Applicants claim the priority benefits of U.S. Provisional Patent Application No. 60/605,264, filed Aug. 30, 2004; and U.S. patent application Ser. No. 11/215,225, filed Aug. 29, 2005.
This invention relates to thermal identification, and more particularly, to a thermal image identification marker utilizing infrared (IR) energy.
The inability of reconnaissance to determine friend or foe in low light or total darkness is a major failing in battlefield and law enforcement operations. The worst effect is that fratricide (the inadvertent killing of friendly forces by other friendly forces) occurs, and at best is a waste of time and resources attempting to confirm identification. Accurate intelligence allows deployment effort to be maximized and focused.
Present marking and identification systems are limited to either Near IR range (1010 nano meters or less) beacons for use with night vision glasses or thermal panel identification marking equipment. Present thermal panel identification marking equipment is passive and only provides identification by temperature or emissivity differences between adjacent areas and the marking equipment. Passive marking equipment is easily masked by surrounding operations, and is difficult to differentiate from adjacent targets.
There is a need to provide a thermal image, which can change state rapidly so as to provide a clear signal in the heat transmission of the spectrum, normally within the range of 2-12 micrometers.
The thermal image can be achieved by means of a system with a heat source than can be made to rotate and produce a flash of heat at every rotation relative to a point of view with the speed of rotation determining the flash repetition rate. However, this type of system has the disadvantage of being omni-directional and inefficient. The image can also be confused by other nearby heat sources producing a pulsating heat image output.
A thermal image, as produced by a heat source, cannot be made to switch on and off rapidly. There is always a time lag created by heating and cooling cycles. In addition, ambient temperature has an effect. It is difficult to control power input to prevent an additional visual input.
The present invention overcomes the above disadvantages, minimizing the power required to produce a clear thermal signal and, also provides means by which the thermal image can be made to change state rapidly to produce a signal which can be used for identification purposes. Furthermore, the present invention provides a uniquely coded image with an ability to change its coding. In addition, the marker's thermal image is continuously differentiated from ambient surroundings thereby providing optimum viewing by a thermal imaging device.
These together with other objects of the invention, along with various features of novelty which characterize the invention, are pointed out with particularity in the claims annexed hereto and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and the specific objects attained by its uses, reference should be had to the accompanying drawings and descriptive matter in which there is illustrated a preferred embodiment of the invention.
Referring to the drawings in detail wherein like elements are indicated by like numerals, there is shown a plurality of rapidly flashing thermal image beacons within a thermal image identification marking system 1 constructed according to the principles of the present invention. The system 1 is comprised of a one or more rapidly flashing thermal image beacons 10, a plurality of sensors 30, a control subsystem 40, input means 42, and a power source 46.
Each thermal image beacon 10 of the present invention emits in the infrared (IR) range. The underlying principle of the present invention may be best seen in
Referring more particularly to
The mechanism 17 is comprised of a screw thread 18 driven by a motor 19. The mechanism 17 provides an oscillary action through the carriage 16 to the heating element 15. The mechanism 17 is controlled by a microprocessor system 20 so that the thermal energy being emitted is being moved through the mirror focal point 13 creating a rapidly changing coded flashing thermal image. An infrared sensitive diode detector 21 is positioned in the mirror housing 22. The detector output is connected to the microprocessor system 20. The detector output is part of a negative feedback circuit within the microprocessor system 20, which continuously maintains the infrared output from the heating element 15 to a set level below the red heat level. This has the benefit of concentrating the maximum radiant heat from the mirror while minimizing the heat absorbed by the mirror housing 22. A nominal direct current (DC) from a battery supplies power to the thermal image emitter 10 and its components.
The sensors 30 are grouped into three functions. The first group 31 of sensors measure the thermal IR emission from each emitter 10. The second group 32 of sensors measure thermal IR emission from background or thermal IR surface radiation from the mirror housings 22. The third group 33 of sensors provide a measure of ambient thermal IR emission from sources in close proximity to the IR emitters 10. All sensors 30 provide their measurement data back to the control subsystem 40.
The input means 42 to the control subsystem 40 is comprised generally of a set IR emitter contrast control 43 and an IR mode control 44. The contrast control 43 enables the setting of the thermal IR emission difference between each heating element 15 and background or ambient thermal IR emission levels. The mode control 44 enables the setting of code for the speed of movement of the carriage 16 holding the heating element 15. The mode control 44 also enables setting the mode of display, i.e., flashing, steady, or changing thermal IR emission intensity. The input means 42 may use manual input devices, such as switches and the like. The input means may also use remote controls for setting the contrast controls 43 and mode control 44.
The control subsystem 40 reads the thermal IR emissions from each group of sensors 31, 32, 33. The control subsystem 40 calculates the difference between the emitter emission and background emission, factoring into the calculation the ambient emission. The control subsystem 40 compares the calculated result with the value read from the contrast control 43 as modified by the mode control 44 as appropriate.
The power source 46 will typically be a battery power source, either disposable or rechargeable. Each emitter 10 may have its own power source 23.
The control subsystem 40 may be either digital or analog. Digital control provides a sequential step by step flow with a decision at each stepping point or gate. The parameters set at the gate will determine the path to the next gate. Thus, the path changes based on the measured parameters. Digital circuit speed is so fast as the decisions are executed, that to the mind it appears as a single action. Control is exercised though microcode.
Analog control systems operate at each measurement point simultaneously relative to all of the other points. The whole unit requires several independent analog operations, one for each functional entity. While analog systems are more difficult to change, they are fast and robust. The proportionality within algorithms is always maintained.
It is understood that the above-described embodiment is merely illustrative of the application. The control subsystem 40 may repeat the various sequences as many times as desired. It may also check available power reserve in the power source. The control subsystem 40 may also be used to report failures or lack of available power. Other embodiments may be readily devised by those skilled in the art which will embody the principles of the invention and fall within the spirit and scope thereof.
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