DE2344323C3 - recipient - Google Patents

Description

The present invention relates to a receiver as characterized in the preamble of claim 1.
In conventional television transmissions, the information essentially consists of moving images, with only one piece of information being transmitted at a time within a bandwidth of 6 MHz. In order to transmit various kinds of information signals, the information signals must be transmitted at divided time intervals so that the receiver must wait until a desired information signal is transmitted. This means that it is impossible at the receiving end to obtain a desired information signal at any point in time.

Teaching programs are currently being broadcast by television stations, but the speed of learning is determined by the fermentation, so that the

so learning speed is the same for all students. There Television broadcasts Single-channel broadcasts from the television station to the individual receivers are, the progression of the program takes place regardless of the fact whether the student is the learning content understood or not.

In conventional television broadcasts for moving pictures, z. B. 30 Transfer images. With certain learning programs, however, sufficient information can be provided in the transmission are transmitted from immovable images, so that especially with learning programs large amounts of Information can be transmitted.

When transmitting still images, it is sufficient to use a still image video signal

to be transmitted once, which is then stored in a memory on the receiving end, so that the stored video signal can be reproduced repeatedly.

When transmitting such video signals in the form Video signals corresponding to conventional television signals can produce 30 different images transmitted within a second. To a big one To transmit amount of information, sound information must also be transmitted so that Different tones have to be transmitted at the same time for the individual immovable images. if the still images and sounds within the same bandwidth as conventional television broadcasts transmitted, a number of tones can be transmitted by adding the number to be transmitted of images is reduced. For example, when a video signal is equivalent to ten still pictures is transmitted per second, the audio signal can be transmitted to the remaining part. Through this a composite signal is formed which repeats within a period of 5 seconds is transmitted. This results in a video signal for fifty different still images and one Audio signal for more than fifty channels, each of which is at least five in length Seconds. As soon as a still picture and a sound are combined into one set of information, there is the possibility of different sets of information content of the fifty channels within the To transmit bandwidth of the television broadcast signal. This in turn creates the possibility that to the different recipients the different wishes of the viewer are taken into account at the same time. This results in an access time at the receiving end for the desired information of five seconds. If a longer access time is permitted, the amount of information to be transmitted can be very large increase.

These different types of video and audio signals are combined in the transmission, whereby a set of informational contents results. At the same time an auxiliary signal is transmitted, with which the control is carried out on the recipient side for the reproduction of this information content is, this depending on a predetermined rule, i. H. depending on an answer of the Students, so that there is an opportunity to carry out programmed teaching programs.

The receiver according to the present invention is particularly suitable for receiving signals with a large amount of information suitable for example a programmed learning program. The transmission system for the transmission of such signals, a still picture transmission signal can be used being. In still picture transmission systems, a video signal is transmitted which is a Corresponds to majority of immovable images. At the same time, an audio signal is pulse-code-modulated Form transmitted with time division multiplexing, which one of a plurality of tones in connection with the corresponds to immovable images. Furthermore, a control signal is transmitted which provides information for Treatment of the video and audio signals on the fio receiving end. Finally there is one more Synchronization signal necessary in order to receive the video signal, the audio signal and the Reproduce control signal. These three signals are in a given order within a given ('5 given time interval.

In a certain still picture transmission system, the video signal for a still picture is transmitted within a time interval of 1 / μsec, which is one frame of a conventional television signal. The audio signal is transmitted during a time interval of V ₁₅ seconds. These two signals are transmitted alternately. During a video signal transmission period within each second, part of the control signal is transmitted in place of the video signal. The control signal a) contains a program material identification signal, which in turn consists of a video identification signal, with which a plurality of stationary images is identified. Furthermore, an audio channel signal is provided which identifies the individual audio signals in each of the multiplexed audio channels. There is also a second control signal with which a combination of a still picture and a sound can be carried out for the production of a set of program material. A first control signal is used to select a desired program material from a number of program materials in accordance with a predetermined rule with which the reproduction can be switched on on the receiving end. The first control signal is inserted once every second in the control signal transmission period of V _{30 seconds.} The second control signal is carried out in vertical exchange periods of the video signal and the control signal.

The program material identification signal is inserted in initial areas of each video signal and each audio signal, thus making the desired ones To derive video and audio signals from the transmitted signal, certain positions have to be extracted into which the control signal has been inserted.

From GB-PS 1147 603 a receiver for TV teaching system is known in which under one repeatedly transmitted number of still images, any desired still image is optionally displayed and the still picture displayed has an identification number identified by a keypad. Around In order to be able to extract a desired still picture to be displayed, the identification number of this desired one must be required The still image can be designated directly by operating the keypad. Then the frame you want can be extracted and displayed with the identified identification number. A message to the recipient according to the GB-PS 1147 603 similar receiver is known from GB-PS 1183 338. This one differs from the former in that the identification numbers for the identification of the still pictures in the form of Transmit combinations of signals at different frequencies instead of pulse codes will.

