Abstract: The electronic circuit for measuring at least one physical parameter supplies an analogue output measurement signal (SA) dependent upon the value of a supply voltage. The circuit includes a sensor interface, connected to a sensor for supplying an analogue measurement signal (Vm) which is then filtered, an analogue-digital converter for digitally converting the filtered signal (Sm), and a digital signal control and processing unit for receiving a converted signal from the converter and supplying a digital measurement signal (SD). The sensor interface, the analogue-digital converter, and the processing unit are powered by a voltage regulator. The analogue and digital measurement signals are thus independent of any variation in the supply voltage (VCC) of the electronic circuit. A ratiometric unit, which may be an analogue multiplier or an analogue-digital converter, is powered by the supply voltage source (Bat) to recreate ratiometry on SA on the basis of Sm or SD.

Abstract: The measuring method is for measuring a physical parameter by means of an electronic interface circuit (1) for a capacitive sensor (2) with at least two capacitors (C1X, C2X) whose common electrode (CM) is mobile between the fixed electrodes. The electronic circuit includes an amplifier (4) connected to the common electrode (CM) by a switching unit (3), a logic unit (5) connected to the amplifier for supplying first and second digital measuring signals, and a digital-analogue converter (7) for supplying a measurement voltage (VDAC) to the electrodes on the basis of a conversion of one of the digital signals.

Abstract: A method for measuring relative motion between an illuminated surface and an optical sensing device comprising a coherent light source and a photodetector array is described.

Abstract: The optoelectronic circuit includes a photoreceptor (1) made in a silicon semiconductor substrate (4), and a monomode VCSEL laser diode (2) made in a gallium arsenide substrate. The photoreceptor includes at least one photosensitive area with a pixel array for picking up light and an area with a control and processing unit for the signals supplied by the pixels. The laser diode is mounted and electrically connected directly on one part of the photoreceptor. The laser diode is connected by a conductive terminal (12) to a first contact pad (3) at the bottom of a cavity (13) made through a passivation layer (5) of the photoreceptor. An electrode (17) on the top of the diode is connected by a metal wire (15) to a second contact pad (3) of the photoreceptor. The photoreceptor controls the diode directly via the electrode and the conductive terminal to generate a laser beam (L).

Abstract: Calibration instrument for an altimetric device delivering an indication of the altitude of the location where it is located on the basis of an atmospheric pressure measurement, characterized in that it includes means for transmitting a signal carrying data representative of the altitude at which it is placed. The invention also concerns a device delivering an indication of the altitude of the place where it is located on the basis of an atmospheric pressure measurement and a calibration system including a calibration instrument and an altimetric device.

Abstract: There is described a method for measuring relative motion between an illuminated portion of a surface and an optical sensing device comprising a coherent light source and a photodetector array, the method comprising the steps of illuminating under a determined gradient by means of the coherent light source the surface portion at a determined flash rate; detecting by means of the photodetector array speckled light intensity pattern of the illuminated portion of the surface for a first flash; detecting a second speckled light intensity pattern of the illuminated portion of the surface for a second flash; extracting motion features of two different types from the detected first and second speckled light intensity patterns; determining a measurement of the relative motion between the optical sensing device and the illuminated surface portion based on a comparison of motion features extracted; wherein before the step of determining a measurement of the relative motion, the method further comprises the step of keep

Abstract: The electronic circuit (1) with a capacitive sensor (2) is used for measuring a physical parameter, such as an acceleration. The sensor includes two capacitors mounted in differential, whose common electrode (Cm) can move relative to each fixed electrode of the two capacitors to alter the capacitive value of each capacitor. The electronic circuit has an interface connected to the capacitive sensor, which includes a charge transfer amplifier unit (4) connected to the common electrode (Cm), an integrator unit (5) for integrating the charges supplied by the charge transfer amplifier unit, and an excitation unit (3) arranged between the output of the first integrator unit and the sensor to polarise each fixed electrode of the sensor capacitors at a determined voltage value. A compensation capacitor (Cc) is connected to the input of the integrator unit.

