Aditya Chopra scite author profile

We present measurements and analysis of self-interference in multi-panel millimeter wave (mmWave) full-duplex communication systems at 28 GHz. In an anechoic chamber, we measure the self-interference power between the input of a transmitting phased array and the output of a colocated receiving phased array, each of which is electronically steered across a number of directions in azimuth and elevation. These self-interference power measurements shed light on the potential for a full-duplex communication system to successfully receive a desired signal while transmitting in-band. Our nearly 6.5 million measurements illustrate that more self-interference tends to be coupled when the transmitting and receiving phased arrays steer their beams toward one another but that slight shifts in steering direction (on the order of one degree) can lead to significant fluctuations in self-interference power. We analyze these measurements to characterize the spatial variability of self-interference to better quantify and statistically model this sensitivity. Our analyses and statistical results can be useful references when developing and evaluating mmWave full-duplex systems and motivate a variety of future topics including beam selection, beamforming codebook design, and self-interference channel modeling. I. INTRODUCTIONResearch on full-duplex millimeter wave (mmWave) systems has been motivated by the potential for dense antenna arrays to strategically steer transmit and receive beams in a way

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Statistical Modeling of Co-Channel Interference

Gulati

Chopra

Evans

et al. 2009

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Abstract-With increasing spatial reuse of the radio spectrum, co-channel interference is becoming the dominant noise source and may severely degrade the communication performance of wireless transceivers. In this paper, we consider the problem of statistical-physical modeling of co-channel interference. Statistical modeling of interference is a useful tool to analyze the outage probabilities in wireless networks and to design interference-aware transceivers. Our contributions include (1) developing a unified framework to derive interference models for various wireless network environments, (2) demonstrating the applicability of the symmetric alpha stable and Middleton Class A distributions in modeling co-channel interference in ad-hoc and cellular network environments, and (3) deriving analytical conditions on the system model parameters for which these distributions accurately model the statistical properties of the interference. Simulation results allow us to compare the key properties of empirical co-channel interference and their statistical models under different wireless network environments.

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Outage Probability for Diversity Combining in Interference-Limited Channels

Chopra

Evans

2013

IEEE Trans. Wireless Commun.

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Many wireless data communication systems such as LTE, and Wi-Fi, are increasingly facing interference that is much stronger than thermal noise. Interference may arise due to dense spatial reuse of spectrum intended to increase user data rates, or from other devices emitting radiation in the same spectrum, or from electronic circuitry within the communication platform. For a multi-antenna receiver operating in an interference-limited channel, we evaluate four diversity combining algorithms in terms of outage probability in the low-outage regime. The contributions of this paper are (1) derivation of closed-form expressions for the output signalto-interference ratio (SIR) statistics of fixed weight, maximal ratio, selection and post-detection combining; (2) comparison of the relative outage performance of these algorithms; and (3) proposed diversity combining algorithms to reduce outage probability. Our results can be applied in analyzing the outage performance and throughput capacity of both centralized and decentralized interference-limited wireless networks.Index Terms-Co-channel interference, symmetric alpha stable, Poisson point processes, impulsive noise, diversity reception, outage probability, spatial dependence.

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Total variation, adaptive total variation and nonconvex smoothly clipped absolute deviation penalty for denoising blocky images

Chopra

Lian

2010

Pattern Recognition

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The total variation-based image denoising model has been generalized and extended in numerous ways, improving its performance in different contexts. We propose a new penalty function motivated by the recent progress in the statistical literature on high-dimensional variable selection. Using a particular instantiation of the majorization-minimization algorithm, the optimization problem can be efficiently solved and the computational procedure realized is similar to the spatially adaptive total variation model. Our twopixel image model shows theoretically that the new penalty function solves the bias problem inherent in the total variation model. The superior performance of the new penalty is demonstrated through several experiments. Our investigation is limited to "blocky" images which have small total variation.

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Performance bounds of MIMO receivers in the presence of radio frequency interference

Chopra

Gulati

Evans

et al. 2009

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Aditya Chopra

Beamformed Self-Interference Measurements at 28 GHz: Spatial Insights and Angular Spread

Statistical Modeling of Co-Channel Interference

Outage Probability for Diversity Combining in Interference-Limited Channels

Total variation, adaptive total variation and nonconvex smoothly clipped absolute deviation penalty for denoising blocky images

Performance bounds of MIMO receivers in the presence of radio frequency interference

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