DE556424C - Projection device for recording and demonstration, especially for the purposes of photo sculpture - Google Patents

Description

The invention relates to a device for photographic apparatus and projection lamps which enables them all in different Distances projected images homothetically with respect to a single fixed homothetic one Center are. Homothetic figures are understood to be those that are, firstly, similar to one another and, secondly, still are stored in perspective. They can be homothetic directly or vice versa, depending after the figures are on the same or on two opposite sides of the homothetic center.

The application possibilities of this device are manifold. It can be used are used for cartographic purposes with oblique terrain photographs or for cinema projection apparatus to create special movement effects, whereby the projection screen is moved. Particularly useful and it is advantageous to use it in photosculpture. In the known way of working of the photosculpture are made from two different points from a model provided with marks and lines Photographs taken and the generated clichés in the same place in projection apparatus set, which have the same optical centers and optical axes as the photographic ones used for taking pictures Apparatus. The clichés are then projected from the two points onto the material in question, from which the Statue o. The like. To be made. So much of this material is then removed in each case, until two related points or lines coincide on the material. Due to the special facility of the apparatus according to the invention it is achieved that no distortion occurs in the picture work, but just that corresponds to photographed object. One or more devices can be used here. this However, it was not possible with the known devices, because they were included always reproduced distortions of the pictorial work.

In order to avoid any distortion, according to the invention, the lens of the projection lamp is shifted by X and the cliché by Y, whereby the values X and Y are automatically given by the equations given below and correspond to the respective depth (s or iXsj in which one just processed the material.

In the drawing, Fig. 4 shows schematically the path of the light rays in the photographic photograph recording. B is the lens with the focal length / '. The plate A is at distance α and the front side of the IkKL model, which is shown here schematically as a trapezoid, is located at distance b. The plate height A corresponds to narrower

Cover the height Ik = h on the front and the height LK ~ h ' on the back. Let the setting be sharp on Ik at distance b, but because of the closed diaphragm the parts LK at depth b + ζ are also sharp on the plate.

The well-known lens equation is:

I_ I _ I_ α ⁺ b ~~~ f or, in other words,

In Fig. 5, the photographic pickup apparatus is replaced by the projection apparatus. B is the lens again, but with the focal length / and with the aperture wide open. The plate generated above is set in A ' at distance ρ and provides a sharp image at distance q in V k', the height of which is equal to ίχ / ί, where t is the enlargement (or reduction) factor.

You have the lens equation again:

and the value of t

t -

(2)

(3)

The plane / 'k' is the front of the t times enlarged replica. The other dimensions are also tidal enlarged, so you have:

and

All projections generated at the different depths t X ζ should be homothetic with respect to the point U.

Fig. 6 shows the sharp setting of the projection lamp, always with the aperture wide open, to the depth U K '. The objective has been advanced by X to B " and the plate by Y to A". The values and q of the lens equation (2) are replaced by p + XY and p + tz - X.

The invention consists in moving the lens and the plate together by X on the one hand and the plate alone by Y - X on the other hand, so that equations (4) and (5) are fulfilled:

(5)

In the drawing, an embodiment of the subject of the invention is shown schematically and only as an example in FIG. A is the frame (picture holder) of the projection lamp, and B is the lens mount; both are connected by a bellows C. The ob j ektivträger B is firmly connected to the support D, which is displaceable on the frame 6 and on which a carriage F , like the support D, can slide parallel to the optical axis. The picture holder A, which is fixedly connected to the plate 52, may initially be set at the correct distance from B by moving the plate on the carriage F and fastened with screws 4 to F. The displacement X is given to the support D by a pull or push rod which can be swiveled by 40 and is adjustable in length and which is displaced in c by the lever M. The lever M can swing about d. So one has set the lengths de = »X ί (α - /) and de = ny ^ a , where η is a constant numerical factor. If you drag point e by length ζ to the right, point c moves by distance X. The error due to the angle of inclination of the rod / becomes very small if this rod is as long as possible and approximately horizontal.