Abstract: The chip card (11) includes at least one integrated circuit (11) fitted with a memory unit, in which personal data and/or at least one chip card identification code and/or configuration parameters can be stored. The integrated circuit is enclosed in an insulating material (3) that forms said card. The chip card (1) also includes connecting means (2) for communicating with an electronic instrument. These connecting means are electrically connected to corresponding contact pads of the integrated circuit. The chip card further includes a measuring circuit with a sensor for measuring a physical parameter so as to provide at least one output signal relating to the measurement (SD) of the physical parameter. The measuring circuit containing a sensor is arranged in a rigid case to define an electronic module (10), which is enclosed in the insulating material (3) that forms said chip card.

Abstract: A method for automatically testing an electronic circuit with a capacitive sensor having two capacitors is provided, wherein the common electrode of the capacitors moves relative to each fixed electrode. The electronic circuit includes a sensor interface that includes a charge transfer amplifier unit, an integrator unit connected to the amplifier unit to provide measurement output voltage, and an excitation unit. The excitation unit inversely polarizes each fixed electrode at high or low voltage or discharges the capacitors. The method includes several successive measurement cycles each divided into a first phase discharging capacitors by output voltage and a second phase for polarizing the fixed electrode of the first capacitor at high voltage and inversely polarizing the fixed electrode of the second capacitor at low voltage. In the measuring cycles, a test phase replaces a second polarizing phase in at least one cycle in every two successive measurement cycles.

Abstract: The chip card includes at least one integrated circuit (11) provided with a memory unit, which stores personal data and some configuration parameters. The integrated circuit is enclosed in an insulating material that forms said card. The chip card may also include connecting means, such as a zone of accessible electric contacts (VCC, GND) on at least one surface of the card, for contact with complementary contact terminals of an electronic instrument. These electric contacts are electrically connected to corresponding contact pads of the integrated circuit. The chip card may be a memory card or a SIM card. The chip card also includes a measuring circuit with a sensor (C) for measuring a physical parameter so as to provide at least one output signal relating to the physical parameter measurement (SD) by one of the electric contacts (I/O).

Abstract: An electronic interface circuit of a capacitive sensor usable for measuring a physical parameter, wherein the sensor includes two differential mounted capacitors whose common electrode moves relative to each fixed electrode in order to alter capacitive value of each capacitor. The electronic circuit includes a charge transfer amplifier unit connected to the common electrode, a first integrator unit for integrating charges supplied by the charge transfer amplifier, a first excitation unit arranged between the output of the first integrator unit and the sensor for polarizing each fixed electrode of the capacitors to a determined voltage value, a second integrator unit for integrating the charges supplied by the charge transfer amplifier, and a second excitation unit arranged between the output of the second integrator unit and the sensor for polarizing each fixed electrode of the capacitors at an opposite voltage value to the voltage value controlled by the first excitation unit.

Abstract: The electronic circuit (1) for measuring at least one physical parameter supplies an analogue output measurement signal (SA) dependent upon the value of a supply voltage. The circuit includes a sensor interface (2) connected to a sensor (C) for supplying an analogue measurement signal (Vm) which is then filtered. The circuit further includes an analogue-digital converter (8) for digitally converting the filtered signal (Sm), a digital signal control and processing unit (9) for receiving a converted signal from the converter, and supplying a digital measurement signal (SD). The sensor interface, the analogue-digital converter and the processing unit (9) are powered by a regulated voltage supplied by a voltage regulator (4). The analogue and digital measurement signals are thus independent of any variation in the supply voltage (VCC) of the electronic unit.

Abstract: The optoelectronic circuit includes a photoreceptor (1) made in a silicon semiconductor substrate (4), and a monomode VCSEL laser diode (2) made in particular in a gallium arsenide substrate. The photoreceptor includes at least one photosensitive area with a pixel array for picking up light and an area with a control and processing unit for the signals supplied by the pixels. The laser diode (2) is mounted and electrically connected directly on one part of the photoreceptor. This laser diode may be housed in a cavity (13) made through a passivation layer (5) of the photoreceptor, and connected by a conductive terminal (12) to a first contact pad (3) at the bottom of the cavity. An electrode (17) on the top of the diode can be connected by a metal wire (15) to a second neighbouring accessible contact pad (3) of the photoreceptor. The photoreceptor (1) controls the diode directly via the electrode and the conductive terminal to generate a laser beam (L).

