Abstract
Massive multiple-input multiple-output (MIMO) techniques have the potential to bring tremendous improvements in spectral efficiency to future communication systems. Counterintuitively, the practical issues of having uncertain channel knowledge, high propagation losses, and implementing optimal non-linear precoding are solved more or less automatically by enlarging system dimensions. However, the computational precoding complexity grows with the system dimensions. For example, the close-to-optimal and relatively “antenna-efficient” regularized zero-forcing (RZF) precoding is very complicated to implement in practice, since it requires fast inversions of large matrices in every coherence period. Motivated by the high performance of RZF, we propose to replace the matrix inversion and multiplication by a truncated polynomial expansion (TPE), thereby obtaining the new TPE precoding scheme which is more suitable for real-time hardware implementation and significantly reduces the delay to the first transmitted symbol. The degree of the matrix polynomial can be adapted to the available hardware resources and enables smooth transition between simple maximum ratio transmission and more advanced RZF.By deriving new random matrix results, we obtain a deterministic expression for the asymptotic signal-to-interference-and-noise ratio (SINR) achieved by TPE precoding in massive MIMO systems. Furthermore, we provide a closed-form expression for the polynomial coefficients that maximizes this SINR. To maintain a fixed per-user rate loss as compared to RZF, the polynomial degree does not need to scale with the system, but it should be increased with the quality of the channel knowledge and the signal-to-noise ratio.
Highlights
The current wireless networks must be greatly densified to meet the exponential growth in data traffic and number of user terminals (UTs) [1]
We have proposed a new class of TPE precoding schemes where the inversion is approximated by truncated polynomial expansions to enable simple hardware implementation
In terms of implementation complexity, TPE precoding has several advantages: (1) There is no need to compute the precoding matrix beforehand; (2) the delay to the first transmitted symbol is reduced significantly; (3) the multistage structure enables pipelining; and (4) the parameter J can be tailored to the available hardware
Summary
The current wireless networks must be greatly densified to meet the exponential growth in data traffic and number of user terminals (UTs) [1]. The beauty of massive MIMO is that this is not the case: simple linear precoding is asymptotically optimal in the regime M K 0 [3] and random matrix theory can provide simple deterministic approximations of the stochastic achievable rates [5, 10,11,12,13,14] These so-called deterministic equivalents are tight as M grows large due to channel hardening but are usually very accurate at small values of M and K. A main analytic contribution is the derivation of deterministic equivalents for the achievable user rates for any order J of TPE precoding These expressions are tight when M and K grow large with a fixed ratio and provide close approximations at small parameter values.
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