Convergence Behavior of Matrix-Based Iterative Transceiver Optimization

2006 IEEE 7th Workshop on Signal Processing Advances in Wireless Communications Pub Date : 2006-07-02 DOI:10.1109/SPAWC.2006.346419

H. Boche, M. Schubert

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引用次数: 8

Abstract

We analyze and compare two iterative algorithms for the joint optimization of powers and receive strategies in a multiuser network. The design goal is to minimize the total power while fulfilling individual QoS requirements. This problem can be solved by the fixed-point iteration proposed by Yates, (1995) as well as by a recently proposed matrix-based iteration (M. Schubert and H. Boche, 2006; H. Boche et al., 2005). It was observed in the literature that the matrix-based iteration has an excellent convergence speed. However, an analytical investigation of the convergence behavior has been an open problem so far. In this paper, we show that the matrix-based iteration performs better than the fixed-point iteration in each step, given the same initialization. The resulting sequence of power vectors is component-wise monotonic decreasing. We also show that the matrix-based iteration has super-linear convergence. If the underlying interference functions are smooth, then the algorithm even has quadratic convergence, whereas the convergence of the fixed-point iteration is only linear, and depends on the system load. This explains the convergence behavior observed from simulations

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基于矩阵迭代的收发器优化的收敛性

分析比较了多用户网络中功率和接收策略联合优化的两种迭代算法。设计目标是在满足单个QoS要求的同时最小化总功率。这个问题可以通过Yates(1995)提出的不动点迭代以及最近提出的基于矩阵的迭代(M. Schubert和H. Boche, 2006;H. Boche et al.， 2005)。从文献中观察到，基于矩阵的迭代具有优异的收敛速度。然而，对收敛性的分析研究至今仍是一个开放性问题。在本文中，我们证明了在初始化相同的情况下，基于矩阵的迭代在每一步中都优于定点迭代。所得的幂向量序列是分量单调递减的。我们还证明了基于矩阵的迭代具有超线性收敛性。如果底层干扰函数是光滑的，则该算法甚至具有二次收敛性，而不动点迭代的收敛性仅为线性，并且依赖于系统负载。这解释了从模拟中观察到的收敛行为

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2006 IEEE 7th Workshop on Signal Processing Advances in Wireless Communications

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