Determining multi-phasic fluid properties and hydrocarbon production information as a function thereof

The invention claimed is: 1. A method of determining properties of a fluid having an oil phase, a water phase, and an emulsion phase between the oil phase and water phase, the method comprising: emitting an electromagnetic wave into the fluid; measuring an amplitude of a reflection of the electromagnetic wave off an interface between the oil phase and the emulsion phase; determining a dielectric constant of the emulsion phase based on the amplitude of the reflection of the electromagnetic wave from the interface; determining a water-in-liquid ratio of the emulsion phase based on the dielectric constant; determining a height of a coalescing portion of the interface between the oil phase and the emulsion phase based on the emitted and reflected waves; determining a height of a creaming portion of the interface between the emulsion phase and the water phase based on a difference between a first product and a second product, wherein the first product comprises a product of a total height of the fluid and a total water-in-liquid ratio, and wherein the second product comprises a product of the height of a coalescing portion and the water-in-liquid ratio of the emulsion phase; and determining a thickness of the emulsion phase based on the difference between the height of the coalescing portion and the height of the creaming portion. 2. The method of claim 1 , wherein the thickness of the emulsion phase is estimated using a mass balance model. 3. The method of claim 1 , wherein the dielectric constant of the emulsion phase is determined based on the amplitude of the reflection of the electromagnetic wave from the interface and a dielectric constant of the oil phase. 4. The method of claim 3 , further comprising, prior to determining the dielectric constant of the emulsion phase: measuring an amplitude of a reflection of the electromagnetic wave off an interface between free space and the oil phase; and determining the dielectric constant of the oil phase based on the amplitude of the reflection of the electromagnetic wave off the interface between free space and the oil phase. 5. The method of claim 1 , wherein the water-in-liquid ratio of the emulsion phase is determined based on the dielectric constant of the emulsion phase and a dielectric constant of the oil phase. 6. The method of claim 1 , wherein the water-in-liquid ratio of the emulsion phase is determined based on the dielectric constant of the emulsion phase and a dielectric constant of the water phase. 7. The method of claim 1 , wherein the water-in-liquid ratio of the emulsion phase is also determined based on shear rate of the emulsion phase, salinity of the emulsion phase, and continuous phase transition of the emulsion phase. 8. The method of claim 1 , further comprising, prior to estimation of the thickness of the emulsion phase: determining the total height of the fluid as a function of an elapsed time between emitting the electromagnetic wave into the fluid and receiving a reflection of the electromagnetic wave from an interface between the water phase and a body holding the fluid; and determining the height of the coalescing portion of the interface between the oil phase and the emulsion phase as a function of an elapsed time between receiving a reflection of the electromagnetic wave from the coalescing portion and receiving a reflection of the electromagnetic wave from the interface between the water phase and the body holding the fluid. 9. The method of claim 1 , further comprising determining kinetics of separation of the emulsion phase as a function of the thickness of the emulsion phase. 10. The method of claim 1 , further comprising estimating a percentage of emulsion separation over time as a function of the thickness of the emulsion. 11. An apparatus comprising: a vessel containing a fluid having an oil phase, a water phase, and an emulsion phase between the oil phase and water phase; a guided wave radar associated with the vessel; and a computing device coupled to the guided wave radar and configured to: cause the guided wave radar to emit an electromagnetic wave into the fluid; measure an amplitude of a reflection of the electromagnetic wave off an interface between the oil phase and the emulsion phase, using the guided wave radar; determine a dielectric constant of the emulsion phase based on the amplitude of the reflection of the electromagnetic wave from the interface; determine a water-in-liquid ratio of the emulsion phase based on the dielectric constant; determine a height of a coalescing portion of the interface between the oil phase and the emulsion phase based on the emitted and reflected waves; determine a height of a creaming portion of the interface between the emulsion phase and the water phase based on a difference between a first product and a second product, wherein the first product comprises a product of a total height of the fluid and a total water-in-liquid ratio, and wherein the second product comprises a product of the height of a coalescing portion and the water-in-liquid ratio of the emulsion phase; and estimate a thickness of the emulsion phase from the difference between the height of the coalescing portion and the height of the creaming portion. 12. The apparatus of claim 11 , wherein the vessel comprises one of a closed tank, a closed pipe, and a separator. 13. The apparatus of claim 12 , wherein the vessel comprises a separator; and wherein the separator has components operable by the computing device; and wherein the computing device operates the components of the separator based on the water-in-liquid ratio or the thickness of the emulsion phase. 14. The apparatus of claim 11 , further comprising a sensor associated with the vessel; and wherein the computing device is also coupled to the sensor and configured to determine the water-in-liquid ratio of the fluid based upon output from the sensor in the vessel. 15. The apparatus of claim 11 , wherein the thickness of the emulsion phase is estimated using a mass balance model. 16. The apparatus of claim 11 , wherein the computing device determines the dielectric constant of the emulsion phase based on the amplitude of the reflection of the electromagnetic wave from the interface and a dielectric constant of the oil phase. 17. The apparatus of claim 11 , wherein the computing device determines the water-in-liquid ratio of the emulsion phase based on the dielectric constant of the emulsion phase and either a dielectric constant of the oil phase or a dielectric constant of the water phase. 18. The apparatus of claim 11 , wherein the computing device determines the water-in-liquid ratio of the emulsion phase based on shear rate of the emulsion phase, salinity of the emulsion phase, and continuous phase transition of the emulsion phase. 19. The apparatus of claim 11 , wherein the computing device is configured to determine the total height of the fluid as a function of an elapsed time between emitting the electromagnetic wave into the fluid and receiving a reflection of the electromagnetic wave from an interface between the water phase and a body holding the fluid; and determine the height of the coalescing portion of the interface between the oil phase and the emulsion phase as a function of an elapsed time between receiving a reflection of the electromagnetic wave from the coalescing portion and receiving a reflection of the electromagnetic wave from the interface between the water phase and the body holding the fluid.