Read operations can be performed to read data stored at a data block. Parameters reflective of a separation between a pair of programming distributions associated with the data block can be determined based on the plurality of read operations. A read request to read the data stored at the data block can be received. In response to receiving the read request, a read operation can be performed to read the data stored at the data block based on the parameters that are reflective of the separation between the pair of programming distributions associated with the data block.

An example memory sub-system includes a memory device and a processing device, operatively coupled to the memory device. The processing device is configured to identify a set of embedded servo cells stored on the memory device; determine a read voltage offset by performing read level calibration based on the set of embedded servo cells; and apply the read voltage offset for reading a memory page associated with the set of embedded servo cells.

A memory device and a method of correcting error in a memory device is provided. The memory device controller includes a memory array, a tie-breaker array, a write controller, a verify circuit, and a controller. The memory array includes a plurality of memory cells. The tie-breaker array includes a plurality of tie-breaker rows. The write controller is configured to apply a programming voltage to the memory array. The verify circuit is configured to apply a verify voltage to verify whether the memory cells in the memory array are in an unambiguous state or not. The controller is configured to enable one or more tie-breaker rows in additions to the memory array to adjust an output of the memory array when the memory cells in the memory array are in an ambiguous state.

A block family associated with a memory device is created. The block family is associated with a threshold voltage offset bin. A set of read level voltage offsets is determined such that, applying the set of read level voltage offsets to a base read level threshold voltage associated with the block family, result in a suboptimal error rate not exceeding a maximum allowable error rate. The determined set of read level offsets is associated with the threshold voltage offset bin by updating a block family metadata.

A method for finding an optimum read voltage includes acquiring difference values between state bit counts of different positions. A direction for finding the optimum read voltage is determined based on the difference values. An offset for finding the optimum read voltage is determined based on correspondence between a difference value of bit count and offset. Reading is performed with the offset applied to a current read reference voltage, wherein upon read-success, the current reference voltage superimposed with the offset is the optimum read voltage, and upon read-error, new first and second positions are obtained based on the direction and the offset for finding the optimum read voltage until reading becomes successful.

Disclosed is a system that comprises a memory device and a processing device, operatively coupled with the memory device, to perform operations that include, identifying a block family comprising a plurality of blocks of the memory device. The operations performed by the processing device further include associating the block family with a threshold voltage offset. The operations performed by the processing device further include computing an adjustment value of the threshold voltage offset, wherein the adjustment value reflects a time period that has elapsed since a triggering event and a temperature of a memory component carrying one or more blocks of the plurality of blocks.

A memory device includes a memory array and control logic, operatively coupled with the memory array, to perform operations including causing a first current to be obtained with respect to cells of a wordline maintained at a first voltage, determining that the cells are at a second voltage lower than the first voltage, in response to determining that the cells are the second voltage, causing a voltage ramp down process to be initiated, causing a second current to be sampled with respect to the cells during the voltage ramp down process, and detecting an existence of charge loss by determining whether the second current satisfies a threshold condition in view of the first current.

A receiver includes the following: a signal receiving circuit, including a first MOS transistor and a second MOS transistor, where a gate of the first MOS transistor is configured to receive a reference signal and a gate of the second MOS transistor is configured to receive a data signal, and the signal receiving circuit is configured to output a comparison signal, the comparison signal being configured to represent a magnitude relationship between a voltage value of the reference signal and a voltage value of the data signal; and an adjusting circuit, including a third MOS transistor, where a source of the third MOS transistor is connected to a source of the first MOS transistor, a drain of the third MOS transistor is connected to a drain of the first MOS transistor, and a gate of the third MOS transistor is configured to receive an adjusting signal.

A storage circuit includes: the array of a memory cell MC including a variable-resistance element; a conversion circuit that converts the resistance value of each memory cell into the signal level of an electric signal; a reference signal generation circuit that generates a reference signal common to a plurality of columns; a correction circuit that corrects one of the signal level of the reference signal and the signal level of the electric signal for each column of the array of the memory cell; and an RW circuit that determines data stored in the memory cell belonging to a corresponding column by comparing one of the reference level and the signal level of the electric signal, corrected by the correction circuit, and the other of the reference level and the signal level of the electric signal.

Methods, systems, and media for decoding data are described. A sequence of read-level voltages for decoding operations may be determined based on a trend of decoding success indicators, including a first decoding success indicator and a second decoding success indicator. The first decoding success indicator is obtained from a more recent successful decoding operation. The first one of the sequence may be set to a read-level voltage of the first decoding success indicator. If the read-level voltage of the first decoding success indicator is less than a read-level voltage of the second decoding success indicator, then the trend is decreasing, and the second one of the sequence may be set to a read-level voltage less than that of the first one of the sequence. After executing one or more decoding operations, the decoding success indicators may be updated based on the read-level voltage of the current successful decoding operation.