Abstract: An optical waveguide in a semiconductor material, may include, between two adjacent portions of the waveguide, a plurality of parallel strips of alternating conductivity types forming a plurality of opposing bipolar junctions between the two adjacent portions.

Abstract: A semiconductor electro-optical phase shifter may include an optical action zone configured to be inserted in an optical waveguide, and a bipolar transistor structure configured so that, in operation, collector current of the bipolar transistor structure crosses the optical action zone perpendicular to the axis of the optical waveguide.

Abstract: The present disclosure relates to a photodiode comprising: a P-conductivity type substrate region, an electric charge collecting region for collecting electric charges appearing when a rear face of the substrate region receives light, the collecting region comprising an N-conductivity type region formed deep in the substrate region, an N-conductivity type read region formed in the substrate region, and an isolated transfer gate, formed in the substrate region in a deep isolating trench extending opposite a lateral face of the N-conductivity type region, next to the read region, and arranged for receiving a gate voltage to transfer electric charges stored in the collecting region toward the read region.

Abstract: A semiconductor electro-optical phase shifter may include a substrate, an optical waveguide segment (12) formed on the substrate, and first and second zones of opposite conductivity types configured to form a first bipolar junction perpendicular to the substrate. The phase shifter may also include a dynamic control structure configured to reverse bias the first junction and a static control structure configured to direct a quiescent current in the second zone, parallel to the first junction.

Abstract: An optical modulator uses an optoelectronic phase comparator configured to provide, in the form of an electrical signal, a measure of a phase difference between two optical waves. The phase comparator includes an optical directional coupler having two coupled channels respectively defining two optical inputs for receiving the two optical waves to be compared. Two photodiodes are configured to respectively receive the optical output powers of the two channels of the directional coupler. An electrical circuit is configured to supply, as a measure of the optical phase shift, an electrical signal proportional to the difference between the electrical signals produced by the two photodiodes.

Abstract: A method for simulating, in an electrical device simulator, electrical behavior of an integrated diode is described. The diode is modelled using a compact model in the electrical device simulator to determine the electrical behavior of the diode in a given situation. The modelling includes modelling a series resistance relating to the active regions and to the connections, modelling a PN junction of the diode, and modelling a well resistance for positive values of a current passing through the diode involving a conductivity modulation model. The method further includes modelling of the well resistance for negative values of the current by a curve which increases steeply from an initial resistance value corresponding to a zero value of current up to a plateau.

Abstract: An ESD protection device for an electro-optical device may include an optical waveguide segment being in semiconductor material and including a central zone of a first conductivity type, and first and second wings of a second conductivity type different from the first conductivity type and being integral with the central zone. The ESD protection device may include a first conduction terminal on the first wing for defining a first protection terminal, a second conduction terminal on the second wing for defining a second protection terminal, and a resistive contact structure of the first conductivity type having a transverse arm integral with the central zone, and an end in ohmic contact with the first conduction terminal, the resistive contact structure being electrically insulated from the first wing.

Abstract: An electro-optical phase shifter to be located in an optical waveguide may include a rib of a semiconductor material extending along a length of the optical waveguide and a control structure configured to modify a concentration of carriers in the rib according to a control voltage present between first and second control terminals of the phase shifter. The control structure may include a conductive layer covering a portion of the rib and electrically connected to a first of the control terminals. An insulating layer may be configured to electrically isolate the conductive layer from the rib.

Abstract: A semiconductor electro-optical phase shifter may include an optical action zone configured to be inserted in an optical waveguide, and a bipolar transistor structure configured so that, in operation, collector current of the bipolar transistor structure crosses the optical action zone perpendicular to the axis of the optical waveguide.

Abstract: An optical modulator uses an optoelectronic phase comparator configured to provide, in the form of an electrical signal, a measure of a phase difference between two optical waves. The phase comparator includes an optical directional coupler having two coupled channels respectively defining two optical inputs for receiving the two optical waves to be compared. Two photodiodes are configured to respectively receive the optical output powers of the two channels of the directional coupler. An electrical circuit is configured to supply, as a measure of the optical phase shift, an electrical signal proportional to the difference between the electrical signals produced by the two photodiodes.

Abstract: An electro-optical phase shifter to be located in an optical waveguide may include a rib of a semiconductor material extending along a length of the optical waveguide and a control structure configured to modify a concentration of carriers in the rib according to a control voltage present between first and second control terminals of the phase shifter. The control structure may include a conductive layer covering a portion of the rib and electrically connected to a first of the control terminals. An insulating layer may be configured to electrically isolate the conductive layer from the rib.

