Your search keyword '"Adve, Raviraj S."' showing total 7 results

1. Semi-Blind Time-Domain Channel Estimation for Frequency-Selective Multiuser Massive MIMO Systems.

Author

Mirzaei, Javad, Adve, Raviraj S., and Shahbazpanahi, Shahram

Subjects

*CHANNEL estimation, *MIMO systems, *BROADBAND receivers, *FOURIER transforms, *COVARIANCE matrices, *EIGENVECTORS, *ANTENNAS (Electronics)

Abstract

The availability of accurate channel state information (CSI) is essential in multiuser massive multiple-input multiple-output (MIMO) systems. However, most published works focus on frequency-flat channel estimation which requires that the estimation must be repeated for every frequency slot, e.g., subcarrier, in a broadband system. Since the channels in the frequency-domain are the Fourier transform of a small set of time-domain channel coefficients, the time-domain channel estimation requires that fewer parameters be estimated. In this paper, we propose a semi-blind, time-domain, channel estimation technique for frequency-selective massive MIMO systems. Our solution depends on the subspace spanned by the signal eigenvectors of the received signal covariance matrix. Importantly, since the receiver samples at the symbol rate, time-domain-based estimation inherently has available enough samples for an accurate matrix estimate. To avoid asymptotic assumptions, we express each channel vector as a linear combination of the signal eigenvectors. We estimate the linear combination using a set of training symbols. Given the many samples of the received signal in the time-domain, we obtain a better channel estimate compared to conventional subcarrier-wise frequency-domain channel estimation. Unlike the previous published results, in this paper, we do not assume orthogonality of users’ channels or knowledge of large-scale fading coefficients. In addition, our estimation procedure does not require orthogonality between the training symbols of the users in all cells. [ABSTRACT FROM AUTHOR]

Published

2019

2. On the Stability of Distributed Power Control Algorithms Under Imperfect Estimation of Channel and Interference.

Author

Karamad, Ehsan and Adve, Raviraj S.

Subjects

*DISTRIBUTED power generation, *ALGORITHMS, *MATHEMATICAL optimization, *INTERFERENCE (Telecommunication), *NOISE control, *MATHEMATICAL models

Abstract

The distributed power control algorithms available in this paper assume perfect estimation of interference power at the receivers and often, the availability of perfect local channel state information (CSI). However, perfect estimation of interference power or acquisition of channel information is impractical. In this paper, we consider a generic class of distributed power control algorithms and analyze the resulting performance loss when faced with errors in CSI and/or interference level estimation. We approximate such power control algorithms with linearized state space dynamics wherein the errors in the estimation of received interference or the CSI, can be modeled as additive observation noise. Based on the proposed model, we derive lower bounds on the norm of the errors in the transmit power vector and receive signal-to-interference-plus-noise ratio (SINR) vector. Our analysis suggests that when the target SINR vector approaches the Pareto-optimal bound, the errors in the transmit vectors could grow without bound. As a consequence, to maintain a performance loss within an acceptable range, either much longer estimation times or lower target SINRs are required. Our numerical results confirm the validity of our analysis and the validity of the proposed bounds. [ABSTRACT FROM PUBLISHER]

Published

2017

3. Analyzing the Impact of Inter Cooperation Region Interference in Coordinated Multi-Point Uplink Networks.

Author

Banani, S. Alireza and Adve, Raviraj S.

Subjects

*CELL phone systems, *MOBILE communication systems, *WIRELESS communications, *TELECOMMUNICATION systems, *GSM communications

Abstract

We analyze the uplink of coordinated multi-point (CoMP) networks in which cooperation can be amongst $N=2$ or $N=3$ base stations (BSs). We consider a 2-D network of BSs on a regular hexagonal lattice wherein the cooperation tessellates the 2-D plane into cooperation regions (CRs); specifically, we analyze the impact of the interference between the CRs in the network. Our model accounts realistic propagation conditions, particularly including shadowing. We obtain accurate, closed-form, approximations for the user capacity coverage probability (CCP) and the ergodic capacity at each point within the CR. To provide a network-level analysis, we focus on the locations within each CR with the minimum CCP—“the worst-case point(s)”. The worst-case CCP and/or ergodic capacity can be used in parametric studies for network design. Here, the analysis is applied to obtain the relationship between cell size and CCP and, thereby, the required density of BSs to achieve a chosen target capacity coverage. The analysis also allows for a comparison between different orders of BS cooperation, quantifying the reduced required BS density from higher orders of cooperation. Comprehensive simulations are used to illustrate the accuracy of our analysis, including the approximations used for analytic tractability. [ABSTRACT FROM PUBLISHER]

Published

2015

4. Distributed Massive MIMO Systems With Non-Reciprocal Channels: Impacts and Robust Beamforming.

Author

Minasian, Arin, Shahbazpanahi, Shahram, and Adve, Raviraj S.

