Millimeter wave: What industry opportunities does Huawei pre-research on the main direction of 6G bring?

The core technology of 5G and 6G-millimeter wave

Compared with the previous 4G communication, 5G communication has many advantages, and the most intuitive one is undoubtedly “high-rate transmission.” It is known that the transmission speed of 5G will increase by 10 times or even 100 times that of 4G, and the theoretical download speed of 6G will be expected to reach 100 times that of 5G, which is 1TB per second! From 4G to 5G to 6G, why can the transmission speed be increased by a hundredfold? A key technology is involved behind this: millimeter wave (mmWave).

In the decades since the development of mobile communications, the most commonly used frequency band is Frequency range 1 (FR1) below 6GHz, the frequency range is 450MHz to 6GHz, commonly known as centimeter wave. Until the comprehensive coverage of 5G networks, people put forward higher requirements for bandwidth, and the communication frequency band will inevitably extend in the direction of “high-speed transmission”. According to the 3GPP agreement, 5G NR supports two major frequency bands: one is FR1 below 6GHz, and the other is Frequency range 2 (FR2) in the frequency range of 24.25GHz to 52.6GHz. Because the FR2 wavelength has been reduced to the millimeter level, it is called the millimeter wave band.

Compared with the frequency bands below 6GHz, the millimeter wave frequency band has abundant spectrum resources and has a huge advantage in carrier bandwidth. It can achieve large bandwidth transmissions of 400MHz and 800MHz. Through co-construction and sharing between different operators, ultra-high rate data transmission. At the same time, the millimeter-wave wavelength is short and the required component size is small, which facilitates the integration and miniaturization of equipment products and meets the mainstream needs of the current terminal market. Therefore, starting in 2019, millimeter wave technology has gradually taken the center stage of the civilian market, assuming the important task of providing better quality networks.

Global centimeter wave and millimeter wave band deployment

Image source: Qorvo official website

In fact, millimeter wave communication technology was mainly used in the military industry in the past. It was a special radar technology that used short-wavelength electromagnetic waves. Thanks to the rapid iteration of 5G and 6G communications, millimeter waves have been able to open up the civilian market and become a major development direction of the global communications industry. At the beginning of 2019, millimeter wave-related product and policy information was spread frequently, and technological progress exceeded expectations. Even Ren Zhengfei, the founder of Huawei, was a “platform” for the technology. He once publicly stated: “Huawei’s success in 5G technology is due to the centimeter wave; the 6G millimeter wave is the general direction!”

It is worth mentioning that Huawei’s deployment of millimeter wave technology was earlier. During the 3rd Tokyo Bay Global 5G Summit in June 2017, Huawei and NTT DOCOMO completed the 39GHz high-frequency technology test based on the 3GPP 5G new air interface for the first time, realizing three-party real-time 4K HD video conferencing. In February 2018, Huawei and Canadian operator Telus tested a 28GHz system in Vancouver to provide fixed wireless broadband access services. In October of the same year, Huawei opened the world’s first 3GPP-based 5G millimeter wave commercial Firstcall, which marked the maturity of the 3GPP-based 5G millimeter wave network and related industry chains, and China’s 5G millimeter wave applications began to set sail. In August 2019, Huawei demonstrated the use of the folding screen mobile phone HUAWEI Mate X to communicate with the base station through millimeter wave technology to play 4K high-definition video online. It is the world’s first mobile phone with a folding screen to open up 5G millimeter wave end-to-end communication in a real network environment. factory.

Coming to mid-2020, good news about the 6G millimeter wave layout is coming. Recently, Yang Tao, vice president of Huawei’s China Operator Business Department, publicly disclosed that Huawei is already participating in 6G-related pre-research work. It has pre-researched 6G mainly using millimeter wave bands, and is in the stage of scene mining and technology search. According to Huawei’s estimates, there will be some 6G usage in 2030, and Huawei is currently actively participating in this area.

