DE3232092C1 - Day-vision/night-vision device - Google Patents

Abstract

The invention relates to a day-vision/night-vision device (1) having a day-vision device (periscope 2) and a thermal imaging device whose thermal image, which is converted in a cathode ray tube (13) into visible frequencies, is reflected into the beam path of the day-vision device (2) in a manner congruent with the image thereof. In order to achieve axial harmonisation of the day-vision device and night-vision device in a simple way, the thermal image detector (10) with an image scale of 1:1 and the cathode ray tube (13) are arranged on opposite sides of a frequency-selective beam splitter (11). The thermal image detector (10), cathode ray tube (13) and beam splitter (11) are arranged in a block (9) which is inserted into the beam path of the day-vision device (2) so that the beam splitter (11) is situated in the beam path. The beam splitter allows the visible light of the day-vision device to pass through, directs the IR light for the thermal-imaging detector (10) into the thermal-imaging device and reflects the image of the cathode ray tube (13) into the beam path of the day-vision device. Axial harmonisation of the day-vision device and night-vision device is performed by a thermal point (thermistor 18) which is arranged in the screen plane of the cathode ray tube (13). This thermal point is likewise imaged via the thermal-imaging device (10) on the screen of the cathode ray tube (13). Both points can be observed through the eyepiece (3) of the day-vision device and can be brought to coincidence by electrical adjustment of the cathode ray tube. <IMAGE>

Description

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The invention relates to a day / night vision device according to the preamble of the first claim.

Such a day / night vision device is known from DE-OS 26 23 399. The thermal imager has has an image scale of 1: 1 and is connected to the day vision device in the manner of an attachment. Day vision device and thermal imaging device have different input optics, but the optical ones Axes of thermal imaging device and day vision device are parallel. The 5Q via an arrangement of light-emitting Diodes (LED) converted into visible light image of the thermal imaging device is via a frequency-selective Spectral splitter reflected in the day vision device. Due to the selected reproduction ratio of 1: 1 des Thermal imaging device and the common beam splitter is achieved that the images of day vision and Night vision devices are congruent, provided the other optical deflection elements used in the thermal imaging device are defined in their location. However, it must be ensured that the optical axes of Thermal imaging device and day vision device are parallel. The advantage of such an arrangement is that the precise positioning of the thermal imaging device and also of the common beam splitter is relatively uncritical. However, one must Such an arrangement ensures that the image converted in the thermal imaging device is axially harmonized with the Day vision device is reflected.

In the known day / night vision device, the design effort is still relatively high, there both devices have separate entry optics and the beam up to the common spectral splitter in the Thermal imaging device must be deflected several times. In addition, there is no possibility here that the to adjust both devices for axis harmony.

The invention is based on the object of constructing a day / night vision device further improve, in particular to reduce the number of critical optical deflection elements and further specify a simple way of adjusting the axes of day vision device and thermal imaging device.

According to the invention, this object is given by those specified in the characterizing part of claim 1 Features solved. According to these features, the only deflecting element in the thermal imaging device is Common frequency-selective beam splitters used with the day vision device. The arrangement of the Thermal image detector and convert the recorded thermal image signals into visible signals Device, preferably a cathode ray tube on opposite sides of the beam splitter, allows this simple construction. This also results in a simple adjustment option. In the plane of the The screen of the cathode ray tube becomes a point light source that also radiates in the visible light range or a small thermal image, e.g. B. set with the help of a thyristor. This point light source will on the one hand reflected into the day vision device via the beam splitter and can be observed here. To the On the other hand, the thermal image detector on the other side of the beam splitter also absorbs the thermal radiation from it Point, which is then in turn displayed on the screen of the cathode ray tube. Also this one Image point can be observed in the day vision device. By shifting the image field of the Cathode ray tube, e.g. B. by mechanical displacement of the device or by electrical displacement of the image field of the cathode ray tube in relation to this point light source can then use the mentioned both pixels are brought to coincide. You do not need your own for axis harmonization Additional device can be used, rather the axis harmonization takes place internally in the day / night vision device self.

