A memory includes an array of resistive memory cells and circuitry for setting a write parameter for improving write effectiveness to the cells of the memory array. The circuitry performs a write parameter setting routine that determines a midpoint resistance of a memory state of cells of the array and determines a write efficiency of a weak write operation to cells of the array. Based on the determined midpoint resistance and the determined write efficiency, the circuit sets a write parameter level for subsequent writes to cells of the array.

According to one embodiment, a semiconductor storage device includes a memory cell, a bit line connected to the memory cell, and a sense circuit connected to the bit line, wherein the sense circuit includes a first transistor with a first end connected to the bit line, a second transistor with a first end connected to a second end of the first transistor, a third transistor with a first end connected to the bit line, a fourth transistor with a first end connected to a second end of the third transistor, and an amplifier connected to a second end of the second transistor and to a second end of the fourth transistor.

1. The present disclosure is drawn to, among other things, a method for accessing memory using dual standby modes, the method including receiving a first standby mode indication selecting a first standby mode from a first standby mode or a second standby mode, configuring a read bias system to provide a read bias voltage and a write bias system to provide approximately no voltage, or any voltage outside the necessary range for write operation, based on the first standby mode, receiving a second standby mode indication selecting the second standby mode, and configuring the read bias system to provide at least the read bias voltage and the write bias system to provide a write bias voltage based on the second standby mode, the read bias voltage being lower than the write bias voltage.

A semiconductor device capable of changing a data programming process in a simple manner according to a situation is provided. The semiconductor device includes a plurality of memory cells, a programming circuit for supplying a programming current to the memory cell, and a power supply circuit for supplying power to the programming circuit. The power supply circuit includes a charge pump circuit for boosting the external power supply, a voltage of the external power supply according to the selection indication, and a selectable circuit capable of switching the boosted voltage boosted by the charge pump circuit. The control circuit further includes a control circuit for executing data programming processing by the programming circuit by switching the selection indication.

A processing apparatus includes a bit-cell array including at least one bit-cell line including a plurality of bit-cells electrically connected to each other in series, wherein each of the plurality of bit-cells includes: a first magnetic resistor that is configured to store a first resistance value based on a movement of a location of a magnetic domain-wall; a second magnetic resistor that is configured to store a second resistance value, wherein the second resistance value is equal to or less than the first resistance value; a first switching element configured to switch an electrical signal applied to the first magnetic resistor; and a second switching element configured to switch an electrical signal applied to the second magnetic resistor.

A memory device including a plurality of memory cells, a peripheral circuit, and control logic. The peripheral circuit is configured to generate a plurality of operating voltages used in a memory operation, based on a target pump clock, and perform the memory operation by using the plurality of operating voltages. The control logic is configured to select the target pump clock among a plurality of pump clocks, based on a number of data bits which selected memory cells on which the memory operation is to be performed among the plurality of memory cells store, and control the peripheral circuit to perform the memory operation on the selected memory cells.

The present disclosure is drawn to, among other things, a method for accessing memory using dual standby modes, the method including receiving a first standby mode indication selecting a first standby mode from a first standby mode or a second standby mode, configuring a read bias system to provide a read bias voltage and a write bias system to provide approximately no voltage, or any voltage outside the necessary range for write operation, based on the first standby mode, receiving a second standby mode indication selecting the second standby mode, and configuring the read bias system to provide at least the read bias voltage and the write bias system to provide a write bias voltage based on the second standby mode, the read bias voltage being lower than the write bias voltage.

A nonvolatile memory device includes an array of magnetic memory cells, and control logic circuit having a voltage generator therein, which is configured to generate a gate voltage. A row decoder is provided, which is connected by word lines to the array of magnetic memory cells, and has a word line driver driven therein, which is responsive to the gate voltage. A column decoder is provided, which is connected by bit lines and source lines to the array of magnetic memory cells. A write driver is provided, which has a write voltage generating circuit therein that is configured to output a write voltage, in response to: (i) a reference voltage generated using a replica magnetic memory cell, and (ii) a feedback voltage generated using a magnetic memory cell in which a write operation is to be performed.

A semiconductor storage according to an embodiment of the present disclosure includes two power source paths, and a connection path that connects the power source paths. Each of the power source paths includes a power gate transistor and a current source transistor which are coupled in series. The connection path connects ends of the respective power source paths on a side of the current source transistor. The semiconductor storage further includes a storage element, and a switch element inserted between the connection path and the storage element. A back gate is coupled to an internal node in the current source transistor provided in a low-side path of the two power source paths.

Disclosed are a method of operating a selector device, a method of operating a nonvolatile memory apparatus to which the selector device is applied, an electronic circuit device including the selector device, and a nonvolatile memory apparatus. The method of operating the selector device controls access to a memory element, and includes providing the selector device including a switching layer and first and second electrodes disposed on both surfaces of the switching layer, which includes an insulator and a metal element, and applying a multi-step voltage pulse to the switching layer via the first and second electrodes to adjust a threshold voltage of the selector device, the multi-step voltage pulse including a threshold voltage control pulse and an operating voltage pulse. The operating voltage pulse has a magnitude for turning on the selector device, and the threshold voltage control pulse has a lower magnitude lower than the operating voltage pulse.