A method for performing a read of a flash memory includes storing configuration files for a plurality of RRD-compensating RNNs. A current number of PE cycles for a flash memory are identified and TVSO values are identified corresponding to the current number of PE cycles. A current retention time and a current number of read disturbs for the flash memory are identified. The configuration file of the RRD-compensating RNN corresponding to the current number of PE cycles, the current retention time and current number of read disturbs is selected and is loaded into a neural network engine to form an RNN core in the neural network engine. A neural network operation of the RNN core is performed to predict RRD-compensated TVSO values. The input to the neural network operation includes the identified TVSO values. A read of the flash memory is performed using the predicted RRD-compensated TVSO values.

Memory might include a controller configured to cause the memory to capacitively couple a first voltage level from a voltage node to a node of a sense circuit, selectively discharge the node of the sense circuit through a memory cell, measure a current demand of the voltage node while selectively discharging the node of the sense circuit through the memory cell, determine a second voltage level in response to the measured current demand, isolate the node of the sense circuit from the memory cell, capacitively couple the second voltage level from the voltage node to the node of the sense circuit, and determine a data state of the memory cell in response to a voltage level of the node of the sense circuit while capacitively coupling the second voltage level to the node of the sense circuit.

A memory device may receive a read request describing a logical address at the memory device. The memory device may obtain a table entry associated with the logical address. The table entry comprises a physical address corresponding to the logical address and a write temperature data indicating a write temperature for the logical address. The memory device may determine a corrected threshold voltage for reading the physical address based at least in part on the write temperature data and read the physical address using the corrected threshold voltage.

An apparatus includes an error correction component coupled to read recovery control circuitry. The error correction component can be configured to perform one or more initial error correction operations on codewords contained within a managed unit received thereto. The read recovery control circuitry can be configured to receive the error corrected codewords from the error correction component and determine whether codewords among the error corrected codewords contain an uncorrectable error. The read recovery control circuitry can be further configured to determine that a redundant array of independent disks (RAID) codeword included in the plurality of error corrected codewords contains the uncorrectable error, request that codewords among the error corrected codewords that contain the uncorrectable error are rewritten in response to the determination, and cause the plurality of error corrected codewords to be transferred to a host coupleable to the read recovery control circuitry.

Non-volatile memory systems are disclosed. The memory systems include rows of memory holes FC-SGD and SC-SGD, the latter of which may be created by a SHE cutting operation. The SC-SGD include erase speeds slower than those of FC-SGD. In order to overcome the erase speed disparities, SC-SGD are programmed to a higher Vt as compared to FC-SGD. By programming SC-SGD to a higher Vt, the erase speed increases and matches the erase speed of FC-SGD. Further, different SC-SGDs are cut to different amounts, creating different erase speeds among SC-SGD. SC-SGDs with a greater degree/amount of cut have slower erase speeds as compared to SC-SGDs with a lesser degree/amount of cut. However, verify levels among SC-SGDs can differ to produce SC-SGDs with Vt's such that their erase speeds match with each other as well as with FC-SGD.

Methods, systems, and devices for programming techniques for polarity-based memory cells are described. A method may include writing memory cells to an intermediate state based on receiving a write command. Writing the intermediate state may include applying a first pulse having a first polarity to the memory cell. The method may include isolating a first access line coupled with the memory cell from a voltage source based on applying the first pulse. The method may also include applying a second pulse to a second access line coupled with the memory cell based on isolating the first access line.

Apparatus having a string of series-connected memory cells, a plurality of access lines with each access line of the plurality of access lines connected to a control gate of a respective memory cell of the plurality of memory cells, and a controller for access of the string of series-connected memory cells and configured to cause the memory to increase a threshold voltage of a particular memory cell of the string of series-connect memory cells to a voltage level higher than a predetermined pass voltage to be received by a control gate of the particular memory cell during a read operation on the string of series-connected memory cells, and concurrently change a respective data state of each memory cell of a plurality of memory cells of the string of series-connected memory cells.

An average inter-pulse delay of a data unit of the memory device is calculated. An average temperature of the data unit is calculated. A first scaling factor based on the average inter-pulse delay and a second scaling factor based on the average temperature is obtained. A media management metric based on the first scaling factor and the second scaling factor is calculated. Responsive to determining that the media management metric satisfies a media management criterion, a media management operation on the data unit at a predetermined cycle count is performed.

A memory apparatus and method of operation are provided. The apparatus includes memory cells connected to one of a plurality of word lines and arranged in strings and configured to retain a threshold voltage corresponding to one of a plurality of memory states. A control circuit is coupled to the plurality of word lines and strings and is configured to erase the memory cells using a stripe erase operation in response to determining a cycle count is less than a predetermined cycle count maximum threshold. The control circuit is also configured to perform a dummy cycle operation in response to determining the cycle count is not less than the predetermined cycle count maximum threshold.

A method for dynamically adjusting an erase voltage level to be applied in a subsequent erase cycle, comprising: in a current erase cycle, initiating a current erase/verify loop by applying an initial stored erase voltage level according to an erase sequence in which each successive erase/verify loop is incremented by a pre-determined voltage amount, storing an erase/verify loop count, and determining whether the current erase cycle is complete according to a pass criterion. If the erase cycle is complete, a determination is made as to whether the stored erase/verify loop count equals a pre-defined threshold count. Further, if the stored count does not equal the pre-defined threshold count, the initial stored erase voltage level is adjusted such that, upon applying the adjusted erase voltage level in a subsequent erase cycle, an erase/verify loop count will now equal the pre-defined threshold count.