Abstract: A system and method are provided for compensating for thermal drift of a probe device. The method includes monitoring a first temperature of a laser source in a sensor head that receives output electrical signals from a DUT and outputs corresponding optical signals; monitoring a second temperature of a photoreceiver in a probe interface that converts the optical signals to electrical test signals to input to the test instrument; calculating a first value of a first bias voltage using the first temperature; applying the first value of the first bias voltage to the laser source to compensate for thermal drift when the first temperature is within a first predefined temperature range; calculating a second value of a second bias voltage for the photoreceiver using the second temperature; and applying the second value of the second bias voltage to the photoreceiver to compensate for thermal drift when the second temperature is within a second predefined temperature range.

Abstract: A direct current (DC) power rail probe includes a single-ended probe tip, and a two-path circuit having an input coupled to the single-ended probe tip and an output configured for connection to measurement equipment such as an oscilloscope. The two-path circuit includes an alternating current (AC) path in parallel with a feed-forward (FF) path, the AC path including a capacitive element, and the FF path including a series connection of at least one resistive element and an amplifier. The probe tip and two-path circuit are selectively operable in a non-attenuating mode and an attenuating mode.

Abstract: A direct current (DC) power rail probe includes a single-ended probe tip, and a two-path circuit having an input coupled to the single-ended probe tip and an output configured for connection to measurement equipment such as an oscilloscope. The two-path circuit includes an alternating current (AC) path in parallel with a feed-forward (FF) path, the AC path including a capacitive element, and the FF path including a series connection of at least one resistive element and an amplifier. The probe tip and two-path circuit are selectively operable in a non-attenuating mode and an attenuating mode.

Abstract: A miniature probe for measuring small voltage signals of a DUT includes a probe body having a flexible substrate and signal transmission lines running a longitudinally, and a first probe connection circuit located at a first end of the probe body and including exposed wires, SMT components coupled between the exposed wires and the signal transmission lines, respectively, and a local mechanical stiffener mounted adjacent the SMT components. The wires are connectable to the DUT for receiving the voltage signals. The probe further includes a second probe connection circuit located at a second end of the probe body, and including transmission line connectors coupled to the signal transmission lines, respectively, and a bent portion of the flexible substrate between the probe body and the transmission line connectors. The bent portion enables the transmission line connectors to exit the probe substantially axially, relative to the longitudinal length of the probe body.

Abstract: A miniature probe for measuring small voltage signals of a DUT includes a probe body having a flexible substrate and signal transmission lines running a longitudinally, and a first probe connection circuit located at a first end of the probe body and including exposed wires, SMT components coupled between the exposed wires and the signal transmission lines, respectively, and a local mechanical stiffener mounted adjacent the SMT components. The wires are connectable to the DUT for receiving the voltage signals. The probe further includes a second probe connection circuit located at a second end of the probe body, and including transmission line connectors coupled to the signal transmission lines, respectively, and a bent portion of the flexible substrate between the probe body and the transmission line connectors. The bent portion enables the transmission line connectors to exit the probe substantially axially, relative to the longitudinal length of the probe body.

Abstract: Offset adjustments for both differential and single-ended measurements are accomplished in the same probe or system. Different variable offsets are provided for the positive and negative inputs of a differential amplifier, and a variable offset adjustment is provided to remove differential amplifier output offset. Common mode and reduced dynamic range problems for both differential and single-ended measurements are eliminated. All or desired portions of required functions may be implemented using discrete or DSP approaches.

Abstract: A voltage probe includes a signal lead that is configured to be soldered to a probing location in a device that is to be probed by the voltage probe, and a first cable that is coupled to the signal lead and that is configured to conduct an output signal that is responsive to an input signal that is received by the signal lead from the device. The signal lead has a thermal conductivity of less than 200 Watts per meter Kelvin (W/mK). Methods and other systems for providing electrical connections to devices under test are disclosed.

Abstract: A voltage probe includes a signal lead that is configured to be soldered to a probing location in a device that is to be probed by the voltage probe, and a first cable that is coupled to the signal lead and that is configured to conduct an output signal that is responsive to an input signal that is received by the signal lead from the device. The signal lead has a thermal conductivity of less than 200 Watts per meter Kelvin (W/mK). Methods and other systems for providing electrical connections to devices under test are disclosed.