Abstract: A method of fabricating an integrated BiCMOS circuit is provided, the circuit including bipolar transistors 10 and CMOS transistors 12 on a substrate. The method comprises the step of forming an epitaxial layer 28 to form a channel region of a MOS transistor and a base region of a bipolar transistor. Growing of the epitaxial layer includes growing a first sublayer of silicon 28a, a first sublayer of silicon-germanium 28b onto the first sublayer of silicon, a second sublayer of silicon 28c onto the first sublayer of silicon-germanium, and a second sublayer of silicon-germanium 28d onto the second sublayer of silicon. Furthermore, an integrated BiCMOS circuit is provided, which includes an epitaxial layer 28 as described above.

Abstract: A semiconductor light-emitting device includes a semiconductor light-emitting element including a first multilayer reflector, an active layer having a light-emitting region, and a second multilayer reflector in the stated order; a semiconductor light-detecting element disposed opposite the first multilayer reflector in relation to the semiconductor light-emitting element and including a light-absorbing layer configured to absorb light emitted from the light-emitting region; and an insulating oxidized layer disposed between the semiconductor light-emitting element and the semiconductor light-detecting element.

Abstract: Provided are a photodetector capable of suppressing variations in the output characteristics among photodiodes, and a display device provided with the photodetector. A display device in use has an active matrix substrate (20) including a transparency base substrate (2), a plurality of active elements and a photodetector. The photodetector includes a light-shielding layer (3) provided on one main surface of the base substrate (2), a photodiode (1) arranged on an upper layer of the light-shielding layer (3), and an electrode (12) arranged in the vicinity of the photodiode (1) on the upper layer of the light-shielding layer (3). The photodiode (1) includes a silicon layer (11), and the silicon layer (11) is insulated electrically from the light-shielding layer (3). The electrode (12) is insulated electrically from the light-shielding layer (3) and the silicon layer (11).

Abstract: There is provided a photonic crystal light emitting device including: a substrate; a plurality of nano rod light emitting structures formed on the substrate to be spaced apart from one another, each of the nano rod light emitting structures including a first conductivity type semiconductor layer, an active layer and a second conductivity type semiconductor layer; and first and second electrodes electrically connected to the first and second conductivity type semiconductor layers, respectively, wherein the nano rod light emitting structures are arranged with a predetermined size and period so as to form a photonic band gap for light emitted from the active layer, whereby the nano rod light emitting structures define a photonic crystal structure. In the photonic crystal light emitting device, the nano rod light emitting structures are arranged to define a photonic crystal to enhance light extraction efficiency.

Abstract: Provided are a photodetector capable of suppressing variations in the output characteristics among photodiodes, and a display device provided with the photodetector. A display device in use has an active matrix substrate (20) including a transparency base substrate (2), a plurality of active elements and a photodetector. The photodetector includes a light-shielding layer (3) provided on the base substrate (2), and a photodiode (1) arranged on an upper layer of the light-shielding layer (3). The light-shielding layer (3) is overlapped with the photodiode (1) in the thickness direction of the base substrate (2). The photodiode (1) includes a silicon layer (11) insulated electrically from the light-shielding layer (3). The silicon layer (11) includes a player (11c), an i-layer (11b) and an n-layer (11a) that are provided adjacent to each other in the planar direction. The p-layer (11c) is formed so that its area (length Lp) will be larger than the area (length Ln) of the n-layer (11a).

Abstract: Provided is an optical modulator having pixelization patterns. The optical modulator includes an optical-electric (O-E) conversion element converting input optical images to current signals using the photoelectric effect, and an electric-optical (E-O) conversion element that emits light using the current signals transferred from the O-E conversion element. Trenches are formed from at least a surface of the optical modulator to a predetermined depth in the optical modulator so as to block or reduce electrical interference between pixels when the electric signals are transferred from the O-E conversion element to the E-O conversion element.

