DE2900208A1 - Compact video tape recorder - uses multitrack recording technique to record a whole picture line simultaneously - Google Patents

Abstract

An optical system (26) projects an image (27) on to a matrix (21) of light sensitive elements. A sequential scanner (20) connects a number of elements of the matrix at a time to a linear array (19) of recording heads. The recording tape (15) is moved past the recording heads by a drive (16, 17, 18). The recording medium may be optial, magnetic or electronic and the scanner and recording heads may employ fiber-optic or solid state techniques. For black and white television there would nominally be 833 recording heads corresponding to the picture elements in one line. More recording heads would be used to record the accompanying sound. For colour television, the optical system would resolve the picture into the three component colours and there would be three sets of matrices scanners and recording heads.

Description

The invention relates to a device according to the preamble

of claim 1.

It is known from the cine film technology that filming is aimed at broad sections of the population only after the introduction of the Super 8 cassette system became of interest because the cassette technology enables uncomplicated handling of the camera. Disadvantageous with the Super 8 film system, however, it is still only one film cassette has a small storage capacity of a few minutes, so that after a short time Time the exposed cassette film can be exchanged for an unexposed one got to. In addition, it is disadvantageous that the exposed films only have to be attached to a special Must be sent to the development agency in order to receive a screenable film. Furthermore, it is not with all film systems - and thus also with the Super 8 system possible to use a film that has been exposed once again for filming because the exposure process is irreversible. Although with the recent introduction of the Instant film from the Polaroid Corporation that has no special development in one Development institute needed a considerable simplification of amateur filming has been achieved, the disadvantages of low storage capacity and irreversible Exposure process received.

To make filming more attractive to amateurs, the use is already there miniaturized television cameras.

These television cameras come with a tape recorder that is around your shoulder can be hung, connected, so that the recorded television signals on this Tape device can be recorded. In contrast to the Super 8 cameras, at which the film cassette can be inserted into the camera is such an amateur video system two-part; i.e. it consists of the actual camera and the tape storage device. Since the television camera alone is heavier than a Super 8 camera and to this one Weight nor the weight of the technically complicated tape recorder has to be added such video systems have only been able to establish themselves in closed rooms so far. you In addition, energy requirements do not allow battery supply.

A first problem with portable video systems is the television camera pickup tubes which on the one hand should be technically uncomplicated and on the other hand inexpensive. As is well known, a distinction is made between the following main types of these pick-up tubes: Iconoscope, Super-Ikonoskop, Orthikon, Super-Orthikon and Vidikon. These types give way in detail strongly differ, but have the following features in common: (a) a light-sensitive Layer on which the optical image that is to be converted is sharply mapped is and which each light value in a corresponding ert of an electric charge converts and thus generates an electrical charge image; (b) an image storage device, which causes the charges within several hundredths of a second accumulate between successive scans; (c) an electron beam, which emanates from an electron source and is guided over the electrical image and (d) a device which generates an electrical current or

an electric voltage is generated at every instant of the electric Charge is proportional to that has been accumulated on the point across which the electron beam is being conducted.

Of all conventional television pick-up tubes, the Vidikon is am the simplest structure, since it uses the inner photo effect, so not with free Secondary electrons works. This vidicon is therefore most often used there where small cameras count. The resolution of an image becomes practical with the Vidikon limited only by the size of the electron scanning beam. So it is e.g.

possible to take an image with more than 200,000 picture elements from a photoelectric A layer of only 1.3 mm² can be obtained. In addition, the Vidikon is highly sensitive to light and a low dark current (see P.K. Weimer, S.V. Forgue, R.R. Goodrich: he Vidicon Photoconductive Camera Tube ", Electronics, 23: 7; RCA Review, 12: 306, 1951).

While most Vidikon tubes use selenium as the photosensitive Working element is part of a further development of the vidicon, the so-called Saticon, a selenium-arsenic-tellurium photoconductor used.

The advantage of the Saticon over the Vidikon is that it ages less quickly, because the addition of arsenic increases the tendency of selenium to do so to crystallize out at room temperature, largely prevented. The addition of Tellurium increases the camera's sensitivity to red. Because of her The Saticon tube has numerous positive properties, especially with small ones Color video cameras used (Robert G. Neuhauser: The Saticon ColcrTelevision Camera Tube, SMPTE Journal, Volume 87, March 1978, pages 147-152). The Saticon is working but still with an electron scanning beam. They are also television tubes for small television cameras it has been proposed to use semiconductor elements such as CCD (= batch Use Coupled Devices) or MOS elements. The image sensor is made of MOS technology e.g. from 484 x 384 sensor points and is also suitable for color images ( ELEKTRONIK magazine, 1978, issue 14, page 11). Practically usable cameras however, these types are not yet available on the market.

As mentioned above, the television recording tube is only one part a recording camera if this camera has the same functions as a Super 8 camera should meet. The other part consists in recording the television signal tape, disk, or other storage. So far, in general open magnetic tapes that have been recorded by a video recorder have been used, wherein the video recorder was manufactured in a long-known technique. The video recorders of the 50s that worked with a fixed head technology were only suitable for studio purposes. They were created in 1956 through a system of the company Ampex, which worked with four rotating recording heads. But also this The Ampex system was reserved for studio technology. Around 1960 succeeded as another important Step the realization of the helical scan method, after which all today on the market and not intended for professional television studios magnetic video recording systems work. When the helical scan method is the video magnetic tape spirally around a cylindrical head drum emotional, whereby the video magnetic heads rotate and the signal in - tracks under a flat Record angles from 4 ... .140. A video head draws the information in each case of a television field, i.e. each video track corresponds to a field.

With the non-professional devices in helical track technology no open tapes, but cassettes used. Here have lately Different systems developed at the time, of which the VCR, VHS and Betamax systems the best known are (cf. Proc. IEE, Vol. 125, No.6, June 1978, page 621, table 2).

The SVR system is a further development of the VCR system (cf.

Television and cinema technology, Volume 32, No.5, 1978, page 170).

