ChenYang Xia scite author profile

As the first kind of forward error correction (FEC) codes that achieve channel capacity, polar codes have attracted much research interest recently. Compared with other popular FEC codes, polar codes decoded by list successive cancellation decoding (LSCD) with a large list size have better error correction performance. However, due to the serial decoding nature of LSCD and the high complexity of list management (LM), the decoding latency is high, which limits the usage of polar codes in practical applications that require low latency and high throughput. In this work, we study the high-throughput implementation of LSCD with a large list size. Specifically, at the algorithmic level, to achieve a low decoding latency with moderate hardware complexity, two decoding schemes, a multi-bit double thresholding scheme and a partial G-node look-ahead scheme, are proposed. Then, a high-throughput VLSI architecture implementing the proposed algorithms is developed with optimizations on different computation modules. From the implementation results on UMC 90 nm CMOS technology, the proposed architecture achieves decoding throughputs of 1.103 Gbps, 977 Mbps and 827 Mbps when the list sizes are 8, 16 and 32, respectively.

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Low-latency list decoding of polar codes with double thresholding

Fan

Chen

Xia

et al. 2015

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For polar codes with short-to-medium code length, list successive cancellation decoding is used to achieve a good error-correcting performance. However, list pruning in the current list decoding is based on the sorting strategy and its timing complexity is high. This results in a long decoding latency for large list size. In this work, aiming at a low-latency list decoding implementation, a double thresholding algorithm is proposed for a fast list pruning. As a result, with a negligible performance degradation, the list pruning delay is greatly reduced. Based on the double thresholding, a low-latency list decoding architecture is proposed and implemented using a UMC 90nm CMOS technology. Synthesis results show that, even for a large list size of 16, the proposed low-latency architecture achieves a decoding throughput of 220 Mbps at a frequency of 641 MHz.

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ChenYang Xia

A Low-Latency List Successive-Cancellation Decoding Implementation for Polar Codes

A High-Throughput Architecture of List Successive Cancellation Polar Codes Decoder With Large List Size

Low-latency list decoding of polar codes with double thresholding

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