Wi-Fi 8 promises a lot — from smooth extended reality experiences to safer cities and roads to improved roaming and data offloading, thanks to proposed features like Multi-Access Point Coordination (MAPC) and integrated mmWave — but that’s all it is right now: promises. There’s still a lot to work out, on the technical level, to achieve some of the things the industry says to expect once Wi-Fi 8 devices start making their way into our homes and businesses.
Below are some of the challenges associated with making ultra-reliable Wi-F a reality:
- RF interference and network congestion. Because Wi-Fi operates in unlicensed spectrum bands, it is highly susceptible to interference from neighboring networks, Bluetooth devices and other RF sources. While the introduction of wider 320 MHz channels in Wi-Fi 7 helps mitigate congestion, device density will continue to increase in urban environments, stadiums and industrial settings, and therefore, interference management will remain a major challenge for Wi-Fi 8. Solutions like AI-driven dynamic frequency selection (DFS) and adaptive power control will be essential for minimizing interference and ensuring reliability.
- Seamless roaming and mobility challenges. For ultra-reliable connectivity, Wi-Fi networks must ensure seamless roaming between Access Points (APs) without packet loss or interruptions. This is particularly important for enterprise environments, warehouses and healthcare facilities where mobile devices continuously move across coverage zones. Wi-Fi 6E and Wi-Fi 7 have improved Fast BSS Transition — also known as IEEE 802.11r — a protocol that allows wireless clients to quickly switch between APs within the same Extended Service Set (ESS) without needing to re-authenticate with the network. But Wi-Fi 8 must further enhance these roaming protocols to enable near-instantaneous handoffs, potentially leveraging AI-driven predictive mobility solutions.
- Balancing power efficiency and reliability. Many reliability-critical use cases—such as industrial sensors and medical monitoring devices—depend on battery-powered Wi-Fi devices. Maintaining a balance between power efficiency and ultra-reliable connectivity is a complex challenge. Low-power modes, such as TWT, help extend battery life but can introduce communication delays. Wi-Fi 8 will need to develop smarter energy-saving mechanisms that do not compromise reliability for mission-critical applications.
- Infrastructure and backhaul limitations. Even if Wi-Fi 8 offers higher throughput and reliability at the radio layer, overall performance is still dependent on the underlying infrastructure. Many enterprise and public networks still rely on aging backhaul solutions, such as traditional gigabit Ethernet, which may not support the ultra-low latency and high throughput demands of Wi-Fi 8. The adoption of multi-gigabit Ethernet and fiber-optic backhaul solutions will be critical to delivering end-to-end reliability.
- Regulatory and standardization hurdles. There is no new spectrum planned for Wi-Fi 8; however, many are of the opinion that the next standard will, in fact, require access to additional spectrum, possibly in the 7 GHz or higher frequency bands. But, as we are seeing with the 6 GHz band, spectrum allocation varies by region, with different regulatory bodies setting different rules. Additionally, interoperability across devices and vendors remains a challenge, requiring strong industry collaboration to establish universal standards for reliability.
Final thought: Wi-Fi 8 is not just about keeping up with growing data demands — it’s about ensuring that connectivity is more predictable, efficient and resilient than ever before.
