LI Jia,DENG Genghui,CHEN Yongqiang.FPGA-based Time base Design and Time base Nonlinear Compensation[J].Journal of Chengdu University of Information Technology,2024,39(06):660-664.[doi:10.16836/j.cnki.jcuit.2024.06.003]
基于FPGA的时基设计和时基非线性补偿
- Title:
- FPGA-based Time base Design and Time base Nonlinear Compensation
- 文章编号:
- 2096-1618(2024)06-0660-05
- 分类号:
- TN929.52
- 文献标志码:
- A
- 摘要:
- 为提高宽带时域反射计的等效采样率和时基分辨率,设计一种基于现场可编程门阵列(field programmable gate array,FPGA)的时域反射计数据采集模块的时基方案,并设计一种基于查找表的时基校准方法对时基非线性进行补偿。该方法基于等精度测频法,使用FPGA测量该方波信号的频率,得到准确的延迟时间以实现查找表的建立。并利用采样芯片的微调引脚实现1 ps步进的顺序等效采样和时基非线性实时补偿。实测数据表明:设计的时基采样方案实现了1 TSa/s等效采样率,时基补偿方案使时基非线性减小至-0.8~1 ps。
- Abstract:
- To improve the equivalent sampling rate and resolution of a high-bandwidth time domain reflectometer(TDR),this paper designs a field-programmable gate array(FPGA)-based time base scheme for time domain reflectometer data acquisition module,and a lookup table-based time base calibration method designed to compensate for the time base nonlinearity.The method is based on the equal precision frequency measurement method, which uses the FPGA to measure the frequency of this square wave signal to get the accurate delay time for the lookup table and the trim pin of the sampling chip to achieve the sequential equivalent sampling in 1 ps steps and the time-base nonlinearity compensation in real-time.The measured data show that the designed time base sampling scheme achieves a 1 TSa/s equivalent sampling rate and the time base compensation scheme reduces the time base nonlinearity to the range of -0.8-1 ps.
参考文献/References:
[1] 李承阳.20GSPS 宽带数据采集系统研究与实现[D].成都:电子科技大学,2017.
[2] Merelle V,Gaugue A,Khamlichi J,et al.Anew high speed,high bandwidth acquisition platform for impulse UWB see through-the-wall radar[C]//IEEE International Conference on Ultra-wideband.IEEE,2016:202-206.
[3] 刘映光.取样示波器中频信号处理技术研究[D].太原:中北大学,2020.
[4] 李海涛,李斌康,孙彬,等.基于时间交替采样技术的1 GS/s,16 bit数据采集系统研究[J].电子技术应用,2022(7):118-123.
[5] Yamamoto S,Sasaki Y,Zhao Y,et al.Metallic Ratio Equivalent-Time Sampling:A Highly Efficient Waveform Acquisition Method[C]//2021 IEEE 27th International Symposium on On-Line Testing and Robust System Design(IOLTS).IEEE,2021:1-6.
[6] Takahashi K,Roberts R,Jiang Z,et al.Statistical Evaluation of Signal-to-Noise Ratio and Timing Jitter in Equivalent-Time Sampling Signals[J].IEEE Transactions on Instrumentation and Measurement,2021(70):1-4.
[7] Masui Y,Nishimiya T,Uemi A,et al.A 7.21-bit ENOB 100MS/s 1.51mW Inverter based Pipelined ADC with Digital Calibration for Breast Cancer Detection System[J].IEEJ Transactions on Electronics,Information and Systems,2020,140(6):585-591.
[8] Madsen K N,Gathman T D,Daneshgar S,et al.A High-Linearity,30 GS/s Track-and-Hold Amplifier and Time Interleaved Sample-and-Hold in an InP-on-CMOS Process[J].IEEE Journal of Solid-State Circuits,2015,50(11):1-11.
[9] 王超.10GHz宽带信号时域获取技术的研究与实现[D].成都:电子科技大学,2019.
[10] 李海涛,李斌康,阮林波,等.一种基于频差法的顺序等效采样方法及其实现[J].电子学报,2020,48(6):1071-1076.
[11] 邱渡裕.宽带等效取样示波器关键技术研究[D].成都:电子科技大学,2015.
[12] Cao Y,Wen H,Tu Y,A double reference line calibrate method for calibrating characteristic impedance in time domain of a time domain reflectometer.[P].CN.2020.
[13] Wang C,Hale P D,Jargon J A,et al.Sequential Estimation of Timebase Corrections for an Arbitrarily Long Waveform[J].IEEE Transactions on Instrumentation & Measurement,2012,61(10):2689-2694.
[14] 李子桐.取样示波器精密时基模块技术研究[D].太原:中北大学,2020.
[15] 朱江淼,李然,缪京元,等.高速取样示波器时基失真数学模型的研究与仿真[J].北京工业大学学报,2013,39(12):1810-1814.
[16] 李海生.基于移相技术的改进等精度测频法[J].山西大同大学学报(自然科学版),2020,36(2):14-17.
备注/Memo
收稿日期:2023-07-24
通信作者:陈永强.E-mail:chengyongq@cuit.edu.cn