Abstract: A backlight assembly that does not use a bottom chassis is presented. The absence of bottom chassis reduces manufacturing cost, simplifies the assembly process, and facilitates heat dissipation. The backlight assembly includes a lamp, a light guide plate, a mold frame and a securing mold. The lamp unit includes a lamp that generates light and a lamp cover that partially encloses the lamp. The light guide plate receives the light from the lamp unit and guides the light toward the front of the backlight assembly. The mold frame receives the lamp unit and the light guide plate through an open portion. The securing mold is coupled to the lamp unit and combines with the mold frame to secure the first lamp unit. The backlight assembly relies on one mold frame to hold its components together.

Abstract: An image sensor, in which, a planarized layer is formed on a semiconductor substrate including a pixel array region, an optical black region, and a logic region to cover a photo sensing unit array in the pixel array region, a patterned metal layer is formed on the planarized layer corresponding to the pixel array region and the logic region, but not the optical black region. An optical black layer is formed in the optical black region after a passivation layer is formed and before a color filter array is formed at a temperature less than about 400° C., and preferably contains metal material.

Abstract: Light emitting diode systems are disclosed. An optical display system that includes a light emitting diode (LED) and a cooling system is disclosed. The cooling system is configured so that, during use, the cooling system regulates a temperature of the light emitting diode.

Abstract: The present invention provides a highly stable light emitting device having high light-emitting efficiency (light-extraction efficiency) with high luminance and low power consumption, and a method of manufacturing thereof. A partition wall and a heat-resistant planarizing film are formed of a same material so as to be well-adhered to each other, thereby reducing material costs. Either an anode or a cathode is formed on the heat-resistant planarizing film. The partition wall and the heat-resistant planarizing film is adhered to each other without inserting a film having different refractive index therebetween, and therefore reflection of light is not caused in an interface.

Abstract: Double mold opto-coupler and method for manufacture. A first subassembly is formed that includes a light detector. The first subassembly is molded with a first mold material to form a molded first subassembly. A light source is attached to the molded first sub-assembly to form a second sub-assembly. The second sub-assembly is molded with a second mold material to form a final assembly with predetermined dimensions.

Abstract: Provided is a high-speed optical interconnection device. The high-speed optical interconnection device includes a first semiconductor chip, light emitters, optical detectors, and a second semiconductor chip, which are disposed on a silicon-on-insulator (SOI) substrate. The light emitters receive electrical signals from the first semiconductor chip to output optical signals. The optical detectors detect the optical signals to convert the optical signals into electrical signals. The second semiconductor chip receives the electrical signals converted by the optical detectors.

Abstract: A method includes placing a first bonding layer on at least one of a first functional region bonded on a release layer with a light releasable adhesive layer on a first substrate, and a transfer region on a second substrate; bonding the first functional region to the second substrate by the first bonding layer; irradiating the release layer with light with a light blocking member being provided to separate the first substrate from the first functional region at the release layer; placing a second bonding layer on at least one of a second functional region on the first substrate, and a transfer region on the release layer or a transfer region on a third substrate; bonding the second functional region to the second substrate or the third substrate by the second bonding layer; and separating the first substrate from the second functional region at the release layer.

Abstract: In a light emitting device and a fabricating method thereof are provide, wherein the light emitting device includes a light converting element, and a light emitting element positioned on the light converting element and including a first electrode, a light emitting structure and a second electrode, the first electrode formed on the light emitting element and having a first opening, the light emitting structure having a first conductive pattern of a first conductivity type, a light emitting pattern, and a second conductive pattern of a second conductivity type, which are sequentially stacked, and the second electrode formed on the second conductive pattern, wherein the light generated from the light emitting structure reaches the light converting element through the first opening.

Abstract: A method includes arranging a bonding layer of a predetermined thickness on at least one of a first functional region bonded on a release layer, which is capable of falling into a releasable condition when subjected to a process, on a first substrate, and a region, to which the first functional region is to be transferred, on a second substrate; bonding the first functional region to the second substrate through the bonding layer; and separating the first substrate from the first functional region at the release layer.

