CPC Class H04N

A back-side illumination image capturing apparatus includes a semiconductor substrate having a first surface for receiving incident light and a second surface located on the opposite side as the first surface, and including a photoelectric conversion portion, and a gate electrode disposed above the second surface. The apparatus further includes a first insulating layer disposed above the second surface of the semiconductor substrate, an interlayer insulation film disposed on the first insulating layer, a contact plug connected to the gate electrode, and a light-cutting portion for cutting light, of the incident light, that has passed through the photoelectric conversion portion. The light-cutting portion passes through at least part of the interlayer insulation film. The first insulating layer is located between the light-cutting portion and the semiconductor substrate.

An image sensor having active, peripheral and dummy regions is provided as follows. A dummy through electrode is disposed in the substrate. An active through electrode is disposed in the substrate. An insulation structure in which a color filter is embedded is disposed on the substrate. A dummy bottom electrode is disposed on the insulation structure and connected electrically to the dummy through electrode. An active bottom electrode is disposed on the insulation structure and connected electrically to the active through electrode. A photoelectric conversion layer is disposed on the insulation structure. A top electrode is disposed on the photoelectric conversion layer and the dummy bottom electrode. The top electrode is connected electrically to the dummy bottom electrode. The photoelectric conversion layer is interposed between the top electrode and the active bottom electrode which are separated from each other.

This solid-state imaging device 100 has: a photosensitive part that includes pixel portions 211, which are disposed in a matrix, and charge transfer parts 212 for transferring, by the column, the signal charge of the pixel portions; a plurality of charge storage parts 220 that accumulate the signal charges transferred by the plurality of charge transfer parts of the photosensitive part; a relay part 240 that relays the transfer of the signal charges transferred by the plurality of charge transfer parts to each charge storage part; an output part 230 that outputs the signal charges of the plurality of charge storage parts as electric signals; a first substrate 110 at which the photosensitive unit 210 is formed; and a second substrate 120 at which the charge storage part 220 and output unit 230 are formed. The first substrate and second substrate are stacked together, and the relay part 240 electrically couples the charge transfer parts of the first substrate to the charge storage parts of the second substrate by means of a connecting parts passing through the substrates outside the photosensitive region of the photosensitive part.

A system for dynamically adjusting a bias voltage for a laser diode or a light emitting diode is provided. An output voltage of the laser diode is measured and a level of a supply voltage applied to the laser diode is adjusted to change the bias voltage to the laser diode to manage power usage and avoid saturation of the laser diode. Also, a junction temperature of a laser diode may be estimated by mapping a measured output voltage and known current to device characteristic data based on temperature and the supply voltage adjusted in order to bias the laser diode to compensate for a temperature change. Further, data indicating an intensity level of data to be rendered by the laser diode is used to adjust the second supply voltage to bias the laser diode in advance of rendering the data.