However, there are still many bottlenecks in the current 5G millimeter wave technology layout, requiring leading communications companies to lead their local supply chains to break through. For example, the landing application of millimeter wave technology still faces many urgent problems and technical challenges such as spectrum planning, domestic high-frequency device industry capabilities, and system testing solutions. These are all technical bottlenecks that the millimeter wave industry must overcome.

Many countries are betting on millimeter waves, and the competitive landscape has basically taken shape

5G commercialization will usher in a peak in 2020, and 6G pre-research has also been put on the agenda, and the upstream and downstream industry chain companies that deploy millimeter wave technology in advance may usher in opportunities.

Judging from the current 5G millimeter wave pattern, the United States, South Korea, Japan and other countries have successively completed the division and auction of 5G millimeter wave spectrum. The prospects for 5G commercial deployment are clear and the industrial chain is relatively concentrated. In the early stage of their millimeter wave deployment, most countries focused their attention on the two frequency bands of 26GHz and 28GHz, and the resources invested in these two frequency bands are also the most.

At the same time, multiple operators, including Verizon and T-Mobile in the United States, NTT in Japan, and KT in South Korea, have begun testing and applying millimeter wave 5G systems in the country, and have made positive progress. For example, in January 2018, T-Mobile, Nokia and Intel in the United States also tested 28GHz high-frequency systems in Washington, mainly using high-frequency communications to provide users with fixed wireless broadband access services; another example is Korea Telecom in February 2018 ( KT) Implemented 28GHz 5G network applications at the Pyeongchang East Olympics, using the North American operator’s V5G system, etc.

As for China, the communications industry has also begun to consider 5G millimeter wave deployment and application issues from the perspective of system applications. Last year, China Mobile revealed that it has completed the verification of 5G millimeter wave key technologies and plans to realize the commercial deployment of 5G millimeter wave in 2020. But frankly speaking, the relevant domestic research is still relatively scattered, and a clear 5G millimeter wave mobile communication system application direction and deployment plan have not yet been formed. The resistance mainly comes from three aspects:

1. China’s millimeter wave spectrum plan is not yet clear, and the government needs to clarify the millimeter wave spectrum plan as soon as possible to accelerate the development of the millimeter wave industry chain.

2. The maturity of my country’s 5G millimeter wave industry chain lags behind 5G low-frequency, and also lags behind the international advanced levels of the United States and Europe. It is manifested in the single form of millimeter wave equipment, the functions and performances still do not meet the needs of 5G networking, and the small number of 5G millimeter wave chips and terminal models, and the insufficient coverage and form of two aspects. Among them, the hindering factors mainly come from high-frequency devices, including: high-speed and high-precision digital-to-analog and analog-to-digital conversion chips, high-frequency power amplifiers, low-noise amplifiers, filters, integrated package antennas, and so on.

3. There is a shortage of low-cost, high-reliability packaging and testing technologies. Traditional mobile communication radio frequency testing is based on conduction testing, while 5G millimeter wave testing can only use the OTA test method in a darkroom environment. At present, the cost of test site, test efficiency, and test accuracy are all issues that need to be considered for OTA test programs and solutions are given.

Although the overall industry started late, China’s 5G millimeter wave industry is gradually catching up and is expected to open up a huge incremental market. At the end of last year, the industry consulting company TMG predicted that the economic benefits of using millimeter wave frequency bands in China will have an effect of approximately US$104 billion by 2034, accounting for approximately the estimated contribution of millimeter wave frequency bands in the Asia-Pacific region (estimated to reach 2,120 Billion dollars).

In terms of specific vertical industries, manufacturing and utilities such as water and electricity have the largest contribution, accounting for 62% of the total contribution; followed by professional services and financial services, accounting for 12%; information communication and trade, accounting for 10%; and then It is agriculture and mining, and finally public services. In the long run, as the use of 5G millimeter waves continues to grow, this economic advantage, coupled with the many potential industrial applications of 5G millimeter waves, will contribute to the significant impact of vertical industries on GDP.

In this regard, it is imminent to promote the localization of the millimeter wave industry. Some industry players said that the mobile communication industry urgently needs operators to issue clear signals, put forward the overall needs of the 5G millimeter wave new air interface system, clarify the development plan of equipment and terminals, promote the maturity of the millimeter wave industry chain, and prepare for future deployment .

