P6015A:1R产品概述
Spring Contact Probe, Gold Plated Barrel, Beryllium Copper Spring
Introduction:
Precision Measurements start right at the probe tip. The right probes matched to the oscilloscope and the device-under-test (DUT) allow the signal to be brought to the oscilloscope cleanly for the greatest signal fidelity and measurement accuracy.
To measure typical signal and voltage levels, passive probes provide ease-of-use and a wide range of measurement capabilities at an affordable price. The pairing of a passive voltage probe with a current probe will provide you with an ideal solution to measure power.
However, general-purpose passive probes cannot accurately measure signals with the fastest rise times, and may excessively load sensitive circuits. To measure signals with fast rise times, a high-speed active or differential probe will provide more accurate results.
Tektronix is the leader in probing technologies. We offer the world's most advanced high-bandwidth differential and active probes — up to 5 GHz differential and 6 GHz active — to access dense, high-speed circuitry with the highest signal fidelity currently achievable, all matched perfectly to Tektronix oscilloscopes.
In addition to its industry-leading probes, Tektronix offers carts and workstations to free up bench space and make equipment easy to share and move around. Our rugged transit cases and travel accessories can be used to ship or transport your instrument.
Attenuating passive Voltage Probes are the most commonly used probes today. They provide a convenient and extremely rugged, yet inexpensive way to acquire signals from your device under test. They maintain the accuracy of the oscilloscope to which they are connected over a wide dynamic range. The 10X passive voltage probe presents a high impedance to the circuit under test at low frequencies (approximately 5 MHz and lower). Their main disadvantage is a decreasing impedance level with increasing frequency (i.e. high input capacitance).
For heavy-duty, high-performance measurements of voltages over 2.5 kV and this is industry standard. You can measure DC voltages up to 20 kVRMS and pulses up to 40 kV (peak, 100 ms duration). The 75 MHz bandwidth enables you to capture fast, high-voltage