With the viewing device according to the invention, a device-internal check of the image scale is also possible of the thermal imaging device possible. After the axis harmonization described, the same or another point light source brought about to the edge of the screen on the cathode ray tube. If the image scale is correctly 1: 1, then this point light source and its image must be on be congruent with the screen of the cathode ray tube.

The internal axis harmonization and the checking of the reproduction scale 1: 1 is in every position the viewing device possible, z. B. not tied to a very specific rotational position of the display device, in which the above-mentioned collimator is turned on.

It is also possible to additionally couple a target tracking device to the thermal imaging device. Since that Thermal imaging device with an image scale of 1: 1 in the conventional sense does not have an optical axis, a reference point for the target tracking device must be artificially created here. This can e.g. B. by the The above-mentioned central point light source is carried out on the screen of the cathode ray tube, wherein

then the image of this point light source is adjusted to the crosshairs of the day vision device. This is an exact assignment of all image points of the thermal imaging device is given in relation to the crosshairs.

Further refinements and advantages of the invention emerge from the subclaims in connection with The following description shows an embodiment of the invention based on the drawing is explained in more detail. In the drawing represents

F i g. 1 shows a schematic section through a day / night vision device according to the invention with a Thermal imaging device;

F i g. 2 shows a schematic representation of the essential individual parts of the thermal imaging device in connection with a cathode ray tube.

In Fig. 1 schematically shows a day / night vision device 1 which has a periscope 2 with an eyepiece 3 and a straightening head 4 with a pivotable straightening mirror 5. At the front of the A window 6 is provided through the straightening head, through which light falls, deflected at the straightening mirror 5 and is finally passed through an optics 7, only indicated here, and a deflecting mirror 8 into the eyepiece 3. Even if a periscope has been described here as a day vision device, another one can also be used conventional type of viewing device can be used. Likewise, z. B. another in the periscope Goniometer available; the beam path of the periscope then becomes a part for the goniometer reflected.

Between straightening head. 4 and the shaft of the periscope is a block 9 for a thermal imaging device 10 arranged at the reproduction ratio of 1: 1. In the block

9 is a frequency-selective beam splitter 11 at an angle in the beam path for the periscope 45 ° from the vertical axis of the periscope. This beam splitter lets the visible light for the Periscope, but reflects the thermal radiation for the thermal imaging device and directs it to a Input optics 12 of the thermal image detector.

On the side of the beam splitter 11 opposite the thermal image detector 10 is a cathode ray tube 13, the screen of which faces the beam splitter. Between the screen and the Beam splitter 11 is an optical system 14. On the screen of the cathode ray tube appears that of Thermal image recorded by the thermal image detector. This is via the beam splitter 11 into the periscope and can be observed on the eyepiece 3.

A schematic structure of the thermal image detector

10 in connection with the cathode ray tube 13 is shown in FIG. 2 shown. That in the thermal image detector 10 with The IR light incident through the input optics 12 with an imaging scale of 1: 1 is transmitted to a scanning mirror 19 and steered by this via a collecting optics 15 to a detector 16. The output signals of the detector are ordered and amplified in a multiplexer and amplifier 17 and then the signal input the cathode ray tube 13 is supplied. In order to ensure a clear assignment of the individual signals to the To obtain the respective rotational position of the scanning mirror 19, a position transmitter 20 is the scanning mirror assigned to the respective scanning position of the scanning mirror 19 to a synchronization input of the Cathode ray tube 13 transmitted. Because of the two input signals on the cathode ray tube the thermal image is then developed in this conventional manner on their screen. The cathode ray tube has compared to other imaging devices such. B. an LED screen, the advantage of greater Brightness so that image intensifiers can be avoided. In principle, however, the thermal image could also be used can be displayed on such an LED screen.

From Fig. 1 it can be seen that by switching on the block 9 with the beam splitter 11 in the Beam path of the day vision device the visible image and the thermal image are always congruent. The position

ίο of the beam splitter 11, as well as the position of the block 9 are not critical. So z. B. the block 9 on the shaft of the periscope 2 a tilted position of about ± 2 mrad in relation to the beam axis of the day vision device, without this resulting in imaging errors.

learning is coming. Similar requirements also apply to the beam splitter 11. These permissible tolerances are much larger than the tolerances for conventional devices, which already have the axis accuracy must be at 0.1 mrad.

