DE2326319C3 - Still picture broadcast receiver - Google Patents

Description

shows. This can lead to errors in identifying the FIG. 3 and 4 block diagrams for the principle of the

Lead audio signal and distort the video signal. still image broadcast signal receiver according to the invention

The tone and synchronization signals are pulsed,

modulated signals, so that normally to FIG. 5 a block diagram of a synchronizing

Reproduction of these PCM signals for the identification 5 signal generator for the receiver,

decoration in a previous stage a clamping F i g. 6 and 7 vibration diagrams for

circuit required. This clamping circuit serves to clarify the circuit according to FIG. 5,

Coincident setting of a specific signal F i g. 8, 9 and 10 block diagrams for explanation

level with a reference level. In the preceding another embodiment of the synchronizing

The freeze frame signal can be the pause period for this single signal regenerator,

position can be used. That means with other figures. 11 and 12 block diagrams for explanation

Words that in this system the pause in one embodiment of a coincidence circuit

correct level is transmitted, regardless of the according to FIG. 5, 8, 9 and 10,

Content of the signal, so that the pause period is preceded by F i g. 13 is a block diagram of an embodiment

part is useful for the AGC system. 15 a circuit for automatic gain control

As already mentioned, the break has an under-

different subsequent period / h or yes in the video grid

and in the tone grid, so that the clamping or holding of the receiver according to the invention and

of the clamping circuit in each case at different periods. FIG. 15 shows the circuit diagram of an embodiment of FIG

would have to be carried out, which, however, results in a clamping circuit for the block diagram according to FIG. 14th

Ripple with audio frequency can lead, so that a According to F i g. 1 becomes the still picture broadcast signal

perfect clamping or holding is not possible. transmitted with a subsequent period of 5 seconds.

The object of the invention is to create a receiver for 5 sub-still image broadcast signals in this subsequent period of 5 seconds, in which a raster SMF-Q, SMF-I ... SMF-4 very simple synchronizing signal regenerators with a period of one second are used one after the other. It will be turned. The regenerator reproduces the synchronizing SMF that is inserted into the therefore every 5 seconds an identical sub-grid freeze frame broadcast signal. A sub-grid SMF consists of signal. Synchronization signals can be regenerated 30 television frames with a television frame frequency of 30 Hz with different repetition frequency. One of the 30 frames serves as control grid C for video signal transmission period and in the sound 3 ° different control signals. In the still picture over-signal transmission period are transmitted. Through the transmission system, two video and audio signals are used by an automatic gain control circuit to display a specific program. The amplitude deviations of the two freeze frame signals are easily suppressed by one transmitter end in the time broadcast signal. multiplex transmitted separately. On the receiving side, the control signals are used to produce the synchronization signals, which are also used to ensure that the two reproduced signals of a different repetition frequency in the video signal over-program exactly match. Other control transmission periods and in which the audio signal transmission signals in the control grid C are used to select a period to be transmitted. desired program, consisting of two signals

By a clamp circuit, the level becomes one of 40 among a variety of programs. Of the

certain period of the Standbikl broadcast signal 30 rasters are used as video raster V and 9 raster

kept at a reference level in a simple manner. 20 grids as tone grids A. In a series of 30 sub-

This clamping circuit of the receiver works with rasters SMF , the control raster C is at the beginning of the

the synchronizing signals with different series.

Subsequent period in the video and audio signal transmission 45 F i g. FIG. 2 shows a vibration diagram of FIG

transmission period. Video grid V and tone grid A signals used.

According to Fig. 2b, the tone grid A contains an impulse

Gabe goes from the characterizing part of claim 1 modulated sound multiplex signal 1 and a synchronizing

emerged. control signal 2 inserted The query period of the pulse

Another embodiment of the invention draws 5 ° modulated sound multiplex signal 1, with the insertion

by the fact that a third signal is generated.

with a common measuring frequency of the two subsequent sequences, is 1 // a, where f _{A is} approximately equal to 10.5 kHz

frequencies from the first and second signal, for this period is referred to below as the tone grid period

version of the signal level of the blanking period, denoted by In the video grid V are shown in FIG. 2c Fade-out or gating of the blanking period 55 an NTSC video signal 3 and a synchronization signal 4

of the composite signal using. The synchronizing signal 4 is at each

this third signal, and that the gain of the horizontal period \\ fn inserted (fg = 15.734kHz),

The composite signal depends on the detected The following relationship therefore exists:

Signal level is controlled. , R _ 7/3

In a further embodiment of the 60 J ouch β /.

