Abstract:
A method of forming infrared light patterns is provided to simulate the  ration from actual scenes encountered by infrared image detection systems. The patterns are formed using inexpensive black and white film treated with a silver reducing agent and certain photographic toners to produce specularly reflective images, which strongly reflect far-infrared.

Description:
The invention described herein may be manufactured, used, and licensed by the U.S. Government for governmental purposes without the payment of any royalties thereon. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention pertains to infrared image detection systems. In particular, it involves a method of IR image simulation and a method for evaluating such systems in a laboratory environment. 
     2. Prior Art 
     Laboratory testing of infrared imaging systems has been conducted using heated objects which are moved about in front of the imager to check temporal, spatial and temperature responses. To actually check the system operation in the real world, it has been necessary to place the system in its final environment such as an aircraft or tank in battlefield situations. Not only is this expensive, but it unduly extends development time. 
     The present inventor has found one solution to this problem using a special type of black and white silver diffusion transfer photography. The film used, however, is much more expensive than conventional black and white film, is available only in limited formats, and requires special equipment for processing. The above film and usage is disclosed in U.S. Pat. No. 4,639,603 for an &#34;IR IMAGE SOURCE USING A SPECULARLY REFLECTIVE TRANSPARENCY&#34; issued to the present inventor on 27 Jan. 1987. Applicant has since discovered that similar results can be obtained using ordinary black and white film with special processing. 
     SUMMARY OF THE INVENTION 
     The present invention provides simulated infrared (IR) images of real scenes by using an IR imager to obtain a visible image of an IR scene. The visible image is then photographed using conventional black and white film. The film is then specially processed to obtain a specularly reflective image. Finally, the simulated IR image is formed by reflecting IR from the image surface of the film, or passing IR through the film. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention is best understood with reference to the accompanying drawings wherein: 
     FIG. 1 shows an infrared to visible photographic system focused on a typical IR radiating scene; 
     FIG. 2 shows a developed negative transparency-type black and white photographic film exposed in the system of FIG. 1; 
     FIG. 3 shows the film from FIG. 2 after additional processing steps; and 
     FIG. 4 shows a test arrangement for regenerating the IR image radiated by the scene to the system in FIG. 1. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring to FIG. 1 there is shown an IR (infrared) image detector. This device may be used to perform step A in the Program Step Chart on Page 3. An imager such as the Army&#39;s Forward Looking Infrared system FLIR uses IR optics to form an image of a target such as truck 12 against backgrounds such as trees, shrubbery, snow, rocks and soil. The image is focused on an array containing as many as 250,000 individual detectors. The imager then generates a video signal representing the invisible IR intensity pattern from the scene. This signal can simply be recorded on video tape, but more often (step B) is fed to a black and white video monitor, which may or may not be part of the image detector. The detectors are sensitive to peak blackbody radiations at temperatures from -50° to 200° (F.). 
     In FIG. 1, the monitor is assumed to be on the detector or imager. The visible pattern on the monitor can be focused on film (step C) using a camera 13. As shown in FIG. 2, this film can be any of the inexpensive black and white films commercially available, having a polyester backing 21 and forming final images of colloidal silver 23 suspended in an emulsion layer 22. The film is developed (step D) to produce this image, but not necessarily fixed to remove the remaining unexposed silver salts (halides). Fixing the film (step E1) is optional and, if performed, is followed by a bleaching step which converts the image of colloidal silver to silver salts. Photographic bleaches for this purpose, which is actually an extreme reduction in contrast, are readily available at photographic supply houses. 
     PROGRAM STEP CHART 
     A. Electronically detect and store invisible pattern of IR intensity from scene. 
     B. Convert invisible pattern to visible light pattern. 
     C. Focus light pattern on film. 
     D. Develop film. 
     E1. (Optional) Fix film and bleach colloidal silver to silver salts (Negative). 
     E2. (Optional) Etch away colloidal silver (Positive). 
     F. Reduce remaining silver salts to thin specularly reflecting silver flakes or sheets. 
     G1. (Optional) Gold tone the silver flakes. 
     G2. (Optional) Coat film with protection layer of wax or other IR transparent material. 
     H. Install film in IR simulator with IR source. 
     I. Test imaging systems with simulator using IR projected through film and/or reflected from silver image. 
     The materials needed to perform steps E2 and F are described in U.S. Pat. No. 4,362,796, &#34;PROCESS OF MAKING PHOTOGRAPHIC PRINTS SIMULATING DEPTH AND RESULTANT ARTICLE&#34;, issued to Robert Monroe on 7 Dec. 1982. Step E2 is also optional and is used to produce a positive image in silver salts (the original unexposed halides) as opposed to the similar negative image produced by step E1, both of which are normally invisible. 
     As shown in FIG. 3, the photographic processing is completed (step F) by reducing the silver salts or halides to specularly reflecting sheets or flakes 31 of pure silver. Performing both E1 and E2 is impractical since step E1 negates the purpose of E2. If both steps are omitted, an interesting image in black and silver is obtained, which can be utilized in the present invention, as well as the negative and positive images resulting from steps E1 and E2, respectively. It is believed that the flakes 31 form near the top of the emulsion layer, because there is a fairly rapid erosion of the mirror-like surfaces, if the emulsion surface remains exposed to the atmosphere. This can be avoided by using a non-reactive toner like gold 31 (step G1) and/or by applying a thin impermeable layer 32 (step G2) of wax or polymer to the emulsion surface. The film is then inserted in a simulator (step H) and used to demonstrate and test IR imagers or IR to visible convertors (step I). 
     FIG. 4 shows a scene regenerator using more than one film. There are four IR sources 41-44 shown, two for each of the sample films 46 and 47. A pellicle 45 is used to direct and combine the radiations from the various sources. Sources 41 and 42 transmit through the films and sources 43 and 44 are reflected from the film emulsion surfaces, which face the pellicle. All transmitted and reflected IR images are directed toward the collimator lens and are focused as a combined image on the detector array in the imager. The contrast of the combined image can be controlled by varying the relative intensity of the various sources. If needed, the contrast can be completely reversed. The sample films may be, for example, positive and negative images of a scene including a hot object against a relatively colder background. The combined image can then simulate changes in solar heating and ambient temperatures of this specific scene. The films can be motion pictures to provide temporal data. Special glasses and crystalline materials with low IR absorption factors can also be used as backing materials, if extremely intense IR sources are required. Projection systems tested to date have shown no heating problems or loss of contrast using commercially available films with polymer backing layers.