Abstract: A magnetostrictive position measuring system is provided with a waveguide and which is allocated with a magnet movable along the waveguide. An impulse generator for generating an excitation pulse and a conductive wire for guiding the excitation pulse through the waveguide to the magnet are provided, whereby a torsion wave arises in the waveguide when the excitation pulse reaches the magnet. A reel for generating a reply pulse as a function of the torsion wave and a position calculation unit for ascertaining the position of the magnet as a function of the excitation pulse and the reply pulse are provided. A processor is provided in which a table is present in which a large number of positions and excitation pulse correction values are allocated to one another. The duration of the next excitation pulse is altered as a function of the position of the magnet ascertained and the associated excitation pulse correction value from the table.

Abstract: A method of tuning an input signal (S) is described. The method comprises the steps of amplifying the input signal (S) by a gain element (14) having a variable impedance (22) associated therewith and thereby generating an output signal (C), comparing the output signal (C) with a reference voltage (V), tuning the variable impedance (22) such that the impedance is increased if the amplitude of the output signal (C) is smaller than the reference voltage (V), and that the impedance is decreased if the amplitude of the output signal (C) is greater than the reference voltage (V).

Abstract: A magnetostrictive position measuring system is provided with a waveguide and which is allocated with a magnet movable along the waveguide. An impulse generator for generating an excitation pulse and a conductive wire for guiding the excitation pulse through the waveguide to the magnet are provided, whereby a torsion wave arises in the waveguide when the excitation pulse reaches the magnet. A reel for generating a reply pulse as a function of the torsion wave and a position calculation unit for ascertaining the position of the magnet as a function of the excitation pulse and the reply pulse are provided. A processor is provided in which a table is present in which a large number of positions and excitation pulse correction values are allocated to one another. The duration of the next excitation pulse is altered as a function of the position of the magnet ascertained and the associated excitation pulse correction value from the table.

Abstract: A method of tuning an input signal (S) is described. The method comprises the steps of amplifying the input signal (S) by a gain element (14) having a variable impedance (22) associated therewith and thereby generating an output signal (C), comparing the output signal (C) with a reference voltage (V), tuning the variable impedance (22) such that the impedance is increased if the amplitude of the output signal (C) is smaller than the reference voltage (V), and that the impedance is decreased if the amplitude of the output signal (C) is greater than the reference voltage (V).

Abstract: A modular waveguide assembly for use in a position sensor promotes efficient manufacturing, and can be tested and handled separately from the electronics module of the sensor. The waveguide assembly includes a channel having an opening extending along its length, a waveguide located within the channel, a conductor located within the channel, and a mode converter, such as a coil, located within the channel and positioned to generate an electrical signal from a signal traveling along the waveguide. A damping material can be inserted into the channel opening and around a portion of the waveguide such that the material adheres to the waveguide. Preferably, the damping material is at least initially partially flowable, and is then cured.

Abstract: A method for the serial transmission of digital data from a transmitter to a receiver is described. In the method, at least one data word is transmitted which has a plurality of bits. Also transmitted is an associated error bit which indicates whether the generation of the data word was error-free. Likewise, a plurality of associated test bits are transmitted, from which it is possible to deduce whether the transmission of the data word and of the error bit was error-free.

Abstract: A modular waveguide assembly for use in a position sensor promotes efficient manufacturing, and can be tested and handled separately from the electronics module of the sensor. The waveguide assembly includes a channel having an opening extending along its length, a waveguide located within the channel, a conductor located within the channel, and a mode converter, such as a coil, located within the channel and positioned to generate an electrical signal from a signal traveling along the waveguide. A damping material can be inserted into the channel opening and around a portion of the waveguide such that the material adheres to the waveguide. Preferably, the damping material is at least initially partially flowable, and is then cured.

Abstract: A measurement transducer and method is provided which provides a pair of pulses as an output, the measured condition being represented by the time between the pulses, and which includes internal compensation such that the pair of pulses are adjusted to mimic the output of a predetermined ideal transducer. In one embodiment, correction factors are calculated for a magnetostrictive linear position transducer by comparing the transducer output with a position measurement taken by a separate measuring device. These correction factors are stored in a non-volatile memory. Then, during operation of the transducer, a correction factor is selected for each uncorrected measurement and added to the uncorrected measurement to provide a compensated measurement. The compensated measurement is then used to generate a time value using a calculation which includes a predetermined standard waveguide propagation velocity value.

Abstract: A modular waveguide assembly for use in a position sensor promotes efficient manufacturing, and can be tested and handled separately from the electronics module of the sensor. The waveguide assembly includes a channel having an opening extending along its length, a waveguide located within the channel, a conductor located within the channel, and a mode converter, such as a coil, located within the channel and positioned to generate an electrical signal from a signal traveling along the waveguide. A damping material can be inserted into the channel opening and around a portion of the waveguide such that the material adheres to the waveguide. Preferably, the damping material is at least initially partially flowable, and is then cured.

Abstract: A modular waveguide assembly for use in a position sensor promotes efficient manufacturing, and can be tested and handled separately from the electronics module of the sensor. The waveguide assembly includes a channel having an opening extending along its length, a waveguide located within the channel, a conductor located within the channel, and a mode converter, such as a coil, located within the channel and positioned to generate an electrical signal from a signal traveling along the waveguide. A damping material can be inserted into the channel opening and around a portion of the waveguide such that the material adheres to the waveguide. In one embodiment, the damping material is at least initially partially flowable, and is then cured.

Abstract: A method and apparatus for calibrating the output signal of a linear position detector without accessing the interior of the detector housing is provided. According to one exemplary embodiment, a magnet is selectively movable toward and away from the exterior of the electronics housing, and a sensor is provided within the housing for sensing the presence of the magnet. According to this embodiment, the linear position detector is calibrated by setting a movable marker at the desired position and pushing the magnet toward the housing. The sensor then detects the presence of the magnet, and a processor saves the position of the marker as a reference point. All future positions of the marker can then be scaled based upon the reference point. Thus, the linear position detector can be calibrated without the need for opening the electronics housing and potentially exposing the electronics components to moisture, contaminants, and/or static electricity.

Abstract: An apparatus and method for automatically and periodically tuning a signal having a gain element, a variable impedance associated with the gain element, and a control device. The gain element has an input for receiving the signal and an output for providing an output signal and is preferably an operational amplifier with a feedback path extending from the output to the input. The variable impedance is preferably connected in series in the feedback path and includes a plurality of resistors connected in series and a plurality of switches, each switch being connected in parallel with one of the resistors. The control device receives the gain element output signal and generates a control signal in response to the amplitude of the gain element output signal. The control signal is transmitted to the variable impedance for regulating the setting of the impedance.

Abstract: An overvoltage protection apparatus for use with a data transmission interface, having at least one data transmission line associated therewith, for protecting the interface from power spikes, transients, and/or the continuous application of an excessive voltage. In a preferred embodiment, the apparatus includes at least one voltage limiting device associated with each data line. Each voltage limiting device being connected at one end to the associated data line, and at a second end to a current sensing and switching structure, which is in turn connected to ground. The current sensing and switching structure monitors the current through the voltage limiting device. In the event an excessive voltage is applied to a pin or data line of the interface, the voltage limiting device briefly absorbs the excess power and generates an increased current. This increased current is sensed by the current sensing and switching structure, which responds by opening a switch which disconnects the interface from ground.