Provided are standby circuit dispatch method, apparatus, device and medium. The method includes: a first test item is executed and first test data is acquired, the first test data including position data of a failure bit acquired during execution of the first test item; a first redundant circuit dispatch result is determined according to the first test data; a second test item is executed and second test data is acquired; when the failure bit acquired during execution of the second test item includes a failure bit outside the repair range of the dispatched regional redundant circuits and dispatched global redundant circuits, and the dispatchable redundant circuits have been dispatched out, a maximum target bit umber is acquired according to the first test data and the second test data; and a target dispatch mode is selected and a second redundant circuit dispatch result is determined according to the target dispatch mode.

A redundant circuit assigning method a includes: first test item is executed and first test data is acquired; a first redundant circuit assigning result including the number of assigned local redundant circuits and position data of the assigned local redundant circuits is determined according to the first test data; a second test item is executed and second test data is acquired; when fail bits acquired during execution of the second test item include one or more fail bits beyond the repair range of the assigned local redundant circuits and assigned global redundant circuits, and the assignable redundant circuits have been assigned out, target position data of fail bits in a target subdomain and a related subdomain is acquired based on the first test data and the second test data; and a second redundant circuit assigning result is determined according to the first test data and the second test data.

A memory system includes a memory device including a memory cell array including a plurality of memory cell groups, and a controller for selectively activating or inactivating one of the memory cell groups.

A memory device includes at least one memory bank comprising a set of redundant word lines, a set of normal word lines, and row hammer refresh logic. The RHR logic comprises a first input to receive a first signal indicative of whether a match was generated at a fuse of the memory device, a second input to receive a redundant row address corresponding to a first location of a memory array of the memory device, a third input to receive a word line address corresponding to a second location of the memory array of the memory device. The RHR logic also comprises an output to transmit at least one first memory address adjacent to the first location or at least one second memory address adjacent to the second location based on a value of the first signal.

A local region to be repaired including the fail bit is determined. A preliminary repair LR circuit for repairing the local region to be repaired is determined (S210). A region level of the local region to be repaired is determined (S230) according to the number of available GR circuits other than any replacement GR circuit configured for replacing the preliminary repair LR circuit and the number of available LR circuits. It is controlled, according to the region level of the local region to be repaired, to repair the fail bit by the GR circuit or the LR circuit (S240).

Fuse logic is configured to selectively enable certain group of fuses of a fuse array to support one of column (or row) redundancy in one application or error correction code (ECC) operations in another application. For example, the fuse logic may decode the group of fuses to enable a replacement column (or row) of memory cells in one mode or application, and decodes a subset of the group of fuses to retrieve ECC data corresponding to a second group of fuses are encoded to enable a different replacement column or row of memory cells in a second mode or application. The fuse logic includes an ECC decode logic circuit that is selectively enabled to detect and correct errors in data encoded in the second group of fuses based on the ECC data encoded in the subset of fuses of the first group of fuses.

A semiconductor memory device includes a memory and a memory controller configured to control the memory. The memory controller includes a normal operation control part and a repair part. The normal operation control part is configured to control a normal operation of the memory and includes a plurality of storage spaces used while the normal operation is controlled. The repair part is configured to control a repair operation of the memory and stores faulty addresses detected while the repair operation is controlled into the plurality of storage spaces included in the normal operation control part.

Runtime memory cell row defect detection and replacement includes detecting in a memory of a computer system operating in a runtime operating system mode, a defective row of memory cells having at least one defective cell. In response to the detection of the defective row, interrupting the operating system of the computer system and, in a runtime system maintenance mode, replacing the defective row of memory cells with a spare row of memory cells as a replacement row of memory cells. Execution of the operating system is then resumed in the runtime operating system mode Other aspects and advantages are described.

A method includes specifying a target memory macro with one or more parameters, finding function-blocks in the target memory macro, and determining failure rates of the function-blocks based on an amount of transistors and area distributions in a collection of base cells. The method includes generating a failure-mode analysis for the target memory macro, from a memory compiler, based on the failure rates of the function-blocks. The method includes determining a safety level of the target memory macro, based upon the failure-mode analysis of the target memory macro.

Methods, systems, and devices for speculative memory section selection are described. Defective memory components in one memory section may be repaired using repair components in another memory section. Speculative selection of memory sections may be enabled, whereby access lines in multiple memory sections may be selected when a memory command indicating an address in one memory section is received. While the access lines in the multiple memory sections are selected, a determination of whether repair components in another memory section are to be accessed is performed. Based on the determination, the access line in one of the memory sections may be maintained and the access lines in the other memory sections may be deselected.