Optimum Filters for Second- and Third-Order Phase-Locked Loops by an Error-Function Criterion

IEEE Transactions on Space Electronics and Telemetry Pub Date : 1965-06-01 DOI:10.1109/TSET.1965.5009645

S. Gupta, R. J. Solem

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引用次数: 5

Abstract

The advantages of a third-order phase-locked loop for FM television is considered here. The bandwidth is maintained small and since the operation is generally at frequencies small compared to the bandwidth, the criterion is to keep error as small as possible in this frequency range. A study is made by comparing second- and third-order phase-locked loops designed from Wiener filtering theory, as advanced by Jaffe and Rechtin [1]; considerable improvement in error is evident using a third-order phase-locked loop for frequencies up to about one-twentieth of the bandwidth. To improve the error function still further, a new error-function criterion is established whereby the error at the lower frequencies of interest is minimized. Such a minimum is obtained for both second- and third-order phase-locked loops. Transfer function behavior, transient response, and root locus plots of all these cases are given to emphasize the advantages of this new design. Error is reduced up to six decibels with no degradation of transient response, overshoot, etc. It is shown that the bandwidth can be reduced without increasing the error if the filter designed by this new criterion is used.

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基于误差函数准则的二阶和三阶锁相环的最优滤波器

本文讨论了调频电视用三阶锁相环的优点。带宽保持较小，由于操作通常在比带宽小的频率上进行，因此准则是在该频率范围内保持尽可能小的误差。比较Jaffe和Rechtin[1]提出的基于Wiener滤波理论设计的二阶锁相环和三阶锁相环;相当大的改进误差是明显的使用三阶锁相环频率高达约二十分之一的带宽。为了进一步改进误差函数，建立了一种新的误差函数准则，使低频处的误差最小化。对于二阶和三阶锁相环都可以得到这样的最小值。并给出了所有情况下的传递函数行为、瞬态响应和根轨迹图，以强调这种新设计的优点。误差减少到6分贝，没有退化的瞬态响应，超调等。结果表明，采用该准则设计的滤波器可以在不增加误差的情况下减小带宽。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE Transactions on Space Electronics and Telemetry

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