DE346026C - Device for the electromechanical application of comparator measurements - Google Patents

Description

Device for the electromechanical application of comparator measurements. In the main patent 3o6383 the problem of the aerial topographical map order discussed for recordings lying generally crooked in space. It becomes: this solution the resulting terrain pyramid (lens as a tip, the four corners of the plate with their image areas in the terrain) as corner points in the horizontal rights and instead of the optical axis, the foot guide was introduced as the main line. This achieves that the hint]. to divide two terrain points in the horizontal plane appears as a true horizontal angle.

In the event that two recording devices are triggered at the same time used at a certain fixed distance in an airship to the recordings, one obtains parallel-axis aerial topographical recordings with a simpler one Apparatus can be measured, which is the subject of the present additional patent forms.

The essence of this invention is that the objective point of view is folded four times in the horizontal plane and revolves around the same guide lines, which two track rulers, one for the X direction and a second for the Y direction so that the new terrain point is a right-angled intersection of the x and y planes appears.

As with the main patent, the usual one is used to measure the plates Stereo comparator connected to the applicator.

The two application devices from T h o m p s o n and are known from V. O r e 1. Both devices are used to evaluate terrestrial stereograms for card purposes.

Each of these apparatuses is based on the idea, the known displacements of the two communicator slides, i the displacement of the X slide and the displacement of the Y-carriage onto the drawing board by means of cranesbill-like devices to be transferred taking into account the photogrammetric equations.

Thompson uses a multiple of the focal length, has moved the mechanism beyond the comparator and has also chosen a constant base. v. O re 1 works with a fraction of the focal length and with a multiple of the base. The advantage here is that the constant base is replaced by the parallactic triangle, which represents the mechanical order of the equations of the rule of three. O re 1 gets the distance .by the equation This shortening of the focal length is somewhat alarming, since this size is already very small in relation to the other distances in the area.

This equatorial triangle retains the same value if the equation is based on a multiple of the focal side and a multiple of the parallax with an unchanged base length, so that one receives. In this form, the geodetic and equally important mechanical principle is taken into account, to use larger distances for application and larger lever arms for power transmission.

First, the new application device is shown in Figs. 1 and 2, as he did for normal stereograms, which were recorded in a rigid airship, is determined.

Here again, as in the main patent, we see the principle of in ; the horizontal plane of the folded side faces is applied. The pivot points 1, 2, 3, q. represent the tip of this space pyramid in their allocation, which is through the Exposure of the square plate arises.

The routes 1-5, 2-6 etc. represent the balloon height or the distance: of the objective above the terrain. We equate it to n. f.

Now have a terrain point with the coordinates x "and y1 $ on the plate. In the terrain, this point is then assigned the coordinates n # x @ s and n # y13. There we in aeronautical recordings in contrast to the terrestrial measurements, where if we photograph the elevation, obtain the outline, the x and y rulers must be used cross at right angles. So you can't move the movement on the parallax ruler here place. It now makes the ruler connection 1-9-13-1o-3 logically .the X-track plane and the ruler connection 2-11-13-12-q. represents the Y-track plane. The intersection: the two The image point 13 aimed at under the microscope is a ruler.

A peculiar phenomenon occurs to us in these aeronautical recordings which we do not get to know in terrestrial stereophotogrammetry. Namely, each of the plates 18 and 1g lying unchanged in the comparator already contains the ground plan, since the optical axis is perpendicular to the earth's surface during exposure was standing. The right plate is only used to represent the height relationships, i.e. H. it conveys the mechanical contour line drawing of the plan.

In our case, however, the altitude is in contrast to the terrestrial one Elevation view not a variable of Y, but of parallax a. We must so set a new parallax value each time with each new altitude and Use the X and Y slides to find all those points which are under the microscope unite at the given parallax position to form a single point in space.

Now that we have turned over the four faces of the tetrahedron, we have to we also mechanically adjust the position of the parallax ruler in each of these assignments knock down. We achieve this requirement in the following simple way: On a big one Multiple glued boards 20-21-22-23 lie in the panels 18 and ig of the very low comparator in their slide mechanisms. The X slide supports the plate 18 and also the entire device for parallax shifting. So when we move the X-carriage through the drum 124, it moves too Carriage of the right plate and the entire gearbox of shaft 38, 40, 41, 39. The mechanism for the X, # settlement is used by those at 27 and 25 bevel gears at right angles to each other moved in the directions 34-29 and 35-3o. The shaft 35-3o here has a left-hand thread, so that any screw errors turn itself off. At 28 and 31 this is an X-track ruler and at 29-3o the second X-track ruler switched on. Above this mechanism lies the transmission of the Y-crank movement. The same is shown in particular in Fig. 2. The Y-crank 32 splits at 33 and is broken again at right angles at 34 and 35 and ends as border rulers for Y, 54-37 and 35-36 This wave also carries the Thread for the Y coordinate development.

For the construction of the device, which is very easy on the drawing board is attached, it makes no difference whether the X-gear or Y-gear is placed on the board.

The parallactic movement differs from this. The same will always placed under the drawing board, so that the plan drawing is not disturbed will. The necessary openings in the drawing board interfere with the plan drawing at no stead.

