DE1562316C - Device for synchronizing the vertical scanning with the film transport in a television film scanner - Google Patents

Description

1 2

The present invention relates to a device markings can consist of crossbars,

to synchronize the vertical scanning with the one which is located in the space between the

Film transport in a television film scanner, in the case of other individual frames of the film,
which a film, which is a sequence of frames It is also from the British patent

Contains, which each'ein marking part assigned 5 711 268 known and in the German patent

is proposed, grid-like in the horizontal and vertical directions 1 178 893, in a film with Perfo-

is scanned, with a scanning device, the abration of the perforation holes as markings

. Steering signal generator circuits for generating hori- control of the compensation of the film movement to

Contains zontal and vertical deflection signals and a turn. In the known case, the perforation

The video signal corresponding to the image content and an io tion holes either through a wedge-shaped screen

Synchronization corresponding to the marking parts or by means of a sinusoidal oscillation

tion signal supplies. deflected point of light scanned, and the · generated

With film scanners, which is amplitude- or phase-dependent control signal with raster-like scanning the individual frames of the film work, the grid must be used to control a deflection that is not described in detail of the scanning device, which uses a light-like arrangement, which the deflection raster as point scanning tube or an image decomposition tube containing the whole in register with the scanned film image can be synchronized with the film transport. holds. Via the control of the grid deflection itself be that the (or the interlaced method is not found in the British patent the) cover the scanning grid with the individual images. In the case of information, the proposed arrangement will In the usual studio systems, this is achieved either by means of a grid deflection using a central impulse line Mains-synchronous operation or controlled by a synchro generator.

nization of the film drive with a central clock. Finally, from the ■ German patent specification

transmitter of the studio reached (Kino-Technik, No. 2/1959, 667 830 a television synchronization method known,

S. F16). ■ in which the synchronization of the receiver

In the case of film scanners in which the film is transported at the same speed as required line and image alternation, pulses with opposite polarities must be generated in addition to the synchronization of the raster deflection by the fact that the image to be transmitted is also transferred to the scanning device with the film transport Edge has a white edge and on one it must be ensured that on the uniformly perpendicular edge has a black edge, film images moving at a speed relative to the raster is still produced by the film. The Nipkow disc, which was synchronized with the film drive by means of a mechanical Koppser compensating for the film movement,
above the first mentioned synchronization in principle. For example, it can be seen from the problem of compensating for the film movement that the compensation in the case of interlacing still has to be set back with the problem of the receiver synchronization method with half the raster frequency, but with the synchronization of the raster. With the known film scanners distraction with the film transport. The above mentioned are therefore also for the synchronization and the th known studio film scanner, although different devices have been provided for compensation. proven to be excellent, but they are very expensive

In one from the USA. Patent 2,818,466 4 ° dig. For teaching and entertainment purposes in schools, well-known film scanners, hospitals and the like are balanced. On the other hand, there is considerable film movement through an optical system with linear demand for simple and cheap film disks and a rotating shutter, by scanning, with the help of their cinema films Because the successive individual frames of the film can be reproduced, television sets can be reproduced, essentially for a specific time interval. The film transport uses films without perforation. A per contains a drive motor, which, like the Abforationslosen RIm, is not synchronized with the film transport due to the slip which is unavoidable in practice in the steering signal generators for the image splitting tube. Due to imperfections in the network or due to a local pulse generator optical compensation system, short, jump- possible. Even if the space requirement of the film does not play a decisive role in relation to the motion of the film images, and a perforation of the photocathode onto which they are projected occur. A synchronous drive can be used. To compensate for such "jumps", the film scanner, which is known because of the equipment and circuitry required, is undesirable in addition to the actual technical complexity.
Compensation system still a photocell that responds to a marking assigned to each individual image, reasons to work with raster-like film scanning and to specify the simplification, as well as the projected image, in the event of an undesired movement of the marking film scanning device while it is cheap and does not have to meet high demands on the end of the scanning, it appeals and a precision of the film transport is required,
pulse-like correction signal to the vertical deflection · This task is provided according to the invention with a spool of the image splitting tube, which briefly shifts the device for synchronizing the vertical raster so that despite the movement scanning with the film transport in a television the projected image with respect to the Photo 65 film scanner with continuous film transport, with cathode practically no relative movement between which a film, which contains a sequence of individual images, the projected image and the scanning raster, each of which is followed by a marking part assigned. The one that controls this electronic compensation is grid-like in the horizontal and vertical directions

