Downhole fluid flow control system and method having autonomous closure

What is claimed is: 1. A downhole fluid flow control system comprising: a flow control assembly having a fluid flow path for a flowing fluid; a first flow control component disposed in the fluid flow path having a positive flowrate response to decreasing fluid viscosity; a second flow control component disposed in the fluid flow path in parallel with the first flow control component having a negative flowrate response to decreasing fluid viscosity; and a valve disposed in the fluid flow path in series with and downstream of the first and second flow control components, the valve having a single valve seat, a plug, a discharge port, a first inlet path for fluid from the first flow control component and a second inlet path for fluid from the second flow control component, wherein the single valve seat circumscribes the discharge port and is disposed between the discharge port and both of the first and second inlet paths such that fluid flows through the single valve seat from both of the first and second to the discharge port, wherein, decreasing the fluid viscosity of the flowing fluid increases a ratio of the flowrate through the first flow control component to the flowrate through the second flow control component; wherein fluid flow into the first inlet path of the valve from the first flow control component biases the plug toward the single valve seat and fluid flow into the second inlet path of the valve from the second flow control component biases the plug away from the single valve seat; and wherein, when the ratio reaches a predetermined level, the valve autonomously shifts from an open position wherein the plug is remote from the single valve seat to a closed position wherein the plug is forced against the single valve seat to prohibit fluid flow through the discharge port. 2. The downhole fluid flow control system as recited in claim 1 wherein the first and second flow control components have viscosity dependent fluid flow resistance. 3. The downhole fluid flow control system as recited in claim 1 wherein the first flow control component is selected from the group consisting of nozzles, flow tubes, labyrinths and fluid selectors. 4. The downhole fluid flow control system as recited in claim 1 wherein the second flow control component is selected from the group consisting of vortex chambers, fluid selectors, fluid disrupters and fluid diodes. 5. The downhole fluid flow control system as recited in claim 1 wherein the valve further comprises a magnet, and wherein the magnet supports the plug remote from the single valve seat when the valve is in the open position. 6. The downhole fluid flow control system as recited in claim 1 wherein the first inlet path further comprises a plurality of first inlet openings and wherein the second inlet path further comprises a plurality of second inlet openings. 7. The downhole fluid flow control system as recited in claim 1 wherein fluid flow into the first inlet path of the valve from the first flow control component enters the valve in at least one substantially longitudinal direction and fluid flow into the second inlet path of the valve from the second flow control component enters the valve in at least one substantially radial direction. 8. The downhole fluid flow control system as recited in claim 1 wherein the plug is supported between the first inlet path and the second inlet path such that the directionality of the fluid impacting plug from the first inlet path and second inlet path biases the plug toward and away from the valve seat, respectively. 9. A flow control screen comprising: a base pipe with an internal passageway; a filter medium positioned around the base pipe; a housing positioned around the base pipe defining a fluid passageway between the filter medium and the internal passageway; a flow control assembly positioned in the fluid passageway, the flow control assembly having a fluid flow path for a flowing fluid; a first flow control component disposed in the fluid flow path having a positive flowrate response to decreasing fluid viscosity; a second flow control component disposed in the fluid flow path in parallel with the first flow control component having a negative flowrate response to decreasing fluid viscosity; and a valve disposed in the fluid flow path in series with and downstream of the first and second flow control components, the valve having a single valve seat circumscribing a discharge port, a plug, a first inlet path for fluid from the first flow control component and a second inlet path for fluid from the second flow control component, wherein, decreasing the fluid viscosity of the flowing fluid increases a ratio of the flowrate through the first flow control component to the flowrate through the second flow control component; wherein fluid flow into the first inlet path of the valve from the first flow control component biases the plug toward the single valve seat and fluid flow into the second inlet path of the valve from the second flow control component biases the plug away from the single valve seat; and wherein, when the ratio reaches a predetermined level, the valve autonomously shifts from an open position wherein the plug is remote from the single valve seat and fluid flow is permitted through the valve from both the first and second inlet paths, to a closed position wherein the plug is forced against the single valve seat to prohibit fluid flow through the valve. 10. The flow control screen as recited in claim 9 wherein the first and second flow control components have viscosity dependent fluid flow resistance. 11. The flow control screen as recited in claim 9 wherein the valve further comprises a magnet, wherein the magnet supports the plug remote from the single valve seat when the valve is in the open position. 12. The flow control screen as recited in claim 9 wherein the first inlet path further comprises a plurality of first inlet openings and wherein the second inlet path further comprises a plurality of second inlet openings. 13. The flow control screen as recited in claim 9 wherein fluid flow into the first inlet path of the valve from the first flow control component enters the valve in at least one substantially longitudinal direction and fluid flow into the second inlet path of the valve from the second flow control component enters the valve in at least one substantially radial direction. 14. A downhole fluid flow control method comprising: positioning a fluid flow control system at a target location downhole, the fluid flow control system including a flow control assembly having a fluid flow path for a flowing fluid, first and second flow control components disposed in parallel in the fluid flow path, the first flow control component having a positive flowrate response to decreasing fluid viscosity and the second flow control component having a negative flowrate response to decreasing fluid viscosity and a valve disposed in the fluid flow path in series with and downstream of the first and second flow control components, the valve having a valve seat, a plug and first and second inlet paths for fluid from the first and second flow control components, respectively; flowing fluid through the fluid flow path of the flow control assembly through the first and second flow control components and the valve; biasing the plug toward the valve seat responsive to fluid flow into the first inlet path of the valve from the first flow control component and biasing the plug away from the valve seat responsive to fluid flow into the second inlet path of the valve from the second flow control component; decreasing the fluid visc