Inventory: 5G millimeter wave industry chain

From the perspective of the industry chain, the millimeter wave industry chain is composed of equipment manufacturers, chip manufacturers, terminal manufacturers, antenna manufacturers, and vertical industries. The following table lists some representative companies:

1. Millimeter wave equipment

From a technical point of view, the millimeter-wave baseband part has the same maturity as 5G low-band equipment, but the radio-frequency-related functions and performance are far behind 5G low-band equipment. In terms of main equipment, since North America, Japan and South Korea have already begun to deploy millimeter wave systems, the frequency bands for manufacturers’ equipment are mainly North America, Japan and South Korea. The device can support basic functions, but some functions such as beam management and mobility need to be further improved. Representative companies are: Ericsson, Nokia, ZTE and other manufacturers.

From the data point of view, in terms of bandwidth and peak rate, millimeter wave equipment should support 200MHz, 400MHz single carrier capability, multi-carrier aggregation, and a total bandwidth of 800MHz. Millimeter wave equipment should support 64QAM and 256QAM modulation methods, and the peak transmission rate of the system should reach more than 10Gbps.

In addition, equipment needs to provide flexible deployment capabilities. Compared with sub 6G equipment, the size of millimeter wave components is smaller, and more antenna elements can be deployed per unit area or millimeter equipment is easier to miniaturize. The equipment needs to be optimally designed to reduce the size of the micro-station and micro-AAU unit equipment, beautify the design to facilitate concealed deployment, and provide a variety of power supply schemes and return schemes.

2. Chip

As for chips, although major chip manufacturers around the world have released 5G millimeter wave related products, the progress is generally behind the equipment, mainly in the R&D and testing stages, and actual commercialization is still in progress.

According to incomplete statistics, there are many 5G chips related to millimeter wave technology on the market. Intel (Intel) released the XMM 8060 5G multimode baseband chip in November 2017. The chip supports both the sub-6GHz frequency band and the 28GHz millimeter wave frequency band. Qualcomm has been able to provide commercial millimeter wave terminal chips X50 and X55, and antenna module QTM525.

As for Qualcomm’s second-generation 5G NR modem, the Snapdragon X55 5G modem, it is a 7-nanometer single chip that supports 5G to 2G multi-mode, as well as 5G NR millimeter wave and frequency bands below 6 GHz. Among them, the new RF front-end solutions include QTM525 5G millimeter wave antenna modules, which can support the design of slim 5G smartphones with a thickness of less than 8 millimeters. At present, 20 OEM manufacturers around the world have carried out related product research and development, and 18 operators around the world are also using X50 5G modems for mobile trials.

In early 2019, the Federal Communications Commission (FCC) of the United States has certified the 5G module released by Motorola. The 5G module is equipped with a proximity sensor. Its function is to turn off 4 millimeter wave antenna modules before the user’s face approaches the phone to reduce the impact of radiation on the user; in addition, if the proximity sensor detects that the finger is blocking the antenna, the 5G module will strengthen Antenna power to achieve better reception of 5G signals.

As for domestic companies, as the subsidiary of H&T is in the field of domestic microwave and millimeter wave T/R chips, private companies that master core technologies except for a few national defense research institutes have strong technological scarcity in China. It can be completed in the data interface, and it can also expand some high-end applications.

3. Antenna

Massive MIMO and beamforming technology are one of the key technologies of millimeter wave systems, so the antenna industry is also worthy of attention.

Generally speaking, the antenna is a wire with a specified length, so it can be manufactured on PCB and FPC. However, due to the miniaturization and portability of the equipment, the design space left for the antenna is already very small, so the current mainstream solution is to use FPC to manufacture the antenna, that is, the foldable antenna. The foldable antenna is made of a soft board and can be bent into any shape to meet people’s higher requirements for the size and design of portable devices.

As the wavelength of millimeter waves is greatly reduced, the problem is that the diffraction ability of electromagnetic waves becomes worse, and the attenuation becomes abnormally obvious. Therefore, in order to improve attenuation and increase transmission speed, 5G technology will adopt MIMO multi-antenna technology, beamforming beamforming, and spatial hierarchical multiplexing technologies.