3 4 ,

is scanned with a scanning device that rejects. The film 12 also carries an audio track 26,

Steering signal generator circuits for generating horizons, for example, as shown, one lane more variable

Contains zontal and vertical deflection signals and a density can be, in which case the sound information

the video signal corresponding to the image content as well as a video signal due to the density or transparency of the track

Synchronisa- 5 corresponding to the marking parts is shown. Of course you can too

tion signal, solved in that one of the use a track of variable area, and the er-

Synchronization signal derived control voltage finding is not based on a special training

to readjust the vertical frequency and the audio track limited. The movie 12 also includes

vertical position of the grid with respect to the film images marking parts 28, which are used for synchronization purposes

serves. io serve. The synchro shown in more detail in Fig. 3

In the case of the present device, the filmization marking takes place in each case for a single image 24

Scanning in the vertical direction (direction of the FiI- assigned and can, for example, between two

mes) can be arranged with single or double film frames.

frequency and is not, as before, from the network or Typical values for the width and thickness of the in a central clock, but through the film 15 F i g. 2 shown films are for example about synchronized itself. With normal network conditions 6.3 mm or 25 to 90 μΐη. So the film can leave out · yourself with a simple, cheap, and usually slim and thin, and one will space-saving film drive generates a television signal- therefore generally do not use a toothed roller drive, that of any standard television receiver. The individual images 24 are approximately 3.2 x 4.42 mm ger can be processed properly. 20 tall, and the dimensions of the dashed

Preferably ^ the frequency control has a line enclosed area 24 a be approximately

greater time constant than the position control. 3.12-4.16 mm. The area 24 a represents the one

According to one embodiment of the invention, the part of the image area 24 is actually in the

Control signal for position control the deflection signal - television receivers arranged elsewhere

generator circuits and for frequency control a 25 is displayed visibly. The. Sound track 26 is

Synchronous pulse generator, the vertical synchronous approximately 1.7 mm wide, and the marking part 28 is

provides pulses to the deflection signal generator circuits, approximately 0.09 by 4.4 mm in size. The relatively opaque

fed. - casual markings 28 a and the in-between

When using a film, the marking lying transparent parts 286 (FIG. 3) are approximately

tion parts arranged between the individual images 30 1.34 mm wide.

The synchronization signal is preferably when the filmstrip 12 is fed by the drive of its frequency-selective stage, the on arrangement 16 from the supply reel 14 to the oscillations that frequency responds, which winding bobbin 18 is transported, migrate together Scanning of the marking parts occurs, the individual images 24 through the scanning area shown in because a sequence of alternating in the line direction is designated as a whole by 30. The film contain relatively dark and light areas. is scanned by a moving point of light,

The following is an embodiment of the by a conventional cathode ray tube or

Invention explained in more detail with reference to the drawing. a light point scanner 32 is generated and both

It show for example for a film speed of 10.16 cm

F i g. 1A and 1B a block diagram of a single 40 or 30 frames per second for the film of the above-

direction according to the invention, said dimensions and according to the der-

Fig. 2 is a greatly enlarged fragmentary view of an early US standard showing the screen 34 of the tube

Film on which the interlaced lines by the television receiver at a rate of 60

information to be reproduced is recorded, scanning nested rasters per second, whereby

Fig. 3 is an enlarged representation of a synchro 45 each raster consists of 262.5 scan lines and approximately

identification mark, as it is between 82.6-31.2 mm on top of each other. The. Light from the screen

the following frames of the film according to FIG. 2 34 of the cathode ray tube 32 falls through a rotary

is arranged and rende closure disk 40, which in Fig. 4 in more detail

F i g. 4 is a plan view of a closure disk, which is shown, on two parallel 45 ° -

which is part of a tracking device for the 50 prisms 36, 38 .. which are driven by a motor 42