Finally, GB-PS 12 13 357 describes a System for the transmission of a number of still pictures and audio signals. In this known system, an audio signal with a given length of time is fixedly added to each still image, d. H. every still picture comes with combined a predetermined respective audio signal.

However, it cannot combine any of the still pictures with any of the audio signals and hence the degree of freedom in expressing programmed information is limited and complicated programmed instruction cannot be carried out.

The invention is therefore based on the object of creating a receiver in which the program materials through the various combinations of any still pictures and audio signals are formed and the sequence of the program material reproduction by the transmitted control signals is controlled so that the degree of freedom in printing out programmed information is increased and the operation of the keypad can be simplified.

According to the invention, this is achieved by the features of the characterizing part of claim 1.

Within the scope of the present invention, a learning program can be carried out using one-way transmission the programming being carried out similarly to a two-way transmission is.

The invention will now be explained and described in more detail using an exemplary embodiment, reference being made to the accompanying drawing. It shows

1 shows a schematic view of a signal configuration for the transmission of still images,

2a and 2b are schematic representations of a frame of the transmission signal,

F i g. 3a to 3c are schematic representations of waveforms of a known television signal and FIGS a signal used to transmit still images,

FIGS. 4a to 4c are schematic representations of a transmission program for still images,

5a and 5b are schematic representations to explain the configuration of the control signal within the transmission signal for still images,

6 shows a schematic representation of the manner in which the control signal is transmitted,

7 shows a schematic representation of the positions, at which the start signal and the end signal are sent out,

8a and 8b are schematic representations of the positions in which the second control signal and the Video identification signals are sent out,

9a and 9b are schematic representations of the Positions at which the first control signal is sent,

9c shows a schematic representation of the composition the first control signal,

Fig. 10 is a block diagram showing the basic construction of the receiver according to the invention;

F i g. 11 is a block diagram of an embodiment of the control signal extraction circuit according to the invention;

FIG. 12 is a flow chart showing sequential operations in the process shown in FIG. 11 shown extraction circle,

F i g. 13 is a block diagram of a portion of the FIG. 11th the extraction circle shown,

14a to 14h are graphical representations of FIG Waveforms for explaining the operation of a first control signal extraction circuit,

15 is a detailed block diagram of a program material extraction circuit;

16a to 16c are schematic representations of FIG Waveforms to explain how the device shown in FIG. 15 shown extraction circle,

F i g. 17a is a block diagram of the addressing circuit;

FIGS. 17b to 17k are schematic representations of the waveforms for explaining the in FIG. 17a shown Addressing circle,

18 is a detailed block diagram of an index circle;

19 is a block diagram of another embodiment of the receiver according to the invention,
FIG. 20 is a detailed block diagram of the FIG. 19 receiver shown.

An example of a still picture transmission signal used in connection with the present invention Receiver should be used in ίο the following with reference to Figs. 1 to 9 to be discribed.

Fig. 1 shows an example of a frame configuration of the still picture transmission signal. This signal contains a video signal for the still picture, the frame having a duration of one frame period, for example 1/30 second of the NTSC system used in Japan and the United States. This same signal is sent out repeatedly every 5 seconds within a repetition period of 150 frames. These 150 frames are each summarized in groups of 3 frames, ie '/ ίο second. The first frame in each case is a video signal period, while the second and third frames represent an audio signal period. One video signal frame is used as the control signal period every second. In Fig. 1, the control signal period is denoted by C while the signal transmitted within this period will first be described in the following. Each video signal frame V consists of a still picture. Sb and S] denote first and second audio signal periods in which the audio signal is transmitted as a pulse code modulated multiplex signal. Accordingly, within the period of 5 seconds with 150 frames, 5 frames are provided for the control signal period C, 45 frames for the video signal period and 100 frames for the audio signal period So and Si.

F i g. 2a and 2b show the type of assignment of the various signals with respect to the horizontal scanning periods H within the video frame V or the control frame C. FIG. 2a shows the video frame V which is the same as that of the NTSC system and consists of 525 // periods. F i g. 2b shows the control frame C which differs from the video frame Vdahingehenc that within the video frame an odd field video period from the 22nd horizontal scanning line, ie 22 // to 262.5 // is assigned, while within the control frame C the control signal transmission period is somewhat shorter than the video period therefore lasts from 22 H to 262 H. The; also applies to even fields.

