CS215997B1 - Connection for determination of distances,areas and quantities respective of objects displayed by the television systems - Google Patents

Description

The invention relates to circuitry for determining the distance, areas and quantities related to objects displayed by television systems, in particular for use in non-destructive defectoscopy, medicine, biochemistry, biology, holography and the like.

The use of CCTV systems is associated with the problem of determining the dimensions and / or coordinates of the displayed objects, eg defectoscopy defects, location of medical radiography location, etc., or variables related to length or area, eg number of defects per unit length of weld. defectoscopy, blood cell count in biochemistry, etc. So far, two ways of solving this problem are known. The first method is characterized by the use of different rasters, scales, etc. on transparent masks applied to the screen. Considerable simplicity is redeemed by disadvantages: The possibility of a parallax error is not prevented, the image is on the screen on the back of the thick glass screen, the mask on the front, often it is necessary to convert the measured value to real recalculation.

The second method is based on the use of digital technology and is common in graphical displays. A pair of lines, so-called cursors, are created on the screen, the distance of which is adjustable and also indicated. Two such pairs of lines, horizontal and vertical, serve to measure the size of a sheet. This is both convenient and accurate, but requires the addition of a computer system to the television system and complicates the solution. Certain difficulties are related to the scaling of the television image with the scaling in the vertical direction, where the line spacing may correspond to an inconsistent length measure.

The aforementioned drawbacks of both methods of determining distances, areas and related quantities of objects displayed by television systems are overcome by using the circuitry for their determination according to the invention. The essence of the circuit is that the circuit input terminal is connected to the line and frame sync pulse separator inputs and to the mark insertion circuit in the video signal. The output of the line sync pulse separator is coupled to the input of the first adjustable pulse delay circuit and to the count input of the second preset counter. The output of the first adjustable pulse delay circuit is coupled to the input of the keyed clock generator and the preset input of the first counter. The output of the keyed clock generator is connected to the counting input of the first counter 8 by a preselection and further to the second input of the highlighting of the horizontal horizontal lines. The output of the first preset counter is coupled to the first input of the highlight vertical lines, the output of which is connected to the input of the first former.

The output of the first former is connected to the first input of the first logic product circuit. The output of the frame sync pulse separator is coupled to the second input of the highlight vertical lines, and to the second pulse delay circuit, the output of which is connected to the preset input of the second counter. The output of the second preset counter is connected to the input of the second former, the output of which is connected to the input terminal of the highlighting horizontal line, the output of the latter being connected to the second input of the first logic sum circuit. The output of the first logic sum circuit is coupled to the keying input of the tag inserting circuit, the output of which is coupled to the wiring output terminal.

The essence of the highlight vertical lines is that its first input is coupled to the input of the first frequency divider and the input of the first logic product circuit. The output of the first frequency divider is connected β by the first input of the negated logic product. The second significant vertical line enhancement circuit input is coupled to a frequency divider input connected to a second negated logic circuit input, the last circuit output being coupled to a second first logical product circuit output of a significant vertical enhancement circuit output. .

The essence of the highlighting of the horizontal horizontal lines is that its input terminal is connected to the input of the second frequency divider and to the second input of the second logic product circuit. The output of the second frequency divider is coupled to the second input of the second logic sum circuit, the first input of which is connected to the second input of the highlight horizontal circuit, and whose input is connected to the first input of the second logic product circuit. The output of the second circuit of the logical product is the output of the circuit to emphasize the significant horizontal lines.

By using the circuitry according to the invention, it is possible in a simple manner to accurately determine the dimensions and distances of the objects displayed by the television system. At the same time, the influence of parallax is completely eliminated and the need to use parts of computer systems is eliminated. Easy adjustability of the displayed rectangular grid module is advantageous in cooperation with systems with variable magnification during displaying. The haster created in the above-mentioned way allows to determine the dimensions and position of the depicted objects, as well as the surface density of particles and to estimate the areas of the depicted objects, which can significantly increase the possibilities of quantitative evaluation of defectoscopic, microscopic and other images. The exemplary embodiment of the invention will be elucidated further with reference to Fig. 1, which represents the basic circuitry of the invention, and Figs. 2 and 3, which show examples of the internal arrangement of the two functional blocks of Fig. 1.