For portable television cameras, the video recorders are with However, helical track technology is only suitable to a limited extent because it is an extremely complex Own mechanics. First, the tape of the cassette must be handled by a complicated picker mechanism fetched from the cassette and placed omega or alpha-shaped and diagonally around a drum will. The heads then rotate very quickly in this drum, for example at the same time 1500 rpm. All of this requires extreme precision in production and a lot of adjustment work and, because of the high speed of rotation, considerable wear.

To avoid these disadvantages, the LVR system was proposed, that works with longitudinal track recording. With this system, a band of 8 mm width is used, which offers space for 48 adjacent tracks that lead out and written and scanned here. Every two and a half minutes the tape is that runs at 4 m / sec, decelerated and accelerated again, so that all 48 tracks can be sampled in two hours or more (Elektronik International, 1977, pp 385-387). Although the mechanics are greatly simplified in this process, means the high belt speed is a major disadvantage.

While all the methods mentioned so far saved the video signal in analog format, a digital storage has already been proposed (SMPTE Journal, 87, 1978, pp. 375-378; Proc. Inst.

Electr. Closely. 125, June 1978, No. 6, pp. 606-610; Proc. of the Conf. on Video and Data Recording, Univ. of Birmingham, July 20-22, 1976). These digital Processes have some advantages compared to analog and frequency-modulated systems Benefits on. Difficulties, however, are the extraordinarily high bit rates, into which the television signals must be resolved. Used with twice the subcarrier frequency sampled and each sample is resolved into 8 bits, the result is a bit rate of 70.94 Mbit / sec. If an error bit is also added, it is 79.81 Mbit / sec.

A sufficient image quality is obtained with a bit density of 1 to 1.2 Kbits / mm reached, which corresponds to 76 trace meters per second.

Two possible solutions have been proposed: the use of two heads moving at 38 m / sec or the use of a large number, e.g. 100, static heads, with the tape moving past these heads at 76 cm / sec (Proc. IEE, Vol.

125, No 6, June 1978, p. 607).

To reduce tape usage when digitally recording For television signals, differential pulse code modulation has also been proposed to be used (DE-PS 22 29 049). Here the digital signals are sent to the same Number of magnetic heads placed across the magnetic tape serving as a recording medium are arranged next to each other, i.e. the rotating heads are dispensed with and still worked with the usual belt speed. Is disadvantageous with the differential pulse code module, however, that the errors that occur until the system is reset. Guess at a given error rate the DPCM will therefore be about 500 times worse than the PCM (see Proc.IEE, Vol.125, 1978. page 608, point 6).

However, it is already a video recording device with pulse amplitude modulation has been proposed, in which the digitization is omitted and only after the The pulse samples obtained from the sampling theorem are stored (GB-PS 1,285,745). This Device has an optical image scanner, which is derived from a conventional There is a television camera, as well as several magnetic heads facing a magnetic tape are arranged These magnetic heads are sequentially and with a Respective assigned pulse sample, which was previously stored, applied, see above that the brightnesses of the scanned image points on the magnetic tape - as magnetic Sizes are shown. To reduce the time delay when connecting the magnetic heads: to eliminate, it has already been proposed to use an entire scan line save and act on all heads arranged in parallel at the same time (a.a.0., Page 2, lines 120-122). The disadvantage of this device, however, is that for scanning of the optical image is a conventional one. TV camera is being used, i.e. it will first of all an analog television signal is generated in which the brightness signals of the individual Pixels are included one after the other and then the analog Remote-..

sehsignal chopped up again and broken down into pulse amplitude samples.

All of this requires complicated sample-and-hold circuits, etc.

It is also a television signal recording and reproducing apparatus has been proposed in which a broadband television signal is sampled, in such a way that the sampling pulse train has a repetition frequency accordingly has m times the line frequency and is phase-locked to this and the Signals of the sampled values corresponding to m fixed points of each line in a corresponding scanning circuit per line by buffering at the same time made available and substantially at right angles to the direction of travel of the tape recorded (DE-AS 24 48 579). Another disadvantage of this device is that it is based on a television signal in which the bitmap information is time-division multiplexed are present. So a broadband television signal must first be transmitted over a conventional one Recording camera can be obtained, which then with the help of a sampling pulse sequence in narrowband signals is broken down.

With none of the camera or recording systems mentioned so far it is possible to make a television camera about the size of a Super 8 camera, wherein the recording medium can be integrated into the camera.

Such a system for recording, storing and playing back However, television pictures has already been proposed in DE-OS 27 03 507, where a memory cassette can be inserted into a television camera. The cartridge contains here a memory unit with which approx. 3-10 minutes of television recordings are saved can be. The storage means are digital shift registers made from magnetic bubble memories or CCD memories are provided. After the television signals through an analog-to-digital converter have been stored in the digital storage unit, they are saved via a Digital-to-analog converter placed on a conventional video tape recorder. With the known device, so to speak, by inserting a digital intermediate step circumvented the problem that the conventional recording devices cannot in a video camera can be installed. The disadvantage of the known device is that it can be used with a conventional video camera as well as with a conventional one Video tape recorder is working.

The invention is therefore based on the object of the recording system a television camera so that an image memory can be inserted into the camera can record images for a longer period of time, e.g. an hour or more, whereby the saved images can later be played back on a television set.

This task is achieved according to the characterizing features of the patent claim 1 solved.

The advantage achieved with the invention consists in particular in that located between the camera lens and the storable medium Devices without moving parts and without complicated electron beam tubes get along. All of these parts can be integrated into a single solid block be, so that the video camera according to the invention compared to a conventional Film camera differs in that there is a solid block between lens and film is provided. However, it has the advantage over a conventional camera the increased storage capacity as well as the possibility of using a continuously working film drive.