F i g. 3a to 3c show waveforms of signals inserted within this // period, urr to determine the difference between conventional television signals and immobile image signals gen. F i g. 3a shows the waveform of a // period one: conventional television signal, while Fig.3b di < Waveform of the // period of the transmission signal for F i g represents immobile images. 3c shows the waveform of the // period of the control signal for such Transmission signals of still images. An essential distinction between conventionali Television signals and signals for transmission in front of still images is in the waveform de: Synchronizing signal. As well as this in FIGS. 3b and 3 < the synchronizing signal is shown for a transmission signal for still images is a digita les synchronization signal, which consists of pulses 0,1, 0,:

..., consists. Such a digital synchronizing signal cannot be amplitude-separated like this is possible with conventional synchronizing signals according to FIG. 3a. The waveform of the video signal, apart from the synchronizing signal from FIG. 3b, is an analog signal like that of conventional ones Television signals. The control signal according to FIG. 3c, on the other hand, is a digital signal which is made up of combinations of pulses 0 and 1.

FIGS. 4a to 4c show the composition of a transmission program for still images. F i g. Figure 4a shows a number of still pictures which make up a broadcast program. If all video signal periods according to FIG. 1 are used for a single program, then 45 still images are contained within the program. Each of the η immobile pictures has its own video identification number, which consists of a combination of eight-bit pulses. This video identification number is sent out repeatedly in periods of 1 A / to 9 H within one vertical return period. F i g. Figure 4b shows a number of tones used in connection with a program. Jt tones can be inserted in k audio channels. The duration of each channel can be changed appropriately on the transmission side, but the average duration of each channel is 10 seconds. The audio signal of k channels is in the form of a time-division multiplexed quaternary PCM signal, which is contained in the audio signal periods 5b and S] according to FIG. 1 is transmitted.

A still picture broadcasting program consists of still pictures as shown in FIG. 4a and tones according to FIG. 4b. In a still picture broadcast program, the program material is composed of an appropriate combination of still pictures and sounds. On the transmission side, various program materials are achieved through a suitable combination of the η immobile images and the tones stored on the k channels. On the receiving end, a television viewer or a student selects the desired program material in a predetermined order. This is how the progression of the program is carried out. This system is the same as programmed teaching programs.

F i g. 4c shows the composition of the program material. The program material is g by a set of video identification numbers in accordance with F i. 4a and an audio channel number according to FIG. 4b denotes These two numbers relate to the video signal and the audio signal which is related to the program material in question. Accordingly , a set of a video identification number and an audio channel number is assigned to a specific index or element. If, for example, in the embodiment shown in FIG the relevant index is referred to as the second control signal, which forms part of the actual control signal

Figures 5a and 5b show the construction of the control signal. F i g. 5a shows the second control signal and parts of the second control signal which are selected by the viewer. For example, a viewer according to FIG. 5a a program material, which is denoted by the index A ₀ B ₀ . The viewer can then select any one of 7 program materials which are defined by the indices A ₁ Bu AiB ₂ , A ₁ B ₃ , AiB ₄ , A, B _S , A ₁ Bb and A ₁ B ₇ . The structure of such 7 program materials, from which any one can be selected, is referred to as a branch of the program material.

F i g. 5b shows the structure of the first control signal for controlling the branching of the program material according to FIG. 5a. According to FIG. 5b, A ₀ B _{0 is} the index which the programrnaieria! that is reproduced at the time. Ai is an index of a branch A, which is substituted for the index Ao. B \, B ₂ , B _} , ZJ ₄ , B $, B ₆ and B ₁ are indices of the branches B, which can substitute the index Bo.

The viewer selects one of the branches according to FIG. 5a by performing a corresponding operation on the control panel. In this case, the new index of the selected branch consists of branches A and the index of branch B, which is contained in the first control signal according to FIG. 5b. In this way, the aforementioned index AoBo is replaced by a new index A _x B _x . The viewer can then view a new program material which is composed of a still picture with a video identification number χ and a sound with an audio channel number y . This results in a new control signal with the new index A _x B _x instead of AoBo.

F i g. 6 shows signal periods during which the two control signals are transmitted. The first control signal is transmitted within the control frame C during the time periods from 22 H to 262 H and from 285 H to 526 H. The second control signal is transmitted in the video frame V and the control frame C during the time periods 1 H to 9 H.

The control signal consists essentially of the upper two control signals, but in addition a control signal is present to determine the beginning and the end of the various audio signals.

This additional control signal defines the beginning and the end of an audio channel reproduction. For this purpose, the same is expressed by the audio channel number which corresponds to the beginning or the end of the audio channel in question. F i g. 11 shows the position at which the audio start signal and the audio end signal are inserted. 7 shows the signal assignment within a PCM frame period which corresponds to an audio sample period and has a duration of 1.5 H The audio start and end signal, which corresponds to the respective audio channel number, consists of 8 bits and is generated after the digital synchronization signal shortly before the PCM Audio signals inserted If an audio start and end signal in the audio frame according to S ₀ according to FIG. 1 inserted

this signal means the beginning of the reproduction of an audio signal in the associated channel. If, on the other hand, the signal in question is inserted into the second audio frame S ₂ , then this signal means the end of the reproduction of the audio signal in

⁶ S the associated channel.