In order now to give the picture holder the shift Y - X , the slide / ⁷ is shifted by the rod 43. This rod, which can pivot about 42 and is articulated to the lever G in FIG. 11, receives the displacement Y - X _{1 in} FIG. 11 when the lever G swings about its axis 10. Determine the lengths 10-11 = m (p - /) on the lever G with a suitable division; 10 - Ho = mX b and Ho - Hz = m X z, ^lon where m and η are constant factors. If, in addition to the general displacement of all points of the support D, including all points of the lever G, the point Hz is drawn to the right by the distance, then the movement of point 11 is equal to X - \ - (F - X) = Y . The axis of the lever G is carried on an extension 8 of the support D. In order to adjust the height correctly, the point 10 can be moved up and down with a screw or, more simply, the hollow axis of the lever G is inserted into that of the holes 9 which results in the best position of the rod 43. The lever G is extended by the rod 20, which prevents inappropriate movements of the lever G by the brake band 23 tightened with screws 24. All movements can be generated by a single lever Q , swingable by 25, which bends at two points 26 and 27 at the distance ff »X5 and ^ (where m is the same factor as above) from the fulcrum.

same traction elements, for example steel wires, carries, whereby the points e and Hs are shifted by ζ when the point 27 of the lever Q is lowered by ζ to the right. The effect of the rope 31 running over the pulleys 33 can be seen from the drawing. The rope 45, starting from 26 and running over the pulleys 46, 46 ', 15 (in front of the axis of rotation of the lever G) 16 (behind this axis), 17, pulls the sleeve 19 down by m X s . In this case 46 'should lie approximately vertically below the axis 10 and far below. It should be noted that the rope between the rollers 15 and 16 coincides exactly with the axis of the hollow axis of rotation 10, so that the roller 15 can swing about the axis 10 and is carried by it. The roller 16 is carried by the lever G itself. Finally, starting from 27, running over the fixed deflection pulleys 32 and around the pulley 32 ', which can swing about its fixed axis, and then running over the pulleys 32 ", the rope 30 engages the center of the sleeve 19. The pulleys 32" are also around the axle carrying it is swingable, and this axle itself is also carried by a downward extension of the support D. 48 is a counterweight which prevents the sleeve 19 from falling through the rope 47. The levers G and O can also be provided with counterweights such as 37, which tend to pull the levers M and G into the starting position and the lever Q into the end position. The effect of the weights of levers M and G, as well as of weight 48, should be canceled out precisely by the effect of the weight of lever Q. The positions of the pulleys are chosen so that the errors in the angle of inclination of the levers and ropes and by sliding around m X ζ of the sleeve along the lever G cancel each other out. You can also bend the lever G or attach a shaped piece between it on its pulling side and the sleeve 19 so that, apart from the movement X, the horizontal projection of the movement of the point Hs is always the same as the horizontal projection of the movement of the point 27. A hood or apron that is not indicated protects the facility from dust and bumps.

If a - f in equation (4), then Ä ^r = O is constant. The objective is no longer shifted; since the points c and d coincide on the lever M , the lever M and the rod / are superfluous. Part D is fixed.

If one does not have a photographic apparatus with the desired focal length / 'to produce the plate according to equation (1), any hand-held camera with a focal length / "can be used. The distance b is retained and a different plate is obtained at a distance ra, see above that

raX b = f "(ra + b).
Afterwards, one enlarges or reduces the size of the plate photographically in a known manner, so that

r = -

f X f "

is because you have:

r · a

If, on the other hand, α is smaller than /, point d comes to lie above point c. X becomes negative, ie the shift takes place in the opposite direction as Y and z.

If you set yourself up so that p = a , then the formulas (3), (4) and (5) become (3 '), (4') and (S ') -

t = £ or q = tb

b + ζ
from these equations then arises

X_ tb + tz _ g + tz

Y ~ a + tb + tz ~~ p + q + tz

(6)

and if i = i, i.e. should the simulation have the same size as the model, then equation (6) becomes (6 '):

(6 ¹ )

In the drawing, an embodiment for this case is given schematically and merely as an example in FIGS. The frame has been replaced by the slide rails E here. A lever G, which is articulated to slide F and object B in 50 and 51, inevitably determines the position of the image carrier A and the lens carrier B. The lever G is pivotable about an adjustable point H located on its axis in the initial position arranged. The joints 50 and 51 used to connect the lever G to the parts F and B are slidable vertically in the grooves of the parts F and B. The joint H of the lever can be formed by a bolt 2 which, for. B. by means of two clamping clips 3 along the lever G provided with a suitable pitch and another fixed running rail / can slide. The lever G is in its

