DE1774089A1 - Optical scanning of upright perforated data carriers - Google Patents

Description

Df. Htrhfrt Sehols

Applicant: < ^: l> w '■■■''- ■■ - * - är-n - <. \ Hany £ * r, it> ii Act No. PHD- 869

from »April 3, 1968 1774 089

Philips Patentverwaltung GmbHc., 2 Hamburg 1, Mönckebergstrasse »7

"Optical scanning of standing perforated data ··

carrier"

The invention relates to an optical scanning device for data carriers that are stationary during the entire scanning process, such as punch cards, which are located between a fixed light source and fixed photo transducers, for scanning information stored in the form of holes, the location of the scanning being indicated by a light source and photo transducers moving panel is given ·

In data processing as well as in digital control and regulation technology, there are numerous applications in which relatively small amounts of information should be entered, e.g. in production control, worker hourly cards, parts lists, stocks, etc., in control technology programs for machine tools or for certain component mixtures in the chemical industry and in data processing, as in invoicing Industry programs and customer addresses · With the usual input into computers, the data is first transferred to a memory and called up from there at the appropriate time for further processing. Wherever the required amount of information is so small that it can be placed on a Looh card or a relatively short piece of a punched tape, for example , you can save intermediate storage by keeping the punched card in the input device as long as the information is needed.

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(EV- 2967) 109840/1387

This task is carried out by the so-called block blanks for punched strips and punch cards met. In the first case, the punch card is inserted by hand and so for scanning the 80 columns long held until the information is no longer needed will. Punched tapes are made by hand or by machine so far transported until the desired block is under the reading station * These well-known blookleeers work according to ver ~ different principles

With some devices, data carriers and defensive organs are fixed, all information on the data carrier is queried "in parallel". In this case, as many scanning elements are required as the maximum possible number of bits in the block, i.e. ζ «Β _Φ with the usual punched card 12 χ 80» 960 scanning elements «The information contained in the card is then available for any time« parallel ¹¹ , ie available on 960 channels. This requires a considerable amount of effort both in terms of the number of scanning elements (especially if, for reasons of reliability, the mechanical contacts are replaced by photoelectric, thermal or capacitive scanning elements) and in terms of the further processing of the information. In addition, an additional parallel to serial converter will generally be required.

In other cases, the data carrier and the defensive organs are moved relative to one another. The data carrier is periodically sent to the reading station passed, which now only contains the scanning elements for one column (that is, in the case of the punch card 12). For example, »B * the punched card held in place on a rotating cylinder by negative pressure «If the punched card is illuminated from the inside, you can by means of the fixed reading station located outside the individual columns are scanned in sequence, ep that the information is available serially and periodically the one that keeps going around. The expenditure on scanning elements goes back considerably, and since the information is already supplied in series a parallel to serial converter is no longer required This advantage is bought with the disadvantage that

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BADORIQINAL ** ~

Relatively more precise and complex transport and guide mechanism for the data carrier is required «In addition, it is In the case of punched tape, for structural reasons, it is often not possible to make the loop so short that it would correspond to the stored information, so that undesirable spaces are also accepted must be taken »

It is also known that data carriers and scanning devices are fixed stand, but the light paths between light source, data carrier and light receiver are deformed or switched reliable information recognition sufficient light energy from a not excessively strong light source through each individually of the holes distributed over the planes of the information carrier reaches the light receiver (s), very elaborate light guides have been used in the known implementations of this principle.So, systems made from mechanically moved polygon mirrors, from light-conducting glass rods or from fiber optics have become known Used in connection with light switches, in which for parallel · * ■ serial conversion of the information and for saving photodiodes e.g. the 12 light entry surfaces of 12 light guides (e.g. glass rods) that lead to 12 photodiodes »mechanically on the 960 Idoth exit areas of 960 light guides, which come from the information-bearing points on the data carrier, are passed by The disadvantage is the high cost of light guides, as well as the function-related necessary high accuracy of the guiding mechanisms of the moving light-guiding components as well as the Disk. Ζ · Β »the data carrier holes must be exactly on the ends of the light guide in both directions of the plane.