A major advantage of the device according to the invention over known devices (DE-PS 969 818, DE-AS-1 069 672) for storing video signals is that there is no high frequency video signal and according to the sampling theorem must be scanned. According to this theorem, the sampling frequency must be at least twice be as high as the highest frequency contained in the signal (see Zinke / Brunswig: Textbook of high frequency technology, 1965, page 490). For a 6.5 tsHz television signal this means a sampling frequency of at least 13 MHz. In the present invention it is only necessary, however, the image scanning device with such Scan frequency so that there is no flickering of the picture. This so-called merger frequency is - depending on the brightness of the surroundings and other influencing factors - between 17 and 30 frames per second. If you put the television-appropriate merging frequency of 25 images per second at 520 833 pixels, this results in a sampling frequency of only 520 833. 25 833 = 15 631.2 Hz or approx.15.6 kHz. With the arrangement according to GB-PS 1 285 745 is not sampled with the frequency according to the sampling theorem, but obviously only with half this frequency (page 2, lines 46), yes this means, on the one hand, a decrease in quality and, on the other hand, still one extraordinarily high sampling frequency of 6.5 Hz for a television signal. Also at the arrangement according to DE-AS 24 48 579, the sampling frequency is higher because it m times the local line frequency of 15 kHz.

In addition, the fact that in the known arrangement causes the Sampling frequency is smaller than according to the sampling theorem that a not insignificant Quality loss has to be accepted.

Further advantages of the invention emerge from the following Description, this description by no means the scope of the invention should constrict.

The figures show: FIG. 1 a video camera with sound recording; Fig.2 the Principle of the invention, the multi-channel magnetic heads being arranged in a stationary manner and moving the storable medium; 3 shows a representation of the moment in time the arrangement according to Figure 2, but the Plehrkanal heads are driven and the storable medium stands still; 4 shows the principle of a coupling device between an image scanner and multi-channel heads; 5 shows an electronic coupling device, which the recording magnetic heads with the photosensitive elements of a Image scanner connects; 6 shows an optical coupling device with which it is possible is the image projected on an image scanner without intermediate conversion to record electrical or magnetic signals directly on film; Fig. 7 a second optical coupling device, which performs the same as the optical Coupling device of FIG. 6, which, however, consists of individual mirrors which are easier to manufacture consists; Fig.8 shows the principle of an arrangement with which the recorded image can be displayed on a television picture tube; FIG. 9 corresponds to one of FIG Representation of the principle according to the invention for recording video signals, however, color signals are recorded; Fig.lo shows a variant of a color image scanner; 11 shows the basic representation of the reproduction of a recorded color image a color television screen; Fig. 12 the recording of an acoustic signal on the storable medium; Fig.13a the recording of a signal with high upper limit frequency; Fig.13b the recording of a stereo signal, which over two separate microphones are recorded; Fig. 14 a television set that has a slide-in unit for video cassettes.

In the figure 1, a video camera 1 is shown, which is similar to a Super 8 sound film camera looks like and a lens 2, a camera body 3, a handle 4, a microphone 5 and an eyecup 6. With the help of push buttons 7 and rotary knobs 8, the video camera can be operated. It is possible to use different Data, e.g. the length of the filmed material, with the help of a digital display 9, as it is already known in film technology (see P 28 39 741.3). The various camera functions can be controlled with the help of a micro-computer (see P 28 32 033.4).

Instead of the film cassette used in a film camera, the Video camera 1 equipped with a compact cassette 10 or a mini cassette. Such cassettes are known from tape technology, where they are primarily used in cassette recorders or dictation machines are used.

m to be able to insert the cassette 10 into the video camera 1 is on the side of the camera 1 a flap 11 is provided, which opens like a door and can be closed. When the flap 11 is closed, a one provided on it engages Projection 12 into a corresponding recess in the camera side. Of course the cassette 10 can also be inserted into the camera 1 in any other desired manner as is the case with Super 8 or Single 8 cameras or with cassette recorders It is usual, since it does not matter, the cassette 10 in the direct beam path of the lens 2.

The microphone 5 is in a known manner on a telescopic Rod 14 attached, which is pushed into the handle 4 and out of this again can be. M. with the help of a provided in the handle 4 and not shown The microphone 5 can also be pivoted in the direction of the lens 2 by means of a joint.

The principle of the invention is shown in more detail in FIG. Man detects a magnetic tape 15, which is used as a storable medium serves. This magnetic tape 15 is made with the help of a roller 16 on the other side of the Magnetic tape 15 is assigned a pressure roller 17, moved from right to left. An electric motor 18 serves as a drive for the roller 16.

Immediately in front of the magnetic tape 15 is a multi-channel magnetic head 19, which consists of several individual magnetic heads arranged one above the other, of which only eight are shown here.

With the help of thin film and other known technologies (cf.

DE-OS 28 00 215) it is possible to create multi-channel magnetic heads, which consist of 500 or more individual magnetic heads.

Each magnetic head of the multi-channel magnetic head 19 is via leads 22 connected to a coupling device 20, which connects to an image scanner 21 manufactures. This image scanner 21 has a plurality of sensor points 23, only a few of which are shown in FIG. Such image scanners are already widely known (see Fig. 1 of DE-CS 25 14 230; ELEK-TRONIK, 1978, issue 14, page 11). On the sensor points 23, which via lines 24 with the Coupling device 20 can be connected, the object 25 to be recorded is imaged, namely via an objective 26, which is only shown schematically here. As an object 25, a T is selected in FIG. 2, which is mapped onto the image scanner 21 as element 27 is.

The number of sensor points 23 expediently corresponds to the number of the pixels of a television set if the scenes recorded with camera 1 later to be played back on a television set. It is, however possible to choose any other number of pixels, if this appears necessary.

With the CCIR standard currently valid in Germany, the image of the TV screens broken down into 625 horizontal lines running from left to right and follow a certain pattern vertically from top to bottom. The aspect ratio horizontal to vertical is 4: 3. This results in 625 4/3 = per line 833.3 Picture elements, i.e. a total of a black-and-white screen has around 520 833 pixels on. In the following, these numerical values will be used as a starting point, although of course any other television standard can also be used to illustrate the invention could.

In Figure 2, the magnetic heads are on the lines 22 and the coupling device 20 connected to the lines 24, without it being shown in detail to which of the lines 24 each lead the connections. In principle, all are conceivable Connections possible.

3 shows, however, a particularly advantageous connection in which the magnetic heads of the multi-channel magnetic head 19 simultaneously with each one Sensor point of a line 28 are connected. The coupling device 20 is omitted here, so that the connection established at a point in time is clearly recognizable.

