DE916178C - Synchronization method for the transmission of an image that has been scanned interlaced with lines being added - Google Patents

Description

Issued on the basis of the First Transitional Act of July 8, 1949

CWiGBl. P. 175)

FEDERAL REPUBLIC OF GERMANY

ISSUED AUGUST 5, 1954

GERMAN PATENT OFFICE

PATENT LETTERING

CLASS 21a ¹ GROUP 35io

Electric & Musical Industries Ltd., Hayes, Middlesex (Great Britain) *)

Synchronization method for the transmission of an image scanned interlaced with η lines

Patented in the territory of the Federal Republic of Germany on August 31, 1935

Patent application published May 15, 1952

Patent announced by gemaclit on June 24, 1954

The priority of filings in Great Britain dated August 31, October 18, 1934 and March 7, 1935

is used

The term of protection of the patent is extended according to Law No. 8 of the Allied High Commission Beginning of the 3rd patent year on August 31, 1937, beginning of the 6th patent year on September 28, 1950

It has already been proposed that, for the synchronization of television receivers without interlaced transmission, the picture change pulse should be composed of several individual pulses of the same length and longer than that of a line pulse, in such a way that the line deflection generator passes through the front of each of these individual pulses even during the occurrence of the picture change pulses is synchronized in the same way as in the pause between the image change pulses. A picture change pulse constructed in this way is shown in Fig. Ι of the drawing. The individual impulses, which together represent the image change impulse, are hatched, and the fronts L of these individual impulses have the same distance from one another as the front

*; The patent seekers indicated that the inventors were:

Michael Bowman-Manilold, Woking, Surrey (UK), Edward Cecil Cork and

Cecil Oswald Brown, London

fronten L of two consecutive line pulses. The distance of the front F of the first single pulse from the front of the preceding line pulse is also the same as the distance between the front of two successive line pulses.

If one tries to use such a design of the image change pulse for an interlaced transmission with η lines per image, in which the successive line impulses have a different phase position compared to the line impulses that occur in regular succession, one encounters a difficulty which is illustrated in Fig. 2 and 3 should be explained. In Fig. "2 Zeilenzugimpuls for the first Zeilenzug and in Fig. 3 for the second Zeilenzug is shown for interlaced scanning with two lines of trains per image. The fronts L have the next as well as the preceding front L respectively to the interval of one line period, and accordingly the line deflection generator with a line train pulse form according to Figs. 2 and 3 can also be synchronized during the occurrence of the line train pulses as well as in the pause between the line train pulses. However, the front F of the line train pulse in Fig. 3 is only half a line period from the front L of the previous line pulse removed, and the duration t _± or t _z , which elapses from the front F until the response of the Zeilenzugablenkgenerators, must therefore be of different sizes works in such a way that a condensation Sator is charged with a current proportional to the line pull pulse amplitude until a certain fixed voltage value is reached at which the line pull deflection generator responds. Since the first in Fig. 3 existing single pulse only ⁴ / io line periods comprises rather ⁹ Ao line periods, as the other individual pulses in Fig. 2 and 3, is found for the response delay of the line train steering generator for the Zeilenzugimpuls according to Fig. 3 +5 the value £ ₂ , which is 1.8 line periods, while with the pulse according to Fig. 2 the deflection generator responds after 1.7 line periods. This phenomenon, which is a direct consequence of the different form of the line train pulses shown in Figs. 2 and 3, means that the lines are not reproduced in the received image at exactly the same intervals, but rather that the lines are, as one would say, in pairs stand.

To avoid this disadvantage, in an interlaced process with η lines per image, in which line and line train pulses are given over the same transmission path and successive line train pulses have a different phase position compared to the line pulses that occur in regular succession even during the duration of the line train pulses, the line train pulses single pulses of equal length and spacing are built up, each of which has a shorter duration than an i / n of the line period but is longer than a line pulse; the fronts of these individual pulses are used to synchronize the line deflection generator even during the occurrence of the line train pulses.

