A system includes a multiple input signature register (MISR) to receive outputs from M different scan chains in response to N test patterns applied to test an integrated circuit. The MISR provides N test signatures for the integrated circuit based on the outputs of the M different scan chains generated in response to each of the N test patterns. Each of the scan chains holds one or more test data bits that represent behavior of the integrated circuit in response to each of the N test patterns. A shift register is loaded from an interface and holds one of N comparison signatures that is used to validate a respective one of the N test signatures generated according to a given one of the N test patterns. A comparator compares each of the N test signatures with a respective one of the N comparison signatures to determine a failure condition based on the comparison.

A device for a system on a chip (SOC), the device includes: a comparator that includes a first input port, a second input port, and an output port. A first input signal and a second input signal are split into N bit pairs that include one bit from the first input signal and one bit from the second input signal. The comparator is configured so a mismatch between the first input signal and the second input signal causes an output signal to assume a first expected state. The device further comprises a test controller to perform a first operability test by mismatching the N bit pairs and verifying that the output signal assumes the first expected state.

A device for a system on a chip (SOC), the device includes: a comparator that includes a first input port, a second input port, and an output port. A first input signal and a second input signal are split into N bit pairs that include one bit from the first input signal and one bit from the second input signal. The comparator is configured so a mismatch between the first input signal and the second input signal causes an output signal to assume a first expected state. The device further comprises a test controller to perform a first operability test by mismatching the N bit pairs and verifying that the output signal assumes the first expected state.

An apparatus comprises a first semiconductor chip comprising a first communication controller to receive first debug data from a second semiconductor chip; a memory to store the first debug data from the second semiconductor chip and second debug data of the first semiconductor chip; and a second communication controller to transmit the first debug data from the second semiconductor chip and the second debug data of the first semiconductor chip to an output port of the first semiconductor chip.

A load pull system for making measurements on a DUT at millimeter wave frequencies using active tuning. The system uses phase and amplitude control of each signal at low frequency before being upconverted to the millimeter wave measurement frequencies. The measured signals at the DUT plane may be down-converted for measurement with a low frequency analyzer.

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.

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.

A measurement system for measuring a device under test is described. The measurement system includes a control and analysis module composed of one or more circuits, a stimulus module composed of one or more circuits, and a measurement interface composed of ,for example, one or more circuits. The stimulus module is configured to generate an electric stimulus signal based on predefined measurement parameters. The measurement system is configured to be connected to a device under test via the measurement interface. The measurement interface is configured to forward the electric stimulus signal from the stimulus module to the device under test. The measurement interface further is configured to forward a response signal from the device under test to the control and analysis module, wherein the response signal corresponds to a response of the device under test to the stimulus signal. The control and analysis module is configured to analyze the response signal, thereby generating a set of analysis data. The control and analysis module is further configured to compare the set of analysis data generated with a database. The database includes several measurement data sets being associated with different classes or types of devices under test. The control and analysis module is further configured to adapt the predefined measurement parameters of the stimulus module based on the comparison of the set of analysis data with the database. Further, a method of measuring a device under test is described.

A multi-channel timing calibration device and a method applicable thereto are provided. The device includes: a plurality of channel inputs, at least one relay switch, at least one comparator, at least one first multiplexer, and a time measurement chip. The at least one comparator is connected to the at least one relay switch, and connected to a reference voltage or a digital analog converter. The at least one first multiplexer has different signals for different channel groups and outputs a signal of a designated channel. The time measurement chip calculates a timing difference of each of the channels of each of the channel inputs as a basis for delay of the timing signals.

This document describes techniques and systems for leakage screening based on power prediction. In particular, the described systems and techniques estimate, during a silicon manufacturing process, use-case power (e.g., low power, ambient power, high power, gaming power) to apply leakage screening for apart (e.g., a chip package). In some aspects, measurable silicon parameters (e.g., leakage values, bin values, processor sensor values) may be used for use-case power prediction. Using the described techniques, a maximum allowable predicted use-case power can be determined and used for leakage screening regardless of an individual rail leakage or voltage bin assignment.