An apparatus is described. The apparatus includes a memory chip. The memory chip has an error correction code (ECC) encoder logic circuit and an ECC decoder logic circuit. The ECC decoder logic circuit is to place an additional one or more errors that result from incorrect error correction applied to a read code word into a same block of multiple blocks of the read code word's raw data bit portion where original errors in the read code word existed before the read code word was decoded by the ECC decoder logic circuit.

A semiconductor memory device includes a memory cell array, an on-die error correction code (ECC) engine, and a control logic circuit. The on-die ECC engine, based on an ECC, in a write operation, performs an ECC encoding on main data to generate first parity data, selectively replaces a portion of the first parity data with a poison flag to generate second parity data based on a poison mode signal, provides the main data to a normal cell region in a target page of the memory cell array, and provides the first parity data to a parity cell region in the target page or provides the poison flag and the second parity data to the parity cell region. The control logic circuit controls the on-die ECC engine and generates the poison mode signal, based on a command and an address from a memory controller.

Methods, systems, and devices for managing error control information using a register are described. A memory device may store, at a register, an indication of whether the memory device has detected an error included in or otherwise associated with data requested from a host device. The memory device may determine to store the indication based on whether a communication protocol is enabled or disabled, and whether an error control configuration is enabled or disabled. The host device may request information from the register of the memory device, and the memory device may output the indication of whether the error was detected in response to the request.

A memory system includes a memory module that includes a first memory device through a fourth memory device and a first error correction code (ECC) device, and a memory controller that exchanges first user data with each of the first memory device through the fourth memory device through 8 data lines and exchanges first ECC data with the first ECC device through 4 data lines. The memory controller includes an ECC engine that corrects a 32-random bit error of the first user data, based on the first ECC data.

A memory system includes a memory module that includes a first memory device through a fourth memory device and a first error correction code (ECC) device, and a memory controller that exchanges first user data with each of the first memory device through the fourth memory device through 8 data lines and exchanges first ECC data with the first ECC device through 4 data lines. The memory controller includes an ECC engine that corrects a 32-random bit error of the first user data, based on the first ECC data.

Data transmission mitigating interwire crosstalk including: dividing a data block to be transmitted from a transmitter to a receiver across a set of signal wires into sub-blocks; encoding each of the sub-blocks into a plurality of codewords; selecting, for each sub-block by a cost function, one of the codewords that is less likely to introduce interwire crosstalk; transmitting the selected codewords; and updating the cost function at the transmitter with feedback from the receiver.

A method for detecting an address error when reading a bitstream from a memory is proposed, wherein a check is carried out as to whether the bitstream in conjunction with the present read address is a code word of an error code and wherein, should the bitstream in conjunction with the present read address not be a code word of the error code, an address error is subsequently detected provided the error code does not correct an error correctable thereby. Accordingly, an apparatus, a system and a computer program product are specified.

Described in detail herein is a method for encrypting or encoding time-stamped location data associated with a computing device. The method converts time and location information associated with the computing device into a vector format. The method generates a code vector based on the converted time and location vector. The method sorts entries in the code vector based at least in part on a predetermined ordering scheme. The method executes a random modification to each of the sorted entries. The method compares the code vector to at least one other code vector associated with another computing device. The method identifies other code vectors within a specified distance of the given code vector. The method concludes that the computing device and the at least one other computing device were in proximity to each other during a time period corresponding to the time information.

Described in detail herein is a method for encrypting or encoding time-stamped location data associated with a computing device. The method converts time and location information associated with the computing device into a vector format. The method generates a code vector based on the converted time and location vector. The method sorts entries in the code vector based at least in part on a predetermined ordering scheme. The method executes a random modification to each of the sorted entries. The method compares the code vector to at least one other code vector associated with another computing device. The method identifies other code vectors within a specified distance of the given code vector. The method concludes that the computing device and the at least one other computing device were in proximity to each other during a time period corresponding to the time information.

Apparatuses, systems, and methods for multi-bit error detection. A memory device may store data bits and parity bits in a memory array. An error correction code (ECC) circuit may generate syndrome bits based on the data and parity bits and use the syndrome bits to correct up to a single bit error in the data and parity bits. A multi-bit error (MBE) detection circuit may detect an MBE in the data and parity based on at least one of the syndrome bits or the parity bits. For example, the MBE detection circuit may determine if the syndrome bits have a mapped or unmapped state and/or may compare the parity bits, data bits, and an additional parity bit to determine if there is an MBE. When an MBE is detected an MBE signal is activated. In some embodiments, an MBE flag may be set based on the MBE signal being active.