A serial arbitration for memory diagnostics and methods thereof are provided. The method includes running a built-in-self-test (BIST) on a plurality of memories in parallel. The method further includes, upon detecting a failing memory of the plurality of memories, triggering arbitration logic to shift data of the failing memory to a chip pad.

A serial arbitration for memory diagnostics and methods thereof are provided. The method includes running a built-in-self-test (BIST) on a plurality of memories in parallel. The method further includes, upon detecting a failing memory of the plurality of memories, triggering arbitration logic to shift data of the failing memory to a chip pad.

A memory test system may include: a data storage device including a nonvolatile memory device, and a controller configured to control an operation of the nonvolatile memory device; and a test device configured to: request a test to the data storage device; request, to the data storage device, an output of a variable to be generated through driving of a firmware for performing the test, while the test is performed in the data storage device; and determine whether the firmware is normally driven based on the variable outputted from the data storage device.

A memory test apparatus according to the present embodiment comprises a first storage medium temporarily retaining a test result of memory cells of a device under test in a plurality of divided portions based on data output from the device under test. A first processor reads the divided test result from the first storage medium to compress the test result. A second storage medium is provided to respectively correspond to a plurality of the devices under test and receives the compressed test result from the first processor and saves the compressed test result.

A device has a digital-to-analog converter to convert waveform data into analog waveforms, a waveform memory to store stored waveform data, an external waveform interface to receive real-time waveform data from an external device, a waveform multiplexer connected to the digital-to-analog converter to select between the first memory and the external waveform interface, a sequencer to receive and execute instructions to identify and access waveform data to drive the digital-to-analog converter, a sequencer instruction memory to provide stored instructions to the sequencer, an external instruction interface to receive real-time instructions for the sequencer, and a sequencer multiplexer to select between the sequencer instruction memory and the external instruction interface connected to the sequencer. A method of controlling a waveform generator includes selecting a mode of operation, where the mode of operation is selected from streaming waveform data, real-time waveform memory updates, real-time sequencer instructions, real-time sequencer instruction updates, and real-time sequencer flow control.

A method of operating a semiconductor memory device is provided. In a method of operating a semiconductor memory device including a memory cell array which includes a plurality of bank arrays, memory cells in a first region of the memory cell array are tested to detect one or more failed cells in the first region, a fail address corresponding to the detected one or more failed cells is determined and the determined fail address is stored in a second region different from the first region, in the memory cell array.

A method includes configuring an integrated circuit comprising one or more registers to provide a free running clock in the integrated circuit, simulating N clock cycles in the circuit to provide performance results for one or more registers in the circuit, wherein N is a selected number of staging levels, selecting one of the one or more registers, comparing the performance results for the selected register to performance results for each of the remaining registers to provide one or more equivalent delay candidate registers, and verifying each of the one or more equivalent delay candidate registers to provide one or more confirmed equivalent delay registers. A corresponding computer program product and computer system are also disclosed.

Provided are a method and an apparatus for repairing a memory cell in a memory test system. A test device detects a fail address by testing a memory device according to a test command, and temporarily stores the fail address in a fail address memory (FAM). The fail address is transmitted to the memory device according to a fail address transmission mode, is temporarily stored in a temporary fail address storage of the memory device, and is then stored in an anti-fuse array, which is a non-volatile storage device. To secure the reliability of data, stored data can be read to verify the data and a verification result can be transmitted in series or in parallel to the test device.

Provided are a method and an apparatus for repairing a memory cell in a memory test system. A test device detects a fail address by testing a memory device according to a test command, and temporarily stores the fail address in a fail address memory (FAM). The fail address is transmitted to the memory device according to a fail address transmission mode, is temporarily stored in a temporary fail address storage of the memory device, and is then stored in an anti-fuse array, which is a non-volatile storage device. To secure the reliability of data, stored data can be read to verify the data and a verification result can be transmitted in series or in parallel to the test device.

Provided are a method and an apparatus for repairing a memory cell in a memory test system. A test device detects a fail address by testing a memory device according to a test command, and temporarily stores the fail address in a fail address memory (FAM). The fail address is transmitted to the memory device according to a fail address transmission mode, is temporarily stored in a temporary fail address storage of the memory device, and is then stored in an anti-fuse array, which is a non-volatile storage device. To secure the reliability of data, stored data can be read to verify the data and a verification result can be transmitted in series or in parallel to the test device.