Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a test system comprises pre-qualifying test components, functional test components, a controller, a transceiver, and a switch. The pre-qualifying test components are configured to perform pre-qualifying testing on a device under test. The functional test components are configured to perform functional testing on the device under test. The controller is configured to direct selection between the pre-qualifying testing and functional testing. The transceiver is configured to transmit and receive signals to/from the device under test. The switch is configured to selectively couple the transceiver to the pre-qualifying test components and functional test components.

The disclosure describes a novel method and apparatus for improving the operation of a TAP architecture in a device through the use of Command signal inputs to the TAP architecture. In response to a Command signal input, the TAP architecture can perform streamlined and uninterrupted Update, Capture and Shift operation cycles to a target circuit in the device or streamlined and uninterrupted capture and shift operation cycles to a target circuit in the device. The Command signals can be input to the TAP architecture via the devices dedicated TMS or TDI inputs or via a separate CMD input to the device.

The present invention provides a method, device, and system for testing devices under testing (DUTs). The method comprises: sending a scan activated signal and a synchronous clock signal via the second signal line, and sending a first preset signal via the serial signal line, wherein each bit of the first preset signal is transmitted to a corresponding scan chain unit in a sequence of serial connection of the plurality of scan chain units with according to the synchronous clock signal, the corresponding scan chain unit is one of the plurality of scan chain units connected serially and coupled to the plurality of DUTs via a third signal line; sending a scan deactivated signal via the second signal line, to deactivate the scan chain units from identifying and receiving the first preset signal; and sending a second preset signal via the second signal line, and sending a test signal via the first signal line.

The invention discloses an extended joint test action group based controller and a method for functional debugging using the extended joint test action group based controller. The object of the invention to lower the power dissipation (dynamic and leakage) but providing the same functionality of the testing and debugging procedures at the same time will be solved by an extended joint test action group (JTAG) controller for testing flip-flops of a register of an integrated circuit (IC) using a design for testing scan infrastructure on the IC which comprises at least one scan chain, wherein an external debugger is connected to the design for testing scan infrastructure via the JTAG controller which is extended by a debug controller, whereas a feedback loop is formed from an output of the scan chain to an input multiplexer of the scan chain which is activated according to the extended JTAG controller.

An augmented simulation model can be created of an integrated circuit (IC) design by inserting a switch in a simulation model of the IC design between an output of a scan cell and an input of a combinational logic cloud. A simulation enable signal can be used to control the switch. Next, an IC design simulation environment can be generated based on the augmented simulation model. The IC design can be verified by using the IC design simulation environment. The simulation enable signal can be activated when the combinational logic cloud is desired to be simulated by the IC design simulation environment.

Ring packet built-in self-test (PBIST) circuitry configured to detect errors in wires connecting a ring of superconducting chips includes circuitry configured to make the PBIST immune to interchip latency and still allow the PBIST to test a stop-to-stop connection. By making a PBIST independent of latency, an entire ring can be characterized for latency and for its bit-error rate prior to running any functional test. Such systems and associated methods can be scaled to larger platforms having any number of ring stops. The PBIST circuitry can function as either transmitter or receiver, or both, to test an entire ring. The PBIST can also be used to tune clocks in the ring to achieve the lowest overall bit error rate (BER) in the ring.

Various embodiments are described that relate to failure determination for an integrated circuit. An integrated circuit can be tested to determine if the integrated circuit is functioning properly. The integrated circuit can be subjected to a specific radiation such that the integrated circuit produces a response. This response can be compared against an expected response to determine if the response matches the expected response. If the response does not match the expected response, then the integrated circuit fails the test. If the response matches the expected response, then the integrated circuit passes the test.

Testing of die on wafer is achieved by; (1) providing a tester with the capability of externally communicating JTAG test signals using simultaneously bidirectional transceiver circuitry, (2) providing die on wafer with the capability of externally communicating JTAG test signals using simultaneously bidirectional transceiver circuity, and (3) providing a connectivity mechanism between the bidirectional transceiver circuitry's of the tester and a selected group or all of the die on wafer for communication of the JTAG signals.

Ring packet built-in self-test (PBIST) circuitry configured to detect errors in wires connecting a ring of superconducting chips includes circuitry configured to make the PBIST immune to interchip latency and still allow the PBIST to test a stop-to-stop connection. By making a PBIST independent of latency, an entire ring can be characterized for latency and for its bit-error rate prior to running any functional test. Such systems and associated methods can be scaled to larger platforms having any number of ring stops. The PBIST circuitry can function as either transmitter or receiver, or both, to test an entire ring. The PBIST can also be used to tune clocks in the ring to achieve the lowest overall bit error rate (BER) in the ring.

A method for testing a chip comprising: receiving N scan-in chains of test data; using the N scan-in chains of test data to perform tests on the chip; receiving a merged expected test-result and masking-instruction signal on X pins of the chip from the off-chip test equipment, X being less than 2*N; decoding the merged expected test-result and masking-instruction signal to extract N decoded output signals, each of the N decoded output signals corresponding to a respective chain of test results.