Capacitive loading – Teledyne LeCroy ZS2500 User Manual

ZS Series High-Impedance, Active Probes

The resonant frequency of a series LC circuit can be raised by decreasing the

inductance, capacitance or both. Since the input capacitance is already very low

and cannot be reduced, you can only try to reduce the inductance. This can be

accomplished by using the shortest possible input lead as well as the shortest

possible ground lead.
For example, to obtain the shortest possible ground lead when measuring IC

related signals, attach a small piece of copper clad material to the top of the IC

package and connect this to the package grounding wires.
Using the shortest ground lead and input lead available makes probing signals on

the package easier and makes for the shortest lead length for the best signal

fidelity. To illustrate how dramatic this effect is, we will work a simple example.

Assuming an input capacitance of 0.9 pF and a total lead length (input and

ground) of 2 inches (inductance of

≈ 25 nH/inch) such a setup may cause ringing

with a resonant frequency (f0) of:

This frequency is well within the passband of the probe and therefore shows up

as part of the measured signal at faster time/div settings. To determine how fast

a waveform to be measured can be without causing ringing on a probe like this,

divide the BW (ringing frequency) of the probe into 0.35:

Any input signal with a rise time faster than 0.47 ns can cause ringing.

Capacitive Loading

Capacitive loading is usually the most troublesome of the three loading effects.

It can affect the rise time, bandwidth and delay time measurements. At higher

frequencies the capacitive loading can affect the amplitude as well as the

waveshape of the measured signal by introducing an exponential response to

the waveform.
For a simple RC network the time constant of this exponential response is:

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