A memory-testing circuit configured to perform a test of reference bits in a memory. In a read operation, outputs of data bit columns are compared with one or more reference bit columns. The memory-testing circuit comprises: a test controller and association adjustment circuitry configurable by the test controller to associate another one or more reference bit columns or one or more data bit columns with the data bit columns in the read operation. The test controller can determine whether the original one or more reference bit columns have a defect based on results from the two different association.

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.

Memory devices are disclosed. A memory device may include a number of column planes, and at least one circuit. The at least one circuit may be configured to receive test result data for a column address for each column plane of the number of column planes of the memory array. The at least one circuit may also be configured to convert the test result data to a first result responsive to only one bit of a number of bits of the number of column planes failing a test for the column address. Further, the at least one circuit may be configured to convert the test result data to a second result responsive to only one column plane failing the test for the column address and more than one bit of the one column plane being defective. Methods of testing a memory device, and electronic systems are also disclosed.

A memory device includes a memory bank that includes a first set of memory rows in a first section of the memory bank, a first set of redundant rows in a first section of the memory bank, a second set of memory rows in a second section of the memory bank, and a second set of redundant rows in the second section of the memory bank. The memory bank also includes a repeater blocker circuit that when in operation selectively blocks a signal from transmission to the second section of the memory bank and blocker control circuitry that when in operation transmits a control signal to control the selective blocking of the signal by the repeater blocker circuit.

Methods, systems, and apparatuses for redundancy in a memory array are described. A memory array may include some memory cells that are redundant to other memory cells of the array. Such redundant memory cells may be used if a another memory cell is discovered to be defective in some way; for example, after the array is fabricated and before deployment, defects in portions of the array that affect certain memory cells may be identified. Memory cells may be designated as redundant cells for numerous other memory cells of the array so that a total number of redundant cells in the array is relatively small fraction of the total number of cells of the array. A configuration of switching components may allow redundant cells to be operated in a manner that supports redundancy for numerous other cells and may limit or disturbances to neighboring cells when accessing redundancy cells.

A memory system includes a main memory array, a redundant memory array, and a content addressable memory (CAM). The CAM includes a plurality of entries, wherein each entry includes a plurality of column address bits and a plurality of maskable row address bits. When an access address for a memory operation matches an entry of the CAM, the memory system is configured to access the redundant memory array to perform the memory operation.

A memory controller including: a fault determination circuit to receive first parity, second parity, and data read out from a first row of a memory device, and determine, based on a result of a first error detection operation using the first parity and a result of a second error detection operation using the second parity, whether the first row is faulty; a parity storage circuit to store a repair parity for repairing a fault of a row of a plurality of rows of the memory device, wherein the plurality of rows constitutes a repair unit, and wherein the repair unit includes the first row and one or more second rows; and a recovery circuit to repair a fault of the first row by using data of at least one of the second rows and the repair parity, when the first row is determined to be a faulty row.

A memory device includes a memory cell array including a plurality of memory cells connected to a plurality of wordlines and a plurality of bitlines, a wordline driving circuit including a plurality of sub-wordline decoders respectively connected to the plurality of wordlines, wherein each of the sub-wordline decoders is configured to input a first driving signal to the respectively connected wordline when the wordline is selected, and wherein each sub-wordline decoder is configured to input a predetermined power supply voltage to the respectively connected wordline when the wordline is unselected, The memory device may include a sense amplifier circuit including sense amplifiers connected to the bitlines, and a logic circuit configured to determine a failure of at least one of the memory cell array and the wordline driving circuit.

In certain aspects, a memory device includes an array of memory cells, an input/output (I/O) circuit, and control logic coupled to the I/O circuit. The array of memory cells includes a plurality of banks including a plurality of main banks and a redundant bank. The I/O circuit is coupled to each pair of adjacent banks of the plurality of banks and configured to direct a piece of data to or from either bank of each pair of adjacent banks. The control circuit is configured to select one bank of each pair of adjacent banks based on bank fail information indicative of a failed main bank of the plurality of main banks. The control circuit is further configured to control the I/O circuit to direct the piece of data to or from the selected bank of each pair of adjacent banks.

In certain aspects, a memory device includes an array of memory cells, an input/output (I/O) circuit, and I/O control logic coupled to the I/O circuit. The array of memory cells includes P groups of banks. P redundant banks are included in and shared by the P groups of banks. The I/O circuit is coupled to the P groups of banks and configured to direct P×N pieces of data to or from P×N working banks, respectively. The I/O control logic is configured to determine the P×N working banks from the P groups of banks based on bank fail information indicative of K failed main banks from the P groups of banks. The P×N working banks include K redundant banks of the P redundant banks. The I/O control logic is also configured to control the I/O circuit to direct P×N pieces of data to or from the P×N working banks, respectively.