Spatial diversity is one of those fundamental technologies used in wireless communications
(cellular networks, Wi-Fi, satellite communications, and broadcasting) that does not get much exposure. The technology is used to combat fading and improve signal quality, enabling reliable communication links, especially in challenging environments characterized by obstacles, interference, or long propagation distances. Let’s take an introductory look.
Spatial diversity exploits the spatial dimension of wireless channels by deploying multiple antennas at either the transmitter or receiver, or both. By leveraging spatial separation between antennas, spatial diversity techniques minimize the effects of fading, which result from signal attenuation, reflections, and scattering in multipath propagation environments. Through the simultaneous reception of multiple independent copies of a transmitted signal, spatial diversity enhances the likelihood of receiving at least one strong signal, thus improving the overall reliability of communication links.
There are three key methods involved - Selection Diversity, Maximal Ratio Combining (MRC) and Equal Gain Combining (EGC).
Selection Diversity: In selection diversity, multiple antennas are strategically placed to receive the same signal, and the antenna with the highest received signal strength is chosen for further processing. This technique is relatively simple to implement and offers improved diversity gain, particularly in scenarios with moderate to severe fading.
Maximal Ratio Combining (MRC): MRC combines signals from multiple antennas with different complex weights, determined based on the channel conditions. By weighting each received signal based on its signal-to-noise ratio (SNR) and combining them coherently, MRC maximizes the received signal power, thereby enhancing the overall signal quality and reliability.
Equal Gain Combining (EGC): EGC employs a simpler approach by combining signals from multiple antennas with equal weights. While less complex than MRC, EGC provides diversity gain by mitigating the impact of fading through signal averaging.
Spatial diversity offers an effective mechanism to combat fading and enhance signal reliability. Through the strategic deployment of multiple antennas and the application of diverse combining techniques, the technology improves data transmission across a wide range of environments and applications.