Abstract: A method for automatically testing an electronic circuit with a capacitive sensor having two capacitors is provided, wherein the common electrode of the capacitors moves relative to each fixed electrode. The electronic circuit includes a sensor interface that includes a charge transfer amplifier unit, an integrator unit connected to the amplifier unit to provide measurement output voltage, and an excitation unit. The excitation unit inversely polarizes each fixed electrode at high or low voltage or discharges the capacitors. The method includes several successive measurement cycles each divided into a first phase discharging capacitors by output voltage and a second phase for polarizing the fixed electrode of the first capacitor at high voltage and inversely polarizing the fixed electrode of the second capacitor at low voltage. In the measuring cycles, a test phase replaces a second polarizing phase in at least one cycle in every two successive measurement cycles.

Abstract: The invention concerns an optical pointing device comprising a coherent light source for illuminating a surface portion with radiation, a driver of the coherent light source for controlling coherent light emissions, a photodetector device responsive to radiation reflected from the illuminated surface portion, processing means for determining, based on the photodetector device response, a measurement of relative motion between the optical pointing device and the illuminated portion of the surface, wherein the coherent light source driver is a fault-tolerant driver comprising redundant power control means for limiting the output power of coherent light emissions.

Abstract: A method for measuring relative motion between an illuminated portion of a surface and an optical sensing device comprising a coherent light source and a photodetector device comprising an array of pixels and comparators for extracting motion features, said method comprising the steps of: a) illuminating by means of said coherent light source said surface portion at a determined flash rate; b) detecting by means of said array of pixels a speckled light intensity pattern of said illuminated portion of the surface for each flash; c) extracting edge direction data of two different types from said detected speckled light intensity patterns by comparing light intensity between pixels; d) determining a measurement of the relative motion between said optical sensing device and said illuminated portion of the surface based on extracted edge direction data; wherein the extracting edge direction data step comprises a preliminary step consisting of introducing a selecting factor which promotes detection of one ty

Abstract: A method for extending battery life in an optical pointing device powered by one or more battery cells (30), the optical pointing device including an optical motion sensing device (10) for tracking motion with respect to a surface (S) and comprising motion sensing circuitry (12) coupled to an optical sensor (15) and at least one light source (14) for illuminating a portion of the surface. The method comprises the steps of (i) monitoring the power output of the said one or more battery cells (30), (ii) detecting when the said power output falls below a certain threshold indicative of a low battery status (EOL) and (iii) upon detection of the low battery status, switching the optical pointing device into a low power consumption mode where power consumption of the optical pointing device is reduced and performance of the optical motion sensing device is partially degraded. An optical pointing device implementing this method.

Abstract: The electronic interface circuit (1) of a capacitive sensor (2) is used for measuring a physical parameter, such as an acceleration. The sensor includes two differential mounted capacitors (C1, C2) whose common electrode (Cm) can move relative to each other fixed electrode in order to alter the capacitive value of each capacitor. The electronic circuit includes a charge transfer amplifier unit (4) connected to the common electrode (Cm), a first integrator unit (5) for integrating the charges supplied by the charge transfer amplifier and a first excitation unit (3) arranged between the output of the first integrator unit and the sensor for polarizing each fixed electrode of the capacitors to a determined voltage value.

Abstract: The present invention concerns a device for detecting crossing of a horizontal land demarcation marker of a carriageway for motor vehicles, characterized in that it includes at least one box (2) to be placed under the vehicle and enclosing means for projecting two light beams (4, 6) onto the carriageway (8) in two distinct zones (10, 12) that do not overlap, and distinct means for picking up each of the two light beams (14, 16) after reflection onto the carriageway (8).

Abstract: The photodiode cell (1) includes at least one photosensitive area (3), made in a silicon semiconductor substrate (2), for receiving light, particularly coherent light, and a passivation layer and a dielectric layer (4). The passivation layer is composed of at least a first silicon oxide layer (5) and a second nitride layer (6), made on the photosensitive area. The second nitride layer is made with a thickness within a determined margin, so as to be situated in a zone with the most constant possible light reflectivity independently of the thickness of the first layer. An etch (7) can be performed on one portion of the dielectric layer (4) or on the first layer (5) corresponding to half of the reception surface of the photosensitive area in order to obtain a reflectivity percentage mean of the light to be sensed by the photodiode cell.