Abstract: A pixel includes, on a first face, first trenches extending parallel to a first direction and regularly spaced in a second direction (orthogonal to the first direction) and second trenches extending parallel to the second direction and regularly spaced in the first direction. The first trenches include first notches, each first notch extending from a first trench and being aligned with a corresponding second trench. The second trenches include second notches, each second notch extending from a second trench and being aligned with a corresponding first trench.

Abstract: A photodiode is formed in a semiconductor substrate of a first conductivity type. The photodiode includes a first region having a substantially hemispherical shape and a substantially hemispherical core of a second conductivity type, different from the first conductivity type, within the first region. An epitaxial layer covers the semiconductor substrate and buries the first region and core.

Abstract: The present disclosure relates to a process to control an optoelectronic device comprising a single-photon avalanche diode n a substrate, wherein the diode comprises a first region doped with a first type of conductivity level with a first face of the substrate and a second region doped with a second type of conductivity extending from the first face to a second face of the substrate opposed to the first face, wherein the device comprises a third conducting or semiconducting region at the second face, wherein the process comprises the application of a biasing voltage to the third region in order to generate an electric field that accelerates the charges generated in the diode.

Abstract: Devices, methods, and systems for detecting a fault in an electrical power system which includes a source-side converter in communication with a load-side converter via a transmission line. An output current from the source-side converter to the load-side converter over the transmission line is measured during a time period from a beginning of a first current pulse of the output current to a beginning of a second current pulse of the output current. An output voltage of the source-side converter is reduced, responsive to a profile of the output current differing from an expected profile of the output current during the time period. In some implementations, the expected profile of the output current includes a current limit, and the output current differs from the expected profile by exceeding the current limit during the first current pulse.

Abstract: The present disclosure relates to a pixel comprising: a photodiode comprising a portion of a substrate of a semiconductor material, extending vertically from a first face of the substrate to a second face of the substrate configured to receive light; a layer of a first material covering each of the lateral surfaces of the portion; a layer of a second material covering the portion on the side of the first face, first and second material having refractive indexes lower than that of the semiconductor material; and a diffractive structure disposed on a face of the photodiode on the side of the second face.

Abstract: The present disclosure relates to an avalanche photodiode pixel including: a transistor adapted to be controlled by an enable signal having a first state for controlling the enabling of the pixel and a second state for controlling the disabling of the pixel, the transistor being configured to couple an avalanche photodiode of the pixel to a node of application of a substrate voltage when the enable signal is in the first state; and an output circuit adapted to be controlled by the enable signal and configured to provide a pixel output signal when the enable signal is in the first state and to block the pixel output signal when the enable signal is in the second state.

Abstract: A method for fabricating a semiconductor chip includes forming a plurality of conducting pads at a front face of a substrate, thinning a rear face of the substrate, etching openings under each conducting pad from the rear face, depositing a layer of a dielectric on walls and a bottom of the openings, forming a conducting material in the openings, and forming a conducting strip on the rear face. The conducting strip is electrically connected to the conducting material of each of the openings. The etching is stopped when the respective conducting pad is reached.

Abstract: A photodiode is formed in a semiconductor substrate of a first conductivity type. The photodiode includes a first region having a substantially hemispherical shape and a substantially hemispherical core of a second conductivity type, different from the first conductivity type, within the first region. An epitaxial layer covers the semiconductor substrate and buries the first region and core.

Abstract: The present disclosure relates to a pixel comprising: a photodiode comprising a portion of a substrate of a semiconductor material, extending vertically from a first face of the substrate to a second face of the substrate configured to receive light; a layer of a first material covering each of the lateral surfaces of the portion; a layer of a second material covering the portion on the side of the first face, first and second material having refractive indexes lower than that of the semiconductor material; and a diffractive structure disposed on a face of the photodiode on the side of the second face.

Abstract: In a line to line fault detection and protection system, a source end power supply supplies power to a remote load over a transmission line and monitors the dynamic behavior of a transmission line power characteristic. If that dynamic behavior is outside a constraint that is actively imposed on the transmission line dynamic behavior by a load end power conditioning system, a possible line to line fault is recognized. The preferred power characteristic is current and the preferred constraint is a maximum rate of change of current drawn from the transmission line by the load end power conditioning system.