According to the receiver, the level of a load becomes The insertion position of the two signals 2 and 4

Period of the composite signal under Ver or the phase position of these two signals are thus

application of the third signal to a predetermined one at the greatest common measurement frequency of the two

Level fixes frequencies / h and f _A of approx. 5 kHz coincident (cf. For a more detailed explanation of the invention 65 Fig. 2d). The synchronizing signals 2 and 4 are

reference is made to the drawing. They show from a sampling period BL, a PCM raster

F i g. 1 and 2 diagrams for the signal combination signal PFP (hereinafter referred to as the PFP signal

setting in one embodiment, draws) and a mode control signal MCC (in the following

Io

called MCC signal). The and the pulse-modulated audio signal in the standard-PFP signal is a series of pulses with the modulated radio signal and also causes a series of vibrations to be formed by the audio multiplex signal. The identified signal arrives at the sated. The pulse train has a fixed pulse pattern tone regenerator 34 and to the PFP detector 24. This 0101 of 16 bits. By using this fixed 5 PFP detector 24 checks at least the adaptation of the pulse pattern, the bit signal with the repetition frequency PFP signal pattern and the fixed pulse pattern of the quenz / b = 6.5454 MHz to achieve the time-identified signal and detected by the periodicity Control of the pulse-modulated signal (PCM- the PFP signal. After detecting the position of the PFP signal) reproduced. The MCC signal is formed by a signal in the detector 24, this signal becomes an 8-bit signal in which 7 types of synchronizing ίο MCC detector 25. In this MCC detector 25 siersignalen are inserted, a horizontal synchronizing an MCC Signal derived with 8 bits. This MCC-siersignal 5 with the repetition frequency 15.734 kHz, a signal is detected in the MCC detector 25, since the ent-Tonrastersynchronisiersignal 6 with the repetition frequency speaking positions of the 7 types of synchronizing 10.5 kHz, a raster synchronizing signal 7, a syn- siersignalen are known in the MCC signals, so chronisiersignal 8 with the position of the control grid, syn- 15 that the synchronizing signals can be easily derived from chronisiersignale 9 and 10 to display the position of and reproduced. The 7 most synchronized and second tone grids and one synchronizing signal arrive at a horizontal synchronizing signal 11 for displaying the position of the video signal. If sierschaltung 26, a Tonrastersynchronisierschalin the synchronizing signals 5 to 11 the pulse has the device27, a raster synchronizing circuit 28, a value 1, the synchronizing signal is inserted, 20 control raster synchronizing circuit 29, to two tones while at a value of Odes pulse the synchronizing rastersynchronisierschaltungen 30 and 31 or . to set signal is not used. a video raster synchronization circuit 32, whereby

The still picture broadcast signal shown in FIG. 1 and 2 the 7 synchronization signals are reproduced. the is received by a recipient according to FIG. 3 consecutive periods of the 7 synchronization signals took. 25 15.734 kHz, 10.5 kHz, 30 Hz, 1 Hz, 10 Hz, 10 Hz or

In the simplified block diagram of a receiver 10 Hz. In the receiver according to the invention, that for the still picture broadcast signal according to FIG. 3 he still image video signal, which is known by the video detector 33 , an input connection 12, to which the still image was detected, stored in the raster memory 35 and fed to the image signal, a Braun tube 13 as an NTSC signal repeatedly on the Braun image to reproduce the still image, a speaker 14 30 tube 13 given. Through this circuit, a nor for the audio signal and an instruction keyboard 15 for the painter NTSC receiver can be used as a control receiver for designating a specific pair of video and the still image broadcast signal.
Sound signals according to the selection of the reception The identified and shaped in the identifier 23,

part. The freeze frame broadcast signal from the input pulse-modulated signal (PCM) arrives at the audio connection 12, first arrives at the synchronizing signal generator 34, is controlled by control signals from the control generator 16 to detect only the synchronizing apparatus 17 , by the required pulses and for reproduction of the synchronizing detected via digital-to-analog converter as a normal signal, the audio signal required to reproduce the still image is reproduced and transmitted to the loudspeaker 14 . This information is given to the other parts.

of the recipient. By instruction on the 40 F i g. 5 shows a block diagram of the synchronizing keyboard 15 , a control apparatus 17 is matched to the control signal generator belonging to the PFP detector 24, the signal in the still image broadcast signal and the MCC detector 25, the horizontal synchronization detects the timing of the desired pair of tion circuit 26 and the Tonrastersynchronisations video and audio signal and provides a trigger pulse circuit 27 in the receiver according to the invention according to for a video grid memory 18 and a Tonregene- 45 F i g. 4. Fig. 5 shows various signals A, B, C .. .H rator 19. The video raster memory 18 only takes at different points in the circuit. The Schwinlich the desired image on the basis of the triggering form of the signals A to H is shown in FIG. 6 shown. The embodiment shown regenerates the two by supplying the stored signal for types of periods of the input signal according to Braun's tube 13, a still image as a continuous 50 Fig. 2, the input signal being obtained in a time-division multiplexed signal. The tone regenerator 19 takes on system with two periods 1 // h, Hf α is transmitted, the basis of the trigger pulse a desired tone - where / bI / a = 3/2 and Fa = 15.734 kHz, under Versignal and reproduces the stin " ne by turning the greatest common measurement frequency from the delivery of the signal to a loudspeaker 14. Approx. 5 kHz.

