An integrated circuit includes a first circuit and a test circuit. The test circuit is configured to test the timing of a first circuit. The first circuit includes a plurality of flip-flops and a plurality of data paths. Each data path of the plurality of data paths is connected to one or more of the plurality of flip-flops. The test circuit includes a plurality of loopback paths, a controller, a multiplexer connected to the plurality of loopback paths and a counter connected to the multiplexer. The controller is configured to select a path from the plurality of loopback paths and the plurality of data paths. The multiplexer is configured to selectively output a first signal including an oscillation frequency. The first signal is applied to the selected path and the counter is configured to measure the oscillation frequency of the first signal.

Disclosed is a system for providing an inference associated with delays in processing input data packet(s) by a Design Under Verification (DUV)/System Under Verification (SUV) characterized by maintaining timing information of the input data packet(s) is disclosed. To provide an inference, initially, an input data packet is processed by a DUV or SUV. Simultaneously, an expected data packet corresponding to the input data packet is predicted and a Unique Identifier is assigned to the expected data packet corresponding to the input data packet that entered into the DUV/SUV. After assigning the Unique Identifier, the plurality of data fields pertaining to the Unique Identifier are populated in an array of Packet Timing Entries based on a Delay Identifier (ID) and a Delay Mode. The plurality of data fields may then be used for reporting various delay statistics and operational behaviour of DUV/SUV.

Aspects include techniques for bypassing an encoded latch on a chip during a test-pattern scan and using on-chip circuitry to generate a desired encoded pattern, which is inserted into a scan-bypassed latch, to test the on-chip circuitry for defects. A computer-implemented method may include applying a global control bit to the chip; initializing a scan of the chip while bypassing the encoded latch; and applying an extra scan clock to initiate the encoded latch after completing the scan, wherein the encoded latch is updated with check bits generated by the on-chip circuitry.

A method for compliance testing of a Digital Interface Board attached to Automatic Test Equipment in the testing of integrated circuit semiconductor devices using Impedance Response Profiling. The includes launching alternating voltage digital clock signals from the Pin Electronics to one or more circuit paths in the Digital Interface Board, and sampling a mix of the launched alternating voltage digital clock signals and reflected signals. The method also includes compositing time domain waveforms originating at the Pin Electronics, and generating an initial reflection response profile baseline. The method is repeated at a later predetermined time, generating a later reflection response profile. The method further includes comparing the initial reflection response profile baseline with the later reflection response profile, and determining whether the one or more circuit paths of the Digital Interface Board are in compliance with predetermined operating standards.

Testing of integrated circuits is achieved by a test architecture utilizing a scan frame input shift register, a scan frame output shift register, a test controller, and a test interface comprising a scan input, a scan clock, a test enable, and a scan output. Scan frames input to the scan frame input shift register contain a test stimulus data section and a test command section. Scan frames output from the scan frame output shift register contain a test response data section and, optionally, a section for outputting other data. The command section of the input scan frame controls the test architecture to execute a desired test operation.

A tester including an interface configured to interface with an electronic device and a logic circuit. The logic circuit includes a pattern generator and at least one finite-state machine and is configured to sequentially acquire read data from the electronic device at sequential testing points of a testing range for evaluating an operating parameter of the electronic device or the tester until a set of consecutive passing points having a first passing point and a last passing point is identified, in response to identifying the first passing point, write data within the logic circuit of the tester identifying the first passing point, in response to identifying the second passing point, write data within the logic circuit of the tester identifying the second passing point, and output only data identifying the first passing point and data identifying the last passing point to a software application.

Systems, devices and methods for high-speed I/O margin testing can screen high volumes of pre-production and production parts and identify cases where the electrical characteristics have changed enough to impact operation. The margin tester disclosed is lower cost, easier to use and faster than traditional BERT and scopes and can operate on the full multi-lane I/O links in their standard operating states with full loading and cross-talk. The margin tester assesses the electrical receiver margin of an operation multi-lane high speed I/O link with a device under test simultaneously in either or both directions. In a technology-specific form, an embodiment of the margin tester can be implemented as an add-in card margin tester to test motherboard slots of a mother board under test, or as a as a motherboard with slots to test add-in cards.

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 burn-in resilient integrated circuit is provided. The burn-in resilient integrated circuit includes an inverter chain and a plurality of inverter circuits on the inverter chain. The burn-in resilient integrated circuit also includes a loop providing an electrical connection from an output of the inverter chain to an input of the inverter chain. The loop is selectable in accordance with a burn-in operation.

A circuit includes a dynamic core data register (DCDR) cell that includes a data register, a shift register and an output circuit to route the output state of the data register or the shift register to an output of the DCDR in response to an output control input. A clock gate having a gate control input controls clocking of the shift register in response to a first scan enable signal. An output control gate controls the output control input of the output circuit and controls which outputs from the data register or the shift register are transferred to the output of the output circuit in response to a second scan enable signal. The first scan enable signal and the second scan enable signal to enable a state transition of the shift register at the output of the DCDR.