Information

ManualsBrandsTeledyne LeCroy ManualsProbesTeledyne LeCroy T3RC6000-LF Probe 6.5 MHz, 0.055 Hz

T3RC Rogowski Probe Fact Sheet

Rogowski Current Transducers

Electrical Specications

Model Bandwidth Channel Memory

(per Ch/interleaved)

4 dierent coil sizes, 80mm,

100mm, 200mm or 300mm coil

circumferences. See the Data Sheet

for more details.

The Attenuation Ratio value can be

used in your Oscilloscope’s channel

settings to correctly scale the

channel vertical (Y axis) range.

Some Oscilloscopes allow the

vertical (Y axis) units to be

changed. This should be set to ‘A’

to reflect an Amps measurement.

The Teledyne Test Tools Rogowski

Current Transducers come in a

protective case and include a set of

batteries and a wall power adaptor.

The inclusion of both battery power and

wall plug operation means that the

Teledyne Test Tools Rogowski Current

Probes are as happy working out in the

eld as they are working on the bench.

Excellent Performance

●

5 dierent probes covering a wide range of

applications.

●

Maximum current measurement coverage up to

6000 Amps.

●

Peak coil insulation voltage up to 10 kV depending

on probe model (See the Data Sheet for more

details).

●

Power via the supplied wall power adaptor or use

with batteries.

●

Low loading of the circuit under test.

●

Wide coil operating temperature from -40 C to

+125 C on UM and HF probes. -20 C to +100 C

for LF probes.

●

Compatible with the majority of Oscilloscopes with

a BNC input connector and a 1 MOhm input

impedance.

Model Sensitivity

Peak

Current

Max Noise

Droop

(%/ms)

LF (-3dB)

Bandwidth

HF (-3dB)

Bandwidth

Peak di/dt

Attenuation

Ratio

T3RC0300-UM 20 mV/A 300 A 2.5 mV rms 9 9.2 Hz 30 MHz 20 kA/us 50

T3RC0600-HF 10 mV/A 600 A 1.7 mV rms 11 12 Hz 30 MHz 40 kA/us 100

T3RC3000-HF 2 mV/A 3000 A 1.4 mV rms 2.8 3 Hz 23 MHz 80 kA/us 500

T3RC3000-LF 2 mV/A 3000 A 2.5 mV rms 0.1 0.11 Hz 6.5 MHz 11 kA/us 500

T3RC6000-LF 1 mV/A 6000 A 2.5 mV rms 0.05 0.055 Hz 6.5 MHz 11 kA/us 1000

Application Fields

Component level design and development such as

semiconductor switching waveforms in MOSFET or

IGBT, also capacitor and inductor devices.

Research and Development.

System level development such as motor drives in

hybrid and fully electric transportation systems

(automotive, rail, sea, etc)

Power converter design and development for wind

farms and other renewable energy.

Long term system monitoring and maintenance.