Abstract
We consider a power constrained downlink communication scenario where energy efficiency, reliability, and latency take precedence over rate, as in some Internet of Things (IoT) applications. To reduce its receiver power consumption and complexity, we assume that the IoT device has a single RF chain and investigate the finite-resolution analog-to-digital converter (ADC) operation with differential Phase Shift Keying (PSK) modulation. A lower ADC resolution leads to an exponential decrease in power consumption, while adopting differential PSK enables the use of a low-cost detector with no channel state information (CSI) or carrier phase recovery circuitry. Our main goal in this article is to compare, both analytically and numerically using representative IoT system design parameters, the receiver energy efficiency of the proposed differential PSK system with a coherent PSK system that uses estimated CSI under reliability and latency constraints in Rayleigh slow-fading and ADC quantization distortion conditions. To mitigate the ADC finite-resolution effects without requiring CSI at the receiver or transmitter, we propose and analyze a PSK differentially-modulated Alamouti space-time block transmission scheme with only two RF chains at the transmitter while still restricting the IoT device to have a single RF chain. Our results demonstrate that in the considered low-rate, and outage and latency-constrained scenario with stringent power consumption requirements, differentially-modulated Alamouti transmissions to a single RF-chain IoT device with a low-resolution ADC is an attractive choice in terms of receiver energy efficiency, reliability, and transmission latency.
Highlights
A major challenge in Internet-of-Things (IoT) communications is the power consumption constraint at the device due to its limited battery life
Unlike these works which assumed coherent quadrature amplitude modulation (QAM) schemes, we propose using differential phase shift keying (DPSK) as a low-complexity spectrally-efficient modulation scheme that eliminates the need for channel estimation at the receiver and feeding it back to the transmitter
We analyzed the outage probability, transmission latency, and constrained energy efficiency of DPSK for a slow-fading low-rate downlink to a power-constrained device with a single radio frequency (RF) chain and a finite-resolution analog-to-digital converter (ADC)
Summary
A major challenge in Internet-of-Things (IoT) communications is the power consumption constraint at the device due to its limited battery life. The studied communication scenario assumes low mobility and narrow bandwidth operation at a sub 6 GHz carrier frequency under a device low-power-consumption constraint with low-rate and given reliability (outage probability) and latency requirements This scenario is vastly different from the other ADC low-resolution scenarios previously studied in the literature that mainly focused on massive Multi-Input Multi-Output (MIMO) receivers We quantify the potential outage probability reductions, transmission latency reductions, and energy efficiency gains of DPSK over coherent PSK with estimated channel state information at the receiver (CSIR) as a function of operating system parameters such as ADC bit resolution, target rate, and input SNR.
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