A memory device includes a first memory area including a first memory cell array having a plurality of first memory cells and a first peripheral circuit disposed below the first memory cell array; a second memory area including a second memory cell array having a plurality of second memory cells and a second peripheral circuit disposed below the second memory cell array; and a pad area including a power wiring. The first and second memory areas respectively include first and second local lockout circuits separately determining whether to lock out of each of the memory areas. The first and second memory areas are included in a single semiconductor chip to share the pad area, and the first and second memory areas operate individually. Accordingly, in the memory device, unnecessary data loss may be reduced by selectively stopping an operation of only a memory area requiring recovery.

The present disclosure includes apparatuses and methods related to performing background operations in memory. A memory device can be configured to perform background operations while another memory device in a memory system and/or on a common memory module is busy performing commands received from a host coupled to the memory system and/or common memory module. An example apparatus can include a first memory device, wherein the first memory device can include an array of memory cells and a controller configured to perform a background operation on the first memory device in response to detecting a command from a host to a second memory device.

The present disclosure includes apparatuses and methods related to performing background operations in memory. A memory device can be configured to perform background operations while another memory device in a memory system and/or on a common memory module is busy performing commands received from a host coupled to the memory system and/or common memory module. An example apparatus can include a first memory device, wherein the first memory device can include an array of memory cells and a controller configured to perform a background operation on the first memory device in response to detecting a command from a host to a second memory device.

The present disclosure includes apparatuses and methods related to performing background operations in memory. A memory device can be configured to perform background operations while another memory device in a memory system and/or on a common memory module is busy performing commands received from a host coupled to the memory system and/or common memory module. An example apparatus can include a first memory device, wherein the first memory device can include an array of memory cells and a controller configured to perform a background operation on the first memory device in response to detecting a command from a host to a second memory device.

A control circuit that controls a memory including a storage region and a redundant region, the control circuit includes a detector that detects a defective block in the memory, and a controller that switches, when the detector has detected the defective block, a data storage scheme of the first block detected as the defective block from a first storage scheme to a second storage scheme in which the number of bits of data to be stored in each of memory elements is smaller than the number of bits of data to be stored in each of the memory elements in the first storage scheme, and that stores a portion of data stored in the first block in the first storage scheme to be stored in the first block in the second storage scheme.

A storage device includes: a non-volatile memory configured to include a plurality of blocks having a plurality of word lines and to write data to the blocks or to erase data of the blocks; and a splitter configured to obtain write times for a plurality of word lines of a first block of the blocks while the non-volatile memory writes data in the first block, and to command the non-volatile memory to perform an erase operation on a second block of the blocks by the reference time when a write time for one of the word lines is shorter than the reference time.

A semiconductor memory device includes first and second memory cell arrays, and first and second control circuits configured to execute an operation on the first and second memory cell arrays. The first control circuit executes an operation on the first memory cell array responsive to a first command set that is received by the semiconductor memory device. The second control circuit executes an operation on the second memory cell array responsive to second and third command sets that are received by the semiconductor memory device while the first control circuit is executing the operation on the first memory cell array.

A control circuit that controls a memory including a storage region and a redundant region, the control circuit includes a detector that detects a defective block in the memory, and a controller that switches, when the detector has detected the defective block, a data storage scheme of the first block detected as the defective block from a first storage scheme to a second storage scheme in which the number of bits of data to be stored in each of memory elements is smaller than the number of bits of data to be stored in each of the memory elements in the first storage scheme, and that stores a portion of data stored in the first block in the first storage scheme to be stored in the first block in the second storage scheme.

A semiconductor memory device includes first and second memory cell arrays, and first and second control circuits configured to execute an operation on the first and second memory cell arrays. The first control circuit executes an operation on the first memory cell array responsive to a first command set that is received by the semiconductor memory device. The second control circuit executes an operation on the second memory cell array responsive to second and third command sets that are received by the semiconductor memory device while the first control circuit is executing the operation on the first memory cell array.

The present disclosure includes apparatuses and methods related to performing background operations in memory. A memory device can be configured to perform background operations while another memory device in a memory system and/or on a common memory module is busy performing commands received from a host coupled to the memory system and/or common memory module. An example apparatus can include a first memory device, wherein the first memory device can include an array of memory cells and a controller configured to perform a background operation on the first memory device in response to detecting a command from a host to a second memory device.