Abstract: The present invention relates in one aspect to an auxiliary charge pump for a RFID rectifier, the charge pump, which comprises a first charge pump stage (11; 111) connected to an input (14; 114), a second charge pump stage (12; 112) connected to the input, a diode clamp (13; 113) connected to an output (15; 115), and a regulating transistor (16; 116) having a gate connected with an output (21; 121) of the first charge pump stage and having a source and a drain, wherein one of the source and the drain is coupled to the diode clamp. In further aspects the invention relates to a RFID transponder, to a multistage rectifier and to a rectifier stage comprising such an auxiliary charge pump.

Abstract: The present invention relates in one aspect to an auxiliary charge pump for a RFID rectifier, the charge pump, which comprises a first charge pump stage (11; 111) connected to an input (14; 114), a second charge pump stage (12; 112) connected to the input, a diode clamp (13; 113) connected to an output (15; 115), and a regulating transistor (16; 116) having a gate connected with an output (21; 121) of the first charge pump stage and having a source and a drain, wherein one of the source and the drain is coupled to the diode clamp. In further aspects the invention relates to a RFID transponder, to a multistage rectifier and to a rectifier stage comprising such an auxiliary charge pump.

Abstract: The present invention relates to a transponder, which comprises an antenna and a multi-stage rectifier. The antenna is connected to an input of the multi-stage rectifier having m rectifier stages, and a shunt limiter is connected to an output of the rectifier and connected to an nth stage of the multi-stage rectifier, wherein n<m.

Abstract: The present invention relates to a transponder, which comprises an antenna and a multi-stage rectifier. The antenna is connected to an input of the multi-stage rectifier having m rectifier stages, and a shunt limiter is connected to an output of the rectifier and connected to an nth stage of the multi-stage rectifier, wherein n<m.

Abstract: The voltage regulator comprises a regulation loop (2), which comprises at least a pass transistor (18), a source transistor (28), a sensing transistor (22) and a retention transistor (24), and a stability compensation circuit (10), which comprises a first MOS resistor (12) and a second MOS resistor (14) coupled with the first MOS resistor (12). The gate of the second MOS resistor (14) is coupled to the gate of the pass transistor (18).

Abstract: The voltage regulator comprises a regulation loop (2), which comprises at least a pass transistor (18), a source transistor (28), a sensing transistor (22) and a retention transistor (24), and a stability compensation circuit (10), which comprises a first MOS resistor (12) and a second MOS resistor (14) coupled with the first MOS resistor (12). The gate of the second MOS resistor (14) is coupled to the gate of the pass transistor (18).

Abstract: It is described a method for measuring the movement of an optical pointing device on a work surface, which includes a pixel photo-detector array to pick-up reflected light on the work surface, a window comparator array receiving pixel voltages and providing comparison signals to a processing circuit. Light intensity between neighboring pixels is compared to determine edge direction data, which includes a positive edge for a first pixel voltage smaller than a second pixel voltage by more than a half of a window voltage, a no-edge, with the difference between the pixel voltages smaller than the half of the window voltage, and a negative edge, for which the first pixel voltage is greater than the second pixel voltage by more than the half of the window voltage. Two edge direction data from two successive flash are compared to determine the relative motion of the pointing device on the work surface.

Abstract: A method for operating an optical sensing device having a light source and a photodetector device with at least one photosensitive element, said method comprising the steps of: (i) illuminating a surface portion with radiation by means of said light source; (ii) detecting radiation reflected from the illuminated surface portion with said at least one photosensitive element; (iii)while said surface portion is being illuminated, integrating an output signal of said at least one photosensitive element over time; (iv)comparing the output signal integration level with a first integration reference level during integration; (v) interrupting said integration step (iii) if said output signal integration level has reached said first integration reference level, or getting back to comparison step (iv) until a first integration period has elapsed if said output signal integration level has not reached said first integration reference level, and wherein said method further comprises the steps of: (vi) comparing said outp

Abstract: A method for operating an optical motion sensing device comprising a light source and a photodetector device, said method comprises the steps of: a) illuminating a surface portion with radiation by means of the light source; b) detecting radiation patterns reflected from the illuminated surface portion by means of the photodetector device; c) extracting motion features from the detected radiation patterns by comparing light intensity between neighbouring pixels of said photodetector device by means of comparators with a determined hysteresis threshold; d) detecting and measuring displacement with respect to the illuminated surface portion based on said extracted motion features; e) determining whether the optical motion sensing device is moving or at rest; f) adjusting said determined hysteresis threshold of the comparators between at least a low and a high hysteresis values, consisting in selecting said low hysteresis value when the optical motion sensing device is moving and selecting said high hysteresis v

Abstract: There is described an integrating circuit for converting light energy produced by a photodetector into a voltage signal, this integrating circuit comprising an amplifier having an input coupled to a terminal of the photodetector and an output for outputting the voltage signal, and an integration capacitor having a first electrode connected to the amplifier input and a second electrode connected to the amplifier output. The first electrode of the capacitor is formed by the terminal of the photodetector connected to the amplifier input and the second electrode is formed by a layer of conductive material deposited on top of the photodetector and separated from this photodetector by a layer of insulating material, these layers of conductive material and of insulating material being transparent or nearly transparent at least for a given range of wavelengths of light. There is also described a method of forming the integration capacitor as well as a photodetector including the integration capacitor.