A fault handling apparatus and a fault handling method which perform a built-in self-test (BIST) and a repair on a static random-access memory (SRAM) cell, and the fault handling apparatus and the fault handling method store the fault and repair history information of a previous SRAM test, provide the information to a current test, and reflect both BIST results and the information on the previous test, thereby performing multiple repairs until there is no available spare SRAM.

A memory device includes a memory cell array including normal memory cells and redundant memory cells; first page buffers connected to the normal memory cells through first bit lines including a first bit line group and a second bit line group and arranged in a first area corresponding to the first bit lines in a line in a first direction; and second page buffers connected to the redundant memory cells through second bit lines including a third bit line group and a fourth bit line group and arranged in a second area corresponding to the second bit lines in a line in the first direction, wherein, when at least one normal memory cell connected to the first bit line group is determined as a defective cell, normal memory cells connected to the first bit line group are replaced with redundant memory cells connected to the third bit line group.

An improved chip interface circuit and chip are disclosed. The circuit includes: a voltage divider circuit, including a first resistor, a second resistor and a switch; an input gate circuit, including a MOS transistor P1 and a MOS transistor N1; one end of the first resistor is connected to the input terminal, and the drains of P1 and N1 are connected to the first terminal, wherein the first terminal is used to connect the main circuit of the chip, and the switch is turned on when the input terminal receives a high-voltage input voltage. The circuit uses low-voltage transistors combined with a voltage divider circuit to realize the chip interface circuit, thereby achieving good interface speed characteristics, and avoiding the problem that the chip cannot work normally when the operating voltage is low due to the high threshold voltage of the high-voltage transistor.

Systems of screening memory cells of a memory include modulating bitline and/or wordline voltage. In a read operation, the wordline may be overdriven or underdriven with respect to a nominal operating voltage on the wordline. In a write operation, one or both of the bitline and wordline may be overdriven or underdriven with respect to corresponding a nominal operating voltage. Such a system has margin control circuity, which may be in the form of bitline and wordline margin controls, to modulate bitline and wordline voltages, respectively, in the memory cells of the memory array.

Methods, systems, and devices related to counter-based sense amplifier method for memory cells are described. The counter-based read algorithm may comprise the following phases: storing in a counter associated to an array of memory cells the value of the number of bits having a predetermined logic value of the data bits stored in the memory array; reading from said counter the value corresponding to the number of bits having the predetermined logic value; reading the data stored in the array of memory cells by applying a ramp of biasing voltages; counting the number of bits having the predetermined logic value during the data reading phase; stopping the data reading phase when the number of bits having the predetermined logic value is equal to the value stored in said counter.

A memory controller generates error codes associates with write data and a write address and provides the error codes over a dedicated error detection code link to a memory device during a write operation. The memory device performs error detection, and in some cases correction, on the received write data and write address based on the error codes. If no uncorrectable errors are detected, the memory device furthermore stores the error codes in association with the write data. On a read operation, the memory device outputs the error codes over the error detection code link to the memory controller together with the read data. The memory controller performs error detection, and in some cases correction, on the received read data based on the error codes.

Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a multiple-name-space testing system comprises a load board, testing electronics, and a namespace testing tracker. The load board is configured to couple with a plurality of devices under test (DUTs). The testing electronics are configured to test the plurality of DUTs, wherein the testing electronics are coupled to the load board. The controller is configured to direct testing of multiple-name-spaces across the plurality of DUTs at least in part in parallel. The controller can be coupled to the testing electronics. The namespace testing tracker is configured to track testing of the plurality of DUTs, including the testing of the multiple-name-spaces across the plurality of DUTs at least in part in parallel. In one embodiment, the DUTs are NVMe SSD devices.

An on-die logic analyzer (ODLA) can reduce the time and resources that would otherwise be spent in validating or debugging memory system timings. The ODLA can receive an enable signal with respect to a start command and start a count of clock cycles in response to a first issued command matching the start command defined in a first mode register. The ODLA can stop the count of clock cycles in response to a second issued command matching a stop command defined in a second mode register. The ODLA can write a value indicative of the stopped count to a third mode register or an on-die storage array in response to the stopped count exceeding a previously stored count.

Semiconductor devices, packaging architectures and associated methods are disclosed. In one embodiment, a semiconductor device is disclosed. The semiconductor device includes a first semiconductor die having a first bonding surface that is formed with a first set of contacts patterned with a first connection pitch. A second semiconductor die has a second bonding surface that is formed with a second set of contacts patterned with a second connection pitch. The second set of contacts are further patterned with a paired offset. The second semiconductor die is bonded to the first semiconductor die such that the first set of contacts is disposed in opposed electrical engagement with at least a portion of the second set of contacts.

A memory device includes a data pad; a read circuit outputting read or test data to the data pad according to a read timing signal and a read command; a write circuit receiving write data through the data pad according to a write timing signal; a test register circuit performing a preset operation on data and storing the data, and transferring the stored data as the test data in response to the read command, during a first test mode; a data compression circuit generating a test output signal by compressing the test data and outputting the test output signal to a first test output pad, during the first test mode; and a timing control circuit generating, according to first to third output control signals, the read timing signal and generating the write timing signal by delaying the read timing signal, during the first test mode.