Abstract: A memory device with single transistor drivers and methods to operate the memory device are described. In some embodiments, the memory device may comprise memory cells at cross points of access lines of a memory array, a first even single transistor driver configured to drive a first even access line to a discharging voltage during an IDLE phase, to drive the first even access line to a floating voltage during an ACTIVE phase, and to drive the first even access line to a read/program voltage during a PULSE phase, and a first odd single transistor driver configured to drive a first odd access line, the first odd access line physically adjacent to the first even access line, to the discharging voltage during the IDLE phase, to drive the first odd access line to the floating voltage during the ACTIVE phase, and to drive the first odd access line to a shielding voltage during the PULSE phase.

Abstract: The present disclosure includes apparatuses, methods, and systems for charge separation for memory sensing. An embodiment includes applying a sensing voltage to a memory cell, and determining a data state of the memory cell based, at least in part, on a comparison of an amount of charge discharged by the memory cell while the sensing voltage is being applied to the memory cell before a particular reference time and an amount of charge discharged by the memory cell while the sensing voltage is being applied to the memory cell after the particular reference time.

Abstract: Methods, systems, and devices for a read algorithm for a memory device are described. When performing a read operation, the memory device may access a memory cell to retrieve a value stored by the memory cell. The memory device may compare a set of reference voltages with a signal output by the memory cell based on accessing the memory cell. Thus, the memory device may determine a set of candidate values stored by the memory cell, where each candidate value is associated with one of the reference voltages. The memory device may determine and output the value stored by the memory cell based on determining the set of candidate values. In some cases, the memory device may determine the value stored by the memory cell based on performing an error control operation on each of the set of candidate values to detect a quantity of errors within each candidate value.

Abstract: Methods, systems, and devices for method for setting a reference voltage for read operations are described. A memory device may perform a first read operation on a set of memory cells using a first reference voltage and detect a first codeword based on performing the first read operation using the first reference voltage. The memory device may compare a first quantity of bits of the first codeword having a first logic value (e.g., a logic value ‘1’) with an expected quantity of bits having the first logic value (e.g., the expected quantity of logic value ‘1’s stored by the set of memory cells). The memory device may determine whether to perform a second read operation on the set of memory cells using a second reference voltage different than the first reference voltage (e.g., greater or less than the first reference voltage) based on the comparing.

Abstract: The present invention relates to a method of operating memory cells, comprising reading a previous user data from the memory cells; writing a new user data and merging the new user data with the previous user data into write registers; generating mask register information, and wherein the mask register information indicates bits of the previous user data stored in the memory cells to be switched or not to be switched in their logic values; counting numbers of a first logic value and a second logic value to be written using the mask register information, respectively; storing the numbers of the first logic value and the second logic value into a first counter and a second counter, respectively; and applying a programming pulse to the memory cells according to the mask register information.

Abstract: The present disclosure relates to a method for accessing memory cells comprising: applying an increasing read voltage with a first polarity to the plurality of memory cells; counting a number of switching memory cells in the plurality based on the applying the increasing read voltage; applying a first read voltage with the first polarity based on the number of switched memory cells reaching a threshold number; applying a second read voltage with a second polarity opposite to the first polarity; and determining that a memory cell in the plurality of memory cells has a first logic value based on the memory cell having switched during one of the applying the increasing read voltage and the applying the first read voltage or based on the memory cell not having switched during the applying the second read voltage. A related system is also disclosed.

Abstract: A memory device with single transistor drivers and methods to operate the memory device are described. In some embodiments, the memory device may comprise memory cells at cross points of access lines of a memory array, a first even single transistor driver configured to drive a first even access line to a discharging voltage during an IDLE phase, to drive the first even access line to a floating voltage during an ACTIVE phase, and to drive the first even access line to a read/program voltage during a PULSE phase, and a first odd single transistor driver configured to drive a first odd access line, the first odd access line physically adjacent to the first even access line, to the discharging voltage during the IDLE phase, to drive the first odd access line to the floating voltage during the ACTIVE phase, and to drive the first odd access line to a shielding voltage during the PULSE phase.

Abstract: The present disclosure relates to a method for accessing an array of memory cells, including storing a set of user data in a plurality of memory cells, storing, in a portion of the array, additional information representative of a voltage difference between a first threshold voltage and a second threshold voltage of the memory cells programmed to a first logic state, applying to the array a read voltage to activate a first group of memory cells corresponding to a preset number of memory cells, determining that the first group of memory cells has been activated based on applying the read voltage, wherein the read voltage is equal to the first threshold voltage when the first group of memory cells has been activated, and based on the additional data information, applying the voltage difference to the array to activate a second group of memory cells programmed to the first logic state.

Abstract: The present disclosure provides a method, a circuit, and a system for reading memory cells. The method may include: applying a first voltage with a first polarity to a plurality of the memory cells; applying a second voltage with a second polarity to one or more of said plurality of the memory cells; applying at least a third voltage with the first polarity to one or more of said plurality of the memory cells; detecting electrical responses of memory cells to the first voltage, the second voltage, and the third voltage; and determining a logic state of respective memory cells based on the electrical responses of the memory cells to the first voltage, the second voltage, and the third voltage.

Abstract: The present invention relates to a method of operating memory cells, comprising reading a previous user data from the memory cells; writing a new user data and merging the new user data with the previous user data into write registers; generating mask register information, and wherein the mask register information indicates bits of the previous user data stored in the memory cells to be switched or not to be switched in their logic values; counting numbers of a first logic value and a second logic value to be written using the mask register information, respectively; storing the numbers of the first logic value and the second logic value into a first counter and a second counter, respectively; and applying a programming pulse to the memory cells according to the mask register information.

