Detecting a fraction of a component in a fluid

What is claimed is: 1. An apparatus comprising: a production tubing disposed within a borehole to carry fluids from one or more producing zones to a surface; a three-way valve coupled to the production tubing, the three-way valve including an inlet formed by the production tubing, an outlet formed by the production tubing, a borehole inlet configured to receive fluid flow from the borehole surrounding the three-way valve, and a mixing chamber disposed between the inlet formed by the production tubing and the outlet formed by the production tubing, wherein the three-way valve is configured such that inflow from the inlet formed by the production tubing and inflow from the borehole inlet converge in the mixing chamber from which the converged inflows flow out from the outlet formed by the production tubing; a first resonant tube densitometer disposed in at least one of the outlet formed by the production tubing and the inlet formed by the production tubing, said first resonant tube densitometer configured to measure density of the fluids; and a first flow meter disposed in at least one of the outlet formed by the production tubing and the inlet formed by the production tubing, the first flow meter configured to measure volumetric flow of the fluids. 2. The apparatus of claim 1 , wherein said first resonant tube densitometer is formed from a longitudinal section of the production tubing, said apparatus further comprising an upper packer and a lower packer that anchor the longitudinal section of the production tubing. 3. The apparatus of claim 2 , further comprising a pressure holding shroud around the longitudinal section of the production tubing. 4. The apparatus of claim 2 , further comprising a vibration emitter coupled to the longitudinal section of the production tubing. 5. The apparatus of claim 4 , wherein the vibration emitter includes one or more of a piezoelectric source, a mechanical hammer, a mechanical tapper, and a generator of micro-explosions. 6. The apparatus of claim 2 , further comprising a vibration sensor coupled to the longitudinal section of the production tubing. 7. The apparatus of claim 6 , wherein the vibration sensor includes one or more of an accelerometer, an optical sensor, a piezoelectric sensor, a flexoelectric sensor, and an electric strain gauge. 8. The apparatus of claim 1 , wherein said first resonant tube densitometer uses a flow of fluid through the production tubing as a source of vibrations. 9. The apparatus of claim 1 , further comprising: a second resonant tube densitometer disposed in the inlet formed by the production tubing, the second resonant tube densitometer configured to measure the density of the fluids; and a second flow meter disposed in the inlet formed by the production tubing, the second flow meter configured to measure volumetric flow of the fluids. 10. The apparatus of claim 9 , further comprising: a third resonant tube densitometer disposed in the borehole inlet, the third resonant tube densitometer configured to measure the density of the fluids; and a third flow meter disposed in the borehole inlet, the third flow meter configured to measure volumetric flow of the fluids. 11. The apparatus of claim 10 , further comprising: a processor configured to receive outputs from two or more of the first resonant tube densitometer, the first flow meter, the second resonant tube densitometer, the second flow meter, the third resonant tube densitometer, and the third flow meter, and wherein the processor is configured to determine a fraction of a subject fluid in a fluid flowing through the production tubing based on one or more of the outputs. 12. The apparatus of claim 11 , further comprising: a controllable inflow valve that controls fluid input through the borehole inlet, wherein the controllable inflow valve is configured to adjust flow through the borehole inlet based on the determined fraction of the subject fluid. 13. The apparatus of claim 1 , further comprising: a second resonant tube densitometer disposed in the borehole inlet, the second resonant tube densitometer configured to measure the density of the fluids; and a second flow meter disposed in the borehole inlet, the second flow meter configured to measure volumetric flow of the fluids. 14. The apparatus of claim 13 , further comprising: a third resonant tube densitometer disposed in the inlet formed by the production tubing, the third tube resonant densitometer configured to measure the density of the fluids; and a third flow meter disposed in the inlet formed by the production tubing, the third flow meter configured to measure volumetric flow of the fluids. 15. The apparatus of claim 14 , further comprising: a processor configured to receive outputs from two or more of the first resonant tube densitometer, the first flow meter, the second resonant tube densitometer, the second flow meter, the third resonant tube densitometer, and the third flow meter, and wherein the processor is configured to determine a fraction of a subject fluid in a fluid flowing through the production tubing based on one or more of the outputs; and a controllable inflow valve that controls fluid input through the borehole inlet, wherein the controllable inflow valve is configured to adjust flow through the borehole inlet based on the determined fraction of the subject fluid. 16. The apparatus of claim 1 , further comprising a side tube coupled in parallel with a segment of the production tubing and forming a portion of the outlet formed by the production tubing such that a portion of the fluids flow through the side tube, and wherein the first resonant tube densitometer and the first flow meter are disposed within the side tube. 17. A system comprising: a production tubing penetrating an upper zone and a lower zone in a well; a lower zone valve having: a lower zone input coupled to the lower zone by which fluids from the lower zone enter the lower zone valve; a lower zone output by which fluid from the lower zone valve enters the production tubing; a lower zone control to control an amount of fluid from the lower zone valve that enters the production tubing; and a lower zone cut computer to measure a fraction of a subject fluid in a fluid flowing into the lower zone input; an upper zone valve having: a first upper zone input coupled to the lower zone output of the lower zone valve through the production tubing; a second upper zone input coupled to the upper zone by which fluids from the upper zone enter the upper zone valve; an upper zone output by which fluid from the upper zone valve enters the production tubing; an upper zone control to control an amount of fluid from the upper zone valve that enters the production tubing; and an upper zone cut computer to measure a fraction of the subject fluid in a fluid flowing into the second upper zone input; and a subject fluid controller coupled to the lower zone control and the upper zone control to control the amount of fluid from the lower zone valve that enters the production tubing and amount of fluid from the upper zone valve that enters the production tubing based on the fraction of the subject fluid in a fluid flowing into the lower zone input and the fraction of the subject fluid in a fluid flowing into the second upper zone input; wherein one of the lower zone control or the upper zone control has: a resonant tube densitometer to measure density of the fluids carried by the production tubing, the resonant tube densitometer having a tube; wherein a longitudinal section of the production tubing is t