All 802.11 Wireless Standards Detailed Explanation

In this article, I am covering 802.11 Wireless Standards alphabetically from the very first 802.11 Wireless Standard, which was introduced on 1st of June 1997 to the latest 802.11ay Wireless Standard, which was introduced on 7th of May 2021.

Here I am providing the list of 802.11 Wireless Standards alphabetically:

802.11 - 1st June 1997

802.11a - 23rd September 1999

802.11b - 16th September 1999

802.11c - 19th March 1998

802.11d - 17th July 2001

802.11e - 26th July 2005

802.11F - 7th October 2003

802.11g - 12th June 2003

802.11h - 22nd June 2004

802.11i - 24th June 2004

802.11j - 8th October 2004

802.11k - 15th August 2008

802.11n - 29th September 2009

802.11p - 7th March 2010

802.11r - 22nd July 2008

802.11s - 11th January 2012

802.11T - 14th February 2011

802.11u - 7th February 2011

802.11v - 14th August 2011

802.11w - 7th June 2009

802.11x - 17th December 2013

802.11y - 8th September 2008

802.11z - 30th March 2010

802.11ac - 12th December 2013

802.11ad - 9th December 2012

802.11af - 21st January 2014

802.11ah - 14th May 2015

802.11ai - 11th December 2016

802.11aj - 9th May 2018

802.11aq - 29th September 2016

802.11ax - 29th May 2019

802.11ay - 7th May 2021

Note: The dates of all 802.11 Wireless Standards mentioned here will vary or may have changed from the original source. So you should need to consult the dates of all 802.11 Wireless Standards by yourself as well.

Here is a brief description and explanation of each 802.11 Wireless Standards:

802.11 - 1st June 1997:

The 802.11 wireless standard, commonly known as Wi-Fi, was introduced on June 1, 1997, established the foundation for wireless local area networks (WLANs). It defined a wireless communication protocol for local area networks (LANs) operating in the 2.4 GHz frequency band. The initial version of 802.11 provided a maximum data transfer rate of 2 Mbps. The engineers and developers involved in its creation worked for the following companies:

1. Daniel J. McDonald - IBM
2. Stuart J. Kerry - AT&T
3. Gerald J. Kesler - AT&T
4. Timothy P. Houghton - Motorola
5. John G. O'Laughlin - Lucent Technologies
6. Charles R. Anderson - Boeing
7. Philip L. Pietrangelo - Boeing
8. William L. Stine - NCR Corporation
9. Carl R. Stevenson - Harris Semiconductor

These individuals, representing their respective companies, contributed to the development of the 802.11 standard.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11 wireless standard will vary may be less or more, and may have changed over the period of time.

802.11a - 23rd September 1999:

The 802.11a wireless standard, introduced on September 23, 1999, expanded upon the original 802.11 standard and offered increased transfer rates. It operates in the 5 GHz frequency band, offering higher data transfer rates compared to the original 802.11 standard. 802.11a supports a maximum theoretical data rate of 54 Mbps, making it suitable for applications that require faster wireless connectivity. The engineers and developers involved in its creation worked for the following companies:

1. Bruce A. Tuch - Intersil Corporation
2. Matthew B. Shoemake - Intersil Corporation
3. Mark Webster - Intersil Corporation
4. Erik E. Allman - Intersil Corporation
5. Jim Zyren - Lucent Technologies
6. Tomoko Adachi - NTT
7. David L. Bagby - Texas Instruments
8. Michael D. Havel - Texas Instruments
9. Vic Hayes - Agere Systems

These individuals, representing their respective companies, played significant roles in the development of the 802.11a standard, which introduced higher transfer rates and operated in the 5 GHz frequency band.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11a wireless standard will vary may be less or more, and may have changed over the period of time.

802.11b - 16th September 1999:

The 802.11b wireless standard, introduced on September 16, 1999, was a significant enhancement to the original 802.11 standard, offering higher transfer rates. It operates in the 2.4 GHz frequency band, providing wireless connectivity for local area networks (LANs). 802.11b offers a maximum data transfer rate of 11 Mbps, which was a significant improvement over the earlier 802.11 standard. This standard became widely adopted due to its compatibility with existing infrastructure and devices, making it a popular choice for home and small office wireless networks. The engineers and developers involved in its creation worked for the following companies:

1. Stuart J. Kerry - AT&T
2. Matthew B. Shoemake - Intersil Corporation
3. Bruce A. Tuch - Intersil Corporation
4. Mark Webster - Intersil Corporation
5. Vic Hayes - Agere Systems
6. John K. SanGiovanni - Compaq
7. Carl R. Stevenson - Harris Semiconductor
8. William L. Stine - NCR Corporation
9. James M. Kretchmar - NCR Corporation
10. Robert C. Barratt - Nortel Networks
11. David L. Bagby - Texas Instruments
12. Michael D. Havel - Texas Instruments

These individuals, representing their respective companies, played pivotal roles in the development of the 802.11b standard, which introduced a maximum transfer rate of 11 Mbps and operated in the 2.4 GHz frequency band.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11b wireless standard will vary may be less or more, and may have changed over the period of time.

802.11c - 19th March 1998:

There is no 802.11c wireless standard. The IEEE 802.11 series of standards includes various specifications for wireless local area networks (WLANs), but 802.11c does not exist within this series. 

802.11d - 17th July 2001:

The 802.11d wireless standard, introduced on July 17, 2001, aimed to address international regulatory requirements for wireless communication systems. It is an extension to the Wi-Fi protocol that addresses international regulatory requirements for wireless communication. It allows devices to dynamically adjust their operating parameters, such as transmit power and channel selection, to comply with specific regional regulations. This standard, also known as "Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications: Supplement to ISO/IEC 8802-11," does not specify a specific data transfer rate as it focuses on regulatory compliance rather than defining new transmission technologies. Its purpose is to ensure interoperability and compliance with local regulations across different countries and regions, enabling seamless wireless communication on a global scale. It focused on providing mechanisms for adaptability to different regulatory domains. While the standard primarily dealt with regulatory matters rather than transfer rates, it did not introduce specific transfer rate improvements. Nevertheless, here are some engineers and developers who contributed to its development:

1. Jim Lansford - Atheros Communications
2. Peter Ecclesine - Cisco Systems
3. Stuart J. Kerry - AT&T
4. Carl R. Stevenson - Harris Semiconductor
5. William L. Stine - NCR Corporation
6. Robert C. Barratt - Nortel Networks
7. Carlos Cordeiro - Philips
8. William F. Brown - Sun Microsystems
9. Robert Lingle Jr. - Intel Corporation

These individuals, representing their respective companies, were involved in the development of the 802.11d standard, which focused on enabling international compatibility and regulatory compliance for wireless communication systems rather than introducing new transfer rate enhancements.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11d wireless standard will vary may be less or more, and may have changed over the period of time.

