DE2723740C2 - Device for generating a. Clock signal - Google Patents

Description

A _d = b · n- [d + (k- \) z] for Λ, - b · n + z and

Ad = bn-d for Ar = b ■ n-z,

where d is the center-to-center distance between a perforation hole (32) and the closest time code marking (33) in the direction of movement of the information carrier (30) and Ar is the number of time code markings (33) per digit code (34)

is

5. Device according to one of claims 1 to 4, characterized in that all of the reflective light barriers (1 to 4) electrically via a logic OR link (16) are coupled to one another on the output side.

The invention relates to a device of the type specified in more detail in the preamble of Address 1. Such a device is from "Rundfunk-Technisehe Mitteilungen", No. 5. 1976, pages 188 to 194 known

For easier processing of tape-shaped information carriers, such as picture films, magnetic filaments and audio tapes, time information encoded during recording is recorded. This so-called time code consists of a separate code in the case of magnetic films or audio tapes Control or time code track and in the case of film from individual optical markings on the Transport perforations on the opposite edge zone (»Rundfunk-Technische Mitteilungen«, Issue 5, 1976, December 20, 76, pages 183 to 187, in particular Picture 4 and 5). The recorded time code can be used when processing the information carrier, in particular when the production of sections is scanned, decoded and read out on an optical display device which makes it possible to find certain images or sound passages, especially those that belong together Film images and sound passages, is possible in a simple manner (»Rundfunk-Technische Mitteilungen«, booklet 5.1976, pages 203 to 210).

The scanning of the time code is done inductively in magnetic films and tapes, for example with the help of a Hall head, whereas with a picture film the scanning is done by optoelectronic In the latter case, the fact must be taken into account that only the binary one is marked by an exposed field, while in the case of binary zero the film is unexposed

bo remains This means that the clock for the decoding rank of the sampled time code cannot be derived from the data signal itself. To obtain the Data signal clock one therefore makes use of the fact that the exposed time code markings are fixed in

b5 assignment to the transport perforation of the image film stand. A toothed drum engaging in the transport perforations of the picture film is used to generate the timing provided with circumferential slots, the division of which the

The distance between two adjacent time code marks corresponds to The slots interrupt when rotating the toothed drum periodically the beam path of a transmission light barrier, from which pulse-shaped changes of the luminous flux of the passage light barrier. The summation of these luminous flux impulses results in the sought-after clock signal, with the aid of which the signal scanned by a further through light barrier Time code can be decoded ("Rundfunk-Technische Mitteilungen", Issue 5, 1976, pages 188 bis 194). The use of a slotted toothed drum for generating data, however, requires a high amount Manufacturing and constructional effort that prohibits simpler applications of time code reading

In contrast, the object of the invention is to provide a device of the type mentioned at the beginning which provide a simpler way of obtaining a clock signal for decoding an image on film od. dgL allows recorded and scanned time codes

The object is achieved according to the invention by the features specified in the characterizing part of claim 1 solved

Advantageous refinements and developments of the device according to claim 1 are in the Claims 2 to 6 characterized

The device according to the invention allows a contact-free generation of a clock signal for Decoding of a time code scanned from a tape-shaped information carrier using the transport perforations of the information carrier, with a slotted toothed drum in place of a Arrangement of several reflective light barriers arranged one behind the other in the direction of movement of the information carrier occurs

In addition to the advantage of contact-free scanning, the device according to the invention has the further advantage The advantage of a structurally very simple training, which overall leads to a considerable reduction in price

An embodiment of the invention is explained in more detail with reference to the drawings

F i g. 1 is a schematic perspective view of a picture film section and one above the perforation holes The arrangement of several photoelectric retro-reflective sensors attached to the film, soft one Form the main component of the device according to the invention,

F i g. 2 shows a plan view of a device according to the invention as well as parts of one of the device according to the invention Establishment of non-contact scanned, time-decoded film, and

F i g. 3 shows an electrical block diagram of the device according to the invention, which is connected to a further, not Scanning device belonging to the invention for a recorded on magnetic films or magnetic tapes Time code is combined

For a better understanding of the teaching according to the invention, the formation of the time-coded image film 30 illustrated in FIG. 2 will first be explained ω. The image film 30 represents a preferred example of a tape-shaped information carrier suitable for the purposes according to the invention, without, however, the application of the invention being restricted to screens. As shown in FIG. 2 , the image film 30 comprises, drawn in a distorted scale, a multiplicity of film images 31 which are arranged one behind the other with a mutual spacing and leaving two edge strips free. A sequence of perforation holes 32 is punched into the lower edge strip of the image film 30, to be precise in each case below the center of the space between adjacent film images 31. This means that there is a perforation hole 32 for each film frame 31. Optical time code markings 33 are recorded on the upper edge strip of the film frame 30, namely a group 34 of four marks 33 each for each film frame length Film image approximately symmetrical to its vertical axis. In the example case shown, only time code markings 33 of blackened, rectangular fields corresponding to nothing but binary ones are illustrated four time code marks

33 per group 34 or film frame length results from the given dimensions of 16 mm or 32 mm Image areas as well as from the limited resolution accuracy of optical markings. Although from these Establish the number of four time code marks 33 per group 34 by the European Broadcasting Union, Abbreviated »EBU«, which represents recommended opium, if necessary, fewer or more than four can be used Time code markings 33 per film frame length or group

34 and can be decoded using the present invention.

