series of 5 chips covering home, commercial, and enterprise uses.^[51] The company unveiled its second generation Wi-Fi 7 chips on 20 June 2023 featuring tri-band MLO support and lower costs.^[52]

The TP-Link Archer BE900 wireless router was available to consumers in April 2023.^[53] The company's Deco BE95 mesh networking system was also available that month. Later in the year, Asus, Eero, Linksys and Netgear had Wi-fi 7 wireless routers available by the end of 2023.

The ARRIS SURFboard G54 is a DOCSIS 3.1 cable gateway featuring Wi-Fi 7. It became available in October 2023.

Client devices[edit]

Chipset

Notes

OnePlus 11

February 2023

Snapdragon 8 Gen 2^[54]

The OnePlus Open also features Wi-Fi 7 support

ROG Phone 7

April 2023

Snapdragon 8 Gen 2

Legion Slim 7 Gen8 laptop

MediaTek Filogic 380 Wi-Fi 7 card^[55]

Pixel 8 and Pixel 8 Pro^[56]

October 2023

Intel launched the BE200 and BE202 wireless adapters for desktop and laptop motherboards in September 2023.^[57]

The Asus ROG Strix Z790 E II motherboard is among the first with built-in Wi-Fi 7.^[58]

Software[edit]

Android 13 and higher provide support for Wi-Fi 7.^[59]

The Linux 6.2 kernel provides support for Wi-Fi 7 devices.^[60] The 6.4 kernel added Wi-Fi 7 mesh support.^[61] Linux 6.5 included significant driver support by Intel engineers, particularly support for MLO.^[62]

Support for Wi-Fi 7 was added to Windows 11, as of build 26063.1.^[63][64]

Notes[edit]

References[edit]