Finally, a construction has already become known in which the punch card is constantly illuminated on one side and the light falling through the holes in each line is collected by a light guide on a photodiode. the Scanning takes place through a moving screen between the punch card and the light guide, which only releases one gap.

1098 /. n / 1387 ~ 4 ~

INSPSCTSO

The lighting of the map is done with diffuse Light, so that for a clear column selection ilende and map may only have a very small distance, or one on top of the other grinding «In addition, the multiple reflection, the entrance aperture and the transmission * · degree a strong attenuation of the light, which also depends on the position of the column. however, complete serial, hole-by-hole scanning is not possible with just one photodiode.

The invention avoids these disadvantages by illuminating one side of the punched card with parallel light and the photo transducer in the one of the coordinates of the data carrier parallel focal line one on the other side of the disk arranged cylindrical-parabolic mirror part, with the focal line outside the light paths between card and Mirror lies,

This results in a much better harvest of rope, or weaker light sources are possible, which means that from the device heat to be dissipated and thus the risk of overheating is lower There is also more freedom of movement for the location of the aperture (above or below the card, distance from the card), so that special diaphragm arrangements, which are described below are possible

Usual photodiodes and similar light-sensitive elements only have light from a relatively small solid angle their nominal sensitivity

By appropriate choice of the curvature of the mirror * i.e., duroh a large focal length can be achieved because the angle between the light falling through the first column and the light falling through the last column in the photodiodes becomes sufficiently small without causing particular losses of light or making the arrangement unwieldy or even unacceptable. Dimensions received

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The drawing shows an exemplary embodiment.Ee show:

1a and 1b show two views of an embodiment with a parabolic of revolution and a cylindrical parabolic mirror,

2a and 2b show two views of an embodiment with two parabolic of revolution Reflect,

3 shows a special diaphragm arrangement.

1a and 1b show two views of an embodiment of the invention using the example of a punch card reader for column-by-column scanning. On one side of the punch card LK there is a rotational parabolic mirror Sp ^, in the focal point F .. is a point light source L- (zoB * a projection lamp). On the other side of the punch card there is a section of a cylindrical parabolic mirror Spg with its cylinder axis and the parabolic apex line Sch in the direction of the columns of the punch card LK and its focal line Fp outside the area of the light paths through the punch card its focal line Fg t in which the light receivers (e.g. B · photodiodes) D are located, namely at a lateral distance from one another, which corresponds to the hole division in a column Rays from the edge gaps and the middle gaps of the punch card »To suppress scattered light, the cavity of the cylindrical parabolic mirror Sp _{2 can be divided} perpendicular to its cylinder axis into 12 chambers by opaque partitions Trw, so that each of the 12 photodiodes is in one chamber.

For scanning the punched card and for parallel-serial conversion of its information, a slit diaphragm SB ^ runs close to the punched card plane on the side of the S mirror Sp-j or on the side of the mirror Sp «over the length of the punch card. The Blendtnechlitz lies parallel to the columns of the punched card, it is covered

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in its length an entire punch cards column and is approximately as wide as the lands between the holes of the card "He is in one pass all columns of the hole card in order free · The aperture may be reciprocally (possibly with fast reverse) or an endless belt, possibly with multiple slots so that the card is immediately rescanned when a scan is completed. Instead of a slotted screen, the screen can also be designed as a row of holes screen, the holes of which are arranged like the holes in a perforated card column and are roughly as wide as the webs between the holes in the card »

The invention allows not only the columns reading the disk, but also allows a serial scanning of the individual holes ο a result, the savings in many applications (eg in data transmission) necessary parallel-serial converter, -,