At a next point in time, the magnetic heads of the multi-channel magnetic head 19 can be connected to another line which is not shown. Through the Lines 22 and 24 are therefore type of connections between lines 22 and 24 of the image scanner 23-reproduced as columns on the magnetic tape 15. In contrast In relation to FIG. 2, the magnetic tape 15 is not moved here, while the magnetic heads are stationary are, but it is the Ehrkanal magnetic head 19 by means of a motor 29 and a Spindle 30 moves while the tape is stationary. From this it can be seen that it only to the relative movement between the tape 15 and the multi-channel magnetic head 19 arrives. However, as a rule, the arrangement according to Fig. 3 will only be used when individual pictures are to be taken.

In this case, another solid-state memory can also be used instead of a P! Agnetband can be used, which after the image has been saved, as it were, as electronic Slide can be used. Solid-state storage of this type can, as in the case of the earlier popular plate cameras can be inserted into the camera. Thus it can be seen that the invention applies not only to motion picture photography but also to still picture photography is applicable.

The relative speed between the magnetic tape 15 and the multi-channel magnetic head 19 is calculated for taking pictures through a CCIR television screen should be reproduced, based on the numerical values given above, as follows.

Since the 520 833 pixels of a screen 25 times per second of are reproduced on a television set, results in a pixel frequency of approx. 13 106 pixels / second (in television technology, 833/2 Hz is assumed to be Number of vibrations per line, because two pixels are formed by one vibration will; however, 833 pixels are assumed here). For a line with 1sec. 833 Its 833 pixels thus have a time of = 13.1000000 64 µ seconds. If you choose a magnetic tape 3.81 mm wide and assume that the multi-channel magnetic head 19 has a total of 833 magnetic heads arranged one above the other, so result for a full image on the belt 15 a total of 625 side by side and perpendicular to the relative speed arranged tracks, which on a tape length of 3.81. 3/4 = 2.86 mm accommodated are. A time of 64 106 is available for these 625 lines. 625 = 0.04 seconds mm ~ coincidence. This results in a belt speed of 2s84 sec 7.14 cm / sec, which is in the order of magnitude of the tape speed for tape cassettes (= 4.75 cm / sec). The above calculations are of course included just an estimate of the order of magnitude of the belt speed. The minimum In practice, tape speed depends on the storage capacity of the magnetic tape and determined by the controllable multi-channel head technology. The denser the magnetic tape can be packed with information and the narrower the magnetic heads of the multi-channel magnetic head 19 lie next to each other, the lower the relative speed between the Volume 15 and the multi-channel head 19.

Although it is appropriate, the number of magnetic heads and the tape speed To adapt to the existing television standards, the principle according to the invention is not limited to these standards. As long as you can buy a deteriorated picture quality you can, for example, halve the number of magnetic heads. At a re- gift of the recorded images on a television screen becomes the resolution in this case lower, because one line then only approx.

416 pixels. You can also reduce the number of lines, for example in that only every second television line and thus only one field is recorded. The image scanner 21 here consists of only 312 × 416 picture elements.

It seems to be obvious, the individual picture elements of the image scanner 21 each to be connected to a dedicated magnetic head, so that per pixel a magnetic head is provided.

However, this would entail the disadvantage that the multi-channel magnetic head would have to be extremely complicated.

In addition, it would be necessary to use the magnetic tape as with a conventional one Movie camera to move by a stepping mechanism because all the image information would be saved to the tape at the same time.

The coupling device 20 of FIG. 2 is shown again in FIG shown in more detail. Only three columns 31, 32, 33 are representative of all other columns of the photosensitive elements 23 are shown. The multi-channel magnetic head 19 again consists of several heads, each with a line 34,35,36 a coupler 37,38,39 are connected. With the help of a clock 40 can Coupler 37-39 are indexed so that one magnetic head each with another Line of the sensor 21 is connected. All couplers 37-39 are here at the same time clocked, so that when the switches 41-43 of the coupler 37-39 in the sense of move respective arrows, all lines of the image scanner 21 from bottom to top, namely all pixels of a line are scanned simultaneously. With the clock 40, the drive of the multi-channel head 19 can also be coupled, which is indicated by the dashed line Line 44 is indicated.

As a result, each cycle of the clock generator 40 not only effects an incremental switching the coupler 37-39, but also an advancement of a multi-channel head 19 driving motors, which can be a pulse-controlled DC motor 18,29.

An electronic solution for the coupler 20 is shown in FIG. again only a few elements are shown for the sake of simplicity. In the Columns 31, 32, 33 arranged next to one another in FIG. 4 are one above the other in FIG shown. Each individual sensor element is via an electronic switch 45-53 and an amplifier 54,55,56 connected to a magnetic head 57-59.

The totality of all magnetic heads 57-59 forms an integrated one Multi-channel head. There are only as many amplifiers 54-56 as magnetic heads 57-59. In contrast, the number of switches 45-53 corresponds to the number of sensor elements of the image scanner 21.

These switches are designed as analog switches and exist for example from MOS semiconductor (see. DE-AS 22 31 933). Appropriately, they are put together integrated with the elements of the image scanner 21 on a common chip, see above that only the heads 57-59 are outside the integrated circuit and with their 833 ports are connected. With an advanced integration technique Of course, the heads can also be integrated. In this case there is only one left between the magnetic tape and the camera lens Solid.

The light intensity scanned by a sensor element is converted into a electrical voltage or an electrical current converted and over the switch 45-53 and the amplifiers 54-56 are each fed to a magnetic head 57-59. The analog The voltage or the analog current I57 I59 then cause a corresponding magnetic Flux 57-59 at the magnetic heads which is fed to the magnetic tape 15. The corresponding Switches of a column of the image scanner 21, e.g. switches 47,50,53 or 46,49,52 or 45,48,51 are actuated by a clock 60 at the same time. This will causes a complete line of the image scanner 21 to be scanned at the same time. The clock generator 60 can be designed as a circulating counter, its currently pending Counter reading is assigned to a line and the - after all lines has queried - returns to its original state and counts from the beginning begins.

