Apparatus, systems, and methods for downhole fluid filtration

What is claimed is: 1. A fluid production system for downhole fluid purification, comprising: a filtering assembly configured to be disposed within a wellbore and having: a filter comprising a fluid inlet, a permeate outlet, a concentrated fluid outlet and an inner tubing extending in the direction of the longitudinal axis of the filter, wherein the inner tubing comprises a permeable wall portion; and a first pump comprising a suction port and a discharge port, wherein the suction port of the first pump is closely-coupled in fluid communication to the permeate outlet of the filter; a second pump comprising a suction port and discharge port, wherein the suction port of the second pump is closely-coupled in fluid communication to the concentrated fluid outlet of the filter; and an extension shaft extending from the first pump to a source of rotational power disposed adjacent the surface of the earth and configured to simultaneously rotate the first pump and the second pump to move fluid from the fluid inlet of the filter to the permeate outlet of the filter with the first pump and move fluid from the inlet of the filter to the concentrated fluid outlet of the filter with the second pump. 2. The fluid production system of claim 1 , wherein the filter includes a reverse osmosis membrane. 3. The fluid production system of claim 1 , wherein the source of rotational power for the first pump and the second pump comprises a first motor coupled to the extension shaft and electrically coupled to a first motor controller. 4. The fluid production system of claim 3 , wherein the first and second pumps are configured to have a constant pumping ratio. 5. The fluid production system of claim 1 , wherein the first and second pumps are configured to have a constant pumping ratio. 6. The fluid production system of claim 5 , wherein the first pump and the second pump are coupled together by an interconnecting shaft, configuring the two pumps to operate at a same rotational speed. 7. The fluid production system of claim 1 , further comprising: a production tubing having a first end and a tubing permeate discharge port displaced from the first end; wherein the first end is configured to couple to the discharge port of the first pump of the filtering assembly for fluid communication; and wherein the distance between the first end and the tubing permeate discharge port is less than a selected depth for the filtering assembly, thus configuring the tubing permeate discharge port to be subterranean. 8. A method for reducing the amount of dissolved constituents contained in a fluid, comprising: having a filtering assembly disposed in a first wellbore, wherein the filtering assembly comprises a membrane filter, a first pump closely-coupled to a first port of the membrane filter, a second pump closely-coupled to a concentrated fluid outlet of the membrane filter, and an inner tubing extending in the direction of the longitudinal axis of the membrane filter, wherein the inner tubing comprises a permeable wall portion; operating the first pump to move a first portion of a fluid from a fluid supply zone of the earth through the membrane filter of the filtering assembly to remove unwanted constituents, producing a purified permeate stream; operating the second pump simultaneously with the first pump to move a second portion of the fluid from the fluid supply zone of the earth through the filtering assembly, producing a concentrated fluid stream and achieving a constant ratio between the flow rate of the permeate stream and the concentrated fluid stream; and disposing of the concentrated fluid stream in a selected discharge zone within the earth. 9. The method of claim 8 , further comprising: coupling the first pump to the second pump; and maintaining the constant ratio between the flow rate of the permeate stream and the flow rate of the concentrated fluid stream during operation of each of the first pump and second pump. 10. The method of claim 8 , further comprising: selecting the discharge zone to be a zone that is in fluid communication with a hydrocarbon production zone of a second wellbore. 11. The method of claim 8 , further comprising: delivering at least a portion of the permeate stream to a selected permeable storage zone in the earth. 12. A fluid production system to desalinate water from a subterranean source, comprising: a filtering assembly configured for installation within a first wellbore, the filtering assembly comprising: a membrane filter comprising a fluid inlet, a permeate outlet, and a concentrated fluid outlet; a first pump having a discharge port and a suction port, the suction port coupled to the permeate outlet for fluid communication; and a second pump having a discharge port and a suction port, the suction port coupled to the concentrated fluid outlet for fluid communication; and an inner tubing extending in the direction of the longitudinal axis of the membrane filter, wherein the inner tubing comprises a permeable wall portion; wherein the first pump and the second pump are configured to simultaneously operate to move fluid from the fluid inlet of the membrane filter to the permeate outlet of the membrane filter with the first pump and move fluid from the inlet of the membrane filter to the concentrated fluid outlet of the membrane filter with the second pump. 13. The fluid production system of claim 12 , further comprising: an extension shaft extending from the first pump toward the surface of the earth; a first motor disposed adjacent the surface of the earth and coupled to the extension shaft; and a first motor controller electrically coupled to the first motor; wherein the second pump includes a submersible electrical motor electrically coupled to a second motor controller. 14. The fluid production system of claim 12 , wherein the first and second pumps are positive displacement pumps, the filtering assembly further comprising: an interconnecting shaft coupling together the two pumps, configuring the two pumps to operate at a same rotational speed and to achieve a constant pumping ratio. 15. The fluid production system of claim 12 , further comprising: a motor coupled to at least one of the two pumps; and a motor controller electrically coupled to the motor; wherein the motor controller is configured to achieve a constant pumping ratio for the first and second pumps. 16. The fluid production system of claim 12 , further comprising: a production tubing having a first end and a tubing permeate discharge port displaced from the first end; wherein the first end is configured to couple the discharge port of the first pump for fluid communication therebetween; a first packing member coupled to the membrane filter and having a flow passage in fluid communication with the second pump and the concentrated fluid outlet of the filter; a second packing member configured to seal between the production tubing and the first wellbore; and a third packing member displaced from the second packing member and configured to seal the first wellbore; wherein the second packing member is disposed between the first and third packing members; and wherein the tubing permeate discharge port is disposed between the second packing member and the third packing member, thus configuring the tubing permeate discharge port to be subterranean. 17. The fluid production system of claim 12 , wherein the first wellbore extends into each of a permeable fluid supply zone in the earth and a permeable fluid discharge zone in the earth axially displaced from the