DE1524098A1 - Arrangement for the encryption and storage of topologically representable structures, in particular of chemical structural formulas - Google Patents

Description

Arrangement for the encryption and storage of topologically representable structures, in particular of chemical structural formulas Addition to patent u o00 oaa (patent application B 59 818 IXb / 42m) in the patent. ..o ..o (DAS 1 218 186) describes a method for the encryption and storage of togologically representable structures, in particular chemical structural formulas, for documentation purposes by means of data processing systems, in which the individual points or components of the structure picture at least with regard to their connection recorded at other points by identifying data in memories and for this purpose transferred to a rasterized sheet as evaluable linear markings. These markings are then converted into preferably electrical impulses by relative movements of the sheet with respect to tactile organs. According to the inventive benefits of the above-mentioned patent, the structure image to be encrypted is laid down on the sheet exclusively from horizontally, vertically or diagonally marked connections of the raster points and is queried by aligned progressive oscillating relative movements of the tactile organs with respect to the sheet.

According to the additional patent o ..o coc (patent application B 59 818 IXb / 42m), the rastered sheet covered with the structure image to be scanned is additionally prepared with one or more clock tracks for synchronization by coordinate area, the marks of the clocks being arranged purely according to the oscillating form of movement are to determine the gate times for the structure picture querying Taatorgane through their extension and cause their timing when using punched cards as storage means and consequently of card holes as pulse converters. The last-mentioned patent also teaches that two oscillating continuous movements of the prepared sheet with respect to the tactile organs are carried out which are out of phase with one another (see FIG. 1).

Two factors have a major impact on the manual workload the encryption process. The scanning is done safely and correctly if the structure to be scanned is drawn exactly on the grid sheet, i.e. the marked horizontal, vertical and diagonal lines are not crooked from point to point. Furthermore, the sheet must be inserted into the scanning device in a precisely adjusted manner. the possible errors in these two operations add up. The level of care that has to be expended determines the working speed of the coding. The inventive design of the attached to the edge of the sheet In the cycle track, the permissible tolerances are increased significantly.

The use of clock tracks in any type of scanning method is known. They always have a finite width and their surface elements, or the tabs between the elements, are aligned parallel or perpendicular to the general direction of movement. Even when vibrations are superimposed over the general scanning movement, the vertical and parallel alignment of the clock track fields has hitherto been retained (see Figs. 1 and 2), because the straight-line basic speed is decisive for the time rhythm of scanning and the superimposed oscillation has no influence on this rhythm is. A necessary increase in the tolerances has so far been made within limits determined by the required gap by increasing the areas of the clock track fields.

It has now been found that the tolerances for the position of the marked lines and for the insertion of the razor leaf into the encryption device can be significantly increased if, according to the invention, the individual areas and gaps of the clock track fields are made of lines that run at an angle to the general direction of movement, preferably of lines that run at an angle Straight lines, are limited .

With reference to the drawing is the invention and the at of an application on the encryption method progress described in more detail below.

Figures 2, 3 and 4 show the relationships in use the conventional and Figures 5, 6 and? the corresponding ratios the application of the invention. limited track fields again.

When the raster sheet, which oscillates twice in opposite phase, is displaced in relation to the encryption device with the sensitive organs within the limits given by the technical and manual tolerances, a simulated sensitivity range results, as shown schematically in FIG. The border area shown also arises due to deviations from the exactly straight, shortest connection between adjacent grid points by less carefully marked connecting lines that build up the structural image to be encrypted. In FIG. 3, the areas for horizontal and vertical deflection or deviation are shown as solid lines, those for diagonal deflection are shown as dotted lines . The extent of the respective deflection is shown in FIG. 3 by the distance x of the points from the assumed center point of the anti-phase tracks . For the inventive clock track according to FIG 5, the corresponding distance is x 'in Figure 6 deliberately made larger than the previously customary trace of Figure 2, greater to the desired progress reasonable tolerances to be considered. The narrowest boundaries given by the lines in Figure 3 and Figure 6 indicate the area in which the marked line connections to be scanned must be located if the grid sheet is imprecisely inserted into the encryption device according to the main patent, so that they are correctly and reliably detected by the tactile elements. In FIGS. 4 and 7, gates are drawn in corresponding to these narrowest boundaries, through which the marked lines must pass. The rectangles also shown there, similar to the rays of a compass rose, indicate the area in which the lines must run. The width of these squares is a measure of how "crooked" the horizontal, vertical and diagonal line connections between adjacent grid points may be. Despite the 50% increase in the deflection x 'compared to the largest possible conventional dimension x, the smallest tolerances are As can be seen in FIG. 7, it is still significantly greater than the corresponding tolerances according to FIG. 4, especially with regard to the longest diagonally marked connections can be drawn freehand quickly without affecting the accuracy of the data acquisition.

Claims (1)

Claim Arrangement for encoding and storage of topological representable structures, especially of chemical structures formulas, for documentation purposes by means of data processing of the systems in which the individual points or modules of the Structural picture at least in terms of their bond with others Points held by identifying data in memories and on a gridded sheet as evaluable, in it evaluable finally, horizontally, vertically or diagonally linear markings are transferred, which then by aligned progressive, oscillating relative movements of the leaf compared to tactile organs in preferably electrical Impulses are implemented, whereby the sheet for the coordinate Area-by-area synchronization with one or more clock traces are prepared, there are marks according to the swinging the movement form are arranged, according to patent. ... ... (Pa- tent application B 59 818 IXb / 42m), characterized in that the individual surfaces and lines of the clock track fields from opposite lines running at an oblique angle over the direction of movement trains, preferably limited by oblique straight lines are.