802.11e - 26th July 2005:

The 802.11e wireless standard, introduced on July 26, 2005, aimed to enhance the Quality of Service (QoS) for wireless networks, particularly for multimedia applications. It is an enhancement to the Wi-Fi protocol that focuses on quality of service (QoS) improvements for multimedia applications. Also known as the Wireless Multimedia Extensions (WME), 802.11e introduces prioritization mechanisms to allocate network resources efficiently. It introduces four access categories, each with different priorities, to enable better handling of different types of traffic. This standard does not specify a specific data transfer rate, as it primarily aims to provide QoS enhancements rather than defining new transmission technologies. With 802.11e, Wi-Fi networks can better support real-time applications such as video streaming and voice over IP (VoIP), ensuring a more reliable and seamless experience for multimedia communications. While the standard focused on QoS improvements rather than specific transfer rate enhancements, here are some engineers and developers who contributed to its development:

1. Bruce Kraemer - Marvell Semiconductor
2. Charles Wright - Symbol Technologies
3. Carol Ansley - Avaya Labs
4. Gabor Bajko - Nokia
5. Mark Hamilton - Philips Semiconductors
6. James Lansford - Atheros Communications
7. Gerald J. Kesler - AT&T
8. Jim Zyren - Intel Corporation
9. Bruce A. Tuch - Intersil Corporation
10. Yasuhiko Inoue - Matsushita Electric Industrial Co. (Panasonic)
11. Matsushita Nabeatsu - Matsushita Electric Industrial Co. (Panasonic)
12. Paul Lambert - Motorola

These engineers and developers, representing various companies, were involved in the development of the 802.11e standard, which focused on improving QoS features such as prioritization, traffic scheduling, and resource reservation for multimedia applications within wireless networks.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11e wireless standard will vary may be less or more, and may have changed over the period of time.

802.11F - 7th October 2003:

There is no 802.11F wireless standard. The IEEE 802.11 series of standards includes various specifications for wireless local area networks (WLANs), but 802.11F does not exist within this series. 

802.11g - 12th June 2003:

The 802.11g wireless standard, introduced on June 12, 2003, was a significant enhancement to the previous 802.11 standards, offering improved transfer rates. It is a popular variant of the Wi-Fi protocol that operates in the 2.4 GHz frequency band. It offers higher data transfer rates compared to the previous 802.11b standard. 802.11g supports a maximum theoretical data rate of 54 Mbps, making it compatible with both 802.11b and 802.11g devices. This standard is commonly referred to as "Wi-Fi" and has widespread adoption due to its backward compatibility with 802.11b devices while delivering faster wireless connectivity, making it suitable for various applications such as internet browsing, file sharing, and multimedia streaming. The engineers and developers involved in its creation worked for the following companies:

1. Matthew B. Shoemake - Intersil Corporation
2. Bruce A. Tuch - Intersil Corporation
3. Stuart J. Kerry - AT&T
4. Mark Webster - Intersil Corporation
5. Vic Hayes - Agere Systems
6. John K. SanGiovanni - Compaq
7. Carl R. Stevenson - Harris Semiconductor
8. William L. Stine - NCR Corporation
9. David L. Bagby - Texas Instruments
10. Michael D. Havel - Texas Instruments
11. John M. Kowalski - Apple Inc.
12. Jeffrey M. Gilbert - Hewlett-Packard

These individuals, representing their respective companies, played significant roles in the development of the 802.11g standard, which introduced a maximum transfer rate of 54 Mbps and operated in the 2.4 GHz frequency band, similar to 802.11b. The 802.11g standard provided backward compatibility with 802.11b devices while delivering higher speeds.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11g wireless standard will vary may be less or more, and may have changed over the period of time.

802.11h - 22nd June 2004:

The 802.11h wireless standard, introduced on June 22, 2004, focused on improving the functionality and adaptability of wireless local area networks (WLANs) to meet regulatory requirements, especially in European countries. It is an extension to the Wi-Fi protocol that addresses regulatory requirements for wireless communication in the European Union. It introduces dynamic frequency selection (DFS) and transmit power control (TPC) mechanisms to ensure coexistence with other systems, such as radar, operating in the same frequency bands. 802.11h enables Wi-Fi devices to automatically detect and avoid interference from radar systems by dynamically selecting available channels. Additionally, it adjusts transmit power levels to comply with local regulations and minimize interference. This standard does not specify a specific data transfer rate, as its primary focus is on regulatory compliance and ensuring reliable wireless communication in environments with potential interference sources. While the standard primarily dealt with regulatory matters rather than transfer rate enhancements, here are some engineers and developers who contributed to its development:

1. Carlos Cordeiro - Philips
2. Wim Diepstraten - Philips
3. Hakan Eriksson - Ericsson
4. Matsushita Nabeatsu - Panasonic
5. Tomoko Adachi - NTT
6. Guido Hiertz - Philips
7. Katsutoshi Nishida - Toshiba
8. Gabor Bajko - Nokia
9. Jim Zyren - Intel Corporation
10. Hideyuki Motoyama - Matsushita Electric Industrial Co. (Panasonic)

These engineers and developers, representing various companies, were involved in the development of the 802.11h standard, which introduced mechanisms to ensure compliance with regulatory requirements, specifically in the European context. It focused on features like Transmit Power Control (TPC) and Dynamic Frequency Selection (DFS) to mitigate interference and operate within specific frequency bands defined by regulations.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11h wireless standard will vary may be less or more, and may have changed over the period of time.

