Abstract: A semiconductor device in which an SOI substrate having an element region in which circuit elements are formed, an insulation layer having a first surface adjoining the SOI substrate, and a support substrate of a first conductivity type are laminated. On the SOI substrate, a transfer electrode configured to transfer charges generated in the support substrate to a third semiconductor layer is formed in a region different from the element region, and the transfer electrode and the third semiconductor layer are adjacent in plan view.

Abstract: A soil sensor includes a current supply unit, an electrode disposed in soil, and a processing unit that obtains a water content and a total ion concentration in the soil. The processing unit includes an information conversion unit that converts a first time and a second time until the measured voltage reaches first threshold voltages and second threshold voltages into frequency information using the temporal change of the measured voltage, an impedance calculation unit that obtains the impedance of the soil, a water content calculation unit that obtains the water content using the impedance, and a total ion concentration calculation unit that obtains the total ion concentration using the impedance.

Abstract: A soil sensor includes a current supply unit, an electrode disposed in soil, and a processing unit that obtains a water content and a total ion concentration in the soil. The processing unit includes an information conversion unit that converts a first time and a second time until the measured voltage reaches first threshold voltages and second threshold voltages into frequency information using the temporal change of the measured voltage, an impedance calculation unit that obtains the impedance of the soil, a water content calculation unit that obtains the water content using the impedance, and a total ion concentration calculation unit that obtains the total ion concentration using the impedance.

Abstract: In a photoelectric-conversion element having a large light receiving region for a high-speed transfer, and a solid-state image sensor including the photoelectric-conversion element, the photoelectric-conversion element includes first to eighth charge read-out regions, which are provided at positions symmetric with respect to a center position of a light receiving region and first to eighth field-control electrodes, which are arranged on both sides of charge-transport paths extending from the center position of the light receiving region to the first to eighth charge read-out regions, respectively, and change depletion potentials of the charge-transport paths and the octuple charge-transfer channels.

Abstract: In a photoelectric-conversion element having a large light receiving region for a high-speed transfer, and a solid-state image sensor including the photoelectric-conversion element, the photoelectric-conversion element includes first to eighth charge read-out regions, which are provided at positions symmetric with respect to a center position of a light receiving region and first to eighth field-control electrodes, which are arranged on both sides of charge-transport paths extending from the center position of the light receiving region to the first to eighth charge read-out regions, respectively, and change depletion potentials of the charge-transport paths and the octuple charge-transfer channels.

Abstract: A charge-modulation element includes a first charge-accumulation region, a second charge-accumulation region, a third charge-accumulation region, and a fourth charge-accumulation region, provided symmetric with respect to a center position of a light-receiving area, and a first field-control electrode pair, a second field-control electrode pair, a third field-control electrode pair, and a fourth field-control electrode pair, arranged on both sides of respective charge transport paths, for changing depletion potentials of the charge transport paths, which extend from the center position of the light-receiving area to the first charge-accumulation region, the second charge-accumulation region, the third charge-accumulation region, and the fourth charge-accumulation region.

Abstract: A distance measurement device according to one aspect of the present invention includes a photoelectric conversion device which includes a light receiving unit, a charge storage unit, a charge discharge unit, and a gate electrode, a controller which controls an irradiation timing of pulse light having a pulse width which is sufficiently shorter than response time of the light receiving unit to an object and performs control to generate control pulse voltages having at least two kinds of phases based on the irradiation timing and to apply it to the gate electrode, a charge reading unit which reads a first and second charges stored in the charge storage unit according to the applications of the respective control pulse voltages having two kinds of phases as a first and second electrical signals, and a calculation unit which calculates a distance to the object based on the first and second electrical signals.

Abstract: A high-accurate imaging increased in time resolution can be made. The camera device is provided with a plurality of pixels that include a light-receiving surface embedded region to convert incident light into charges, a charge accumulation region to accumulate the charges, and a gate electrode to control the charges to be transferred from the light-receiving surface embedded region to the charge accumulation region, and are one-dimensionally arranged in each of a plurality of columns, a timing generation circuit which generates a control pulse voltage to be applied to the gate electrode, and a correction circuit unit which is provided in accordance with each of a plurality of columns of the pixels, delays the control pulse voltage in a variable time, and applies the control pulse voltage to the gate electrodes of the plurality of pixels belonging to a column corresponding to the control pulse voltage.

