FR2697643A1 - Method for simulating an infra-red image - Google Patents

Abstract

The invention relates to a method for simulating an infrared image. The method comprises the following steps: (a) forming a transparency (20) of an optical image of a scene (22) in the visible band; (b) passing infra-red radiation through said transparency; and (c) detecting infrared radiation passing through said transparency; and (d) providing a visible output of said detected infrared radiation. A device (10) for implementing this method is also described.

Description

The present invention relates to a method for simulating infrared images

red, an associated device

  and simulated infra-red images obtained therefrom.

  Methods for providing images are known

  simulated infra-red A brief description of

  some references of the prior art is made hereinafter. U.S. Patent No. 4,760,267 discloses a method in which an infra-red intensity pattern of a selected wavelength band is detected and a corresponding visible light intensity pattern is created. Visible light is projected onto a photographic film having only a support layer and an emulsion layer.

  is processed, creating a specular reflection silver pattern corresponding to the original infra-red pattern. One side or each side of the film is illuminated with radiation of a selected wavelength, creating a new infra-red pattern corresponding to the infra-red pattern.

  original red US Patent No. 4,679,910 discloses an infrared visible dynamic image converter comprising two liquid crystal layers on each side of a photoconductor carrier, a voltage supply, a gate biaser Spun adjacent to the first liquid crystal layer and a mirror adjacent to the second liquid crystal layer The two liquid crystal layers spatially modulate an incident infrared beam by circular polarization The circular polarization is modified by applying a The photo-conductive carrier receives and adsorbs a visible image and spatially modulates the voltage between the two liquid crystal layers according to the spatially varying image intensity. incident red is reflected by a mirror through the liquid crystal layers and is, therefore, polarized, circular, proportional Visible image5 The polarizer converts the circular polarization of the infra-red beam to generate intensity modulation, thus providing an infrared image. U.S. Patent No. 4,299,864 discloses a method of manufacturing a visible infra-red transducer by depositing a radiation absorber on a thin thermal insulation film in a partial inert vacuum. U.S. Patent No. 4,723,077 discloses an infra-red visible image converter comprising an infra-red light source and a polarizing beam splitter separating infra-red light into two polarized beams whose polarities are orthogonal. Two image converters receive and modulate the two polarized beams respectively with the aid of identical visible information. The modulated infrared beams are analyzed and recombined into a single beam. U.S. Patent No. 4,820,929 describes a device for transforming visible images into infra-red images using a photoconductive layer.

  sandwiched between conductive layers in which a current flows. One of the envelope conductive layers is transparent and has a resistivity modulated according to incident visible radiation.

  US Patent No. 4,767,122 discloses a thermal target 3D simulator Orthogonal thermographs of a target are reproduced on a plastic support and are formed into a model of the target that is transparent to radiation from internal sources. are covered by a filter allowing only a pre-selected part of the spectra of the visible light sources to pass through The model is illuminated from the outside by visible light A5 visible light television camera provided with a filter allowing the pre-selected part to pass through spectrum

  produces a simulation in visible light of the target. An additional television camera in visible light without a filter provides a signal appearing in the form of an infrared image on a TV monitor.

  U.S. Patent No. 4,824,374 describes a terrain screen, a target projector projecting the image of a moving target on the screen, a weapon projecting an infra-red spot on the screen and a spot-sensitive camera. infra-rouge When a trainee activates the weapon, the camera produces a signal

  video signal representing the position of the infrared spot projected on the center of the target The video signal controls a projector which produces a visible spot on the screen representing the position of the spot.

  UK Patent Application No. 2,081,049 discloses an infra-red emission target simulator comprising a UV illuminated target mounted on a field plate and a TV camera for scanning the field plate and the target. is at least partially formed of a substance that is fluorescent in response to UV illumination, thereby simulating an infra-red emission target. UK Patent Application Publication No. 2 067 273 discloses a low light level simulator comprising a projector having an adjustable filter creating a screen image with infra-red and visible components and a weapon with a booster amplifier. This image is sensitive to infra-red radiation and produces a visible image. The radiation emitted by the screen target image simulates a poorly illuminated target or

  weakly visible. The present invention aims to provide an improved simulation of infra-red images.

