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Ground-referenced signals are precisely measured using single-ended active probes. They accurately measure both low-frequency and high-speed signals, and it is crucial that the probe impedance only places a light strain on the test point.
While active probes perform better in terms of bandwidth than passive probes, they do require external probe power for the active components inside the probe, such as transistors and amplifiers. Each category offers a wide variety of probe types, and each probe has a particular application for which it excels.
An attachment point for a ground connection on the tip of a single-ended oscilloscope probe is intended to be a ground reference point on the circuit that is being monitored. The voltage detected by a single-ended probe is the difference in voltage between the ground reference connection and the signal connector.
The Global active single ended probes market accounted for $XX Billion in 2021 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2022 to 2030.
Active probes TAP2500, TAP3500, and TAP4000 for the TekVPI probe interfaceTo achieve the highest signal integrity in your measurements, it is essential to choose the appropriate probe for your application. For high-frequency measurements, active probes give more accurate signal reproduction and fidelity.
The TAP2500, TAP3500, and TAP4000 Single-ended Active FET probes offer superb high-speed electrical and mechanical performance necessary for modern digital system designs thanks to their ultra-low input capacitance and distinctive interface.
The TAP2500, TAP3500, and TAP4000 Active FET probes, which are specifically made for use with oscilloscopes and direct connection via the TekVPI probe interface, address three long-standing issues to enable high-speed signal acquisition and measurement fidelity 0.8 pF input capacitance and 40 k input resistance result in reduced DUT loading effects.Flexible DUT connectivity for securing to tiny SMDs for up to 3.5 GHz oscilloscopes, maintains instrument bandwidth at the probe tip.
