9 research outputs found
Asymptotic Task-Based Quantization with Application to Massive MIMO
Quantizers take part in nearly every digital signal processing system which
operates on physical signals. They are commonly designed to accurately
represent the underlying signal, regardless of the specific task to be
performed on the quantized data. In systems working with high-dimensional
signals, such as massive multiple-input multiple-output (MIMO) systems, it is
beneficial to utilize low-resolution quantizers, due to cost, power, and memory
constraints. In this work we study quantization of high-dimensional inputs,
aiming at improving performance under resolution constraints by accounting for
the system task in the quantizers design. We focus on the task of recovering a
desired signal statistically related to the high-dimensional input, and analyze
two quantization approaches: We first consider vector quantization, which is
typically computationally infeasible, and characterize the optimal performance
achievable with this approach. Next, we focus on practical systems which
utilize hardware-limited scalar uniform analog-to-digital converters (ADCs),
and design a task-based quantizer under this model. The resulting system
accounts for the task by linearly combining the observed signal into a lower
dimension prior to quantization. We then apply our proposed technique to
channel estimation in massive MIMO networks. Our results demonstrate that a
system utilizing low-resolution scalar ADCs can approach the optimal channel
estimation performance by properly accounting for the task in the system
design
Hardware-Limited Task-Based Quantization
Quantization plays a critical role in digital signal processing systems.
Quantizers are typically designed to obtain an accurate digital representation
of the input signal, operating independently of the system task, and are
commonly implemented using serial scalar analog-to-digital converters (ADCs).
In this work, we study hardware-limited task-based quantization, where a system
utilizing a serial scalar ADC is designed to provide a suitable representation
in order to allow the recovery of a parameter vector underlying the input
signal. We propose hardware-limited task-based quantization systems for a fixed
and finite quantization resolution, and characterize their achievable
distortion. We then apply the analysis to the practical setups of channel
estimation and eigen-spectrum recovery from quantized measurements. Our results
illustrate that properly designed hardware-limited systems can approach the
optimal performance achievable with vector quantizers, and that by taking the
underlying task into account, the quantization error can be made negligible
with a relatively small number of bits