A memory device includes a memory array comprising a plurality of memory elements and a memory controller coupled to the memory array. The memory controller when in operation receives an indication of a defect in the memory array determines a first location of the defect when the defect is affecting only one memory element of the plurality of memory elements, determines a second location of the defect when the defect is affecting two or more memory elements of the plurality of memory elements, and performs a blown operation on a defective memory element at the second location when the defect is affecting two or more memory elements of the plurality of memory elements.

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.

A memory may include multiple rows each coupled to multiple memory cells; a target row classification circuit suitable for classifying, as a target row, a row, among the multiple rows, that is susceptible to data loss as a result of activity of an adjacent row; and a target row signal generation circuit suitable for sequentially activating a target row active signal for activating the target row and a target row precharge signal for precharging the target row in response to a precharge command.

A non-volatile memory device includes a memory cell array including a plurality of memory cells respectively connected to a plurality of word lines; a plurality of first pass transistors each connected to one side of one of the plurality of word lines; a plurality of second pass transistors each connected to the other side of one of the plurality of word lines; a voltage generator configured to generate a plurality of operating voltages and to apply the plurality of operating voltages to the memory cell array; in response to a first switch control signal, a first switch circuit configured to connect the plurality of first pass transistors to the voltage generator; and in response to a first switch control signal, a second switch circuit configured to connect the plurality of second pass transistors to the voltage generator.

Provided is a non-volatile memory device. The non-volatile memory device includes: a memory cell array including cell strings, each including memory cells respectively connected to word lines; a page buffer circuit including page buffers respectively connected to the memory cells through bit lines, wherein a first page buffer is connected to a first cell string through a first bit line; a control logic circuit configured to control a pre-sensing operation to disconnect the first bit line and the first cell string from each other during a pre-sensing period for detecting a defect of the first bit line and control a post-sensing operation to connect the first bit line and the first cell string to each other in a post-sensing period for detecting defects of the word lines and the first bit line; and a defect detection circuit configured to detect defects of the word lines based the sensing operations.

A memory device includes word lines vertically stacked from a substrate, memory cells electrically connected to the word lines, a group controller configured to group the word lines into word line groups, and change the word line groups, based on electrical characteristics of the memory cells, and a voltage generator configured to store, in a voltage table, voltage values of operating voltages to be respectively applied to the word line groups.

A memory system includes a memory device including a plurality of banks, each including row and column spares for replacing defective rows and columns; and a memory controller suitable for controlling an operation of the memory device, wherein the memory controller includes: a built-in self-test (BIST) circuit suitable for performing a test operation on the banks and generating fail addresses for each bank based on a result of the test operation; and a built-in redundancy analysis (BIRA) circuit suitable for determining first and second spare counts by respectively counting the number of repairable row spares and repairable column spares, and selecting a target repair address from the fail addresses for each bank, according to the first and second spare counts.

A semiconductor device that has a normal mode of operation and a test mode of operation and can include: a first circuit that generates at least one assist signal having an assist enable logic level in the normal mode of operation, the at least one assist signal alters a read operation or a write operation to a static random access memory (SRAM) cell of the semiconductor device as compared to read or write operations when the assist signal has an assist disable logic level; and the first circuit generates the at least one assist signal having the assist disable logic level in the test mode of operation

A non-volatile memory system includes a plurality of non-volatile data memory cells arranged into groups of data memory cells, a plurality of select devices connected to the groups of data memory cells, a selection line connected to the select devices, a plurality of data word lines connected to the data memory cells, and one or more control circuits connected to the selection line and the data word lines. The one or more control circuits are configured to determine whether the select devices are corrupted. If the select devices are corrupted, then the one or more control circuits repurpose one of the word lines (e.g., the first data word line closet to the select devices) to be another selection line, thus operating the memory cells connected to the repurposed word line as select devices.

In an SRAM circuit mounted in a semiconductor device, power supply voltage reduction circuits generate reduction voltage obtained by reducing an external power supply voltage. A first power supply voltage selection circuit selects one of the external power supply voltage and the reduction voltage as a drive voltage supplied to a word line driver. A second power supply voltage selection circuit selects one of the external power supply voltage and the reduction voltage as a voltage of a power supply line supplying an operating voltage to a memory cell.