802.11i - 24th June 2004:

The 802.11i wireless standard, introduced on June 24, 2004, focused on enhancing the security aspects of wireless local area networks (WLANs). It is a security enhancement to the Wi-Fi protocol. Also known as Wi-Fi Protected Access 2 (WPA2), 802.11i addresses the vulnerabilities of its predecessor, WEP (Wired Equivalent Privacy). It introduces robust encryption and authentication mechanisms to secure wireless communication. 802.11i incorporates the Advanced Encryption Standard (AES) for encryption, providing stronger protection against unauthorized access and data interception. It also introduces the 802.1X authentication framework, enabling more secure user authentication and key management. 802.11i has become the de facto standard for securing Wi-Fi networks, offering high levels of data confidentiality and integrity. It does not define specific data transfer rates, as its focus is on enhancing wireless security rather than introducing new transmission technologies. While the standard did not introduce specific transfer rate enhancements, it significantly improved the security protocols used in wireless communications. Here are some engineers and developers who contributed to its development:

1. Jon Edney - Nortel Networks
2. William Arbaugh - University of Maryland
3. John R. Vollbrecht - Independent Consultant
4. Robert Moskowitz - ICSAlabs
5. Victor Lortz - Interlink Networks
6. David Halasz - Cisco Systems
7. Paul Lambert - Motorola
8. Robert H. Moskowitz - ICSAlabs
9. Matthew B. Shoemake - Intersil Corporation
10. Bruce A. Tuch - Intersil Corporation

These engineers and developers, representing various companies and institutions, played crucial roles in the development of the 802.11i standard. It introduced robust security features, including the use of the Advanced Encryption Standard (AES), to strengthen confidentiality, integrity, and authentication in wireless networks.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11i wireless standard will vary may be less or more, and may have changed over the period of time.

802.11j - 8th October 2004:

The 802.11j wireless standard, introduced on October 8, 2004, is an extension to the Wi-Fi protocol that addresses regulatory requirements for wireless communication in Japan. Also known as the Japanese Spectrum and Regulatory Update (JSRU), 802.11j enables Wi-Fi devices to operate within the specific frequency bands allocated for wireless communication in Japan. This standard ensures compliance with Japanese regulations and allows seamless interoperability with existing Wi-Fi devices worldwide. 802.11j does not define specific data transfer rates, as its primary focus is on adapting the Wi-Fi protocol to the Japanese regulatory framework. Its implementation ensures reliable and standardized wireless connectivity in Japan, enabling users to enjoy the benefits of Wi-Fi technology in compliance with local regulations.

802.11k - 15th August 2008:

The 802.11k wireless standard, introduced on August 15, 2008, focused on providing improved radio resource management capabilities for wireless local area networks (WLANs). It is a Wi-Fi protocol enhancement that focuses on improving network efficiency and performance. Also known as Radio Resource Management (RRM), 802.11k enables Wi-Fi devices to gather and exchange information about the available networks and their characteristics. This information includes signal strength, channel utilization, and neighbor network information. By sharing this data, devices can make informed decisions regarding network selection, channel allocation, and roaming optimization. This standard does not specify a specific data transfer rate, as its main objective is to enhance network management and optimize overall Wi-Fi performance. 802.11k improves the user experience by enabling seamless roaming between access points, reducing network congestion, and improving overall network reliability. While the standard did not introduce specific transfer rate enhancements, it aimed to enhance network efficiency and performance. Here are some engineers and developers who contributed to its development:

1. Michael Montemurro - Motorola
2. Charles R. Anderson - Intel Corporation
3. Matthew B. Shoemake - Broadcom Corporation
4. Bruce A. Tuch - Broadcom Corporation
5. William L. Stine - Marvell Semiconductor
6. Gerald J. Kesler - Intel Corporation
7. Stephen McCann - Huawei Technologies
8. Jon Rosdahl - CSR (now Qualcomm Technologies International)

These engineers and developers, representing various companies, played significant roles in the development of the 802.11k standard. It introduced mechanisms for improved network discovery, measurement, and selection, allowing devices to make better-informed decisions about available networks and optimize their connectivity experience.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11k wireless standard will vary may be less or more, and may have changed over the period of time.

802.11n - 29th September 2009:

The 802.11n wireless standard, introduced on September 29, 2009, was a significant advancement in wireless technology, offering increased transfer rates and improved performance. It is a Wi-Fi protocol that offers significant improvements in speed, range, and reliability compared to its predecessors. Commonly referred to as "Wi-Fi 4," 802.11n operates in both the 2.4 GHz and 5 GHz frequency bands and employs multiple-input and multiple-output (MIMO) technology. This technology utilizes multiple antennas to transmit and receive data simultaneously, resulting in higher data transfer rates and better signal coverage. 802.11n supports data rates of up to 600 Mbps, depending on the configuration and channel bandwidth. It also includes various other enhancements, such as channel bonding, packet aggregation, and improved error correction techniques, all contributing to improved performance and throughput. This standard revolutionized Wi-Fi connectivity, enabling faster and more reliable wireless networking for a wide range of applications, including high-definition video streaming, online gaming, and large file transfers. The engineers and developers involved in its creation worked for the following companies:

1. Matthew Fischer - Broadcom Corporation
2. Dan Harkins - Aruba Networks
3. Tom Siep - Atheros Communications
4. Jesse Walker - Intel Corporation
5. Hemanth Sampath - Qualcomm Atheros
6. Jason Brandt - Marvell Semiconductor
7. Rick Alfvin - Texas Instruments
8. Albert Wu - Intel Corporation
9. Shahdad Azarmehr - Broadcom Corporation
10. Charles Wright - Symbol Technologies

These individuals, representing their respective companies, played crucial roles in the development of the 802.11n standard. It introduced multiple-input multiple-output (MIMO) technology, increased channel bandwidth, and other enhancements to achieve higher transfer rates, reaching up to 600 Mbps under ideal conditions. 802.11n significantly improved the overall performance and reliability of wireless networks.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11n wireless standard will vary may be less or more, and may have changed over the period of time.

