A system comprises a memory sub-system controller mounted to a printed circuit board (PCB) and an in-circuit test (ICT) device. The memory sub-system controller has test points on the PCB comprising stimulus points and observation points. The ICT device connects to the test points of the controller. The ICT device converts automated test pattern generation (ATPG) input test vectors to test signals. A first set of pin drivers of the ICT device applies the test signals to the stimulus points of the controller and a second set of pin drivers of the ICT device read output signals output at the observation points of the controller. A comparator of the ICT device compares the output signals with output test vectors. The comparator provides test result data comprising a result of the comparison.

An integrated circuit comprising: a plurality of on-chip-instrument-modules; a test-controller-module configured to communicate data with the plurality of on-chip-instrument-modules; a functional-module configured to communicate data with the plurality of on-chip-instrument-modules; and an on-chip-instrument-controller. The on-chip-instrument controller is configured to: for each of the plurality of on-chip-instrument-modules, store an access-indicator; and based on a value of the access-indicator for each on-chip-instrument-module, enable the on-chip-instrument-module to communicate with either: the test-controller-module; or the functional-module.

An automatic test equipment (ATE) contactor adapter compatible with at least one test board. The contactor adapter includes a contactor adapter body having a first side and a second side. The contactor adapter body includes: 1) a first set of contact components disposed on the first side in an arrangement to contact conductive pads of the at least one test board; and 2) a second set of contact components disposed on the second side and coupled to the first set of contact points. The contactor adapter also includes an adapter interface disposed on the contactor adapter body. The adapter interface includes a third set of contact components coupled to the second set of contact components. The ATE contactor adapter is configured to convey signals between a device under test (DUT) and the at least one test board via the first, second, and third sets of contact components.

A method of network extraction based on phase localization using a test setup including a standard includes measuring frequency data using a measuring instrument connected with the test setup by performing a frequency sweep across an identified bandwidth, correlating filter functions as required against the measured frequency domain data to localize phase across the test setup, removing excess phase rotation and solving for inner plane match of the test setup based on known composite measurement and previously identified components of the test setup.

A system comprises a memory sub-system controller mounted to a printed circuit board (PCB) and an in-circuit test (ICT) device. The memory sub-system controller has test points on the PCB comprising stimulus points and observation points. The ICT device connects to the test points of the controller. The ICT device converts automated test pattern generation (ATPG) input test vectors to test signals. A first set of pin drivers of the ICT device applies the test signals to the stimulus points of the controller and a second set of pin drivers of the ICT device read output signals output at the observation points of the controller. A comparator of the ICT device compares the output signals with output test vectors. The comparator provides test result data comprising a result of the comparison.

Methods and systems of detecting chip degradation are described. A processor may execute a test on a device at a first time, where the test includes executable instructions for the device to execute a task under specific conditions relating to a performance attribute. The processor may receive performance data indicating a set of outcomes from the task executed by the device during the test. The processor may determine a first value of a parameter of the performance attribute based on the identified subset. The processor may compare the first value with a second value of the parameter of the performance attribute. The second value is based on an execution of the test on the device at a second time. The processor may determine a degradation status of the device based on the comparison of the first value with the second value.

An automatic test equipment (ATE) contactor adapter compatible with at least one test board. The contactor adapter includes a contactor adapter body having a first side and a second side. The contactor adapter body includes: 1) a first set of contact components disposed on the first side in an arrangement to contact conductive pads of the at least one test board; and 2) a second set of contact components disposed on the second side and coupled to the first set of contact points. The contactor adapter also includes an adapter interface disposed on the contactor adapter body. The adapter interface includes a third set of contact components coupled to the second set of contact components. The ATE contactor adapter is configured to convey signals between a device under test (DUT) and the at least one test board via the first, second, and third sets of contact components.

Certain aspects of the disclosure are directed toward test control and test access configuration via two pins on an integrated circuit (IC). According to a specific example, an IC chip-based apparatus is used in connection with a controller for testing a target IC. The IC chip-based apparatus includes an event (capture) circuit configured and arranged to control logic states through which a static test configuration is selected for a given event detected in response to a clock signal and to a data signal respectively derived from the controller. A test-operation control circuit may be configured and arranged to test the target IC by selectively configuring each of the clock pin and the I/O pin of the controller for use as an analog test bus, data input to the controller or data output from the controller, and carrying out dynamic operations by communicating test signals via pins of the target IC.

Methods and apparatus for a diagnostic in situ ring oscillator (RO) circuit for DC and transient characterization. The RO circuit includes a plurality of symmetrical stages coupled via an RO feedback signal line and forming an inverter chain, where each stage includes a CMOS inverter comprising a pair of pMOS and nMOS transistors coupled between power-gating transistors respectively coupled to a positive voltage source and ground, wherein an output of a CMOS inverter for the stage is coupled to an input for the CMOS inverter of a next stage. The first stage is a configurable enable stage to enable the inverter chain to be set into a defined logic state, followed by multiple pre-stage-DUT stages. The output of the last stage is feed back to the input of the enable stage to form an RO feedback signal. The RO circuit can operate in multiple modes including an AC mode, a DC mode, and a hybrid mode.

An apparatus that allows for access to any and all registers of a central processing unit in a line replaceable unit (LRU) without a need to open the housing of the LRU is provided. The apparatus may receive write or read packets from an external device and relay the same to an LRU. The apparatus may receive state information from one or more registers of the LRU in response. The apparatus may transmit or transfer the state information to an external device. The apparatus may be used to update firmware in the LRU, for diagnostics or testing.