F i g. 4 shows further details of the still picture receiver 41, a coincidence circuit 42, a baseger. One recognizes an input terminal 12 for the oscillator 43, divider or step circuits 44, 45, still picture broadcast signal and a bit synchronizing a setting circuit 46 for the gate threshold level sation detector 21, the timing oscillation as an example of a coincidence test circuit, and a and the PFP signal the tone grid and AND gate 47. The gate circuit 41 serves ^ m Ausauf a bit synchronizing signal regenerator 22 gives. 60 glare of the input signal at the largest common

The Bitynchronisiersignalregenerator 22 has a common measuring frequency of the two frequencies Iff α and Basisoszillatoi with a frequency equal to the bit sequence- V fa-

frequency and provides a reproduced bit synchronism. The operation of the synchronizing signal generator

siersignal with the same phase position and frequency according to F i g. 5, referring to the input timing vibration 65 fed to Schwinder, is shown in FIG. 6 explained. Of simplicity for the identifier 23. The identifier 23 is used for the sake of FIG. 6 the synchronizing signal sections the reproduced synchronizing signal as the timing of the PFP and MCC through a combined line stabilization oscillation and identifies the PCM signal depressed.

10

In the input signal in Fig. 6A, two peak rectification of the coincidence synchronizing signal having the periods shown in Fig. 6 are effected. 6A 'pulse C and generates a signal as shown in FIG. 6H. and 6A "transmitted in time division multiplex. The The gate circuit 41 is opened when the Si-synchronizing signal of Figure 6A 'has. the subsequent gnal H is greater than the threshold value ν in Fig. 6H. frequency Yes and to F i g 6A "the repetition rate. 5 If the signal H is less than the threshold value, sequence /". The input signal A arrives in the two rows of synchronizing signals, bypassing the gate signals, indicating coincident synchronizing signals directly to the coincidence circuit 42.
in both rows. The repetition frequency of the synchronous F i g. 7 shows the course of the curve when the phases ^: control signals with the * is the greatest common measurement adaptation in the divider circuits 44 and 45 from the frequency of the two repetition frequencies. The entry io for some reason did not take place. For the case 1 in signal A , a gate circuit 41 happens and F i g arrives. 7 and the screen frequency /// is assumed to a coincidence circuit 42 (B in Fig. 5). In that the phase of the input pulse A is changed. Coincidence circuit 42 upon coincidence of the input operates the gate circuit 41. In this case, ergangssignals A with the period of the above, it demonstrates no outlet B, so that a Koinzidenzim- 15 coincidence circuit 42 produces no coincidence output pulse C at the output of the largest common frequency. This coincidence circuit 42 delivers pulse C occurs. The output voltage H of the threshold is only an output pulse when the phase value setting circuit gradually decreases and compares an input pulse pattern with a previously reached pulse pattern finally coincident at a time II. worth v. If it is less than the threshold level v,

F i g. 11 shows a practical embodiment of FIG. 20, the gate circuit 41 is triggered and the on

Coincidence circuit 42. An input signal A passes output signal A directly to the coincidence circuit 42

to a shift register 70. The pulse pattern of the given. Therefore, the following syn-

The input signal is 80 bits in a comparator for chronizing signals of the largest common measuring frequency.

Bit compared with a predetermined pattern, frequency detected and a coincidence pulse C generated

provided by a fixed pattern generator 90. The coincidence pulse C goes to the divider

will. The comparator 80 comprises each bit comparator lines 44, 45 and instantaneously sets the phase position

80a, 8Oi ... 80 /, 8OA: and supplies output pulses for the output pulses G and H coincident with the

the AND gate 67 which produces an output when sync pulses 2 and 4 are on. At the same time will

all bit comparators are fed to the threshold value setting circuit 46 at the same time

lead output signal. To generate the coincident 3 ° pulse in its output voltage H greater than that

Pulse series at a period of the greatest common threshold value v, so that the gate circuit 41 again

The same measuring frequency can be switched on to be compared. At this point the frequency is

pulse pattern from parts of PFP and MCC signals of the gate pulse G completely coincident with the

are formed. The proportion of the MCC signals means the greatest common measurement frequency of the input syn-

a code indicating that the period of the PFP 35 timing signal. After the point in time III, at

Signal is equal to / a , and also a code to display, coincident phase position only the above-mentioned,

that the period of PFP is fn . If a correct sync signals 2 and 4 faded out.

Period of the FFP signal corresponds to Ja and fn , then the gate circuit thus determines the coincidence

if this period coincides with the period of the largest pulse C is recorded synchronously,

common measurement frequency. 40 Even if an identical pulse pattern PFP and

The coincidence pulse C obtained in this way arrives as part of MCC is generated at random and acts as a coincidence reset pulse on the divider circuits 44 and 45. The counter pulse acts and the synchronization circuits 43 fundamental oscillation D herpulse pattern delivered by the above working method by the faulty sub-switched. Signals E and F are obtained with the 45 low periodicity being neglected, so that the frequencies / a or fn- The phase position is syncnron gate opens. The real synchronism with the coincidence pulse C is then set. In this siersignale 2 and 4 through the real, largest common case, the coincident pulse series C has the largest measurement frequency determined and the raster synchronization common measurement frequency between the frequencies / a brought about. At IV the input signal is through and fs, so that the phase adjustment is not disturbed by all noise or the like, and PFP is erenlichen synchronization signals and is longer if disturbed by at least 1 bit. In this case it is used as 1 // a and 1 // ». However, this does not constitute a special no coincidence pulse is generated. The output span problem arises when the frequency ratio is small, the voltage H to the threshold value setting does not go under and an output signal with the phase position that refuses and detects synchronizing signals 2 and synchronized input signal of adapted phase is aimed at the next largest common measurement frequency and maintains the correct way of working

