Methods, systems, and devices for a dynamic interval for entering a low power state are described. A memory system or device may support a low power mode, which the memory system or device may enter in response to a command from a host system. In some cases, an amount of idle time observed by the host system before issuing such a command may vary based on a status of maintenance operations for the memory system or device. Additionally or alternatively, after receiving such a command, the memory system or device may complete one or more pending maintenance operations before entering the low power mode.

Memory bank remapping based on sensed temperatures of a memory device can provide an overall reduced power consumption of the memory device. Signaling indicative of sensed temperatures detected by a plurality of temperature sensors within a stack of memory dies of a memory device can be received by address circuitry of the memory device. Based on the sensed temperatures and respective positions of the temperature sensors within the stack of memory dies, a portion of the memory device experiencing an excessive operating temperature can be identified. Logical addresses of a first memory bank of a memory die of the stack of memory dies near or at least partially within the identified portion can be remapped to physical addresses of a second memory bank of the memory die that is further away from the identified portion than the first memory bank.

An apparatus includes a memory and one or more processors. The memory includes multiple memory blocks. The one or more processors are configured to read at least part of data stored in a group of one or more memory blocks, the data including multiple code words of an Error Correction Code (ECC) that is decodable using one or more processing elements selected from among multiple predefined processing elements. The one or more processor are further configured to decode one or more of the code words, and identify one or more of the predefined processing elements that actually participated in decoding the respective code words, and, based on cost-values associated with the identified processing elements, the cost-values are indicative of processing latencies respectively incurred by the identified processing elements, to make a decision of whether or not to refresh the one or more memory blocks in the group.

Performing refresh operation in a memory device is provided. A refresh operation without address rotation is performed in a cell array of the memory device. Performing the refresh operation without address rotation is repeated for a predetermined number of times. After repeating performing the refresh operation with address rotation for the predetermined number of times, a refresh operation with address rotation is performed in the cell array.

A semiconductor device includes a logic circuit, a memory, and a storage device. The storage device has a first special information storage region into which special information is written before a solder reflow process, a second special information storage region into which special information for updating is written after the solder reflow process, and a data storage region. The first special information storage region is constituted by a memory cell having a high reflow resistance and in which data is retained even after the solder reflow process. The second special information storage region and the data storage region are constituted by memory cells having a low reflow resistance and in which data may not be retained during the solder reflow process.

A first impurity layer 101a and a second impurity layer 101b are formed on a substrate Sub at both ends of a Si pillar 100 standing in a vertical direction and having a circular or rectangular horizontal cross-section. Then, a first gate insulating layer 103a and a second gate insulating layer 103b surrounding the Si pillar 100, a first gate conductor layer 104a surrounding the first gate insulating layer 103a, and a second gate conductor layer 104b surrounding the second gate insulating layer 103b are formed. Then, a voltage is applied to the first impurity layer 101a, the second impurity layer 101b, the first gate conductor layer 104a, and the second gate conductor layer 104b to generate an impact ionization phenomenon in a channel region 102 by current flowing between the first impurity layer 101a and the second impurity layer 101b. Of generated electrons and positive holes, the electrons are discharged from the channel region 102 to perform a memory write operation for holding some of the positive holes in the channel region 102, and the positive holes held in the channel region 102 are discharged from one or both of the first impurity layer 101a and the second impurity layer 101b to perform a memory erase operation.

Systems, apparatuses and methods may provide for technology that determines a write-to-write delay with respect to a memory cell, wherein one or more neighboring cells are adjacent to the memory cell and controls a write disturb refresh rate of the one or more neighboring cells based on the write-to-write delay. In one example, the technology increments a write counter corresponding to the memory cell by a first value if the write-to-write delay exceeds a delay threshold and increments the write counter by a second value if the write-to-write delay does not exceed the delay threshold, wherein the second value is greater than the first value, and wherein the write disturb refresh rate is controlled based on the write counter.

In-vehicle detection system includes nonvolatile memory, a controller (SoC) that reads and writes data from and in nonvolatile memory, and detector that outputs detection information to SoC. SoC changes a control signal of nonvolatile memory in accordance with the output of detector.

A temperature sensing circuit of a data storage system includes a temperature sensor, a digital-to-analog circuit, and a reference generation and trimming circuit configured to generate a common mode voltage (VCM), a positive reference voltage (VREFP), and a negative reference voltage (VREFN) using a single band gap reference signal. The trimming circuit is configured to trim the VCM, VREFP, and VREFN by adjusting a VC trim signal to increase the VCM until a VCM error is below a threshold; adjusting a high temperature trim signal to increase the VREFP and decrease the VREFN until a digital temperature signal associated with the digital-to-analog circuit attains a predetermined accuracy level for a first temperature; and adjusting a low temperature trim signal to increase the VREFP, VCM, and VREFN until the digital temperature signal attains a predetermined accuracy level for a second temperature.

A memory device includes pages arranged in columns and each constituted by a plurality of memory cells on a substrate, voltages applied to a first gate conductor layer, a second gate conductor layer, a first impurity layer, and a second impurity layer in each memory cell included in each of the pages are controlled to perform a page write operation of retaining, inside a channel semiconductor layer, a group of positive holes generated by an impact ionization phenomenon or by a gate-induced drain leakage current, and the voltages applied to the first gate conductor layer, the second gate conductor layer, the first impurity layer, and the second impurity layer are controlled to perform a page erase operation of discharging the group of positive holes from inside the channel semiconductor layer. The first impurity layer of the memory cell is connected to a source line, the second impurity layer thereof is connected to a bit line, one of the first gate conductor layer or the second gate conductor layer thereof is connected to a word line, and the other of the first gate conductor layer or the second gate conductor layer thereof is connected to a first driving control line. In a page read operation, page data in a group of memory cells selected by the word line is read to sense amplifier circuits, and in at least one operation among the page write operation, the page erase operation, and the page read operation, a voltage applied to at least one of the source line, the bit line, the word line, or the first driving control line is controlled by a reference voltage generating circuit combined with a temperature-compensating circuit.