This counter can also be switched in such a way that it initially counts all even-numbered Lines and then scans all odd lines.

6 shows an alternative optical solution to the principle of the invention shown, the part corresponding to the image scanner 21 of FIG Image scanner 61 is replaced. This image scanner. 61 is an optical component which consists of several scanning lines, of which the scanning lines in FIG. 6 are exemplary 62-68 are shown. With the aid of a clock 69, scan lines 62-68 are scanned successively, in such a way that only that line is light which is currently being controlled. Lines 62-68 are thus about electro-optical elements, which their optical properties when put on change an electrical voltage. Such elements have already been proposed several times and known as liquid crystal elements, Pockels and Kerr and PLZR cells.

A parabolic mirror 70 is provided opposite the image scanner 61, in which several glass fibers 71-76 are embedded.

These glass fibers each have a type of lens at their upper ends which collects the light hitting it and completely into the respective optical fiber enters. The lower ends of the glass fibers 71-76 lie opposite a storable one Medium, which is a film 83, for example. This film 83 is relative to the glass fibers 71-76 movable.

The mode of operation of the arrangement according to FIG. 6 is as follows. Will be on If an image is designed for the image scanner 61 by means of an objective, this image can are scanned line by line by scan lines 62-68, i.e. lines 62-68 are electrically controlled one after the other and therefore always leave that one after the other Pass through a line of light. One side of the image scanner 61 on which the The image to be scanned is shown, can in this case be designed as a matt screen 84 be.

The scanning line 62-68 parallel to the axis of the parabolic stomach Rays running through the mirror 70 are combined in the focal line of the mirror 70, regardless of the center distance of the beams. This means that all scan lines 62-68, provided they release light in the direction of the mirror 70, in the focal line can be mapped. The lenses 77-82 are arranged in this focal line of the mirror, which have such refractive indices that all rays impinging on them in the optical fibers 71-76 are guided. In this way, one line at a time becomes one The image is passed through the optical fibers 71-76 and placed on the film 82. This So film is exposed line by line with individual pixels, whereupon it Stores information in the traditional way.

The image scanner 61 is expediently only parallel to the upper one Half of the parabolic mirror 70 arranged so that the emanating from him Rays are not obstructed by the glass fibers 71-76. It goes without saying that the height of the lines 62-68 correspond approximately to the diameter of the glass fibers 71-76.

In Figure 7, a further device is shown with the electro-optical Way an image can be scanned line by line.

The image scanner 61 is again designed in the same way as in Fig. 6. On a line parallel to this image scanner 61 are several small mirrors 86-93, which are oriented so that they can see the light of those Lines 62-68,85 of the image scanner 61 to which they are respectively assigned, in the direction deflect onto a series of linearly arranged optical fibers. Of these, arranged linearly Glass fibers, only one glass fiber 71 is shown in FIG.

The alignment of the mirrors 86-93 is such that the angle of incidence of a light beam of the light beam 94 equal to the angle of reflection of the relevant Light beam of the light bundle 95 is. For example, is an image to be scanned is projected onto the right side of the image scanner 61 and this image is to be scanned scan lines 62-68, 85 are activated sequentially, i.e., these these Scanning lines transmit light one after the other. For example, at the time when the scan line 62 is transparent, all other scanning lines 63-68,85 are optically blocked. The light of the scanning line 62 now arrives - if necessary via a light channel 96, which prevents stray light from entering adjacent channels - on the mirror 86, from where it reaches the upper end of the linearly arranged glass fibers, from which only the fiber optic 71 is shown.

It is understood that the arrangements of Figures 6 and 7 not only suitable for black and white recording, but also for color recording are. Instead of a black-and-white film 83, only a color film has to be used accordingly fine grain can be used.

8 shows how a recorded according to the invention Black and white video information can be reproduced. One recognizes here again the storable medium, for example the magnetic tape 15, but now is written to and read by the multi-channel magnetic head 19. The term multi-channel magnetic head is intended to use both read and write heads in connection with this description include, magnetoresistive sensors are also included.

When the tape 15 is moving at the same speed as when recording moved, appear e.g. at the output of the multi-channel head 19 at a distance of the television line frequency the point information of one line at a time. This point information becomes by means of a switch 97 controlled by a clock 98, sequentially given via line 99 to the control grid of a picture tube 101. With this Control grid (blehnelt cylinder) 100 allows the electron beam to flow between the electron-emitting cathode of the tube 1C1 and the phosphor screen 102 steer. t1 with each clock that comes from the clock 98 to the switch 97, a clock is also given to a device 103 for horizontal deflection. Of the Clock 98 can be a circular counter, for example until counts to the number 833, which corresponds to the number of points on a line.

Then he starts counting again. Thus, with everyone Clock an analog brightness signal that acts as a corresponding magnetic quantity on the tape 15 is scanned by one of the read heads of the multi-channel magnetic head and given as an electrical signal to the control grid 100. At the same time will the electron beam of the picture tube 101 is continued by one raster point on a line.

If the electron beam has reached the end of a line, then also has the counter 98 reaches its final count and starts counting again from the beginning. At the transition to a new number cycle, the counter 98 is a pulse a device 104 for vertical deflection and thus causes a new line is scanned.

Unless the signals sampled by the Plehrkanal head 19 are direct to be supplied to the television tube 101, a buffer memory 105 may be provided which stores one or more line information completely and simultaneously. This line information can then by means of a clock generator or the like are read out and fed to the control grid 100 of the tube 101. This possibility is indicated by the dashed line 106.

The switch 97 is when using a buffer memory 105 with its Lines 107 not with the multi-channel head 19, but with the buffer memory 105 tied together. One of these lines 107- is then line 106.

If the storable medium 15 is not a magnetic tape, but rather an exposed film, the heads of the multi-channel head exist made up of simple photosensitive elements, those on the other side of the film a corresponding number of light sources is assigned. With a magnetic tape A magnetoresistive resistor can be provided as a read head, several of which form the multi-channel magnetic head.

In Fig.9 a circuit arrangement is shown with the color images can be recorded. This circuit arrangement is particularly useful for Suitable for recording color images on magnetic tape.