Device according to F i g. 3 forms. level sealing disc consists of a light-

In the case of the FIGS. 1A and 1B shown impermeable material and has two slits

Embodiment of the invention runs a film 12, the 44, 46 on. When the closure disc 40 by the

by a drive arrangement 16 continuously to motor 42 is set in rotation, give the

is driven, from a supply reel 14 to a 55 slots 44, 46 the prisms 36 and 38 alternately

Take-up reel 18. The drive assembly 16 can be used for the cathode ray beam from the screen 34

consist of a friction drive, so that the film tube outgoing light freely.

does not need to contain a perforation and dement- The prisms 36, 38 each form in connection

can be dimensioned speaking smaller. The surface with a semi-reflective and semi-permeable

Drive assembly 16 is driven by a motor 20 to 60 the beam splitting prism 48 and a lens 50 den

driven by an independent power screen 34 of the cathode ray tube on different

source 22 is fed. which sides one through the center of the lens 50

Fig. 2 shows a piece of film 12 which is moving and perpendicular to the film

Series of individual images 24, which reduce the image information axis on the film 12. If so

represent, thus contains a row of at a distance «5 the 45 ° prism 36 through the locking slot 44

information-bearing that is arranged from one another is released, the screen 34

Areas that generally have the same dimensions as the cathode ray tube migrating light point

and distances in the longitudinal direction of the film on the sub-area 30a of the scanning area (Fig. IA)

5 6

pictured. If, on the other hand, the 45 ° prism 38 stage 68 is fed to an output line 72 which is released through the shutter slot 46, the light point can lead to a sub-area of video playback devices which are not shown and are arranged elsewhere. Except-30 b of the scanning area 30 shown. this signal is sent to a modulator 74

In this manner known per se, a 5 is produced, the output signal of which is fed to an input of a first complete line raster of the movable mixer 75. The other input point of light on the sub-area 30 a and then one of the mixer 75 is fed a sound signal from an FM second complete line raster on the sub-area signal generator 86, and the mixer 75 30 b is written, while a single image 24 at delivers a combined video and audio signal, the transport of the film 12 from the supply reel 14 io via a line 76, not shown, to the take-up reel 18, which is customary and continuously through the television receivers. Each frame 24 of the film zen can be fed.
12 is interlaced twice through the video signal in mixer 75

raster scanned. Since the film 12 continues, the sound signal is generated in the following way: Moved manually, each grid comprises an area 15 As FIG. 1A shows, this contains the sound track 26 in reality half of a single image 24 tends to be the portion of that running through the scanning area 30 is equivalent to. The motion of the film and the Ablen film 12 are illuminated by a light source 78. The The effect of the light point interacts in such a way that the light transmitted by the sound track 26 passes through that the grid covers the entire frame. a mask 80 on a photocell 82. The output

The cathode ray tube 32 can also, as a pre-signal of the photocell 82 is in an amplifier 84 struck, belong to an arrangement that amplifies with and gives a signal that the on the tonciner Film recording works in which the film track 26 reproduces recorded sound information, images possibly anamorphic in the longitudinal direction. The output signal of the amplifier 84 becomes one can be ized and in which each individual image is only fed directly to line 88, which is connected to another location is scanned a single time. The film is provided with sound reproduction (not shown) located there driven so that 60 frames per second is connected units, z. B. usual audio amplifiers Scan area 30 pass through. There is then no kernel and speakers through which the on the film disassembly assembly like the shutter disk 40, track 26 reproduced recorded sound information Drive motor 42 and the prisms 36, 38, 48 will ben. The output of amplifier 84 necessary. 30 is also added to the FM signal generator 86

The intensity of the light point generated by the cathode ray tube 32, which supplies a frequency-modulated signal, can, if desired, be kept constant by a control loop in the mixer 75 for the main video signal, which is added by the modulator 74 to the combination photodiode 52, a reference voltage source 54, to generate the nated signal on line 76,
corresponds to a reference light level, and a comparator. Control loop that controls the peak amplitude of the