4. Terminal

Many industry players predict. 5G mobile phones will drive the first wave of terminal consumption of millimeter wave products.

In terms of commercial terminals, OPPO/VIVO/ZTE all expected to launch X55 chip prototype terminals by the end of 2019, and commercial terminals are expected to appear in 2020. Apple is already secretly launching the research and application of millimeter wave technology. Its 5G version of the iPhone that supports millimeter wave will be launched in December 2020 or January 2021, at least three later than the regular version (supporting 5G in the Sub-6G band) Months show the complexity of the commercial use of millimeter wave technology.

There is also news that TSMC has won an order for Apple’s 5G antenna packaging, and it is specifically aimed at 5G millimeter wave system integration.

Regardless of whether the above-mentioned mobile phones can be launched as scheduled, this series of news has brought small surprises to those concerned about 5G millimeter wave applications.

China Unicom believes that in the face of diverse 5G millimeter wave application scenarios, especially campus private network scenarios, millimeter wave terminals should be customized according to the needs of private network services. According to 5G millimeter wave application scenarios, millimeter wave terminals include public and private network hybrid terminals, private network function terminals, and customized CPE. The specific requirements are as follows: public and private network hybrid terminals, integrated design with 5G terminals, supporting multi-mode and multi-frequency, Support 5G high and low frequency dual connection and 5G millimeter wave carrier aggregation capabilities. Support private network APP application. The terminal’s other capability requirements are the same as the current public network terminal.

5. Scenario application

The vertical application scenarios of 5G millimeter wave are rich and diverse, whether it is personal terminal consumption, industrial manufacturing, medical and health and other markets, it will also give birth to a large number of applications. These innovations include enhanced telemedicine and education, industrial automation, virtual and augmented reality, and more.

In terms of medical treatment, telemedicine can achieve a more accurate and fast level through the speed and low latency supported by the millimeter wave spectrum. This includes sensing network functions, using remote sensors and wearable devices that are always connected to enhance preventive medicine, as well as remote surgery and “smart” instruments.

In the field of industrial manufacturing, a new generation of robots, remote object manipulation (remote precise control of machines), drones, and other real-time control applications in digital industrial centers are expected to improve efficiency, reduce costs, enhance safety, and bring Product and process innovation. This is one of the effective means to improve the current uneven level of manufacturing intelligence.

In terms of autonomous driving transportation, 5G millimeter waves will allow unmanned vehicles to communicate with each other, as well as with the cloud and the physical environment, thereby establishing an efficient public transportation network. In the future, these and many other innovative use cases are expected to account for 25% of the total value created by 5G.

In addition, from the perspective of enterprises and industries, indoors, parks, docks, etc.

​Popular Science: What is WiFi 6

The latest generation of Wi-Fi (called Wi-Fi 6) brings some significant performance improvements and is designed to address the limitations of the older generation. Although 802.11ax-certified chips provide a large number of routers and clients, Wi-Fi 6 has just begun to spread. It will become part of the IEEE formal specification in September 2020. This will usher in a wave of updated equipment, touting new wireless features, which will bring faster speeds and less congestion to next-generation networks.
Before going further, we must emphasize that 802.11ax (also known as “high-efficiency wireless”) and Wi-Fi 6 are the same thing, which is very important. But if you say it, Wi-Fi 6 is easier than 802.11ax.
This is a new naming standard established by the Wi-Fi Alliance. The previous generations are now called Wi-Fi 5 (802.11ac) and Wi-Fi 4 (802.11n). It is expected that this labeling convention will appear on the device as shown below.
Technically speaking, the single-user data rate of Wi-Fi 6 is 37% faster than 802.11ac, but more importantly, the updated specification will provide four times the throughput for each user in a crowded network environment, and has Higher power efficiency. It should extend the battery life of the device.


In order to achieve these improvements, 802.11ax has made various changes, including several multi-user technologies borrowed from the cellular industry, namely MU-MIMO and OFDMA. These technologies greatly increase the use of more simultaneous connections and spectrum throughput. Improve the capacity and performance of the network.
Home users who upgrade their hardware can look forward to these technological improvements, especially over time, as the number of devices per household increases—some estimates indicate that by 2022, there will be as many as 50 nodes per household .
Although Wi-Fi 6 is not designed to significantly increase download speeds, as the number of devices in the area increases, these new features will really come into play. It has a more nuanced approach and is expected to bring relocation benefits over time. This will ultimately lay the foundation for the expected number of nodes on the upcoming smart infrastructure (for example, IoT devices). In addition to solving the problem of overlapping coverage of a large number of devices and network deployments due to the introduction of the Internet of Things, Wi-Fi 6 can also meet the growing demand for multi-user data rates.

Overall, Wi-Fi 6 is built on 802.11ac. According to the original proposal, there will be more than 50 updates, but not all final features are included in the final specification.
The following are the main advantages of Wi-Fi 6:

  • Higher total bandwidth per user for UHD and virtual reality streaming
    Support more simultaneous data streams and increase throughput
    More total spectrum (2.4GHz and 5GHz, the final frequency band is 1GHz and 6GHz)
    The spectrum is divided into more channels to achieve more communication paths
    Data packets contain more data, and the network can process different data streams at once
    Improved performance within the maximum range of the access point (up to 4 times)
    Better performance/robustness in outdoor and multipath (cluttered) environments
    Ability to divert wireless traffic from cellular networks with poor reception

802.11n and 802.11ac and 802.11ax

 

802.11ac (that is, WiFi 5) was standardized in 2013. Although the specification is suitable for today’s typical home use to a large extent, it only uses the frequency band of the 5GHz spectrum and lacks the level of multi-user technology, which will support more and more devices to connect at the same time.

As a reference for the upcoming changes in Wi-Fi 6, the following is the extension of 802.11ac (Wi-Fi 5) over 802.11n (Wi-Fi 4):

  • A wider channel (80MHz or 160MHz, while the maximum in the 5GHz band is 40MHz)
    Eight spatial streams (spatial streams) instead of four
    256-QAM and 64-QAM modulation (each QAM symbol transmits more bits)
    Multi-user MIMO (MU-MIMO) on 802.11ac Wave 2 can achieve four downlink connections at a time instead of only one on single-user MIMO (uplink is still 1×1)

The specification is backward compatible with previous standards, combining 2.4GHz and 5GHz, and finally expanding the spectrum to include 1GHz and 6GHz bands when available.
Perhaps more notable than including these additional spectrum is the technology that puts this bandwidth into use. With more available spectrum, Wi-Fi 6 can divide the bandwidth into narrower (more) sub-channels, creating more communication channels for clients and access points, and supporting others on any given network equipment. In the older 802.11n, due to too much overlap, you basically can only use 3 independent channels at the same time. Since everyone’s routers are competing with each other, this makes crowded places such as apartments a mess. 802.11ac adds extra space in the 5GHz band, but 802.11ax does a better job of dealing with this problem.
Another area to consider is the performance of multiple devices on a single network. This is the so-called multiple input multiple output, which allows a single device to communicate through multiple channels at once. It’s basically like connecting multiple wireless adapters to the same network. The extension at the access point is called MU-MIMO or multi-user MIMO. As the name suggests, it allows the access point to connect to multiple users at once via MIMO.
Although MU-MIMO can enable Wi-Fi 5 to provide services to four downstream users at a time (compared to the single-user MIMO on Wi-Fi 4), this function is not necessary. Only added to new 802.11ac devices. On paper, 802.11ax can increase the number of uplink and downlink users to eight, and it is possible to deliver four simultaneous streams to a single client.
However, uplink MU-MIMO is unlikely to be used. Currently, almost no device can benefit from the four spatial streams, because most existing MU-MIMO-equipped smartphones and laptops only have 2×2:2 or 3×3:3 MIMO radios, so there is almost no Wi-Fi 6 support Eight spatial streams.


