Get our free email newsletter

Impact of Decoupling Capacitors and Trace Length on Conducted Emissions in a CMOS Inverter Circuit

The impact of decoupling capacitors and a PCB trace length on signal integrity was discussed in [1], while the impact on radiated emissions was discussed in [2]. In this article, we evaluate the impact of the capacitors and trace length on conducted emissions.

1. CMOS Inverter Circuit

Figure 1 shows the block diagram of the inverter circuit and the PCB. In this study, trace length varied between 3,000 mils (short trace) and 20,000 mils (long trace). Additionally, the PCB was tested in two configurations: without the decoupling capacitors and with decoupling capacitors by each inverter (0.1 µF and 1 µF).

Figure 1: Block diagram of the inverter circuit and the PCB

2. Conducted Emissions Measurement Setup

The measurement setup is shown in Figure 2. The measurements were performed in a semi-anechoic chamber, in accordance with CISPR 25 Edition 5 automotive standard.

- Partner Content -

Shielding Effectiveness Test Guide

Just as interference testing requires RF enclosures, isolation systems in turn need their own testing. This document reviews some of the issues and considerations in testing RF enclosures.
Figure 2: Measurement setup

Measurements were taken on both the battery and ground lines, in the frequency range 150 kHz – 108 MHz. In the frequency range 150 kHz – 30 MHz measurements were taken with a bandwidth of 9 kHz while in the range 30 MHz – 108 MHz the bandwidth was set to 120 kHz. All measurements were taken with the average, peak and quasi-peak detectors.

3. Impact of the Trace Length on Conducted Emissions

In this section, we evaluate the conducted emission results from the PCB with short traces (3,000 mils) and long traces (20,000 mils) without decoupling capacitors by the inverters.

3A. Short trace vs. long trace: 150 kHz – 30 MHz

Conducted emission results are shown in Figure 3 (battery line) and Figure 4 (ground line).

Figure 3: Battery line, 150 kHz – 30 MHz: a) short trace b) long trace

 

Figure 4: Ground line, 150 kHz – 30 MHz: a) short trace b) long trace

Observations

- From Our Sponsors -

Both short and long trace showed failures at the same frequencies, on both the battery and ground lines. The failures for the short trace were smaller.

3B. Short trace vs. long trace: 30 MHz – 108 MHz

Conducted emission results are shown in Figure 5 (battery line) and Figure 6 (ground line).

Figure 5: Battery line, 30 MHz – 108 MHz: a) short trace b) long trace

 

Figure 6: Ground line, 30 MHz – 108 MHz: a) short trace b) long trace

Observations

Both traces showed failures over the entire frequency region, with one trace outperforming the other in three frequency subregions.

30 – 42 MHz: Short trace outperformed the long trace, on both the battery and ground lines, using both detectors.

44 – 88 MHz: Long trace outperformed the short trace, on both the battery and ground lines, using both detectors.

90 – 108 MHz: Short trace outperformed the long trace, on both the battery and ground lines, using both detectors.

4. Impact of the Decoupling Capacitors on Conducted Emissions – Short Trace

In this section, we evaluate the conducted emission results from the PCB with short traces, without the decoupling capacitors, and with the decoupling capacitors by each inverter (0.1 µF and 1 µF).

4A: Short trace with and without decoupling capacitors: 150 kHz – 30 MHz

Conducted emission results are shown in Figure 7 (no caps) and Figure 8 (caps).

Figure 7: Battery line, 150 kHz – 30 MHz: a) without capacitors b) with capacitors

 

Figure 8: Ground line, 150 kHz – 30 MHz: a) without capacitors b) with capacitors

Observations

Battery Line: Capacitors eliminated the failure at 6.04 MHz. At 26.17 MHz, quasi-peak failure was eliminated and the average detector failure was substantially reduced.

Ground Line: Capacitors eliminated the failures at 6.04 MHz and 26.17 MHz.

4B. Short trace with and without decoupling capacitors: 30 MHz – 108 MHz

Conducted emission results are shown in Figure 9 (no caps) and Figure 10 (caps).

Figure 9: Battery line, 30 MHz – 108 MHz: a) without capacitors, b) with capacitors

 

Figure 10: Ground line, 30 MHz – 108 MHz: a) without capacitors, b) with capacitors

Observations

Battery Line: Capacitors eliminated the quasi-peak failures over the entire frequency range except for a single substantially reduced failure, at 107.73 MHz. The average detector failures were eliminated up to the frequency of 73 MHz, and the failures in the range 73 – 108 MHz were substantially reduced.

Ground Line: Capacitors eliminated the quasi-peak failures up to the frequency of 87 MHz, and the failures in the range 87 – 108 MHz were substantially reduced. The average detector failures were eliminated up to the frequency of 73 MHz, and the failures in the range 73 – 108 MHz were substantially reduced.

References

  1. Bogdan Adamczyk and Mathew Yerian-French, “Impact of a Decoupling Capacitor and Trace Length on Signal Integrity in a CMOS Inverter Circuit,” In Compliance Magazine, January 2024.
  2. Bogdan Adamczyk and Mathew Yerian-French, “Impact of a Decoupling Capacitor and Trace Length on Radiated Emissions in a CMOS Inverter Circuit,” In Compliance Magazine, March 2024.

Related Articles

Digital Sponsors

Become a Sponsor

Discover new products, review technical whitepapers, read the latest compliance news, and check out trending engineering news.

Get our email updates

What's New

- From Our Sponsors -

Sign up for the In Compliance Email Newsletter

Discover new products, review technical whitepapers, read the latest compliance news, and trending engineering news.