Abstract: An integrated circuit includes a high-voltage MOS (HV) transistor and a capacitor supported by a semiconductor substrate. A gate stack of the HV transistor includes a first insulating layer over the semiconductor layer and a gate electrode formed from a first polysilicon. The capacitor includes a first electrode made of the first polysilicon and a second electrode made of a second polysilicon and at least partly resting over the first electrode. A first polysilicon layer deposited over the semiconductor substrate is patterned to form the first polysilicon of the gate electrode and first electrode, respectively. A second polysilicon layer deposited over the semiconductor substrate is patterned to form the second polysilicon of the second electrode. Silicon oxide spacers laterally border the second electrode and the gate stack of the HV transistor. Silicon nitride spacers border the silicon oxide spacers.

Abstract: A photodiode is formed in a semiconductor substrate of a first conductivity type. The photodiode includes a first region having a substantially hemispherical shape and a substantially hemispherical core of a second conductivity type, different from the first conductivity type, within the first region. An epitaxial layer covers the semiconductor substrate and buries the first region and core.

Abstract: The present disclosure relates to a device that includes a photodiode having a first terminal that is coupled by a resistor to a first rail configured to receive a high supply potential and a second terminal that is coupled by a switch to a second rail configured to receive a reference potential. A read circuit is configured to provide a pulse when the photodiode enters into avalanche, and a control circuit is configured to control an opening of the switch in response to a beginning of the pulse and to control a closing of the switch in response to an end of the pulse.

Abstract: The present disclosure relates to a pixel comprising: a photodiode comprising a portion of a substrate of a semiconductor material, extending vertically from a first face of the substrate to a second face of the substrate configured to receive light; a layer of a first material covering each of the lateral surfaces of the portion; a layer of a second material covering the portion on the side of the first face, first and second material having refractive indexes lower than that of the semiconductor material; and a diffractive structure disposed on a face of the photodiode on the side of the second face.

Abstract: A method for fabricating a semiconductor chip includes forming a plurality of conducting pads at a front face of a substrate, thinning a rear face of the substrate, etching openings under each conducting pad from the rear face, depositing a layer of a dielectric on walls and a bottom of the openings, forming a conducting material in the openings, and forming a conducting strip on the rear face. The conducting strip is electrically connected to the conducting material of each of the openings. The etching is stopped when the respective conducting pad is reached.

Abstract: In a line to line fault detection and protection system, a source end power supply supplies power to a remote load over a transmission line and monitors the dynamic behavior of a transmission line power characteristic. If that dynamic behavior is outside a constraint that is actively imposed on the transmission line dynamic behavior by a load end power conditioning system, a possible line to line fault is recognized. The preferred power characteristic is current and the preferred constraint is a maximum rate of change of current drawn from the transmission line by the load end power conditioning system.

Abstract: A semiconductor chip includes at least two insulated vias passing through the chip from the front face to the rear face in which, on the side of the rear face, the vias are connected to one and the same conducting strip and, on the side of the front face, each via is separated from a conducting pad by a layer of a dielectric.

Abstract: The present disclosure relates to a device that includes a photodiode having a first terminal that is coupled by a resistor to a first rail configured to receive a high supply potential and a second terminal that is coupled by a switch to a second rail configured to receive a reference potential. A read circuit is configured to provide a pulse when the photodiode enters into avalanche, and a control circuit is configured to control an opening of the switch in response to a beginning of the pulse and to control a closing of the switch in response to an end of the pulse.

Abstract: An integrated circuit includes a high-voltage MOS (HV) transistor and a capacitor supported by a semiconductor substrate. A gate stack of the HV transistor includes a first insulating layer over the semiconductor layer and a gate electrode formed from a first polysilicon. The capacitor includes a first electrode made of the first polysilicon and a second electrode made of a second polysilicon and at least partly resting over the first electrode. A first polysilicon layer deposited over the semiconductor substrate is patterned to form the first polysilicon of the gate electrode and first electrode, respectively. A second polysilicon layer deposited over the semiconductor substrate is patterned to form the second polysilicon of the second electrode. Silicon oxide spacers laterally border the second electrode and the gate stack of the HV transistor. Silicon nitride spacers border the silicon oxide spacers.

Abstract: An integrated circuit includes a high-voltage MOS (HV) transistor and a capacitor supported by a semiconductor substrate. A gate stack of the HV transistor includes a first insulating layer over the semiconductor layer and a gate electrode formed from a first polysilicon. The capacitor includes a first electrode made of the first polysilicon and a second electrode made of a second polysilicon and at least partly resting over the first electrode. A first polysilicon layer deposited over the semiconductor substrate is patterned to form the first polysilicon of the gate electrode and first electrode, respectively. A second polysilicon layer deposited over the semiconductor substrate is patterned to form the second polysilicon of the second electrode. Silicon oxide spacers laterally border the second electrode and the gate stack of the HV transistor. Silicon nitride spacers border the silicon oxide spacers.