This digital format (AxB:C) is used to demonstrate the largest transmit antenna (A), the largest receive antenna (B), and the largest spatial data stream (C) supported by the MIMO radio. Although Wi-Fi devices must support MU-MIMO to directly benefit from the technology, hardware without MU-MIMO chips should indirectly benefit from the additional broadcast time available on MU-MIMO-enabled access points.
To help you visualize these technologies, the combination of MU-MIMO and OFDMA can be equivalent to having many employees and multiple lines, and each employee can serve multiple customers at once, rather than a single employee serving a single customer. In addition, 802.11ax can more clearly notify clients when routers are available, rather than let them compete for access.

Although the overall data rate and channel width of Wi-Fi 6 are similar to Wi-Fi 5, dozens of technologies have been implemented in accordance with the updated specifications. These technologies will significantly improve the efficiency and throughput of future Wi-Fi networks. It may transmit devices at a speed of several gigabits per second on a single channel for dozens of Wi-Fi network services. We will now discuss some of them.
OFDMA: Wi-Fi 6 also introduced support for uplink and downlink “Orthogonal Frequency Division Multiple Access” (OFDMA), which is a modulation scheme equivalent to the multi-user version of OFDM (802.11ac/n specification). OFDMA reduces delay, increases capacity, and improves efficiency by allowing up to 30 users to share a channel at a time. Do not confuse this with Orthogonal Frequency Division Multiplexing (OFDM).
OFDMA allows better allocation of resource units in a given bandwidth. Integrated in Wi-Fi 6, so more clients (up to 30) can share the same channel instead of waiting, and can also improve efficiency by combining different traffic types. OFDMA is compared to the multi-user version of OFDM.
For simplicity, OFDM divides the channel into several subcarriers, allowing multiple parallel data streams. However, each user must use its complete subcarrier. On the other hand, OFDMA further subdivides it into resource units that can be allocated individually. This fine-grained allocation is the key to OFDMA’s performance advantages.


1024-QAM:

The next major performance improvement is the jump from 256-QAM to 1024-QAM. When a wireless device transmits a message, it must send out an analog signal because it cannot directly transmit binary data. The analog signal has two parts, called amplitude (the strength of the signal) and quadrature (how much the signal is offset from the reference point). By controlling quadrature and amplitude, we can effectively transmit digital data through analog signals.
The 256-QAM system used in 802.11ac divides amplitude and quadrature into 16 predefined levels. This provides a total of 256 (16 * 16) possible transfer values, and each transfer allows up to 8 bits (2^8 = 256). Since the introduction of 802.11ac, the transmitter and receiver technology has advanced significantly, so we can now assign more precise values ​​to transmissions. 802.11ax can divide the orthogonality and amplitude of the transmission into 16 possible values ​​instead of dividing it into up to 32 levels. This provides us with 1024 (32 * 32) possible transmission values, with a maximum of 10 bits per transmission.
Of course, as we pack more and more data into the same amount of resources, our sensitivity and accuracy must also increase. Small errors in the reception of 256-QAM signals may not cause problems, but since 1024-QAM packs symbols closer together, the same error may cause incorrect values ​​to be decoded. The device is smart enough to know that if many transmissions are decoded incorrectly, it should be reduced to a lower scheme.
Using an 80MHz channel, 1024-QAM can generate a theoretical single-stream data rate of 600Mb/s, which is 39% higher than the theoretical 433Mb/s single-stream data rate of Wi-Fi 5.


Longer OFDM symbols: Increase the transmission time of OFDM symbols from 3.2us on Wi-Fi 5 to 12.8us on Wi-Fi 6, and support a longer cyclic prefix (CP) for each symbol.
The cyclic prefix (CP) adds a part of the end of the OFDM symbol to the front of the payload to provide a guard interval to prevent inter-symbol interference and improve robustness, because this part can be used when necessary. This number can be adjusted according to overhead requirements (a longer CP repeats more data and takes up more space in the symbol, resulting in a lower data rate).

