Tomography of multiphase mixtures

The invention claimed is: 1. A tomography system for determining properties of flowing multiphase fluid, comprising: a duct having a duct wall and interior space within the duct wall for carrying a flow of a multiphase fluid; a plurality of sensors at positions distributed substantially evenly around the duct wall on a planar cross section through the duct transverse to the duct axis, for making a plurality of measurements of electrical or magnetic properties through the multiphase fluid, wherein the sensors are electrodes that measure data values representative of capacitance, resistance, conductance or admittance between a plurality of pairs of electrodes in the plane of the cross section or the sensors are coils that measure data values representative of inductance between a plurality of pairs of coils in the plane of the cross section; and a processor receiving the measured data values from the sensors and configured to compute from the measured data values to derive computed quantitative values of at least one property selected from permittivity, conductivity, magnetic permeability and complex-conductivity of the multiphase fluid within the duct, which are independent of effects external to the fluid flow. 2. The system of claim 1 , wherein deriving the computed quantitative values selected from permittivity, conductivity, permeability and complex-conductivity of the multiphase fluid from the measured data values comprises determining normalized values representative of at least one of capacitance, resistance, conductance, inductance and admittance exclusively of the multiphase fluid within the duct, and converting the normalized capacitance, resistance, conductance, or admittance to the quantitative values of permittivity, conductivity, permeability or complex-conductivity of the multiphase fluid within the duct. 3. The system of claim 1 , which is an electrical tomographic system wherein the sensors are electrodes that measure values representative of capacitance, resistance, conductance or admittance between the plurality of pairs of electrodes at positions distributed around the exterior of the duct wall and the processor receiving measurement data from the electrodes is configured to determine a plurality of quantitative values of permittivity, conductivity or complex-conductivity of the multiphase fluid within the duct. 4. The system of claim 1 , wherein the sensors are coils that measure values representative of inductance between the plurality of pairs of coils at positions distributed around the exterior of the duct wall and the processor receiving measurement data from the coils is configured to determine a plurality of quantitative values of conductivity or magnetic permeability of the multiphase fluid within the duct. 5. The system of claim 1 , wherein the processor is configured to compute at least one of a water-in-liquid-ratio and a liquid fraction of the multiphase fluid from one or more of the plurality of quantitative values of permittivity, conductivity or complex-conductivity. 6. The system of claim 1 , wherein the processor is configured to compute at least one image showing spatial distribution of permittivity, conductivity, magnetic permeability or complex-conductivity of the multiphase fluid within the planar cross-section of the duct. 7. The system of claim 1 , wherein the processor is configured to compute at least one image showing temporal distribution of permittivity, conductivity, magnetic permeability or complex-conductivity of the multiphase fluid within the planar cross-section of the duct. 8. A computer implemented method of measuring properties of a multiphase fluid flowing within a duct, comprising: making a plurality of measurements representative of capacitance, resistance, conductance, inductance or admittance between a plurality of pairs of sensors distributed substantially evenly around a planar cross section through the fluid transverse to the direction of flow within the duct; and computing permittivity, conductivity, magnetic permeability or complex-conductivity of the multiphase fluid from the measurements made; wherein the computed permittivity, conductivity, magnetic permeability or complex-conductivity is exclusively that of the multiphase fluid independent of effects external to the flow of the multiphase fluid. 9. The method of claim 8 , wherein measurements are between sensors that are electrodes or coils mounted around the duct carrying the flowing multiphase fluid and the method further comprises: determining normalized values representative of capacitance, resistance, conductance, inductance or admittance at the planar cross section through the fluid, wherein the normalized values relate exclusively to the multiphase fluid and are independent of effects external to the flow of the multiphase fluid; and computing permittivity, conductivity, magnetic permeability or complex-conductivity of the multiphase fluid from one of the normalized values. 10. The method of claim 8 , wherein measurements are between electrodes mounted outside the duct carrying the flowing multiphase fluid, and the method further comprises: determining normalized values representative of capacitance, resistance, conductance, inductance or admittance at the planar cross section through the fluid, wherein the normalized values relate exclusively to the multiphase fluid and are independent of effects external to the flow of the multiphase fluid, and computing permittivity, conductivity, magnetic permeability or complex-conductivity of the multiphase fluid within the duct from one of the normalized values. 11. The method of claim 8 , further comprising: computing at least one of a water-in-liquid-ratio and a liquid fraction of the multiphase fluid from the computed permittivity, conductivity, magnetic permeability or complex-conductivity of the multiphase fluid. 12. The method of claim 8 , further comprising: computing one or more images showing spatial distribution of permittivity, conductivity, magnetic permeability or complex-conductivity within the cross-section through the multiphase flow. 13. The method of claim 8 , further comprising: computing one or more images showing temporal distribution of permittivity, conductivity, magnetic permeability or complex-conductivity within the cross-section through the multiphase flow. 14. The method of claim 8 , further comprising: making a plurality of measurements representative of capacitance, resistance, conductance, inductance or admittance at one or more further cross sections through the fluid transverse to the direction of flow within the duct. 15. The method of claim 8 , wherein the plurality of sensors comprises eight sensors distributed substantially evenly around the duct wall and the system is configured for making measurements representative of capacitance, resistance, conductance, inductance or admittance between all pairs of the eight sensors other than those which are adjacent to each other. 16. The method of claim 9 , further comprising: making calibration measurements representative of capacitance, resistance, inductance or admittance between pairs of sensors at the planar cross section when the duct contains single phase fluids. 17. The system of claim 1 , wherein the plurality of sensors comprises eight sensors distributed substantially evenly around the duct wall and the system is configured for making measurements representative of capacitance, resistance, conductance, inductance or admittance between all pairs of the eight sensors other than those which are adjacent to each other.