Abstract: A transformer connection method for a transformer includes a first high-frequency terminal configured as a first end of a first plate winding, a second high-frequency terminal configured as a first end of a second plate winding, and a direct current terminal connected to a second end of the first plate winding and a second end of the second plate winding. The transformer connection method comprises connecting the first high-frequency terminal and the second high-frequency terminal to a circuit board to cause the first high-frequency terminal and the second high-frequency terminal to be upright from a surface of the circuit board; and connecting the direct current terminal to a component or to the circuit board connecting with the component, the direct current terminal extending from a portion between the transformer and the circuit board to an outside.

Abstract: An influence of a reflected image included in an infrared light image is reduced. An image pickup unit (20) includes an image pickup element (21) including an infrared light image-image pickup region (21a) and a visible light image-image pickup region (21b) and a polarizing filter (25) in which a plurality of polarizing units including a plurality of polarizing elements (25a to 25d) having principal axes different from each other are associated with a plurality of pixels forming the infrared light image-image pickup region and are arranged two-dimensionally.

Abstract: In an ion concentration sensor, both an improvement of an SN ratio of output and high responsiveness are achieved. In an ion sensor (100), a sensing unit (1) accumulates as electron injected from an n-type substrate (21) via a p-well (22) as a signal charge. The p-well (22) is laminated on the n-type substrate (21). A concentration distribution of impurities exists in the p-well (22) located between the sensing unit (1) and the n-type substrate (21), and a maximum value C1 of an impurity concentration in the p-well (22) is 0<C1?3.0×1014 cm3.

Abstract: The image processing method includes a luminance value information obtaining step of obtaining effective radiance values from a subject, and an image generating step of generating a picture image as a set of unit regions each of which has a luminance value obtained by at least partially removing a regular reflection light component on a surface of the subject from the effective radiance values.

Abstract: The image processing method includes a luminance value information obtaining step of obtaining effective radiance values from a subject, and an image generating step of generating a picture image as a set of unit regions each of which has a luminance value obtained by at least partially removing a regular reflection light component on a surface of the subject from the effective radiance values.

Abstract: The disclosure has an object to restrain properties of a filter from declining in reducing the filter in size. A periodically structured filter includes a plural types of filters. At least one of the plural types of filters is structured so as to have an optical parameter or shape that changes perpendicular to the normal to the surface of that filter with a prescribed spatial regular pattern. At least one of filters of an identical type in each unit and at least one of units adjacent to that unit is adjacent.

Abstract: A mobile information terminal includes an emitted-light polarizing filter having a transmission axis in a first direction, a received-light polarizing filter having a transmission axis in a second direction, an infrared light source emitting near infrared light through the emitted-light polarizing filter, and an image pickup section receiving reflected light generated when the near infrared light is reflected off an object, through the received-light polarizing filter. The second direction has such an angle determined with respect to the first direction that the received-light polarizing filter blocks at least part of light having a polarization property in the reflected light.

Abstract: The image processing method includes a luminance value information obtaining step of obtaining effective radiance values from a subject, and an image generating step of generating a picture image as a set of unit regions each of which has a luminance value obtained by at least partially removing a regular reflection light component on a surface of the subject from the effective radiance values.

Abstract: An ion sensor includes a sensing section that accumulates signal charges, an ion-sensitive membrane that changes the amount of signal charges which can be accumulated in the sensing section, a vertical transfer section that reads and transfers the signal charges, a reference electrode that defines a reference potential in order to determine a potential of the measurement target, and a voltage control section that changes a reference electrode voltage in association with a drive voltage for operating the ion sensor.

Abstract: A semiconductor device is provided with the variable resistance element, and a control circuit that controls a resistance state of the variable resistance element by controlling current between a first end and a second end of the variable resistance element. The control circuit causes the variable resistance element to change from a first resistance state to a second resistance state by having a first current flow from the first end to the second end of the variable resistance element. In addition, after a second current smaller than the first current is made to flow from the first end to the second end of the variable resistance element, the control circuit causes the variable resistance element to change from the second resistance state to the first resistance state by having a third current flow from the second end to the first end thereof.

Abstract: A method of a forming process for a variable resistive element, which is performed in short time comparable to the pulse forming and a writing current in a switching action is the same level as that of the DC forming, is provided. In the forming process, a variable resistive element is changed by voltage pulse application from an initial high resistance state just after produced to a variable resistance state where the switching action is performed. The forming process includes a first step of applying a first pulse having a voltage amplitude lower than a threshold voltage at which the resistance of the variable resistive element is lowered, to between both electrodes of the variable resistive element, and a second step of applying a second pulse having a voltage amplitude having the same polarity as the first pulse and not lower than the threshold voltage, thereto after the first step.

