A memory-testing circuit configured to perform a test of a memory comprising error-correcting code circuitry comprises repair circuitry configured to allocate a spare row or row block in the memory for a defective row or row block in the memory, a defective row or row block being a row or row block in which a memory word has a number of error bits greater than a preset number, wherein the test of the memory comprises: disabling the error-correcting code circuitry, performing a pre-repair operation, the pre-repair operation comprising: determining whether the memory has one or more defective rows or row blocks, and allocating one or more spare rows or row blocks for the one or more defective rows or row blocks if the one or more spare rows or row blocks are available, and performing a post-repair operation on the repaired memory.

An electronic device includes an error correction circuit configured to detect an error included in internal data, to generate a failure detection signal during a read operation, and to correct the error included in the internal data during a refresh operation, and a core circuit configured to store an address signal for activating a word line in which the internal data including the error is stored through as a failure address signal when the failure detection signal is input to the core circuit, and store the error-corrected internal data in the core circuit through a word line activated by the failure address signal during the refresh operation.

Methods, systems, and devices for monitoring and adjusting access operations at a memory device are described to support integrating monitors or sensors for detecting memory device health issues, such as those resulting from device access or wear. The monitoring may include traffic monitoring of access operations performed at various components of the memory device, or may include sensors that may measure parameters of components of the memory device to detect wear. The traffic monitoring or the parameters measured by the sensors may be represented by a metric related to access operations for the memory device. The memory device may use the metric (e.g., along with a threshold) to determine whether to adjust a parameter associated with performing access operations received by the memory device, in order to implement a corrective action.

A method of protecting a DRAM memory device from the row hammer effect, the memory device comprising a plurality of banks composed of memory rows, may be implemented by at least one logic prevention device configured to respectively associate contiguous sections of rows of a bank with sub-banks. The prevention logic is also configured to execute a preventive refresh cycle of the sub-banks that is entirely executed before the number of rows activated in a sub-bank exceed a critical hammer value. A DRAM memory device, a buffer circuit or a controller of such a memory may comprise the logic for preventing the row hammer effect.

Apparatuses, systems, and methods for fuse based device identification. A device may include a number of fuses which are used to encode permanent information on the device. The device may receive an identification request, and may generate an identification number based on the states of at least a portion of the fuses. For example, the device may include a hash generator, which may generate the identification number by using the fuse information as a seed for a hash algorithm.

A plurality of memory cells are arranged along a plurality of bit lines and a plurality of word lines. A sense amplifier is connected to each of the bit lines. Arranged along each bit line are at least four memory cells including first to fourth memory cells that are either connected to or disconnected from one of the bit lines by means of first to fourth switching elements according to an active or inactive state of first to fourth word lines. The first memory cell stores a first bit value, the second memory cell stores a second bit value, and the third and fourth memory cells each store a third bit value. A memory cell array control circuit activates and then deactivates the third and fourth word lines, subsequently activates the first and second word lines, and then activates the sense amplifier.

A memory device includes a data storage region and a spare column remap storage. The data storage region includes a plurality of sub-arrays, and each of the plurality of sub-arrays has a plurality of main columns and a plurality of spare columns. The spare column remap storage includes a plurality of storage units storing column address information of a repaired main column of one of the plurality of sub-arrays and address information of a repaired main column of another of the plurality of sub-arrays into at least one of the plurality of storage units included in the spare column remap storage.

Provided are a memory device and a memory controller, which are configured to repair a weak word line, and a method of operating a storage device including the memory device and the memory controller. A memory device includes a memory cell array including a plurality of normal word lines and at least one spare word line, and a repair controller configured to set memory cells connected to at least one weak word line to a first operation mode and further configured to set memory cells connected to the at least one spare word line to a second operation mode. The at least one weak word line is detected from among the normal word lines based on a test result.

A semiconductor device includes a stack structure comprising decks. Each deck of the stack structure comprises a memory element level comprising memory elements and control logic level in electrical communication with the memory element level, the control logic level comprising a first subdeck structure comprising a first number of transistors comprising a P-type channel region or an N-type channel region and a second subdeck structure comprising a second number of transistors comprising the other of the P-type channel region or the N-type channel region overlying the first subdeck structure. Related semiconductor devices and methods of forming the semiconductor devices are disclosed.

A method of protecting a DRAM memory device from the row hammer effect, the memory device comprising a plurality of banks composed of memory rows, may be implemented by at least one logic prevention device configured to respectively associate contiguous sections of rows of a bank with sub-banks. The prevention logic is also configured to execute a preventive refresh cycle of the sub-banks that is entirely executed before the number of rows activated in a sub-bank exceed a critical hammer value. A DRAM memory device, a buffer circuit or a controller of such a memory may comprise the logic for preventing the row hammer effect.