Dynamic fragmentation: Wi-Fi 5 has static fragmentation, which requires that all fragments of the packet have the same size (except the last fragment), and dynamic fragmentation allows these fragments to have different sizes In order to make better use of network resources.
Spatial Frequency Multiplexing/OBSS (BSS Coloring): If multiple access points are operating on the same channel, they can transmit data with a unique “color” identifier so that they can communicate through the wireless medium at the same time. No need to wait for colors to enable them to distinguish each other’s data.


Beamforming: This exists on Wi-Fi 5, although the standard supports four antennas, while Wi-Fi 6 increases it to eight. Beamforming increases the data rate and extends the range by directing the signal to a specific client rather than in each direction at the same time. This helps MU-MIMO, which is not suitable for fast-moving devices. Beamforming can be performed on Wi-Fi 4 devices, but with the realization of MU-MIMO on Wi-Fi 5 Wave 2, beamforming becomes necessary. In a new direction.
TWT (Target Wake-up Time): Wake-up time scheduling, rather than contention-based access. The router can tell the client when to fall asleep and when to wake up, which is expected to greatly extend battery life because the device will know when to listen to the channel.


Uplink resource scheduler: Similarly, Wi-Fi 6 will not rush to upload data like on older wireless networks. Instead, it will schedule the uplink to minimize conflicts and achieve better resource management. Everyone has their own speaking space, so no one needs to shout or talk to others.
Trigger-based random access: You can also reduce data conflicts/conflicts by specifying the length of the uplink window in other attributes, which can improve resource allocation and increase efficiency.
TWO NAVs (Network Assignment Vector): When a wireless station is transmitting, it will announce the duration required for completion so that other stations can set their NAV to avoid conflicts when accessing the wireless medium. Wi-Fi 6 introduced two types of NAV: one for the network to which the site belongs, and the other for the adjacent network. This will also reduce energy consumption by minimizing the need for carrier sensing.
Improved outdoor operation: Some of these features will bring better outdoor performance, including new packet formats, longer guard intervals and modes to improve redundancy and error recovery.

Wi-Fi 6E: Extend Wi-Fi 6 to include 6GHz

Wi-Fi 6E is the name of a new extension to the existing Wi-Fi 6 standard, indicating that it can support the brand new 6 GHz frequency. This will increase spectrum, higher throughput and lower latency.
Industry leaders such as Qualcomm have determined that proper service quality on future networks will require spectrum beyond what 2.4GHz or 5GHz can provide. For a long time, the 2.4GHz band has been saturated by common electronic devices such as microwaves. Another option is 5GHz, its spectrum is not enough for wider bandwidth channels (such as 80MHz or 160MHz), and some parts of 5GHz are restricted to limit its use.
At the beginning of 2020, the Federal Communications Commission (FCC) formally approved Wi-Fi to extend its coverage to the new radio spectrum in the US 6 GHz band. Specifically, the new Wi-Fi 6E standard will have access to the 1.2 GHz or 1200 MHz radio spectrum, ranging from 5.9 GHz to 7.1 GHz (and merge all 6 GHz frequencies in between, and therefore also include a 6 GHz reference).
Standard Wi-Fi faces the problem of spectrum shortage, because if the number of devices used worldwide continues to increase and the increase of 6GHz will help alleviate this problem. Once allowed, 6GHz will promote the continued growth of Wi-Fi, as well as other advantages, such as wider channel size and less interference from traditional Wi-Fi 4 (802.11n) and Wi-Fi 5 devices. Analysts predict that approval will trigger the rapid adoption of the frequency band by equipment manufacturers.
From the perspective of the new spectrum, even the widest connection of millimeter wave 5G (the fastest existing 5G connection) is limited to 800 MHz. In other words, the frequency that the new Wi-Fi connection can access is almost 1.5 times that of the fastest 5G connection.
In theory, this means that the connection speed of Wi-Fi 6E may be significantly faster than the highest speed 5G can provide. In addition, due to the basic laws of physics and signal propagation, the coverage of Wi-Fi 6E can actually be wider than that of millimeter wave 5G.
The influence of Wi-Fi 6E will really come into play in highly congested areas. Routers will have wider channels and can accommodate more devices at higher throughput rates.
Wi-Fi 6 or 802.11ax is just one of many upcoming wireless standards developed to meet the various network requirements that different types of devices will meet. 802.11ad/ay will bring multi-gigabit speeds through the use of millimeter wave frequencies. On the contrary, 802.11ah is designed for ultra-low power consumption, which may lead to several years of battery life.