  Then, according to a preferred embodiment of the present invention, a method is provided for simulating an infra-red image, which method comprises steps of forming a transparency of an optical image of a scene in the visible band directing an image. infra-red radiation through the transparency, detection of infra-red radiation through the transparent and generation of a visible output of infrared radiation detected. In addition, according to a preferred embodiment of the present invention, the method also comprises a step of passing through a collimator of infra-red radiation before detection. According to a preferred embodiment of the present invention, a device is also provided for simulating an infra-red image, comprising a transparency of an optical image of a scene in the

  visible band, a source of infra-red directing infrared radiation through the transparency and an infra-red imaging device detecting infra-red radiation passing through the transparency and producing a visible output of infra-red radiation;

  red detected. In addition, according to a preferred embodiment of the present invention, the device further comprises

  a collimator acting on the infra-red radiation before detection.

  According to a preferred embodiment of the present invention, a simulated infra-red image is also provided, comprising a carrier and an image formed on the carrier by directing infra-red radiation through a transparency carrying an optical image in the visible band . In addition, according to a preferred embodiment of the present invention, the image is formed by detecting collimator radiation received through the transparency.

  The present invention will be better understood and appreciated from the following detailed description

  taken in conjunction with the appended single Figure 10 illustrating a simplified block diagram of the infrared image simulation device which is arranged and operated according to a preferred embodiment of the present invention. The device 10 comprises a transparency in the infra-red 20 of a scene, characterized in that it is transparent to infra-red radiation. The transparency in the infra-red 20 can be created using the following steps (a) photographing a scene 22 using a conventional visible light detection camera 24 such as Canon A 1, whose angle of view is alpha; and (b) printing the negative film processed from step (a) in a positive mode on a support

  transparent to infra-red radiation such as a suitable plastic material.

  The transparency 20 is placed on or adjacent to the focal plane of a collimator in the infra-red 30.

  The covered field of view is close to alpha. A black body 34, such as a wide area IC-SR 8 black differential body, is placed opposite the opposite side of the field.

  slide and produces infra-red radiation from the slide Infrared radiation passing through the transparent portions of the transparency 20 strikes a collimator 30.

  A Recognition Camera in Infra-Red 36, hereinafter referred to as FLIR, looks at transparency 20 and generates an electronic image 38 approximating the image that FLIR would have produced in response to a direct view of the scene represented by the transparency 20 The angle of view of the FLIR 36

  does not exceed alpha and the dimensions of its aperture do not exceed those of the collimator. An adapted FLIR is constituted by the TD Imaging System 32,10 commercially available from RAFAEL, Armament Development Expert, Haifa, Israel.

  The electronic image 38 generated by the FLIR is transformed into a visually sensitive image 40 to

  using a video printer such as a CP-20015 produced by Mitsubishi.

  Those skilled in the art will understand that the present invention is not limited in particular to what is

  As illustrated and described above, the scope of the present invention is defined only by the appended claims.

Claims (8)

  A method of simulating an infrared image, comprising the steps of: forming a transparency of an optical image of a scene in the visible band; passing infrared radiation through said transparency; detecting infra-red radiation passing through said transparency; and   generating a visible output of said detected infrared radiation.   The method of claim 1 comprising a step of passing through a collimator of the   infrared radiation before detection.   A device for simulating an infra-red image (10), comprising: a transparency (20) of an optical image of a scene in the visible band; an infra-red source (34) directing infra-red radiation through said transparency; and an infra-red imaging device (36) detecting infra-red radiation passing through said   transparent and providing a visible output of said detected infrared radiation.   4 Apparatus according to claim 3, further comprising a collimator (30) acting on the infra-red radiation before detection. Device according to claim 3,   wherein the infra-red imaging device (36) comprises a Recognition Camera in the Infra-Red   red (FLIR). Device according to claim 3, wherein the infra-red source comprises a body black (34).   Simulated infra-red image comprising a support; and an image formed on the support directing the infra-red radiation through a transparent   carrying an optical image in the visible band.   The simulated infrared image according to claim 7, wherein said image is formed by detecting radiation emerging from the collimator and received through said transparency.