Abstract: The present disclosure relates to a photodiode comprising: a P-conductivity type substrate region, an electric charge collecting region for collecting electric charges appearing when a rear face of the substrate region receives light, the collecting region comprising an N-conductivity type region formed deep in the substrate region, an N-conductivity type read region formed in the substrate region, and an isolated transfer gate, formed in the substrate region in a deep isolating trench extending opposite a lateral face of the N-conductivity type region, next to the read region, and arranged for receiving a gate voltage to transfer electric charges stored in the collecting region toward the read region.

Abstract: The electric behavior of a reverse-biased PN junction diode is modeled by measuring the value of voltage V present across the diode and the value of the corresponding current I running through this diode, the voltage V varying within a range of values including the value of diode breakdown voltage. A representation of a function ln ? ( I - I s ) according to voltage V is established from the measured values of current I and of voltage V, IS being the saturation current of the diode. A linear function representative of a substantially linear portion of the function, characterized by voltages V greater than breakdown voltage VBK in terms of absolute value, is determined. An avalanche multiplication factor MM is then calculated by MM = 1 + ? ( - slbv · V + bv bv ) , with parameter slbv equal to the ordinate at the origin of the linear function, and parameter slbv/bv equal to the slope of the linear function.

Abstract: A semiconductor electro-optical phase shifter comprises a central zone (I1, I2) having a minimum doping level; first and second lateral zones (N+, P+) flanking the central zone along a first axis, respectively N and P-doped, so as to form a P-I-N junction between the first and second lateral zones. The central zone comprises first and second optical action zones (I1, I2) separated along the first axis. The second lateral zone is doped discontinuously along a second axis perpendicular to the first axis. Two electrical control terminals (A, C) are provided, one in contact with the first lateral zone, and the other in contact with doped portions of the second lateral zone.

Abstract: A semiconductor electro-optical phase shifter may include a first optical action zone having a minimum doping level, a first lateral zone and a central zone flanking the first optical action zone along a first axis, doped respectively at first and second conductivity types so as to form a P-I-N junction between the first lateral zone and the central zone. The phase shifter may include a second optical action zone having a threshold doping level, and a second lateral zone flanking the second optical action zone with the central zone along the first axis doped at the first conductivity type so as to form a P-I-N junction between the second lateral zone and the central zone.

Abstract: A model for simulating the electrical behavior of a thyristor includes a model of an NPN bipolar transistor whose emitter forms the cathode of the thyristor and the base forms a low-side control terminal of the thyristor, and a model of a PNP bipolar transistor whose emitter forms the anode of the thyristor and the base forms a high-side control terminal of the thyristor, the collector of the PNP transistor being connected to the low-side control terminal and the collector of the NPN transistor being connected to the high-side control terminal. The transistor models are present a small signal behavior over the entire range of anode currents of the thyristor, whereby the transistor models exhibit a gain drop when the anode current exits the small signal range.

Abstract: The present disclosure relates to a photodiode comprising: a P-conductivity type substrate region, an electric charge collecting region for collecting electric charges appearing when a rear face of the substrate region receives light, the collecting region comprising an N-conductivity type region formed deep in the substrate region, an N-conductivity type read region formed in the substrate region, and an isolated transfer gate, formed in the substrate region in a deep isolating trench extending opposite a lateral face of the N-conductivity type region, next to the read region, and arranged for receiving a gate voltage to transfer electric charges stored in the collecting region toward the read region.

Abstract: A semiconductor electro-optical phase shifter may include a substrate, an optical waveguide segment (12) formed on the substrate, and first and second zones of opposite conductivity types configured to form a first bipolar junction perpendicular to the substrate. The phase shifter may also include a dynamic control structure configured to reverse bias the first junction and a static control structure configured to direct a quiescent current in the second zone, parallel to the first junction.

Abstract: A thyristor may include a first optical waveguide segment in a semiconductor material, having first and second complementary longitudinal parts of opposite conductivity types configured to form a longitudinal bipolar junction therebetween. The thyristor may further include a second optical waveguide segment in a semiconductor material, adjacent the first waveguide segment and having first and second complementary longitudinal parts of opposite conductivity types configured to form a longitudinal bipolar junction therebetween. A transverse bipolar junction may be between the second longitudinal portions of the first and second waveguide segments. An electrical insulator may separate each of the first longitudinal portions from the waveguide segment adjacent thereto.

Abstract: An optical waveguide in a semiconductor material, may include, between two adjacent portions of the waveguide, a plurality of parallel strips of alternating conductivity types forming a plurality of opposing bipolar junctions between the two adjacent portions.