Efficient solutions for reducing electromagnetic interference in legacy electronic test equipment systems

11 views

Authors

  • Pham Van May (Corresponding Author) Institute of Missile, Academy of Military Science and Technology
  • Lai Quoc Huy Institute of Missile, Academy of Military Science and Technology
  • Trinh The Anh Naval Academy

DOI:

https://doi.org/10.54939/1859-1043.j.mst.112.2026.83-91

Keywords:

Electromagnetic compatibility; Electromagnetic interference; Legacy system modernization.

Abstract

This paper presents a comprehensive methodology for reducing electromagnetic interference (EMI) and improving electromagnetic compatibility (EMC) during the modernization of legacy analog-digital mixed electronic test systems. The research addresses critical challenges encountered when replacing obsolete Soviet-era discrete components with modern commercial off-the-shelf (COTS) integrated circuits in precision optoelectronic testing equipment. A systematic approach combining signal integrity analysis, power distribution network (PDN) optimization, and multi-layer shielding techniques is proposed. Experimental results demonstrate successful EMI suppression achieving conducted emission levels below CISPR 11 Class B limits (66 dBμV at 150 kHz to 40 dBμV at 30 MHz) and radiated emission compliance with MIL-STD-461G RE102 requirements. The proposed methodology enables functional equivalence while maintaining measurement accuracy within ± 0.5% of original specifications across the operational bandwidth of 1 MHz to 100 MHz.

References

[1]. H. W. Ott. “Electromagnetic Compatibility Engineering”. Hoboken, NJ, USA: Wiley, (2009).

[2]. C. R. Paul. “Introduction to Electromagnetic Compatibility”. 2nd ed. Hoboken, NJ, USA: Wiley, (2006).

[3]. P. Morrison and R. Weir. “Upgrade/Downgrade: Efficient and secure legacy electronic system replacement”. IEEE Des. Test, vol. 35, no. 6, pp. 7-14, (2018).

[4]. G. V. Shirsavar and M. J. Brookes. “Securing FPGA-based obsolete component replacement for legacy systems”. Proc. IEEE Int. Symp. Hardware Oriented Security and Trust (HOST), Washington, DC, USA, pp. 148-153, (2018).

[5]. S. P. Bisio et al. “Redesign driven by manufacturing data for next-generation modernization of legacy products”. J. Mech. Des., vol. 144, no. 3, Art. no. 032001, (2022).

[6]. S. Caniggia and F. Maradei. “Signal Integrity and Radiated Emission of High-Speed Digital Systems”. Chichester, UK: Wiley, (2008).

[7]. E. Bogatin. “Signal and Power Integrity - Simplified”. 3rd ed. Boston, MA, USA: Pearson, (2018).

[8]. J. Fan, X. Ye, J. Kim, B. Archambeault, and A. Orlandi. “Signal integrity design for high-speed digital circuits: Progress and directions”. IEEE Trans. Electromagn. Compat., vol. 52, no. 2, pp. 392-400, (2010).

[9]. Specification for Radio Disturbance and Immunity Measuring Apparatus and Methods - Part 1-1: Radio Disturbance and Immunity Measuring Apparatus - Measuring Apparatus, CISPR 16-1-1:2019, (2019).

[10]. Requirements for the Control of Electromagnetic Interference Characteristics of Subsystems and Equipment, MIL-STD-461G, (2015).

Downloads

Published

25-06-2026

How to Cite

[1]
M. Phạm Văn, Lai Quoc Huy, and Trinh The Anh, “Efficient solutions for reducing electromagnetic interference in legacy electronic test equipment systems”, J. Mil. Sci. Technol., vol. 112, no. 112, pp. 83–91, Jun. 2026.

Issue

Section

Electronics & Automation