Abstract: A semiconductor device is provided with the variable resistance element, and a control circuit that controls a resistance state of the variable resistance element by controlling current between a first end and a second end of the variable resistance element. The control circuit causes the variable resistance element to change from a first resistance state to a second resistance state by having a first current flow from the first end to the second end of the variable resistance element. In addition, after a second current smaller than the first current is made to flow from the first end to the second end of the variable resistance element, the control circuit causes the variable resistance element to change from the second resistance state to the first resistance state by having a third current flow from the second end to the first end thereof.

Abstract: A variable resistance element that can stably perform a switching operation with a property variation being reduced by suppressing a sharp current that accompanies completion of forming process, and a non-volatile semiconductor memory device including the variable resistance element are realized. The non-volatile semiconductor memory device uses the variable resistance element for storing information in which a resistance changing layer is interposed between a first electrode and a second electrode, and a buffer layer is inserted between the first electrode and the resistance changing layer where a switching interface is formed. The buffer layer and the resistance changing layer include n-type metal oxides, and materials of the buffer layer and the resistance changing layer are selected such that energy at a bottom of a conduction band of the n-type metal oxide configuring the buffer layer is lower than that of the n-type metal oxide configuring the resistance changing layer.

Abstract: Provided is a semiconductor memory device that is capable of stably programming with desirable controllability to a desired electric resistance state in a random access programming action and is provided with a variable resistance element. Regardless of a resistance state of a variable resistance element of a memory cell that is a target of a writing action (erasing and programming actions), an erasing voltage pulse for bringing the resistance state of the variable resistance element to an erased state having a lowest resistance value is applied. Thereafter, a programming voltage pulse for bringing the resistance state of the variable resistance element to a desired programmed state is applied to the variable resistance element of the programming action target memory cell. By always applying the programming voltage pulse after having applied the erasing voltage pulse, a plurality of programming voltage pulses being sequentially applied can be avoided.

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 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: Regardless of a resistance state of a variable resistance element of a memory cell that is a target of a writing action (erasing and programming actions), an erasing voltage pulse for bringing the resistance state of the variable resistance element to an erased state having a lowest resistance value is applied. Thereafter, a programming voltage pulse for bringing the resistance state of the variable resistance element to a desired programmed state is applied to the variable resistance element of the programming action target memory cell. By always applying the programming voltage pulse after having applied the erasing voltage pulse, a plurality of programming voltage pulses being sequentially applied can be avoided. Further, the memory cell array is constituted of even-numbers of subbanks, and the application of the erasing voltage pulse in one subbank and the application of the programming voltage pulse in the other subbank are alternately performed.

Abstract: A nonvolatile semiconductor memory device includes a memory cell array for storing user data provided by arranging memory cells each having a variable resistive element having a first electrode, a second electrode, and a variable resistor made of a metal oxide sandwiched between the first and second electrodes. The first and second electrodes are formed of a conductive material forming ohmic junction with the variable resistor and a conductive material forming non-ohmic junction with the variable resistor, respectively. The variable resistor changes between two or more different resistance states by applying a voltage between the electrodes. The resistance state after being changed is maintained in a nonvolatile manner. The variable resistive elements of all memory cells in the memory cell array are set to the highest of the two or more different resistance states in an unused state before the memory cell array is used to store the user data.

Abstract: A method of a forming process for a variable resistive element, which is performed in short time comparable to the pulse forming and a writing current in a switching action is the same level as that of the DC forming, is provided. In the forming process, a variable resistive element is changed by voltage pulse application from an initial high resistance state just after produced to a variable resistance state where the switching action is performed. The forming process includes a first step of applying a first pulse having a voltage amplitude lower than a threshold voltage at which the resistance of the variable resistive element is lowered, to between both electrodes of the variable resistive element, and a second step of applying a second pulse having a voltage amplitude having the same polarity as the first pulse and not lower than the threshold voltage, thereto after the first step.

Abstract: A nonvolatile semiconductor memory device include: a two terminal structured variable resistive element, wherein resistive characteristics defined by current-voltage characteristics at both ends transit between low and high resistance states stably by applying a voltage satisfying predetermined conditions to the both ends. A transition from the low resistance state to the high resistance state occurs by applying a voltage of a first polarity whose absolute value is at or higher than first threshold voltage, and the reverse transition occurs by applying a voltage of a second polarity whose absolute value is at or higher than a second threshold voltage. A load circuit is connected to the variable resistive element in series having an adjustable load resistance. A voltage generation circuit applies a voltage to both ends of a serial circuit. The variable resistive element can transit between the states by adjusting a resistance of the load circuit.