In some examples, a defective memory cell detection circuitry is configured to provide a failure signal indicative of a failure of a sub-group of memory cells (e.g., a row of memory cells). The failure signal is generated responsive to the failure of a sense line to transition to one of a set of reference voltages within a threshold time from a memory command. In some examples, failure signals indicative of a failure of a sub-group of memory cells is used by vehicle computer control systems to operate a vehicle.

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.

Apparatuses and methods related to authenticating memory. Memory devices can be authenticated utilizing authentication codes. An authentication code can be generated based on information stored in a fuse array of the memory device. The authentication code can be compared to an externally provided authentication code to authenticate the memory device. The memory device may be authenticated to ensure that the memory device is not a security threat.

Various implementations described herein relate to systems and methods for performing error correction in a flash memory device by determining suggested corrections by decoding a codeword. In addition, whether a first set of the suggested corrections obtained based on a first component code of the plurality of component codes agree with a second set of the suggested corrections obtained based on a second component code of the plurality of component codes is determined. One of accepting the first set of the suggested corrections or rejecting the first set of the suggested corrections is selected based on whether the first set of the suggested corrections and the second set of the suggested corrections agree.

Provided are a semiconductor memory device and a memory system including the same. The semiconductor memory device includes a power-up signal generator configured to generate a power-up signal in response to a memory voltage reaching a target voltage level, an initializer configured to generate an initialization signal in response to the power-up signal and a reset signal and to generate an initial refresh command in response to completion of an initialization operation, and a memory cell array including a plurality of memory cells connected between a plurality of word lines and a plurality of bit lines, the memory cell array configured to perform an initial refresh operation on the plurality of memory cells in response to the initial refresh command.

A memory cell arrangement for Random Access Memory (RAM) including one or more RAM cell groups. The RAM cell groups having two or more local bit-lines sharing a Global Bit-Line (GBL), a pre-charging circuit connected to the GBL, a multiplexer connected to multiple GBLs and configured to shift an output of a first GBL from a first bit to a second bit at least in part according to a value of a fuse bit register associated with a second GBL, and at least one pre-charge enabling circuit controlled by a combination of a pre-charge input value applied to all GBLs of the memory cell arrangement and a pre-charge enable signal for the GBL.

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.

The purposes of the present invention are: to provide a layered semiconductor device capable of improving production yield; and to provide a method for producing said layered semiconductor device. This layered semiconductor device has, layered therein, a plurality of semiconductor chips, a reserve semiconductor chip which is used as a reserve for the semiconductor chips, and a control chip for controlling the operating states of the plurality of semiconductor chips and the operating state of the reserve semiconductor chip. In such a configuration, the semiconductor chips and the reserve semiconductor chip include contactless communication units and operating switches. The semiconductor chips and the reserve semiconductor chip are capable of contactlessly communicating with another of the semiconductor chips via the contactless communication units. The control chip controls the operating states of the semiconductor chips by switching the operating switches of the semiconductor chips, and controls the operating state of the reserve semiconductor chip by switching the operating switch of the reserve semiconductor chip.

Various implementations described herein refer to a device having an encoder coupled to memory. The ECC encoder receives input data from memory built-in self-test circuitry, generates encoded data by encoding the input data and by adding check bits to the input data, and writes the encoded data to memory. The device may have an ECC decoder coupled to memory. The ECC decoder reads the encoded data from memory, generates corrected data by decoding the encoded data and by extracting the check bits from the encoded data, and provides the corrected data and double-bit error flag as output. The ECC decoder has error correction logic that performs error correction on the decoded data based on the check bits, wherein if the error correction logic detects a multi-bit error in the decoded data, the error correction logic corrects the multi-bit error in the decoded data to provide the corrected data.

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.