A memory includes: a memory array; a nonvolatile memory circuit suitable for storing a plurality of data sets each including flag information and multi-bit data; a plurality of repair register sets suitable for receiving and storing the multi-bit data included in the data sets whose flag information is marked for repair among the data sets during a boot-up operation; a plurality of setting register sets suitable for storing setting information included in the data sets whose flag information is marked for setting among the data sets during the boot-up operation; and a repair circuit suitable for repairing a defect in the memory array based on the multi-bit data stored in the repair register sets.

A method for operating a memory includes determining to perform an error correction operation; determining whether to perform an error correction operation; generating an internal address when the error correction operation is performed; reading data from memory cells that are selected based on the internal address and an error correction code corresponding to the data; performing an error correction operation on the data based on the error correction code to produce an error-corrected data; writing the error-corrected data and an error correction code corresponding to the error-corrected data into the memory cells; determining one or more regions among regions in the memory as a repair-requiring region based on an error detected when the error correction operation is performed; receiving a first command; backing up the data and the error correction code into a redundant region in response to the first command; and repairing the repair-requiring region with the redundant region.

A memory apparatus includes an address decoding circuit configured to output a test redundancy address based on an address that is transmitted from a memory controller; and a redundancy address check circuit configured to determine whether the test redundancy address is replacing a failed address, in order to perform an ECC test operation by using the test redundancy address.

The present disclosure provides an operation method related to a post package repair (PPR) function in a dynamic random access memory (DRAM) device. The method for operating a post package repair (PPR) function of a memory device is disclosed. The method includes providing a memory bank, which includes a memory array and a sense amplifier adjacent to the memory array, wherein the memory array comprises at least one defective row and at least one associated row, and the at least one associated row is electrically connected to the sense amplifier by a plurality of bit lines. The method also includes arranging a redundant row adjacent to the memory array, wherein the redundant row is electrically connected to the sense amplifier by the plurality of bit lines. The method also includes activating the at least one associated row to transmit data in the at least one associated row to the sense amplifier, latching the data in the sense amplifier; activating the redundant row, and transmitting the data from the sense amplifier to the redundant row.

A memory device includes a memory cell array including normal memory cells and redundant memory cells; first page buffers connected to the normal memory cells through first bit lines including a first bit line group and a second bit line group and arranged in a first area corresponding to the first bit lines in a line in a first direction; and second page buffers connected to the redundant memory cells through second bit lines including a third bit line group and a fourth bit line group and arranged in a second area corresponding to the second bit lines in a line in the first direction, wherein, when at least one normal memory cell connected to the first bit line group is determined as a defective cell, normal memory cells connected to the first bit line group are replaced with redundant memory cells connected to the third bit line group.

A memory device with built-in flexible redundancy is provided according to various aspects of the present disclosure. In certain aspects, a memory device includes a first sense amplifier, a second sense amplifier, a first comparator, a second comparator, a reference circuit, and a logic gate. During a redundant read operation, the first sense amplifier, the first comparator, and the reference circuit are used to read one copy of a redundant bit stored in the memory device, and the second sense amplifier, the second comparator, and the reference circuit are used to read another copy of the redundant bit stored in the memory device. The logic gate may then determine a bit value based on the bit values of the read copies of the redundant bit (e.g., determine a bit value of one if the bit value of at least one of the read copies of the redundant bit is one).

A method for accessing a memory includes the following. Location information of fail bits of multiple banks is acquired, backup circuits are distributed to the target banks from the multiple banks according to the location information of the fail bits by using a repair algorithm, a predicted repair result of the target bank is acquired, the availability of the target bank is detected according to the predicted repair result of the target bank, information indicating whether bits of target partial address bits of the target banks are predicted to be valid or invalid is acquired, and then predicted partial address bits are determined from the multiple address bits according to the information of the target partial address bits of the target banks to access a memory in a partial access mode according to the predicted partial address bits.

According to one embodiment, a memory device includes: a memory cell array including a first and a second array; a fuse circuit to hold first data; and a control circuit to control a replacement process on the first and second arrays based on the first data. When a first address in a first direction in the first array is supplied, the fuse circuit transfers the first data corresponding to the first address to the control circuit, and when a second address in a second direction in the first array is supplied after the first data is transferred, the control circuit accesses one of the first and second arrays based on a comparison result for the second address and the first data.

A memory repair system in an integrated circuit (IC) that optimizes the fuseROM used for memory repair. The IC includes a plurality of memory wrappers. Each memory wrapper includes a memory block with a fuse register and a bypass register. The bypass register have a bypass data that indicates a defective memory wrapper of the plurality of memory wrappers. A fuseROM controller is coupled to the plurality of memory wrappers. A memory bypass chain links the bypass registers in the plurality of memory wrappers with the fuseROM controller. The fuseROM controller loads the bypass data in the memory bypass chain. A memory data chain links the fuse registers in the plurality of memory wrappers with the fuseROM controller. The memory data chain is re-configured to link the fuse registers in a set of defective memory wrappers of the plurality of memory wrappers responsive to the bypass data loaded in the memory bypass chain.

According to one embodiment, a memory system includes: a first memory cell area where a first memory cell is provided; a second memory cell area where a second memory cell is provided; an ECC circuit which corrects an error of data stored by the first memory cell; and a control circuit which replaces the first memory cell with the second memory cell if the number of times an error is successfully corrected in the first memory cell reaches a first value.