Multiphase meter to provide data for production management

What is claimed is: 1. A method of determining an emulsion stability parameter of a multiphase fluid flowing in a tubular in order to determine a fluid flow rate, comprising: imparting a magnetic field on the multiphase fluid to align nuclei of the multiphase fluid along a direction of the magnetic field; transmitting a radio frequency signal into the multiphase fluid to excite the nuclei; detecting a signal from the nuclei responsive to the transmitted radio frequency signal; using a processor to: determine an amplitude of the detected signal; estimate a water cut of the multiphase fluid from the determined amplitude; determine a relaxation time of the detected signal; determine a viscosity of the multiphase fluid from the determined relaxation time of the detected signal; determine the emulsion stability parameter of the multiphase fluid from the determined viscosity, the estimated water cut and a curve that relates the viscosity, the water cut and the emulsion stability parameter; model the multiphase fluid with an emulsion characterized by the emulsion stability parameter; image a flow pattern of the multiphase fluid in the tubular using the emulsion model; determine a volume of the phase flowing in the tubular using the determined amplitude and an amplitude of a calibration signal; and determine the fluid flow rate from using one or more of the parameters determined above. 2. The method of claim 1 , further comprising determining water cut of a liquid phase by determining a proton density of the liquid phase from an accumulated relaxation time density. 3. The method of claim 1 , further comprising determining a volume of a phase of the multiphase fluid using an integrated signal from the calibration signal obtained from a flow of water and the amplitude of the detected signal. 4. The method of claim 3 , wherein determining the volume of the phase further comprises determining a hydrogen index of a phase of the multiphase fluid. 5. The method of claim 3 , further comprising: determining a flow velocity of the phase; and determining a flow rate of the phase using the determined volume of the phase and the determined flow velocity of the phase. 6. The method of claim 3 , wherein the amplitude of the calibration signal is a temperature-corrected amplitude. 7. An apparatus for determining an emulsification stability parameter of a multiphase fluid flowing in a tubular in order to determine a fluid flow rate, comprising: a magnetic source configured to impart a magnetic field on the multiphase fluid to align nuclei of the multiphase fluid along a direction of the magnetic field; a source configured to transmit a radio frequency signal into the multiphase fluid to excite the nuclei; a detector for detecting a signal from the nuclei responsive to the transmitted radio frequency signal; and a processor configured to: determine an amplitude of the detected signal; estimate a water cut of the multiphase fluid from the determined amplitude; determine a relaxation time of the detected signal; determine a viscosity of the multiphase fluid from the determined relaxation time; determine the emulsification stability parameter of the multiphase fluid from the determined viscosity, the estimated water cut and a curve that relates the viscosity, the water cut and the emulsion stability parameter; model the multiphase fluid with an emulsion characterized by the emulsion stability parameter; image a flow pattern of the multiphase fluid in the tubular using the emulsion model; determine a volume of the phase flowing in the tubular using the determined amplitude of the detected signals and an amplitude of a calibration signal; and determine the fluid flow rate from using one or more of the parameters determined above. 8. The apparatus of claim 7 , wherein the processor is further configured to determine water cut of a liquid phase of the multiphase fluid by determining a proton density of the liquid phase from an accumulated relaxation time density. 9. The apparatus of claim 7 , wherein the processor is further configured to determine a volume of a phase of the multiphase fluid using the calibration signal obtained from a flow of water and the amplitude of the detected signal. 10. The apparatus of claim 9 , wherein the processor is further configured to determine the volume of the phase by determining a hydrogen index of a liquid phase of the multiphase fluid. 11. The apparatus of claim 9 , wherein the processor is further configured to: determine a flow velocity of the phase; and determine a flow rate of the phase using the determined volume of the phase and the determined flow velocity of the phase. 12. The apparatus of claim 9 , wherein the amplitude of the calibration signal is a temperature-corrected amplitude. 13. A method of determining stability of an emulsion flowing in a production string in order to determine a fluid flow rate, comprising: imparting a magnetic field on the emulsion to align nuclei of the emulsion along a direction of the magnetic field; transmitting a radio frequency signal into the emulsion flowing in the production string; detecting a signal from the nuclei of the emulsion responsive to the transmitted radio frequency signal; using a processor to: determine an amplitude of the detected signal; estimate a water cut of the multiphase fluid from the determined amplitude; determine a relaxation rate of the detected signal obtained from nuclei of the emulsion excited in response to the transmitted radio frequency signal; determine a viscosity of the multiphase fluid using the volume determined from the determined relaxation rate; determine an emulsion stability parameter of the emulsion from the determined emulsion viscosity, the water cut of the emulsion and a curve that relates the viscosity, the water cut and the emulsion stability parameter; model the multiphase fluid with an emulsion characterized by the emulsion stability parameter; image a flow pattern of the multiphase fluid in the tubular using the emulsion model; determine a volume of the phase flowing in the tubular using the determined amplitude and an amplitude of a calibration signal; and determine the fluid flow rate from using one or more of the parameters determined above.