The output signal generated by the light multiplier 58 which is transmitted by the film 12 regulates the point at which it falls on a photomultiplier 58, which generates an electrical signal which is relatively appropriate for a maximum light input. That is uniform. This is received in the following way through-62 corresponds to a customary aperture corrector 64 of the light allowed to be drawn, is measured through a guide which can be constructed in a known manner, peak detector 90. The output signal (see, for example, US Pat. No. 3,011,018) and the 45 of the peak detector 90 is a comparison stage 92 signal is corrected with respect to aperture distortion. The output signal of the aperture corrector 64 is fed to a conventional gamma corrector 66, which compares a reference voltage source 94, if likewise in a known manner these two S ignals differ from each other, returns (see e.g. B. USA. Patent 2 697 758) and the 50 comparator 92 an error signal which corrects a signal with regard to the non-linear gradation of the voltage control and supply circuit 96 for the film 12. The photomultiplier is fed from the gamma corrector 66 and a bias signal fed to the video signal of a synchronization mixer 68 multiplier 58 is fed in, which bias signal also flows from a synchronization. In this way, the maximum amplification pulse generator 70 receives a series of blanking and 55 the synchronization signals in the output signal of the photomultiplier, which keep the video at a fairly constant value,
signal. That the video signal pulls - The raster scan of the through the cathode ray

set blanking signal causes only those parts of tube 32 generated light point is with the Bewedes Video signal that causes a deflection of the lighting of the film 12 in the following manner synchronizing point over the area 24a of the film recording 60: In connection with Fig. 2 it was mentioned 12 (Fig. 2) correspond to be reproduced. that the synchronization marks 28 between In addition, the blanking signal naturally causes two successive individual images 24 of the figure also a blanking of those parts of the video mes 12 are arranged. With the values mentioned signals that correspond to the horizontal and vertical return of the film dimensions, film speed and distance Correspond to the light point. The synchronization sampling rate of the light point is used for scanning signal controls the synchronization during the re-synchronization markings about seven deliveries. touch lines required. If the point of light is the. U.N-

The output signal of the synchronizing mixing transparent and transparent parts 28 a and

286 (FIG. 3), the photomultiplier 58 delivers a pulse signal. With the values given above for the dimensions of the parts 28 a, 28 b of the markings and the scanning speed, the frequency of the signal generated by the photomultiplier 58 is approximately 300 kHz. This value is of course completely arbitrary.

An amplifier 98 (FIG. 1B) is coupled to the main video amplifier 62 and

the frequency of the vertical synchronization pulses generated by the generator 70, which ^{initiate the vertical or field deflection 1 of} the scanning light point. The frequency of the field deflection is thereby automatically regulated in such a way that it corresponds to the frequency with which the individual images of the film 12 are passed through the scanning

■ areas 30 a or 306 run, corresponds.

In the deflection signal generator circuits 118, the error signal supplied by the amplifier 116 serves as a correction

The frequency of the signal is matched to the rectuT signal for the vertical deflection in the case of the over- io rectuT signal. The distraction prank of the synchronization marks 28 are circling namely horizontal and vertical den Point of light is created. In the case of the present case, synchronization pulses are supplied which carry the signals the amplifier 98 is tuned to 300 kHz. synchronize the cathode ray tube 32 to The output of the tuned amplifier 98 horizontal and vertical deflection of the point of light is fed to a detector 100 to which a pulse 15 is fed. The vertical deflection error signal to an amplifier 102. The output signal from amplifier 116 controls that from the generator signal of the amplifier 102 is generated in a limiter 118 vertical deflection voltage and shifts 104 limited, the output signal of which a separating the position of the vertical deflection in such a way that transformer 106 is supplied. The transformer matched them with the frames on film 12-106 delivers a signal that is independent of ground as 30 correct.