Subjects

*MIMO systems, *CHANNEL estimation, *CALIBRATION, *BEAMFORMING, *WIRELESS communications

Abstract

Hardware calibration is essential to restore the uplink/downlink channel reciprocity for multi-user massive multiple-input multiple-output (MIMO) systems operating in a time division duplexing mode. Unfortunately, due to the associated overhead, calibration cannot be performed frequently; furthermore, any calibration procedure leaves behind a residual mismatch between the uplink and downlink channels. In this paper, we study the effects of these calibration errors on the achievable rates in the downlink of a multi-cell, multi-user, and distributed massive MIMO system. Specifically, we develop accurate, yet simple, lower-bounds on the per-user achievable rate, assuming either zero-forcing (ZF) or matched filtering (MF) are used. We also introduce a performance loss coefficient as a measure of sensitivity of the performance to the calibration errors. Using this measure, we identify the conditions under which ZF precoding is more sensitive to calibration errors than MF. Finally, we consider the robust weighted sum-rate maximization problem to mitigate the degrading effects of non-ideal calibration. Our numerical experiments show that the rate lower-bounds developed in this paper accurately quantify the impacts of non-ideal calibration on performance. Also, the proposed robust beamforming scheme improves the average sum-rate by up to 42% compared with the other available schemes. [ABSTRACT FROM AUTHOR]

Published

2018

5. Minimizing Sum-MSE Implies Identical Downlink and Dual Uplink Power Allocations.

Author

Tenenbaum, Adam J. and Adve, Raviraj S.

Subjects

*MIMO systems, *MULTIUSER computer systems, *ALGORITHMS, *ITERATIVE methods (Mathematics), *MATHEMATICAL optimization, *RESOURCE management, *PROBLEM solving

Abstract

In the multiuser downlink, power allocation for linear precoders that minimize the sum of mean squared errors under a sum power constraint is a non-convex problem. Many existing algorithms solve an equivalent convex problem in the virtual uplink and apply a transformation based on uplink-downlink duality to find a downlink solution. In this letter, we analyze the optimality criteria for the power allocation subproblem in the virtual uplink, and demonstrate that the optimal solution leads to identical power allocations in the downlink and virtual uplink. We thus extend the known duality results and, importantly, simplify the existing algorithms used for iterative transceiver design. [ABSTRACT FROM PUBLISHER]

Published

2011

6. Analyzing the Impact of Access Point Density on the Performance of Finite-Area Networks.

Author

Banani, S. Alireza, Eckford, Andrew W., and Adve, Raviraj S.

Subjects

*POINT processes, *APPROXIMATION theory, *SIGNAL-to-noise ratio, *INTERFERENCE (Telecommunication), *BANDWIDTHS

Abstract

Assuming a network of infinite extent, several researchers have analyzed small-cell networks using a Poisson point process (PPP) location model, leading to simple analytic expressions. The general assumption has been that these results apply to finite-area networks as well. However, do the results of infinite-area networks apply to finite-area networks? In this paper, we answer this question by obtaining an accurate approximation for the achievable signal-to-interference-plus-noise ratio (SINR) and user capacity in the downlink of a finite-area network with a fixed number of access points (APs). The APs are uniformly distributed within the area of interest. Our analysis shows that, crucially, the results of infinite-area networks are very different from those for finite-area networks of low-to-medium AP density. Comprehensive simulations are used to illustrate the accuracy of our analysis. For practical values of signal transmit powers and AP densities, the analytic expressions capture the behavior of the system well. As an added benefit, the formulations developed here can be used in parametric studies for network design. Here, the analysis is used to obtain the required number of APs to guarantee a desired target capacity in a finite-area network. [ABSTRACT FROM AUTHOR]

Published

2015

7. Optimizing the MIMO Cellular Downlink: Multiplexing, Diversity, or Interference Nulling?

Author

Hosseini, Kianoush, Zhu, Caiyi, Khan, Ahmad Ali, Adve, Raviraj S., and Yu, Wei

Subjects

*MIMO systems, *WIRELESS communications, *ANTENNAS (Electronics), *SPATIAL systems, *BEAMFORMING, *INTERFERENCE (Telecommunication)

Abstract

A base-station (BS) equipped with multiple antennas can use its spatial dimensions in three different ways: 1) to serve multiple users, thereby achieving a multiplexing gain; 2) to provide spatial diversity in order to improve user rates; and 3) to null interference in neighboring cells. This paper answers the following question: What is the optimal balance between these three competing benefits? We answer this question in the context of the downlink of a cellular network, where multi-antenna BSs serve multiple single-antenna users using zero-forcing beamforming with equal power assignment, while nulling interference at a subset of out-of-cell users. Any remaining spatial dimensions provide transmit diversity for the scheduled users. Utilizing tools from stochastic geometry, we show that, surprisingly, to maximize the per-BS ergodic sum rate, with an optimal allocation of spatial resources, interference nulling does not provide a tangible benefit. The strategy of avoiding inter-cell interference nulling, reserving some fraction of spatial resources for multiplexing, and using the rest to provide diversity, is already close-to-optimal in terms of the sum-rate. However, interference nulling does bring significant benefit to cell-edge users, particularly when adopting a range-adaptive nulling strategy where the size of the cooperating BS cluster is increased for cell-edge users. [ABSTRACT FROM AUTHOR]

Published

2018