SYSTEM AND METHOD FOR A PRECISION VARIABLE FOCUS TELESCOPE

Abstract

A system and method are disclosed for a precision variable-focus telescope that includes a telescope housing containing an optical system; a gap pad including a first side and a second side, wherein the first side of the gap pad is attached to the telescope housing; a heat spreader including a first side and a second side, wherein the heat spreader is contiguous with the telescope housing and wherein the second side of the heat spreader is attached to the second side of the gap pad; a temperature-sensing device connected to the first side of the heat spreader; and an electric-film heater including a first side and a second side, wherein the second side of the electric-film heater is attached to the first side of the heat spreader.

Claims

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; 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; and 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.

2. The precision variable-focus telescope of claim 2, further comprising a gap pad disposed between the telescope housing exterior and the heat spreader.

3. The precision variable-focus telescope of claim 2, wherein the gap pad comprises a material with a low thermal impedance.

4. The precision variable-focus telescope of claim 1, wherein the second side of the electric heater is coupled to the first side of the heat spreader by a pressure-sensitive adhesive.

5. The precision variable-focus telescope of claim 1, wherein the heat spreader comprises aluminum.

6. The precision variable-focus telescope of claim 1, wherein the electric heater comprises a polyimide foil.

7. The precision variable-focus telescope of claim 2, wherein the gap pad is contiguous with the heat spreader.

8. The precision variable-focus telescope of claim 1, wherein the electric heater is contiguous with the heat spreader.

9. The precision variable-focus telescope of claim 1, wherein the temperature-sensing device comprises a thermistor.

10. The precision variable-focus telescope of claim 1, wherein the heater spreader substantially surrounds the telescope housing exterior.

11. 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; at least one temperature sensing device coupled to a section of the first side of the heat spreader; and 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.

12. The precision variable-focus telescope of claim 11, further comprising a gap pad, wherein the gap pad is sandwiched between the telescope housing and the second side of the heat spreader.

13. The precision variable-focus telescope of claim 12, wherein the gap pad comprises a material with a low thermal impedance.

14. The precision variable-focus telescope of claim 11, wherein the second side of the electric-film heater is coupled to the first side of the heat spreader by a pressure-sensitive adhesive.

15. The precision variable- focus telescope of claim 11, wherein the electric-film heater comprises a polyimide foil.

16. The precision variable-focus telescope of claim 11, wherein the gap pad is contiguous with the heat spreader.

17. The precision variable-focus telescope of claim 11, where the electric-film heater is contiguous with the heat spreader.

18. The precision variable-focus telescope of claim 11, wherein the electric-film heater substantially surrounds the telescope housing.

19. The precision variable-focus telescope of claim 11, 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.

20. A precision variable-focus telescope heating mechanism control loop comprising: 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 the voltage across the heat spreader and controls the power applied to the heat spreader, maintaining the telescope at a desired temperature to achieve diffraction-limited performance.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] FIG. 1 is a perspective view of a precision variable-focus telescope according to one embodiment.

[0019] FIG. 2 is a cross-sectional view of a precision variable-focus telescope according to one embodiment.

[0020] FIG. 3A is an example embodiment of a block diagram of a precision variable-focus telescope heating mechanism control loop.

[0021] FIG. 3B is an example embodiment block diagram of a Field Programmable Gate Array (FPGA) contained within the precision variable-focus telescope heating mechanism control loop.

[0022] FIG. 3C is an alternative embodiment of a block diagram of a precision variable-focus telescope heating mechanism control loop.

[0023] FIG. 3D is an alternative block diagram of a Field Programmable Gate Array (FPGA) contained within the precision variable-focus telescope heating mechanism control loop.

[0024] FIG. 4 is a flow diagram of a method for focusing the optical system in a precision variable-focus telescope according to one embodiment.

[0025] These and other features of the present embodiments will be understood better by reading the following detailed description, taken together with the figures herein described. The accompanying drawings are intended to be drawn to scale. For purposes of clarity, not every component may be labeled in every drawing.

