Abstract: A method includes performing a copyback operation comprising transferring, using an internal processing device, user data and header data corresponding to the user data from a first block of memory in a memory device to a register in the memory device, decoupling the user data from the header data, performing an error correction code (ECC) operation on updated header data using an external processing device, transferring, via the external processing device, the updated header data to the register, and transferring the user data and the updated header data from the register to a second block of memory in the memory device.

Abstract: A system includes a processing device and a memory device coupled to the processing device. The memory device can include a cyclic buffer portion and a snapshot portion. The processing device can store time based telemetric sensor data in the cyclic buffer portion, copy an amount of the telemetric sensor data from the cyclic buffer portion to the snapshot portion in response to a trigger event, operate the cyclic buffer portion with a first trim tailored to a performance target of the cyclic buffer portion, and operate the snapshot portion with a second trim tailored to a performance target of the snapshot portion.

Abstract: A system includes a memory device having a plurality of groups of memory cells and a processing device communicatively coupled to the memory device. The processing device is be configured to read a first group of memory cells of the plurality to determine a calibrated read voltage associated with the group of memory cells. The processing device is further configured to determine, using the calibrated read voltage associated with the first group of memory cells, a bit error rate (BER) of a second group of memory cells of the plurality. Prior to causing the memory device to perform a copyback operation on the plurality of groups of memory cells, the processing device is further configured to determine whether to perform a subsequent read voltage calibration on at least the second group of the plurality based, at least partially, on a comparison between the determined BER and a threshold BER.

Abstract: A system includes a processing device and a memory device coupled to the processing device. The memory device is further coupled to the processing device and to a primary power supply and a secondary power supply. The processing device is to determine, based at least in part on availability of the primary power supply to the memory device, whether to operate the memory device with a first trim tailored to data reliability or a second trim tailored to programming time. The processing device is further to operate the memory device with the determined one of the first trim or the second trim.

Abstract: A method includes writing received data sequentially to a particular location of a cyclic buffer of a memory device according to a first set of threshold voltage distributions. The method further includes performing a touch up operation on the particular location by adjusting the first set of threshold voltage distributions of the data to a second set of threshold voltage distributions in response to a determination that a trigger event has occurred. The second set of threshold voltage distributions can have a larger read window between adjacent threshold voltage distributions of the second set than that of the first set of threshold voltage distributions.

Abstract: A system includes a processing device and trigger circuitry to signal the processing device responsive, at least in part, based on a determination that a trigger event has occurred. The system can further include a memory device communicatively coupled to the processing device. The memory device can include a cyclic buffer partition portion having a first endurance characteristic and a first reliability characteristic associated therewith. The memory device can further include a snapshot partition portion coupled to the cyclic buffer partition portion via hold-up capacitors. The snapshot partition portion can have a second endurance characteristic and a second reliability characteristic associated therewith. The processing device can perform operations including writing received data sequentially to the cyclic buffer partition portion and writing, based at least in part on the determination that the trigger event has occurred, data from the cyclic buffer partition portion to the snapshot partition portion.

Abstract: Instructions can be executed to determine a quantity of logical units that are part of a memory device. The instructions can be executed to operate the logical units with a programming time sufficient to provide a required throughput for storage of time based telemetric sensor data received from a host. The instructions can be executed to operate the logical units with a trim that correspond to the programming time.

Abstract: A memory component comprises a cyclic buffer partition portion and a snapshot partition portion. In response to receiving a signal that a trigger event has occurred, a processing device included in the memory component performs an error correction operation on a portion of data stored in the cyclic buffer partition portion, copies the data stored in the cyclic buffer partition portion to the snapshot partition portion in response to the error correction operation being successful, and sends the data stored in the cyclic buffer partition portion to a processing device operatively coupled to the memory component in response to the error correction operation not being successful.

Abstract: A method includes during a first portion of a service life of a memory device, programming at least one memory cell of the memory device to a first threshold voltage corresponding to a desired data state. The method can include during a second portion of the service life of the memory device subsequent to the first portion of the service life of the memory device, programming at least one memory cell of the memory device to a second threshold voltage corresponding to the desired data state. The second threshold voltage can be different than the first threshold voltage.

Abstract: A system includes a processing device and a memory device communicatively coupled to the processing device. The memory device can include a cyclic buffer partition portion and a snapshot partition portion coupled to the cyclic buffer partition portion via hold-up capacitors. The snapshot partition portion can further include a first sub-partition portion having a first programming characteristic and a second sub-partition portion having a second programming characteristic. The processing device can write received data sequentially to the cycle buffer partition portion and write, based at least in part on a determination that a trigger event has occurred, data from the cyclic buffer partition portion to the first sub-partition portion or the second sub-partition portion, or both.