Starting position of the running rail J parallel. This also carries a division that is the same as that of the lever and coincides with it. The plane of movement of the lever G, as well as the movements of the carriage F and the support D, are exactly parallel to the optical axis of the objective. To adjust the image precisely, the upper end of the lever 50 is swung forward about the respective pivot point H , and so the displacements of the lens and the plate always correspond to equations (4 ') and (6') if the horizontal displacement of point 50 is equal ζ and at the same time, the respective pivot point H is in Hz, is determined so that its distance from the initial position Ho equal to or ζ ms, depending on whether one of the distances 50-51 and Si Ho, the length /; and chose q or mp and mq . Here again, m is an arbitrary constant factor. The tensioning clamps 3 can be fastened to the lever G and the running rail / by means of screws. The handling is very simplified by the lever M, which by means of the oscillating rod 7 provides the displacement X of the support and consequently also the displacement Y of the carriage, as in the embodiment shown in FIG the front of the replica will be quite sharp. Since ρ = a and t = /, it should be at the distance q = tb - b . You will move the carriage F on the support D and at the same time, if necessary, the lens itself with the adjusting screw located on it. In this case, the focal lengths of the two lenses / 'and f must also be exactly the same. Depending on the value of the factor m , the inclination of the lever G will turn out and the running rail J will be set exactly parallel to the lever G in this position.

In Figs. 2 and 3 there is only one side

Lever G indicated. In reality it will

4-5 it can be arranged between the rails E in order to avoid jamming, or two lateral levers G, if possible connected to form a frame, are used. The lever M should not interfere with the projections.

It is therefore bent to the side or placed horizontally or behind the apparatus. The pivot point d can even be at the top. If the factor η is large enough, the error due to the angle of inclination of the rod / is very small, and a groove like 61 does not need to be made at point c. If there were a groove at point c, the rod / would always have to remain exactly horizontal, ie it would not have to be guided far from c between two fixed parts.

If the size factor t is larger or smaller than i, the distance between the points 51 becomes I - HO = mq and Ho - Hz - mtz.

If you want to avoid the grooves, you can also connect the points 50 and 51 of the lever G on the one hand and the carriage f and the support D with small tie rods with adjustable lengths. The lengths are advantageously chosen so that the upper one is slightly longer than the lower, approximately in the ratio of

2 ^> + 2 q + ζ

2q + ζ

where here ζ is the greatest depth (thickness) of the replica.

If you only want to work with one device, you wear z. B. on the model with a Markers have level curve-like lines (and points), each of which is in a plane perpendicular to the optical axis. After taking the picture with a very dimmed Objectively, the homothetic projections of the plate become more open Aperture set to the appropriate depth and processed the material. Man The depth of field can be reduced by looking through the central rays of light a central screen closes off.

It is often advantageous to move the lever end Q (Fig. 1) or M (Fig. 2) forward not by the length z, but by tz . Then multiply the lever length by t. In this way, the displacement components of the lever end and the tool tip that are parallel to the optical axis can then be connected to one another.

If you want to create replicas that have a different size scale in one direction than in the other, e.g. B. the factor g for the direction parallel to the axis and t in the directions perpendicular to it, then in Fig. 5 and 6 Ul ' = gb and IU = gz. The equation (5) remains unchanged, while the equation (4 ) becomes (4 "):

Thus, the device can be used with a single apparatus for ground reliefs (with a very large b , Y - X is practically zero) and for so-called vertical images (relief replicas), provided that the necessary level curves are generated on the model or are known. If X is to be equal to zero, one chooses a; so that the counter is equal to zero, so:

In the applications of the apparatus for photosculpture described above, the was Stone block fixed in place. But you could

also assume that ζ. B. the cliché would be fixed, and the shifts of the Lens and log so calculate that the images on the log in different Lows are the right sizes. One then comes to the shift - F des Block and - (F-X) of the lens. So it's the same procedure, only you have that whole system: cliché + lens + block

ίο In addition to the above-mentioned shifts X of the lens and Y of the cliché, a new shift - F is given, which defines the cliché, because -f- Y - Y = O. If, on the other hand, the new additional shift were instead of - Y equal to - X, then it would be the lens is fixed. The cliché b then moves around Y - X and the block around - X. It is also an application of the above formulas. As described above, the magnitudes of the displacements are formed as fourth proportions, only it is more difficult to move the heavy stone block exactly parallel to the optical axis on rails than a light cliché or a lens.