F i g. 8 shows the association of the second control signal of the video identification signal with the video identification number and the digital synchronization signal

within a period of 1 H. This period of 1 H corresponds to any period from 1 H to 9 H of the video frame V and the control frame C of F i g. 6th

The video identification number of each still picture is expressed by 8 bits as shown in Fig. 4a. S These 8 bits are repeatedly sent out within the vertical feedback period of the video signal from 1 H to 9 H. According to FIG. 8a, 16 bits, which follow the digital synchronizing signal, are allocated for the transmission of the video identification signal or the video identification number. The video identification signal specifies the number of still images transmitted within the video frame. The video identification signal is therefore not inserted into the control frame C. The video identification signal consists of 8 bits. so that the same video identification signal is inserted twice during the 16-bit period. As a result, the video identification signal is repeatedly sent out 18 times during a time period of 1 to 9 H.

The second control signal is inserted after the video identification signal. One row of the second control signal consists of 40 bits, thereby defining a set of program material. During a period of 1 H , 9 rows of the second control signal are inserted. As shown in FIG. 8b, each row of the second control signal consists of 40 bits. Of these 40 bits, 8 bits are provided for a control signal, 16 bits for indexing, 8 bits for the video identification number and 8 bits for the audio channel number. Such rows of the second control signal are provided in the video frame and the control frame of 1 H to 9 H. Accordingly, 81 rows of the second control signal are completely accommodated within one frame.

The 8-bit pulse signal is a signal to ensure at the receiving end whether a pulse signal has been transmitted correctly or not. This signal prevents malfunctions on the receiving end. The control signal is only used if the 4> "> Control signal has been received, so that in this way erroneous; Control signals excluded who which can be formed, for example, by noise.

The first control signal will now be described in more detail below. 9a shows the assignment of the first control signal within the 1 // period. This period of 1 H is any period from 22 H to 262 H and from 285 H to 525 H, within the control frame C of FIG. 6. A number of the first control signal is composed of 120 bits, where 3 such rows are provided within a period of 1 hour. The series of the first control signal consists of a control signal of 8 bits, an index AoBo of 16 bits, a sequence index A \ of 8 bits for branch A and the next seven indices Bt, Bz, Ih, B ₄ , Bs, Bi and Bi , where each of these values consists of 8 bits for the branch /? exist. In each period 1 // three rows of the first control signal are inserted; in 482 // periods of control frame C there are thus 1446 rows for the first control signal, as in FIG. 1, 5 control frames C are provided within an interval of 5 seconds, so that the same first control signals are transmitted 5 times within 5 seconds. ⁶ p

F i g. 9 shows the branch construction in which, with the aid of the first control signal, one of the indices of the program material is determined which is to be reproduced after the program material currently being projected. According to FIG. 5, seven program materials are provided, any of which can be reproduced in the following.

The still picture transmission signal as described above can be transmitted with the aid of a receiver are received, as shown in Fi g. 10 is shown. Fig. 10 shows a block diagram of the general Construction of a receiver according to the invention.

The in the F i g. 1 as well as 3b and 3c shown transmission signals! is sent out with the help of a suitable carrier. The transmitted signal is received with the aid of an antenna 11 which is connected to a high-frequency amplifier 1, which is designed similar to that of a conventional television receiver. This is followed by demodulation within a demodulator 2, as a result of which the original signal is recovered. The demodulated signal includes various kinds of signals as described above. Apart from the video signal, a pulse signal is brought to the correct waveform with the aid of a discriminator 4. This corrected pulse signal is fed to an audio part 5, a synchronization part 8 and a control part 9. The video and audio signals formed as a function of certain control processes on a control desk 10 in the control part 9 are identified by the transmitted signal. With the aid of a control signal of the control signal 9, the video signal of the still picture to be reproduced is extracted within a video part 3 and stored therein. The video signal thus stored is repeatedly reproduced and supplied to a reproducing part 7. In the same way, with the aid of a control signal from the control part 9, the audio signal associated with the relevant audio channel is extracted within an audio part 5 and fed to a loudspeaker 6 from there.

Fig. 11 shows a block diagram of an embodiment of the control part 9 according to the invention. This control part 9 has a first signal extraction circuit 100, a first signal storage circuit 150, a second signal extraction circuit 200, a second signal storage circuit 250, an index setting circuit 300, a program material extraction circuit 400, a sequence control circuit 500 and a control panel 10 . The synchromesh signal is received along a signal path 50 , which in a synchromesh signal part! 8 according to FIG. 10 has been reproduced. The pulse signal of the in FIG. 1 is received along a signal path 48. 10 shown discriminator. These two signal paths 48, 50 result in the input signal paths for the control part 9. A control signal for the program material extraction is passed from the control desk 10 to the sequence control circuit 500 via a further signal path 60. The control part 9 uses the synchronization signal of the synchronization signal part 8 as a reference signal.

