Abstract: In a serial transmission method using a two-wire serial interface, a master device transmits a first synchronous serial signal via the two-wire serial interface to wake-up a slave device followed by an asynchronous data transmission on one of the two-wires of the two-wire serial interface. The asynchronous data signal directly controls a function of the slave device.

Abstract: In a serial transmission method using a two-wire serial interface, a master device transmits a first synchronous serial signal via the two-wire serial interface to wake-up a slave device followed by an asynchronous data transmission on one of the two-wires of the two-wire serial interface. The asynchronous data signal directly controls a function of the slave device.

Abstract: Disclosed is a circuit and method for automatic tuning of a resonant circuit in a transceiver having a receiver and a transmitter that includes a power amplifier for driving the resonant circuit. During a transmit mode of the transceiver, a resonance voltage of the resonant circuit is compared to an input voltage signal to the power amplifier to determine an error signal that is converted into a control word. The control word drives an adjustable capacitance bank that is part of the resonant circuit. During a receive mode of the transceiver, the control word value is held constant to substantially maintain resonance of the resonant circuit during operation of the receiver.

Abstract: The present invention is directed toward a system and apparatus for digitally controlling a bias control signal for at least one transistor. The present invention provides for software writable registers that control the bias control signal. The present invention further provides for the bias control signal to be temperature compensated based upon a temperature signal and a temperature profile stored in software writable registers. The present invention further provides for software control of the initialization and configuration of the bias control signal through stored program control of the values in the software writable registers.

Abstract: A method and circuit are shown for generating a higher order compensated bandgap voltage is disclosed, in which a first order compensated bandgap voltage and a linearly temperature dependent voltage are generated. Thereafter, a difference between the linearly temperature dependent voltage and the first order compensated bandgap voltage is generated. The resulting difference voltage is squared, and finally the squared voltage is added to the first order compensated bandgap voltage, resulting in a higher order compensated bandgap voltage. There is also disclosed a higher order temperature compensated bandgap circuit.

Abstract: Disclosed is a circuit and method for continuous automatic tuning of a resonant circuit. A resonance voltage of the resonant circuit is phase shifted by a predetermined phase shift ? degrees and an input voltage signal to a power amplifier driving the resonant circuit is phase shifted by ?±90 degrees to place the signals in quadrature. The phase shifted signals are mixed to obtain a error signal. The error signal is compared to a predetermined voltage range in order to generate control signals for a control word generator, such as an up-down counter. The control word generator produces a control word that drives a capacitance bank that is part of the resonant circuit. The present invention continuously automatically adjusts the capacitance of the capacitance bank to tune the resonant circuit.

Abstract: A method and circuit are shown for generating a higher order compensated bandgap voltage is disclosed, in which a first order compensated bandgap voltage and a linearly temperature dependent voltage are generated. Thereafter, a difference between the linearly temperature dependent voltage and the first order compensated bandgap voltage is generated. The resulting difference voltage is squared, and finally the squared voltage is added to the first order compensated bandgap voltage, resulting in a higher order compensated bandgap voltage. There is also disclosed a higher order temperature compensated bandgap circuit.

Abstract: Shown is a method and circuit for determining a calibration factor between a fast, high accuracy clock signal and a slow, low accuracy clock signal, which can be realised with a minimum number of electronic units, and which obtains the calibration factor in a very short time, thus minimising power consumption of the circuit. The present invention operates by counting the number of cycles of a high accuracy clock signal during a single cycle of a low accuracy clock signal to obtain a first number representing the number of cycles counted and then successively summing the first number until a sum of the first numbers reaches a first predetermined value. The count of the number of summing operations required to reach the first predetermined value is then used to determine the calibration parameter, which is proportional to the number of summing operations.

