A semiconductor memory device includes a memory cell array and a peripheral circuit. The memory cell array includes at least two planes. The peripheral circuit performs a memory operation on a selected plane of the at least two planes during a single plane operation and performs a dummy operation on an unselected plane of the at least two planes.

A power supply circuit of a semiconductor device includes a voltage generation circuit, first and second terminals, and a switch circuit. The voltage generation circuit is configured to generate an operation voltage of the semiconductor device. The first terminal is configured to be at a reference voltage corresponding to an external power supply voltage that is supplied from an external source external to the semiconductor device. The second terminal is connectable to a measuring device. The switch circuit is configured to cause one of the operation voltage and the reference voltage to be output toward the second terminal and then the other of the operation voltage and the reference voltage to be output toward the second terminal.

A power supply circuit of a semiconductor device includes a voltage generation circuit, first and second terminals, and a switch circuit. The voltage generation circuit is configured to generate an operation voltage of the semiconductor device. The first terminal is configured to be at a reference voltage corresponding to an external power supply voltage that is supplied from an external source external to the semiconductor device. The second terminal is connectable to a measuring device. The switch circuit is configured to cause one of the operation voltage and the reference voltage to be output toward the second terminal and then the other of the operation voltage and the reference voltage to be output toward the second terminal.

A system and method for operating a memory cell is provided. A non-volatile memory storage device includes an array of memory cells of differential or single-ended type. In an embodiment, a regulator is coupled to a sense amplifier. The regulator is configured to generate a voltage to gate terminals of one or two transistors of the sense amplifier. In the differential type, the voltage is generated such that the first bias current and the second bias current have a current value equal to the sum of a maximum current flowing in a memory cell being in a RESET state and a fixed current. In the single-ended type, the regulated voltage is generated such that the first bias current and the second bias current have a current value equal to the sum of a fixed current and the reference current generated by the reference current source across temperature.

A system and method for operating a memory cell is provided. A non-volatile memory storage device includes an array of memory cells of differential or single-ended type. In an embodiment, a regulator is coupled to a sense amplifier. The regulator is configured to generate a voltage to gate terminals of one or two transistors of the sense amplifier. In the differential type, the voltage is generated such that the first bias current and the second bias current have a current value equal to the sum of a maximum current flowing in a memory cell being in a RESET state and a fixed current. In the single-ended type, the regulated voltage is generated such that the first bias current and the second bias current have a current value equal to the sum of a fixed current and the reference current generated by the reference current source across temperature.

A memory device includes a cell array including a memory cell that includes a variable resistance element, a reference resistor configured to provide a resistance varying according to an adjustment code, and a read circuit configured to read data that is stored in the memory cell, based on a resistance of the variable resistance element and the resistance of the reference resistor. The memory device further includes a reference adjustment circuit configured to obtain a first calibration code corresponding to a temperature variation, and a second calibration code corresponding to a process variation, and perform an arithmetic operation on the obtained first calibration code and the obtained second calibration code, to obtain the adjustment code.

Provided are an apparatus, a memory device, and a method for storing a plurality of parameter codes for an operation parameter. The memory device includes a mode register and a control logic circuit. To set a first operating condition and a second operating condition for one operation parameter, the mode register stores a first parameter code for the operation parameter and a second parameter code, which is expressed as an offset value from the first parameter code. The control logic circuit sets the first operating condition as a current operating condition of the memory device by using the first parameter code based on a first control code and sets the second operating condition as the current operating condition of the memory device by using the first parameter code and the second parameter code based on a second control code.

Provided are an apparatus, a memory device, and a method for storing a plurality of parameter codes for an operation parameter. The memory device includes a mode register and a control logic circuit. To set a first operating condition and a second operating condition for one operation parameter, the mode register stores a first parameter code for the operation parameter and a second parameter code, which is expressed as an offset value from the first parameter code. The control logic circuit sets the first operating condition as a current operating condition of the memory device by using the first parameter code based on a first control code and sets the second operating condition as the current operating condition of the memory device by using the first parameter code and the second parameter code based on a second control code.

A sense amplifier reference is generated with the same memory cell columns as data cells in order to match signal paths between the data and reference signals. Each row of data memory cells may have a corresponding set of reference cells, which greatly reduces the number of data cells supported by a reference, and in turn reduces the impact of process variations. A memory array may include data columns, a first reference column in the memory array configured to provide a logic 0 reference signal, and a second reference column in the memory array configured to provide a logic 1 reference signal. A circuit is configured to combine at least the logic 0 reference signal and the logic 1 reference signal to generate a reference signal for a sense amplifier to identify the data signal provided from the data columns.

A row decoder includes decoder logic generating an initial word line signal, and two inverters. The first inverter is formed by a first p-channel transistor having a source coupled to a supply voltage and a gate receiving the initial word line signal. The second inverter is formed by a first n-channel transistor having a drain coupled to a drain of the first p-channel transistor, a source coupled to a shared ground line, and a gate receiving the initial word line signal. An inverse word line signal is generated at the drain of the first n-channel transistor. A second inverter inverts the inverse word line signal to produce a word line signal. Negative bias generation circuitry generates a negative bias voltage on the shared ground line when the initial word line signal is logic high, and otherwise couples the shared ground line to ground.