A multiple operating-mode comparator system can be useful for high bandwidth and low power automated testing. The system can include a gain stage configured to drive a high impedance input of a comparator output stage, wherein the gain stage includes a differential switching stage coupled to an adjustable impedance circuit, and an impedance magnitude characteristic of the adjustable impedance circuit corresponds to a bandwidth characteristic of the gain stage. The comparator output stage can include a buffer circuit coupled to a low impedance comparator output node. The buffer circuit can provide a reference voltage for a switched output signal at the output node in a higher speed mode, and the buffer circuit can provide the switched output signal at the output node in a lower power mode.

A ground fault detection circuit can include a band-pass filter that can have a first node and a second node that can be coupled to an earth ground. The first node can be coupled to a local ground of an automatic test equipment (ATE) system for an electrical device that can be coupled via at least one wire to the ATE. The band-pass filter can be configured to pass and amplify a test current signal established at the first node in response to a coupling of one of a conductor of the at least one wire carrying the test current signal to the local ground, and a conductive element of the electrical device carrying the test current signal to the local ground. A fault alert signal can be provided to provide an indication of ground fault based on a comparison of the amplified test current signal.

A test and measurement system includes a test and measurement device configured to receive a signal from a device under test, and one or more processors configured to execute code that causes the one or more processors to generate a waveform from the signal, apply an equalizer to the waveform, receive an input identifying one or more measurements to be made on the waveform, select a number of unit intervals (UIs) for a known data pattern, scan the waveform for the known data patterns having a length of the number of UIs, identify the known data patterns as short pattern waveforms, apply a machine learning system to the short pattern waveforms to obtain a value for the one or more measurements, and provide the values of the one or more measurements for the waveform. A method includes receiving a signal from a device under test, generating a waveform from the signal, applying an equalizer to the waveform, receiving an input identifying one or more measurements to be made on the waveform, selecting a number of unit intervals (UIs), scanning the waveform to identify short pattern waveforms having a length equal to the number of UIs, applying a machine learning system to the short pattern waveforms to obtain a value for the one or more measurements, and providing the values of the one or more measurements for the waveform from the machine learning system.

The present disclosure describes a method for analyzing signal waveforms produced by integrated circuits. The method includes determining characteristic points of a control signal, and each characteristic point includes a corresponding time value and represents an edge change of the control signal. The method also includes determining sets of data sampling points. Each set of data sampling points is located between adjacent characteristic points of the characteristic points. The method further includes obtaining data values of a signal waveform, and a data value of the signal waveform is obtained at a data sampling point of the sets of data sampling points. The method further includes obtaining data values of a reference waveform, and a data value of the reference waveform is obtained at the data sampling point and determining a difference between the data value of the signal waveform and the data value of the reference waveform.

A multiple operating-mode comparator system can be useful for high bandwidth and low power automated testing. The system can include a gain stage configured to drive a high impedance input of a comparator output stage, wherein the gain stage includes a differential switching stage coupled to an adjustable impedance circuit, and an impedance magnitude characteristic of the adjustable impedance circuit corresponds to a bandwidth characteristic of the gain stage. The comparator output stage can include a buffer circuit coupled to a low impedance comparator output node. The buffer circuit can provide a reference voltage for a switched output signal at the output node in a higher speed mode, and the buffer circuit can provide the switched output signal at the output node in a lower power mode.

Systems, methods, and apparatuses are described for verifying the authenticity of an integrated circuit device. An integrated test apparatus may use quiescent current and/or conducted electromagnetic interference readings to determine if a device under test matches the characteristics of an authenticated device. Deviations from the characteristics of the authenticated device may be indicative of a counterfeit device.

A test system can receive a test signal from a device under test (DUI) via a first signal path. A comparator circuit can receive the test signal and, in response, generate an intermediate output signal based on a magnitude relationship between the test signal a comparator reference signal. A compensation circuit can generate a correction signal that is complementary to a portion of the received test signal, such as to correct for loading effects of the first signal path. The test system can include an output circuit configured to provide a corrected differential output signal that is based on a combination of the intermediate output signal and the correction signal.

A measurement system is described. The measurement system includes a test-and-measurement (T&A) circuit and an error analysis circuit. The T&A circuit is configured to generate measurement data. The measurement data includes at least one of analysis data and configuration data. The analysis data is associated with an analysis of at least one input signal. The configuration data is associated with at least one of a physical measurement setup of the measurement system and measurement settings of the measurement system. The T&A circuit further is configured to generate a graphic representation of the measurement data. The error analysis circuit is configured to identify errors or anomalies associated with the measurement data based on the graphic representation. Further, a measurement method is described.

A measurement instrument for testing a device under test is described. The device under test has at least two test points. The measurement instrument includes a first measurement channel, a second measurement channel, and a machine-learning circuit. The first measurement channel is configured to process a first input signal associated with one of the at least two test points, thereby generating a first measurement signal. The second measurement channel is configured to process a second input signal associated with another one of the at least two test points, thereby generating a second measurement signal. The machine-learning circuit is configured to determine at least one correlation quantity based on the first measurement signal and based on the second measurement signal, wherein the at least one correlation quantity is indicative of a correlation between the first measurement signal and the second measurement signal. Further, a measurement system and a signal processing method are described.

According to one or more embodiments, the semiconductor integrated circuit device includes a pattern generator, a result comparator, and a control circuit. The pattern generator supplies input data to a device-under-test. The result comparator compares output data of the device-under-test with expected value data and outputs a test result signal. The control circuit controls the pattern generator and the result comparator. The device-under-test and the result comparator are commonly connected to a first clock line. The pattern generator and the control circuit are commonly connected to a second clock line different from the first clock line.