DE2603129A1 - OPTICAL DEVICE FOR COLLECTING AND FOCUSING RADIATION FROM AN AIRPLANE - Google Patents

Description

NY OPTICAL INDUSTRY "DE OUDS DELFT"
Van Miereveltlaan 3, DeIft - The Netherlands

Optical device for collecting and focusing radiation from a plug tool.

The invention relates to an optical device for collecting and focusing radiation from a plug tool, in particular from UV radiation comprising a rotor provided with three or more scanning mirrors which are symmetrical and parallel to the axis of rotation of the rotor are arranged and in cross section perpendicular to the axis of rotation form a regular polygon ″ for optical scanning of a strip of land lying across the plug direction, and two focussing systems stars that reflect the radiation from the scanning mirrors can feed common radiation detector.

Such a device is from US PS 3.2II.O46, column 2, line ff known. In this device, radiation originating from the terrain is reflected on two scanning mirrors via the respective Focusing systems added to the radiation detector. As the rotor rotates, the amount of "across each focusing system" varies Radiation energy added to the radiation detector in such a way that

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all reflected on the scanning mirrors and through the focusing systems Radiant energy added to the detector in principle in the time remains constant. In this way it is achieved that a constant optical aperture is maintained during the entire scanning cycle will. Veiter, this known device comprises a folding mirror which the radiation focused thereon by the focusing systems on the detector reflects, so that the first split by the scanning mirror Radiation finally reaches the detector in combination.

A disadvantage of this known device is revealed when the Device - used to collect and focus UV radiation from an airplane to obtain UV photographic images of a terrain. In that the radiation incident on the scanning mirrors is sent to the focusing systems in this way using two belonging parabolic mirror elements splits that the radiation energy of each of the sub-bundles varies, but the total radiation energy remains constant, each of the parabolic mirror elements sweep an angle that is large enough to focus the entire radiant energy on the folding mirror. This gives the radiation detector not only UV radiation originating from the terrain and reflected by the scanning mirrors, but also no useful data contained from the interior of the optical device, e.g. from the sites and / or from a mirror currently not scanning the terrain of the rotor, UV radiation. If you think that it is mostly desirable, temperature differences of about 0.15 C to register photographically and a significantly higher temperature prevail within the device than in the area to be scanned can, it will be clear that the known device is actually not suitable for UV radiation. Another disadvantage of the known The device is that, although the principle of optical doubling is used and so a high scanning speed is obtained, the number of scans per rotation of the rotor over 300 on the total Number of scanning mirrors is limited.

The purpose of the invention is to create a device of the type mentioned, on the one hand, the detector only from the Receives radiation originating from the terrain and, on the other hand, the number of scans per rotation of the rotor over 360 is twice as large,

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without reducing the scanning speed. The device according to the invention is soir.it characterized in that 'the two focusing systems focus the radiation reflected on the scanning mirrors in focal points whose mutual distance is small in relation to the focal point distances of the focusing systems and possibly equal to zero, that the device continues to synchronize with the rotor-drivable optical switch, which is arranged in the vicinity of the focal points of the focusing systems, for causing the radiation detector to alternately receive radiation via the first and second focusing systems, and that the focusing systems are set up so that they are momentarily under with respect to each other Receiving radiation coming from different angles from the terrain and reflected at the scanning mirrors and alternately supplying the radiation detector with, in principle, an equal amount of radiant energy, with each rotation of the rotor
gel two samples can be obtained.

feed, with each rotation of the rotor over 36O over each scanning mirror

It is noted that the use of an optical switch, which is set up in the vicinity of the focal points of the focusing systems which are relatively close to one another, to cause the radiation detector to receive radiation alternately via the first and second focusing systems, the focusing systems alternating with the Radiation detector in principle supply an equal amount of radiant energy, which is known per se from Dutch patent application 66.18165. The device described there is, however, a rotor with scanning mirrors which are arranged symmetrically at angles other than 0 with respect to the axis of rotation, while the focusing systems face the rotor with the scanning mirrors at the same angles. Thereby, the principle of optical doubling, which allows, is not used a greater scanning speed and a scanning angle grösse'ren, but is the number of samples per rotation of the rotor about 36O ⁰ also on the total number of scanning mirror limited.

In a preferred embodiment of the optical device according to the invention, the focusing systems are set up in such a way that at least one of the focusing systems receives radiation from the scanning 'mirrors', which radiation is propagated in a direction

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the rait a plane perpendicular to the axis of rotation of the rotor Includes an angle not equal to 0. This ha; a larger scanning angle is obtained.