Abstract: An organic light emitting display device. The organic light emitting display device includes a substrate having a pixel region in which pixels are formed and a non-pixel region in which a light sensor is formed, an insulating film formed on the substrate, a first electrode formed on the insulating film and formed of a reflective material reflecting light, the first electrode being formed on the entire surface of the insulating film except for a region between the pixels and a region over the light sensor, a pixel defining film exposing a region of the first electrode and formed on the insulating film, an organic light emitting layer formed on the exposed region of the first electrode, and a second electrode formed on the organic light emitting layer. The first electrode is formed to have a greater area than that of the organic light emitting layer.

Abstract: A semiconductor device includes a substrate, a semiconductor layer formed on the substrate, and an optically functional portion formed by using at least a portion of the semiconductor layer. The optically functional portion performs light emission or light reception. The semiconductor device further includes a first driving electrode that is electrically connected to a semiconductor layer on a surface of the optically functional portion, and the first driving electrode drives the optically functional portion. The semiconductor device further includes an encapsulating electrode that is formed on the semiconductor layer to surround periphery of the optically functional portion, and electrically connected to the first driving electrode.

Abstract: In a light emitting apparatus using LEDs, luminance and chromaticity of the LED changes largely due to a temperature change. Meanwhile, by using phosphors, it is possible to improve the stability of the luminance and chromaticity against the temperature change. However, color reproducibility of the light emitting apparatus decreases. Therefore, the light emitting apparatus includes a first LED, a second LED, a first phosphor which is excited by the second LED and emits light whose color is the same as or similar to a color of light emitted from the first LED, and a control circuit which controls a ratio between an emission intensity of the first LED and an emission intensity of the second LED.

Abstract: In a thin film transistor and a flat panel display device having the same, cross-talk is minimized. The flat panel display device includes a substrate, a first thin film transistor, a second thin film transistor, and a display element. The first thin film transistor includes: a first gate electrode formed on the substrate; a first electrode insulated from the first gate electrode; a second electrode insulated from the first gate electrode and surrounding the first electrode in the same plane; and a first semiconductor layer insulated from the first gate electrode and contacting the first electrode and the second electrode.

Abstract: A system that facilitates high-speed data transfer between integrated circuit chips. The system contains a first integrated circuit chip, which includes a capacitive receiver and an electrical-to-optical transceiver. The capacitive receiver receives a capacitively coupled voltage signal transmitted from a corresponding capacitive transmitter located on a second integrated circuit chip and converts the capacitively coupled voltage signal into an electrical signal. The electrical-to-optical transceiver converts the electrical signal to an optical signal and transmits the optical signal to an optical device through optical coupling.

Abstract: A tamper-resistant semiconductor device (5;20;30;40;50;60) which includes a plurality of electronic circuits formed on a circuitry side (6) of a substrate (7) having an opposite side which is a backside (8) of the semiconductor device, and comprises at least one light-emitting device (9a-f;21) and at least one light-sensing device (10a-f;22a-b) provided on the circuitry side (6) of the semiconductor device. The light-emitting device (9a-f;21) is arranged to emit light, including a wavelength range for which the substrate (7) is transparent, into the substrate towards the backside (8), and the light-sensing device (10a-f;22a-b) is arranged to sense at least a fraction of the emitted light following passage through the substrate (7) and reflection at the backside (8), and configured to output a signal indicative of a reflecting state of the backside, thereby enabling detection of an attempt to tamper with the backside (8) of the semiconductor device (5;20;30;40;50;60).

Abstract: A light emitting device having a vertical structure and a method for manufacturing the same, which are capable of increasing light extraction efficiency, are disclosed. The method includes forming a light extraction layer on a substrate, forming a plurality of semiconductor layers on the light extraction layer, forming a first electrode on the semiconductor layers, forming a support layer on the first electrode, removing the substrate, and forming a second electrode on a surface from which the substrate is removed.

