Intelligent belt drive system and method

What is claimed: 1. A tensioning system for tensioning an endless drive member in a vehicle, comprising: a tensioner including a tensioner pulley that is movable between a free arm stop position and a load stop position, and further including a tensioner actuator operable to exert an actuator force on the tensioner pulley to drive the tensioner pulley towards the free arm position; and a tensioner control system operatively connected to the tensioner actuator to control the actuator force on the tensioner pulley, wherein the tensioner control system is operatively connected to at least one vehicle accessory that is driven by the endless drive member, wherein the tensioner control system is programmed to: a) issue commands for controlling the operation of said at least one vehicle accessory so as to control the tension in the endless drive member; and b) control the actuator force on the tensioner pulley to control the tension in the endless drive member based at least in part on the issued command, wherein the tensioner control system is configured to receive signals indicative of the speed of the tensioner pulley and the speed of at the at least one vehicle accessory, and is programmed to: determine the amount of slip that exists between the endless drive member and the at least one vehicle accessory based on the speed of the tensioner pulley and the speed of the at least one accessory; and control the actuator force to control the amount of slip. 2. A tensioning system as claimed in claim 1 , wherein the vehicle includes a engine control unit that is operatively connected to the at least one vehicle accessory, and wherein the tensioner control system is programmed to issue the commands for controlling the operation of the at least one vehicle accessory to the engine control unit, and is further programmed to determine whether the engine control unit will execute the commands or not. 3. A tensioning system as claimed in claim 1 , wherein the at least one vehicle accessory includes an alternator and wherein the tensioner control system is configured to receive signals indicative of the speed of the alternator, the temperature of the alternator and the voltage output of the alternator, and wherein the tensioner control system is programmed to control the operation of the alternator based on the level of charge in a vehicle battery that is charged by the alternator, and based on the tension in the endless drive member. 4. A tensioning system as claimed in claim 1 , wherein the at least one vehicle accessory includes a first vehicle accessory and a second vehicle accessory, wherein the tensioner control system is further programmed to: control the tension in the endless drive member by preventing full operation of the first vehicle accessory and permit the operation of the second vehicle accessory when the tensioner control system determines that operation of the second vehicle accessory is needed and that full operation of the first vehicle accessory is not needed; and control the tension in the endless drive member by preventing full operation of the second vehicle accessory and permit the operation of the first vehicle accessory when the tensioner control system determines that operation of the first vehicle accessory is needed and that full operation of the second vehicle accessory is not needed. 5. A tensioning system as claimed in claim 4 , wherein the tensioner control system is further programmed to: control the actuator force on the tensioner pulley to increase tension in the endless drive member when the tensioner control system determines that full operation of both the first vehicle accessory and the second vehicle accessory is needed. 6. A tensioning system as claimed in claim 1 , wherein the tensioner includes: a pivot shaft that is fixedly mountable with respect to an engine block of an engine in the vehicle; a tensioner arm rotatably mounted to the pivot shaft for pivoting about a tensioner arm axis between the free arm stop position and the load stop position, wherein the pulley is rotatably mounted to the tensioner arm; and a tensioner spring positioned to exert a biasing force on the tensioner arm to bias the tensioner arm towards the free arm stop position, wherein the tensioner spring has a first end and a second end, wherein the first end is engaged with the tensioner arm. 7. A tensioning system as claimed in claim 6 , wherein the tensioner actuator is operatively connected to control the position of the second end of the tensioner spring so as to control the biasing force exerted by the tensioner spring on the tensioner arm. 8. A tensioning system as claimed in claim 1 , wherein the vehicle includes an engine control unit that is operatively connected to the at least one vehicle accessory, and wherein the tensioner control system is programmed to issue the commands for controlling the operation of the at least one vehicle accessory directly to the at least one vehicle accessory, and wherein operation of the at least one accessory under the control of the tensioner control system requires permission by the engine control unit. 9. A tensioning system for tensioning an endless drive member in a vehicle, comprising: a tensioner including a tensioner pulley that is movable between a free arm stop position and a load stop position, and further including a tensioner actuator operable to exert an actuator force on the tensioner pulley to drive the tensioner pulley towards the free arm position; and a tensioner control system operatively connected to the tensioner actuator to control the actuator force on the tensioner pulley, wherein the tensioner control system is configured to receive signals indicative of the state of at least one vehicle component aside from the tensioner, wherein the tensioner control system is programmed to: a) determine whether or not a load increase on the endless drive member is imminent, and b) control the actuator force based on the determination in step a) and substantially prior to the load increase, c) determine whether or not slip of the endless drive member is imminent, and d) control the actuator force based on the determination in step c), e) determine whether the ambient humidity is above a selected threshold; f) control the actuator force based on the determination in step e).