The functioning of the circuit described above will now be described in the following:

The control signal extraction circuit 100 is used to extract a series of the first control signal of 120 bits, which in the control frame according to FIG. 9a and 9b has been added. In this case, a Information to indicate which row of the first control signal must be extracted by the index of the index detection circuit 300 set. A first control signal memory 150 is used to store the

Indices A \ to Bi of the first control signal extracted by the extraction circuit 100. According to FIG. 9, each of the indices A \ to Bi consists of 8 bits, so that the control signal memory 150 must have a storage capacity of 64 bits. The second control signal extraction circuit 200 extracts a row of the second control signal from a number of rows of the second control signals, which are each composed of 40 bits as shown in FIG. 8. The series of the respective second control signal is determined by the index which is determined by the index determination circuit 300, similarly to the case of the first control signal extraction circuit 100. A second control signal memory 250 is used to store 16-bit signals which each consist of a video identification signal with 8 bits and an audio channel number signal with 8 bits, as shown in FIG. 8b. The index detection circuit 300 displays the index of the control signals to be extracted depending on operations on the control panel 10. The program material extraction circuit 400 uses a video identification signal and an audio channel signal, these values yielding a program material identification whereby a particular still image and associated sound can be extracted from the transmitted signal. The sequence control circuit 500 is used to sample the first control signal extraction circuit 100, the control signal memory 150, the second control signal extraction circuit 200, the control signal memory 250 and the program material extraction circuit 400, so that these individual circuits are only independent of each other during the transmission periods of the first control signal, the second control signal and the program material identification signal Are operating. The scanning process is carried out by applying certain time pulses to these circuits.

12 shows a flow chart for the above-mentioned control of the control part 9. Steps 1 and 2 of FIG. This represents an input period during which the receiver maintains the picture and sound already displayed while preparation is made for the next index of the program material to follow the program just displayed. Step 3 is a step for selecting the first control signal, the index of which is determined by the index detection circuit 300. The control signal extraction circuit 100 is used to store in the control signal memory 150. The next step 4 is a step for extracting the second control signal from the transmitted signal using the control signal extraction circuit 200, which is then stored in the control signal memory 250. Accordingly, steps 3 and 4 are used to extract the two control signals. Steps 5, 6 and 7 are steps for generating a control signal in the program material extraction circuit 400, whereby a video signal and an audio signal are formed with a video identification number and an audio channel number specified in the Control signal memory 250 are stored. Accordingly, steps 5, 6 and 7 are used to extract the program material.

In the following, the control part 9 of FIG. 11 will now be explained in more detail. 13 shows a detailed block diagram of the FIG. 11 illustrated control part. In this context, the modes of operation of the control signal extraction circuit 100 and of the control signal memory 150 will be described. According to FIG. 13, a control circuit 101 is provided with which the occurrence of erroneous signals is to be prevented. A transfer register 102 is also provided, with which the index Aq of the first control signal is transferred. A second transfer register 103 is also used to transfer the index Sb. Both registers 102, 103 consist of

ίο Shift registers with 8 bits each. Furthermore, a coincidence circuit 149 is provided, with which it is determined whether the content in the form of combinations of lines 0 and 1 within the transfer registers 102, 103 is equal to the content Aq and Bq of locking registers.

"5 stars 301, 302 of the index detection circuit 300. As soon as a match has been established Output pulses generated. Furthermore, shift registers 151 to 158 are provided, in which the first Control signals are stored. These shift registers each have 8 bits. Finally are Addressing circuits 110, 160 are provided, with which 8 time pulses are sent to the transmission registers 102, 103 and the shift registers 151 to 158 of the control signal memory 150 are supplied.

F i g. 14 shows a waveform for the mode of operation of the control signal extraction circuit 100 and the control signal memory 150 according to FIG. 13. FIG 48 is fed. In the same way, FIG. 14b shows input time pulses for the addressing circuits 110, 160 of FIG. 13. As soon as a first control signal! 14a enters the signal path 48 from FIG. 13, the sequence control circuit 500 generates a signal shown in FIG G. 14c to 14h are supplied to the control circuit 101, the transfer registers 102, 103 and the shift registers 151 to 158 of the control signal memory 150. The transfer register 103 receives, for example, time pulses of 8 bits in accordance with FIG. 14e, which means that the index βb is composed of 8 bits which are fed to the flb transfer register 103. In this way, the control signal of FIG. 14a is stored in the control circuit 101 according to FIG. 13, while the index Aq is stored in the Ao transfer register 102. The other elements are stored in the same way up to the index Bi, which is stored in the shift register 158.

