Adaptive electrical capacitance volume tomography

What is claimed is: 1. A system for tomographic imaging of a domain in a pipe, tube or object, the system comprising: a sensor, comprising: a plurality of electrodes, positioned in a predetermined arrangement relative to each other, and configured to be placed around the pipe, tube or object, each electrode comprising a plurality of capacitance plate segments; and a voltage source; a measuring circuit electrically coupled to the sensor; wherein the plurality of electrodes is further comprised of: a first electrode, having a plurality of capacitance plate segments that are addressable with the voltage source; a second electrode, having a plurality of capacitance plate segments, each of the capacitance plate segments of the second electrode electrically coupled to the measurement circuit; and wherein each of the capacitance plate segments of the first electrode form capacitance pairs with at least one of the capacitance plate segments of the second electrode when activated; and wherein the measurement circuit is configured with an algorithm to generate and collect capacitance data by: defining a capacitor by selecting a capacitance plate segment on the first electrodes as a source electrode, selecting a capacitance plate segment on the second electrode as a detecting electrode charging and discharging the defined capacitor by directing a predetermined voltage to the source electrode from the voltage source; detecting a capacitance of the defined capacitor by detecting a current induced in the detecting electrode by charging and discharging the source electrode; and an image reconstruction processor, in communication with the measuring circuit, and configured with an algorithm to convert detected capacitance data into an image. 2. The system of claim 1 , wherein the algorithm in the measuring circuit controls the sensitivity of the sensor by changing the frequency of the voltage distribution applied to at least one electrode. 3. The system of claim 1 , wherein the algorithm in the measuring circuit activates one electrode at a time as a source electrode and one electrode as the detecting electrode, and wherein the detecting electrode is connected to the measuring circuit. 4. The system of claim 1 , wherein the algorithm in the image reconstruction processor obtains the capacitance between all the electrodes and reconstructs an image of the region between the electrodes based on the capacitances obtained. 5. The system of claim 3 , wherein a switch controlled by the measuring circuit algorithm selectively connects each capacitance plate segment of each electrode to the voltage source. 6. The system of claim 1 , wherein the measuring circuit algorithm focuses the electric field between the first and second electrodes by means of the voltage levels used to address the capacitance plate segments. 7. An electrical capacitance tomography system, comprising: a sensor comprised of a plurality of electrodes arranged in a predetermined arrangement, wherein a plurality of the electrodes are each comprised of a plurality of capacitance plate segments and wherein each of the capacitance plate segments are individually addressable; a measurement circuit adapted to be connected to each of the electrodes for obtaining measurements used for obtaining capacitance levels between pairs of the electrodes; a processor connected to the measurement circuit adapted to construct an image of the region between the plurality of electrodes from outputs received from the measurement circuit; a voltage source electrically coupled to the sensor; wherein the plurality of electrodes is further comprised of: a first electrode, having a plurality of capacitance plate segments that are addressable with the voltage source; a second electrode, having a plurality of capacitance plate segments, each of the capacitance plate segments of the second electrode electrically coupled to the measurement circuit; and wherein each of the capacitance plate segments of the first electrode form capacitance pairs with at least one of the capacitance plate segments of the second electrode; wherein the measurement circuit is configured with an algorithm to generate and collect capacitance data by: defining a capacitor by selecting a capacitance plate segment on the first electrode as a source electrode, selecting a capacitance plate segment on the second electrode as a detecting electrode; charging and discharging the defined capacitor by directing a predetermined voltage to the source electrode from the voltage source; detecting a capacitance of the defined capacitor by detecting a current induced in the detecting electrode by charging and discharging the source electrode; wherein the measurement circuit is adapted to receive current from all of the capacitance pairs of the first and second electrodes and convert it to an output voltage (Vo); wherein the processor is programmed with one or more software routines executing on the processor to determine images from the output voltage (Vo); and wherein each of the capacitance plate segments of each of the electrodes are individually addressable by voltages and where sensor sensitivity is controlled by varying the voltage distribution or envelope applied to the capacitance plate segments. 8. An electrical capacitance tomography system, according to claim 7 , wherein the system is adapted to determine capacitance levels between each pair of electrodes of the sensor for image construction. 9. An electrical capacitance tomography system according to claim 7 , wherein each of the capacitance plate segments of each of the electrodes are individually addressable by at least one of following: a voltage source, a current source, or a passive circuit element. 10. An electrical capacitance tomography system according to claim 7 , wherein the electric field between electrodes of the sensor is focused by connecting voltages of various amplitudes to the capacitance plate segments of at least one of the electrodes. 11. An electrical capacitance tomography system according to claim 8 , wherein the electric field between electrodes of the sensor is focused toward the center of the electrodes by connecting voltages of various amplitudes to the capacitance plate segments of at least one of the electrodes, and wherein the voltages connected towards the center of the electrode is greater than the voltages connected to the periphery of the electrode. 12. An electrical capacitance tomography system according to claim 7 , wherein the measurement circuit is adapted to connect to each of the capacitance plate segments of each of the plurality of electrodes to provide an output to the processor for use in image construction. 13. An electrical capacitance tomography system according to claim 7 , wherein the sensor is adapted to be placed around a body of a human or animal to detect fluid flow or tissues through the body of the human or animal. 14. An electrical capacitance tomography system, comprising: a sensor comprised of a plurality of electrodes arranged in a predetermined arrangement; a measurement circuit adapted to be connected to each of the electrodes for obtaining measurements used for obtaining capacitance levels between pairs of the electrodes; a voltage source electrically coupled to the sensor; a processor connected to the measurement circuit adapted to construct an image of the region between the plurality of electrodes from outputs received from the measurement circuit; and wherein the plurality of electrodes is further comprised of: a first electrode, having a plurality of capacitance plate segments that are addressable with the v