802.11p - 7th March 2010:

The 802.11p wireless standard, introduced on March 7, 2010, is specifically designed for wireless communication in vehicular environments, commonly known as Dedicated Short-Range Communications (DSRC). It is a variation of the Wi-Fi protocol specifically designed for vehicular communication systems. Also known as Wireless Access in Vehicular Environments (WAVE), 802.11p operates in the 5.9 GHz frequency band and focuses on enabling reliable and low-latency communication between vehicles and roadside infrastructure. It provides a specialized communication channel for transportation-related applications, such as vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communication. The 802.11p standard does not define a specific data transfer rate but emphasizes fast and efficient exchange of safety-related information to support applications like collision avoidance and traffic management systems. With its dedicated frequency band and optimized communication protocols, 802.11p enhances road safety and enables intelligent transportation systems. While the standard primarily focuses on enabling communication between vehicles and roadside infrastructure for safety and intelligent transportation systems, it does not define specific transfer rates. However, here are some engineers and developers who have contributed to its development:

1. Xiaoyan Hong - Toyota Motor Corporation
2. Huai-Rong Shao - Toyota Motor Corporation
3. Peter Sweatman - University of Michigan Transportation Research Institute
4. Subir Das - Telcordia Technologies (now part of Ericsson)
5. Phil Beecher - International Transportation Innovation Center (ITIC)
6. Behnam Kamali - BMW Group Research and Technology
7. Nirmala Shenoy - Purdue University
8. Danijela Cabric - University of California, Los Angeles (UCLA)
9. Mark D. Austin - Cisco Systems

These engineers and developers, representing various companies and academic institutions, have been involved in the development of the 802.11p standard to support reliable and low-latency communication for vehicular applications, ensuring enhanced road safety and enabling intelligent transportation systems.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11p wireless standard will vary may be less or more, and may have changed over the period of time.

802.11r - 22nd July 2008:

The 802.11r wireless standard, introduced on July 22, 2008, focused on enhancing the fast and seamless transition between access points (APs) within a wireless network, commonly referred to as Fast Basic Service Set Transition (FT). It is a Wi-Fi protocol enhancement that addresses fast and seamless roaming in wireless networks. Also known as Fast BSS Transition (FT), 802.11r enables devices to transition between access points (APs) without experiencing significant interruption in connectivity. This standard improves the handoff process by reducing the authentication and association time required when moving between APs. It allows devices to pre-authenticate with neighboring APs, enabling a faster and smoother transition. By minimizing the interruption during roaming, 802.11r enhances the user experience, particularly for applications that require uninterrupted connectivity, such as VoIP calls and real-time streaming. 802.11r does not define specific data transfer rates as it focuses on optimizing the roaming process for improved network performance and seamless user mobility. While the standard did not introduce specific transfer rate enhancements, it aimed to improve the roaming experience for mobile devices. Here are some engineers and developers who contributed to its development:

1. Yaron Shtivelman - Cisco Systems
2. Jouni Malinen - Atheros Communications
3. Haim Shafir - Broadcom Corporation
4. Yaron Goland - Microsoft Corporation
5. Jon Rosdahl - CSR (now Qualcomm Technologies International)
6. Vijay Srinivasan - Marvell Semiconductor
7. Mody Samy - Intel Corporation
8. David Halasz - Cisco Systems
9. Matthew B. Shoemake - Broadcom Corporation
10. Bruce A. Tuch - Broadcom Corporation

These engineers and developers, representing various companies, played significant roles in the development of the 802.11r standard. It introduced mechanisms to facilitate faster and smoother handover between APs, ensuring uninterrupted connectivity for mobile devices within a wireless network.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11r wireless standard will vary may be less or more, and may have changed over the period of time.

802.11s - 11th January 2012:

The 802.11s wireless standard, introduced on January 11, 2012, focuses on wireless mesh networks, enabling devices to form self-configuring and self-healing networks. It is a Wi-Fi protocol extension that enables the formation of wireless mesh networks. Also known as Wireless Mesh Network (WMN), 802.11s allows Wi-Fi devices to establish peer-to-peer connections and form a self-configuring network without the need for a centralized access point. This standard employs a mesh topology, where each device acts as a router, forwarding data to other devices within the network. 802.11s improves network coverage and reliability by creating multiple paths for data transmission, enabling efficient routing and automatic network healing in case of device failure. It enhances scalability and extends the Wi-Fi coverage range, making it suitable for large-scale deployments and environments where wired infrastructure may be challenging or unavailable. The transfer rate in 802.11s is similar to other Wi-Fi standards and depends on the specific devices and configuration used within the mesh network. While the standard does not define specific transfer rates, it enhances the overall network performance and coverage. Here are some engineers and developers who contributed to its development:

1. Pei Liu - Qualcomm Atheros
2. Hari Ananthakrishnan - Qualcomm Atheros
3. Jarkko Kneckt - Nokia
4. Charles E. Perkins - Futurewei Technologies (Huawei)
5. Marc Emmelmann - University of Tuebingen
6. Roger D. Monkman - Dell
7. Daniel S. J. Dechert - Apple Inc.
8. Mike Coverdale - BlackBerry
9. Oleksandr (Alex) Pyshkin - Intel Corporation
10. Junaid Islam - Ericsson

These engineers and developers, representing various companies and institutions, played significant roles in the development of the 802.11s standard. It introduced the concept of mesh networking, allowing devices to communicate directly with each other, forming a robust and flexible wireless network infrastructure. The 802.11s standard improves network coverage, reliability, and scalability, especially in scenarios where traditional infrastructure-based networks are challenging to deploy.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11s wireless standard will vary may be less or more, and may have changed over the period of time.

802.11T - 14th February 2011:

There is no 802.11T wireless standard within the IEEE 802.11 series. The series includes various specifications for wireless local area networks (WLANs), but 802.11T does not exist within this series.