Abstract: Methods and apparatuses with counter-based reading are described. A memory cells of a codeword are accessed and respective voltages are generated. A reference voltage is generated and a logic state of each memory cell is determined based on the reference voltage and the respective generated cell voltage. The reference voltage is modified until a count of memory cells determined to be in a predefined logic state with respect to the last modified reference voltage value meets a criterium. In some embodiments the criterium may be an exact match between the memory cells count and an expected number of memory cells in the predefined logic state. In other embodiments, an error correction (ECC) algorithm may be applied while the difference between the count of cells in the predefined logic state and the expected number of cells in that state does not exceed a detection or correction power of the ECC.

Abstract: Methods and devices for techniques for precharging a memory cell are described. Precharging a memory cell while the memory cell is coupled with its digit line may reduce a total duration of an access operation thereby reducing a latency associated with accessing a memory device. During a read operation, the memory device may select a word line to couple the memory cell with a selected digit line. Further, the memory device may selectively couple the selected digit line with a reference digit line that is to be precharged to a given voltage. A difference in voltage between the selected digit line and the reference digit line at the completion of precharging may represent a signal indicative of a logic state of the memory cell. The memory device may use a capacitor precharged to a first voltage to capture the signal.

Abstract: Methods, systems, and devices that support techniques for programming self-selecting memory are described. Received data may include a first group of bits that each have a first logic value and a second group of bits that each have a second logic value. The first and second group of bits may be stored in a first set of memory cells and a second set of memory cells, respectively. A first programming operation for writing the second logic value to both the first and second set of memory cells and verifying whether the second logic value is written to each of the first set of memory cells, the second set of memory cells, or both may be performed. A second programming operation may write the first logic value to either the first set of memory cells or the second set of memory cells based on a result of the verification.

Abstract: Methods, systems, and devices for time-based access of memory cells in a memory array are described herein. During a sense portion of a read operation, a selected memory cell may be charged to a predetermined voltage level. A logic state stored on the selected memory cell may be identified based on a duration between the beginning of the charging and when selected memory cell reaches the predetermined voltage level. In some examples, time-varying signals may be used to indicate the logic state based on the duration of the charging. The duration of the charging may be based on a polarization state of the selected memory cell, a dielectric charge state of the selected state, or both a polarization state and a dielectric charge state of the selected memory cell.

Abstract: Methods, systems, and devices for operational modes for reduced power consumption in a memory system are described. A memory device may be coupled with a capacitor of a power management integrated circuit (PMIC). The memory device may operate in a first mode where a supply voltage is provided to the memory device from the PMIC. The memory device may operate in a second mode where it is isolated from the PMIC. When isolated, a node of the memory device (e.g., an internal node) may be discharged while the capacitor of the PMIC remains charged. When the memory device resumes operating in the first mode, a supply voltage may be provided to it based on the residual charge of the capacitor.

Abstract: Apparatuses and methods for memory that includes a first memory cell including a storage component having a first end coupled to a plate line and a second end coupled to a digit line, and a second memory cell including a storage component having a first end coupled to a digit line and a second end coupled to a plate line, wherein the digit line of the second memory cell is adjacent to the plate line of the first memory cell.

Abstract: A counter can have a number of sensing components. Each respective sensing component can be configured to sense a respective event and can include a respective first capacitor configured to be selectively coupled to a second capacitor in response to the respective sensing component sensing the respective event. The second capacitor can be configured to be charged to a voltage by each respective first capacitor that is selectively coupled to the second capacitor. The counter can have a comparator with a first input coupled to the second capacitor and a second input coupled to a reference voltage corresponding to a threshold quantity of events. The comparator can be configured to output a signal indicative of the threshold quantity of events being sensed in response to the voltage of the second capacitor being greater than or equal to the reference voltage.

Abstract: The present disclosure relates to a method for reading memory cells, and may include applying a first read voltage to a plurality of memory cells, detecting first threshold voltages exhibited by the plurality of memory cells in response to application of the first read voltage, associating a first logic state to one or more cells of the plurality of memory cells, applying a second read voltage to the plurality of memory cells, where the second read voltage has the same polarity of the first read voltage and a higher magnitude than an expected highest threshold voltage of memory cells in the first logic state, and detecting second threshold voltages exhibited by the plurality of memory cells in response to application of the second read voltage, among other aspects. A related circuit, a related memory device and a related system are also disclosed.

Abstract: Methods, circuits, and systems for reading memory cells are described. The method may include: applying a first voltage with a first polarity to a plurality of the memory cells; applying a second voltage with a second polarity to one or more of said plurality of the memory cells; applying at least a third voltage with the first polarity to one or more of said plurality of the memory cells; detecting electrical responses of memory cells to the first voltage, the second voltage, and the third voltage; and determining a logic state of respective memory cells based on the electrical responses of the memory cells to the first voltage, the second voltage, and the third voltage.

Abstract: Methods, systems, devices, and techniques for read operations are described. In some examples, a memory device may include a first transistor (e.g., memory node transistor) configured to receive a precharge voltage at a first gate and output first voltage based on a threshold of the first transistor to a reference node via a first switch. The device may include a second transistor (e.g., a reference node transistor) configured to receive a precharge voltage and output a second voltage based on a threshold of the second transistor to a memory node via a second switch. The first voltage may be modified by a reference voltage and input to the second transistor. The second voltage may be modified by a voltage stored on a memory cell and input to the first transistor. The first and second transistor may output third and fourth voltages to be sampled to a latch.