New design of high-precision oven controlled crystal oscillator 被引量：1

New design of high-precision oven controlled crystal oscillator

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摘要 Combining oven controlled technique,digital compensation,high-resolution frequency difference measurement and self-calibration technique,a new design method of precise oven controlled crystal oscillator（OCXO） is proposed.Fine compensation is made in the vicinity of the crystal temperature inflection point by using the non-real-time temperature compensation strategy,and self-calibration system is integrated in the crystal.The method improves the digital compensated phase noise,simplifies the traditional OCXO development system,reduces the cost and shortens the developing cycle.Experiment results show that with a standard reference signal and self-calibration updated data,the oscillator can work stable and achieve its best performence.The performance index of crystal oscillator had an improvement with one to two orders of magnitude on the basis of original technical index.The method is widely used in the improvement of high-end crystal oscillator and atomic clock. Combining oven controlled technique,digital compensation,high-resolution frequency difference measurement and self-calibration technique,a new design method of precise oven controlled crystal oscillator（OCXO） is proposed.Fine compensation is made in the vicinity of the crystal temperature inflection point by using the non-real-time temperature compensation strategy,and self-calibration system is integrated in the crystal.The method improves the digital compensated phase noise,simplifies the traditional OCXO development system,reduces the cost and shortens the developing cycle.Experiment results show that with a standard reference signal and self-calibration updated data,the oscillator can work stable and achieve its best performence.The performance index of crystal oscillator had an improvement with one to two orders of magnitude on the basis of original technical index.The method is widely used in the improvement of high-end crystal oscillator and atomic clock.

作者董绍锋杜保强周渭

机构地区 Department of Measurement and Instrument School of Electric and Information Engineering

出处《Journal of Beijing Institute of Technology》 EI CAS 2012年第3期362-369,共8页 北京理工大学学报（英文版）

基金 Supported by the National Natural Science Foundation of China (10978017) the Open Fund of Key Laboratory of Time and Frequency Primary Standards (CAS) the Postdoctoral Grant of China (94469) the Basic and Advanced Technology Research Foundation of Hennan Province (122300410169) the Fundamental Research Funds for the Central Universities

关键词 crystal oscillator temperature compensation non-real-time control frequency difference measurement self-calibration crystal oscillator temperature compensation non-real-time control frequency difference measurement self-calibration

分类号 TN752 [电子电信—电路与系统]

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Journal of Beijing Institute of Technology

2012年第3期

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