System and method for a precision variable focus telescope

What is claimed is: 1. A precision variable-focus telescope, comprising: a telescope housing comprising an interior and an exterior, wherein the telescope housing interior contains an optical system, wherein the optical system comprises a plurality of lenses having thermo-optical coefficients with a non-zero linear relationship between defocus and temperature; a heat spreader comprising a first side and a second side, wherein the second side of the heat spreader is coupled to the telescope housing exterior; a temperature-sensing device coupled to the first side of the heat spreader; a heater comprising a first side and a second side, wherein the second side of the heater is coupled to the first side of the heat spreader; and a gap pad having low thermal impedance disposed between the telescope housing exterior and the heat spreader. 2. The precision variable-focus telescope of claim 1 , wherein the gap pad comprises a material with a low thermal impedance. 3. The precision variable-focus telescope of claim 1 , wherein the second side of the heater is coupled to the first side of the heat spreader by a pressure-sensitive adhesive. 4. The precision variable-focus telescope of claim 1 , wherein the heat spreader comprises aluminum. 5. The precision variable-focus telescope of claim 1 , wherein the heater comprises a polyimide foil. 6. The precision variable-focus telescope of claim 1 , wherein the gap pad is contiguous with the heat spreader. 7. The precision variable-focus telescope of claim 1 , wherein the heater is contiguous with the heat spreader. 8. The precision variable-focus telescope of claim 1 , wherein the temperature-sensing device comprises a thermistor. 9. The precision variable-focus telescope of claim 1 , wherein the heater spreader substantially surrounds the telescope housing exterior. 10. A precision variable-focus telescope comprising: a heat spreader comprising a first side and a second side, wherein the second side of the heat spreader is coupled to a telescope housing, wherein the telescope housing contains an optical system, wherein the optical system comprises a plurality of lenses having thermo-optical coefficients with a non-zero linear relationship between defocus and temperature; at least one temperature sensing device coupled to a section of the first side of the heat spreader; at least one electric-film heater comprising a first side and a second side, wherein the second side of the electric-film heater is coupled to a section the first side of the heat spreader; and a gap pad having low thermal impedance, wherein the gap pad is sandwiched between the telescope housing and the second side of the heat spreader. 11. The precision variable-focus telescope of claim 10 , wherein the gap pad comprises a material with a low thermal impedance. 12. The precision variable-focus telescope of claim 10 , wherein the second side of the electric-film heater is coupled to the first side of the heat spreader by a pressure-sensitive adhesive. 13. The precision variable-focus telescope of claim 10 , wherein the electric-film heater comprises a polyimide foil. 14. The precision variable-focus telescope of claim 10 , wherein the gap pad is contiguous with the heat spreader. 15. The precision variable-focus telescope of claim 10 , where the electric-film heater is contiguous with the heat spreader. 16. The precision variable-focus telescope of claim 10 , wherein the electric-film heater substantially surrounds the telescope housing. 17. The precision variable-focus telescope of claim 10 , further comprising a controller is communicatively coupled to the electric film heater and the temperature sensing device, wherein the controller maintains a desired temperature to achieve diffraction-limited performance. 18. A precision variable-focus telescope heating mechanism control loop comprising: a heater; a heat spreader; a temperature-sensing device attached to the heat spreader; a controller, wherein the controller receives a digitized temperature from the temperature sensing device; a proportional/integral controller (PID controller) comprising an input and output, wherein the PID controller is implemented by the controller; and a linear power supply comprising an input and output, wherein the input of the linear power supply receives the output signal from the PID controller; wherein the linear power supply output regulates a voltage across the heater and controls a power applied to the heater, maintaining a telescope at a desired temperature to achieve diffraction-limited performance, wherein the telescope comprises a plurality of lenses having thermo-optical coefficients with a non-zero linear relationship between defocus and temperature.