Learning approximate neural estimators for wireless channel state information

Tim O'Shea, Kiran Karra, T. Clancy
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引用次数: 43

Abstract

Estimation is a critical component of synchronization in wireless and signal processing systems. There is a rich body of work on estimator derivation, optimization, and statistical characterization from analytic system models which are used pervasively today. We explore an alternative approach to building estimators which relies principally on approximate regression using large datasets and large computationally efficient artificial neural network models capable of learning non-linear function mappings which provide compact and accurate estimates. For single carrier PSK modulation, we explore the accuracy and computational complexity of such estimators compared with the current gold-standard analytically derived alternatives. We compare performance in various wireless operating conditions and consider the trade offs between the two different classes of systems. Our results show the learned estimators can provide improvements in areas such as short-time estimation and estimation under non-trivial real world channel conditions such as fading or other non-linear hardware or propagation effects.
学习无线信道状态信息的近似神经估计器
在无线和信号处理系统中,估计是同步的关键组成部分。有大量的工作是关于估计量的推导、优化和分析系统模型的统计特征,这些模型在今天被广泛使用。我们探索了一种构建估计器的替代方法,该方法主要依赖于使用大型数据集和大型计算效率高的人工神经网络模型的近似回归,这些模型能够学习非线性函数映射,从而提供紧凑和准确的估计。对于单载波PSK调制,我们探讨了这种估计器的精度和计算复杂性与目前的金标准分析推导的替代方案。我们比较了各种无线操作条件下的性能,并考虑了两种不同类型系统之间的权衡。我们的研究结果表明,学习估计器可以在短时估计和非平凡现实信道条件下(如衰落或其他非线性硬件或传播效应)的估计等领域提供改进。
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