AMI Semiconductor Belgium BVBA Patent applications |
Patent application number | Title | Published |
20090213696 | ECHO DETECTION - An echo detection circuit that detects an echo by detecting the magnitude of a digitally mixed representation of the received acoustic signal and reference sine and cosine signals. That magnitude is then compared against an echo threshold to verify the presence or absence of an echo signal. A low pass filter with a configurable cut-off frequency may be used to define the selectivity of the echo detector. | 08-27-2009 |
20090115462 | DRIVER CIRCUIT WITH EMI IMMUNITY - A driver circuit suitable for outputting a signal onto an output line affected by conducted EMI, has a slope control circuit and an output circuit, (op-amp, Mo, M | 05-07-2009 |
20090051433 | DIFFERENTIAL SENSING WITH HIGH COMMON MODE REJECTION - A differential operation circuit that uses the differential input signals to generate a reference voltage that fluctuates with the common mode voltage of the differential input signals. The reference voltage includes a common mode component that generally follows the common mode voltage of the differential input signals. The common mode component of the reference voltage is used to fully or almost fully offset the common mode voltage of the differential input signals, thereby increasing the differential operation circuit's common mode rejection characteristics. | 02-26-2009 |
20090039460 | DEEP TRENCH ISOLATION STRUCTURES IN INTEGRATED SEMICONDUCTOR DEVICES - A integrated semiconductor device has a first semiconductor layer of a first conductivity type, a second semiconductor layer of the first conductivity type over the first layer, a third semiconductor layer of a second conductivity type over the second layer, an isolation trench extending through the entire depth of the second and third layers into the first layer, and a first region of the second conductivity type located next to the isolation trench and extending from an interface between the second and third layers, along an interface between the second layer and the isolation trench. This first region can help reduce a concentration of field lines where the isolation trench meets the interface of the second and third layers, and hence provide a better reverse breakdown characteristic. | 02-12-2009 |
20090014785 | SEMICONDUCTOR DEVICE WITH IMPROVED BREAKDOWN PROPERTIES AND MANUFACTURING METHOD THEREOF - The present invention provides a semiconductor device ( | 01-15-2009 |
20080290461 | DEEP TRENCH ISOLATION FOR POWER SEMICONDUCTORS - An integrated power semiconductor device has an isolation structure having two or more isolation trenches, and one or more regions in between the isolation trenches, and a bias arrangement coupled to the regions to divide a voltage across the isolation structure between the isolation trenches. By dividing the voltage, the reverse breakdown voltage characteristics such as voltage level, reliability and stability can be improved for a given area of device, or for a given complexity of device, and avalanche breakdown at weaknesses in isolation structures can be reduced or avoided. | 11-27-2008 |
20080265984 | OVER-VOLTAGE PROTECTION FOR POWER AND DATA APPLICATIONS - A power supply device is described comprising a DC voltage supply, a power section connected to the DC supply for supplying DC power from the DC voltage supply to first and second outlet ports for connection to a remote device via a cable connection, a voltage boosting circuit for generating a voltage above that of the DC supply, an energy absorbing circuit connected between an output of the voltage boosting circuit and a ground potential, and a diode connection means between the first outlet port and the energy absorbing circuit. The major components of the power supply device may be implemented as an integrated circuit. | 10-30-2008 |
20080238410 | AUTO-CALIBRATION OF MAGNETIC SENSOR - The present invention provides a method to compensate for the sensitivity drift of a magnetic field sensor for sensing a magnetic field. The magnetic field sensor comprises at least four electrodes. The method comprises a first step where a first set of two electrodes is used to bias the sensor and a second set of two electrodes is used to sense an output signal of the magnetic field sensor, and a second step where the second set of two electrodes is used to bias the sensor and the first set of two electrodes is used to sense an output signal of the magnetic field sensor. The method is characterized in that at least one of the first or the second step is subdivided in at least a first sub-step and a second sub-step. A reference magnetic field has first magnetic field parameters, e.g. a first amplitude and/or direction, in the first sub-step and second magnetic field parameters, a second amplitude and/or direction, in the second sub-step. An output signal is sensed in the first and in the second step, and within the first or the second step an output signal is sensed in the first and the second sub-step. | 10-02-2008 |
20080218113 | Output Contact for Feedback in Integrated Circuit Motor Driver - An integrated circuit has drive circuitry to drive the windings of an electrical motor, means to make a measurement from the drive circuitry during rotation of the motor, suitable for use as motor control feedback, and has an output contact through which the motor control feedback measurement is available as an analog output signal. It can be used with an external motor control circuit coupled to receive the analog output signal to generate motor control signals, to control the drive circuitry. The analog feedback output gives more flexibility to the design of a motor control loop in terms of bit resolution, bandwidth and choice of discrete time or continuous time control. | 09-11-2008 |
20080197794 | METHOD AND APPARATUS FOR DRIVING A DC MOTOR - A circuit for determining a direction of rotation of an electric motor, the motor having asymmetry and/or eccentricity in a profile of back electromotive force as a function of angular position of a rotor with respect to a stator, the circuit receiving a signal representing the BEMF, and use the corresponding asymmetry and/or eccentricity in the signal to derive the direction of rotation. The signal representing the back emf can be generated by a control circuit. The control circuit can have a feedback loop regulator to generate a control signal (TL or TR) to control a current drive circuit ( | 08-21-2008 |