Abstract: A photoelectric conversion device in which a substantially intrinsic i-type amorphous hydrogen-containing semiconductor layer, a p-type amorphous hydrogen-containing semiconductor layer, and a first transparent conductive layer are stacked in this order on a first surface of an n-type semiconductor substrate that generates a photogenerated carrier by receiving light, wherein the first transparent conductive layer includes a hydrogen-containing area formed of a transparent conductive material that contains hydrogen and a hydrogen-diffusion suppression area that is present on a side of the p-type amorphous hydrogen-containing semiconductor layer with respect to the hydrogen-containing area and that is formed of a transparent conductive material that does not substantially contain hydrogen, and the hydrogen-diffusion suppression area has a hydrogen concentration distribution in which a hydrogen content on a side of the p-type amorphous hydrogen-containing semiconductor layer is lower than that on a side of the h

Abstract: A lighting apparatus includes a light-emission unit having plate shape; and a base unit configured to be detachably attached thereto the light-emission unit. The base unit has substantially rectangular shape. The base unit includes a power supply rail for supplying electricity to the light-emission unit and a support section supporting the light-emission unit. The power supply rail has rail-shape and extending in a longitudinal direction of the base unit. The light-emission unit includes a luminescent panel, a control circuit configured to control lighting of the luminescent panel and an electrically conductive connection terminal electrically connecting the control circuit to the power supply rail. The base unit is formed so as to be capable of being attached thereto a plurality of the light-emission units along the longitudinal direction of the base unit. The connection terminal is connected to an arbitrary point of the rail-shaped power supply rail.

Abstract: A method for feeding electric power to a planar light-emitting element which includes a planar anode electrode, a planar cathode electrode, a light-emitting layer provided between the anode electrode and the cathode electrode, two or more anode terminal portions protruding from the anode electrode and one or more cathode terminal portions protruding from the cathode electrode. The method includes sequentially providing the electric power to the anode terminal portions.

Abstract: A lighting apparatus includes: a light source unit that has a case storing therein a light-emitting panel and a wiring board mounted on a non-light emitting face thereof; and an attachment unit that has a housing storing therein a circuit board and configured to be detachably attached to the light source unit. The case has a wiring board storage. The housing has a circuit board storage. The case and the housing are arranged such that a whole of the wiring board storage and a whole of the circuit board storage are arranged at different positions in a direction perpendicular to an attachment direction of the light source unit and the attachment unit.

Abstract: A light emitting module device includes: a power line through which power is supplied to light emitting modules; and a signal generation circuit which generates a control signal. The power line is shared by a plurality of the light emitting modules, and has switches and switches which turn on or off current conduction to the light emitting modules, through open/close operations. The signal generation circuit individually controls the switches and the switches. The open/close operations include a light-emission period in which the light emitting module emits light; and an extinction period in which the light emitting module is extinguished, and if there is a control signal to be transmitted to the light emitting module, the control signal is superimposed onto supply power. Since a control signal is superimposed onto supply power to each light emitting module, the light emitting modules can be individually controlled.

Abstract: A photoelectric converter in which an intermediate layer is provided between a first photoelectric-conversion-layer including a first p-type-semiconductor-layer and a first n-type-semiconductor-layer and a second photoelectric-conversion-layer including a second p-type-semiconductor-layer and a second n-type-semiconductor-layer. The intermediate layer includes an n-type-transparent conductive-oxide-film in contact with the first n-type-semiconductor-layer and a p-type-transparent-conductive oxide-film in contact with the second p-type-semiconductor-layer respectively having a bandgap equal to or higher than 1.5 electron volts.

Abstract: A light emitting device includes: a plurality of light emitting elements configured to emit light when a direct current is supplied thereto; and a direct current power supply circuit configured to supply an electric current of a given level or more to the light emitting elements. The light emitting device further includes: a light emitting element voltage detection circuit configured to detect a voltage applied to the light emitting elements; and a forward/reverse inverting circuit configured, when the light emitting element voltage detection circuit detects an abnormality in a light emitting element, to apply a reverse voltage to the light emitting element in which the abnormality is detected.

Abstract: A planar light-emitting module lighting circuit uses a lamp comprising an organic electroluminescence layer and electrodes sandwiching the organic electroluminescence layer as a load, and applies a current to the load so as to cause the organic electroluminescence layer to emit light. In the planer light-emitting module lighting circuit, a current at a lighting start time of the lamp is made small as compared with a current at a stationary lighting time at which a predetermined time period has passed since a lighting start.

Abstract: A photoelectric conversion device includes a front electrode, a photoelectric conversion layer formed of a semiconductor material, a transparent conductive layer formed of a transparent conductive oxide, a back electrode formed of a metal material, and a conductive layer formed of a semiconductor material primarily of silicon and having a refractive index higher than the transparent conductive layer contactually sandwiched between the transparent conductive layer and the back electrode. The photoelectric conversion device exhibits a high photoelectric conversion efficiency by keeping low the electrical resistance between the semiconductor layer and the back electrode and by increasing reflectance for light having passed though the semiconductor layer.

Abstract: A light control apparatus and a lighting appliance using the same enable increased luminous efficiency in light control and elongated operative life of a light source. The lighting appliance includes a light source and a light control apparatus. The light control apparatus comprises an electric current output circuit that outputs a constant electric current for lighting to a light source configured of an organic electroluminescence device, and a light control circuit that performs light control of the light source by intermittently supplying the constant electric current outputted from the electric current output circuit. The light control apparatus also comprises an electric discharge prevention circuit (diode) that prevents electric discharge of an electric charge charged in a capacitive component of the organic electroluminescence device.