The basic idea of the present invention is now one of the number of time code marks 33 per group 34 or per film frame length corresponding number of photoelectric retro-reflective sensors 1 up to 4 along an axis running in the direction of movement of the image film 30 (arrow 34), and so that the beam path of each photoelectric reflex switch 1 to 4 when passing through a perforation hole 32 is interrupted. In the example shown, there are four time code markings 33 per film frame length are provided, four reflection light barriers 1 to 4 are accordingly in a common Housing 6 arranged one behind the other in the manner described. The housing 6 is located in a such a distance above or below the image film 30 that the housing 6 facing image film surface the light beams emitted by the retro-reflective light barriers 1 to 4 exactly in the respective Receiver of the retro-reflective photoelectric sensors 1 to 4 reflected (Fig. 1). For example, one serves as the light source of each reflection light barrier 1 to 4 Light-emitting diode 8, while a phototransistor 9 or a photo transistor 1 to 4 is used as a receiver Photodiode (not shown) is provided. The light-emitting diode 8 and the phototransistor 9 of each reflective light barrier 1 to 4 are installed inclined with respect to the vertical in the housing 6, in such a way that that the optical axes 35 of the components 8 and 9 of each reflective light barrier under a point Angle α (FIG. 1) on the surface of the image film 30 cut. The points of intersection of the optical axes 35 lie on an imaginary line, which are the center points the perforation holes 32 connects to one another. In this way, the beam path of each reflection light barrier 1 to 4 is interrupted as soon as a Perforation hole 32 vertically below the relevant

is moved past the photoelectric retro-reflective sensor. As a result of the lacing of the retro-reflective photoelectric barriers 1 to 4 at a mutual center-to-center spacing A _r (Fig. 2) to be explained in more detail, the perforation holes 32 generate successive interruptions in the beam paths of the retro-reflective photoelectric barriers 1 to 4, each of these interruptions leading to an output pulse from the relevant reflective photoelectric barrier The time interval between two successive interruptions or two successive output pulses corresponds to the time interval in which two adjacent time code markings 33 of each group 34 are scanned by means of a through light barrier 5 (FIG. 2). The electrical pulse sequence obtained from the successive interruption of the beam paths of the reflective light barriers 1 to 4 therefore represents the clock signal sought in order to decode the scanned time code present as the electrical output signal of the transit light barrier. This decoding is based on FIG. 3 illustrates in more detail

In Fig. 3 are first of all the reflection light barriers 1 to 4 for scanning the perforation holes 32 as well the through light barrier 5 for scanning the time code markings 33 in the form of circuit blocks schematically illustrates the housing 6 for the retro-reflective light barriers 1 to 4 and the Housing 7 for the passage light barrier 5 indicated with a dashed line is the overall arrangement the circuit blocks for the light barriers 1 to 5 form a non-contact scanning device, which is illustrated as a dot-dash block and is provided with the reference numeral 10 The electrical The structure of each light barrier 1 to 5 is illustrated in the circuit block of the reflection light barrier 1 As can be seen from this, a light-emitting diode 8 emits one illustrated by three arrows Light beam that is received by a phototransistor 9 and converted into an electrical signal. This electrical signal has a continuous course as long as the beam path between the diode 8 and the transistor 9 is not interrupted. When interrupted by a perforation hole 32 changes the electrical signal at the output of the transistor 9 and only returns after the interruption in return to the previous state. This corresponds to every interruption of the beam path between the Diode 8 and transistor 9 with a pulse of the electrical signal at the output of transistor 9, which, if necessary, edited with the help of a trigger, not shown, and assigned to the electrical output 11 to 14 of the respective reflective light barrier 1 to 4 is fed. In The beam path of the through light barrier 5 is also interrupted in a similar manner blackened time code markings 33 to electrical output pulses of the light barrier 5, the whose electrical output 15 are supplied. In contrast to the periodic occurrence of electrical Pulses at the outputs 11 to 14, the electrical pulses at the output 15 are non-periodic, there these pulses of the non-periodic sequence of blackened time code marks 33 or binary Correspond to ones of the time code.

The outputs 11 to 14 lead to an OR gate 16, which adds the sequentially arriving output pulses from the photoelectric retro-reflective sensors 1 to 4 and as Clock signal via a further OR element 17 feeds the clock signal input of a shift register 18 The data signal input of the shift register 18 win from an OR gate 19 is fed one ■> The input is connected to output 15 of the passage light barrier 5 With each pulse de The clock signal at the clock input of the shift register 11 is a binary one or a binary NuI existing bit of the at output 15 of the passage

ίο light barrier 5 pending data signal in there Read in shift register with further shifting of the previously read-in bits. As soon as the slide control When 18 is "filled", its content will consist of a sequence of binary ones and / or zeros its multiple output read out and a spoke! 20 supplied. The content of the memory 20 is stored in a Display device reproduced optically.

