DE1423636A1 - Procedure for determining the area content of areas - Google Patents

Description

Procedure for determining the area of surfaces.

The invention relates to a method for approximate determination of the surface area of irregularly delimited areas, which are distinguished by their color and / or Stand out the brightness from the background.

The area content of irregularly limited areas can be known be determined with planimeters or by photo-technical means. Have these procedures the disadvantage that they are relatively time consuming.

According to another known method for determining the area irregularly delimited printing areas is based on the area to be poured a equally large stencils generated and these with a large number of small bodies, for example with small balls of the same diameter.

The balls used are then in the form of a rectangle arranged and the total area occupied by them calculated in a simple manner. This known method has the disadvantage that the template is relatively cumbersome and must be made in a time-consuming manner. According to another known process the area to be measured is provided with an adhesive coating so that the Imprint of this area on a measuring area densely covered with spheres, part of the Balls on the sticky surface and the other part of the ball remains on the measuring surface.

Those adhering to the surface or those remaining on the measuring surface Balls can then be arranged in the shape of a rectangle, so that of them occupied area can be determined in a simple manner. This known method has the disadvantage that the area to be measured after the method has been carried out must be cleaned to remove the sticky mass. Furthermore, the Balls are cleaned after each measurement, if you don't have the greater effort, which is conditioned by the use of ever newer balls, wants to accept.

The invention aims to provide a method according to which the disadvantages the known methods can be avoided.

By default, the area is the area whose area is to be determined is to be scanned and, using per se known television technology means a video signal obtained that corresponds to the area or according to the Background has different amplitudes. Furthermore, measured values are derived that of the duration of the acquired during the scanning of the surface or the background Signal are proportional and eventually there is a summation of all of these readings made, which thereby gained at least one complete scan of the surface became.

The method according to the invention can be used, for example, in printing technology can be used to determine the expected ink consumption. The inventive The method can also be used to determine the surface area of electrically conductive surfaces are used, the surface of which is electroplated, for example calculate the gold consumption. Such electrically conductive surfaces must in particular a galvanic surface treatment during the creation of so-called ttprinted circuits be subjected.

The inventive method has the advantage that so that the Measured values are available almost instantly stand. Furthermore is it is advantageous that cleaning of the area to be measured is not necessary, since they are only scanned optically according to the method according to the invention and in particular is not provided with an adhesive coating, as is the case after one of the known methods happens. It is also advantageous that the Area even with no mechanical parts, such as small balls, in Is brought into contact, so that, for example, when applying the invention in the Printing technology the risk of damage to the roller by accidentally remaining Balls is switched off from the start. Finally, the inventive Also still have the advantage that it can be done during operation can, so that for example the surface area of printed on a paper tape Areas can be measured without switching off the tape transport.

A generator can be used to carry out the method according to the invention be used, which generates vibrations or pulses of equal duration that only as long as a counting stage are fed as the electron beam the image of the to be measured scans. By counting the generated in this generator Vibrations or pulses can then be determined as a measurement number that corresponds to the area is proportional to the area to be measured.

In some cases it is easier to do this when scanning the area to chop the recovered video signal by electronic or optical means, whereby a large number of pulses of the same length are obtained, the number of which is also one The measured value represents1 which is proportional to the area sought.

It is also conceivable to use the video signals or signals derived therefrom To feed signals to a switchable timepiece, which within a measuring period automatically switched on at a certain position of the scanning electron beam and is automatically switched off later when this same position is reached. Except this first switch-on and the one finally made at the end of the measurement period last switch-off, the timing device is always switched on when the video signal reached a certain amplitude and then switched off when a certain Amplitude is not reached.

According to a development of the invention, a body can be used Television technical means from at least two different directions of reception be recorded in such a way that one of the dimensions of the recorded areas further measure can be derived, which is proportional to the volume of the body. To the A calculating machine can be provided for calculating this further dimension figure the dimensions of the recorded areas are forwarded as input.

In the following the invention and embodiments thereof described with reference to Figures i to 4, the same occurring in several figures Circuit arrangements and forms of pulse trains are denoted by the same reference numerals are. For the sake of simplicity of illustration, only those for understanding the invention are provided necessary details are shown schematically. The figures show: FIG. I a measuring method using a generator and a Zälilstufe, Figure 2 a measuring method, after the video signal is fed to a counter in the chopped state, figure 3 a measuring method according to which square-wave pulses of constant amplitude from the video signal derived and after rectification using an instrument a measured value is derived, Figure 4 shows a measuring method using a Light point scanner.

According to FIG. 1, the area 1 to be measured and the background 2 recorded with the camera 3 and thereby a video signal obtained line-by-line scanning. The video signal 4 corresponding to a Zeilc with the horizontal sync pulses 5 and 6 run in clearly separated aplitude areas with the black level 7 and the white level 8.

This video signal 4 is in the limiter stage 9 by double-sided Amplitude limitation derives the signal 11, which is derived from a sequence of square-wave pulses 12 composed. The duration D of these rectangular pulses 12 from time t1 to at time t2, the area of one line of area 1 is proportional. at the line-by-line scanning of the surface 1, it can naturally happen that per line not just a single pulse 12, but several of which are generated, their sum however, a measurement of the area of the scanned along a line Represents area.

The Impulsiolge 11 is fed to the generator 13, in which b the Point in time ti to point in time t2 either the sinusoidal oscillations 14 (under Use of a so-called 3-start-stop oscillator) or the pulses 14 ′ are generated will.

Both the individual oscillations 14 and all of the pulses 141 have each same duration and their number is the area of one line of the surface i is proportional and can therefore be viewed as a measured value. These vibrations 14 or the pulse 14 'are then fed to the counting stage 15 and their number summed up, so that after a whole dildo has been scanned, the sum of the measured values is obtained, which is proportional to the area of the area 1 to be measured. The repetition frequency of the oscillations 14 and the pulses 14 'should be essential be greater than the e repetition frequency of the Morizontalsynchronimpulse, for example about 1000 times larger to ensure accurate determination of the contents. 909813/0040 ORIGINAL BATHROOM With the counting stage 15 can in this way Oscillations 14 or pulses 14 'are counted by repeated television viewing Scanning of the area 1 have been obtained. The measurement accuracy is all the greater the greater the number of samples on which the essun is based.

In this television-like scanning, the camera 3 is known per se Way and using stage 18 synchronized. Since the count level 15 at certain periodically repeating positions of the scanning electron beam must be switched on or off, the counting stage 15 can after switching on of the total circuit arrangement shown in FIG. 1, vertical synchronization pulses are fed from stage 18, the counting process (with respect to the vibrations 14 or the pulses 14 ') initiated by a first of these vertical sync pulses and by a very specific further one of these vertical sync pulses, for example the eighth vertical sync pulse is ended. In the payment level 15 is therefore excluded a first counter for counting the oscillations 14 or the pulses 14 'also another counting stage for counting the vertical sync pulses and also a circuit arrangement built in, which after deposits of the certain vertical sync pulse causes the first counting stage to be switched off.

The generator 13 and the counting stage 15 can possibly by a timing device 17 must be replaced. The sequence of square-wave pulses 12 is then dashed over the Line 16 shown supplied to the Zeitiuoßgerät 17, which within a Measuring period automatically at a certain position of the scanning electron beam switched on and later switched off automatically when this same position is reached will. This timepiece 17 is within this measuring period during the Duration D of the square-wave pulses 12 and similar during the duration - but during the scanning other lines obtained - iLechteckimpulses switched on and during the rest Time off. Since each of these square-wave pulses represents a measured value, in timing device 17 the sum these measured values determined that the Area of area 1 is proportional.

The synchronization of this timepiece 17 can be done with vertical synchronization pulses be effected, the measuring period by a first of these vertical sync pulses initiated by level 18 and by a very specific further one of these verticals sync pulses is terminated.

It is often advantageous to derive measures that correspond to the area the area 1 or that of the ground 2 are proportional. Because the sum these measures must be constant, is made by a possible change in this sum a false indication of the measuring device is displayed. Furthermore, both dimensions result one independent of any fluctuations in the operating voltages and the like relative measure. To carry out this measure, in addition to the counting stage 15, for Counting the oscillations 14 or the pulses 14 'provided a further Zälilstufe be turned on during all full scans of area 1, but is always switched off when the supply of oscillations 14 or pulses 14 'to counting stage 15 is effected.

In some cases it can be useful to use electronic To chop up means and with the impulses obtained in this way of the same duration Derive measured values.

According to Figure 2, the surface 1, as already described, with the camera 3 recorded and the video signal thus obtained is chopped up in the chopper 19 so that the pulse train 21 arises.

This chopping can be done, for example, by mixing with a sequence caused by square pulses, the pulse repetition frequency of which is much higher than the pulse repetition rate of the liorizontal sync pulses should be to one allow accurate measurement.

The pulse train 21, which is 1111 present case for the purpose of einfactierer Representation only from the square pulses 22g 2), 24 composed, is converted into the pulse train by double-sided amplitude limitation in the limiter 25 26 converted, which is fed to the counting stage 15 4 The number of pulses 22, 23, 24 represents a measured value, so that in the counting stage 15 a summation of these Measured values and thus a measure is obtained, which is the area of the area 1 is proportional.

According to FIG. 3, the video signal 4 can be made using the crosser 28 a sequence of pulses 29 can be derived, the amplitude of which is largely constant so that the pulse area f represents a measured value and is proportional to that duration is, while the scanning electron beam is the Uild of the surface i along a Line scans. The sequence of the square-wave pulses 29 is then sent to the rectifier 31 fed in, where the individual measured values are summed up and the DC voltage thus obtained is indicated by the instrument 32.

Instead of the television camera shown in FIGS 3, a light point scanning device known per se can optionally also be used will. Furthermore, by a rotating aperture that is in the beam path between the Surface 1 and the scanning tube of the television light point scanner is arranged, one Chopping of the video signal can be made so that this is in a variety pulses 22, 23, 24 of equal length are divided. These impulses can eventually can be counted using a counter 15, such a chopped video signal can also be periodically intermittent when using a light point scanner Illumination of the area i can be achieved.

According to Figure 4 is a light point scanner with a cathode ray tube 30, a lens 31 and photocells 32 and 33 for television-like scanning of the belt 34 is used.

It is assumed that on the belt 34 at regular intervals Areas 35 are printed, the area of which is to be determined. If the The scanning process is carried out using the interlace method, the Feed of the tape in the direction of the drawn part and the deflection of Electron beam are carried out within the cathode ray tube 30 in such a way that a grid on a first surface 35 'and the second grid on the following one Area 35 "is written.

This surface 35 on the moving belt 34 can also be used a television camera are scanned, means being provided each for the duration of this scan and for the duration of a periodically intermittent one Illumination on the photo layer of the television pickup tube creates a still image cause. In doing so, either kaiui the television camera in the direction of movement of the belt 34 carried along or caused a compensation of the tape movement by optical means will.

Claims (22)