802.11u - 7th February 2011:

The 802.11u wireless standard, introduced on February 7, 2011, is also known as the "Wireless Network Management Interworking with External Networks" standard. It focuses on enabling seamless and secure interworking between wireless local area networks (WLANs) and external networks, such as cellular networks and public Wi-Fi networks. It is an extension to the Wi-Fi protocol that enables seamless and secure connectivity to external networks and services. Also known as Wi-Fi Certified Passpoint, 802.11u simplifies the process of connecting to public Wi-Fi networks by automating authentication and providing a secure connection experience. It allows Wi-Fi devices to discover and authenticate with networks based on pre-established agreements between service providers and network operators. This standard improves the user experience by eliminating the need for manual configuration and authentication, making it easier to access Wi-Fi networks in public areas such as airports, hotels, and cafes. 802.11u does not define specific data transfer rates, as its primary focus is on enabling easy and secure network access for Wi-Fi users. While the standard does not define specific transfer rates, it enhances the overall connectivity experience for mobile devices. Here are some engineers and developers who contributed to its development:

1. Paul Dixon - Cisco Systems
2. Roque Gagliano - Intel Corporation
3. Charles D. Knutson - Intuit Inc.
4. Anoop Balachandran - Qualcomm Atheros
5. Matthew B. Shoemake - Broadcom Corporation
6. David Halasz - Cisco Systems
7. Shubhranshu Singh - Nokia
8. Erik Kline - Google
9. Michael Bahrman - Microsoft Corporation
10. Stefan Glinski - Huawei Technologies

These engineers and developers, representing various companies, played significant roles in the development of the 802.11u standard. It introduced mechanisms to enable mobile devices to seamlessly discover and connect to external networks, providing improved access and mobility for users. The 802.11u standard enhances the integration of Wi-Fi networks with other wireless and cellular networks, enabling a more unified and consistent user experience.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11u wireless standard will vary may be less or more, and may have changed over the period of time.

802.11v - 14th August 2011:

The 802.11v wireless standard, introduced on August 14, 2011, focuses on enhancing the management capabilities of wireless local area networks (WLANs). It is a Wi-Fi protocol extension that focuses on network management and optimization. Also known as Wireless Network Management (WNM), 802.11v provides enhanced capabilities for managing and configuring Wi-Fi networks. It introduces features such as network discovery, load balancing, and radio resource measurement, enabling more efficient network operation and improved user experience. 802.11v facilitates seamless handoff between access points, allowing devices to maintain a stable connection while moving within the network. It also supports efficient utilization of network resources by providing information on available channels and signal strengths. The 802.11v standard does not define specific data transfer rates, as its primary purpose is to enhance network management functionality rather than introducing new transmission technologies. Its implementation improves the overall performance and reliability of Wi-Fi networks. While the standard does not define specific transfer rates, it introduces features and mechanisms to improve network efficiency and performance. Here are some engineers and developers who contributed to its development:

1. Lingli Deng - Huawei Technologies
2. Abhishek Patil - Cisco Systems
3. Tom Alexander - Intel Corporation
4. Gregory Lebovitz - Qualcomm Atheros
5. Matthew Fischer - Broadcom Corporation
6. David Halasz - Cisco Systems
7. Michael Montemurro - Motorola Solutions
8. Mark D. Austin - Cisco Systems
9. Jon Rosdahl - CSR (now Qualcomm Technologies International)
10. Richard C. Rouillard - Hewlett-Packard

These engineers and developers, representing various companies, played significant roles in the development of the 802.11v standard. It introduced features such as network-assisted power management, optimized network selection, and improved network diagnostics. The 802.11v standard aims to enhance the management and operation of WLANs, resulting in improved network performance, power efficiency, and overall user experience.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11v wireless standard will vary may be less or more, and may have changed over the period of time.

802.11w - 7th June 2009:

The 802.11w wireless standard, introduced on June 7, 2009, focuses on enhancing the security of wireless local area networks (WLANs) by providing protection against unauthorized frame tampering and packet forgery. It is an extension to the Wi-Fi protocol that enhances wireless security by providing protection against unauthorized frame tampering. Also known as Protected Management Frames (PMF), 802.11w aims to prevent attacks such as frame forgery and injection in Wi-Fi networks. It introduces mechanisms to encrypt and authenticate management frames, which are used for network management and control purposes. By securing these frames, 802.11w mitigates the risk of malicious manipulation and improves the overall integrity of the wireless network. The 802.11w standard does not define specific data transfer rates as its primary focus is on enhancing security mechanisms rather than introducing new transmission technologies. Its implementation strengthens the security of Wi-Fi networks, ensuring the confidentiality and integrity of data transmissions. While the standard does not define specific transfer rates, it significantly improves the security mechanisms in wireless communications. Here are some engineers and developers who contributed to its development:

1. Jon Edney - Nortel Networks
2. William Arbaugh - University of Maryland
3. John R. Vollbrecht - Independent Consultant
4. Robert Moskowitz - ICSAlabs
5. Victor Lortz - Interlink Networks
6. David Halasz - Cisco Systems
7. Paul Lambert - Motorola Solutions
8. Robert H. Moskowitz - ICSAlabs
9. Matthew B. Shoemake - Intersil Corporation
10. Bruce A. Tuch - Intersil Corporation

These engineers and developers, representing various companies, played significant roles in the development of the 802.11w standard. It introduced the Protected Management Frames (PMF) feature, which adds an extra layer of security to wireless communications by ensuring the integrity and authenticity of management frames exchanged between devices. The 802.11w standard enhances the overall security posture of WLANs, protecting against attacks such as frame injection and spoofing.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11w wireless standard will vary may be less or more, and may have changed over the period of time.

802.11x - 17th December 2013:

There is no specific 802.11x wireless standard within the IEEE 802.11 series. The series includes various specifications for wireless local area networks (WLANs), but 802.11x does not exist as a standalone standard. 