The scanning device 10 associated with the present invention can be used with a known inductive

21) scanning device 25 for the odei on magnetic film Time code recorded on tape can be combined to create a suitable one for any information carrier: System to create. The inductive scanning device 2i consists of a magnetic head 22 with a downstream Amplifier 23 and a demodulator 24, desser one, the clock signal leading output over there! OR gate 17 with the clock signal input de! Shift register 18 and its second, the data signal leading output via the OR gate 19 connected to the data signal input of the shift register 18 is

The geometric assignment of the light barriers 1 to 5 results from the representation according to FIG. 2. Wi < this shows the center-to-center distance between

j 5 adjacent Retroreflective 1 to 4 with A and the center distance between the through-light barrier 5 and the closest reflection light barrier, in the illustrated example case, the reflection light barrier 4, Ad denotes Furthermore dei center distance between two adjacent perforation holes 32 of the picture film 30 b, the center distance between each perforation hole 32 and the - seen in the direction of movement (arrow 34) of the film 30 - closest time code mark with d and the center distance between adjacent time code markings 33 with ζ This results in the center distance between each perforation hole 32 zi der - opposite to Direction of movement of the picture film! 30 - nearest timecode marker 33

b- (d + Zz).

A simple consideration shows that the following relationships exist between the distance variables A _r and Ad of the light barriers 1 to 'and the distance variables b, d and ζ of the image film 31:

A, = ζ
or

«> A _r = b + ζ

or

A _r = b - ζ
or

A _r = 2b + ζ

or

A. = 2b - ζ

7 8

in general: A, = h ■ n ± ζ where η = 0.1.2 A _d = bnd fa \ h A _r = b ■ η - ζ

A, = hd-iz = b-id + 3z) if Λ, = bn + ζ where η = 0,1,2,. . .

Zt = 1,2,3

^or _r (number of Zcil-

A ₁ , = 3r - ((/> - <y - 3z) - b - d if A _r = hnz ' code markings

per group 34).
or

Ai = 2b -k / + 3z) if A _r = h-n + z ^ ^^ ^ ^^ _{severalj given to} each other

_oc j _er ίο the phase-shifted clock signals are required,

_A _ j /, _ y if / 1 = /> · H ~ - z. B. for detection of the direction of movement of the

^d ~ ' ^r * information carrier, two can according to the invention with

general: institutions trained in retro-reflective photoelectric sensors

A = b ■ - id J- (/ <- 1) ■ -Ί if A = bn + z are provided in a suitable manner, without the

'' ^L '' r to depart from the scope of the present invention.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1. Device for generating a clock signal required for scanning a time code, the signal period of which is in a certain ratio to the speed of movement of a tape-shaped information carrier provided with time code markings and perforation holes, the time code markings each representing a digit code being applied in a uniform grid between two adjacent perforation holes, characterized in that at the level of the perforation holes (32) of the information carrier (3Q) a number of reflective light barriers (1 to 4) corresponding to the number of time code markings per digit code are mounted one behind the other in the direction of movement of the information carrier (30) so that the plane of the beam path each Reflection light barrier (1 to 4) is oriented perpendicular to the direction of movement (arrow 34) of the information carrier (30) and the beam paths of the reflection light barriers from the perforation holes (32) in their Movement are briefly and successively interrupted, these interruptions being associated with pulse-shaped changes in the luminous flux of the reflective light barriers (1 to 4), the summation of which results in the clock signal, and that the mutual distance (A _r ) between two adjacent reflective light barriers (1 to 4) accordingly is measured in the following equation. Ar = b ■ η ± 2, where η is an integer from 0.1.2 ... ζ the mutual center-to-center distance between two adjacent time code markings (33) within a digit code (34 ·) between two adjacent perforation holes (32), and b is the mutual center-to-center distance between two adjacent perforation holes (32) 2. Device according to spoke 1, characterized in that each reflection addiction barrier (1 to 4) comprises a light-emitting diode (8) and a phototransistor (9) or photodiode, the optical axes (35) of which are at an acute angle (<x) cut a surface of the information carrier (30). 3. Device according to one of claims 1 or 2, characterized in that for optical scanning the time code markings (33) a through light barrier (5) is provided, which so is attached that the perpendicular to the information carrier (30) oriented beam path of the light barrier (5) of the time code markings (33) when they are moved briefly and successively keyed, what with pulse-shaped Changes in the luminous flux of the passage light barrier (5) is connected 4. Device according to claim 3, characterized in that the distance (A4) of the through light barrier (5) to the group of reflective light barriers (1 to 4) is dimensioned according to the following equation: