Resumen

El estándar IEEE 802.11 de red de área local inalámbrica se ha desarrollado por más de 28 años desde su primera versión con velocidad a 2 Mbit/s. La última versión de Wi-Fi está por aparecer, la versión ax, que alcanza la velocidad de 10 Gbit/s. IEEE 802.11ax fue concebido en 2014 con el objetivo de mejorar el rendimiento por área en escenarios de alta densidad. Describiremos las principales características de 802.11ax. En este trabajo se hace una revisión bibliográfica de las principales diferencias entre este nuevo estándar y las versiones anteriores. Entre las diferencias se pueden mencionar las siguientes; el enfoque de acceso aleatorio con división de frecuencia ortogonales, nuevas técnicas de reutilización de canales espaciales y control de potencia. Además, se destacarán otras mejoras significativas seleccionadas; incluyendo mejoras en la capa física, múltiples usuarios con múltiples entradas y salidas, avances en el ahorro de energía, etc. que hacen este estándar una mejora importante con respecto a su predecesor 802.11ac.

Palabras clave: Ahorro de potencia, Calidad de servicio, OFDMA, MU-MIMO, Redes de alta densidad, Redes de alta eficiencia.

 

Abstract

The IEEE 802.11 wireless local area network standard has been developed for more than 28 years since its first version with a speed of 2 Mbit / s. The latest version of Wi-Fi is about to appear, the ax version, which reaches the speed of 10 Gbps. IEEE 802.11ax was conceived in 2014 with the objective of improving performance per area in high density scenarios. We will describe the main features of 802.11ax, among which may be mentioned the following; the random access approach with orthogonal frequency division, new spatial channel reuse techniques and power control. In addition, other significant improvements selected will be highlighted; including improvements in the physical layer, multiple users with multiple inputs and outputs, advances in energy saving, etc. that make this standard a significant improvement over its predecessor 802.11ac.

Keywords: High density networks, High efficiency networks, OFDMA, MU-MIMO, QoS, Power saving.

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