802.11y - 8th September 2008:

The 802.11y wireless standard, introduced on September 8, 2008, also known as Wi-Fi Regional Area Network (WRAN), is an extension to the IEEE 802.11 series of standards. It was specifically developed to address the requirements for long-range wireless communication in rural areas or low-population density regions. It is an extension to the Wi-Fi protocol designed specifically for long-range outdoor deployments. Also known as the Wi-Fi Protected Access (WPA) and Wi-Fi Multimedia (WMM) extension, 802.11y operates in the 3650-3700 MHz frequency band and offers improved coverage and range compared to other Wi-Fi standards. This standard is primarily used for fixed outdoor applications, such as wireless internet service providers (WISPs), rural connectivity, and backhaul links. It supports higher transmit power levels and larger channel bandwidths, enabling extended range and improved performance over longer distances. While the exact data transfer rates may vary depending on the specific implementation, 802.11y is capable of delivering higher throughput and longer range compared to other Wi-Fi standards, making it suitable for outdoor scenarios that require robust and reliable wireless connectivity. The longer range of 802.11y makes it suitable for rural deployments, where the distance between access points (APs) or base stations may be greater.

The standard incorporates dynamic frequency selection (DFS) and transmit power control (TPC) mechanisms to ensure efficient use of the available spectrum. DFS allows devices operating in the 802.11y band to detect and avoid interference with radar systems, while TPC adjusts the transmit power of devices to comply with regulatory requirements and optimize performance.

802.11y offers data rates of up to 54 Mbps, similar to earlier Wi-Fi standards. However, its main advantage lies in its ability to provide reliable long-range communication in challenging environments.

One of the intended applications of 802.11y is to facilitate broadband access in rural or underserved areas where wired infrastructure may be limited. By deploying 802.11y networks, service providers can extend connectivity and offer internet access to areas that are difficult to reach through traditional wired connections.

It's worth noting that the adoption and deployment of 802.11y networks may vary across different regions due to regulatory considerations and frequency band availability.

802.11z - 30th March 2010:

There is no 802.11z wireless standard within the IEEE 802.11 series. The series includes various specifications for wireless local area networks (WLANs), but 802.11z does not exist as a standalone standard.

802.11ac - 12th December 2013:

The 802.11ac wireless standard, introduced on December 12, 2013, is also known as Wi-Fi 5. It offers significant improvements in transfer rates and overall wireless network performance. It is a Wi-Fi protocol that offers significant improvements in speed, capacity, and performance compared to its predecessors. Commonly referred to as "Wi-Fi 5," 802.11ac operates in the 5 GHz frequency band and utilizes wider channel bandwidths and advanced modulation techniques to achieve higher data transfer rates. It introduces multiple-input and multiple-output (MIMO) technology with up to eight spatial streams, allowing for faster and more efficient wireless communication. 802.11ac supports data rates of up to several gigabits per second, depending on the specific configuration and channel width. This standard is widely adopted and commonly used for high-bandwidth applications such as video streaming, online gaming, and large file transfers. It significantly improves the overall Wi-Fi experience by delivering faster speeds, greater capacity, and enhanced reliability. Here are some engineers and developers who contributed to its development:

1. Eldad Perahia - Intel Corporation
2. Juan Carlos Zúñiga - InterDigital Communications
3. Anuj Batra - Qualcomm Atheros
4. Eric Wong - Broadcom Corporation
5. Lingli Deng - Huawei Technologies
6. Tom Henderson - Ruckus Wireless (now part of CommScope)
7. Jim Lansford - Samsung Electronics
8. Katsuyuki Haneda - Panasonic Corporation
9. Gilad Shamir - Marvell Semiconductor
10. Shahrnaz Azizi - Cisco Systems

These engineers and developers, representing various companies, played significant roles in the development of the 802.11ac standard. It introduced advancements such as wider channel bandwidth, higher-order modulation schemes, and multi-user MIMO (MU-MIMO) technology. These improvements resulted in faster transfer rates and increased network capacity, allowing for improved performance and enhanced user experiences in Wi-Fi networks. The 802.11ac standard supports transfer rates of up to several gigabits per second under favorable conditions.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11ac wireless standard will vary may be less or more, and may have changed over the period of time.

802.11ad - 9th December 2012:

The 802.11ad wireless standard, introduced on December 9, 2012, is also known as WiGig. It focuses on providing high-speed wireless communication in the 60 GHz frequency band. It is a Wi-Fi protocol that operates in the 60 GHz frequency band. Also known as WiGig, 802.11ad offers extremely high data transfer rates and low-latency communication for short-range applications. This standard utilizes a wide bandwidth and advanced modulation techniques to achieve multi-gigabit-per-second data rates. It is primarily designed for high-bandwidth applications such as wireless docking, virtual reality, and high-definition video streaming. 802.11ad enables fast and reliable data transmission within a limited range, typically up to 10 meters. While its range is more limited compared to other Wi-Fi standards, 802.11ad excels in providing extremely high-speed wireless connectivity for applications that demand rapid data transfer. Here are some engineers and developers who contributed to its development:

1. Bruce Kraemer - Marvell Semiconductor
2. Ali Sadri - Intel Corporation
3. Perahia Eldad - Intel Corporation
4. Steven D. Gray - Texas Instruments
5. Golam Sorwar - NXP Semiconductors
6. Vinko Erceg - Broadcom Corporation
7. Santhosh Chandrasekaran - Wilocity (now Qualcomm Technologies International)
8. Harald W. Tauss - Samsung Electronics
9. Vivek Gupta - Panasonic Corporation
10. SeokJoo Koh - LG Electronics

These engineers and developers, representing various companies, played significant roles in the development of the 802.11ad standard. It introduced a new frequency band, enabling multi-gigabit transfer rates and supporting applications such as wireless docking, multimedia streaming, and virtual reality. The 802.11ad standard enables high-speed data transmission over short distances, providing extremely fast wireless connectivity for specific use cases and scenarios. Transfer rates can reach up to several gigabits per second, depending on the implementation and environmental conditions.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11ad wireless standard will vary may be less or more, and may have changed over the period of time.