Abstract: An etching step is performed on an LED/substrate wafer to etch through the LED epitaxial layers entirely around each LED on the substrate wafer to form a gap between each LED on the wafer. The substrate is not etched. When the LEDs/substrates are singulated, edges of each substrate extend beyond edges of the LED die. The LEDs are flip-chips and are mounted on a submount with the LED die between the submount and the substrate. An insulating underfill material is injected under the LED die and also covers the sides of the LED die and “enlarged” substrate. The substrate is then removed by laser lift-off. The raised walls of the underfill that were along the edges of the enlarged substrate are laterally spaced from the edges of the LED die so that a phosphor plate can be easily positioned on top to the LED die with a relaxed positioning tolerance.

Abstract: A light emitting device (1) is provided and comprises a light emitting diode (2) and a self-supporting wavelength converting element (3) arranged to receive at least part of the light emitted by said light emitting diode (2). The wavelength converting element has a flat light receiving surface (4), a light output surface (5) and lateral edge surfaces (6), wherein said lateral edge surfaces (6) are provided with a reflecting material (7). The reflecting edge surfaces increases the color homogeneity of the light exiting the device and the device is suitable for mass production.

Abstract: An alphanumeric display includes a substrate that has top and bottom surfaces, a plurality of electrical contacts on the top surface, a plurality of light-emitting electronic devices mounted on the top surface, and a plurality of electrical pads on the bottom surface. The electrical contacts are connected to at least one light-emitting electronic device, and each of the light-emitting electronic devices is electrically connected with corresponding ones of the electrical contacts. The electrical pads are electrically connected to corresponding ones of the electrical contacts for communicating to the light-emitting electronic devices external sources of electrical power and control signals. The electrical pads on the bottom surface are arranged in a pattern to facilitate connections to the device using a conductive adhesive.

Abstract: A light emitting device having a circuit protection unit is provided. The circuit protection unit has a low-resistance layer and a potential barrier layer, wherein a barrier potential exists at the interface between the low-resistance layer and the potential barrier layer. The circuit protection unit is electrically connected with the light emitting device. When an electrostatic discharge or excessive forward current is occurred in the light emitting device, the circuit protection unit provides a rectifying function for preventing damages caused by static electricity or excessive forward current to the light emitting device.

Abstract: The light emitting device has a light emitting diode which is made of a nitride semiconductor and a phosphor which absorbs a part of lights emitted from the light emitting diode and emits different lights with wavelengths other than those of the absorbed lights. The phosphor is made of alkaline earth metal silicate fluorescent material activated with europium.

Abstract: A semiconductor device, particularly, a photoelectric conversion element having a semiconductor layer is demonstrated. The photoelectric conversion element of the present invention comprises, over a substrate, a photoelectric conversion layer and first and second electrodes which are electrically connected to the photoelectric conversion layer. The photoelectric conversion element further comprises a wiring board over which a third and fourth electrodes are provided. The characteristic point of the present invention is that a bonding layer, which readily forms an alloy with a conductive material, is formed over the first and second electrodes. This bonding layer improves the bonding strength between the first and third electrodes and the second and fourth electrode, which contributes to the prevention of the connection defect between the substrate and the wiring board and consequentially to high reliability of the photoelectric conversion element.

Abstract: A light emitting device having a plastic substrate is capable of preventing the substrate from deterioration with the transmission of oxygen or moisture content can be obtained. The light emitting device has light emitting elements formed between a lamination layer and an inorganic compound layer that transmits visual light, where the lamination layer is constructed of one unit or two or more units, and each unit is a laminated structure of a metal layer and an organic compound layer. Alternatively, the light emitting device has light emitting elements formed between a lamination layer and an inorganic compound layer that transmits visual light, where the lamination layer is constructed of one unit or two or more units, and each unit is a laminated structure of a metal layer and an organic compound layer, wherein the inorganic compound layer is formed so as to cover the end face of the lamination layer.

