An exemplary testing environment can operate in a testing mode of operation to test whether a memory device or other electronic devices communicatively coupled to the memory device operate as expected or unexpectedly as a result of one or more manufacturing faults. The testing mode of operation includes a shift mode of operation, a capture mode of operation, and/or a scan mode of operation. In the shift mode of operation and the scan mode of operation, the exemplary testing environment delivers a serial input sequence of data to the memory device. In the capture mode of operation, the exemplary testing environment delivers a parallel input sequence of data to the memory device. The memory device thereafter passes through the serial input sequence of data or the parallel input sequence of data to provide an output sequence of data in the shift mode of operation or the capture mode of operation or passes through the serial input sequence of data to provide a serial output sequence of scan data in the scan mode of operation.

An exemplary testing environment can operate in a testing mode of operation to test whether a memory device or other electronic devices communicatively coupled to the memory device operate as expected or unexpectedly as a result of one or more manufacturing faults. The testing mode of operation includes a shift mode of operation, a capture mode of operation, and/or a scan mode of operation. In the shift mode of operation and the scan mode of operation, the exemplary testing environment delivers a serial input sequence of data to the memory device. In the capture mode of operation, the exemplary testing environment delivers a parallel input sequence of data to the memory device. The memory device thereafter passes through the serial input sequence of data or the parallel input sequence of data to provide an output sequence of data in the shift mode of operation or the capture mode of operation or passes through the serial input sequence of data to provide a serial output sequence of scan data in the scan mode of operation.

The present disclosure relates to an apparatus, and a method for memory management and more a memory device structured with internal analogic measurement mode features. The memory device includes memory component having a memory array, a memory controller coupled to the memory component, a JTAG interface in the memory controller, voltage and current reference generators, and an analogic measurement block driven by the JTAG interface.

The present disclosure relates to an apparatus, and a method for memory management and more a memory device structured with internal analogic measurement mode features. The memory device includes memory component having a memory array, a memory controller coupled to the memory component, a JTAG interface in the memory controller, voltage and current reference generators, and an analogic measurement block driven by the JTAG interface.

A semiconductor device capable of monitoring a connection state of a terminal on a semiconductor chip includes a selector configured to acquire terminal levels of a plurality of respective terminals on the semiconductor chip to which an inspection pattern is inputted based on a detection signal, a memory configured to store latch data based on a chip address which identifies the semiconductor chip and a plurality of the terminal levels corresponding to the plurality of terminals based on the detection signal, an output circuit configured to read a plurality of pieces of latch data from the memory based on the detection signal and to output the plurality of pieces of latch data, and a timing control circuit configured to generate the detection signal by detecting an edge of a clock inputted during an inspection mode and configured to activate the selector, the memory, and the output circuit.

A first scan operation of a set of memory pages of a data block is performed using a first reliability threshold level to identify a set of scan results. A workload type associated with the data block is determined based on the set of scan results. The first reliability threshold level is adjusted to a second reliability threshold level based on the workload type. A second scan operation of the set of memory pages of the data block is performed using the second reliability threshold level.

Testability of memory on integrated circuits is improved by connecting storage elements like latches in memory to scan chains and configuring memory for scan dump. The use of latches and similar compact storage elements to form scannable memory can extend the testability of high-density memory circuits on complex integrated circuits operable at high clock speeds. A scannable memory architecture includes an input buffer with active low buffer latches, and an array of active high storage latches, operated in coordination to enable incorporation of the memory into scan chains for ATPG/TT and scan dump testing modes.

Testability of memory on integrated circuits is improved by connecting storage elements like latches in memory to scan chains and configuring memory for scan dump. The use of latches and similar compact storage elements to form scannable memory can extend the testability of high-density memory circuits on complex integrated circuits operable at high clock speeds. A scannable memory architecture includes an input buffer with active low buffer latches, and an array of active high storage latches, operated in coordination to enable incorporation of the memory into scan chains for ATPG/TT and scan dump testing modes.

An integrated circuit includes a latch array including a plurality of latches logically configured in rows and columns, a plurality of repair latches operatively coupled to the plurality of latches and latch array built in self-test and repair logic (LABISTRL) coupled to the plurality of latches. In some implementations the LABISTRL configures latches in the array as one or more column serial test shift register, detects one or more defective latches of the plurality of latches based on applied test data, and selects at least one repair latch in response to detection of at least one defective latch.

The present application provides a circuit and an associated chip. The circuit is coupled to a memory. The circuit includes: a first scan flip-flop (FF), being a previous-stage scan FF of an input terminal of the memory and having an output terminal coupled to an input terminal of the memory; and a second scan FF, being a next-stage scan FF of an output terminal of the memory and having an input terminal coupled to an output terminal of the memory; wherein a scan mode of the circuit has a load phase and a capture phase, during the capture phase, data output from the output terminal of the first scan FF loops back to a data input terminal of the first scan FF via a first loop, and the first loop is free from passing through the second scan FF.