A semiconductor device, the device including: a first level overlaid by a first memory control level; a first memory level disposed on top of said first control level, where said first memory level includes a first thinned single crystal substrate; a second memory level, said second memory level disposed on top of said first memory level, where said second memory level includes a second thinned single crystal substrate, where said memory control level is bonded to said first memory level, and where said bonded includes oxide to oxide and conductor to conductor bonding.

A memory device includes an at least one first normal mat and an at least one second normal mat, a first redundancy mat configured to provide one or more first redundancy column lines for repairing one or more column lines disposed in the at least one first normal mat, a second redundancy mat configured to provide one or more second redundancy column lines for repairing one or more column lines disposed in the at least one second normal mat, and a redundancy segmented input/output (I/O) line coupled to both of the first redundancy mat and the second redundancy mat.

A memory device includes an at least one first normal mat and an at least one second normal mat, a first redundancy mat configured to provide one or more first redundancy column lines for repairing one or more column lines disposed in the at least one first normal mat, a second redundancy mat configured to provide one or more second redundancy column lines for repairing one or more column lines disposed in the at least one second normal mat, and a redundancy segmented input/output (I/O) line coupled to both of the first redundancy mat and the second redundancy mat.

A memory device includes a mode register set configured to store a first repair mode, a second repair mode, and a second repair off mode, and a repair control circuit configured to perform a first repair operation for permanently repairing a first wordline corresponding to a defective address to a first redundancy wordline in the first repair mode, to perform a second repair operation for temporarily repairing the first wordline corresponding to the defective address to a second redundancy wordline in the second repair mode, and to turn off a repair logic that is configured to perform the second repair operation in the second repair off mode to access old data after the second repair operation.

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.

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.

Storage device programming methods, systems and media are described. A method may include encoding data to generate an encoded set of data. A first programming operation may write the encoded set of data to a memory device. The method includes encoding, using a second encoding operation based on the data, to generate a second set of encoded data. The second set of encoded data is stored to a cache. A first decoding operation is performed, based on the second set of encoded data and the encoded set of data, to generate a decoded set of data. A second decoding operation is performed to generate a second decoded set of data. The second decoded set of data is encoded to generate a third set of encoded data. The method includes performing a second programming operation to write the third set of encoded data to the memory device.

A method includes replacing an address of a first normal memory cell in a first column of a first memory block with a destination address that is an address of a second normal memory cell in a second column of the first memory block, and reassigning the address of the second normal memory cell in the second column of the first memory block to an address of a first redundancy memory cell in a redundancy block of the memory device.

Storage device programming methods, systems and media are described. A method may include encoding data to generate an encoded set of data. A first programming operation may write the encoded set of data to a memory device. The method includes encoding, using a second encoding operation based on the data, to generate a second set of encoded data. The second set of encoded data is stored to a cache. A first decoding operation is performed, based on the second set of encoded data and the encoded set of data, to generate a decoded set of data. A second decoding operation is performed to generate a second decoded set of data. The second decoded set of data is encoded to generate a third set of encoded data. The method includes performing a second programming operation to write the third set of encoded data to the memory device.

A semiconductor memory device has a memory cell array area including a normal area including memory blocks and a redundant memory area including a redundant block which is a replacement target of a defective block among memory blocks; a storage unit storing address information indicating a position of the defective block in the normal area and address information indicating a position of the redundant block being the replacement target of the defective block, both being in association with each other as a first information; and an output circuit outputting a data row exhibiting a positional relation between the defective block and a memory block other than the defective block in the normal area based on the first information stored in the storage unit in response to the data read signal.