DETAILED DESCRIPTION

[0026] The present disclosure relates to the fine adjustment of telescope optical systems. More particularly, a telescope optical system with a temperature-based variable focus. The following description focuses on variable-focus telescopes capable of precision tuning of the fine focus while minimizing wave front error and without the need for mechanical actuation or movement of any lens elements within the telescope. The adjustment and determination of a desired telescope focus using a digital controller facilitates diffraction-limited performance over a wide temperature environment. Unlike passive athermalization, the thermo-optical coefficients are specifically chosen such that the optical system (i.e. telescope) has a known, non-zero, linear relationship between the defocus and temperature. This non-zero linear relationship between defocus and temperature allows precision control of the focus of the system through use of a thermal control loop. In other words, designing for this linear, but non-zero relationship allows for precision control of the focus of the optical system (i.e. telescope) that is not possible in state of the art designs. Various embodiments of the present disclosure will be described herein.

[0027] In accordance with an embodiment of the present disclosure, Table 1 shows the linear (but non-zero) relationship between telescope temperature and telescope focus for two units. A telescope's set point corresponds to a particular temperature, as represented on the x-axis. Optical performance is indicated on the y-axis as the power component of the wavefront error, also known as defocus. The difference in slopes is due to unit-to-unit variation (i.e. manufacturing tolerances). By precisely controlling the temperature of the telescope, the defocus of the telescope can be tightly controlled. Unit-to-unit variation in defocus can be calibrated by adjusting the temperature set-point for the desired focus.

[0028] In one embodiment, the telescope may be used as a stand-alone telescope. In an alternative embodiment, the telescope may be used in a larger optical system. Adjustment of the telescope through temperature control can be used to correct the defocus in a larger system where a telescope is used with additional external optics. The desired focus of a telescope, or a larger system including a telescope, can be maintained through a wide range of ambient temperatures. In various embodiments, heaters and heat spreaders are attached to a telescope, and in combination with a control loop, the telescope temperature remains constant even as ambient air conditions around the telescope vary.

[0029] Now turning to FIG. 1 and FIG. 2, therein is shown a precision variable-focus telescope 100 that has a telescope housing 110 and an optical system 120. By way of example, the telescope housing 110 may be comprised of titanium. A heat spreader 130 is attached or coupled to the telescope housing 110 either directly or indirectly. In one embodiment, the heat spreader 130 surrounds the telescope housing 110. Additionally, the heat spreader 130 may be contiguous with the periphery of the telescope housing 110. The heat spreader 130 may be one piece in one embodiment. In another embodiment, the heat spreader 130 may be machined in at least two parts. The heat spreader 130 parts may be connected or coupled by any suitable method, including but not limited to, screws, adhesives, and welds. By way of example, the heat spreader 130 may be comprised of aluminum.

[0030] At least one heater 140 is attached to the heat spreader 130 to regulate temperature of the precision variable-focus telescope 100. The heater 140 can be spread along sections of the heat spreader 130 and in patterns such as strips or rows to allow for effective heating. In one embodiment, the heater 140 is an electric-film heater that is contiguous with the heat spreader 130. The electric-film heater 140 has a resistance element to evenly heat the heat spreader 130. By way of example, the electric-film heater 140 may be comprised of polyimide foil. In one embodiment, the electric-film heater 140 is attached to the heat spreader 130 by pressure-sensitive adhesive. The composition of the adhesive should not interfere with the heating of the heat spreader 130. Other attachment mechanisms of the film heater 140 to the heat spreader 130 include screws, pins and posts.

[0031] In this example, at least one temperature-sensing device 150 is attached to the heat spreader 130 either directly or indirectly. The temperature-sensing device 150 may also be mounted elsewhere on the telescope. The temperature-sensing device 150 measures the temperature of the telescope 100. By way of example, the temperature-sensing device 150 may comprise a thermistor. In one example the temperature-sensing device 150 is located away from the heater 140. In another example there are multiple temperature-sensing device 150. According to one embodiment a temperature calibration table is used such a temperature of the telescope 100 is or any location thereof is established by knowing the temperature at the temperature-sensing device 150.

[0032] Turning now to FIG. 2, therein is shown a cross-sectional view of a precision variable-focus telescope 100 that has a telescope housing 110 and an optical system 120. In one embodiment, a gap pad 210 is sandwiched between the telescope housing 110 and the heat spreader 130. The gap pad 210 fills in the empty space between the heat spreader 130 and telescope housing 110 to evenly heat the telescope housing 110. In various embodiments, the gap pad 210 may be contiguous with the telescope housing 110 and the heat spreader 130. By way of example, the gap pad 210 may be comprised of a material with a low thermal impedance to transfer heat from the heat spreader 130 to the telescope housing 110.