All movement is done by the parallax wave 38-40, 41-39. Spie runs in the X-direction on the X-carriage, then goes through the left fixed one Base point 43 and is .bei 39 through an angular gear to the parallax crank gear 55-56 connected .. Depending on the movements of the X-carriage, the ball gear grinds 39 on the shaft 47-48 and thereby rotates the one under the drawing board Central gear 48. As a result. but there are also those placed in the diagonal directions Drive shafts48-49, 48-5o and 48-5i, 48-52 in uniform motion so that the four Parallax rulers 49-50 50-51, 51-52 52-49 can be pushed out or in. With the parallax ruler 49-52, however, the parallax lever is through the pivot pin 46 46-44 connected. Because the pivot pin 46 is only in the direction 4o-39 on the parallax shaft can slide, it pushes during this sliding movement and during its rotation around the second base point 42 through the pin 44 the plate carrier of the second equatorial Plate 1g back and forth in the X-direction by the size X, -X "until below the field of vision . of the right microscope the same point appears as in the left microscope.

In our case the relationship B: n - a = E: nf, so underlying. In the case of the aerial topographical order, it is important that the base is not changed, that is to say that neither a multiple nor any fraction of this invariable quantity is used to produce the plan. In the present case, the base is always the same at all balloon heights, because it is determined by the distance between the two cameras that are triggered at the same time.

By rolling the four parallax rulers 49, 50; 49, 52; 5-1. 52; However, we also get the sections corresponding to the mathematical conditions on the X and Y limit rulers The track rulers 9-io and I1-12, the intersection point 13 of which indicates the horizontal position of the terrain point 13 aimed at in both microscopes, are accordingly shifted.

If we now want to go to points of the same height, we may only use the X and Y cranks. It can be seen that the pin 13 at a certain Parallax position can easily specify only points that belong to the same height.

What is peculiar about this construction is that when X, track rulers are at rest the pin i i the cross-section in the X-direction and the pin io the cross-section records in the Y-direction as a data input, so to speak. The whole drawing device is, as is described in the main patent, through holes on the drawing board put on and through alidaden-like devices the pivot points of the rulers set.

The spindle of the guide rail 11-12 can be turned by hand cranking. However, electromechanical operation is also provided. Each of the crankshafts, that is the X, Y and parallax cranks, is provided with an electromagnetic coupling device so that this card self-applicator can easily work through a connection to a light line.

In Fig. 2, the magnetic switch-on and switch-off device is for Y in 54 and in Fig. 53 the magnetic locking device is drawn. See on the parallax wave we do the same at 55 and the lock at 56. All three movements are through the switchboard 58, which has nine buttons, requires every slide movement an activation for forward and for backward, run and for Standstill - served.

Because the recording in airships is always at a finite distance must take place from the earth, the parallactic triangle always has one Angle 43-46-42 at its tip and can therefore always be represented mechanically.

But we can also use the concept of balloon height as the largest The distance of a point on the terrain from the base line 42-43 is understood, - we velche just want to use our plan orders. With this view of the We can now use our air topographical applicator at the balloon height without any problems can also be used for terrestrial purposes. We just put the equatorial Triangle to the smallest value of the parallax X, - X2, which is the largest still to be plotted Distance corresponds to one and take into account at the same time in the length of the to be set Baseline the yardstick. Let us now run a tongue j-13 on the X-track ruler, so at 13 we can see the individual plan points on the drawing surface. the The height can still be read from the pen i i of the parallax ruler 49-5o.

It is precisely the peculiarity of this fourfold arrangement that gives us the opportunity, independently of one another and at the same time, both the cooperation of the X slide with the parallax slide - i.e. the contour line display - as well as the cooperation of the Y slide with the parallax slide - i.e. the profile display - independent of the recording through pins io, ii and 13 to bring. ' This recording also takes place outside of the actual drawing area 28, 29, 30, 31, so that only the two track lines for X and Y that cross each other at the most favorable cutting angle - below 90 ° - are located above the drawing area. Since the continuous setting of the Y-ruler is not necessary for the pure terrestrial plan drawing, because the heights can be read off at i1, there is the possibility that only the X-track ruler with the tongue 9-13 and the pen 13 carries out the entire plan and contour line drawing.

Claims (5)

PATENT CLAIMS: i. Device for the electromechanical plotting of comparator measurements for parallel-axis aerial photographs taken at a known distance according to patent 3o6383, characterized in that the optical center point of the taking lens, which is turned four times on a board plane, is represented by four axis pins 1, 2, 3, 4, around which rulers 1 , 9; 2, 16; 3, 10; 4, 12 turn as a straight line, which guide two rulers 9, io and 11, 12 that intersect at right angles for the purpose of dot application. 2. Apparatus according to claim i, characterized .gekiert, that the parallax mechanism 48, 49, 50, 54 52, 48 has four rulers 49-5o, 50-5r, 51-52 52-49 owns, which from a central gear with the axis 48 from: the The drawing surface is moved from the crank 38 by gears lying in the diagonal will. 3. Apparatus according to claim i and 2, characterized in that the intersection points the parallax rulers and the drawing track rulers pens, e.g. B. io, ii, used which the X-profile and the Y-profile outside the drawing area automatically record. 4. Apparatus according to claim 1 to 3, characterized in that the entire ruler mechanism on a multi-glued wooden base plate Drilled holes put on and through Alidi pegs, around which the rulers rotate, can be changed in the proportions. 5. Apparatus according to claim i -to 4 for terrestrial stereograms, characterized by the fact that when setting out of the ruler mechanism on the wooden base plate 20-21-22-23 the balloon height 8-4, i-5, 2-6, 3-7 is the greatest terrestrial distance to be applied and therefore the plan drawing of terrestrial stereograms by a single ruler dem X-track ruler is done by the pin 13 and by simply switching off the Y-crank the pen of the X-track ruler draws lines of the same height.