Methods for testing an application specific integrated circuit (ASIC). A set of representations is created that overlays power density information and clock gate physical locations of a set of clock gates in a critical sub-chip of the ASIC for test mode power analysis. The set of representations are further grouped in the sub-chip into various groups based on overlapping of the set of representations. Then, a set of test control signals is generated corresponding to each of the set of clock gates during at-speed test mode of operation such that each clock gate with overlapping representations receive different test control signals. Further, patterns are generated using a virtual constraint function to selectively enable the set of test control signals such that the set of test control signals are not activated simultaneously.

A safety circuit for the multi-channel processing of an input signal. The safety circuit includes an analog-to-digital conversion device having a first analog input and a second analog input and at least one digital output for processing the input signal. Furthermore, the safety circuit has a test device which is set up to apply a test signal at the first and/or second input of the A/D conversion device in such a way that the test signal superposes the input signal such that the test signal dominates the input signal.

Approaches for testing phase rotators are provided. A circuit for testing phase rotators includes a compare element including a first input and a second input, wherein the compare element is configured to compare a first phase of a first signal provided at the first input to a second phase of a second signal provided at the second input. The circuit also includes a first test bus connected to the first input and a second test bus connected to the second input.

An embodiment of the present invention provides a computer-implemented method for functional test and diagnostics of integrated circuits. The computer-implemented method includes executing one or more functional test exercisers in a functional execution sequence for a device under test up to one or more checkpoints, applying dynamic clock switching to a clock of the device under test to identify one or more likely causes of a failure identified at the one or more checkpoints, and includes iteratively invoking a portion of the functional execution sequence between a plurality of the checkpoints to progressively isolate the one or more likely causes of the failure as a most likely failure source based at least in part on the applied dynamic clock switching.

Embodiments include methods, and computer system, and computer program products for performing system functional test on a chip having partial-good portions. Aspects include: initializing, by system functional test software, a service engine of the chip, performing, by service engine, system functional test, and completing system functional test of chip. The chip may include service engine, a service engine memory and one or more partial-good portions. The initializing may include: loading system functional test software into the service engine memory, identifying each partial-good portion of the chip, writing a partial-good parameter for each partial-good portion of the chip identified to service engine memory, and triggering execution of system functional test. Method may include: decoding system functional test software, retrieving partial-good parameters, initializing partial-good portions of chip, and performing system functional test on partial-good portions of chip. The chip may include is a processor chip that has one or more partial-good cores.

In one embodiments, a system comprises: a plurality of scan test chains configured to perform test operations at a first clock speed; a central test controller for controlling testing by the scan test chains; and an interface configured to generate instructions to direct central test controller. The interface communicates with the centralized test controller at the first clock speed and an external scan input at a second clock speed. The second clock speed can be faster than the first clock speed. The instructions communicated to the central controller can be directions associated with sequential scan compression/decompression operations. In one exemplary implementation, the interface further comprise a mode state machine used to generate the mode control instructions and a test register state machine that generate test state control instructions, wherein the test mode control instructions and the test state control instructions direct operations of the centralized test controller.

An embodiment of the present invention provides a computer-implemented method for functional test and diagnostics of integrated circuits. The computer-implemented method includes executing one or more functional test exercisers in a functional execution sequence for a device under test up to one or more checkpoints, applying dynamic clock switching to a clock of the device under test to identify one or more likely causes of a failure identified at the one or more checkpoints, and includes iteratively invoking a portion of the functional execution sequence between a plurality of the checkpoints to progressively isolate the one or more likely causes of the failure as a most likely failure source based at least in part on the applied dynamic clock switching.

A method of testing an integrated circuit on a test circuit board includes performing, by a processor, a simulation of a first heat distribution throughout an integrated circuit design, and simultaneously performing a burn-in test of the integrated circuit and an automated test of the integrated circuit. The burn-in test has a minimum burn-in temperature of the integrated circuit or a burn-in heat distribution across the integrated circuit that includes a set of circuit blocks or a first set of heaters. The integrated circuit design corresponding to the integrated circuit. The performing the simulation includes determining a heat signature of the integrated circuit design from configured power information or location information for each circuit block of the set of circuit blocks or each heater of the set of heaters included in the integrated circuit design. The heat signature includes heat values distributed throughout the integrated circuit design.

A system for data creation, storage, analysis, and training while margin testing includes a margin test generator coupled through an interface to a Device Under Test (DUT). The margin test generator is structured to modify test signals for testing the DUT during one or more testing states of a test session to create testing results. The testing results are stored in a data repository along with a DUT identifier of the DUT tested during the test session. A comparator determine whether any results of the DUT test results match a predictive outcome that is based from an analysis of previous DUT tests. If so, a message generator produces an indication that the tested DUT matched the predictive outcome.

Systems and methods for generating defect criticality are disclosed. Such systems and methods may include identifying defect results including a defect and a defect location. Such systems and methods may include receiving fault test recipes configured to test potential faults at a plurality of testing locations. Such systems and methods may include identifying a plurality of N-detect parameters based on a countable number of times the fault test recipes are configured to test a potential fault. Such systems and methods may include determining a plurality of weighting parameters based on the plurality of N-detect parameters. Such systems and methods may include generating the defect criticality for the defect based on a proximity between the plurality of testing locations and the defect location and the plurality of weighting.