Once the above process has been completed, coincidence circuit 149 of FIG. 13 found that the contents of the transfer registers 102, 103, ie the indices Aq and B _{0 are the} same as those within the index detection circuit 300 . If there is such a match, a coincidence pulse is generated by the logic product circuit 148 as an output signal. The control circuit 101 checks whether the signal of the corresponding row is correctly stored. If this is the case, an output signal is output to the logic product circuit 148 . As soon as a coincidence pulse and a control signal are present at the same time, the logic product circuit 148 gives an output signal to an output terminal of the sequence control circuit 500, whereby the output of time pulses to the control signal extraction circuit 100 and the control circuit

signal memory 150 is interrupted. The sequence control circuit 500 interrupts the generation of timing pulses from the output cycle circuit 3t with the aid of the signal supplied to the input terminal 71. The supply of time pulses to the shift registers 151 to 158 is consequently interrupted while the information A \ B \ B2 ... Bj has been stored in each of the shift registers 151 to 158. If a match cannot be achieved, the sequence control circuit 500 continues to generate timing pulses as shown in FIG. 14b until a match has been achieved. Up to this step, a detailed description of step 3 shown in FIG. 12 has been carried out.

In the following, the functioning of the second control signal extraction circuit 200 and the second control latch 250 will be discussed. These control signal elements 200, 250 have the same thing Working principle like the elements already mentioned for the first control signal. The control circle 201 of the Control signal extraction circuit 200 accordingly corresponds to control circuit 101 of the first control signal extraction circuit 100. In the same way, an addressing circuit 200 corresponds to the addressing circuit 110, transfer register 202, and 203 to the transfer registers 102 and 103, a coincidence circle 249 to the coincidence circle 149, a logic product circuit 248, the corresponding logic product circuit 148, and an addressing circuit 260 the addressing circuit 160. Furthermore, shift registers 251, 252 correspond to the shift registers 151, 152. So like As shown in Figure 8, the second control signal comprises a video identification signal and a Audio channel signal, each of these signals being composed of 8 bits. It is therefore sufficient to that two such shift registers 251, 252 are present within the control signal memory 250. in the With regard to the functioning of the second control signal extraction circuit 200 and the second control signal memory 250 must have the waveforms shown in FIG. 14a by the second control signal in accordance with Fig.8a to be replaced. That shown in Fig. 14b Signal then becomes the signal at output terminal 32. Up to this point there is a detailed description up to step 4 of FIG. 12 has been carried out.

FIG. 15 shows a detailed block diagram of the program material extraction circuit, while FIG. 16 a shows the signal waveforms to explain how it works. 15 is a transfer register 401 for the video identification signal and a transfer register 402 for the audio channel signal provided which elements are for the shift register. In addition, circles of coincidence 403 and 404 and Logic product circles 405,406 provided.

The operation of the program material extraction circuit 400 is discussed below with reference on FIG. 16 will be explained. As soon as shown in Fig. 16a an input signal is supplied to the transfer register 401 are only during the time periods of the video identification signal timing pulses of 8 bits having the waveform of Fig. 16b from the Sequence control circuit 500 is supplied to transfer register 401 via a signal path 33. The transfer register 401 stores the video identification signal regardless of whether the stored video identification number with that previously stored in the shift register 251 of the control signal memory 250 Video identification number matches a weighing up by the coincidence circle 403. If one If a match is found, a coincidence signal occurs, i. H. a video extraction control signal to de Terminal 64 open.

The other transfer register 402 stores the audio start and stop signals which during the Audio signal period with the aid of time pulses according to FIG. 16b in a similar manner as with the transmission Register 401 are generated, whereupon it is checked whether there is a match with the stored content

ίο of storage register 525 of control signal memory 25 ( is present, which is carried out with the help of the coincidence circle 40 *. When a coincidence occurs; Within the coincidence circuit 404, both logic circuits 405, 406 are supplied with coincidence pulses At the same time the other input terminal 3i of the logic product circuit 405 receives an input signal which indicates the 50 period of the audio signal. The other input terminal 36 of the logic product Circuit 406, on the other hand, is supplied with a signal which emits the Si period of the audio signal. If a < Signal agreement with the coincidence circle 40 <is determined, then it is a start signal in which case a coincidence pulse at the terminal 62 is generated because the start signal in the Ao period is inserted. However, if it is a Stopsigna acts, a coincidence pulse occurs at terminal 6 ^ on. The output signal at output terminal 64 de: coincidence circle 403 within the program material extraction circle 400 is an output of step!

according to Fig. 14. The at the output terminal 62 de! The output signal appearing in the logic product circuit 406 is an output of step 6. The output signal at the output terminal me 63 of the logic product circuit 405 occurring «The output signal is an output of the step!

