基于低成本Artix-7 FPGA的多链插值高精度时数转换器

2021 7th International Conference on Event-Based Control, Communication, and Signal Processing (EBCCSP) Pub Date : 2021-06-22 DOI:10.1109/EBCCSP53293.2021.9502368

Junchen Wang, C. Feng, W. Dong, Z. Shen, Shubin Liu

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引用次数: 4

摘要

提出了一种基于低功耗现场可编程门阵列(FPGA)的高精度时间-数字转换器(TDC)。它采用插值法进行精细时间测量，并采用多链抽头延迟线(TDL)结构实现高精度测量。为了避免气泡误差和减少死区时间，在每条链上采用流水线结构的Wallace-tree编码器，对延迟抽头中的234位温度计编码。在Xilinx Artix-7 100T FPGA上实现了不同链数的双通道TDC，验证了设计理念并对其性能进行了详细研究。测试结果表明，在每个通道实现8条链的情况下，前沿测量(通道到通道)的最佳精度可达到6.4 ps的均方根(RMS)。双通道TDC(连同辅助电路)的LUT资源占用约为9.77%，显示出在高密度、低成本应用中扩展通道数的良好潜力。

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A High Precision Time-to-Digital Converter based on Multi-chain Interpolation with a Low Cost Artix-7 FPGA

This paper presents a high precision Time-to-Digital Converter (TDC) implemented in a low-end, low power Field Programmable Gate Array (FPGA). It applies the interpolation method for fine time measurement, and a multi-chain tapped-delay line (TDL) structure is used to achieve high precision. To avoid bubble error and to decrease dead time, a Wallace-tree encoder with pipeline structure is utilized in each chain, for encoding the 234-bit thermometer code from the delay taps. A double-channel TDC with different numbers of chains is implemented in a Xilinx Artix-7 100T FPGA to verify the design concept and to study the performances in detail. Test results show that with eight chains implemented for each channel, the best precision of leading-edge measurement (channel to channel) can reach 6.4 ps in root mean square (RMS). The LUT resource occupancy of the double-channel TDC (together with auxiliary circuits) is about 9.77%, which shows good potential for expanding the channel numbers for high density, low cost applications.

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来源期刊

2021 7th International Conference on Event-Based Control, Communication, and Signal Processing (EBCCSP)

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