The output synchronization signals E and F, syn- In F i g. 8 is a block diagram showing another chronized with the input signal A, an embodiment of the invention. Here, there is an AND gate 47. This AND gate 47 generates a raster synchronization by taking along an output pulse G with the largest common 60, the smallest common multiplex frequency. Measuring frequency / λ and / b and with the same phase The circuit according to F i g. 8 ¹ differs partially from the position of the input signal. The output pulse G those according to F i g. 5 from. According to FIG. 8 the frequency is reached to the gate circuit 41 and fades out the frequency of the gate pulse G as the smallest common input signal. In this way a single multiplex frequency of ja and / b is obtained . The gear synchronization signal with good S / N condition and 65 common lowest multiplex frequency provides a basis for a stable synchronization circuit. oscillator 43 via a divider circuit 51. The reverse

The setting circuit 46 for the threshold value is used to set the pulse of the divider circuit 51 comes via a

for confirmation of coincidence. The setting circuit 46 coincidence circuit 52. The connection of the coincidence

Denz circuit 52 differs somewhat from that of the already explained coincidence circuit 42 according to FIG. 5 from. The coincidence circuit 52; supplies the coincidence pulse C to the gate threshold value setting circuit 46 and the divider circuits 44 and 45, as in FIG. 5, but in addition to the coincidence pulse C , the 16-bit PFP signal part is identified. A coincidence pulse J (the curve profile is not shown) is generated and given as a reset pulse to a divider circuit 51 for phase matching of the gate pulse. Since in this case the gate circuit 41 is switched by the lowest common multiplex frequency, the coincidence pulse J acts not only as a coincidence pulse for the largest common measurement synchronization signals 2 and 4, but also as a coincidence pulse for all PFP signals of these synchronization signals. In this way one obtains an identical characteristic with the example already mentioned by means of gating over the lowest common multiplex frequency.

F i g. 9 shows a block diagram of a further embodiment of the invention. This embodiment differs in that it has two different oscillators for the frequencies / 4 b; w. Y _n . These two frequencies are required as an output signal. In this embodiment, voltage-controlled oscillators 58 and 59 and phase detectors 56 and 57 are provided instead of the base oscillator 43 and the divider circuits 44 and 45 according to circuit 5, while the remaining part of the circuit is unchanged. By phase control of the output of the two oscillators 58 and 59 via two phase detectors 56 and 57 and by utilizing the largest common measurement frequency coincidence pulse C at the output, an output synchronous with the input pulse is obtained.

FIG. 10 shows a block diagram of a further embodiment of the invention in which the basic oscillator according to FIG. 5 is missing. This circuit works with the output of the other oscillator with a higher frequency than the frequencies f α and fn and is provided for another circuit.

In order to demodulate the PCM signal, the bit synchronization signal must be reproduced, for which purpose a bit synchronization circuit is required. The period 1 / ft, of the bit synchronization signal corresponds to the PFP pulse pattern according to FIG. 2D. The embodiment according to FIG. 10 can be used when the bit frequency / & is in an integer ratio to the screen frequencies / ^ and / h. Compared to F i g. 5, FIG. 10 shows a voltage-controlled oscillator 66 which oscillates at the bit frequency / »instead of the base oscillator 43. This oscillator 66 provides a synchronization output for the synchronization circuit 62, which is indicated in a dashed block. The bit synchronization circuit 62 according to FIG half the resonance frequency of the bit frequency / &, a rectifier circuit 64, a phase detector 65 and a voltage controlled oscillator 66, the output of the oscillator 66 being processed as in the basic oscillator. The circuit according to FIG. 10 operates in the same way as the circuit of FIG. 5 so that raster synchronizing signals / a and fn can be obtained.

indispensable for demodulating the PCM signal and eliminating distortion of the waveform caused on the transmission path of the input signal.

In the foregoing cases, the coincidence circuit 42 or 52 is in the circuit for deriving a protection circuit is provided for the synchronization signal. The coincidence circuits 42 and 52 are according to FIG. 11 executed and cause coincidence pulses by identifying the transmitted synchronization signals 2 and 4 and by comparing them with the pattern previously established at the time the coincidence of all patterns. However, if the number of fixed samples is large or the transmitted If the signal contains impulsive noise, the coincidence impulse must be protected. The PFP coincidence circuit is then according to FIG. 12 amended.

One recognizes in FIG. 12 a shift register 71, a comparator 81, a fixed pattern generator 91, a memory circuit 68 and a connection 69 for the timing signal. The masked out synchronization signals 2 and 4 remain in the shift register 71 and are compared bit by bit by a timing signal at the terminal 69 with the output of the fixed pattern oscillator 91. The one bit coincidence pulse reaches the memory circuit 68. This stores this one-bit coincidence pulse. When the number of the one-bit coincidence pulse reaches a certain number, the circuit assumes that the complete coincidence pulse has been received and the coincidence pulse output C is output.

In this way a stable synchronizing signal output is obtained even if part of the PFP signal is lost due to external noise. As already mentioned, according to the invention the synchronization signal regeneration takes place in the same phase with the transmitted synchronization signals even if the synchronization signals are two different Have repetition frequencies and are transmitted in time division multiplex.