Abstract: An illumination load determination device includes an illumination load; a voltage applying unit for applying a voltage to the illumination load; a connection unit for connecting the illumination load and the voltage applying unit; a detection unit for detecting at least one of a current flowing through the illumination load and a voltage across the illumination load when the voltage is applied to the illumination load from the voltage applying unit via the connection unit; and a determination unit for determining a type of the illumination load based on an output from the detection unit. The determination unit has a comparator for comparing a detection value detected by the detection unit to a predetermined threshold, and determines that the illumination load has a capacitance based on an output of the comparator. The voltage applying unit lights on the determined illumination load with a rated driving voltage.

Abstract: A discharge lamp lighting device includes: a power converting circuit including a step-down chopper circuit and a polarity inversion circuit configured to convert an output from the step-down chopper circuit to a rectangular-wave alternating-current voltage, and thus to apply the rectangular-wave alternating-current voltage to a discharge lamp; and a memory configured to store a history of an output from the power converting circuit in a previous stable lighting mode. A control circuit controls on and off of each of switching elements in the step-down chopper circuit and the polarity inversion circuit, and thereby changes the output from the power converting circuit in a predetermined time period after the lamp starts lighting until reaching a stable lighting state on the basis of the history stored in the memory, so that a rise of a lamp voltage is suppressed. This enables extension of the lifespan of the lamp and suppression of the occurrence of arc jump.

Abstract: It is an object to provide a light control apparatus and a lighting appliance using the same which enables to increase luminous efficiency in the light control. The lighting appliance includes a light source and a light control apparatus. The light control apparatus includes an electric current output circuit which outputs a constant electric current for lighting to a light source configured of an organic electroluminescence device, an electric current control circuit which controls an intensity of a driving electric current outputted from the electric current output circuit, and the electric current control circuit biases a direct current component so as to vary the driving electric current periodically between a predetermined maximum value and a predetermined minimum value and flows in the same direction at all times in the light control of the light source.

Abstract: A photoelectric converter in which an intermediate layer is provided between a first photoelectric-conversion-layer including a first p-type-semiconductor-layer and a first n-type-semiconductor-layer and a second photoelectric-conversion-layer including a second p-type-semiconductor-layer and a second n-type-semiconductor-layer. The intermediate layer includes an n-type-transparent conductive-oxide-film in contact with the first n-type-semiconductor-layer and a p-type-transparent-conductive oxide-film in contact with the second p-type-semiconductor-layer respectively having a bandgap equal to or higher than 1.5 electron volts.

Abstract: An organic electroluminescence (EL) module capable of reducing a processing loss of wiring boards for supplying power to an anode and a cathode is provided. Each wiring board (5) is formed by bending a strip conductor in a manner that parts of the strip in the same surface contacting each other, and is arranged on the outer periphery of the element substrate (2) in a manner of connecting the extended anode (31P) with the same pole and connecting the extended cathode (31M) with the same pole. In this manner, the wiring boards (5) having a width satisfying a shape of the electrodes without cutting a conductive plate into a U shape.

Abstract: A light emitting module device includes: a power line through which power is supplied to light emitting modules; and a signal generation circuit which generates a control signal. The power line is shared by a plurality of the light emitting modules, and has switches and switches which turn on or off current conduction to the light emitting modules, through open/close operations. The signal generation circuit individually controls the switches and the switches. The open/close operations include a light-emission period in which the light emitting module emits light; and an extinction period in which the light emitting module is extinguished, and if there is a control signal to be transmitted to the light emitting module, the control signal is superimposed onto supply power. Since a control signal is superimposed onto supply power to each light emitting module, the light emitting modules can be individually controlled.

Abstract: Provision of a light emitting device having functionality for restoring to normal even if a low-voltage error occurs, by temporarily applying a reverse current to a low-voltage error light emitting element using a direction inverting circuit, and repairing portions in which impedance has fallen by applying the current.

Abstract: A discharge lamp lighting device includes: a DC power source; an inverter for inverting the DC power at a predetermined inversion time interval to supply a square wave AC power to a discharge lamp; and a controller for controlling the output power. The controller performs a synchronous operation and controls the DC power source such that DC power outputted during a period other than the output temporarily increasing period in a power increasing period is greater than the DC output power outputted during the period other than the output temporarily increasing period in a rated power period. Further, the controller controls the DC power source such that at least one of an increment of the output power for the output temporarily increasing period and a length of the output temporarily increasing period is less in at least a part of the output increasing period than in the rated power period.

Abstract: A discharge lamp lighting device has an oscillation control circuit for determining a frequency with time constant of R and C, a L-C series resonant circuit connected to a half bridge or full bridge operating at the frequency and a circuit in which one end of hot cathodes at both ends of a hot cathode type discharge tube are respectively connected to both ends of a resonant capacitor. A capacitor is further connected in series to other ends of filaments at both ends of the discharge tube for lighting. Dimming of tube current is achieved by changing the oscillation frequency with a DC dimming control voltage by use of a variable capacitor or diode for determining the frequency of the oscillation control circuit. By simultaneously changing the tube current and a filament current of the discharge lamp, the tube current is decreased upon dimming and the filament current is increased.

Abstract: An illumination load determination device includes an illumination load; a voltage applying unit for applying a voltage to the illumination load; a connection unit for connecting the illumination load and the voltage applying unit; a detection unit for detecting at least one of a current flowing through the illumination load and a voltage across the illumination load when the voltage is applied to the illumination load from the voltage applying unit via the connection unit; and a determination unit for determining a type of the illumination load based on an output from the detection unit. The determination unit has a comparator for comparing a detection value detected by the detection unit to a predetermined threshold, and determines that the illumination load has a capacitance based on an output of the comparator. The voltage applying unit lights on the determined illumination load with a rated driving voltage.