Abstract: A charge-modulation element includes a first charge-accumulation region, a second charge-accumulation region, a third charge-accumulation region, and a fourth charge-accumulation region, provided symmetric with respect to a center position of a light-receiving area, and a first field-control electrode pair, a second field-control electrode pair, a third field-control electrode pair, and a fourth field-control electrode pair, arranged on both sides of respective charge transport paths, for changing depletion potentials of the charge transport paths, which extend from the center position of the light-receiving area to the first charge-accumulation region, the second charge-accumulation region, the third charge-accumulation region, and the fourth charge-accumulation region.

Abstract: A high-accurate imaging increased in time resolution can be made. The camera device is provided with a plurality of pixels that include a light-receiving surface embedded region to convert incident light into charges, a charge accumulation region to accumulate the charges, and a gate electrode to control the charges to be transferred from the light-receiving surface embedded region to the charge accumulation region, and are one-dimensionally arranged in each of a plurality of columns, a timing generation circuit which generates a control pulse voltage to be applied to the gate electrode, and a correction circuit unit which is provided in accordance with each of a plurality of columns of the pixels, delays the control pulse voltage in a variable time, and applies the control pulse voltage to the gate electrodes of the plurality of pixels belonging to a column corresponding to the control pulse voltage.

Abstract: A distance measurement device according to one aspect of the present invention includes a photoelectric conversion device which includes a light receiving unit, a charge storage unit, a charge discharge unit, and a gate electrode, a controller which controls an irradiation timing of pulse light having a pulse width which is sufficiently shorter than response time of the light receiving unit to an object and performs control to generate control pulse voltages having at least two kinds of phases based on the irradiation timing and to apply it to the gate electrode, a charge reading unit which reads a first and second charges stored in the charge storage unit according to the applications of the respective control pulse voltages having two kinds of phases as a first and second electrical signals, and a calculation unit which calculates a distance to the object based on the first and second electrical signals.

Abstract: In a pixel 11, a floating semiconductor region FD accumulates a charge from a photoelectric transducer PD. A first charge transfer path CTP1 extends from the photoelectric transducer PD to the floating semiconductor region FD through the storage diode SD. A second charge transfer path CTP2 extends from the photoelectric transducer PD to the floating semiconductor region. An output unit AMP provides a signal corresponding to a potential in the floating semiconductor region FD. The first charge transfer path CTP includes a first shutter switch TR(GS1) for controlling a transfer of the charge from the photoelectric transducer PD, the storage diode SD for accumulating the charge from the photoelectric transducer PD, and a transfer switch TR(TF1) for controlling a transfer of the charge from the storage diode SD to the floating semiconductor region PD, while the second charge transfer path CTP includes a shutter switch TR(GS2) for controlling a transfer of the charge from the photoelectric transducer PD.

Abstract: A semiconductor element includes a base-body region of p-type; a charge-generation buried region of a n-type, implementing a photodiode together with the base-body region, configured to create a first potential valley in the base-body region; an accumulation region of n-type, being buried in a part of the upper portion of the base-body region, configured to create a second potential valley deeper than the first potential valley; a transfer-gate insulation film provided on a surface of the base-body region; a transfer-gate electrode provided on the transfer-gate insulation film, configured to control a potential of a transfer channel formed in the base-body region between the charge-generation buried region and the accumulation region; and a recessed-potential creation mechanism configured to create a stair-like-shaped potential barrier for electronic shuttering.

Abstract: In a pixel 11, a floating semiconductor region FD accumulates a charge from a photoelectric transducer PD. A first charge transfer path CTP1 extends from the photoelectric transducer PD to the floating semiconductor region FD through the storage diode SD. A second charge transfer path CTP2 extends from the photoelectric transducer PD to the floating semiconductor region. An output unit AMP provides a signal corresponding to a potential in the floating semiconductor region FD. The first charge transfer path CTP includes a first shutter switch TR(GS1) for controlling a transfer of the charge from the photoelectric transducer PD, the storage diode SD for accumulating the charge from the photoelectric transducer PD, and a transfer switch TR(TF1) for controlling a transfer of the charge from the storage diode SD to the floating semiconductor region PD, while the second charge transfer path CTP includes a shutter switch TR(GS2) for controlling a transfer of the charge from the photoelectric transducer PD.

Abstract: A semiconductor element includes a base-body region of p-type; a charge-generation buried region of a n-type, implementing a photodiode together with the base-body region, configured to create a first potential valley in the base-body region; an accumulation region of n-type, being buried in a part of the upper portion of the base-body region, configured to create a second potential valley deeper than the first potential valley; a transfer-gate insulation film provided on a surface of the base-body region; a transfer-gate electrode provided on the transfer-gate insulation film, configured to control a potential of a transfer channel formed in the base-body region between the charge-generation buried region and the accumulation region; and a recessed-potential creation mechanism configured to create a stair-like-shaped potential barrier for electronic shuttering.