Noisey gate drive

Measuring Silicon Carbide (SiC) MOSFET Signals Effectively

Published: 10th December 2021

Silicon Carbide (SiC) MOSFETs are increasingly being used in industries ranging from electric vehicles and solar power, to backup power systems. This is thanks to their ability to withstand high temperatures, offer faster switching, deliver higher efficiency especially at higher voltages, and high current capacity.

However, there are some challenges in validating designs using SiC MOSFET’s. The switching characteristics that make them attractive also pose challenges for accurate validation measurements. The right probe selection and application can greatly improve measurement accuracy.

After reading this post, you can find more detailed information in a new Tektronix application note titled Effective Measurement of Signals in Silicon Carbide (SiC) Power Electronics Systems.

Challenges When Measuring SiC MOSFETs in Power Electronics Systems

The challenges you will face when measuring SiC MOSFETs will depend on where and how you’re measuring. Especially in high-side switches, the gate voltage signal on high side (VGS) is floating on a high, rapidly switching offset voltage. These “common mode” variations can cause ringing in the measurement system, as shown in the figure above, and it can be impossible to determine if the ringing is coming from the DUT or from the measurement system. The drain-to-source voltage (VDS) is significantly higher than VGS and is often floating with respect to earth ground. Drain current measurements also require care to insure adequate oscilloscope and probe bandwidth for accurate measurements.

Accurate Silicon Carbide Gate Voltage Measurement

Gate-to-source voltage (VGS) measurements, especially on high-side switches, can be especially challenging. The gate threshold voltage is usually just a few volts, so it is relatively small compared to VDS which can be hundreds of volts.

Traditionally these measurements have been performed using differential probes like the Tektronix THDP0200 Differential Probe. However, using a differential probe may lead to unnecessarily large design margins, especially when making high-side VGS measurements. The voltage on the source terminal of the high-side MOSFET is changing quickly, relative to earth ground. Making this measurement accurately requires very high common mode rejection ratio (CMRR) at high frequencies. Ringing introduced by differential probes can result in devices that are within specification seeming like they are not. Adjusting your design to slow down switching and eliminate spurious ringing will “undo” some of the benefit of designing with these high-speed SiC MOSFETs.

Having a probe with a high CMRR limits the effects of common mode voltage on the output. To enable more accurate measurements, it is recommended that you use optically isolated probes like the IsoVu optically isolated probes. These probes reject 80 dB of common mode signal at 1 GHz and 120 dB at 100 MHz. An example of this effect is shown in Figures 1 & 2 below.

Figure 1. Gate voltage signals observed using a passive probe on the low side (yellow trace) and differential probe on the high side (blue trace). This setup shows significant ringing on the VGS signals, including the high-side drive signal.

Figure 2. Gate voltage signal observed using two IsoVu optically isolated probes (yellow & blue traces). The ringing is greatly reduced, and detail can be seen on the low-side gate signal (yellow). High common mode rejection eliminates the spurious disturbances on the high-side gate signal (blue).

Accurate Silicon Carbide Drain Voltage Measurement

To measure drain voltage in SiC MOSFET’s, you can either use ground-referenced passive probes or differential probes. Ground-referenced probes are relatively inexpensive and are included with oscilloscopes, but they should only be used for ground-referenced measurements. Connecting a ground-referenced probe to a floating (ungrounded) component will result in current flow in the ground lead. And when using multiple ground-referenced probes, extreme care must be taken to connect all reference leads to the same earth potential. An example of an easy mistake using two probes is given in the Effective Measurement of SiC Application Note.

Never remove the ground pin on the power cord of your oscilloscope because this allows the chassis of the scope to float. This presents a safety hazard and may negatively impact measurement performance.

If you do have a ground point available in your design, Tektronix TPP0850 passive high-voltage probes are a good choice for drain voltage measurements on SiC devices. These passive probes can handle up to 1000 Vrms and 2.5 kV peak and present only 1.8 pF of loading.

Using a differential probe such as a Tektronix THDP0200 Differential Probe within its specifications is a simpler and safer way of taking drain voltage measurements. Since it is decoupled from the ground, it provides better safety for both the measuring units and the operator.

MCS Test are an approved UK partner for Tektronix
Content Source: Measuring Silicon Carbide (SiC) MOSFET Signals Effectively | Tektronix


Tektronix THDP0200 High Voltage Differential Probe

200 MHz Bandwidth

The THDP0200 supports bandwidths up to 200 MHz and slew rates up to 650 V/ns at 1/500 gain.

Find out more about Tektronix THDP0200 High Voltage Differential Probe

Tektronix TPP0850 High Voltage Single Ended Probe

800 MHz Bandwidth, Rise Time: <525 ps

The Tektronix TPP0850 High Voltage Single Ended Probe offers the industry's highest bandwidth probe (800 MHz) for high-voltage signals (up to 2500 Vp-p)

Find out more about Tektronix TPP0850 High Voltage Single Ended Probe

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