Abstract: Disclosed is a circuit and method for automatic tuning of a resonant circuit in a transceiver having a receiver and a transmitter that includes a power amplifier for driving the resonant circuit. During a transmit mode of the transceiver, a resonance voltage of the resonant circuit is compared to an input voltage signal to the power amplifier to determine an error signal that is converted into a control word. The control word drives an adjustable capacitance bank that is part of the resonant circuit. During a receive mode of the transceiver, the control word value is held constant to substantially maintain resonance of the resonant circuit during operation of the receiver.

Abstract: Transmitter and receiver circuits are shown that are capable of operating in a stand-alone mode without the necessity of an external controller to program the transmitter and receiver circuits, such as by providing operating parameters through a control interface. An internal controller of the transmitter detects that no external controller is present and operates to access an external storage device, such as an EEPROM, to obtain data for configuring at least some of the operating characteristics of the transmitter. The transmitter may be configured to respond to predetermined events by accessing corresponding data at predetermined addresses of the EEPROM. The internal controller of the receiver may also detect that no external controller is present and to obtain data for configuring at least some of the operating characteristics of the receiver.

Abstract: A variable frequency oscillator circuit comprising a resonator circuit part and an amplifier circuit part. The resonator circuit part has a first end and a second end, and it comprises a parallel connected inductor-capacitance pair. The amplifier circuit part comprises first and second transistors having a collector, base, and emitter. The amplifier circuit part further comprises a first impedance matching element connected between the base of the second transistor and the first end of the resonator circuit part, and a second impedance matching element connected between the base of the first transistor and the second end of the resonator circuit part. The impedance matching elements are inductors, namely the third inductor and the fourth inductor. The application of the inductors provides a noise-matched optimum source impedance for the active amplifier circuit part.

Abstract: A circuit and method are shown for minimizing a phase noise of an amplifier circuit in an oscillator circuit. A pair of cross-coupled transistors in the amplifier circuit actively amplify a signal from a resonator circuit of the oscillator circuit. In order to reduce the phase noise of the oscillator circuit, an impedance matching element is connected between each transistor and the resonator circuit. Each impedance matching element may take the form of an inductor that may be tuned to minimize the phase noise of the active amplifier circuit. The inductors need not have a high quality factor.

Abstract: A process for the preparation of high-purity deferoxamine salts from filtered fermentation liquors containing deferoxamine B as active ingredient by the adsorption of the active ingredient onto an ion exchange resin and the subsequent dissolution and purification thereof, which comprises carrying out the separation of the deferoxamine salt subsequent to the concentration of the eluate by salting out from an aqueous solution or from a mixture of water and an organic solvent and purifying it by repeated salting out and/or by methods known per se, and optionallya) preparing the methanesulfonate salt by known methods, orb) passing the aqueous solution of the deferoxamine salt trough an ion exchange resin containing methanesulfonate anions as counter ions and recovering the methanesulfonate salt from the effluent, preferably by lyophilization.

Abstract: The present invention relates to electro-analytical measuring equipment for the determination--by means of one or more measuring cells comprising sensing elements of chemical similar composition, being in constant galvanic contact with each other--of the concentration and ion-activity of solutions or of the partial pressure of gases. The sensing elements are in contact with sample or with one or more standardizing media separated in time or space. At least two reference electrodes are in direct or in indirect contact--through electrolite--with sample and standardizing medium. The reference electrodes join, in a given case, to electronic signal processor comprising arithmetic unit calculating, by fault compensation, value of one or more parameters to be measured.

Abstract: An electro-analytical measuring process and apparatus for the determination of the concentration and the ion-activity of stationary or flowing solutions or of the partial pressure of gases. The measuring cell of the measuring equipment--connected to an electronic signal processor--comprises, in addition to one or several sensing elements and reference electrodes, at least one fluid clutch capable of galvanically short-circuiting one or more parts of the measuring chain. The measuring cell of the measuring equipment comprises, in a given case, integral sensing unit and standardizing media, being in contact with sensing elements. Further, a control unit for programming short-circuiting belongs to the measuring cell, a fault compensating unit producing signals is connected to the control unit--for calculating the value of the parameter to be measured--is connected to the output of the fault compensating unit.