The AGC circuit shown in the embodiment of the receiver according to the invention for automatic Gain control generates an AGC voltage by detecting the level of the pause period of the composite input signal of a signal period, using the output signal G of AND circuit 47 of the synchronizing signal regenerator, as already in connection with the F i g. 5, 8, 9 and 10 explained.

Fig. 13 shows a block diagram of the AGC system according to the invention using the synchronizing signal regenerator. One recognizes in FIG. 13 an antenna 101, a tuner 102, an intermediate frequency amplifier 103, a detector 104, a synchronizing signal generator according to FIG. 5.9 and 10, a pulse shaper circuit 108, a gate circuit 109, a rectifier 110 and an amplifier 111. As with a normal television receiver, the composite still image signal goes through the antenna 101, the tuner 102 and the intermediate frequency ver stronger 103, is detected by detector 104 and forms a composite signal with the baseband component. This composite signal was passed to a sync signal regenerator, where, wi

F i g. 10 shows as the input circuit for the gate 65 already explained, the two types of synchronizing circuit 41 an identification circuit 61. These signals £ and F with the frequencies f _A and /> ai circuit is not directly related to output terminal 106 or 107 regenerated with the device according to the invention, but is also at the output of an AND circuit 4

ir + ··

13 »14

a synchronizing signal G with the largest common PFP detection circuit 105 and a measuring frequency of approx. 5 kHz for the two synchronizers 19. _
chronisiersignaJe £ and F generated. Part of the Si The tone regenerator 19 includes a gnals G goes into a pulse shaper circuit 108 and digital-to-analog (DA) wall circuit 132 and an amplifier gSgnete one-digit of the phase position of the beekeeper 133. The circuit 19 'causes the DA conversion pulse, through acceleration or deceleration, to generate the identified PCM signal in the converter 132, a gate pulse of suitable pulse width is maintained. "Nd gives the speech signal through a loudspeaker 14. This gate pulse goes into the gate circuit 109. Neither in practice the speech signal is so much multiplied common measuring frequency - lers 132 a gate circuit is provided and from about 5 kHz of the two frequencies f _A and f _H for only the desired tone signal through the in-gate circuit of the pause period according to FIG. 2D structure indicator shown in Fig. 3, hidden. The signal level of the interrogated pause fades out and is played back. These details period, with the period corresponding to a frequency, no longer belong to the invention,
of approx. 5 kHz, is rectified by the rectifier 110. This is rectified in the PFP derivation circuit 105, so that a direct voltage proportional to the queried signal input signal to the PFP control circuit 42 is obtained. This neither via an AND gate 137 nor the And-Gaüer SpLnui-g is explained by an amplifier 111 to 134 and 135 as in FIGS. 5 and 10. The sufficient amplitude brought and given to the tuner 102 PFP-Ko.nadenschaltung 42 comprises a fixed pattern and the intermediate frequency amplifier 103 to »generator for generating an identical pattern as AGC voltage, the automatic amplification with the PFP signal in the input signal and with to effect the regulation, with a single-bit comparator at output 23. The circuit 42 produces an amplitude stabilized composite signal ER-coincidence pulse when the signal PFP the _häl Em [output signal is supplied (see. The F ι g. 11

As already mentioned, according to the invention this is ² 5 and 12). . ... ". ,, _ ..

Input signal for the base of the AGC voltage in The same input signal with the signal for the

of the same period of both the video and PFP coincidence circuits 42 come to one separately

Tone period detected, so that no ripple as a result of the intended MCC-KomzidenzschaUung 125, to the

Difference in the repetition frequencies of the synchronizing ^{and the} coincidence pulse of the PFP coincidence

signa _le in the transmitted composite signal 3 ° circuit 42 passes Corresponding code for uber-

arises so that one has a stable automatic detuning MCC signals after the PFP signal

Get strengthening control. w ^ en detected and corresponding coincidence amps

A practical embodiment of a clamp generated when the code of the MCC signal is equal to one.

circuit for the receiver according to the invention The coincidence pulse of the MCC signal for display

works with the synchronizing signal regenerator 35 of the horizontal synchromesh signal f _H and that

generated signal, as in connection with the F i g. 5, Tonrastersynchronis.ersignal / "_ get to a

8, 9 and 10 explained. AND gate 141, together with an output of the

The practical embodiment PFP coincidence circuit shown in FIG.

form of a receiver ^{according to the invention comprises at the} output of AND-gate_141 is only then

a synchronizing signal regenerator 105, an MCC- 4 ° a pulse when its inputs the three above-

Signal coincidence circuit 125, divider circuits 44 called coincidence pulses are supplied simultaneously

and 45 for obtaining the horizontal synchronization, so that the output pulse in the penode

siersignals f _H and the ^ raster synchronization signal * coincides with the largest common measurement

Sa, a synchronization signal regenerator 121 for the frequency of approx. 5 kHz between horizontal syn-

other synchronization signal, an AND gate 47 (cf. 45 chronisiersignal (/ «= 15.743 kHz) and tone raster

Fig. 10), an AND gate 122, a clamping circuit synchronizing signal [J _A = 10.5 kHz) This pulse