Includes an angle not equal to 0. This definition has the advantage that

In the gate direction according to the invention, with each focusing system Receive a scan of the terrain via each scanning mirror of the rotor. The fact that both focusing systems alternate with the Radiation detector feed radiation, two scans of the terrain are therefore obtained per scanning mirror. Depending on the desired These two scans can cover the same scanning angle per scanning mirror or scan two different angular ranges. In a door pull embodiment of the invention optical device, the focusing systems guide the detector alternately from successive scanning mirrors reflected radiation to, for the effect that both focusing systems scan the terrain via the rotor with scanning mirrors over always the same scanning angle. In this way the signal-to-noise ratio is improved.

The invention is explained with reference to the drawing. Show it:

1a-1d schematically an embodiment of the inventive Gate direction, and

2a-2d schematically another embodiment of the inventive Gate direction.

First of all, it should be mentioned that in the case of the optical scanning devices described here for the slow scanning movement, the locomotion of the aircraft in or on which the optical gate direction is arranged is used. Only the fast scanning movement (line scanning) should take place through the optical gate direction. The choice of the number of scanning mirrors of the rotor is determined by that of the scanning device requirements, such as the scanning angle (i.e. the angle over which, viewed from the aircraft, the terrain is perpendicular the direction of flight is scanned), the scanning speed (i.e. the number of scans per minute) the permissible speed of the rotor,

the bandwidth of the electrical signal in which that passed by the detector radiation received is converted, the signal-to-noise ratio, etc.

An embodiment of the optical device is shown in FIGS. 1a-1d reproduced according to the invention, at the same scanning angle scanned twice in succession by the same scanning mirror will. In this example, the rotor 1 is a symmetrical three-sided prism, which is driven around the axis of symmetry by means of drive means that are not shown 2 can be rotated. Starting from the state of FIG. 1a, one of the three sharp edges of the prism pointing downwards and where only radiation from the right focusing system 5 and 7 reaches the detector 9 via an optical switch 3, that is Move the scanning beam with the rotation of the prism 1 in a clockwise direction and reach the level of Fig. 1b. If you turn the Prism 1, the optical switch 3 is flipped over, so that only radiation from the left focusing system 4> 6 and 8 reaches the detector 9. As a result, the Abtasvbündel arrives, as shown in Fig. 1c new to the right side and this will move again from right to left over the terrain with further rotation of the prism 1 the state according to FIG. 1d has been reached, the next sharp edge of the prism 1 being directed downwards and thus towards one Rotation through 120 again the starting position according to Fig. 1a is reached. There in the reproduced rotation over 120 two samples over only For example, if a single scanning mirror has been obtained, there will be six scans when rotated through 360, two scans each Scanning mirror. In the example shown, these are for the focusing systems belonging hollow spherical secondary mirror 4 and 5 arranged just outside the angular range to be scanned, which actually limited to less than 120 by these mirrors. As a result, for each rotation of the prism 1, there is talk of a "dead time", during which the detector 9 has no useful signal to be processed receives. As can be seen from FIG. 1, this "dead time" corresponds to FIG Rotation from the position according to FIG. 1b to the position according to FIG. 1c, which in practice amounts to a "dead time" of 10 per rotation beyond 120. In this way, the same angle of 110 is scanned twice for every rotation over 120. It will be clear that once the Dimensions of the rotor with scanning mirrors are given the dimensions

the optical elements belonging stones to the focus si erungs sy chosen such were ¹ to s, that the effective apertures of these systems are the same and are constant in time, whereby the detector over each focusing system a constant amount of the premises herrührender Radiant energy is obtained during the effective scan cycle. In particular, the aperture of the focusing system in question is completely filled with radiation originating from the terrain and reflected on a scanning mirror, without radiation not originating from the terrain reaching the detector.

It is noted that the optical switch and the focusing systems can be of any suitable type. In principle, apart from what has already been noted above, the only thing that matters is that the Focal points of the focusing systems lie at a distance from one another which is small in relation to the 3 focal point distances and possibly is equal to O, while the synchronous drivable with the rotor, optical switches close to the "focal points" of the focusing systems should be arranged. The optical switch can e.g. be a mirror that can be moved between three positions synchronously with the rotor, whereby in the first position only radiation from one focusing system can reach the detector, in the second position absolutely none Radiation from the focusing systems can reach the detector (corresponds to the "dead time") and in the third position only radiation from the other focusing system can reach the detector.