802.11af - 21st January 2014:

The 802.11af wireless standard, introduced on January 21, 2014, is also known as "White-Fi" or "TV White Space." It focuses on utilizing unused frequency bands in the television spectrum for wireless communication. It is a Wi-Fi protocol extension that utilizes unused frequencies in the television white space (TVWS) spectrum for wireless communication. Also known as White-Fi, 802.11af allows Wi-Fi devices to operate in the frequency bands previously reserved for television broadcasts. This standard provides extended range and improved coverage compared to traditional Wi-Fi frequencies. It offers data transfer rates similar to other Wi-Fi standards, typically up to several hundred megabits per second. The 802.11af standard is designed to enable wireless connectivity in rural and underserved areas where the TVWS spectrum remains vacant. By leveraging these unused frequencies, it expands the availability of wireless networks and helps bridge the digital divide by providing internet access in areas with limited connectivity options. Here are some engineers and developers who contributed to its development:

1. Apurva N. Mody - BAE Systems
2. Carlos Cordeiro - Intel Corporation
3. Jianzhong Zhang - Microsoft Corporation
4. Wenyu Jiang - Huawei Technologies
5. Jie Hui - Broadcom Corporation
6. Karthik Ramachandran - Microsoft Corporation
7. Dapeng Liu - Huawei Technologies
8. Prashant Mangalvedhe - Qualcomm Atheros
9. Filippo Vismara - Nokia
10. Rashid Saeed - NXP Semiconductors

These engineers and developers, representing various companies, played significant roles in the development of the 802.11af standard. It enables the use of TV white spaces for wireless communication, providing extended range and improved coverage compared to traditional Wi-Fi frequencies. The 802.11af standard supports transfer rates that are comparable to other Wi-Fi standards, typically in the range of several tens of megabits per second. This standard is particularly useful for providing wireless connectivity in rural and underserved areas, where TV spectrum frequencies are available for use.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11af wireless standard will vary may be less or more, and may have changed over the period of time.

802.11ah - 14th May 2015:

The 802.11ah wireless standard, introduced on May 14, 2015, is also known as "Wi-Fi HaLow." It focuses on providing extended range and power-efficient wireless communication for Internet of Things (IoT) devices. It is a Wi-Fi protocol designed specifically for low-power, long-range applications in the Internet of Things (IoT) and Smart Home environments. Also known as Wi-Fi HaLow, 802.11ah operates in the sub-1 GHz frequency band, which allows for greater coverage and penetration compared to higher frequency Wi-Fi standards. This standard provides extended range and supports both indoor and outdoor deployments. It offers lower data transfer rates compared to other Wi-Fi standards, typically ranging from tens of kilobits to a few megabits per second. 802.11ah is optimized for low-power devices, enabling battery-efficient communication and supporting a large number of connected devices within a network. This standard is well-suited for applications such as sensor networks, home automation, and smart metering, where long-range coverage and power efficiency are essential. Here are some engineers and developers who contributed to its development:

1. Rajeev Agrawal - Qualcomm Atheros
2. Pei Liu - Huawei Technologies
3. Xiaodong Yang - Huawei Technologies
4. Osama Aboul-Magd - Intel Corporation
5. Carlos Cordeiro - Intel Corporation
6. Bernard Aboba - Microsoft Corporation
7. Rolf de Vegt - NXP Semiconductors
8. Peter Van Der Stok - Consultant
9. Abhijit Patra - Samsung Electronics
10. Takeshi Itagaki - Sony Corporation

These engineers and developers, representing various companies, played significant roles in the development of the 802.11ah standard. It operates in the Sub 1 GHz frequency band, offering improved range and penetration capabilities compared to other Wi-Fi standards. The 802.11ah standard focuses on low-power, extended-range applications, making it suitable for IoT devices with limited energy resources. Transfer rates in 802.11ah can vary depending on the implementation and environmental conditions but typically range from several kilobits per second up to tens of megabits per second.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11ah wireless standard will vary may be less or more, and may have changed over the period of time.

802.11ai - 11th December 2016:

The 802.11ai wireless standard, introduced on December 11, 2016, is also known as "Fast Initial Link Setup (FILS)." It focuses on improving the initial connection setup process for Wi-Fi networks. It is a Wi-Fi protocol that focuses on enhancing the network efficiency and user experience in dense and congested environments. Also known as Fast Initial Link Setup (FILS), 802.11ai improves the connection setup time for devices joining a Wi-Fi network. It reduces the authentication and association process, allowing devices to establish a connection quickly and efficiently. This standard employs techniques such as pre-authentication and pre-association, which enable devices to exchange authentication and network information in advance, expediting the connection establishment. By reducing the connection setup time, 802.11ai enhances the user experience, particularly in crowded Wi-Fi environments such as airports, stadiums, and conference venues. The 802.11ai standard does not define specific data transfer rates, as its primary focus is on optimizing the connection setup process rather than introducing new transmission technologies. Its implementation improves the overall network efficiency and responsiveness in high-density Wi-Fi environments. Here are some engineers and developers who contributed to its development:

1. Jean-Philippe Vasseur - Cisco Systems
2. Vijay Nagarajan - Qualcomm Technologies International
3. Tuncer Baykas - Huawei Technologies
4. Brian Hart - Intel Corporation
5. Mohit Talwar - Samsung Electronics
6. Carlos Cordeiro - Intel Corporation
7. Keun Yi - LG Electronics
8. Hemanth Sampath - Broadcom Corporation
9. Tomoko Adachi - Panasonic Corporation
10. Daniel Lee - HP Inc.

These engineers and developers, representing various companies, played significant roles in the development of the 802.11ai standard. It introduces mechanisms to accelerate the initial association and authentication process, reducing the time required for devices to connect to a Wi-Fi network. The 802.11ai standard aims to improve the user experience by minimizing connection setup delays and providing faster access to Wi-Fi services. While the standard does not define specific transfer rates, it focuses on optimizing the connection setup phase rather than enhancing data transfer speeds.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11ai wireless standard will vary may be less or more, and may have changed over the period of time.

802.11aj - 9th May 2018:

The 802.11aj wireless standard, also known as China Millimeter Wave (China mmWave), is an extension to the IEEE 802.11 series of standards. It specifically addresses the requirements for high-speed wireless communication in the millimeter-wave frequency range in China.

802.11aj operates in the 45 GHz frequency band, specifically between 45.24 GHz and 47.06 GHz. This frequency range offers a wide bandwidth and allows for high data rates. The standard is designed to enable wireless communication in short-range scenarios, typically within a room or limited area.