The invention is particularly suitable for photographic recording apparatus because, once the apparatus is set precisely to a distance, one immediately not only produces sharp images without looking at the ground glass, but also knows their size in advance, since they are proportional to the Distance from point U is.

Claims (11)

Patent claims: ι. Pro j ection device for recording and demonstration, especially for the purposes of photo sculpture, with a movable lens carrier on which the image holder slides, characterized in that the displacements X of the lens (B) and Y of the image holder (A) are chosen so that all Sharply projected images at different distances with a wide open aperture have a common, fixed homothetic center, that is, all these images are similar to one another and are positioned in perspective to one another. 2. Projection device according to claim i, characterized in that the equations for the displacements X of the lens (B) and Y of the image holder (^ i) are fulfilled. In these equations is the size factor . a q _% α and b are the distances between the optical center of the photographic apparatus, on the one hand, from the plate (A) when taking the picture, and, on the other hand, from the plane (Ik) of the model conjugated by the lens equation; p and q are the distances in the projection apparatus of the optical center, on the one hand from the plate (A ') obtained above and on the other hand from the conjugate plane (Vk') in the replica; f is the focal length of the projector; tz is the depth (VU) of the area to be worked on in the replica , measured from the initial plane (Vk ') , to which depth in the model the depth (/ L) = ζ corresponds. 3. Projection device according to claim ι and 2, in which the lens carrier (B) and the image holder (A) together the displacement X and also the image holder (A) only receive the displacement F - X according to the following equations: X. ' ™ XX. —— · " 4. Projection device according to claim ι to 3, in which the lengths of the displacements X and F - X as fourth proportions for X of the sizes nt (a - /), na and ζ and for F - X of the sizes m (p - /) , m (b + s) and s or, in order to be able to connect the displacement components of the lever end and the tool tip parallel to the optical axis, for X the sizes »(α - /), na and tz and for YX the sizes z . B. m (p - f), mt (b + s) and ts, where m and η are arbitrarily chosen constant numerical factors. 5. Projection device according to claim ι to 4, characterized in that α = f , so that consistently X = O and the lens is no longer shifted needs to become. no 6. Projection device according to claim ι to 3, characterized in that p = α , whereby the equations of claims 2 and 3 merge into the following: .λ. q - {- 1 ζ Y p - \ - q - \ - 1z ' whereby these shifts are either calculated or inevitably as a fourth pro- portionals for X between 'the lengths nt (p - /), np and ζ or η (ρ - /), η p and ts and for Y as fourth proportions of the sizes q - \ - tz, p -f- q 4- tz and X are formed. 7. Projection device according to claim ι to 6, characterized by the Application to photosculpture either by working hard material such as marble or the like, or by applying soft material, such as clay or the like. 8. Projection device according to claim ι to 6, characterized by the Application for the production of maps by means of terrain photographs. 9. Projection device according to claim ι to 6, characterized by the Use in cinema projection to create special movement effects, whereby the projection screen is moved in the direction approximately perpendicular to their plane. 10. Projection device according to claim ι to 4, characterized by the application for the production of relief images in the case that the size factor g of the replica in the direction parallel to the optical axis of the projection device is different from the size factor t in the directions perpendicular to this axis , whereby ga and YX retains the same value as in claim 3. 11. Application of the projection device according to claim r to 4 and 10 for in the event that t _ is that X is constantly equal to zero and the plate (A) is increased by one of the following amounts: P-f P-f Y = tr ^ * or
0 4- ζ • g ζ or- shifts, whereby the lengths multiplied or divided by g should form the fourth proportional. For this purpose ι sheet of drawings