Systems and methods for calibrating a conducted electrical weapon (CEW) to provide a predetermined amount of current for each pulse of the stimulus signal. Providing the predetermined amount of current, close thereto, increases the effectiveness of the stimulus signal in impeding locomotion of a human or animal target. The calibration process enables a CEW to calibrate the amount of charge in a pulse of the stimulus signal in the environmental conditions where the tester operates and also in the field where the environmental conditions may be different from the environmental conditions during calibration.

Systems and methods for calibrating a conducted electrical weapon (CEW) to provide a predetermined amount of current for each pulse of the stimulus signal. Providing the predetermined amount of current, close thereto, increases the effectiveness of the stimulus signal in impeding locomotion of a human or animal target. The calibration process enables a CEW to calibrate the amount of charge in a pulse of the stimulus signal in the environmental conditions where the tester operates and also in the field where the environmental conditions may be different from the environmental conditions during calibration.

An apparatus includes an external terminal, an output circuit having an impedance corresponding to a code signal, and a calibration circuit configured to produce the code signal responsive to a comparison of a voltage at the external terminal with a reference voltage, the comparison performed by a first cycle period in a first mode and by a second cycle which is longer than the first cycle period in a second mode.

The present disclosure provides a method for operating a measurement system that comprises at least one measurement application device and at least one device under test, the method comprising centrally configuring the measurement system for a test measurement, centrally verifying the correct setup of the measurement system, and performing the test measurement with the measurement system. In addition, the present disclosure provides a respective central test control unit and a respective measurement system.

Systems and methods for calibrating a voltage measurement device are provided herein. The voltage measurement device generates a reference current signal and senses the reference current signal in a conductor under test. A calibration system may control a calibration voltage source to selectively output calibration voltages in a calibration conductor. The calibration system may obtain data from the voltage measurement device captured by the voltage measurement device when measuring the calibration conductor. Such data may include one or more reference current measurements, one or more voltage measurements, etc. The calibration system utilizes the obtained measurements to generate calibration data which may be stored on the voltage measurement device for use thereby during subsequent operation. The calibration data may include one or more lookup tables, coefficients for one or more mathematical formulas, etc.

An example process for aligning channels in automatic test equipment (ATE) includes programming a first delay associated with receiving first data over a channel so that timing of the channel is aligned to timings of other channels in the ATE; programming a second delay associated with a driver driving second data over the channel based on receipt of an edge of the second data so that timing of the second data is aligned to the timing of the channel; and programming a third delay associated with a signal to enable the driver to drive the second data over the channel, with the third delay being programmed to align timing of the signal to the timing of the channel, and with the third delay being based on an edge that corresponds to an edge of the signal created by controlling operation of the driver.

Test standards and methods for impedance calibration of a probe system and probe systems that include the test standards and/or utilize the methods are disclosed herein. The test standards include at least one test structure. In some embodiments, the test standard further includes an alignment structure that is associated with the test structure. In some embodiments, the test standards include a plurality of test structures. In some embodiments, the plurality of test structures includes a thin film thru test structure and a thin film offset test structure. In some embodiments, the plurality of test structures is positioned to simultaneously contact a plurality of probe regions of a probe head. The methods include methods of calibrating a probe system.

The invention concerns devices and methods for calibrating an Automated Test Equipment for automated testing of a Device Under Test. The method includes providing two digital channel signals by two different channels of the Automated Test Equipment, wherein the digital channel signals include an identical or a complementary pattern with respect to their edges. The method further includes sum-combining or difference-combining the two digital channel signals in order to obtain a combined residual signal. The step of combining is performed such that combining provides a combined residual signal without a time-variant component if the two digital channel signals have a predetermined time shift or a predetermined phase shift relative to each other, or such that the combined residual signal includes a time variant component if the two digital channel signals have a time shift different from the predetermined time shift or a phase shift different from the predetermined phase shift.

This disclosure is in the field of electronics and more specifically in the field of timing control electronics. In an example, a timing control system can include or use an array of circuit cells, and each cell can provide a signal delay using a fixed delay or interpolation. The interpolation can include, in one or more cells, using three timing signals with substantially different delays to create a delayed output signal. Linearity of the delayed output signal is thereby improved. In an example, an impedance transformation circuit can be applied to improve a bandwidth in one or more of the cells to thereby improve the bandwidth of the timing control system.

A tester including a source and measuring device and a TX port connected to the source and measuring device is configured to determine a source reflection coefficient using an extension circuit. The extension circuit includes a calibration device having a power sensor. The calibration device is configured to provide a plurality of different terminations at the TX port. The tester is configured to calibrate a source power of the source and measuring device using the determined source reflection coefficient and the power sensor.