The position of an object, which may be a user's finger, along a body is sensed capacitively. A measurement circuit meters the simultaneous injection of electrical charge into the two ends of the body, which may be shaped as a straight line or as a curve. A computing device computes the ratio of the
The position of an object, which may be a user's finger, along a body is sensed capacitively. A measurement circuit meters the simultaneous injection of electrical charge into the two ends of the body, which may be shaped as a straight line or as a curve. A computing device computes the ratio of the relative changes in the amount of charge injected into each end of the element. The result of this computation is a one dimensional coordinate number plus a detection state indication, both of which can be fed to another functional element, such as an appliance controller, which interprets the coordinate and detection state as a command or measurement.
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What is claimed is: 1. A capacitive sensor for providing a detection output indicative of proximity to a sensing body extending between two electrodes of an object that is not a portion of the sensor and for providing a position output varying linearly with a position of the object along the sensin
What is claimed is: 1. A capacitive sensor for providing a detection output indicative of proximity to a sensing body extending between two electrodes of an object that is not a portion of the sensor and for providing a position output varying linearly with a position of the object along the sensing body when the object is proximate, thereto, the sensor comprising: two capacitive sensing channels, each channel connected to a respective one of the electrodes, each channel having a respective channel output representative of a respective non-linear response to a capacitive load imposed by the object when the object is proximate the body; means for operating the two channels synchronously; means for summing the respective channel outputs and for providing the detection output if that sum exceeds a selected minimum threshold; and calculation means for receiving the respective outputs from the two channels, for calculating a ratio of a selected linear combination of the outputs of the two channels, wherein the ratio varies linearly with the position of the object, and for supplying the ratio as the position output. 2. The sensor of claim 1 wherein the respective output from each of the channels comprises an algebraic difference between a respective first value measured when the object is adjacent the sensing body and a respective second value measured when the object is distal therefrom. 3. The sensor of claim 1 wherein the object is capacitively coupled to an electrical ground. 4. The sensor of claim 1 wherein each sensing channel comprises: a respective sample capacitor having two terminals, one of which is connected to the associated electrode by means not comprising an electric switching element; three electric switching elements, each of the three switching elements having both a single respective closed state for connecting one of the terminals of the respective sample capacitor to only one of two different reference voltages, each of the respective switching elements further having a respective open state in which it does not connect the respective one of the terminals to either of the two reference voltages; and a respective measurement circuit for supplying the respective channel output responsive to a voltage measurement at a selected one of the terminals of the respective sample capacitor. 5. The sensor of claim 1 further comprising a plurality of electric switching elements, wherein each sensing channel comprises: a respective sample capacitor having two terminals, one of which is connected to a respective electrode by means not comprising one of the electric switching elements; at least one respective electric switching element of the plurality thereof for resetting the respective sample capacitor by connecting both of its terminals to a first selected reference voltage; and at least two additional respective switching elements of the plurality thereof for alternately switching one of the two terminals of the respective sample capacitor to the first selected reference voltage and the second of the two terminals to a second selected reference voltage. 6. The sensor of claim 1 wherein: each channel comprises a respective resistor-capacitor pair and means for measuring a parameter change at the associated electrode; the means for operating the two channels synchronously comprises a controller for controlling at least three electric switching elements; wherein two of the at least three electric switching elements are operable by the controller to simultaneously connect both of the two electrodes to a first reference voltage; and wherein at least a third of the at least three electric switching elements is operable to simultaneously connect a second reference voltage to each resistor-capacitor pair. 7. The sensor of claim 1 wherein each of the channels comprises a sampling capacitor whose voltage rises in an inverse exponential fashion with a capacitive load. 8. The sensor of claim 1 wherein the calculation means comprises a microcontroller and the means for operating the channels synchronously comprises a plurality of switching elements controlled by the microcontroller. 9. The sensor of claim 1 wherein the sensing body comprises two strips of conductive material extending adjacent to each other with a gap therebetween, wherein at least one of the strips tapers along its length. 10. The sensor of claim 1 wherein the sensing body comprises a single resistor. 11. The sensor of claim 1 wherein the sensing body comprises a plurality of discrete resistors connected in series. 12. A capacitive sensor for providing a detection output indicative of proximity of an object and for providing a position output varying linearly with a position of the object along a sensing body extending between two electrodes, the sensor comprising: two sensing channels respectively connected to the two electrodes, each sensing channel a respective sample capacitor having two terminals, one of which is connected to the associated electrode by means not comprising an electric switching element; three electric switching elements, each of the three switching elements having both a single respective closed state for connecting one of the terminals of the respective sample capacitor only to one of two different reference voltages, each of the respective switching elements further having a respective open state in which it does not connect the respective one of the terminals to either of the two reference voltages; and a respective measurement circuit for supplying an output responsive to a measurement of a respective capacitive load imposed by the object at a selected one of the terminals of the respective sample capacitor, said output varying non-linearly with the position of the object along the sensing body when the object is proximate the sensing body and the sensor is in operation; a switch controller for selectively opening and closing the switching elements; means for summing the respective outputs from the two measurement circuits and for providing the detection output if the sum exceeds a stored minimum threshold value ; and means for calculating the position of the object from a ratio of a selected linear combination of the respective non-linear outputs of the two measurement circuits. 13. The sensor of claim 12 wherein the means for calculating the position of the object comprises a microcontroller. 14. The sensor of claim 12 wherein the sensing body comprises a single resistor. 15. The sensor of claim 12 wherein the sensing body comprises a plurality of discrete resistors connected in series. 16. A capacitive sensor for providing a detection output indicative of proximity of an object and for providing a position output that varies linearly with a position of the object along a sensing body extending between two electrodes, the sensor comprising: a switch controller for selectively closing ones of a plurality of electric switching elements; two sensing channels having respective inputs from the electrodes and having respective outputs from respective associated measurement circuits, each of the respective outputs responsive to a capacitive load imposed by the object, each of the respective outputs varying non-linearly with the position of the object along the sensing body when the object is proximate the sensing body and the sensor is in operation, each of the sensing channels comprising a respective sample capacitor having two terminals, one of which is connected to a respective electrode by means not comprising one of the electric switching elements; at least one respective electric switching element of the plurality thereof for resetting the respective sample capacitor by connecting both of its terminals to a first selected reference voltage; at least two additional respective switching elements of the plurality thereof for alternately switching one of the two terminals of the respective sample capacitor to the first selected reference voltage and the second of the two terminals to a second selected reference voltage; means for summing the respective outputs from the two measurement circuits and for providing the detection output if the sum exceeds a selected minimum threshold value; and a means for calculating the position of the object from a ratio of a selected linear combination of the respective non-linear outputs of the two measurement circuits. 17. The sensor of claim 16 wherein the means for calculating the position of the object comprises a microcontroller. 18. The sensor of claim 16 wherein the sensing body comprises two strips of conductive material extending adjacent to each other with a gap therebetween, wherein at least one of the strips tapers along its length. 19. The sensor of claim 16 wherein the sensing body comprises a single resistor. 20. The sensor of claim 16, wherein the sensing body comprises a plurality of discrete resistors connected in series.
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