Abstract: A photovoltaic module of the present invention includes a cluster power generation unit in which multiple photovoltaic elements are connected in series via connection points, a pair of output terminals connected to respective ends of a series circuit formed by the cluster power generation unit, and a specified terminal connected to a specified connection point that is specified from among the connection points.

Abstract: A push-pull circuit comprising: a push-pull first switching element and second switching element; a first rectifier element; a third switching element for switching a pathway between conductance and cutoff, the pathway leading from a connection point between the first switching element and an inductive load via the first rectifier element to a connection point between a DC power source and a center tap of the inductive load; a second rectifier element; and a fourth switching element for switching a pathway between conductance and cutoff, the pathway leading from a connection point between the second switching element and the inductive load via the second rectifier element to a connection point between the DC power source and the center tap of the inductive load.

Abstract: A nonvolatile semiconductor memory device in which a memory cell life can be prolonged while making it possible to perform writing in units of bits. When command information represents writing, a comparing unit 37 compares written data in a target memory cell with write target data to give a comparison result to a write/read control unit 40, when the comparison result represents matching, the write/read control unit 40 does not instruct a decoder unit (51A, 51B, and 53) to perform writing in the target memory cell, and when the comparison result represents mismatching, the write/read control unit 40 instructs the decoder unit to write the write target data in the target memory cell.

Abstract: A vehicle driving device is arranged such that in accordance with an instruction signal from the outside, a first battery managing section outputs, to the outside, a signal related to charging/discharging control for a first battery.

Abstract: In order to offer a power supply circuit that can minimize the drop in efficiency by reducing losses during voltage conversion, in an improved-power factor circuit, a control circuit performs a step-up operation in which a control signal for turning on a first switching element (Tr1) and switching a second switching element (Tr2) is output, and a step-down operation in which a control signal for turning off the second switching element (Tr2) and switching the first switching element (Tr1) is output.

Abstract: In a moving apparatus, flapping angle of a front wing shaft is ?+??/2, and the flapping angle of rear wing shaft is ????/2. Specifically, amplitude difference between front wing shaft and rear wing shaft is ??. Further, the flapping motion of front wing shaft is represented by sin (?+?/2), and the flapping motion of rear wing shaft is represented by sin (???/2). In other words, phase difference between the front and rear wing shafts is ?. Further, amplitude difference ?? and phase difference ? are each represented by a function using a common parameter. Therefore, a control portion can independently change the amplitude difference ?? and phase difference ?, so as to variously change a torsion angle formed by a tip end portion of the wing and a prescribed phantom plane. Thus, a moving apparatus that can make an efficient transition from hovering to forward or backward flight can be provided.

Abstract: There is provided a semiconductor memory device capable of suppressing writing disturbances without increasing the cell array area. A semiconductor memory device has a memory cell array where a number of memory cells having a two-terminal type memory element and a transistor for selection connected in series are aligned in a matrix shape, a first voltage applying circuit for applying a writing voltage pulse to a first bit line, and a second voltage applying circuit for applying a pre-charge voltage to a first and second bit line, such that at the time of the writing of a memory cell, the first voltage applying circuit pre-charges the two ends of the memory cell to the same voltage in advance, and after that, the second voltage applying circuit applies a writing voltage pulse via the first bit line directly connected to the transistor for selection.

Abstract: A nonvolatile semiconductor memory device can carry out a forming process simultaneously on the nonvolatile variable resistive elements of memory cells and make the forming time shorter. The nonvolatile semiconductor memory device has a forming detection circuit provided between the memory cell array and the second selection line (bit line) decoder. The forming detection circuit detects the completion of the forming process for memory cells by measuring the fluctuation in the potential of second selection lines or the current flowing through the second selection lines when applying a voltage pulse for a forming process through the second selection lines simultaneously to the memory cells on which a forming process is to be carried out connected to the same first selection line (word line), and prevents a voltage from being applied to the second selection lines connected to the memory cells where the completion of the forming process is detected.

Abstract: Provided is a nonvolatile semiconductor memory device capable of performing a writing action for a memory cell at high speed. The device includes a memory cell array having a first sub-bank and a second sub-bank each having a plurality of nonvolatile memory cells arranged in a form of a matrix; a row decoder shared by the first sub-bank and the second sub-bank; a first column decoder and a second column decoder provided in the first sub-bank and the second sub-bank, respectively; and a control circuit arranged to execute alternately a first action cycle to perform a programming action in the first sub-bank and a reading action for a programming verifying action in the second sub-bank and a second action cycle to perform the reading action for the programming verifying action in the first sub-bank and the programming action in the second sub-bank.

Abstract: A semiconductor memory device includes a memory cell array where a plurality of memory cells are arranged in a matrix, each of the memory cells serially connecting a two-terminal type memory element and a transistor for selection, a first voltage applying circuit that applies a write voltage pulse to a bit line, and a second voltage applying circuit that applies a precharge voltage to a bit line and a common line. In writing the memory cell, after the second voltage applying circuit has both terminals of the memory cell previously precharged to the same voltage, the first voltage applying circuit applies the write voltage pulse to one terminal of the writing target memory cell via the bit line, and while the write voltage pulse is applied, the second voltage applying circuit maintains the application of the precharge voltage to the other terminal of the memory cell via the common line.

