E-band in 5G refers to a specific range of frequencies in the millimeter wave spectrum, typically around 60 GHz. In 5G networks, E-band is used to provide high-speed data rates and low-latency communications in urban and densely populated areas.
E-band frequencies enable operators to achieve multi-gigabit per second (GBPS) speeds, supporting applications such as high-definition video streaming, augmented reality (AR), virtual reality (VR), and communications Ultra-Reliable Low Latency (URLLC) .
E-band is used for point-to-point communications links, backhaul connections for cellular networks, and other high-capacity applications requiring robust, high-speed wireless connections over relatively short distances.
Its deployment in 5G networks complements low-frequency bands to provide deep coverage and support for the growing demand for data-intensive services and applications.
E-band and V-band are segments in the millimeter wave spectrum used for telecommunications and wireless communications applications. E-band typically ranges from around 60 GHz to 90 GHz, while V-band spans frequencies from 40 GHz to 75 GHz. Both bands are used for high-capacity, short-range communications such as point-to-point links, backhaul connections and broadband wireless access.
They enable operators to offer high data speeds and low latency, supporting the growing demand for high-speed Internet access and mobile connectivity in urban environments.
5G operates on various frequency bands, including low-band (sub-6 GHz) and high-band (millimeter wave) frequencies. The MHz (Megahertz) of 5G refers to the bandwidth allocated in these frequency bands for data transmission. Different bands have different MHz allocations, with higher frequencies generally providing greater bandwidth capacity but shorter range compared to lower frequencies.
MHz allocation in 5G is crucial in determining the data speeds and capacity that can be delivered to users based on available spectrum and network configuration.
The 3500 MHz band for 5G refers to the frequency band around GHz that is widely used to deploy 5G networks around the world. This intermediate spectrum provides a balance between coverage and capacity, providing higher data rates and lower latency compared to lower frequency (sub-6 GHz) bands.
The 3500 MHz band is particularly valuable for urban and suburban deployments where a mix of coverage and capacity is needed to support a wide range of 5G applications, including enhanced mobile broadband (EMBB) and certain aspects of URLLC