Abstract: The present disclosure includes apparatuses and methods for acceleration of data queries in memory. A number of embodiments include an array of memory cells, and processing circuitry configured to receive, from a host, a query for particular data stored in the array of memory cells, wherein the particular data corresponds to a search key generated by the host, search portions of the array of memory cells for the particular data corresponding to the search key, determine data stored in the portions of the array of memory cells that matches the search key, and transfer the data that matches the search key to the host.

Abstract: The present disclosure includes apparatuses and methods for acceleration of data queries in memory. An example apparatus includes an array of memory cells and processing circuitry. The processing circuitry is configured to receive, from a host, a query for particular data in the array of memory cells, wherein the particular data corresponds to a search key generated by the host, search portions of the array of memory cells for the particular data corresponding to the search key generated by the host, search portions of the array of memory cells for the particular data corresponding to the search key, determine data stored in the portions of the array of memory cells that corresponds more closely to the search key than other data stored in the portions of the array of memory cells, and transfer the data that corresponds more closely to the search key than the other data to the host.

Abstract: The present disclosure includes apparatuses, methods, and systems for acceleration of data queries in memory. An example host apparatus includes a controller configured to generate a search key, generate a query for particular data stored in an array of memory cells in a memory device, and send the query to the memory device. The query includes a command to search for the particular data. The query also includes a number of data fields for the particular data including a logical block address (LBA) for the particular data, an LBA offset for the particular data, and a parameter for an amount of bits in data stored in the memory device that do not match corresponding bits in the search key that would result in data not being sent to the host.

Abstract: Methods of operating a memory include boosting a channel voltage of a memory cell selected for programming to a particular voltage level for a particular programming pulse, boosting the channel voltage of the memory cell selected for programming to a second voltage level, greater than the particular voltage level, for a subsequent programming pulse, and boosting the channel voltage of the memory cell selected for programming to a third voltage level, greater than the second voltage level, for a next subsequent programming pulse.

Abstract: Systems and methods are disclosed including a memory component and a processing device, coupled to the memory component. The processing device can program a block of the memory component using a first type of memory cells storing a first number of bits per memory cell. The processing device can then determine that an amount of memory used of the memory component is greater than a capacity threshold. Responsive to determining that a frequency of access to the block meets a criterion, the processing device can then program the block using a second type memory cells storing a second number of bits per memory cell, wherein the second number of bits exceeds the first number of bits.

Abstract: An example memory sub-system comprises: a memory device; and a processing device, operatively coupled with the memory device. The processing device is configured to: receive a first host data item; store the first host data item in a first page of a first logical unit of a memory device, wherein the first page is associated with a fault tolerant stripe; receive a second host data item; store the second host data item in a second page of the first logical unit of the memory device, wherein the second page is associated with the fault tolerant stripe, and wherein the second page is separated from the first page by one or more wordlines including a dummy wordline storing no host data; and store, in a third page of a second logical unit of the memory device, redundancy metadata associated with the fault tolerant stripe.

Abstract: Memory devices might be configured to perform methods including reading a first page of memory cells and flag data wherein the flag data indicates whether a second page of memory cells adjacent to the first page is programmed, and determining from the flag data whether to re-read the first page of memory cells with an adjusted read voltage; performing a sense operation on memory cells coupled to first data lines of a first array of memory cells and memory cells coupled to data lines of a second array of memory cells, and determining a program indication of memory cells coupled to second data lines from the sense operation performed on the memory cells coupled to the data lines of the second array of memory cells; and/or programming memory cells coupled to first data lines in a first array of memory cells, and programming memory cells coupled to second data lines in the first array of memory cells while programming memory cells coupled to data lines in a second array of memory cells with flag data indicative o

Abstract: An example method for determining likelihood of erroneous data bits stored in memory cells may include sensing a first plurality of memory cells based on a first sense thresholds. Responsive to sensing the first plurality of cells, a first set of probabilistic information may be associated with the first plurality of memory cells. A second plurality of memory cells may be sensed based on a second sense threshold. Responsive to sensing the second plurality of memory cells, a second set of probabilistic information may be associated with the second plurality of memory cells. An error correction operation may be performed on the first and second pluralities of memory cells based, at least in part, on the first and second values.

Abstract: Systems, devices, and methods related to reset read are described. A reset read may be employed to initiate a transition of a portion of memory array into a first state or maintain a portion of memory array in a first state, such as a transient state. A reset read may provide a highly-parallelized, energy-efficient option to ensure memory blocks are in the first state. Various modes of reset read may be configured according to different input.

Abstract: Systems, devices, and methods related to reset read are described. A reset read may be employed to initiate a transition of a portion of memory array into a first state or maintain a portion of memory array in a first state, such as a transient state. A reset read may provide a highly-parallelized, energy-efficient option to ensure memory blocks are in the first state. Various modes of reset read may be configured according to different input.