A nonvolatile memory device may include a page buffer including a plurality of latch sets that latch each page datum of selected memory cells among a plurality of memory cells according to each of read signal sets including at least one read signal, and a control logic configured to detect a degradation level of the memory cells and determine a read parameter applied to at least one of the read signal sets based on the detected degradation level.

Methods, systems, and devices for mimicking neuro-biological architectures that may be present in a nervous system are described herein. A memory device may include a memory unit configured to store a value. A memory unit may include a first memory cell (e.g., an aggressor memory cell) and a plurality of other memory cells (e.g., victim memory cells). The memory unit may use thermal disturbances of the victim memory cells that may be based on an access operation to store the analog value. Thermal energy output by the aggressor memory cell during an access operation (e.g., a write operation) may cause the state of the victim memory cells to alter based on thermal relationship between the aggressor memory cell and at least some of the victim memory cells. The memory unit may be read by detecting and combining the weights of the victim memory cells during a read operation.

Techniques are provided for programming a multi-level self-selecting memory cell that includes a chalcogenide material. To program one or more intermediate memory states to the self-selecting memory cell, a programming pulse sequence that includes two pulses may be used. A first pulse of the programming pulse sequence may have a first polarity and a first magnitude and the second pulse of the programming pulse sequence may have a second polarity different than the first polarity and a second magnitude different than the first magnitude. After applying both pulses in the programming pulse sequence, the self-selecting memory cell may store an intermediate state that represents two bits of data (e.g., a logic 01 or a logic 10).

A magnetic wall utilization-analog memory element includes a magnetic wall driving layer including a magnetic wall, a first region, a second region, and a third region located between the first region and the second region, a magnetization fixed layer provided at a the third region through a nonmagnetic layer, and a lower electrode layer provided at a position in the third region that overlaps the magnetization fixed layer in plan view on a second surface opposite to a first surface on which the magnetization fixed layer is provided.

A magnetic wall utilization-analog memory element includes a magnetic wall driving layer including a magnetic wall, a first region, a second region, and a third region located between the first region and the second region, a magnetization fixed layer provided at a the third region through a nonmagnetic layer, and a lower electrode layer provided at a position in the third region that overlaps the magnetization fixed layer in plan view on a second surface opposite to a first surface on which the magnetization fixed layer is provided.

The present disclosure describes analog memories for use in a computer, such as a computer using a combination of analog and digital components/elements used in a cohesive manner.

An analog content addressable memory cell includes a high side and a low side. The high side encodes a high bound on a range of values and includes a first voltage divider formed of a first programmable resistor and a first electronically controlled variable resistor. The low side encodes a low bound on the range of values and includes a second voltage divider formed of a second programmable resistor and a second electronically controlled variable resistor.

A magnetic domain wall type analog memory element includes: a magnetization fixed layer in which magnetization is oriented in a first direction; a non-magnetic layer provided in one surface of the magnetization fixed layer; a magnetic domain wall drive layer including a first area in which magnetization is oriented in the first direction, a second area in which magnetization is oriented in a second direction opposite to the first direction, and a magnetic domain wall formed as an interface between the areas and provided to sandwich the non-magnetic layer with respect to the magnetization fixed layer; and a current controller configured to cause a current to flow between the magnetization fixed layer and the second area at the time of reading.

A magnetic domain wall type analog memory element includes: a magnetization fixed layer in which magnetization is oriented in a first direction; a non-magnetic layer provided in one surface of the magnetization fixed layer; a magnetic domain wall drive layer including a first area in which magnetization is oriented in the first direction, a second area in which magnetization is oriented in a second direction opposite to the first direction, and a magnetic domain wall formed as an interface between the areas and provided to sandwich the non-magnetic layer with respect to the magnetization fixed layer; and a current controller configured to cause a current to flow between the magnetization fixed layer and the second area at the time of reading.

Techniques are provided for programming a multi-level self-selecting memory cell that includes a chalcogenide material. To program one or more intermediate memory states to the self-selecting memory cell, a programming pulse sequence that includes two pulses may be used. A first pulse of the programming pulse sequence may have a first polarity and a first magnitude and the second pulse of the programming pulse sequence may have a second polarity different than the first polarity and a second magnitude different than the first magnitude. After applying both pulses in the programming pulse sequence, the self-selecting memory cell may store an intermediate state that represents two bits of data (e.g., a logic 01 or a logic 10).