123 and a tone regenerator 19 '(see. Fig. 3) ^{with the} largest common measurement frequency goes as

The bit synchronizing signal detection circuit 124 reset pulse to the dividing circuits 44 and 45.

includes a bandpass filter 125 for selecting the bitsyn- The divider circuits 44 and 45 divide the output

chronisiersignalfrequency component, a circuit 5 ° gear of the synchronizing signal regenerator 128 generated

126 Rechieckkurvencharakteristik, such as a ^Si 8 ^{Al (of about} · ^{6 '54 MHz) in a} ratio of 1/416 or

Detector and an amplifier selector circuit 127 for ¹ ^ ^{24 down} > ^mr generation of the horizontal syn-

Acquisition of a signal with a given chronizing signal and the tone grid synchronizing

Gain exceeding value. The bit synchronization signals.

The signal detection circuit 24 detects the signal 55 ^{By using the s0} obtained horizontal syn ·

component with bit synchronizing signal frequency from the chronizing signal and the Tonrastersynchronisiersigna

Input signal. By using and combining ^{on an} AND gate 47, you get at the exit

this detected signal is given a phase of ^the AND gate 141 an output pulse with dei

detector 129 and a voltage-controlled oscillator ^largest common measurement frequency of the frequencies / i

synchronization 130 des Bitsynchronisiersignalregene- 6 " ^and / ^ - ^{This Im} P ^{uIs is set to an} AND gate 13 <

rators 128 and a Bitynchronisiersigna! of approx., which means that from the input signal of the Syn

6.54 MHz, synchronized with the input synchronization signal part of the PFP and MCC signal ·

signal. The regenerated bit synchronization signal can only separate the part that the Penode de

serves as a timing pulse. The amplitude of the greatest common measurement frequency of the frequencies / j

output signal is at the identification circuit 131 ^{corresponds to 65 and} f * , so that by eliminating the nich

recorded. A corrected pulse signal is obtained through the required part of the input signal a stable

Shaping the curve of the input signal. Sync signal reproduction is achieved.

The thus molded input signal passes to a transition ⁱⁿ situations, such as in on and off

15 '16

switch of the device, the other synchronization signals from the divider circuits go to the corresponding 44 and 45 derived signal with the input synchronizing Synchronisiers.signalregeneratoren 121 for the purpose of chronisiersignal not synchronized, so that the gate generation of corresponding coincidence pulses by tersignal, which is derived from the Signal or the MCC coincidence circuit and are used in the faded out input signal through the output 5 necessary circuit,
of the AND gate 47 at the output of the AND gate 134 As mentioned above, a synchronization is obtained that does not contain any portion of the synchronization signal with the greatest common measurement frequency of. In this situation, there is no synchronization of the frequencies f _H and f _A, approximately 5 kHz, to the same sation, so that during transition processes all input modes at the output of the AND gate 47 by sending input signals to the PFP coincidence circuit 42 the two regenerated synchronizing signals / «and gen and an early detection of the synchronizing signal f _A , which is required at the output of the divider circuits 44 and 44. A branch that receives the 45 on the AND gate 122 is used for this purpose. The signal supplies the input signal without fading. The switching goes to a waveform shaping circuit 142 for the cancellation contains an AND gate 137. During the period, speaking acceleration or deceleration in which no raster synchronization is achieved, 15 goes phase, so that only the pause period coincides with the input signal that is not masked out Impulse is generated. The pulse arrives at an AND gate 137. After reaching the Rastersyn- clamping circuit 123, so that the input signal goes single-synchronization, the masked input signal Hch is held when the pulse is supplied, whereupon an AND gate 135. This switchover takes place in both the video grid as well as the tone grid are explained as follows. 20 acts that they keep the level at the same

If the PFP coincidence pulse and a coincidence follow-up period of approx. 5 kHz hold, so that without

pulse between the horizontal synchronization of 10 Hz a stable clamping or holding

signal and the Tonrastersynchronisiersignal are available. The synchronization signal with the frequency

is obtained, as explained above, at the output of the and a common measurement frequency of the frequencies fn

Gate 141 a pulse with a period corresponding to 25 and f _A is obtained by using an output

accordingly the largest common measurement frequency of the AND gate 47 omitting the mentioned

Frequencies fn and f _A. With this pulse, the AND gate is 122, whereby the synchronizing signal regulator

Grid synchronization takes place so that the pulse to the generator with the circuit according to FIG. 5 used

Maintaining a certain voltage during a will.

certain period to an integrating circuit 140 in FIG. 15 is a practical embodiment that can be given. This voltage is applied to a clamping circuit 123 as shown. It is a control circuit 136 which generates an output signal! generated, synchronous clamping circuit, with an input when the voltage across a predetermined voltage connection 153, to which the still image signal is supplied, is voltage level, and an output 0 when the voltage an output connection 154, an input connection drops below this voltage level. The output 35 155 for the pulse signal, a transistor 156 to the output of the control circuit 136, goes to an inverse conversion of the input pulse into two pulse circuits 138 and an AND gate 135, which lets through the output signals of positive and negative polarity, clamp-masked input signal. The reverse diodes 157 and 158 and a voltage source circuit 138 generates an output signal 0 when on for a reference voltage Vr.

