Readout electronics of a prototype time-of-flight ion composition analyzer for space plasma
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Readout electronics is developed for a prototype time-of-flight (TOF) ion composition spectrometer for in situ measurement of the mass/charge distributions of major ion species from 200 to 100 keV/e in space plasma. By utilizing a constant fraction discriminator (CFD) and time-to-digital converter (TDC), challenging dynamic range measurements were performed with high time resolution and event rates. CFD was employed to discriminate the TOF signals from the micro-channel plate and channel electron multipliers. TDC based on the combination of counter and OR-gate delay chain was designed in a high-reliability flash field programmable gate array. Owing to the non-uniformity of the delay chain, a correction algorithm based on integral nonlinearity compensation was implemented to reduce the time uncertainty. The test results showed that the electronics achieved a low timing error of < 200 ps in the input range from 35 to 500 mV for the CFD, and a time resolution of ~ 550 ps with time uncertainty < 180 ps after correction and a time range of 6.4 μs for the TDC. The TOF spectrum from an electron beam experiment of the impacting N2 gas further indicated the good performance of this readout electronic.
KeywordsSpace plasma Ion composition analyzer Readout electronics Constant fraction discriminator Time-to-digital converter
The authors are grateful for the help and discussion of collaboration teams from Hefei National Laboratory for Physical Sciences at Microscale and CAS Key Laboratory of Geospace Environment (USTC).
- 8.J.E. Nordholt, J.J. Berthelier, D.M. Burr et al., Measurement Techniques, in Space Plasmas: Particles, ed. by R.F. Pfaff, J.E. Borovsky, D.T. Young (American Geophysical Union, Washington, DC, 1998), pp. 209–214Google Scholar
- 9.E. Möbius, L.M. Kistler, M.A. Popecki et al., Measurement Techniques, in Space Plasmas: Particles, ed. by R.F. Pfaff, J.E. Borovsky, D.T. Young (American Geophysical Union, Washington, DC, 1998), pp. 243–248Google Scholar
- 10.F.M. Yang, P.C. Huang, W.Z. Chen et al., Progress on laser time transfer project, in Paper Presented at 15th International Workshop on Laser Ranging (Canberra, 15–20 October 2006)Google Scholar
- 11.W. Hsiong, S. Huntzicker, K. King et al., Performance and area tradeoffs in space-qualified FPGA-based time-of-flight systems, in Paper Presented at the 9th International Conference on Electronic Measurement and Instruments (Beihang University, Beijing, 16–19 August 2009)Google Scholar
- 14.Q. Shen, The research on high resolution time to digital conversion for quantum communication (Ph.D. Thesis, University of Science and Technology of China, 2013)Google Scholar
- 15.N. Paschalidis, N. Stamatopoulos, K. Karadamoglou et al., A time-of-flight system on a chip suitable for space instrumentation, in Paper Presented at the 2001 IEEE Nuclear Science Symposium Conference Record (San Diego, 4–10 November 2001)Google Scholar
- 16.J.J. Wang, Radiation effects in FPGAs, in Paper Presented at the Proceedings of the 9th Workshop on Electronics for LHC Experiments (Amsterdam, 29 Sept–3 Oct 2003)Google Scholar
- 19.A121 hybrid charge sensitive preamplifier, discriminator, and pulse shaper (Amptek Inc., USA). http://amptek.com/products/a121. Accessed 12 Sept 2015
- 20.R.H. Maurer, M.E. Fraeman, M.N. Martin et al., Harsh environments: space radiation environment, effects, and mitigation. J. Hopkins APL Tech. D 28, 17 (2008)Google Scholar
- 21.X. Qin, C.Q. Feng, D.L. Zhang et al., A low dead time vernier delay line TDC implemented in an actel flash-based FPGA. Nucl. Sci. Technol. 24, 040403 (2013). https://doi.org/10.13538/j.1001-8042/nst.2013.04.012 Google Scholar