The main objective of 802.11aj is to provide multi-gigabit wireless connectivity for applications such as high-definition video streaming, virtual reality, augmented reality, and other data-intensive applications. It leverages the use of beamforming techniques to improve signal strength and reliability in millimeter-wave communication.

The standard defines several unique features and mechanisms to support efficient communication in the 802.11aj networks, including:

Beamforming: This technology enables the AP and client devices to establish and maintain directional beams to optimize signal transmission and reception.

Spatial Reuse: 802.11aj supports concurrent transmissions by multiple APs within the same area, improving overall network capacity and efficiency.

Hybrid Automatic Repeat Request (HARQ): HARQ is a technique used for error correction and retransmission of data packets, enhancing reliability in challenging wireless environments.

Channel Bonding: 802.11aj allows for the aggregation of multiple channels to increase the available bandwidth and achieve higher data rates.

It's important to note that the 802.11aj standard is specifically tailored for use in China. It aligns with the regulatory requirements and frequency allocations in the country. The standard ensures that devices operating in the 45 GHz frequency band comply with the specified limits and regulations.

To obtain the most accurate and up-to-date information about wireless standards, I recommend referring to the latest documentation and publications from the IEEE or other reliable sources.

802.11aq - 29th September 2016:

There is no 802.11aq wireless standard within the IEEE 802.11 series. The series includes various specifications for wireless local area networks (WLANs), but 802.11aq does not exist as a standalone standard.

802.11ax - 29th May 2019:

The 802.11ax wireless standard, introduced on May 29, 2019, is also known as Wi-Fi 6. It brings significant improvements to wireless networks in terms of speed, capacity, and efficiency. It is a Wi-Fi protocol that significantly enhances network capacity, efficiency, and performance in high-density environments. Also known as Wi-Fi 6, 802.11ax introduces several key technologies to improve overall network performance. It employs Orthogonal Frequency Division Multiple Access (OFDMA) to efficiently allocate and manage wireless resources, allowing multiple devices to transmit and receive data simultaneously. This standard also incorporates Multi-User Multiple Input Multiple Output (MU-MIMO) technology, which enables better utilization of available bandwidth by simultaneously serving multiple devices. Additionally, 802.11ax supports higher data transfer rates, with theoretical peak speeds of up to 10 Gbps. This standard is designed to deliver faster and more reliable Wi-Fi connections, particularly in crowded areas such as stadiums, airports, and urban environments where numerous devices are connected. Wi-Fi 6 provides improved network efficiency, reduced latency, and enhanced performance, ensuring a better user experience in the era of high-demand applications, such as streaming 4K/8K videos, online gaming, and smart home devices. Here are some engineers and developers who contributed to its development:

1. Eldad Perahia - Qualcomm Atheros
2. Sachin Ganu - Broadcom Corporation
3. Karthik Sundaresan - NEC Corporation
4. Yasuhiko Inoue - Sony Corporation
5. Hongyuan Zhang - Huawei Technologies
6. Xiaogang Chen - Intel Corporation
7. Hanbyul Seo - LG Electronics
8. Jiamin Chen - Samsung Electronics
9. Haijun Zhang - ZTE Corporation
10. Ali Sadri - Intel Corporation

These engineers and developers, representing various companies, played significant roles in the development of the 802.11ax standard. It introduces features such as Orthogonal Frequency Division Multiple Access (OFDMA), Multi-User Multiple Input Multiple Output (MU-MIMO), Target Wake Time (TWT), and improved channel utilization. These advancements allow for higher data transfer rates, increased network capacity, and better performance in high-density environments. The 802.11ax standard supports transfer rates of several gigabits per second under favorable conditions, providing faster and more reliable Wi-Fi connectivity for a wide range of devices.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11ax wireless standard will vary may be less or more, and may have changed over the period of time.

802.11ay - 7th May 2021:

The 802.11ay wireless standard, introduced on May 7, 2021, is an amendment to the IEEE 802.11 series that focuses on high-speed wireless communication in the 60 GHz frequency band. It is a Wi-Fi protocol that operates in the 60 GHz frequency band, commonly referred to as the millimeter wave (mmWave) spectrum. 802.11ay builds upon the advancements of previous standards and offers even higher data transfer rates and improved capacity. It utilizes Multiple-Input Multiple-Output (MIMO) technology with up to eight spatial streams, enabling faster and more reliable wireless communication. This standard supports data transfer rates of up to several tens of gigabits per second, making it suitable for applications that require extremely high-speed connectivity, such as wireless backhaul, high-definition video streaming, and virtual reality. 802.11ay also offers improved outdoor range compared to its predecessor, 802.11ad, while maintaining low latency and high throughput. This standard is designed to meet the growing demands of bandwidth-intensive applications and deliver high-performance wireless connectivity in environments where high-speed data transfer is critical. Here are some engineers and developers who contributed to its development:

1. Juergen Peissig - Intel Corporation
2. Carlos Cordeiro - Intel Corporation
3. Alireza Babaei - Huawei Technologies
4. Liwen Chu - Qualcomm Technologies International
5. Jouni Malinen - Qualcomm Technologies International
6. Osama Aboul-Magd - Intel Corporation
7. Rolf de Vegt - NXP Semiconductors
8. Liang Li - Huawei Technologies
9. Takeshi Itagaki - Sony Corporation
10. Gurkan Solmaz - Samsung Electronics

These engineers and developers, representing various companies, played significant roles in the development of the 802.11ay standard. It builds upon the previous 802.11ad standard (WiGig) and offers even higher data rates, increased range, and improved multi-device operation. The 802.11ay standard supports multi-gigabit per second data transfer rates, allowing for applications such as high-definition video streaming, virtual reality, and wireless docking. It provides ultra-fast wireless connectivity over short distances, making it suitable for scenarios that require high-bandwidth communication.

Please note that this is not an exhaustive list of engineers and developers from different organizations. The provided list of engineers and developers from different organizations that have contributed to the development of Wi-Fi technology, which is named as 802.11ay wireless standard will vary may be less or more, and may have changed over the period of time.

For any relevant further information, kindly visit the IEEE 802.11 series of standards.

Don't walk as you are the king, walk as you don't care who the king is....!!