Figure 17a shows a detailed block diagram of a i Embodiment of the addressing circuit, while FIGS. 17b to 17k show waveforms for explaining the Show how it works. The addressing circuit 90 (according to FIG. 17a can be used for the construction of the addressing circuits 110, 160, 210, 260 of Fig. 13 can also be used a ring counter 911, a frequency by one Factor 8 divided frequency divider 910, as well as logic pro product areas 901 to 908 are provided. The entrance de; Addressing circuit 900 are time pulses 912 according to FIG F i g. 17b supplied. These time impulses are contained of the frequency divider 910 divided by 8 and fed to the logic product circuits 901 to 908. Dei Frequency divider 910 divides the input pulses accordingly Fig. 17b by 8, so that output pulses 92ί can be generated according to FIG. 17g. These pulses are fed to the ring counter 911, which is a pulse 17h generated at the first output terminal of the first stage of the ring counter 911. That to you The output signal generated in the second stage is shown in FIG. In this way, the in Figs. 17h to 17k pulses with a width of 8 bits each from the output terminals of each stage of the Ring counter 911 generated. The logical product signal according to FIG. 17h and the signal formed in FIG. 17b is formed in the logic product circuit 901. The pulses 913 with 8 bits according to FIG. 17c, however, occur at the output terminal. The signals generated in Figs. 17i and 17b ... 17j and 17b then become the logic product circuits 902-908 supplied. The in the F i g. 17d to 17f shown output signals 914 to 920 occur at the outputs of the logic product circuits.

18 is a detailed circuit diagram showing a circuit in which information on the end to be extracted is formed from A ₀ and Bo corresponding to the registers 301, 302 of the index detection circuit 300. There are two ways of supplying the index to the index locking circuit 300. In the first case of the circuit shown in Fig. 13 to be extracted index in the index detecting circuit 300 from the controller 10 via a signal path 90 is supplied In this case, the index AoB ₀ of the control panel 10 directly to the index detecting registers 301,302 supplied In this case, the The content of the index Ao with 8 bits is fed directly from the control panel 10 to the signal path 96, while the content of the index fij with 8 bits is also fed directly from the control panel 10 to the signal path 97. At the same time, the timing pulse input terminals of registers 301, 302 are supplied with timing pulses of 8 bits from control desk 10 via signal path 98, which takes place in synchronization with the transmission of indices Ao and B ₀ via signal paths 96 and 97. As a result, the indices Ao and B ₀ are stored in the corresponding registers 301, 302.

In the second case, the receiver selects a suitable index from those stored within the shift registers 151 to 158, whereupon the content of the selected index is fed to the registers 301, 302. The choice of the index is made by selecting under 7 Signal paths 91 to 97 according to FIG. 18 carried out. If the signal path 81 is selected, time pulses of 8 bits are fed to the signal path 81

The time pulses are fed to the B \ shift register 152 via a signal path 162. With the aid of the time pulses, information stored within the shift register 152 with respect to the index B \ is fed via a signal path 93 to the register 302 corresponding to the index Bo. The 8-bit pulses are also passed via the signal path 81 via a summing circuit 169, while they occur simultaneously on two signal paths 91 and 191. The time pulses of 8 bits on the signal path J 61 are fed to the Ao shift register 151, while the content of the / 4 | index within the shift register 151 is fed to the register 301 corresponding to the index index Ao. The 8-bit time pulses appearing on the signal paths 391 are used as time pulses to write the information relating to the indices A \ and B \ into the corresponding registers 301,302. As has been described above, the 8-bit time pulses occurring on signal path 81 are simultaneously fed to registers 151, 152, 301 and 302 via corresponding signal paths 162, 171, 161 and 302 via corresponding signal paths 162, 171, 161 and 91. As a result, the memory contents stored in the shift registers 151 and 152 are transferred to the shift registers 301, 302, which have the indices Ao and B ₀ , via corresponding signal paths 92 and 93.

As soon as the signal path 82 has been selected by the receiver, the content of the index B ₂ , which is stored in the ^ shift register 153, is transferred to the shift register 302 labeled index βb. If, on the other hand, the signal path 83 is selected, the content of the index B ₁ within the ^ shift register 154 is transferred to the shift register 302 labeled flb. In this way, any one of the signal paths 81 to 87 can be selected. As soon as one of the signal paths 81 to 87 has been selected is, time pulses each pass through the summing circuit 169, whereby the content stored with the index A ₁ in the shift register 151 is fed to the shift register 301 designated A _0. The receiver routes the 8-bit timing pulses to any one of the signal paths 81 to 87, FIG. 18, respectively, by actuating a corresponding button on the control panel 10. By choosing any one of 7 signal paths, the content of any one of the subscripts B \ to Bi is selected

The shift registers 152 to 158 are transferred to the shift register 302 labeled B _0. At the same time, the content of the content stored in the shift register 151 with the value A \ is transferred to the shift register 302 labeled A ₀

The circuits described above are made by the sequence control circuit 500 in accordance with FIG controlled by the steps shown in FIG a still image signal is received to carry out the programmed teaching program.

When a still picture and sound are reproduced, there are 7 kinds of combinations of immovable images and sounds are provided which can be selected by the recipient. As a result, different recipients may have different Choose combinations. If there is a programmed teaching program between a single transmitter and a number of receivers is carried out, which receive the same invariable picture transmission signal, each student can of his own choosing the speed adjust the speed of your own learning.

