A memory device including memory cells operating according to a first clock signal having a first clock frequency and accessed based on a data access time. The memory device may include a clock shifter circuit for delaying the access commands based on the data access time. The clock shifter circuitry include a shift register circuit and a phase correction circuit. The shift register circuit delays the access commands using a second clock signal having a fraction of the first clock frequency. The phase correction circuit receives the access commands from the shift register circuitry using the fraction of the first clock frequency, delays the access commands based on phase information of the access commands, and outputs the access commands to the memory cells based on the data access time using the first clock frequency.

A semiconductor memory device includes: a first wiring; a first semiconductor layer connected to the first wiring, the first semiconductor layer; a first electrode, the first electrode being connected to the first semiconductor layer; a second electrode disposed between the first electrode and the first wiring, the second electrode being opposed to the first semiconductor layer; a third electrode disposed between the second electrode and the first wiring, the third electrode; a second semiconductor layer disposed between the third electrode and the first semiconductor layer, the second semiconductor layer being opposed to the third electrode; and an electric charge accumulating layer electrically connected to the first wiring via the second semiconductor layer, the electric charge accumulating layer being opposed to the first semiconductor layer.

An integrated circuit device outputs a sequence of differently delayed calibration data timing signals to a DRAM component via a data-signal timing line as part of a timing calibration operation and then stores a delay value, based on at least one of the calibration data timing signals, that compensates for a difference in signal propagation times over the data-signal timing line and a command/address-signal timing line. After the timing calibration operation, the integrated circuit device outputs write data to the DRAM component and outputs a write data timing signal, delayed according to the delay value, to via the data-signal timing line to time reception of the first write data within the DRAM.

An integrated circuit device outputs a sequence of differently delayed calibration data timing signals to a DRAM component via a data-signal timing line as part of a timing calibration operation and then stores a delay value, based on at least one of the calibration data timing signals, that compensates for a difference in signal propagation times over the data-signal timing line and a command/address-signal timing line. After the timing calibration operation, the integrated circuit device outputs write data to the DRAM component and outputs a write data timing signal, delayed according to the delay value, to via the data-signal timing line to time reception of the first write data within the DRAM.

An electronic device includes a semiconductor memory device configured to store process information and to output the process information to the outside; and a host configured to read the process information from the semiconductor memory device, and to select one of a plurality of operation modes depending on the process information so as to be set to an operation mode of the semiconductor memory device. The plurality of operation modes may define one or more of power consumption of the semiconductor memory device or a response characteristic of the semiconductor memory device.

Methods of operating a memory device are disclosed. A method may include receiving a write command, and in response to the write command, performing a write operation without precharging a local input/output line subsequent to receipt of the write command and prior to performing the write operation. Another method may include receiving a read command, performing a read operation in response to the read command, and receiving an additional command without precharging the local input/output line subsequent to performing the read operation and prior to receiving the additional command. Memory devices and systems are also disclosed.

Disclosed herein is an apparatus that includes a first buffer circuit, a plurality of first driver circuits configured to drive the first buffer circuit, and a plurality of first switch circuits configured to supply an operation voltage to the first driver circuits, respectively. The first driver circuits are collectively arranged in a first region in a matrix, and the first switch circuits are collectively arranged in a second region different from the first region.

Disclosed herein is an apparatus that includes a first buffer circuit, a plurality of first driver circuits configured to drive the first buffer circuit, and a plurality of first switch circuits configured to supply an operation voltage to the first driver circuits, respectively. The first driver circuits are collectively arranged in a first region in a matrix, and the first switch circuits are collectively arranged in a second region different from the first region.

An apparatus can include a number of registers configured to enable the apparatus to operate in an artificial intelligence mode to perform artificial intelligence operations and an artificial intelligence (AI) accelerator configured to perform the artificial intelligence operations using the data stored in the number of memory arrays. The AI accelerator can include hardware, software, and or firmware that is configured to perform operations associated with AI operations. The hardware can include circuitry configured as an adder and/or multiplier to perform operations, such as logic operations, associated with AI operations.

An apparatus can include a number of registers configured to enable the apparatus to operate in an artificial intelligence mode to perform artificial intelligence operations and an artificial intelligence (AI) accelerator configured to perform the artificial intelligence operations using the data stored in the number of memory arrays. The AI accelerator can include hardware, software, and or firmware that is configured to perform operations associated with AI operations. The hardware can include circuitry configured as an adder and/or multiplier to perform operations, such as logic operations, associated with AI operations.