A logic gate system for fault insertion testing can include a logic gate module having a plurality of input pins. The plurality of input pins can include an input signal pin configured to receive an input signal, a power supply input pin configured to receive power from a power supply, and a test input pin. The logic gate module can also include an output pin connected to the input pins via one or more logic gates. The logic gate system can include a power supply line connected to the power supply input pin and the test input pin. The logic gate system can also include a zero-ohm jumper resistor disposed between the power supply input pin and the test input pin. The zero-ohm resistor can be configured to be replaced with a low ohm resistor to allow reverse driving a voltage on the test input pin. The one or more logic gates can be configured to reverse an output at the output pin when the voltage on the test input pin is reverse driven.

Disclosed herein is a pseudo-random binary sequence (PRBS) generator (200) for performing on-chip testing. It comprises of a plurality of lanes (L1-L4), wherein each lane comprises a latch group (Lg1-Lg4) capable of receiving clock signals, wherein a number of latches in each latch group is based on an output sequence to be generated for performing the on-chip testing. Each latch group is having at least one of a flip-flop and a latch is further connected with a plurality of logic gates in such a manner that an output, generated by the at least one of the flip-flop and the latch of each latch group, is provided as an input to the plurality of logic gates.

A failure diagnostic apparatus includes a path calculation unit which calculates, for each input pattern to a diagnosis target cell, a path affecting an output value of the diagnosis target cell when a failure is assumed as an activation path, a path classification unit which classifies the activation path associated with the input pattern for which the diagnosis target cell has passed a test and the activation path associated with the input pattern for which the diagnosis target cell has failed the test, a path narrowing unit which calculates a first failure candidate path, a second failure candidate path and a normal path of the diagnosis target cell based on classified activation paths, and a result output unit which outputs information on the first failure candidate path, the second failure candidate path and the normal path.

Disclosed herein is a pseudo-random binary sequence (PRBS) generator (200) for performing on-chip testing. It comprises of a plurality of lanes (L1-L4), wherein each lane comprises a latch group (Lg1-Lg4) capable of receiving clock signals, wherein a number of latches in each latch group is based on an output sequence to be generated for performing the on-chip testing. Each latch group is having at least one of a flip-flop and a latch is further connected with a plurality of logic gates in such a manner that an output, generated by the at least one of the flip-flop and the latch of each latch group, is provided as an input to the plurality of logic gates.

A field-programmable gate array includes a memory, a firmware state machine, a register, and an interconnect structure. The memory is configured to store a plurality of configurations. Each of the plurality of configurations has at least one parameter associated therewith. The firmware state machine is configured to read the parameters stored in the memory. The register is configured to have the parameters associated with the plurality of configurations written thereto. The interconnect structure is configured to transmit the parameters between the firmware state machine and the register. The interconnect structure is configured to receive the parameters associated with the plurality of the configurations simultaneously and the interconnect structure is configured to transmit the received parameters associated with the plurality of configurations to the register simultaneously.

A test circuit for testing an integrated circuit includes a plurality of normal flip flops and a modified flip flop, wherein the integrated circuit includes a black box circuit and a plurality of combinational logic circuits. The normal flip flops each includes a first input pin, a second input pin and a first output pin and is configured to temporarily store the input value of the first input pin or the input value of the second input pin according to a scan enable signal. The modified flip flop includes a third input pin, a fourth input pin and a second output pin which are coupled to the black box circuit, the normal flip flops and the combinational logic circuits and is configured to temporarily store the input value of the third input pin or the input value of the fourth input pin according to a scan test mode signal.

A test circuit for testing an integrated circuit includes a plurality of normal flip flops and a modified flip flop, wherein the integrated circuit includes a black box circuit and a plurality of combinational logic circuits. The normal flip flops each includes a first input pin, a second input pin and a first output pin and is configured to temporarily store the input value of the first input pin or the input value of the second input pin according to a scan enable signal. The modified flip flop includes a third input pin, a fourth input pin and a second output pin which are coupled to the black box circuit, the normal flip flops and the combinational logic circuits and is configured to temporarily store the input value of the third input pin or the input value of the fourth input pin according to a scan test mode signal.

A failure diagnostic apparatus includes a path calculation unit which calculates, for each input pattern to a diagnosis target cell, a path affecting an output value of the diagnosis target cell when a failure is assumed as an activation path, a path classification unit which classifies the activation path associated with the input pattern for which the diagnosis target cell has passed a test and the activation path associated with the input pattern for which the diagnosis target cell has failed the test, a path narrowing unit which calculates a first failure candidate path, a second failure candidate path and a normal path of the diagnosis target cell based on classified activation paths, and a result output unit which outputs information on the first failure candidate path, the second failure candidate path and the normal path.

A series of pseudo-random test patterns provide inputs to a logic circuit for performing logic built-in self test (LBIST). A weight configuration module applies one or more weight sets to the pseudo-random test patterns, to generate a series of weighted pseudo-random test patterns. A logic analyzer determines a probability expression for each given net of the logic circuit, based on associated weight sets and a logic function performed by the net. A probability module computes an output probability for each net based on associated probability expressions and associated input probabilities. The weight configuration module optimizes the weight sets, based on the computed net probabilities, and further based on a target probability range bounded by lower and upper cutoff probabilities.

A field-programmable gate array includes a memory, a firmware state machine, a register, and an interconnect structure. The memory is configured to store a plurality of configurations. Each of the plurality of configurations has at least one parameter associated therewith. The firmware state machine is configured to read the parameters stored in the memory. The register is configured to have the parameters associated with the plurality of configurations written thereto. The interconnect structure is configured to transmit the parameters between the firmware state machine and the register. The interconnect structure is configured to receive the parameters associated with the plurality of the configurations simultaneously and the interconnect structure is configured to transmit the received parameters associated with the plurality of configurations to the register simultaneously.