Performance Analysis of a Novel Phase-Tracking and Measuring Loop Appropriate for Distance Measurement

HUANG Jing-yu; CHEN Ya-qin; FENG Zheng-he

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Performance Analysis of a Novel Phase-Tracking and Measuring Loop Appropriate for Distance Measurement

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- Performance Analysis of a Novel Phase-Tracking and Measuring Loop Appropriate for Distance Measurement
- Acta Electronica Sinica Vol. 29, Issue 9, Pages: 1168-1172(2001)
- 作者机构：
  
  清华大学电子工程系微波与数字通信国家重点实验室,北京,100084
- 作者简介：
- 基金信息：
- DOI：
  CLC： TM930.115
- Published：2001
- 稿件说明：
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HUANG Jing-yu, CHEN Ya-qin, FENG Zheng-he. Performance Analysis of a Novel Phase-Tracking and Measuring Loop Appropriate for Distance Measurement[J]. Acta Electronica Sinica, 2001, 29(9): 1168-1172.
DOI：

HUANG Jing-yu, CHEN Ya-qin, FENG Zheng-he. Performance Analysis of a Novel Phase-Tracking and Measuring Loop Appropriate for Distance Measurement[J]. Acta Electronica Sinica, 2001, 29(9): 1168-1172. DOI：

摘要

本文介绍了一种新型数字相位跟踪测量环(DPTML)结构

并应用有限状态Markov链理论求解其稳态误差和响应时间.通过分析关键部件的抗噪声性能给出了参数选择依据

提出了应用稳态结果进一步降低输出误差的"稳态平均法".计算和仿真结果均表明

该DPTML比传统的过零采样数字锁相环(ZC-DPLL)具有更强的抗噪声性能

并有效消除了高信噪比下的"hangup"效应

缩短了响应时间

更适于测距应用.

Abstract

A novel digital phase-tracking and measuring loop(DPTML) appropriate for distance measurement are proposed and analyzed using the theory of finite Markov chains.The performance of steady-state phase-tracking error and phase acquisition time in the presence of additive band-limited white Gaussian noise are evaluated.By analysis of the noise-resistant characteristic of the key module

guidelines on selection of its pivotal parameter are given.A new method utilizing the acquired steady-state results to ulteriorly reduce the tracking error is also presented.Both the calculated and simulated results indicate that the DPTML has much less steady-state error than traditional zero-crossing digital phase-locking loop(ZC-DPLL).Additionally

because the "hangup" effect leading to prolonged phase transients owing to the presence of the dead zone around π rad is thoroughly eliminated

the phase acquisition time of the DPTML is much shorter than the latter

especially in high SNR.

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