Summary: The aerial view of Wi-Fi 

As the next WLAN standard to succeed 802.11n and 802.11ac, 802.11ax or Wi-Fi 6 will bring significant improvements in network efficiency and capacity in densely populated centers, and peak data rates will be moderately increased throughout the data center Will be better maintained. Add equipment at once.
As Qualcomm likes to say, “The question is not how fast Wi-Fi can go, but whether the Wi-Fi network has enough capacity to meet the growing demand for many different connected devices and services.”


Currently there are not many Wi-Fi 6 clients, so it will take time to adopt. Until more devices use the standard, you can really feel the improvement of this generation. As usual, Wi-Fi 6 is backward compatible, but older devices will not be able to take advantage of the newer features.
Considering Wi-Fi 6 from a broader perspective, as the demand for user data continues to increase, the increase in multi-user support, especially the increase in simultaneous uplink connections, has arrived. These data will be collected from IoT devices and used for machine learning, promoting the development of artificial intelligence, the future of the entire technology, and the evolving digital economy.

“Analog Circuit Modeling and Fast Simulation of Digital-Analog Hybrid Circuits” Online Technology Sharing Session was successfully held

On May 27, 2020, Zhongguancun Core Park (Beijing National “Core Fire” Innovation Base) and Beijing Opland Technology Co-sponsored the “Analog Circuit Modeling and Rapid Simulation of Digital-Analog Hybrid Circuits-Scientific Analog Efficient Design Process” line The Shanghai Technology Sharing Conference was successfully held through the Tencent Video platform. In this event, more than 120 professional and technical personnel from integrated circuit design companies and scientific research institutes participated in the technology sharing.

 

In this training, Mr. Li Jing, a senior engineer from Opram Technology, explained and shared the rapid simulation solutions of SystemVerilog modeling, Xmode and Modelze software platform. The unique Xmodel uses the systemverilog language and uses revolutionary patented algorithms. The analog circuit waveform is described as a function expression, and an event-driven way is used to complete efficient calculations. Dr. Qiwen Liao from the Institute of Microelectronics of the Chinese Academy of Sciences gave a detailed demonstration of XMODEL, GLISTER, XWAVE, and MODELZEN in the chip design process, scope of application, problems encountered in the specific application process and actual cases. Participants asked questions and discussed the selection of modeling accuracy comparison and software operation methods, and the online communication atmosphere was active.

 

Beijing Opland Technology Co., Ltd.

Beijing Opland Technology Co., Ltd. is a fast-growing high-tech enterprise in the field of simulation software in China. The company is committed to introducing the latest scientific and technological achievements in Europe and the United States, combining domestic practices, providing customers with advanced CAE/EDA software and hardware products, and providing professional technical support and Engineering consulting services to assist customers in improving product quality, shortening the R&D cycle, and reducing R&D costs, and are determined to contribute to my country’s progress from a major producer to a major technological innovation country.

Acting for EDA products: PeakView RF IC electromagnetic field design software, OPTENNI antenna matching design and automatic optimization software, Scientific Analog, Matlab, etc.

About Zhongguancun Core Park (Beijing) Co., Ltd.

Zhongguancun Core Park Company was established by Zhongguancun Development Group as the controlling shareholder, as the national integrated circuit design Beijing industrialization base. Zhongguancun Core Park will adhere to the service concept of openness, neutrality, and public welfare, centering on integrated circuit design, providing EDA License leasing, IP evaluation and authorization, production tapeout (MPW, engineering batch, mass production), packaging and testing agents, IC talent training, The public technical service support of the whole industry chain such as chip application helps enterprises to develop rapidly. Zhongguancun Core Park will regularly hold various technical exchange seminars and sincerely invite all partners and customers of Core Park to participate and seek common development.