Abstract: An integrated circuit and method are provided for preventing reverse engineering by monitoring light emissions emitted from transistors and such electrically active devices in the integrated circuit. The method prevents, in an integrated circuit, a pattern of light emitted from at least one active device in the integrated circuit from being detected external to the integrated circuit by reduction of the intensity of light emitted from the at least one active device in the integrated circuit thereby preventing the reduced intensity light emitted from the at least one active device in the integrated circuit from being detected external to the integrated circuit. The intensity of light emitted from the at least one active device in the integrated circuit can be reduced by modification of operational characteristics of the at least one active device during switching transitions.

Abstract: An integrated circuit and method are provided for preventing reverse engineering by monitoring light emissions emitted from transistors and such electrically active devices in the integrated circuit. The method prevents, in an integrated circuit, a pattern of light emitted from at least one active device in the integrated circuit from being detected external to the integrated circuit by fading the light emitted from the at least one active device in the integrated circuit and that is emitted external to the integrated circuit. Bright light emission emitted in substantial close proximity to the at least one active device in the integrated circuit, and emitted external to the integrated circuit, fades a pattern of light emission emitted from the at least one active device.

Abstract: A photo sensor including a gate, a first insulator, a semiconductor layer, a first electrode pattern layer, a second electrode pattern layer, a second insulator and a transparent electrode is provided. The gate is disposed on the substrate. The first insulator covers the gate and a portion of the substrate. The semiconductor layer is disposed on the first insulator above the gate. Moreover, there is a space between the first electrode pattern layer and the second electrode pattern layer located on the semiconductor layer. The second insulator covers a portion of the semiconductor layer, the first electrode pattern layer and the second electrode pattern layer. The transparent electrode is disposed on the second insulator above the semiconductor layer and corresponds to the first electrode pattern layer. The transparent electrode is electrically connected to the first electrode pattern layer, and a portion of the transparent electrode is within the space.

Abstract: A light emitting device firstly includes a light emitting diode (LED) structure, having a top surface with a light emitting region. The device also has a heterojunction within the device structure, the heterojunction having a p-type and an n-type semiconductor layer, and a plurality of electrodes positioned on the top surface, each being electrically connected to one of the p-type and n-type semiconductor layers. At least a first and a second electrodes are connected to a same type semiconductor layer and are physically separated from each other. The device further includes a first and a second heterojunction regions within the heterojunction, each being respectively defined between one of the first and second electrodes and one of the other electrodes connected to the other type semiconductor layer. The first and second heterojunction regions are alternatively driven for emitting lights in the time domain.

Abstract: A low form-factor transceiver system appropriate for long-reach optical communications is presented. In accordance with the present invention, an electronic interface to a receiver optical sub assembly (ROSA) and a transmitter optical sub assembly (TOSA) is arranged on a multi-layer board to electrically shield the transmitter and receiver portions from a high-voltage power supply, which is utilized to provide bias voltages to optical detectors in the ROSA. In some embodiments of the invention, the high-voltage power supply is arranged on a top layer while the transmitter and receiver are arranged on a bottom layer in a split-ground arrangement. Layers between the top layer and the bottom layer include at least one ground plane and provide vias for electrical connections.

Abstract: A laser and electroabsorption modulator (EAM) are monolithically integrated through an etched facet process. Epitaxial layers on a wafer include a first layer for a laser structure and a second layer for an EAM structure. Strong optical coupling between the laser and the EAM is realized by using two 45-degree turning mirrors to route light vertically from the laser waveguide to the EAM waveguide. A directional angled etch process is used to form the two angled facets.

