Wi-Fi 7 Technology Introduction
In the recent MediaTek Technology Summit, MediaTek teased that it will demonstrate the next-generation Wi-Fi network technology, Wi-Fi 7, at CES2022. MediaTek introduced Wi-Fi 7, which is 2.4 times faster than Wi-Fi 6E, bringing faster speeds, lower latency, and better anti-interference capabilities.
Wi-Fi 7 is said to bring significant improvements over Wi-Fi 6E. One is in terms of speed. If you use the same number of antennas on a Wi-Fi 7 product as you do on Wi-Fi 6E, the speed will be 2.4 times faster.
The official also explained that this new standard will also greatly reduce latency, which will help applications where every millisecond counts, such as gaming. Intriguingly, he said Wi-Fi 7 will be “friendly” with your neighbor’s Wi-Fi 7 network, using new technology to reduce signal interference from outside your home.
Chen also noted, however, that the Wi-Fi Alliance is still “in the early stages of the Wi-Fi 7 standardization process,” and he couldn’t say exactly when the Wi-Fi 7 standard will be finalized, but he said that while the standard is “still evolving,” the Wi-Fi 7 standard is expected to be “released in the second quarter of 2022”. Based on this timeline, the technology is expected to be available in 2023.
According to Huawei’s official website news, the new generation of WiFi 7 is about to debut in 2022 to release the standard. Many people may not know that Huawei is the company with the most Wi-Fi 7 technology holdings in the world, having surpassed Qualcomm and Intel.
Huawei’s contribution to Wi-Fi 7 is not only here, according to Huawei’s official website about WiFi 7, but Huawei also continues to expand more WiFi 7 related technologies, compared to WiFi 6, the new WiFi 7 channel bandwidth up to 320MHz, the maximum transmission rate of up to 30Gbps.
WiFi 7 (Wi-Fi 7) is the next-generation Wi-Fi standard to be launched, also known as IEEE 802.11be — extremely high throughput (EHT). Based on Wi-Fi 6, Wi-Fi 7 introduces technologies such as 320 MHz bandwidth, 4096-quadrature amplitude modulation (QAM), multi-resource unit (RU), multi-link operation (MLO), enhanced multi-user multiple-input multiple-output (MU-MIMO), and multi-access point (AP) coordination. Drawing on these cutting-edge technologies, Wi-Fi 7 delivers a higher data transmission rate and lower latency than Wi-Fi 6. Wi-Fi 7 is expected to support a throughput of up to 30 Gbps, about three times that of Wi-Fi 6.Huawei
Below is Huawei’s official answers regarding Wi-Fi 7:
Why Do We Need Wi-Fi 7?
With the development of WLAN technologies, homes and enterprises rely more and more on Wi-Fi for network access. In recent years, emerging applications have had higher requirements on throughput and latency. Typical examples of these applications include 4K and 8K videos (involving a transmission rate of up to 20 Gbps), virtual reality (VR)/augmented reality (AR), online gaming (requiring latency of less than 5 ms), remote office, online video conferencing, and cloud computing. Facing such high requirements, Wi-Fi 6 — currently the latest Wi-Fi standard — is insufficient despite its dedication to improving user experience in high-density scenarios. As such, the IEEE is about to release a new amendment entitled IEEE 802.11be EHT, also known as Wi-Fi 7.
Wi-Fi 7 Release Time
The IEEE 802.11be Task Group (TGbe) was formally established in May 2019, which is working on the development of 802.11be (Wi-Fi 7). The standard will be available in Release 1 and Release 2. The TGbe plans to release Draft 1.0 of 802.11be in 2021, and Release 1 will be available by the end of 2022. Release 2 is expected to be initiated at the beginning of 2022 and will be released at the end of 2024.
Wi-Fi 7 vs. Wi-Fi 6
Based on the Wi-Fi 6 standard, Wi-Fi 7 introduces a plurality of new technologies. The following compares Wi-Fi 6 and Wi-Fi 7.
New Features in Wi-Fi 7
Wi-Fi 7 aims to increase the WLAN throughput to 30 Gbps and provide low-latency access assurance. To achieve this goal, the standard defines modifications to both the physical layer (PHY) and MAC layer. Compared with Wi-Fi 6, Wi-Fi 7 brings the following technical innovations:
- Up to 320 MHz Bandwidth: The 2.4 GHz and 5 GHz frequency bands are unlicensed spectrums that limited and congested. When running emerging applications (such as VR/AR), existing Wi-Fi networks inevitably encounter a low quality of service (QoS). To achieve a maximum of 30 Gbps throughput, Wi-Fi 7 will support the 6 GHz of frequency band and extend new bandwidth modes, including contiguous 240 MHz, non-contiguous 160+80 MHz, contiguous 320 MHz, and non-contiguous 160+160 MHz.
- Multi-RU: In Wi-Fi 6, each user can send or receive frames only on the RUs allocated to them, which greatly limits the flexibility of spectrum resource scheduling. To resolve this problem and further improve spectrum efficiency, Wi-Fi 7 defines a mechanism for allocating multiple RUs to a single user. To balance the implementation complexity and spectrum utilization, the standard specifications impose certain restrictions on the RU combination. That is, small RUs (containing fewer than 242 tones) can be combined only with small RUs, and large RUs (containing greater than or equal to 242 tones) can be combined only with large RUs. Small RUs and large RUs can be combined.
- Higher-Order 4096-QAM: The highest-order modulation supported by Wi-Fi 6 is 1024-QAM, which allows each modulation symbol to carry up to 10 bits. To further improve the rate, Wi-Fi 7 introduces 4096-QAM so that each modulation symbol can carry 12 bits. With the same coding, 4096-QAM in Wi-Fi 7 can achieve a 20% rate increase compared with 1024-QAM in Wi-Fi 6.
- Multi-Link Mechanism: To efficiently utilize all available spectrum resources, the industry is in urgent need to introduce new spectrum management, coordination, and transmission mechanisms on the 2.4 GHz, 5 GHz, and 6 GHz frequency bands. The TGbe defines multi-link aggregation technologies, including the MAC architecture of enhanced multi-link aggregation, multi-link channel access, and multi-link transmission.
- More Data Streams and Enhanced MIMO: Wi-Fi 7 increases the number of spatial streams from 8 to 16, increasing the theoretical physical transmission rate by more than twice that of Wi-Fi 6. With more data streams, Wi-Fi 7 supports distributed MIMO. That is, 16 data streams can be provided by multiple access points at the same time, meaning that multiple APs need to coordinate with each other.
- Multi-AP Coordination: In the current 802.11 protocol framework, there is not much coordination between APs. Common WLAN functions, such as automatic radio calibration and smart roaming, are vendor-defined features. Multi-AP coordination aims to optimize channel selection and adjust loads between APs to achieve efficient utilization and balanced allocation of radio resources. Coordinated scheduling between multiple APs in Wi-Fi 7 involves inter-cell coordinated planning in the time and frequency domains, inter-cell interference coordination, and distributed MIMO. This reduces interference between APs and greatly improves the utilization of air interface resources. Multi-AP coordination can be implemented in various methods, such as coordinated orthogonal frequency division multiple access (C-OFDMA), coordinated spatial reuse (CSR), coordinated beamforming (CBF), and joint transmission (JXT).
Wi-Fi 7 Application Scenarios
New functions introduced by Wi-Fi 7 will significantly improve the data transmission rate and deliver lower latency. These highlights will contribute to the development of emerging applications:
- Video stream
- Video/Voice conference
- Online gaming
- Real-time collaboration
- Cloud/Edge computing
- Industrial IoT
- Immersive AR/VR
- Interactive telemedicine