The image to be recorded is here via an objective 108 and a Beam splitter mirror 109 thrown onto a green filter 110, which is directly located in front of a green image scanner 111.

This green image scanner 111 is with its photosensitive elements connected to a coupler 112 which make connections to green multiple heads can. These Grtin reehrchannel heads are designated by 212 * 113 and 114 in FIG. Part of the light hitting the beam splitter mirror 109 is incident on a second beam splitter mirror 115 thrown from where this part of the light reaches a red filter 116 on the one hand and a blue filter 117 on the other hand. The blue filter 116 is located immediately in front of a blue image scanner 118, the can be connected to blue multi-channel heads 120, 121, 122 via a coupler 119. That Red filter 117 is arranged directly in front of a red sensor 123, which is connected via a coupler 124 can be connected to blue multi-channel heads 125, 126, 127.

The multi-channel heads are arranged in front of a storable medium 128. Three alternatives for the arrangement of these multi-channel heads are shown. The first alternative shows the green, blue and red heads 212,125,120 one above the other arranged, while in the second alternative green, blue and red heads 113,122,126 are nested. In the third alternative, the blue, green and red heads 114, 121, 127 arranged side by side, which, however, is a kind of step-by-step transport of the magnetic tape 128 conditionally.

The principle of a color recording camera is shown in FIG which no beam splitter mirrors are provided, whereby the light intensity of the Camera can be increased. 129 is a detail from a top view denotes an image scanner, with the blue, green and red sensors 130,131,132 are nested. The different types of sensors are included each with different hatching.

The cross section through this image scanner is denoted by 133.

Two layers can be seen here, namely a filter layer 134 and a photosensitive layer 135. In this way, for example, dot-shaped Red filter with punctiform light-sensitive elements a red sensor. The image scanner is like a color television screen with the red, blue, and green Phosphorus dots by combining a red, blue, green filter with one Light sensor are replaced. Such an image scanner can be manufactured by means of the known vapor deposition techniques.

Instead of the combination of color filter and light sensor it is too possible to use light sensors that only focus on a certain wavelength from the outset or address a specific wavelength range.

Electrical connections 136 lead from the image scanner 133 to one Coupler 137, which connects the sensors of the image scanner 133 in a predeterminable manner via multiple lines 138 can connect to the multi-channel heads 120,125,212.

In Fig.11 is an arrangement for reproducing the on a carrier stored color image information with the help of a color image tube displayed. the The arrangement of FIG. 11 is, so to speak, the colored equivalent to the black-and-white arrangement of Fig. 8.

As is well known, there are a number of different color picture tubes from which only the three-beam shadow mask tube, the three-beam chromatron and the single-beam tube with switching grids should be mentioned (see W. Bruch: color picture tubes - an overview on the most important color television playback processes, reprint from the Telefunken newspaper, Year 38, 1965, issue 1, pages 3-120, pages 83-105) Even though the principle according to the invention is applicable to all types of color television tubes, it is to be described in more detail below with reference to the known three-beam shadow mask tube will.

The multi-channel heads 120,125,212 for red, blue and green, which the Scan storable medium, not shown, are via multiple lines 139 connected to a buffer memory 140 which holds the pulse samples from at least one Can save scanning cycle, separately for red, green and blue. The buffer storage 140 is thus divided into three different memory areas 141,142,143, the can be queried separately via lines 144 and circulation switches 145,146,147. Normally the circulation switches 145, 146, 147 are synchronized by means of a clock 148 switched on, with the scanning information each referring to the assigned red, green or blue grids 149,150,151 of a color picture tube 152 are given. The clock 148 again controls the horizontal and vertical image deflection 153,154 Color picture tube 152. This image deflection acts on all three electron beams 155,156,157 simultaneously. On additional distractions, which color errors etc. should correct and which act individually on each ray will not be discussed in this illustration. It can be seen, however, that these additional distractions in a manner known per se can be added. The three electron beams 155, 156, 157 pass through a shadow mask 15E3 and meet red, green and blue phosphor dots on the screen 159 that make them glow.

In Fig.12 it is shown in which way a sound storage can be made according to the invention. Here is again a storable Medium 15 is provided which is attached to a Diehrkanal head 160 for recording black and white images can be passed. The facilities used to record the black and white images are required are omitted because they are already shown in more detail in FIG are.

The multi-channel head 160 has an additional sound head 161, with the pulse-amplitude-modulated sound signals are recorded.

These pulse-amplitude-modulated signals are generated in such a way that that an acoustic signal 162 received by the microphone 5 and in corresponding electrical signals was converted by a switch 163 with a frequency which is twice the value of the highest occurring in the signal 162 is chopped Frequency corresponds. The chopping frequency is determined by a pulse generator 164 delivered. In this way, from an analog electrical signal 165, which is pending at the output of the microphone 5, a series of pulse samples 166, which over the sound head 161 can be placed on the storable medium. The Impulse Samples 166 can also be given via a sample-and-hold circuit 167, which also may have an amplifier and / or pulse shaper device.

As stated above, 625 lines represent 0.04 seconds available, i.e. the multi-channel head 160 and thus also the audio head 161 moved 625 tracks relative to the magnetic tape within 0.04 seconds. this gives 625 pulse samples per 0.04 seconds or 15625 pulse samples in one second. With this pulse or sampling frequency, a sound signal with an upper Reproduce a frequency of 7.8 kHz exactly. Should a higher audio frequency be stored or reproduced, e.g.

15.6 kHz, this can be done with the aid of an arrangement according to FIG. This arrangement has two tape heads 168, 169 arranged one above the other. That from the microphone 5 received signal is sampled at 31.2 kHz, with the switch 170,171 are clocked at 15.6 kHz each. The pulse generator 172 provides two for this purpose Pulse series from which are equidistantly offset from one another in time. One of these Pulse train is given to switch 170 while the other pulse train is on the switch 171 reaches. Reading out the tone impulses stored in this way happens reciprocally, which is not shown in detail. Then be the pulse amplitude samples that have been read out are fed to a low-pass filter and arrive from there to a loudspeaker, if necessary with the interposition of amplifiers Etc.