In the event that it is an interlacing process with two lines per picture, the design of the line train pulses according to the invention is shown in Fig. 4 and 5 of the drawing. This embodiment shows that the response delays t ₁ and i ₂ become the same for both line pull pulses, namely the value of 1.7 line periods is obtained, since each line pull pulse is now made up of individual pulses of the same length of 0.4 line periods. The fronts L of these individual pulses can now synchronize the line deflection generator for the entire duration of the line pulse, as is done by the fronts L of the line pull pulses.

An embodiment of the invention, which generates the special form of the individual pulses shown in Fig. 4 and 5, works essentially in such a way that line pulses α and pulses c (Fig. 6) of the line train frequency are added to one another and from this pulse mixture a further pulse series b, the pulses of which are to be called auxiliary pulses in the following, is subtracted. The auxiliary pulses have twice the line frequency and approximately the line pulse duration and, like the pulses in series c, are shown in their required phase position relative to the line pulses α . The resulting mixture d is subjected to two-sided limitation of the voltage values χ and ζ , so that all voltage values above χ and below y are limited and thus behind the limiter stage the pulse curve e is created, which is used to synchronize the line and line deflection according to the invention shall be.

In Fig. 7 a circuit is shown which works in the manner explained in Fig. 6. A light source 66 is located behind a screen 64, which illuminates a gap made in the screen. An image of the gap is obtained by means of a mirror wheel 67 which rotates in the direction of the arrow. moved across a second screen 65; The objective 80 images the gap in the screen 64 sharply onto the plane of the screen 65. In Fig. 8, in which the screen 65 is shown in a top view, the moving slit image is denoted by 78 and its direction of movement is indicated by an arrow. When the image 78 moves in the direction of the arrow, it passes over first a gap behind which a photoelectric cell is 69, then a gap 76 behind which a photoelectric cell is located, and finally a third gap 79 voider photocell 81. The circuitry of the photocells 69, 68 and 81 are made in such a way that the line pulses supplied by cell 68 have the opposite polarity as the auxiliary pulses supplied by cells 69 and 81. To the difference of the

Line new impulses and the auxiliary impulses, which are further amplified in an amplifier V , are added to the terminals J2 with the impulses c of Fig. 6, ie the impulses of the line train frequency. The resulting pulse mixture is fed via a coupling capacitor 70 to the control grid of a screen grid tube 71 via a resistor 74, and the grid bleeder resistor is connected to the cathode of the screen grid tube via a voltage source 73

ίο connected. The size and polarity of the bias voltage source 73 is dimensioned in such a way that the voltage value y (Fig. 6, d) is limited at the lower bend of the anode current-grid voltage characteristic curve of the tube 71, and the size of the resistor 74 is such that the resulting pulse mixture d in Fig. 6 does not exceed the voltage value χ , which means that grid current begins to flow at voltage χ. The pulse course e in Fig. 6 can then be picked up at terminals 75.

Another embodiment of the invention for generating the pulse shape according to Figs. 4 and 5 is explained below with reference to Fig. 9. In this embodiment, a mirror wheel can also be used be used, which is used at the same time for scanning a film to be transferred, wherein at a scanning gap z. B. move past 50 frames per second, two of which are the same one after the other and for scanning the even-numbered or the odd-numbered rows to serve. Each mirror generates a line pulse for each line scanned. The course over time this line pulse is shown in Fig. 9 at 34. Depending on these line pulses auxiliary line pulses are generated in any known or suitable manner, shown at 35 in FIG are. These auxiliary line pulses can, for. B. can be made by having a frequency multiplier used. The auxiliary line pulses 35 have twice the frequency as the line pulses themselves and such a duration as the individual pulses within a field pulse and also such a phase position that every second auxiliary line pulse begins at the same time as one Line pulse. The line pulses 34 are fed to the first grid 37 of a screen grid tube 38. This tube 38 is parallel to a hexode 39, both tubes having a common Have anode resistor 40. The auxiliary line pulses are fed to the grid 42 of the hexode, while another type of auxiliary pulses, namely auxiliary image pulses 43, the grid 44 of the Hexode are forwarded.

The auxiliary image pulses can, for. B. generated with the help of a rotating aperture located in front of the film because the aperture z. B. has two opaque arms which hold the filmstrip in the Pause between two consecutive scans, and cover two cams, which light on an image photocell while the film is obscured.

