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A 7.5 ps single-shot precision integrated time counter with segmented delay line.

K Klepacki1, R Szplet1, R Pelka1

  • 1Military University of Technology, Electronics Faculty, Warsaw 00-908, Poland.

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Summary

This study presents a novel time interval counter with 7.5 ps root mean square (rms) precision. It utilizes a two-stage interpolation method with segmented delay lines for enhanced accuracy in time measurements.

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Area of Science:

  • Electrical Engineering
  • Instrumentation and Measurement
  • Semiconductor Devices

Background:

  • Accurate time interval measurement is crucial for various scientific and engineering applications.
  • Existing time interval counters face limitations in precision and measurement range.
  • Advancements in integrated circuit technology enable novel approaches to high-precision timing.

Purpose of the Study:

  • To design and test a novel time interval counter with superior single-shot precision.
  • To achieve a measurement range of 1 ms with sub-picosecond resolution.
  • To integrate the time interval counter into a cost-effective Application Specific Integrated Circuit (ASIC).

Main Methods:

  • Combination of direct counting with a two-stage interpolation technique within a single clock period.
  • Utilizing tapped delay lines stabilized by a delay-locked loop (DLL) mechanism for both interpolation stages.
  • Employing a high-frequency multiphase clock for coarse resolution and a differential delay line for fine resolution.
  • Development of a novel segmented delay line with partial overlapping for improved linearity and precision.

Main Results:

  • Achieved single-shot precision of 7.5 picoseconds (ps) root mean square (rms).
  • Demonstrated a measurement range of 1 millisecond (ms).
  • Maximum integral nonlinearity error of fine-stage interpolators was 16 ps (START) and 14 ps (STOP), corrected via statistical calibration.
  • The time interval counter was successfully integrated into a single 0.35 μm CMOS ASIC.

Conclusions:

  • The proposed time interval counter design effectively achieves high single-shot precision and a wide measurement range.
  • The novel segmented delay line and two-stage interpolation are key to overcoming limitations in linearity and resolution.
  • Integration into a standard CMOS process offers a cost-effective solution for high-performance timing applications.