Abstract: A stacked-type detection apparatus including a plurality of pixels arranged at small intervals is configured to have low capacitance associated with signal lines and/or driving lines. With this novel configuration, small time constant and high-speed driving capability can be achieved in the signal lines and/or driving lines. The plurality of pixels in the detection apparatus are arranged in a row direction and a column direction on an insulating substrate. Each pixel includes a conversion element and a switch element, the conversion element is disposed above the switch element. A driving line disposed below the conversion elements is connected to switch elements arranged in the row direction, and a signal line is connected to switch elements arranged in the column direction. The signal line includes a conductive layer embedded in an insulating member, the insulating member is disposed in a layer lower than an uppermost surface portion of the driving line.

Abstract: A detection apparatus includes a conversion layer configured to convert incident light or radiation into a charge, electrodes configured to collect a charge produced as a result of the conversion by the conversion layer, and impurity semiconductor layers arranged between the electrodes and the conversion layer. The conversion layer is arranged over the electrodes so as to cover the electrodes. A part of the conversion layer which covers a region between an adjacent pair of the electrodes includes a portion smaller in film thickness than a part of the conversion layer which covers edges of the electrodes.

Abstract: A manufacturing method for a detection apparatus is provided. The method includes depositing a first impurity semiconductor layer and a first intrinsic semiconductor layer in this order on a plurality of first electrodes arranged in an array above a substrate. The method also includes patterning the first intrinsic semiconductor layer and the first impurity semiconductor layer and thereby dividing the first intrinsic semiconductor layer and the first impurity semiconductor layer so as to cover each of the plurality of first electrodes separately. The method further includes depositing a second intrinsic semiconductor layer on the patterned first intrinsic semiconductor layer.

Abstract: A detecting apparatus formed on a substrate, includes a plurality of pixels arranged in a matrix, and a signal line electrically connected to the pixels. Each of the pixels includes a sensing element that converts radiant ray or light to electric charges, an amplification thin film transistor that outputs an electric signal based on an amount of the electric charges, a capacitor that holds an electric signal output by the amplification thin film transistor, and a transfer thin film transistor that transfers an electric signal held in the capacitor to the signal line.

Abstract: A detection apparatus includes a plurality of conversion elements, an interlayer insulating layer, and a covering layer. Each of the plurality of conversion elements includes an electrode electrically connected to a corresponding one of a plurality of switching elements and a semiconductor layer disposed on the electrode. The interlayer insulating layer is disposed so as to cover the plurality of switching elements and composed of an organic material, and has a surface including a first region and a second region located outside the first region. The electrodes are disposed on the surface of the interlayer insulating layer in the first region. The covering layer is disposed on the surface of the interlayer insulating layer in the second region and composed of an inorganic material.

Abstract: A detection apparatus includes a driving circuit unit in which a plurality of unit circuits each including a first circuit that supplies conducting voltage of a switch element of a pixel based on voltage included in a clock signal to a driving wire in accordance with an initiation signal and a second circuit that supplies non-conducting voltage of the switch element to the driving wire in accordance with a termination signal are provided for the plurality of corresponding driving wires and a control unit that supplies the clock signal to the driving circuit unit. The control unit supplies control voltage to the plurality of unit circuits, and each of the plurality of unit circuits further includes a third circuit that continues to supply the non-conducting voltage to the corresponding driving wire in accordance with the control voltage.

Abstract: A radiation detection apparatus includes a scintillator, a photoelectric conversion unit, and a grid for removing scattered radiation. The photoelectric conversion unit includes a plurality of pixels arranged in a two-dimensional array on a substrate. Each pixel is configured to convert visible light output from the scintillator into an electric signal. The grid, the substrate, the photoelectric conversion unit, and the scintillator are disposed in this order from a radiation-incident side of the radiation detection apparatus to an opposite side thereof. In this radiation detection apparatus in which the scintillator is disposed on the side opposite to the radiation-incident side, scattered radiation is effectively removed.

