Integrated light concentrator
An infrared sensor including an absorber for absorbing incident infrared power to produce a signal representing the temperature of a target object, a frame supporting a membrane which carries the absorber, the frame including a plurality of reflecting surfaces disposed about the circumference of an opening over which the membrane spans for reflecting incident infrared power toward the absorber. By concentrating incident infrared power through reflection, the temperature difference between the absorber and the surrounding frame is increased, thereby producing an increased electrical output from the sensor.
Latest Patents:
The present invention relates generally to infrared detectors and, more specifically, to a thermopile infrared detector having an integrated light concentrator to increase the amount of infrared power sensed by the detector.
BACKGROUND OF THE INVENTIONNon-contact temperature measurement may be accomplished using a conventional infrared detector. Such infrared detectors are suitable for a variety of applications, including HVAC control systems for automotive applications. In this application, infrared detectors are directed toward the driver and passenger in the vehicle. The detectors sense the infrared power emitted from the occupants' skin, clothing, and surrounding portions of the vehicle interior, and convert that power to heat. Thermocouples in the detector convert the heat flux to a corresponding sensor output voltage which represents the temperature of the object.
More specifically, conventional thermopile detectors include a silicon frame which defines an opening. A thermally isolating membrane spans the opening. An absorber region is created on the membrane and is centered in the opening. The portion of the membrane between the outer dimensions of the absorber region and the inner dimensions of the opening thermally isolates the absorber region from the frame.
A plurality of thermocouples are connected in series and extend across this thermally isolating portion of the membrane between the frame and the absorber. As incident infrared light reaches the absorber, the infrared power is absorbed, and the temperature of the absorber changes. This temperature change results in a change in the Seebeck voltage from the thermocouples, between the ends of the thermocouples connected to the frame and the ends of the thermocouples connected to the absorber. Since the thermocouples are connected in series, the voltage change across each thermocouple is added to the voltage of the remaining thermocouples.
Unfortunately, sensed changes in temperature result in relatively small changes in output voltage of such sensors. Accordingly, it is desirable to increase the output voltage to improve the resolution of the device. One way to increase the output voltage change due to a temperature change of a target object is by increasing the amount of infrared radiation received by the sensor by using a lens such as a refractive lens or a fresnel lens. Refractive lenses made of infrared transmitting materials, however, are typically expensive and must be carefully positioned. Fresnel lenses, which use diffraction, require a relatively large distance between the lens and the absorber, resulting in a larger sensor package. Alternatively, curved surfaces of revolution, or a Winston light concentrator in which a section of a parabola is revolved to form the reflecting surface, could be incorporated into the device. However, the manufacturing process for micromachined devices such as thermopile infrared detectors makes the incorporation of such shapes for each detector commercially undesirable.
SUMMARY OF THE INVENTIONThe present invention provides an infrared sensor including an absorber for absorbing incident infrared power to produce a signal representing the temperature of a target object and a frame supporting the absorber which includes a plurality of reflecting surfaces disposed about the circumference of the absorber for reflecting incident infrared power toward the absorber to increase the output voltage resulting from a given change in temperature of the target object. In one embodiment of the invention, the reflection surfaces are formed on the etched sidewalls of the cavity which are created behind a membrane including the absorber. The cavity is formed during the standard fabrication process of the thermopile. As infrared power reaches the sensor, incident infrared power is reflected off of the reflecting surfaces toward the absorber, thereby increasing the difference in temperature between the absorber and the frame. The reflecting surfaces may be covered with a metal film to further increase the absorbed power of the sensor.
According to another embodiment of the invention, a separate rectangular frame structure is produced by micromachining silicon to form a light concentrator that may be attached to the front side of a thermopile sensor using appropriate adhesive material. The light concentrator includes reflecting surfaces which also reflect incident infrared power to the absorber. In this embodiment, metal may be deposited on the entire frame during a fabrication step already used to manufacture the thermopile detector.
These and other features of the present invention will become more apparent and the invention will be better understood upon consideration of the following description and the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
The embodiments of the invention described herein are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Rather, the embodiments selected for description have been chosen to enable one skilled in the art to practice the invention.
Membrane 16 is supported by frame 12 according to principles well known in the art, and spans opening 22. Absorber 14 is prepared in the central region of membrane 16 in a conventional manner. The plurality of thermocouples 18, which together constitute the thermopile, are also prepared on membrane 16 and extend between absorber 14 and frame 12. As is commonly known in the art, thermocouples 18 are connected in series such that the Seebeck voltage of each thermocouple 18 is added to the Seebeck voltage of the remaining thermocouples to result in an overall induced voltage due to the change in temperature between absorber 14 and frame 12. The output signal (a voltage measured across the total resistance of thermocouples 18) is measured at pads 36, 38. Pad 36 is connected to one end of the plurality of series connected thermocouples 18, and pad 38 is connected to the other end of the plurality of series connected thermocouples 18. When employed in a conventional application, side 40 of sensor 10 is directed toward the target object to receive incident infrared power. Side 42 is directed away from the target object.