Key input to a tapping stage 108. The time constants of the deflection circuits 118 and des

The tapping input terminal of tapping stage 108 synchronization pulse generator 70 can thus be used a triangular oscillation, which must be set and dimensioned so that the deflection circles 118 low way is generated. A multivibrator 110 responds more quickly to the error provided by amplifier 116 fed with vertical synchronization pulses, respond 25 learning signal as the synchronization pulse generated by synchronization generator 70 and generator 70. The error signal from amplifier 116 to trigger the vertical deflection of the light point then first causes a change in the time tes in the cathode ray tube 32 can be used. Location of vertical deflection, and only when this The multivibrator 110 provides pulses that are not required for a complete correction of the deflection tegrator112, which is sufficient in Fig. IB 30, the vertical frequency will be shown later Triangular oscillation generated. This changes. .

Vibration increases from a basic value up to one The synchronous generator 70 is a free vibration

Maximum value increases linearly and then falls back to that of the pulse generator, its vertical pulse frequency Base value decreases linearly. The values supplied by the multivibrator 110 correspond to that supplied by the amplifier 116 generated and in the integrator 112 integrated pulses 35 error signal is variable. Except for the distractions chosen so that the triangular oscillation of circles118 the vertical impulses are also one A reference potential in the middle between the square wave generator 120 is supplied. the Base and peak potential begins while the stretching oscillation from generator 120 is in first half of a vertical deflection on the Spit- an amplifier 122 is amplified and the Verzenpotential rises and then again to the decision drive motor 42 as supply voltage applied potential descends and then while the other leads. The closure disk 40, which alternately the

45 ^C prisms 36, 38 covers or releases, is thereby driven synchronously with the vertical pulses of the synchronous generator 70, which also synchronize the field deflection of the light point in the cathode ray tube 32.

Half of the vertical deflection of the light point of the cathode ray tube from the reference potential to the Base potential falls and then rises again to the reference potential.

The triangular wave is fed to an isolating transformer 114, the secondary side of which is independent of mass and coupled to the input of the tapping stage 108 intended for the signal to be tapped is. When the pulse from the transformer 106 samples the tapping stage 108, it provides an output signal, its value is the instantaneous value of the input signal from transformer 114 at the moment corresponds to the keying. The tapping stage provides an output signal that corresponds to the point in time within a vertical deflection of the scanning light point at which the light point passes over the synchronization marks 28 on the film 12, corresponds. Ideally, the point of light should cover the markings at the end of a vertical deflection. delete, and the output signal of the tap 108 should equal the reference potential of the integrator 112 delivered triangular oscillation.

The output signal of the tapping stage 108 serves as an error signal and is transmitted via an amplifier 116 to the Synchronization pulse generator 70 and deflection general circuits 118 supplied. The field signal from amplifier 116 controls the synchronous generator 70

Claims (4)

Patent claims: 1. Device for synchronizing the vertical scanning with the film transport in one Television film scanner with continuous film transport, in which a film, a sequence of individual images, each of which is assigned a marking part, grid-like in horizontal and vertical direction is scanned, with a scanning device, the deflection signal generator circuits for generating horizontal and vertical deflection signals and an 'image content corresponding video signal and a synchronization signal corresponding to the marking parts supplies, characterized in that one "from the synchronization signal Derived control voltage to readjust the vertical frequency and the vertical position of the Grid and the location with respect to the film images is used. 109 634/140 2. Device according to claim 1, characterized in that that the frequency control has a greater time constant than the position control. 3. Device according to claim 1 or 2, characterized in that the control signal for position control is fed to the deflection signal generator circuits (118) and for frequency control to a sync pulse generator (70) which delivers vertical synchronization pulses to the deflection signal generator circuits. 10 4. Device according to claim 1, 2 or 3, for a film, in which the marking parts are arranged between the individual images, characterized in that the synchronization signal is fed to a frequency-selective stage (98) which is responsive to vibrations of that frequency which during scanning of the marking parts (28) occurs, each of which contains a sequence of relatively dark and light areas (28 a, 28 b) alternating in the line direction. 1 sheet of drawings