a signal is present at its input, and an output is generated by applying the pulse, which is output signal 1 with the pause period, when the signal 0 at an input according to FIG. 2 D is correspondingly at the repetition frequency. The output of the reversing circuit 138 reaches the highest common measurement frequency of the frequency to an AND gate 137, which passes the non-masked zen / h and f _A , achieved by the pulse shaper input signal. If at the output of 142, there is a pulse signal input 155, the AND gates 141 conduct no pulse signal, 45 diodes 157 and 158 are synchronized with this pulse, ie if the raster synchronization is not achieved, while diodes 157, 158 conduct the level, the signal 0 of the control circuit 136 goes to the and the pause period in the input terminal 153 gate 135 and to the reversing circuit 138. The input signal, whose direct current combined input signal, the AND gate 135 component is eliminated by a capacitor, with does not happen, but at the output of the inverting 50 clamped or switched 138 by the reference voltage level, a signal 1 occurs, which cannot be sustained, and a masked input signal is obtained at the output terminal 154 passes the AND gate 137 freeze-frame signal with one at the Reference voltage and goes to the PFP coincidence circuit 42 and the fixed DC voltage level.
MCC coincidence circuit 25. A suitable clamping is thus also achieved

As mentioned above, the bit synchronizing 55 can then when the following period of the pause period im

signal, the horizontal synchronizing signal and the synchronizing signal in video grid and sound grid

Tone screen synchronizing signal can be regenerated. Which is different.

In addition 9 sheets of drawings

Claims (12)