For axis harmonization of the day / night vision device described, in the level of the screen the cathode ray tube 13 a visible point light source, e.g. B. a colorful heated thermistor 18 in the Driven in the center of the image. This thermistor 18 should form a heat point which is precisely limited to <0.1 mrad. This heat point can be observed through the eyepiece 3 of the periscope, since the visible Radiation is reflected through the beam splitter 11 into the periscope beam path. As a reference for the The center of the image can e.g. B. serve the crosshairs of the periscope, not shown here. The thermal radiation of the thermistor 18 passes through the beam splitter 11 and falls into the thermal image detector 10 and is in turn displayed on the screen of the cathode ray tube 13. This pixel can also use the eyepiece 3 can be observed. By electrically adjusting the cathode ray tube, both Points brought to congruence. The axis adjustment is finished.

A problem with the described axis harmonization is that the focal point for the thermal imaging device and not for the visible radiation of the periscope in the area of the screen of the cathode ray tube coincide exactly, since the position of the focal point is known to be frequency-dependent. The focal point for the thermal imaging device is »behind« the radiating thermistor, practically within the screen of the Cathode ray tube. By suitable measure, e.g. B. an aberration-free one aimed at this problem

so optics 14, however, this difficulty can be eliminated, so that the required accuracy for the Axis harmonization can always be achieved.

In addition, the thermistor 18 can also be used for the imaging scale of 1: 1 of the thermal imaging device. The thermistor is used for this purpose. B. to the edge of the Screen of the cathode ray tube 13 brought into position 18 '. The heat point will also be like above Imaged via the thermal imaging device 10 on the screen of the cathode ray tube 13. With the necessary Both images of the thermistor perceived through the eyepiece 3 must be magnified 1: 1 be congruent. If the two points are not congruent, then again becomes electrical Adjustment made with the help of two potentiometers.

The aim is to also provide such night vision devices with automatic target location and target tracking

to pair. To locate the target, the axis of the infrared thermal imaging device must align with the sighting axis of the Day vision device must be harmonized to an accuracy of <0.1 l mrad. As mentioned above, has a thermal imager with the image scale 1: 1 in the usual sense no optical axis at all. Such a thing Thermal imaging device would therefore not be useful for integrated target location. Nevertheless, however, can also a solution can be found here. The thermal image detector 10 is by means not shown here designed to be mechanically adjustable. The mentioned heat point of the thermistor 18 is then through Adjustment of the thermal imaging device set to the crosshair center of the day vision device. This point serves as a reference, so to speak. It is now possible to use the thermal imaging device as a target location and tracking device to pair.

1 sheet of drawings

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Claims (3)

Patent claims: 1. Day / night vision device with a day vision device and a thermal imaging device with an image scale of 1: 1, its detected by a thermal image detector and in a cathode ray tube or a similar image generating device converts thermal image into visible frequencies a frequency-selective beam splitter in the beam path of the day vision device with its image ίο is reflected congruently, the beam splitter the visible light of the day vision device passes through, characterized in that the thermal image detector (10) and the cathode ray tube (13) arranged on opposite sides of the frequency-selective beam splitter (11) are the heat content of the day / night vision device (1) incident light on the thermal image detector (10) directs that immediately in front of the screen plane of the cathode ray tube (13) a point light source (thermistor 18) emitting visible light and thermal radiation is arranged, and that the image field of the cathode ray tube (13) is displaceable in relation to the point light source (18) is that in the day vision device (periscope 2) directly observed point light source (18) and on the Screen of the cathode ray tube (13) generated image (18 ') can be brought to congruence. 2. day / night vision device according to claim 1, characterized in that the image field of the cathode ray tube (13) is displaceable by electrical means with respect to the point light source (18). 3. day / night vision device according to any one of the preceding claims, characterized in that the Position of the thermal image detector (10) is mechanically adjustable.