A modified embodiment of the invention is described below with reference to FIG. 19 to be discribed. This embodiment differs from the already described embodiment Approximation form to the effect that a single common extraction circuit is used instead of two control signal extraction circuits. As a result, common parts of the two memory circuits can be omitted using a single memory which has sufficient storage capacity to save both control signals. This results in a simpler construction.

The functioning of such a receiver is essentially the same as already described. A Control signal extraction circuit 100 '(FIG. 20) extracts the first control signal which has the same index as the register 301 labeled A ₀ and the register 302 labeled B _0. The first control signal thus extracted becomes one in a memory 801 Signal storage circuit 800 stored Thereafter, the control signal extraction circuit 100 'extracts the second control signal, the index of the index detection circuit 300 remaining unchanged. That way extracted second control signal is stored in a memory

SS 802 of the control signal storage circuit 800 is stored. With the help of the video identification signal and the Audio channel signal, the signal extraction circuit 400 generates a control signal for extracting the desired still picture and a sound. The recipient works in the same way as the one already in Relation to F i g. 11, the successive steps shown in FIG. 12 running. The recipient contains a transmitted signal to thereby the teaching program perform.

In the context of the present invention, a single signal is provided with a plurality of invariable images while simultaneously over

the same transmission path audio signals are transmitted. With the help of the receiver according to the invention the student can reproduce any immutable images and sounds in a given order. If a program has previously been compiled on the transmission side by a plurality of unchangeable images and sounds are combined

the student can carry out a learning program on the receiving end by performing certain operating steps on a control panel have to. The student can also choose a programmed teaching program at any time operate as long as the corresponding associated transmitter sends out the corresponding transmit signals

In addition 18 sheets of drawings

Claims (5)

Patent claims: 1. Receiver for the reception of composite signals, consisting of a one A plurality of video signal corresponding to still images, a video identification signal for identification each still image, one representing a plurality of tones, in a plurality of Audio signal inserted into audio channels, one for playback of these signals on the receiver necessary synchronization signal, a control panel with which optionally a still picture and an audio channel is selectable from among the plurality of still pictures and audio channels. Extract circles for Extracting the still video signal and audio signal designated by the control panel when these signals are transmitted, playback devices for the extracted video and audio signals, characterized in that the composite signal further comprises a plurality of Contains control signals, with signals which designate combinations of the still images and tones, as well with signals to control the playback sequence of these combinations in a predetermined order are provided, the receiver extraction circuits (300, 100, 200, 100 ') for extracting one of the Control signals from the composite signal in response to an input from the control panel (10) supplied signal, memory circuits (150,250,801,802) for storing the extracted control signal and extraction circuits (400) for extracting the by the contains stored control signal of the composite signal called still images and tones. 2. Receiver according to claim 1, characterized in that the extraction circuit (400) is a program material identification signal including the second control signal, the latter transmitting one determined by the extraction circuit (300) Has an index and a Signa! generated for the extraction of given video and audio signals, that the extraction circuit (300) defines an index with the aid of a signal from the control panel (10), whereupon on the basis of this index of the extraction circuit (400) a first control signal is extracted which having the index of the composite signal while the extracted first control signal is stored in one of the storage circuits (150, 250, 801, 802), furthermore that the extraction circuit (400) further the second control signal from the composite signal based on the index extracted, whereupon the same is stored in another of the storage circuits that the extraction circuit (400) generates a signal with which the composite signal, the video signal and the Audio signal extracted with the aid of the second control signal stored in the other storage circuit, whereby the desired still image and sound are reproduced, followed by actuating the Control panel (10) a new index is selected from the group of indices, which with the help of the first control signal are stored in one storage circuit, so that in the extracting circuit (300) is replaced, according to which different still images and sounds are consecutive are reproducible. 3. Receiver according to claim 1 or 2, characterized in that a sequence control circuit (500) is additionally provided which generates a signal for actuating the individual circuits in a predetermined order, accordingly extracting a first and a second control signal, and that the two Storage circuits (150,250) and the extraction circuits (300, 100, 200) are made up of shift registers (101-103, 151-158, 201-203, 251, 252, 301, 302), so that these circuits can be selectively supplied with timing pulses from the ι ο sequence control circuit (500) are controllable. 4. Receiver according to one of claims 1 to 3, characterized in that a pair of extraction circles (100, 200) are provided, the first extraction circuit (100) having a first control signal '5 generates, while the second extraction circuit (200) generates the other control signal generated. 5. Receiver according to one of claims 1 to 4, characterized in that in addition a sequence control circuit (500) is provided, which the zo Extraction sequence of the two control signals determined, with the aid of a control signal of the sequence control circuit, the first control signal of the first extraction circuit (100) is extracted, followed by completion of the extraction of the first Control signal the second control signal is extracted from the second extraction circuit (200).