Low power control system for an elevated work platform

The invention claimed is: 1. An elevated work platform comprising: a boom presenting proximal and distal ends; a platform located proximate the boom distal end; a hydraulic control valve generally proximate the boom proximal end; an electronic valve controller for controlling the hydraulic control valve; a control interface communicatively coupled with the platform for receiving operating commands from a user and communicating the operating commands to the electronic valve controller, the control interface including— a multi-function single hand control with a set of position indicating elements for detecting actuation of the single hand control, a master enable switch communicatively coupled with the set of position indicating elements, and a set of individual enable elements, wherein each individual enable element in the set of individual enable elements is communicatively coupled with one of the position indicating elements in the set of position indicating elements, wherein the set of individual enable elements includes a first enable element and the set of position indicating elements includes a first position indicating element, wherein the first enable element is communicatively coupled with the first position indicating element; and a controller for controlling operation of the control interface, the controller configured to sample the first position indicating element only if the master enable switch is actuated and the first individual enable element is actuated asserted, said controller being configured to— operate in a normal operating mode, wherein the controller periodically reads the master enable switch and, if the master enable switch is actuated, samples the first position indicating element if the first individual enable element is actuated, if the master enable switch is not actuated for a predetermined amount of time, operate in a low power mode, wherein the controller reads the master enable switch less frequently than in the normal operating mode, and return to the normal operating mode when it samples one of the position indicating elements within the set of position indicating elements. 2. The elevated work platform of claim 1 , each of the position indicating elements within the set of position indicating elements including a respective potentiometer. 3. The elevated work platform of claim 2 , each of the respective potentiometers having a maximum impedance of between 200Ω and 10 kΩ. 4. The elevated work platform of claim 3 , the control interface further including a capacitor configured to energize a first potentiometer of said respective potentiometers when the controller samples said first potentiometer. 5. The elevated work platform of claim 4 , the control interface further including a high impedance circuit configured to charge the capacitor, the high impedance circuit having an impedance of at least 500 kΩ. 6. The elevated work platform of claim 4 , the controller being configured to sample the first potentiometer to determine the position of the first potentiometer by applying a voltage to the first potentiometer from the capacitor and measuring the voltage at a wiper of the first potentiometer. 7. The elevated work platform of claim 6 , the controller being configured to sample the first potentiometer in less than five microseconds. 8. The elevated work platform of claim 4 , the controller further configured to— identify a fault in the first position indicating element if a voltage reading on the capacitor after applying the voltage is below a predetermined lower threshold level or above a predetermined upper threshold level, and prevent sampling of the first position indicating element in which the fault was identified after the fault is detected. 9. The elevated work platform of claim 1 , the electronic valve controller including a receiver for receiving a signal from the control interface, the receiver including a gain function and being configured to automatically adjust a gain level so that an output of the gain function remains constant as a strength of the received signal fluctuates. 10. The elevated work platform of claim 1 , the electronic valve controller configured to confirm that a control signal received from the control interface includes valid signal values, and to disable the hydraulic valve if the control signal includes one or more invalid signal values. 11. The elevated work platform of claim 1 , further comprising a fiber optic communications link or a wireless communications link for communicating control signals from the control interface to the electronic valve controller. 12. An elevated work platform comprising: a boom presenting proximal and distal ends; a platform located proximate the boom distal end; a hydraulic control valve generally proximate the boom proximal end; an electronic valve controller for controlling the hydraulic control valve; a control interface communicatively coupled with the platform for receiving operating commands from a user and communicating the operating commands to the electronic valve controller, the control interface including— a multi-function single hand control with a set of position indicating elements for detecting actuation of the single hand control, wherein each of the position indicating elements in the set of position indicating elements includes a respective potentiometer, a master enable switch communicatively coupled with the set of position indicating elements, a set of individual enable elements, wherein each individual enable element in the set of individual enable elements is communicatively coupled with one of the position indicating elements in the set of position indicating elements, wherein the set of individual enable elements includes a first individual enable element and the set of position indicating elements includes a first position indicating element and a first potentiometer of said respective potentiometers, wherein the first enable element is communicatively coupled with the first position indicating element, wherein the first potentiometer is included in the first position indicating element, a capacitor configured to energize the first potentiometer, and a high impedance circuit configured to charge the capacitor, the high impedance circuit having an impedance of at least 500 kΩ; and a controller for controlling operation of the control interface, the controller configured to sample the first position indicating element only if the master enable switch is actuated and the first individual enable element is actuated, wherein the capacitor energizes the first potentiometer when the controller samples the first potentiometer. 13. The elevated work platform of claim 12 , the controller being configured to sample the first potentiometer to determine the position of the first potentiometer by applying a voltage to the first potentiometer from the capacitor and measuring the voltage at a wiper of the first potentiometer. 14. The elevated work platform of claim 13 , the controller being configured to sample the first potentiometer in less than five microseconds. 15. The elevated work platform of claim 12 , the controller further configured to— identify a fault in the first position indicating element if a voltage reading on the capacitor after applying the voltage is below a predetermined lower threshold level or above a predetermined upper threshold level, and prevent sampling of the first position indicating element in which the fault was identified after the fault is detected. 16. The elevated work platform of claim 12 , the elect