![]() ![]() 5, a block diagram of an example of a computing device 500 suitable for use in implementations of the technology described herein is provided. To this end, we show that the amount of the overlap can be optimized via adjusting $\alpha$ to achieve a certain design objective. The at least one preferred cell (e.g., the preferred pCell) may adjust the uplink data speed and/or downlink data speed of the user device. Therefore, we propose a novel fine-grained duplexing scheme, denoted as $\alpha$-duplex scheme, which allows a partial overlap between uplink and downlink frequency bands. The study shows that FD communications improve the downlink throughput at the expense of significant degradation in the uplink throughput. The developed model accounts for uplink truncated channel inversion power control in FD cellular networks. For the sake of rigorous analysis, we develop a tractable framework based on stochastic geometry toolset. This paper presents an extensive study of the explicit effect of FD communications on the uplink and downlink performances. However, the explicit impact of spatial interference, imposed by FD communications, on uplink and downlink transmissions has been overlooked in the literature. Using a phone, the Motorola T280, we measured an improved maximum bandwidth, to 5.5 kB/s in the downlink direction. In-band full-duplex (FD) communications have been optimistically promoted to improve the spectrum utilization in cellular networks. The communication going from a satellite to ground is called downlink, and when it is going from ground to a satellite it is called uplink. downlink channels, one uplink), we observed a maximum raw downlink throughput of about 4.15 kB/s, and an uplink throughput of 1.4 kB/s. ![]()
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