Patent claims: 1. Receiver for a composite signal consisting of a video signal and a sound S multiplex signal, transmitted in a predetermined sequence, wherein synchronizing signals necessary for reproducing the video signal and the sound multiplexed signal are required in different subsequent periods in the video signal transmission period and are inserted into the audio signal transmission period, with a common measurement frequency of the two repetition frequencies a part of the synchro signal to an identical mode is characterized in that a coincidence signal with a frequency equal to that common measurement frequency of the two frequencies is generated when a signal with the same mode how this mode part is supplied, and that the phase position of a generator for generating first ao and second signals having a frequency corresponding to the repetition frequencies by the coincidence signal is controllable. 2. Receiver according to claim 1, characterized in that an as from the first two signals third signal is generated, with a common measuring frequency of the two first signals, for derivation one. Synchronizing signal from the composite signal, by controlling a Gate circuit by the third signal, and that 3 »the synchronizing signal of the coincidence circuit derived in this way is fed. 3. Receiver according to claim 1, characterized in that a generator instead of this the synchronization effecting signal generator is provided that the phase position of the generator is controlled by the coincidence signal that generates first and second signals of the repetition frequency and a gate signal with a frequency corresponding to the common measurement frequency of the two repetition frequencies is effected by the two signals passing through an AND gate that synchronizing signals can be derived from the composite signal by controlling the gate circuit by the third signal and that the so obtained synchronization signals are fed to the coincidence circuit. 4. Receiver according to claim 1, characterized by a base oscillator, by two frequency converters instead of the generator, whereby the output signal of the basic generator is sent to the two frequency converters is supplied so that a first signal having a frequency corresponding to one of the two repetition rates through the first. Frequency converter arises and a second signal with an ss Frequency corresponding to the other of the two repetition frequencies by the other frequency converter and through the phase control of the two frequency converters through the coincidence signal, for Achievement of a third signal, in the output «- signals of the two frequency converters to one AND gates go to derive sync signals from the composite signal by controlling the gate circuit by the third signal and providing the one so derived Synchronization signal for the coincidence circuit. 5. Receiver according to claim 1, characterized by three frequency converters instead of the generator, whereby the output signal of the basic oscillator is fed to the three frequency converters, for generating a first signal with a frequency corresponding to one of the repetition frequencies am Output of the first transducer, a second signal with a frequency corresponding to the other Repetition frequency, of a third signal with a frequency corresponding to a common measurement frequency or a common multiple of the frequency of the repetition frequencies through two output terminals at the coincidence circuit for generating a first coincidence signal at the first output terminal when a signal with identical mode to part of the above-mentioned mode is provided, and for producing a second coincidence signal at the second output terminal if a signal is equal to a mode a further part of the mode is provided, and by the phase control of the first two frequency converters by the first coincidence signal and by the phase control of the third frequency converter by the second coincidence signal, the synchronizing signal from the composite Signal derived by controlling the gate circuit through the third signal and sent to the Coincidence circuit is given. 6. Receiver according to claim 1, characterized in that the coincidence circuit has a mode generator comprises a shift register for generating a pulse signal with a fixed mode, a comparator and a memory, the input signal being fed to the shift register and the output pulses of the shift register and the mode generator bit by bit by the comparator are compared and, in the case of coincidence, a pulse is generated for storage the impulses in the memory and to generate a coincidence signal at the output of the memory, when a predetermined number of pulses are stored in the memory. 7. Receiver according to claim 1, characterized by two oscillators instead of the generator, which are controlled by the coincidence signal, a first signal having a frequency accordingly one of the two repetition frequencies arises at the output of the first oscillator and a second signal with a frequency corresponding to the other of the two repetition frequencies at the output of the second oscillator, for generating a third signal with a frequency corresponding to the common Measurement frequency of the two repetition frequencies at the output of the AND gate, by supplying the output signals of the two oscillators, for deriving a synchronization signal from the composite Signal by controlling the gate circuit by the third signal and for supplying the synchronizing signal thus derived for coincidence switching. 8. Receiver according to claim 1, characterized in that the third signal with the common Measuring frequency of the signals from the first and second signal is generated that the signal level the blanking period by gating the blanking period of the composite signal is detected by the third signal and that the gain of the composite signal amplifier is controlled by the detected signal level will. 9. The receiver of claim 8, characterized marked as impulsmodulieries time division multiplex signal with characterized in that the level of the composite of a period IJF _A transmitted which differs from that of the signal in the blanking period by the third video signal. Accordingly, the er signal is fixed at a predetermined voltage. necessary synchronization signals for reproduction 10. Receiver according to claim 8, characterized in that the signal level of the blanking sends 5 of the video and audio signals in separate periods, namely in the period IJfs during the period of the composite signal by transmitting the video signal and the period \ Jf _A mask the blanking period of the composite during the transmission of the audio signal. The tone signal by the third signal is detected and that signal a blanking period comprising a PCM Rasterder signal level of the blanking period of together ₁₀ pattern signal (PFP) signal with a 16-bit Signal, set signal by the third signal to the is synchronized with the sound multiplex signal, predetermined voltage is fixed. and a mode control signal (MCC signal) from horizontal 11. Receiver according to claim I ₁ characterized zontal synchronization signal, Tonrastersynchronisierdurch a gate circuit, by a Koinzi- signal, raster signal, etc. In such a still picture broadcasting signal, signal is provided when a signal Adrd which is at least partially identical to the ratio between the synchronizing signal mode and period 1 ////, during the video signal transmission by an acknowledgment circuit sent for the coincidence period, and 1 / f _A , sent during the tone overdenz to generate a confirmation signal, carrying period, selected so that one gets a given level over an integer at one level. Likewise, the period t _{P of} the PFP step is if the coincidence signal is periodically selected so that it is supplied with the period l / fa and, with signals with two repetition rates \\ f _A forming an integer ratio,
sequences and phased by the coinci- To receive this freeze frame broadcast signal denzsignal and a gate signal with a frequency and for displaying the corresponding image on one according to the common measuring frequency or image display device and for playback of the associated one The common multiple of these frequencies of obedient bifd tones must be that of the PFP signal and the are generated, for controlling the gate circuit MCC signal formed synchronization signal only reproduced when the gate circuit of the are synchronized. chronisiersignals through the coincidence confirmation also required in the receiver for a Verification circuit is confirmed, in which the confirmation 30 freeze frame broadcast signal is an automatic Verification signal and the gate signal to the gate gain control circuit (AGC) for the compensation circuit arrive and the gate circuit so sation of field strength fluctuations of the received controls the composite signal to vibrate, just like a normal television other Cases can happen. receiver In a color television receiver, the 12. Receiver according to claim 11, characterized in that the peak value of the horizontal synchronizing signal is indicates that the oscillator frequency and that with a repetition frequency of 15.734 kHz, are regular Phase position of the basic oscillator inserted into the signal by a part, detected by a gate circuit of the synchronization signal are controlled. and to the tuner and the intermediate frequency stages as AGC voltage returned. The automatic gain control takes place in a known manner in FIG an instantaneous AGC system. In this still image transmission system, the synchronizing signal for accurate detection of the signal level, so that this level becomes the standard for The invention relates to a receiver for a strength control that can be used, a pause or composite signal, consisting of a video and a blanking period. As mentioned above, the signal and a sound-multiplexed signal are transmitted in a previous but the following period of the pause not as in the given sequence, with the synchronizing television signal being constant. This pause signals, which are required for the reproduction of the video signal and in every 1/1 period during the video signal over the sound multiplex signal, are sent in the transmission period and with a period \ Jf _{A during different subsequent periods in the video signal over the sound signal transmission period,}
The level of the pause or the blanking period could be inserted, whereby with a common period as in the instantaneous AGC system a measurement frequency of the two repetition frequencies is recorded by part of the normal television receiver, i.e. becomes an identical mode by means of a synchronizing signal. 55 Reproduction of two synchronizing signals with under- For the exemplary embodiment, the different subsequent period and the signal of a static broadcast signal set by discrimination is shown in front of a code in the MCC signal for display either. The receiver according to the invention is suitable for video or sound transmission periods and preferably for still images. Hiding all the signals present in the transmission signal In a still image transmission system, the 60 existing pauses and to record the transmitted Video and audio signals in a predetermined sequence AGC voltage. alternately broadcast. In a case of a stand such a detection circuit is in itself Bild broadcasting signal becomes a video signal with a realizable, but the reproduction circuit becomes Period of Vso second and a sound signal too complicated and unsettled for the synchronization signal Period of Vw second sent alternately. 65 practical, also because the subsequent period of the The video signal becomes at every horizontal scanning AGC detection voltage in the video and sound periods of 1 // h = 63.5 μ «just as this differs as the transmission period, so that the Standard television signal sent when the audio signal recorded or rectified voltage waves