In this letter, we analyze the spectral and energy efficiency of an intelligent reflecting surface (IRS)-assisted multiple-input single-output (MISO) downlink system with hardware impairments. An extended error vector magnitude (EEVM) model is utilized to characterize the impact of radio-frequency (RF) impairments at the access point (AP) and phase noise is considered for the imperfect IRS. We show that the spectral efficiency is limited due to the hardware impairments even when the numbers of AP antennas and IRS elements grow infinitely large, which is in contrast with the conventional case with ideal hardware. Moreover, the performance degradation at high SNR is shown to be mainly affected by the AP hardware impairments rather than the phase noise of IRS. We further obtain the optimal transmit power in closed form for energy efficiency maximization. Simulation results are provided to verify these results.
Index TermsIntelligent reflecting surface, hardware impairments, downlink spectral efficiency, energy efficiency.
I. INTRODUCTION
INTELLIGENT reflecting surface (IRS) has recently been acknowledged as a promising new technology to realize spectral-, energy-and cost-efficient wireless communication for the fifth generation network and beyond [1]. IRS is a planar array consisting of a large number of low-cost reflecting elements,
Ambient backscatter communication has shown great potential in the development of future wireless networks.It enables a backscatter transmitter (BTx) to send information directly to an adjacent receiver by modulating over ambient radio frequency (RF) carriers. In this paper, we consider a cooperative ambient backscatter communication system where a multi-antenna cooperative receiver separately decodes signals from an RF source and a BTx. Upper bounds of the ergodic rates of both links are derived. The power scaling laws are accordingly characterized for both the primary cellular transmission and the cooperative backscatter. The impact of additional backscatter link is also quantitatively analyzed. Simulation results are provided to verify the derived results.
Index TermsAmbient backscatter, cooperative receiver, successive interference cancellation, ergodic rate.
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