Abstract: A semiconductor memory device includes a memory cell array in which a plurality of memory cells is aligned in a matrix shape, each memory cell including a two-terminal memory element and a transistor for selection connected in series; a first voltage applying circuit that applies a writing voltage pulse to first bit lines; and a second voltage applying circuit that applies a pre-charge voltage to the first bit lines and second bit lines, wherein in a writing of a memory cell, after the second voltage applying circuit has pre-charged both ends of the memory cell to a same voltage, the first voltage applying circuit applies the writing voltage pulse via the first bit line that is directly connected to the transistor for selection, and the second voltage applying circuit applies the pre-charge voltage to the second bit line directly connected to the memory element.

Abstract: A nonvolatile semiconductor memory device in which a memory cell life can be prolonged while making it possible to perform writing in units of bits. When command information represents writing, a comparing unit 37 compares written data in a target memory cell with write target data to give a comparison result to a write/read control unit 40, when the comparison result represents matching, the write/read control unit 40 does not instruct a decoder unit (51A, 51B, and 53) to perform writing in the target memory cell, and when the comparison result represents mismatching, the write/read control unit 40 instructs the decoder unit to write the write target data in the target memory cell.

Abstract: A nonvolatile semiconductor memory device includes a bit voltage adjusting circuit which, for each bit line, fixes potentials of a selected bit line and a non-selected bit line to a predetermined potential to perform a memory operation and a data voltage adjusting circuit which, for each data line, fixes potentials of a selected data line and a non-selected data line to a predetermined potential to perform a memory operation. Each of the voltage adjusting circuits includes an operational amplifier and a transistor, a voltage required for a memory operation is input to the non-inverted input terminal of the operational amplifier, and the inverted input terminal of the operational amplifier is connected to the bit line or the data line, so that the potential of the bit line or the data line is fixed to a potential of the non-inverted input terminal of the operational amplifier.

Abstract: A semiconductor storage device includes a first memory cell for storing two kinds of states, a second memory cell for storing two kinds of states, and a sense amplifier for detecting a potential difference between voltages equivalent to readout currents of the first and second memory cells, respectively. Either one of information data “0” or data “1”, which is stored in combination of the first and second memory cells, is read out by detecting the potential difference equivalent to the readout current difference between the first and second memory cells.

Abstract: There is provided a semiconductor memory device capable of suppressing writing disturbances without increasing the cell array area. A semiconductor memory device has a memory cell array where a number of memory cells having a two-terminal type memory element and a transistor for selection connected in series are aligned in a matrix shape, a first voltage applying circuit for applying a writing voltage pulse to a first bit line, and a second voltage applying circuit for applying a pre-charge voltage to a first and second bit line, such that at the time of the writing of a memory cell, the first voltage applying circuit pre-charges the two ends of the memory cell to the same voltage in advance, and after that, the second voltage applying circuit applies a writing voltage pulse via the first bit line directly connected to the transistor for selection.

Abstract: The semiconductor device of the present invention has a circuit block in which m (m is an integer of not smaller than two) sets of first through m-th transistor columns where two or more transistors are connected in series, one terminal of the first through m-th transistor columns is connected to a first output node, and the other terminal of the first through m-th transistor columns is connected to a second output node. A control signal for substantially simultaneously turning on and off all the transistors of the first through m-th transistor columns is inputted to the control input terminals of the transistors of the first through m-th transistor columns.

Abstract: A nonvolatile semiconductor memory device can carry out a forming process simultaneously on the nonvolatile variable resistive elements of memory cells and make the forming time shorter. The nonvolatile semiconductor memory device has a forming detection circuit provided between the memory cell array and the second selection line (bit line) decoder. The forming detection circuit detects the completion of the forming process for memory cells by measuring the fluctuation in the potential of second selection lines or the current flowing through the second selection lines when applying a voltage pulse for a forming process through the second selection lines simultaneously to the memory cells on which a forming process is to be carried out connected to the same first selection line (word line), and prevents a voltage from being applied to the second selection lines connected to the memory cells where the completion of the forming process is detected.

Abstract: A three-dimensional memory cell array of memory cells with two terminals having a variable resistive element is formed such that: one ends of memory cells adjacent in Z direction are connected to one of middle selection lines extending in Z direction aligned in X and Y directions; the other ends of the memory cells located at the same point in Z direction are connected to one of third selection lines aligned in Z direction; a two-dimensional array where selection transistors are aligned in X and Y directions is adjacent to the memory cell array in Z direction; gates of selection transistors adjacent in X direction, drains of selection transistors adjacent in Y direction and sources of selection transistors are connected to same first selection line, second selection line, and different middle selection lines, respectively; and first, second and third selection lines are connected to X, Y and Z decoders, respectively.

Abstract: Provided is a nonvolatile semiconductor memory device capable of performing a writing action for a memory cell at high speed. The device comprises: a memory cell array having a first sub-bank and a second sub-bank each having a plurality of nonvolatile memory cells arranged in a form of a matrix; a row decoder shared by the first sub-bank and the second sub-bank; a first column decoder and a second column decoder provided in the first sub-bank and the second sub-bank, respectively; and a control circuit arranged to execute alternately a first action cycle to perform a programming action in the first sub-bank and a reading action for a programming verifying action in the second sub-bank and a second action cycle to perform the reading action for the programming verifying action in the first sub-bank and the programming action in the second sub-bank.

Abstract: The semiconductor device of the present invention has a circuit block in which m (m is an integer of not smaller than two) sets of first through m-th transistor columns where two or more transistors are connected in series, one terminal of the first through m-th transistor columns is connected to a first output node, and the other terminal of the first through m-th transistor columns is connected to a second output node. A control signal for substantially simultaneously turning on and off all the transistors of the first through m-th transistor columns is inputted to the control input terminals of the transistors of the first through m-th transistor columns.