A semiconductor apparatus includes a command decoding circuit and an enable signal generation circuit. The command decoding circuit generates an operation code and a strobe pulse based on a command signal and a clock signal. The enable signal generation circuit generates a seed signal based on the operation code and the strobe pulse and generates an enable signal by shifting the seed signal. The enable signal generation circuit generates a plurality of guard keys based on a plurality of operation codes and the strobe pulse and prevents the generation of the enable signal for a predetermined time when the plurality of guard keys are not sequentially enabled.

A semiconductor apparatus includes a command decoding circuit and an enable signal generation circuit. The command decoding circuit generates an operation code and a strobe pulse based on a command signal and a clock signal. The enable signal generation circuit generates a seed signal based on the operation code and the strobe pulse and generates an enable signal by shifting the seed signal. The enable signal generation circuit generates a plurality of guard keys based on a plurality of operation codes and the strobe pulse and prevents the generation of the enable signal for a predetermined time when the plurality of guard keys are not sequentially enabled.

The present disclosure is drawn to, among other things, a method of managing a magnetoresistive memory (MRAM) device. In some aspects, the method includes receiving a configuration bit from a write mode configuration register. In response to determining the configuration bit is a first value, the MRAM device is operated in a NOR emulation mode. In response to determining the configuration bit is a second value, the MRAM device is operated in a persistent memory mode.

The present disclosure relates to a memory device comprising a memory array and a periphery circuitry configured to read data from and/or write data to the memory array, wherein the periphery circuitry comprises a programmable circuitry causing the memory device to access data stored in the memory array in accordance with manifest loop instructions. The programmable circuitry comprises a control logic configured to control the operation of the periphery circuitry in accordance with a set of parameters derived from the manifest loop instructions. The present disclosure further relates to a method for controlling the operation of a memory device and to a processing system comprising the memory device.

In some examples, a memory device may perform refresh operations responsive to internal and/or external commands. internal refresh commands may include auto-refresh commands and row hammer (e.g., targeted) refresh commands. External commands may include refresh management commands. In some examples, the external command may cause a refresh operation to occur after a number of activation commands. The memory device may monitor row addresses associated with the activation commands. In some examples, the memory device may skip a refresh operation indicated by a refresh management command if none of the row addresses associated with the activation commands occurs at a high frequency. In some examples, row addresses may be determined to be aggressor row addresses if a received row address matches a previously received row address.

An address counting circuit includes a shared address counting circuit configured to generate a first shared address and a second shared address by counting an external start address at a first edge and a second edge of a counting clock signal and a latch circuit including a plurality of latches configured to share the first shared address and the second shared address, respectively and generate a plurality of column addresses by latching the first shared address and second shared address according to a plurality of latch clock signals.

Provided is a semiconductor device including a sequential circuit including a first transistor and a capacitor. The first transistor includes a semiconductor layer including indium, zinc, and oxygen to form a channel formation region. A node electrically connected to a source or a drain of the first transistor and a capacitor becomes a floating state when the first transistor turns off, so that a potential of the node can be maintained for a long period. A power-gating control circuit may be provided to control supply of power supply potential to the sequential circuit. The potential of the node still can be maintained while supply of the power supply potential is stopped.

Provided is a semiconductor device including a sequential circuit including a first transistor and a capacitor. The first transistor includes a semiconductor layer including indium, zinc, and oxygen to form a channel formation region. A node electrically connected to a source or a drain of the first transistor and a capacitor becomes a floating state when the first transistor turns off, so that a potential of the node can be maintained for a long period. A power-gating control circuit may be provided to control supply of power supply potential to the sequential circuit. The potential of the node still can be maintained while supply of the power supply potential is stopped.

In some embodiments, an in-memory-computing SRAM macro based on capacitive-coupling computing (C3) (which is referred to herein as “C3SRAM”) is provided. In some embodiments, a C3SRAM macro can support array-level fully parallel computation, multi-bit outputs, and configurable multi-bit inputs. The macro can include circuits embedded in bitcells and peripherals to perform hardware acceleration for neural networks with binarized weights and activations in some embodiments. In some embodiments, the macro utilizes analog-mixed-signal capacitive-coupling computing to evaluate the main computations of binary neural networks, binary-multiply-and-accumulate operations. Without needing to access the stored weights by individual row, the macro can assert all of its rows simultaneously and form an analog voltage at the read bitline node through capacitive voltage division, in some embodiments. With one analog-to-digital converter (ADC) per column, the macro cab realize fully parallel vector-matrix multiplication in a single cycle in accordance with some embodiments.

A memory circuit includes a memory array, a word line, and a bit line. The memory array includes a plurality of memories arranged in a matrix shape in a first direction and a second direction perpendicular to the first direction. The word line extends in the first direction and reads signals from the plurality of memories arranged in the first direction. The bit line includes a digit line connected to the plurality of memories arranged in the second direction and an output line connected to the digit line and extending in the first direction and transmits a signal from a memory corresponding to the word line to the output line as the word line reads a signal.