Abstract: In a process of manufacturing elements of different structures and characteristics on the same substrate at the same time, the number of steps is increased and complicated. In view of this, the invention provides a semiconductor device and a manufacturing process thereof in which elements of different structures are formed on the same substrate while reducing the number of steps. According to the invention, in accordance with a memory transistor that requires the largest number of steps when being formed among elements that forms a semiconductor memory device, other high speed transistor and high voltage transistor are efficiently manufactured. Thus, the number of steps is suppressed and a low cost semiconductor memory device can be manufactured.

Abstract: A semiconductor body (2), comprising a semiconductor layer sequence with an active region (3) suitable for generating radiation. The semiconductor layer sequence comprises two contact layers (6, 7), between which the active region is arranged. The contact layers are assigned a respective connection layer (12, 13) arranged on the semiconductor body. The respective connection layer is electrically conductively connected to the assigned contact layer. The respective connection layer is arranged on that side of the assigned contact layer which is remote from the active region. The connection layers are transmissive to the radiation to be generated in the active region, and the contact layers are of the same conduction type.

Abstract: The present invention relates to an LED package including photo diode. The LED package includes a silicon substrate, and a photo diode is formed in an upper part thereof. Also, an insulation layer is formed on the silicon substrate excluding at least a light-receiving area of the photodiode. In the LED package, an LED terminal is formed on the insulation layer to be connected to the photo diode. First and second LED connecting pads are formed on the insulation layer, and arranged on both sides of the photo diode. In addition, an LED chip is mounted on the silicon substrate, and connected to the first and second LED connecting pads.

Abstract: A LED driver IC includes a control module(s) for controlling one or more LED drive parameters and non-volatile memory for storing settings data for that control module(s). The control module(s) is fully integrated into the LED driver IC and does not require any control input from off-chip components or signals. Therefore, the space requirements for LED circuits that make use of the LED driver IC can be minimized. Also, the non-volatile memory storage of settings data eliminates the need for an initialization or configuration input each time the LED driver IC is powered on. The non-volatile memory can be a one-time programmable memory or can be a reprogrammable memory.

Abstract: Methods and systems are provided for LED modules that include an LED die integrated in an LED package with a submount that includes an electronic component for controlling the light emitted by the LED die. The electronic component integrated in the submount may include drive hardware, a network interface, memory, a processor, a switch-mode power supply, a power facility, or another type of electronic component.

Abstract: A light emitting apparatus includes a light emitting element formed on a surface of a substrate and a light receiving element formed on an area other than an area overlapping the light emitting element on the surface of the substrate, the light receiving element detecting light emitted from the light emitting element.

Abstract: A surface mountable device having a circuit device and a base section. The circuit device includes top and bottom layers having a top contact and a bottom contact, respectively. The base section includes a substrate having a top base surface and a bottom base surface. The top base surface includes a top electrode bonded to the bottom contact, and the bottom base surface includes first and second bottom electrodes that are electrically isolated from one another. The top electrode is connected to the first bottom electrode, and the second bottom electrode is connected to the top contact by a vertical conductor. An insulating layer is bonded to a surface of the circuit device and covers a portion of a vertical surface of the bottom layer. The vertical conductor includes a layer of metal bonded to the insulating layer.

Abstract: A main object of the present invention is to provide a static induction light emitting transistor having an organic EL element structure and a vertical FET structure which is possible to avoid a problem of the shielding of light and a problem of shielding of electric field by a gate electrode. The above object is achieved by providing a light emitting transistor 11 of a vertical FET structure comprising: on a substrate 12; a source electrode 13; a hole transporting layer 14 in which a slit-shaped gate electrode 15 is embedded; an equipotential layer 16; light emitting layer 17; and a transparent or semitransparent drain electrode 18, provided in this order. In this light emitting transistor, the drain electrode 18 provided on the opposite side of the gate electrode 15, viewing from the light emitting layer 17, is transparent or semitransparent. Therefore, light generated in the light emitting layer 17 can be taken out from the drain electrode side.

