An integrated circuit device is disclosed. The device includes a circuit configured to perform a function, a fault management component, at least one user register, an analog test bus component, a built-in self-test component, a safety monitor component, and gating logic. Additionally, the circuit is separated from the fault management component, the at least one user register, the analog test bus component, the built-in self-test component, the safety monitor, and the gating logic.

An integrated circuit device is disclosed. The device includes a circuit configured to perform a function, a fault management component, at least one user register, an analog test bus component, a built-in self-test component, a safety monitor component, and gating logic. Additionally, the circuit is separated from the fault management component, the at least one user register, the analog test bus component, the built-in self-test component, the safety monitor, and the gating logic.

Manufacturers perform tests on chips before the chips are shipped to customers. However, defects can occur on a chip after the manufacturer testing and when the chips are used in a system or device. The defects can occur due to aging or the environment in which the chip is employed and can be critical; especially when the chips are used in systems such as autonomous vehicles. To verify the structural integrity of the IC during the lifetime of the product, an in-system test (IST) is disclosed. The IST enables self-testing mechanisms for an IC in working systems. The IST mechanisms provide structural testing of the ICs when in a functional system and at a manufacturer's level of testing. Unlike ATE tests that are running on a separate environment, the IST provides the ability to go from a functional world view to a test mode.

An example test system includes a circuit to sample a signal that is repetitive in cycles to obtain data; a processor configured to generate an eye diagram based on the data, where the eye diagram represents parametric information about the signal; and a functional test circuit to receive the signal and to perform one or more functional tests on the signal. The test systems is configured to receive the signal from a unit under test and to allow the signal to pass to the functional test circuit inline without changing at least part of the signal.

Fault injection testing for field programmable gate array (FPGA) devices including: interfacing with a FPGA device under test (DUT); imaging a configuration RAM (CRAM) of the FPGA DUT with a first configuration image to define a first operational function of the FPGA DUT where the CRAM includes a plurality of CRAM bits, injecting a plurality of single event upsets into a portion of the plurality of the CRAM bits while the FPGA DUT is operating; concurrently monitoring operations of the FPGA DUT and a reference FPGA device; comparing outputs of the FPGA DUT with outputs of the reference FPGA device during concurrent operations, and if there is a mismatch between the outputs of the FPGA DUT and the reference FPGA, determining that error events have occurred within the FPGA DUT; and storing the error events and CRAM location data associated with corresponding single event upsets in an error log.

A scan flip-flop includes a selection circuit, a primary latch, a secondary latch, and a data retention latch. The selection circuit selects and outputs one of functional data, first reference data, scan data, and first control data as second reference data. The primary latch receives the second reference data and outputs third reference data, whereas the secondary latch receives the third reference data and outputs second control data. The second control data is then provided to a subsequent scan flip-flop of a scan chain. The data retention latch receives one of the third reference data and the second control data, and outputs and provides the first reference data to the selection circuit. The first reference data corresponds to functional data retained in the scan flip-flop during a structural testing mode associated with the scan chain.

A scan flip-flop includes a selection circuit, a primary latch, a secondary latch, and a data retention latch. The selection circuit selects and outputs one of functional data, first reference data, scan data, and first control data as second reference data. The primary latch receives the second reference data and outputs third reference data, whereas the secondary latch receives the third reference data and outputs second control data. The second control data is then provided to a subsequent scan flip-flop of a scan chain. The data retention latch receives one of the third reference data and the second control data, and outputs and provides the first reference data to the selection circuit. The first reference data corresponds to functional data retained in the scan flip-flop during a structural testing mode associated with the scan chain.

A fault rules engine generates a plurality of fault rules files, each of the fault rules files is associated with a respective cell type of a plurality of cell types in an integrated circuit (IC) design. Each fault rules file includes data quantifying a nominal delay for a given two-cycle test pattern and data quantifying a delta delay for the given two-cycle test pattern corresponding to a given candidate defect of a plurality of candidate defects of a given cell type of the plurality of cell types in the IC design. An IC test engine extracts an input to output propagation delay for each cell instance from a standard delay format (SDF) file for the IC design and generates cell-aware test patterns for each cell instance of each cell type in the IC design based on the plurality of fault rules files and the extracted input to output propagation delays.

A circuit debug apparatus for debugging an integrated circuit that causes a functional fault may include a processor configured to extract a scan pattern of a scan chain of the integrated circuit while the integrated circuit is in a scan mode. The scan pattern includes a plurality of logic states for a corresponding plurality of logic circuits of the integrated circuit. The processor may also be configured to apply a modified scan pattern to the integrated circuit while the integrated circuit is in the scan mode, where the modified scan pattern includes a test pattern configured to eliminate the functional fault. The processor may be further configured to determine whether the integrated circuit with the modified scan pattern produces the functional fault while the integrated circuit is in a functional mode.

A circuit includes a test circuit in an integrated circuit to test signal timing of a logic circuit under test in the integrated circuit. The signal timing includes timing measurements to determine if an output of the logic circuit under test changes state in response to a clock signal. The test circuit includes a bit register that specifies which bits of the logic circuit under test are to be tested in response to the clock signal. A configuration register specifies a selected clock source setting from multiple clock source settings corresponding to a signal speed. The selected clock source is employed to perform the timing measurements of the specified bits of the bit register.