Abstract
The use of Aerial Base Stations (ABSs) has received a great deal of attention in academia and industry as a means to support the cellular communication traffic growth. In this article, we focus on obtaining the optimal altitude of an ABS using two criteria - maximum cell coverage area and minimum Symbol Error Rate (SER). Our study is done by using a probabilistic air-to-ground channel model, developed for low altitude aerial platforms via simulations on a commercial ray tracing software, for different scenarios like Urban High Rise, Urban, and Suburban. The probability distributions of the received power of the ground users and of the power delay profile at optimal ABS altitude are provided as a function of the size of the cell area. For the SER analysis, we present a system model based on Generalized Frequency Division Multiplexing (GFDM), in a time-frequency grid that is compatible with Long Term Evolution, by implementing parameters for low latency communication at the physical layer. The impact of “Better than Nyquist” pulses on the GFDM system is evaluated in terms of SER performance. From the presented results, a significant improvement is demonstrated compared to the traditional Nyquist pulses.
Highlights
T HE unmanned aerial vehicles (UAVs1), commonly known as drones, have received a rapid proliferation in various applications due to their progress in payload capacity and prolonged battery life [2]
The symbol-error-rate (SER) analysis was conducted for Generalized Frequency Division Multiplexing (GFDM) based A2G communication with variation of UAV altitude and “Better than Nyquist” (BTN) pulse shaping filters in urban high rise, urban, and suburban environments
We evaluate GFDM and orthogonal frequency division multiplexing (OFDM) Symbol Error Rate (SER) for static and moving aerial base stations (ABSs) under various Nyquist and BTN pulse shaping filters
Summary
T HE unmanned aerial vehicles (UAVs1), commonly known as drones, have received a rapid proliferation in various applications due to their progress in payload capacity and prolonged battery life [2]. An ABS can provide ondemand cellular coverage and enhanced data rates to the ground mobile users in a heterogeneous network (HetNet). In this regards, the third generation partnership group (3GPP) provided a technical report, entitled, “Enhanced LTE support for aerial vehicles” in September 2019 with four crucial requirements, as discussed with detail in [7]; listed as UAV traffic requirements; channel modeling to characterize air-toground (A2G) propagation; possibility to reuse the current LTE framework for aerial vehicles; and definition of enhancements in LTE Release 17 to assist UAV network.
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