Referring now to
Referring now to
Referring again to
Reflecting surfaces 44, 46, 48, 50 may be coated using a variety of conventional techniques. For example, metal may be evaporated or sputtered in a vacuum at an angle such that one portion of body 20 masks or shadows membrane 16 and absorber 14, but permits coating of one of the reflecting surfaces. For example, if metal is directed toward body 20 along the direction indicated by arrow G in
Silicon window 54 roughly corresponds to the size or footprint of body 20 of frame 12. Window 54 includes an upper surface 78, a lower surface 80, side surfaces 82, 84, and two other side surfaces (not shown) which are aligned with side surfaces 26, 30 of frame 12. Window 54 is attached to end surface 34 of frame 12 with glass frit 86 or some other conventional attachment structure. By enclosing the cavity formed by reflecting surfaces 44, 46, 48, 50 and membrane 16, window 54 isolates absorber 14 from convective air currents which may influence the temperature change of absorber 14.
Window 54 further includes an anti-reflection coating 88 applied to upper surface 78 and an interference filter coating 90 applied to lower surface 80. As is commonly known in the art, since silicon has a high index of refraction, an anti-reflection coating is desirable to permit better infrared transmission through window 54 and to prevent incident infrared power from being reflected off of surface 78. Interference filter coating 90 is designed to reduce the short wavelength end of the spectrum of light entering sensor 10. As is known in the art, these visible light components may affect the infrared measurement of absorber 14.
In operation, infrared power is transmitted through silicon window 54 into the cavity formed by a reflecting surfaces 44, 46, 48, 50. Some of the power passes directly to absorber 14 to result in a temperature change between absorber 14 and body 20 of frame 12. Additional power is reflected off of metal coatings 44A, 46A, 48A, and 50A of reflecting surfaces 44, 46, 48, 50, respectively, and directed toward absorber 14 as best shown in
Referring now to
Light concentrator 104 is a separate, micromachined silicon component which is etched using the same technology and processing steps used to form the cavity below membrane 16 of thermopile 100. It should be understood that entire wafers of light concentrators 104 and entire wafers of bodies 20 are produced prior to assembly as sensors 100. A wafer of light concentrators 104 is joined to a wafer of bodies 20, and sensors 100 are individually sawed from the joined wafers. Light concentrator 104 has four main portions or sections, including a first segment 108, a second segment 110, a third segment 112, and a fourth segment 114. Segments 108, 110, 112, 114 include outer surfaces 116, 118, 120, 122, inner surfaces 124, 126, 128, 130, respectively, a shared upper surface 132, and a lower surface 134. As best shown in
During assembly, light concentrator 104 is positioned over opening 22 and attached to body 20 using adhesive material 106. Once attached, as shown in
Segments 224, 226, 228, 230 share an upper surface 240. A silicon window 242 is attached to surface 240 using conventional techniques. Silicon window 242 includes an anti-reflection coating 244 and an interference filter coating 246 which are identical to those described above in conjunction with the description of
Another embodiment of an infrared sensor according to the present invention is shown in
Although the present invention has been shown and described in detail, the same is to be taken by way of example only and not by way of limitation. Numerous changes can be made to the embodiments described above without departing from the scope of the invention.
Claims
1. An infrared sensor, including:
- an absorber for absorbing incident infrared power to produce a signal representing the temperature of a target object, the absorber defining a perimeter;
- a frame defining a plurality of reflecting surfaces for reflecting incident infrared power toward the absorber, wherein the reflecting surfaces define a light collecting region comprising a cavity having a substantially rectangular cross section, each of the reflecting surfaces being coated with a metal film and disposed at an obtuse angle relative to the light collecting region; and
- a membrane contiguously disposed on the frame and spanning the light collecting region, the absorber being disposed in a central region of the membrane, the membrane defining membrane borders extending between the perimeter of the absorber and the plurality of reflecting surfaces, and thermally isolating the absorber from the frame,
- wherein the frame includes a body for supporting the membrane and the absorber and a light concentrator attached to the body, the reflecting surfaces being disposed on the light concentrator.
2. The infrared sensor of claim 1 further including a plurality of series connected thermocouples, each of the thermocouples extending between the frame and the absorber.
3. The infrared sensor of claim 1 wherein each of the reflecting surfaces is coated with a metal film.
4. The infrared sensor of claim 1 wherein the reflecting surfaces define a cavity having a substantially rectangular cross section.
5. The infrared sensor of claim 1 wherein the frame includes a body for supporting the membrane and the absorber and a light concentrator attached to the body, the reflecting surfaces being disposed on the light concentrator.
6. The infrared sensor of claim 1 further including a circuit board having a void, the frame being mounted to the circuit board such that the absorber is disposed adjacent the void.
7. The infrared sensor of claim 1 wherein the frame defines a rectangular opening having a perimeter, the frame including four segments disposed about the perimeter, each of the segments having an inner side defining one of the reflecting surfaces.
Type: Application
Filed: Dec 3, 2004
Publication Date: May 12, 2005
Applicant:
Inventors: David Lambert (Sterling Heights, MI), Han-Sheng Lee (Bloomfield Hills, MI), Dan Chilcott (Greentown, IN), Hamid Borzabadi (Noblesville, IN), Qin Jiang (Kokomo, IN), James Logsdon (Kokomo, IN)
Application Number: 11/003,191