Manual
Table Of Contents
- toc
- General Safety Summary
- Compliance Information
- Preface
- Getting Started
- System Configuration
- Options
- Standard Accessories
- Optional Accessories
- Probe Covers
- Travel Case
- Connecting the Amplifier to an Oscilloscope
- Power on the Amplifier
- Connecting a Current Probe to the Amplifier
- Operating the Current Probe Slide
- Degaussing and Autobalancing the Current Probe
- DC Measurements
- AC Measurements
- Control Summary
- Reference Notes
- Specifications
- Glossary
Application Notes
High-Impedance Pulse
Sources
If the pulse sou
rce has a higher impedance of known resistance, such that the
output voltage drops as the current increases, the inductance of a coil can be
calculated by the time constant of the charge curve. The current ramp shows how
the values for the inductance formula are obtained. (See Figure 22 on page 37.)
Use this formula to ca lculate the inductance based o n the current measurement:
where L is the inductance in henries, t is the time required for the current to rise or
fall 63.2% of the total c urrent value, and R is the source resistance of the pulse
generator.
Figure 22: High-impedance source current ramp
Continuity Test of Multiple-Conductor Cable
Single conductors in a m ulticonductor cable can be tested with the TCPA300 and
TC
PA400. To check a conductor, clamp the current probe around the cable bundle
and check for a specific, known current signal. If there is no current or the current
is abnormally low, then the conductor has a continuity problem. If the current is
abnormally high, then the conductor may have a short to ground.
TCPA300/400 Amplifiers and TCP300/400 Series Current Probes User Manual 37