In Fig. 9, the grid 44 of the hexode is negatively biased relative to its cathode, as follows strong that an anode current can only occur when an auxiliary image pulse reaches the grid 44. The auxiliary image pulses are therefore used to unlock the tube 39, so that the auxiliary line pulses one Can cause anode current. The current in the common anode resistor 40 has hence the shape shown at 45, i. H. it consists of line pulses and the auxiliary line pulses, which are caused during the duration of an auxiliary image pulse. Such a sequence of auxiliary line pulses forms the image synchronization signal, which is represented by a series of individual pulses whose fronts occur with twice the frequency of the line pulses and with these have the same phase position.

The components of the signal drawn in dotted lines at 45 are limited by a limiting device suppressed. However, if you wish, you can also, in order to avoid the suppression, provide devices which generate the line pulses turn off while the tube 39 is in operation. To this end, the tube 38 can be replaced by a hexode be replaced. The start-up of the tube 39 can be added to the auxiliary line pulses in any desired phase take place. This start-up should preferably take place during the pause between two successive ones Pulses take place, and it is also desirable that this start-up happens as quickly as possible.

Examination of Fig. 9 teaches that the error in the position of an image pulse is the size of the period of time 46 can assume which between two consecutive Auxiliary line pulses. The exact point in time at which an image pulse begins is therefore determined by the line impulses, which in turn are determined by the mirror of the mirror wheel be generated. The auxiliary image pulses are generated at a frequency that is independent of the Movement of the mirror wheel is and only serves to indicate the approximate starting point of the image signal to be determined.

If for any reason it is necessary, the phase relationship between the line and image pulses to change so can a suitable delay device between the generator for the line pulses and that for the auxiliary pulses are applied.

It should also be expressly noted that other types of production within the meaning of the invention of the pulses shown in Figures 4 and 5 can be used. An image pulse according to the invention can also include the duration of any number of lines; The invention is also not limited to the interlace method using two series of lines, but can also be used with more than two series of lines.

Claims (5)

PATENT CLAIMS: i. Synchronization method for the transmission of an interlaced image scanned with η lines, with line and line pulses over the same transmission path and successive line train pulses have a different phase position compared to the line pulses occurring in regular succession even during the duration of the line train pulses, characterized in that the line train pulses consist of individual pulses of the same length and occurring at the same time intervals, each of which has a shorter duration than l / n the line period, ίο but is longer than a line pulse, and that the Fronts of these individual impulses are used, the line deflection generator as well synchronize during the occurrence of the line train pulses. 2. Device for generating the synchronization pulses for the method according to claim 1 for two lines per image, characterized in that line impulses (α) with impulses (c) of line frequency and duration longer than ao of a line period are additively mixed and from this mixture auxiliary pulses (b) of twice the line frequency and approximately line pulse duration are subtracted and that the resulting pulse mixture (<f) is subject to such a limitation that, in addition to the line pulses, only the same high pulses of double line frequency and one Duration that is less than half a line period pass through the limiter stage. 3. Device according to claim 2, characterized in that the image (78) in a screen (64) and illuminated by a light source (66) gap is moved by means of a mirror wheel (67) over a second screen (65), in in which there are three slits (γγ, γ6, jg) offset from one another in the direction of travel of the image (78), during their exposure in the photocells (69, 68, 81) arranged behind them, on the one hand, the auxiliary pulses and, on the other hand, the line pulses, in each case immediately subsequently triggered by an auxiliary pulse and in the opposite polarity. 4. Device according to claim 2, characterized in that the line pulses (34) the Control grid (37) of a first tube (38) and that the auxiliary pulses (35) and the line pull auxiliary pulses (43) fed to the control grids (42 and 44) of a further tube of a hexode (39) and that the resulting pulse mixture at the common anode resistor (40) of the two tubes (38, 39) is removed. 5. Device according to claim 4, characterized in that the first tube (38), to which the line pulses are fed, is blocked for the duration of the line train auxiliary pulse. Referred publications:
German Patent Nos. 707990, 716028; French Patent Nos. 742 671,773,485; U.S. Patent No. 2,192,121;
Swiss patent specification No. 181 929. 1 sheet of drawings © 9534 7.54