Claims 1. Method for the approximate determination of the surface area irregularly delimited areas, which are distinguished by their color and / or brightness Distinguish background, characterized in that the area (i) using television technical means (3, 31-33) named per se, scanned and thereby a Video signal (4) is obtained, which corresponds to the area (i) or accordingly has two different amplitudes (7, 8) on the background (2), since further measurements can be derived from the duration (D) of the scanning of the surface (i) and / or of the background (2) obtained signal are proportional and that ultimately a Summation of all measured values is carried out by at least one complete Sampling of area (i) were obtained. 2. The method according to claim 1, characterized in that with the during the scanning of the surface (i) obtained video signal (4) or with one therefrom derived signal (11) in each case the supply of vibrations (14) or Pulses (14t) of the same duration to a counting stage (15) is effected when the video signal (4) or the signal (11) derived therefrom has reached a certain amplitude, that furthermore the repetition frequency of the oscillations (14) or de pulses (14 ') much greater than the repetition frequency of the horizontal sync pulses (5, 6) and that finally the oscillations (14) or pulses (14 ') during the Duration of at least one complete scan of the area (i) using the Counting stage (15) are counted. 3. The method according to claim i, characterized in that the video signal (4) or a signal derived therefrom (ii) with electronic means (19) such that the video signal or the signal derived therefrom is chopped into a plurality pulses of the same length (22, 23, 24) are divided, furthermore that in this way obtained pulses (22, 23, 24), the number of which represents a measured value, a counting stage (15) and the summation of the measured values is carried out. 4. The method according to claim i, characterized in that the surface (i) is scanned using a television light spot scanner, that further by a moving diaphragm that is in the beam path between the surface and the Scanning tube of the television light point scanner is arranged, a chopping of the video signal is carried out in such a way that this is divided into a large number of pulses of equal length (22, 23, 24). is divided and that finally the impulses obtained in this way (22, 23, 24) are fed to a counting stage (15). 5. The method according to claim 1, characterized in that the surface (i) scanned using a light spot scanner and so periodically is intermittently illuminated that the video signal in a plurality of equal length Pulses (22, 23, 24) is divided and that finally the obtained in this way Pulses (22, 23, 24) are fed to a counting stage (is). 6. The method according to claim 1, characterized in that the video signals (4) or signals derived therefrom (ii) are fed to a switchable timing device (17) which is automatically performed at a certain position within a measuring period of the scanning electron beam switched on and later when it is reached same position is automatically switched off and that the timing device (17) within this measuring period depending on the amplitude of the video signal or on the Amplitude of signals derived therefrom (12) is switched on or off. 7. The method according to claim 1, characterized in that from the Video signal (4) using a limiter (28) a sequence of rectangular Impulse (29) is derived, the Imlxulsilache (f) only from the duration of the the scanning of the surface (i) or the background (2) obtained signal depends and that by rectification (31) of this sequence of rectangular pulses (29) the The sum of the measured values is derived, which corresponds to the area of the area to be measured (1) is proportional. 8. The method according to claim 2 and 3, characterized in that except the counting stage (is) for counting the oscillations (14) or pulses (14 ') another Counting stage is provided during all full scans of the area (i) is switched on but is always switched off when the supply of the vibrations (14) the pulses (14 ') to the counter stage (-15) is effected. 9. The method according to claim 1, characterized in that from the obtained in the television scanning of the surface (i) and the background (2) Video signal (4) by limiting and overdriving a sequence of essentially rectangular pulses (12) is obtained, the duration of which is proportional to that duration is, during which the electron beam is the image of the surface (1) or that of the I background (2) is scanned along a line. 10. The method according to claim 2, characterized in that the frequency or pulse repetition frequency in the generator (13), preferably in a start-stop oscillator generated vibrations (14) or pulses (14 ') much larger, preferably at least 500 times greater than the pulse repetition frequency of the horizontal sync pulses (5, 6). 11. The method according to claim 3, characterized in that the video signal (4) or a signal derived therefrom using square-wave pulses is chopped, the pulse repetition frequency of which is substantially greater, preferably at least 500 times greater than the pulse repetition frequency of the Morizontalsynchronimt3ulse (5, 6) is. 12. The method according to claim 2 or 3, characterized in that vertical synchronizing pulses are fed to the counting stage (is) and the counting process is carried out a first of these vertical sync pulses initiated and by a certain further of the vertical sync pulses is terminated. 13. The method according to claim 4, characterized in that the timepiece (17) Vertical syncfiron impulses are fed and that the measuring period by a first of these vertical sync pulses initiated and by a certain further this vertical sync pulse is terminated. 14. The method according to claim i, characterized in that the television-like Scanning the area (i) using a television camera (3) or a light spot scanner (30 - 33) is carried out. 15. The method according to claim i, characterized in that the surfaces, whose area is to be determined, displayed on a moving belt and are scanned using television technology means (3, 30-33) and that the advancement of the tape and the deflection of the electron beam within the television technology means is carried out in such a way that by two after the Interlace consecutive scans a full scan of the image of the surface is achieved. 16. The method according to claim 1, characterized in that the surfaces (35), the area of which is to be determined, on a moving belt (34) and scanned using a television camera and that further means are provided, each during the duration of this scan and for the duration of a, preferably periodically intermittent, illumination cause a still image on the photo layer of the television tube. 17. The method according to claim 16, characterized in that during the duration of one sampling and preferably periodically during the duration intermittent lighting either the television caller in the direction of movement of the tape is carried or that a compensation of the tape movement by optical means is effected. 18. The method according to claim 15, characterized in that on the moving belt (34) applied the same areas at equal intervals and that in an interlace scanning operation the advance of the tape (34) and the deflection of the electron beam are carried out in this way is that a grid on a first surface and the second grid on the next Area is written. 19. The method according to claim 1, characterized by the determination the area of the printed areas. 20. The method according to claim 1, characterized in that dai3 is a body using television technology means from at least two different recording directions is recorded in such a way that from the dimensions of the recorded areas another Dimension can be derived, which is proportional to the volume of the sorper. 21st Device for carrying out the method according to Claim 20, characterized in that that a calculating machine is provided, which the dimensions of the recorded areas are forwarded as input and which is operated in such a way that the further dimension figure, which is proportional to the volume of the body, is derived automatically. 22. Ancestors according to claim i, characterized by the determination the surface area of electrically conductive surfaces, preferably such Areas, the surface of which is to be subjected to a galvanic treatment.