[0033] Turning now to FIG. 3A, therein is shown one embodiment of a precision variable-focus telescope heating mechanism control loop 300. A temperature-sensing device 150 attached to the heat spreader 130 measures the temperature of the telescope 100. The temperature feedback from the sensing device 150 is an input to temperature digitization electronics that converts the temperature feedback to a reading that can be processed. The reading is an input to the telescope temperature input control, coupled to a sample rate count, which outputs the reading as a 12-bit telescope temperature. The 12-bit telescope temperature is an input to a 1-a filter unit that applies filter gain. The filtered telescope temperature is an input to the heater control. The temperature measurement is also an input to a Proportional/Integral controller (PID controller) 310 implemented within a controller such as a Field Programmable Gate Array (FPGA) 320, as shown in FIG. 3B. A temperature calibration table is used in one embodiment to provide a more precise temperature for the telescope.

[0034] Referring to FIG. 3B, the output of the PID controller 310 feeds the input to a switching power supply 330. By way of example, the switching power supply may be a buck (step-down), boost, buck-boost, isolated, or non-isolated switching power supply. This switching power supply 330 regulates the voltage across the electric film heater 140 that applies the heat energy to the heat spreader 130 thereby, maintaining the telescope 100 at a desired temperature to achieve diffraction-limited performance. In one embodiment, the temperature set-point for the control loop 300 is user-settable through a digital interface.

[0035] Turning now to FIG. 3C, therein is shown an alternative embodiment of a precision variable-focus telescope heating mechanism control loop 340. A temperature-sensing device 150 attached to the heat spreader 130 measures the temperature of the telescope 100. The temperature measurement is an input to a Proportional/Integral controller (PID controller) 310 implemented within a Field Programmable Gate Array (FPGA) 350, as shown in FIG. 3D. As further shown in FIG. 3D, the output of the PID controller 310 feeds the input to a linear power supply 360. This linear power supply 360 regulates the voltage across the electric film heater 140 and controls the power applied by the electric film heater 140, maintaining the telescope 100 at a desired temperature to achieve diffraction-limited performance. In one embodiment, the temperature set-point for the control loop 340 is user-settable through a digital interface.

[0036] Turning now to FIG. 4, there is shown a method for focusing the optical system in a precision variable-focus telescope 400 according to one embodiment. This method in this example includes observing the optical prescription to get a linear performance 410. The method also includes adjusting the course adjustment of the telescope optical system to a desired focus 420. In one embodiment, initial (course) adjustment of the desired focus utilizes a traditional method of adjusting and setting of lens optics within the telescope housing 110 while the telescope is heated to an initial value. The method further includes adjusting the heater driver set point temperature for fine adjustment of the telescope optical system 430. In one embodiment, fine (precision) adjustment of focus is accomplished by modifying the temperature of the telescope until diffraction-limited performance is achieved. In various embodiments, the range of temperature used to adjust the focus is greater than the maximum environmental temperature of the air surrounding the telescope 100. The constant heat flow into the telescope 100 eliminates the need to use cooling to maintain temperature. The method includes maintaining the heater driver set point temperature for diffraction-limited performance over a wide temperature environment 440. The method may also include characterizing the temperature of the telescope using a heater circuit over a defined temperature range 450.

[0037] According to one example, the heater maintains the temperature of the telescope housing at a certain range above ambient temperature. The temperature sensing can be measured at any region of the interior or exterior of the telescope housing for a relative reading that is correctable via calibration data. For example, a temperature of the interior of the telescope may be 10 degrees different than a temperature of the exterior of the telescope such that the system can measure at one location but can estimate the temperature at another region. By maintaining the temperature at a certain range above ambient temperature allows for a high degree of uniformity. In one example, the ambient temperature is measured or otherwise provided.

[0038] The foregoing description of the embodiments of the present disclosure has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the present disclosure to the precise form disclosed. Many modifications and variations are possible in light of this disclosure. It is intended that the scope of the present disclosure be limited not by this detailed description, but rather by the claims appended hereto.

[0039] A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the scope of the disclosure. Although operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed, to achieve desirable results.