Abstract: A photo detector is disclosed. The photo detector has a substrate, a semiconductor layer disposed on the substrate, an insulating layer covered on the semiconductor layer, an interlayer dielectric layer covered on the insulating layer, and two electrodes formed on a portion of the interlayer dielectric layer. The semiconductor layer has a first doping region, a second doping region, and an intrinsic region located between the first doping region and the second doping region. The interlayer dielectric layer has at least three holes to expose a portion of the insulating layer, a portion of the first doping region, and the second doping region. The electrodes are connected to the first doping region and the second doping region through two of the holes.

Abstract: Solved is a problem of attenuation of output amplitude due to a threshold value of a TFT when manufacturing a circuit with TFTs of a single polarity. In a capacitor (105), a charge equivalent to a threshold value of a TFT (104) is stored. When a signal is inputted thereto, the threshold value stored in the capacitor (105) is added to a potential of the input signal. The thus obtained potential is applied to a gate electrode of a TFT (101). Therefore, it is possible to obtain the output having a normal amplitude from an output terminal (Out) without causing the amplitude attenuation in the TFT (101).

Abstract: Provided is a reflection type optical sensor device including: a semiconductor light source being formed by providing a light emitting region on a predetermined region of a substrate; and a photo-detection element being integrated on the same substrate as the substrate where the semiconductor light source is formed to surround an outer circumferential surface of the semiconductor light source, and including a light receiving region. When the light emitted from the semiconductor light source is reflected by an external object, the photo-detection element may detect the light to sense the object. Through this, it is possible to reduce cost and ensure a small size. Also, the photo-detection element is constructed to surround the outer circumferential surface of the semiconductor light source, and thus more accurately detect the light.

Abstract: In a light emitting device using a light emitting element, the invention provides a sealing structure capable of preventing ingress of moisture from the outside and obtaining adequate reliability. The light emitting device has a light emitting element comprising a light emitting layer formed between a first electrode and a second electrode and a pixel portion comprising the light emitting element. The entire surface of the pixel portion is covered with the second electrode. An impermeable insulating film is formed in contact with the first electrode of the light emitting element. The edge of the first electrode and the impermeable insulating film are covered with a partition wall. An opening is formed along the circumference of the pixel portion in the partition wall. The opening passes through the partition wall in the thickness direction, and the side wall and the bottom face thereof are covered with the second electrode.

Abstract: In one exemplary embodiment, a light emitting module includes a LED chip, a solar cell unit, and an interconnecting electrode. The LED chip includes a first P type semiconductor layer. The solar cell unit includes a second P type semiconductor layer. The interconnecting electrode is sandwiched between the first and second P type semiconductor layers. The interconnecting electrode electrically couples the solar cell unit to the LED chip.

Abstract: A method for an electronic device is provided for preventing reverse engineering by monitoring light emissions emitted from transistors and such electrically active devices in the electronic device. The method emits extraneous randomized light emissions in substantial close proximity to the transistors to hide a pattern of light emissions emitted from the transistors. As one feature, the device can include a source of randomized light emissions in substantial close proximity to the transistors to hide a pattern of the emitted light from the transistors in randomized light emissions emitted by the source. As a second feature, the device can emit the randomized light emissions by randomly delaying an electrical signal that is electrically coupled to the transistors and, in response to the randomly delayed electrical signal, the transistors randomly emitting light emissions thereby hiding a separate pattern of light emission emitted from the transistors.

Abstract: A pixel having a well-isolated charge storage region or floating diffusion region may be obtained by providing a separate P-well around the storage region or floating diffusion region. In one embodiment, a separate P-well entirely encases the storage region and is in contact with the storage region. This P-well provides an electrical barrier for preventing electrons that are generated elsewhere in the pixel from contaminating the storage region. In another embodiment, a first separate P-well encases and is in contact with the storage region and a second separate P-well encases and is in contact with the floating diffusion region.