If you want to store a stereo signal, you can also use two tape heads 173,174 may be provided, each via a switch 175,176 with pulse samples be applied. These switches 175, 176 are from a pulse generator 177 in the Controlled in sync, which causes the audio-frequency electrical signals of the two Flikrofone 178,179 are simultaneously broken down into pulse amplitude samples.

In the stereo arrangement according to Fig. 13b, despite the two sound heads initially only a signal with an upper frequency of 7.8 kHz. You want it here too To achieve an improvement in the sound quality, only the arrangements of the Figures 13a and 13b to be combined with one another.

In the examples of the storage of video files described so far and audio signals were assumed to be analogue on the storable medium Impulse samples are given, the amplitude of which corresponds to a brightness or sound signal. It was m.a.le '.

to pulse amplitude modulated storage methods. By a known one A modification can, however, also be achieved, a pulse-width-modulated storage to realize. If one assumes, for example, that during the relative movement between tape and more channel head 19 line information in 64 microseconds is written down; so this time can be divided in such a way that when writing it down a small amplitude a constant mean amplitude for a short time, e.g. 6 Microseconds, while when writing a large amplitude same constant mean amplitude for a longer time, e.g. 60 microseconds, is written down.

To implement the pulse width modulation, there is only one Amplitude / time converter 180 required, as shown in FIG. 12 for writing down is represented by sound information. The variable amplitude of the incoming signal is thereby converted into a constant amplitude, the duration of which corresponds to the height of the variable amplitude. When reading out the pulse-width modulated signals terms must then be provided which correspond to the duration of the constant determine can.

In addition, a Arrangement can be selected which has only one recording head 173. In this In this case, this one head 173 can be controlled with two switches, which according to Art 13a work, a separate clock is then provided for each switch, which is designed as a counter and can therefore take over memory functions. While The one who always gives the even impulse samples to the head 173 gives the other clocks always send the even impulse samples to this head 173. This way the two stereo channels are recorded nested.

14 shows how one recorded with the camera 1 Cassette 10 can be played. For this purpose, in a television set 181, which is a Housing 182, a screen 183, a loudspeaker 184 and various control buttons 185 has a cassette device installed. This cassette device can be a drawer 186 in which the cassette 10 is placed.

After the drawer 186 has been loaded with the cassette 10, it is pushed into the television set 181. The motor drive can be used for the cassette 10 can be built into the drawer itself as there are controllable DC motors of very flat design, which are particularly suitable for direct drive of cassettes suitable. Given the small size of such devices, there is no need for their own video recorder will.

It should be understood that the invention described above does not is limited to the exemplary embodiments. For example, instead of the in optical coupling devices shown in FIGS. 6 and 7 also include such couplers used as they are known from other areas of technology (cf. DE-AS 22 56 785; DE-AS 2 128 523).

L e r s e i t e

Claims (47)