In Fig. 1, the wiring input terminal 21 is coupled to the inputs of the splitter 1 and the line sync pulses, the vertical frame pulses separator 2, and the signal input 131 of the tag insertion circuit 13 to the video signal. The output of the separator 2 is connected to the input of the first adjustable delay circuit 6 and to the counting input 91 of the second preset counter 2. The output of the adjustable delay circuit 2 is connected to the input of the keyed clock generator J and to the setting input 42 of the first preset counter 2, whose counting input 41 is connected to the keyed generator J output and connected to the input

112 of the circuit 11 to emphasize significant horizontal lines. The output of the first counter 4 is coupled to the first input 51 of the prominent vertical bars 2, the second input 52 of which is connected to the output of the separator 2 and to the input of the second pulse delay adjustable circuit 8. The circuit output 53 is coupled to the input of the first former 6, the output of which is connected to the input 121 of the first logic sum circuit 12. The output of the adjustable pulse delay circuit 8 is connected to the setting input 92 of the second preset counter 2, the output of which is connected to the input of the second former 10, the output of which is connected to the input 111 of the highlighting horizontal line 11. The output of the circuit 11 is coupled to the input 122 of the logic sum circuit 12, the output of which is connected to the keying input 132 of the marker insertion circuit 1.3 in the video signal. The output of the circuit 13 is connected to the output terminal 22 of the wiring.

The operation of the circuit according to the invention, Fig. 1, is as follows:

From the complete video signal supplied to the input terminal 2.1 the wiring is separated by means of separators 2 and 2, respectively. 2 separates the line or frame synchronization pulses, which are delayed by means of the circuits 2, 8 with an independently adjustable delay, thereby achieving a displacement of the generated grid in the horizontal and in the horizontal direction respectively. vertical direction. The vertical bars of the grid are formed in that the delayed line synchronization pulse resets the first counter 6 by means of the setting input 42 and also triggers the keyed clock frequency generator J with a defined phase at startup. The generator pulses 6 are counted by an adjustable module counter 6 to determine the spacing of adjacent vertical grid lines. The output pulses of the counter 4 pass through the highlighting circuit 2 of prominent vertical lines, where selected raster lines are highlighted, eg every fifth or tenth.

The pulses passed through the circuit 2 are shaped to the length needed to sharply display the vertical lines of the raster through the first former 6, from where they are routed to the first logic sum circuit 12, where they merge with the pulses to form horizontal lines. inserting tags into the video signal. In circuit 13, the video signal level is clamped to a predetermined value (e.g., white or black) for the duration of the tag. The horizontal bars of the grid are formed by resetting the delayed frame sync pulse via input 92 to counter 2, which counts the line sync pulses applied to input 21. Upon reaching the number of pulses corresponding to the module set identically to counter 6, counter 2 generates 10 for the duration of the active portion of the TV line. The signal of the horizontal lines so derived passes through the highlighting circuit 11 of significant horizontal lines, e.g. every fifth or tenth. From the output of circuit 11, pulses proceed to merge to the input 122 of circuit 12.

The operation of the highlight vertical line 2, the more detailed structure of which is shown in FIG. 2, is as follows:

The frame sync pulses applied to the input terminal 52 are adjusted by the frequency divider 15 such that at the input 162 of the negated logic 16 circuit there is a logic zero level for each odd (or even) field, which also ensures the logical one at input 172 of the first circuit 17 logical product. The pulses applied to the first input 51 are divided by the first frequency divider 14 such that the output of the frequency divider 14 is at a logical zero level for one basic pulse period to the first input 51 of the selected cycle of 5 or 10 or other, how many lines of raster are to be highlighted. Logic zero at first input 161 of circuit 16 causes logical one at second input 172 of circuit 12. Therefore, the pulses forming vertical grid lines from the first input 51 pass only in odd or even fields or at every fifth, tenth or other line regardless of type field to highlight the vertical lines of the grid.