2a and 2b show two views of an embodiment for this. On one side of the card there is again a rotational parabolic mirror Sp ^ with a point light source L ₁ at its focal point P ^. On the other side of the Kar te is now a section of a revolution parabolic mirror Sp, with the parable apex Sch · The focus of W * of the mirror is outside the range of the light paths through the hole card, the mirror collects everything through the hole card light passing at its focus F ,, in de « a rented tem-

J. "■; - ■

sensitive diode D is located. A diaphragm arrangement is used for scanning the punched card and for parallel-serial conversion of its information , which can be attached to one or the other side of the punched card or divided on both sides. The panel arrangement only releases one hole position on the punch card . It consists, for example, of a slot screen SB ₁ that runs the length of the punch card and releases all 80 columns of a conventional punch card one after the other , while a second slot _{screen SB 2} runs over the width of the punch card and in the column that runs from

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BATH ORIGINAL

the slit diaphragm SB. · is just released, the 12 hole positions releases this column one after the other.

Fig. 3 shows, as an example, another screen arrangement, which in the embodiment of the punch card reader according to Pig. 2a and 2b can be used instead of the two slit diaphragms shown there. ”It also only releases one hole position on the punch card. While in FIGS. 2a and 2b the two panel parts are moved in two mutually perpendicular spatial dimensions, here panel parts B1 ... B1 are only moved in one dimension, namely, as indicated in FIG. 3, the upper panel B1. J in the opposite direction as the middle and lower cover Bl ₀ and Bl * ο If the holes of the upper and middle cover Bl- and Bl _{2 are} offset from each other by the same amount in the running direction as shown and the amount of the speeds is the same , the holes in a column are released one after the other from top to bottom. In order that the columns are sequentially scanned, a plurality of such groups of two diaphragms Bl ₁ and Bl ₂ are staggered holes arranged on each uer. Depending on the order in which the columns are to be scanned one after the other, the groups on the one diaphragm Bl _{2 have} a smaller spacing than on the diaphragm Bl ^ running in the opposite direction. This difference in group spacing must be exactly twice the hole offset between two adjacent holes, while the absolute value of a group spacing must be at least equal to the sum of all hole offsets in a group, reduced by one. Due to the groups of offset holes, not just one, but several columns are scanned at the same time. In order to select only one of these, a third lower diaphragm Bl is used, the opening of which can be the length of a column and up to a multiple of a gap width and which only moves at the same speed as the columns are to be scanned one after the other while the the other two diaphragms BIj and Bl _{2 are moved} at a multiple of this speed corresponding to the mean distance between the two groups of holes. If the card with mainly parallel

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ORIGINAL

If light is shone through, the three panel parts can be kept at a sufficient distance from each other and from the punched card level in order to avoid friction

Claims

10984 0/1387

Claims (5)

Claims 1. Optical scanning device for during the entire scanning process stationary data carriers, such as * punch cards, which are placed between a stationary light source and stationary photo transducers lie, for the scanning of information stored in the form of holes, the location of the scanning being through a between Light source and photo transducers moving diaphragm is given, characterized in that the illumination of one side of the punch card takes place with parallel light and the photo converter in the focal line parallel to one of the coordinates of the data carrier on the other side of the data carrier arranged cylindrical parabolic mirror part lie, with the focal line outside the light paths between the card and the mirror lie. 2. Apparatus according to claim 1, characterized in that on the mirror according to the number and the mutual distance the photo transducer chambers are attached with opaque partitions. 3. Apparatus according to claim 1, characterized in that the mirror part is the section of a rotationally symmetrical Is parabolic mirror and there is only one photo converter in the focal point. 4β device according to claim 3, characterized in that two diaphragms that are moved perpendicular to one another are provided. 5. Apparatus according to claim 3, characterized in that three diaphragms are arranged one above the other, two of which are located with mutually offset rows of holes with a relative speed in mutually opposite directions perpendicular move to the columns to be scanned »while the third aperture is provided with an opening, the at least one releases whole gap and this moves at a different speed than the relative speed 109RA0 / 1387 J » Blank page