DEVICE FOR RECORDING STANDING AND / OR MOVING IMAGES Claims device for recording still and / or moving images, with a) an objective which images the images to be recorded on an image plane; b) a device which is arranged in the image plane and which several said image plane having sub-dividing elements; c) a device having a plurality of writing heads for writing information on a storable medium, the write heads essentially perpendicular to the speed vector of the relative speed are arranged between the storable medium and the write heads and each can deliver a physical quantity type in the direction of the storable medium; d) a storable medium, at least in those places where the physical quantities coming from the print heads hit the medium, can change its physical state, characterized by e) a controllable Coupling device (20,37-39; 61,70; 86-93), which at the same time all write heads (19.57-59; 71-76) with certain elements (23.31-33; 62-68) connects; f) a control device (40; 60; 69), which the coupling device (? 0; 37-39; 61.70; 86-93) so that the print heads (19; 57-59; 71-76) are timed one after the other with different elements dividing the image plane (23, 31-33; 62-68) get connected. 2. Apparatus according to claim 1, characterized in that the of physical given to the write heads in the direction of the storable medium Size type is light. 3. Apparatus according to claim 1, characterized in that the of physical given to the write heads in the direction of the storable medium Type of magnitude is a magnetic field. 4. Apparatus according to claim 1, characterized in that the elements (23), which subdivide the image plane, are arranged according to a grid of points. 5. Apparatus according to claim 1, characterized in that the elements (62-68), which subdivide the image plane, are arranged according to a line grid. 6. Device according to claims 1 and 2, characterized in that that the storable medium is film (83). 7. Device according to claims 1 and 3, characterized in that that the storable medium is a magnetic tape (15). 8. Device according to claims 1 and 2, characterized in that that the ends of glass fibers (71-76) are provided as writing heads. 9. Device according to claims 1 and 3, characterized in that that magnetic heads (71-76) manufactured using integrated technology are provided as write heads are. 10. The device according to claim 1, characterized in that a drive (16,17,18) is provided with which the storable medium (15) at the fixed Writing heads (19) is passed. 11. The device according to claim 1, characterized in that a drive (29) is provided with which the writing heads (19) on the stationary medium (15) be led by. 12. The device according to claim 1, characterized in that as storable Medium electronic storage media, e.g. magnetic ring cores, magnetic bubble memory, Bucket chain storage, etc., are provided. 13. The apparatus according to claim 1, characterized in that the storable Medium is designed as a circular disc. 14. Device, in particular according to claim 1, characterized in that that it is provided in a video camera (1), this video camera (1) a Can accommodate cassette (10) with the storable medium (15). 15. The device according to claim 14, characterized in that the Video camera (1) has a microphone (5) which is attached to a telescopic rod (14) is, wherein this telescopic rod (14) are inserted into the camera handle (4) can. 16. Device, in particular according to the preamble of claim 1, characterized by the combination of the following features: a) galvanic lines (22,24) for the transmission of electrical voltages and / or currents, which connected to the elements dividing the image plane; b) arranged in a grid Elements (23) representing the elements dividing the image plane and their electrical and / or magnetic state depending on the intensity of the light hitting them change; c) fixedly arranged electro-magnetic Write heads (19), which the coming over the galvanic lines (22,24) Convert voltages and / or currents into a magnetic type of magnitude and this magnetic Size type in the direction of give the storable medium; your as a magnetic tape (15) designed storable medium, which by means of a drive (16,17,18) is moved past the stationary magnetic heads (19). 17. Device, in particular according to the preamble of claim 1, characterized by the combination of the following features: a) glass fibers (71-76) as Head for the transmission of optical signals associated with the image plane dividing elements (62-68) are optically connectable; b) optical print heads, which the light coming from the glass fibers (71-76) in the direction of the storable Give medium; c) a storable medium in the form of a film (83), which by means of a drive is moved past the fixedly arranged writing heads. 18. Apparatus according to claim 17, characterized in that as optical write heads the ends of the optical fibers (71-76) are provided. 19. Device, in particular according to the preamble of claim 1, characterized by the combination of the following features: a) one in lines (62-68) broken down image scanner (61), the lines (62-68) with the help of electrical Signals can be made translucent or opaque; b) a parabolic one Mirror (70) in whose focal line the first ends (77-82) of optical fibers (71-76) are arranged; c) a storable medium to which the second ends of the Optical fibers (71-76) are opposite. 20. Device, in particular according to the preamble of claim 1, characterized by the combination of the following features: a) one in lines (62-68) broken down image scanner (61), the lines (62-68) with the help of electrical Signals light be made permeable or opaque can; b) a plurality of flat mirrors (86-93) parallel to the scanner (61) are arranged along a straight line, with these mirrors (86-93) aligned are that they the light rays coming from the image scanner (61) on a focal line to steer; c) optical fibers (71), one end of which is arranged in the focal line are. 21. Device according to claims 1 and 4, characterized in that that the elements (23) arranged in a point grid are photodiodes, phototransistors, Photoresistors or photocells are. 22. The device according to claim 1, characterized in that the coupling device Circulation switches (37-39), each one connected to a line (34-36) Have pointer (41-43) that can establish connections to several lines, which are connected to light-sensitive elements (31-33). 23 Apparatus according to claim 22, characterized in that the circulation switches (37-39) can be controlled by means of a circulation counter (40). 24. The device according to claim 1, characterized in that the coupling device contains electronic switches (45-53) which are controlled by a clock (60) and connecting the magnetic heads (57-58) to photosensitive elements (31-33), between the photosensitive elements (31-33) and the magnetic heads (57-58) Amplification and adaptation devices (54-56) can be connected .. 25. The device according to claim 1, characterized in that the number of the write heads (19; 57-59; 71-76) the number of pixels in a line of a television set is equivalent to. 26. The device according to claim 1, characterized in that the coupling device the write heads (19; 57-59; 71-76) one after the other with the elements of a Line of an image scanner (21,61) connects. 27. The device according to claim 1, characterized in that the device, which has a plurality of elements dividing the image to be recorded, in one the plane conjugate to the image plane is arranged. 28. The device according to claim 1, characterized in that for the Recording of color images three facilities are provided which the The image to be recorded is broken down into elements, the first of which is of these facilities on the color red, the second on the color green and the third on the color blue appeals to. 29. The device according to claim 28, characterized in that between the three devices and the lens (2) of the video camera (1) beam splitter mirror (109,115) are provided. 30. The device according to claim 28, characterized in that the Devices a green filter (110) with a green image scanner (111), a red filter (117) with a red image scanner (123) and a blue filter (116) with a blue image scanner (118), these devices each via coupling devices (112,119,124) connected to green, red and blue multichannel heads. 31. The device according to claim 30, characterized in that the Green, blue and red multi-channel heads (212,125,120) are arranged one above the other. 32. Apparatus according to claim 30, characterized in that the individual heads for green, blue and red (113,122,126) nested inside one another arranged are. 33. Apparatus according to claim 30, characterized in that the Multi-channel heads for green, blue and red (114,127,121) are arranged side by side. 34. Device, in particular according to claim 1, characterized in that that for the recording of colored images an image scanning device (129) is provided which has red-, green- and blue-sensitive elements (130-132), which are nested. 35. Apparatus according to claim 34, characterized in that each color-sensitive element comprising a filter element (134) and a light-sensitive Element (135) consists. 36. Apparatus according to claim 34, characterized in that each color-sensitive element consists of a light-sensitive element that is just inside is sensitive to a certain spectral range. 37. Device, in particular according to Claim 1, characterized in that that further write heads (161; 168,169; 173,174) are provided for the sound recording which are acted upon with pulse-amplitude-modulated tone signals. 38, device according to claim 37, characterized in that for the increase of the upper limit frequency of the sound information to be stored the number the print heads is increased. 39. Apparatus according to claim 37, characterized in that. for the recording of stereo signals at least two print heads (173,174) provided si-nd. 40. Apparatus according to claim 37, characterized in that for recording of stereo signals is only possible with one print head. seen and this sound head is fed by two pulse amplitude sampling channels one channel with a first counter for odd pulse samples and the other Channel is controlled with a second counter for even pulse samples. 41. Apparatus according to claim 1, characterized in that for reproduction a television set (181) is provided for the recorded image and / or sound signals is. 42. Apparatus according to claim 41, characterized in that the Television set (181) has a drawer (186) for receiving a cassette (10). 43. Apparatus according to claim 41, characterized in that the Control grid of a black and white television tube (101) via coupling devices (97) can be connected to multi-channel heads (19), which receive the recorded image signal from read from a storable medium (15). 44. Apparatus according to claim 43, characterized in that the Coupling device (97) is controlled by a clock (98), which also the Horizontal and vertical deflection (103,104) of a television picture tube (101) controls. 45. Apparatus according to claim 41, characterized in that for the reproduction of stored color images is provided on a color television tube (152) is whose control grid (149,150, 151) via coupling devices (145,146,147) in series or can be connected in parallel with red, green and blue multi-channel heads (212,125,120) are or is. 46. Apparatus according to claim 1, characterized in that for the Recording and playback of picture and / or sound signals the pulse amplitude modulation is used. 47. Apparatus according to claim 1, characterized in that for the Recording and playback of image and / or sound signals using pulse width modulation is used.