According to a preferred embodiment of the invention, the efficiency of the optical device can be increased to $ 100, and so on the scanning angle can be made maximum if you have at least one of the spherical concave mirror 4 'and 5 arranged such that the optical The axis of the beam between the rotor and the scanning mirror in question is at an angle to the surface of the drawing, whereby the Concave mirrors no longer stand in the way of the beam reflected on a scanning mirror. Applied "to that shown in FIG Execution farm is thereby made twice per rotation of the rotor 1 over 120 sampled the same angle of 120. In this case the optical Switch be a switch of the type described in Dutch patent application 66.I8I65, synchronous with the

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Rotor rotatable disc-shaped body with alternating on the circumference reflective and radiation-permeable sectors, the total number of sectors being twice as large as the number of scanning mirrors. This optical switch is arranged in such a way that the focal points of the focusing systems with respect to the reflective sectors have each other to the mirror image, so that it is effected that the radiation detector alternately radiation via the first and the second focusing system receives.

In FIGS. 2a-2d another embodiment of the optical device according to the invention is shown, two different angular ranges adjoining one another being scanned one after the other via the two focusing systems. The rotor 1 is here a symmetrical five-sided prism which can be rotated about the axis of symmetry 2 by means of drive means (not shown). The hollow spherical secondary mirrors 4 and 5, which in this case form the focusing systems, are arranged in such a way that the bundles of these mirrors rotate
Horizontal can meet.

Reflect from the rotating prism 1 at an angle of 18 to the

If it is assumed from the state according to Fig. 2a, with a sharp edge practically directed upwards and only radiation from the right focusing system reaches the radiation detector 9 via the optical switch 5, the scanning beam will move with the rotation of the prism clockwise and the Reach the state according to Fig. 2b, in which a sharp edge of the prism is directed downwards. Then the optical switch is brought into the state in which only radiation from the left focusing system reaches the detector (Fig. 2c). With further rotation of the rotor 1, the scanning beam moves from the vertical direction to the left until the level according to FIG. 2d has been reached and the scanning of the second angular range is thus ended. Subject to a slight further rotation ("dead time"), the starting position according to FIG. 2a will be reached again. In this way, with a rotation of the rotor over 72, two consecutive scans are obtained, so that with a complete rotation over 360, ten scans are carried out, which here, however, appear as the right and left halves of five scan lines.

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As in the embodiment of FIG. 1, the Scanning degree can be increased to 10O ^ and in this way the scanning angle can be made maximum if you have both spherical concave mirrors 4 and 5 arranged so that the yeast lesson on the prism 1 is not in a Surface is perpendicular to the axis of rotation 2.

It is noted that in Figures 1 and 2 with 10 a before Radiation detector 9 arranged collimator is referred to.

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Claims (3)

-Jf- AHS PRTJE C HE : ClV Optical device for collecting and focusing radiation from an aircraft, in particular from UV radiation, comprising a Rotor, provided with three or more scanning mirrors, which are arranged symmetrically and parallel to the axis of rotation of the rotor and in the Cross-section perpendicular to the axis of rotation is a regular polygon form, for the optical scanning of a strip of land lying transversely to the flight direction, and two focusing systems that are attached to the '. Scanning mirrors reflected radiation from a common' radiation detector can feed, characterized in that the two focusing systems, the radiation reflected on the scanning mirrors focus in "focal points whose mutual distance is small with respect to the focal distances of the focusing systems and possibly equal to zero, that the device further one comprises synchronously with the rotor drivable optical switch, which is arranged in the vicinity of the focal points of the focusing systems, for Effect that the radiation detector alternately receives radiation via the first and second focusing system, and that the focusing systems are set up in such a way that they are currently under different angles in relation to each other from the terrain and to the Scanning mirrors received reflected radiation and alternately the radiation detector, in principle, an equal amount of radiant energy feed, with each rotation of the rotor over 360 over each scanning mirror two samples can be obtained. 2. Optical device according to claim 1, characterized in that the radiation received by at least one of the focusing systems is propagated in a direction coincident with a plane perpendicular to the axis of rotation of the rotor includes an angle not equal to 0. 3. Optical device according to claims 1-2, characterized in that the focusing systems alternately supply reflected radiation to the detector at successive scanning mirrors, so that two scans per rotation of the rotor via J6o / n (n = the number of angles of the polygon) via a scanning mirror can be obtained over the same scanning angle.