the operation of the prominent horizontal line circuit 11, the more detailed structure of which is shown in FIG. 3, is as follows:

From the pulses of the duration of the active part of the television line fed to the input terminal 111, every fifth or tenth or other is selected by means of a second frequency divider 18 whose output is logical one for one basic pulse period at the input terminal 111 from the selected cycle. length of 5 or 10 or other. Since pulses from the keyed clock generator J are input to the input 191 of the second logical sum circuit 19, at the first input 201 of the second logical product circuit 20 the pulses from the generator 6 are in addition to the cycles corresponding to the 5th or 10th or other horizontal line segment when there is a logical one at the first entry 201. Therefore, by the circuit 20, at the output 113, in the case of the line segment being highlighted, the level of the logical one, while the lines not being highlighted, interrupt the rhythm of the pulses of the generator 6. Non-highlighted line segments are displayed in dotted, highlighted fully.

For some applications, the highlighting lines 8 and 11 may be omitted or the adjustable pulse delay circuits 2 and 8 may be omitted unless an adjustable grid feed is required. The preselection of the first and second counters 6 and 6 can be readily associated with the device by which the magnification is changed, for example in microscopes. Some CCTV systems already include separators 1 and 6 and possibly a tag 13 for embedding the video signal, which reduces the complexity of wiring. If a color television system is used, the markers creating the raster may be colored. The circuitry according to the invention can further be used to assess the geometry of the imaging television system. An important advantage over using the screen in front of the screen is the elimination of the error due to the non-linearity of image degradation in the television monitor. Using monitors according to the invention, monitors or televisions with inferior degradation parameters and thus less expensive can be used for quantitative evaluation of the image.

Claims (1)

Wiring for determining distances, areas and quantities related to objects displayed by television systems, characterized in that the wiring input terminal (21) is connected to the signal input (131) of the video insertion circuit (13) and to the separator inputs (1) a line sync pulse and a frame sync separator (7), the output of the line sync pulse separator (1) being connected to the input of the first adjustable pulse delay circuit (2) and to the count input (91) of the second preset counter (9); the adjustable pulse delay circuit (2) is coupled to the input of the keyed clock generator (3) and to the set-up input (42) of the first preset counter (4) whose counting input (41) is connected to the output of the keyed clock generator (3) the second input (112) of the circuit (11) being emphasized The output of the first preset counter (4) is connected to the first input (51) of the highlight vertical circuit (5), the output (53) of which is connected to the input of the first former (6), the output of which is connected to a first input (121) of the first logic sum circuit (12), wherein the output of the frame sync pulse separator (7) is coupled to a second input (52) of the significant vertical line enhancement circuit (5) and further to the second adjustable delay circuit (8) the output of which is connected to the adjusting input (92) of the second preset counter (9), the output of which is connected to the input of the second former (10), while the output of the second former (10) is connected to the input terminal (111) of the circuit (11) ) emphasizing significant horizontal lines, the output of which (113) is connected to the di-inlet (122) of the first logical-sum circuit (12), the output of which up is connected to the keying input (132) of the video insertion circuit (13), the output of which is connected to the output terminal (22) of the wiring, wherein the first input (51) of the highlight vertical line (5) is connected to the first divider (14) the frequency and with the first input (171) of the first logic product (17), while the output of the first frequency divider (14) is connected to the first input (161) of the negated logic circuit (16) while the second input (52) of 5) emphasizing significant vertical bars is coupled to an input of a frequency divider (15) whose output is coupled to a second input (162) of the negated logic product (16), the output of which is connected to a second input (172) of the first logic circuit (17) a product whose output is connected to the output (53) of the highlight vertical circuit (5), while the input terminal (111) of the highlight horizontal circuit (11) is connected to the second input (202) of the second logical product (20) and the input of the second frequency divider (18), the output of which is connected to the second input (192) of the second logical product (19), the first input (191) is coupled to the second input (112) of the highlighting horizontal line (11) while the output of the second logic sum circuit (19) is coupled to the first input (201) of the second logic product circuit (20) whose output is coupled to the output ( 113) a circumference (11) emphasizing significant horizontal lines.