Abstract: A detection apparatus includes a plurality of pixels and a plurality of signal wires arranged on a substrate, in which each of the plurality of pixels includes a switch element arranged on the substrate and a conversion element arranged on the switch element, the conversion element includes a first electrode which is arranged on the switch element and electrically connected to the switch element and a semiconductor layer arranged over a plurality of the first electrodes, and a plurality of the switch elements is electrically connected to the plurality of signal wires, and the detection apparatus further includes a constant potential wire which is supplied with a constant potential, in which the first electrode is electrically connected to the constant potential wire in apart of pixels among the plurality of pixels.

Abstract: A radiation detection apparatus includes a scintillator, a photoelectric conversion unit, and a grid for removing scattered radiation. The photoelectric conversion unit includes a plurality of pixels arranged in a two-dimensional array on a substrate. Each pixel is configured to convert visible light output from the scintillator into an electric signal. The grid, the substrate, the photoelectric conversion unit, and the scintillator are disposed in this order from a radiation-incident side of the radiation detection apparatus to an opposite side thereof. In this radiation detection apparatus in which the scintillator is disposed on the side opposite to the radiation-incident side, scattered radiation is effectively removed.

Abstract: A detection apparatus includes a substrate which includes a plurality of pixels arranged in a matrix and adapted to generate pixel signals, a plurality of drive lines arranged in a column direction and each connected in common to a plurality of pixels in a row direction, a plurality of data lines arranged in the row direction and each connected in common to a plurality of pixels in the column direction, connection terminals smaller in number than the data lines, and a multiplexer unit provided between the connection terminals and the data lines; a read circuit provided with a reset switch for supplying a constant potential to the connection terminals and connected to the connection terminals; a drive circuit adapted to control driving of the plurality of pixels; and a control circuit adapted to supply a control signal to the substrate and the read circuit.

Abstract: An active matrix panel includes a gate line connected to control electrodes of a plurality of transistors; and a drive circuit supplying the gate line with a conducting voltage and a non-conducting voltage. The drive circuit includes a shift register including a plurality of shift register unit circuits connected to each other, and a demultiplexer including a plurality of demultiplexer unit circuits into which output signals of the shift register unit circuits are input. The demultiplexer unit circuit includes a first transistor for supplying the gate line with the conducting voltage, and a second transistor for supplying the gate line with the non-conducting voltage. The first transistor is changed from a non-conducting state into a conducting state when the second transistor is in the conducting state.

Abstract: In a method of manufacturing a detection device including pixels on a substrate, each pixel including a switch element and a conversion element including an impurity semiconductor layer on an electrode, which is disposed above the switch element and isolated per pixel, the switch element and the electrode being connected in a contact hole formed in a protection layer and an interlayer insulating layer, which are disposed between the switch elements and the electrodes, the method includes forming insulating members over the interlayer insulating layer between the electrodes in contact with the interlayer insulating layer, forming an impurity semiconductor film covering the insulating members and the electrodes, and forming a coating layer covering an area of the protection layer where an orthographically-projected image of a portion of the electrode is positioned, the portion including a level difference within the contact hole.

Abstract: A detection device includes conversion elements, each including a first electrode disposed on a substrate, a semiconductor layer disposed on the first electrode, an impurity semiconductor layer disposed on the semiconductor layer and including at least a first region and a second region, and a second electrode disposed on the first region of the impurity semiconductor layer in contact with the impurity semiconductor layer. Sheet resistance in the second region disposed at a position where the impurity semiconductor layer is not contacted with the second electrode is less than sheet resistance in the first region.

Abstract: A radiation detection apparatus includes a scintillator, a photoelectric conversion unit, and a grid for removing scattered radiation. The photoelectric conversion unit includes a plurality of pixels arranged in a two-dimensional array on a substrate. Each pixel is configured to convert visible light output from the scintillator into an electric signal. The grid, the substrate, the photoelectric conversion unit, and the scintillator are disposed in this order from a radiation-incident side of the radiation detection apparatus to an opposite side thereof. In this radiation detection apparatus in which the scintillator is disposed on the side opposite to the radiation-incident side, scattered radiation is effectively removed.

Abstract: A method of manufacturing a radiation detection apparatus including a photoelectric conversion element that includes a first electrode placed above a substrate, a semiconductor layer placed on the first electrode, and a second electrode placed on the semiconductor layer includes forming the second electrode by removing a portion of an electrode layer formed over the semiconductor layer, the portion being located on an end section of the semiconductor layer. The method includes forming an insulating layer such that the insulating layer covers a portion of the semiconductor layer that is not covered by the second electrode. The method further includes forming a third electrode on at least one portion of the insulating layer such that the insulating layer is interposed between the third electrode and the end section of the semiconductor layer.

Abstract: A semiconductor apparatus including a substrate, a pixel array on the substrate, first and second conductive pads between which the substrate locates is provided. The apparatus also comprises an insulating layer arranged between the substrate and the first conductive pad; a third conductive pad arranged between the substrate and the insulating layer; a first conductive member which passes through the insulating layer and connects the first and third conductive pads to each other; and a second conductive member which passes through the substrate and connects the second and third conductive pads to each other. The pixel array further comprises a conductive line connected to circuit elements included in pixels aligned in a row or column direction. The first conductive pad is connected to the conductive line in an interval between the pixels.

Abstract: A radiation detection apparatus includes a scintillator configured to convert incident radiation into visible light, a photoelectric conversion unit and an electrically conductive member. The photoelectric conversion unit includes a two-dimensional array of pixels arranged on a substrate. Each pixel is configured to convert the visible light into an electric signal. The electrically conductive member is supplied with a fixed potential. The electrically conductive member, the substrate, the photoelectric conversion unit, and the scintillator are disposed in this order from the radiation-incident side of the radiation detection apparatus to the opposite side.

Abstract: A detection apparatus includes conversion elements and switch elements disposed below the conversion elements; insulating layers are disposed between the conversion elements and switch elements. Each conversion element includes a first electrode corresponding to a switch element. A second electrode extends over the plurality of conversion elements; and a semiconductor layer formed between the first electrodes and the second electrode extends over the plurality of conversion elements. Insulating layers include first regions located immediately below the first electrodes and a second region located between the first regions. A third electrode is disposed in the second region and between the insulating layers. The third electrode is supplied with a potential that sets a potential of a part where the second region is in contact with the semiconductor layer to a value between a potential of the second electrode and a potential of the first electrode.

Abstract: A detection apparatus includes a transistor disposed on a substrate, a conversion element disposed above the transistor and connected to the transistor, a capacitor connected in parallel with conversion element to the transistor, the capacitor including, between the substrate and the conversion element, an ohmic contact part connected to the conversion element, a semiconductor part connected to the ohmic contact part, and an electrically conductive part disposed at a location opposite to the semiconductor part and the ohmic contact part via an insulating layer, and a potential supplying unit configured to selectively supply a first electric potential to the electrically conductive part to accumulate charge carriers in the semiconductor part and a second electric potential to the electrically conductive part to deplete the semiconductor part. The detection apparatus configured in the above-described manner is capable of controlling pixel capacitance thereby achieving a high signal-to-noise ratio.

Abstract: A detection apparatus includes a conversion element; a transistor which includes a semiconductor layer including a first channel region and a second channel region, a first gate electrode, and a second gate electrode; a first drive wiring which is connected to the first gate electrode; a second drive wiring which is connected to the second gate electrode; a first conduction voltage supply unit which supplies the first conduction voltage to the first driving wiring; a second conduction voltage supply unit which supplies the second conduction voltage to the second driving wiring; and a selection unit which selects any one of a first connection between the second drive wiring and the first conduction voltage supply unit and a second connection between the second drive wiring and the second conduction voltage supply unit.