DE4042088A1 - SIGNAL TRANSMISSION SYSTEM FOR A DOOR TELEVIDEOPHONE - Google Patents

Description

The invention relates to a signal transmission location for a door televideophone, especially for communication cation between a main office located in the house and one, e.g. B. located on the outer gate, outside Job.

Such systems are known and shown in Fig. 1. The signal transmission system shown schematically in Fig. 1 has a main station A located in the house and a located at the outer gate B. The main station A contains a monitor 1 , a Sen the / receiver 2 and a buzzer 7th The external unit B comprises a camera 3 , a loudspeaker 4 , a microphone 5 and a switch 6 , e.g. B. a bell button. Five lines connect the main station A to the branch office B, namely an image signal line L 1 , a speech signal line L 2 , a power feed line L 3 , synchronization signal line L 4 and a ground line L 5 .

The known system works as follows: the bell button 6 in the external unit B activates the monitor 1 in the main unit A when actuated. At the same time, the buzzer 7 hums. If a person then lifts off the transmitter / receiver 2 from the main station A, they can recognize a visitor located at the entrance gate. The visitor is picked up by the camera 3 in the branch office B and displayed on the monitor 1 of the main station A. In addition, the microphone 5 of the branch B and the transmitter / receiver 2 of the main station A transmit the visitor's voice. For mutual communication, the transmitter / receiver 2 of the main station A and the loudspeaker 4 of the branch office B transmit the voice of the person operating the main station A. The signals are transmitted in the known transmission system as follows: an image signal is transmitted via the image signal line L 1 , a speech signal, however, via the speech signal line L 2 . However, if it is a power signal, the transmission takes place via the power feed line L 3 . The synchronization signal is finally transmitted from the external unit B to the main unit A via the synchronization signal line L 4 . Finally, the signal communication is completed via the general ground line L 5 .

The known system requires a total of five transfers supply lines between main station A and branch office B to ensure mutual signal transmission most. This complicates the installation of such Investment and increases their costs.

The invention seeks to remedy and achieve this this goal by the subject matter of claim 1.

In the following, the invention is based on a preferred one Embodiment and its schematic drawing shear representations explained in more detail. In the drawing shows:

Fig. 1 shows a known signal transmission system;

Fig. 2 shows an embodiment of a signal transmission system according to the invention;

Fig. 3 is a block diagram of one embodiment of the invention; and

Fig. 4 signals used in the invention.

According to FIG. 2, the embodiment according to the invention essentially has the following components: a main station A located in the house with a monitor 1 , a transmitter / receiver 2 and a buzzer 7 ; an external station B located at the entrance gate with a camera 3 , a loudspeaker 4 , a microphone 5 , a switch 6 , for example a bell button; a signal line L 6 and a ground line L 7 , which connect the main station A and the branch office B.

Fig. 3 shows further details of the invention. Thereafter, the main station A essentially has the following func ons blocks: a power circuit 51 which rectifies an incoming alternating current and emits a power signal; a synchro generator 13 which generates a synchronization signal; Sprechsignal- a modulation circuit 52 which modulates the spoken word of the operator of the main unit A and outputs a modulated signal accordingly; a signal overlay circuit 12 which overlays the power signal, the synchronization signal and the modulated speech signal and outputs the overlay signal thereby obtained to a single transmission line 27 ; a DC isolating circuit 21 which suppresses the DC component in a code, speech and image signal provided by the branch office B; a code signal processor 53 which extracts the code signal from the output signal of the DC isolation circuit 21 ; an image signal processor 54 which extracts the image signal associated with the image of a visitor from the output signal of the DC isolating circuit 21 ; and a speech signal processor 55 which extracts the speech signal from the output signal of the DC separating circuit 21 , demodulates it and then reproduces the visitor's voice via a receiver 26 .

Branch office B has the following functional units:
A camera 29 which picks up a visitor as soon as it is controlled by the power and synchronization signal of the main station A; a code signal generator circuit 56 which generates a code signal when operated by a user; a speech tone modulation circuit 57 which modulates the word spoken by the visitor; a signal overlay circuit 31 , the image signal of the camera 29 , the code signal of the code signal generator circuit 56 and the modulated speech signal of the speech tone modulation circuit 57 superimposed on each other and the resultant overlay signal to the transmission line 27 , and finally a speech signal -Processor 58 , which records the speech signal delivered by the main station A, demodulates and reproduces the voice of the person operating the main station A via a loudspeaker 41 .

The functional units of main and Branch A, B are explained in more detail below.

The power circuit 51 has a transformer 10 on the input side and a rectifier 11 on the output side. The rectifier 11 rectifies the mains voltage supplied to the transformer 10 and outputs a corresponding supply voltage to the coupling element or the signal superimposition circuit 12 .

In the speech signal modulation circuit 52 , a transmitter or receiver 14 picks up the word spoken by the operator. Whose output signal passes through a low-pass filter 15 and is then modulated in a modulator 16 with the output signal of a carrier wave generator 18 . The modulated speech signal then passes through a high-pass filter 17 and is finally supplied to the signal transfer circuit 12 .

As already stated, the power signal, the modulated speech signal and the synchronization signal are superimposed on one another in the signal superimposition circuit 12 .

The signal supplied by the branch office B via the transmission line 27 first reaches the DC isolating circuit 21 . Its output signal is fed to the code signal processor 53 , the image signal processor 54 and the speech signal processor 55 .

On the input side, the code signal processor 53 has a decoder 43 which is connected via a switching driver 42 to a monitor 19 in the image signal processor 54 . The monitor 19 also contains a signal from a low-pass filter 20 connected upstream, to which the output signal of the direct current isolating circuit 21 is in turn supplied.

The speech signal processor 55 contains on the input side a high-pass filter 22 , the output signal of which reaches a demodulator 23 . The demodulator 23 is followed by a low-pass filter 24 , then an amplifier 25 and finally the receiver 26 , for example a loudspeaker.

In the branch office B, the superimposition signal reaches the camera 29 from the transmission line 27 via a low-pass filter 28 and a synchronization signal separation circuit 30 . The low-pass filter 28 branches off the power signal and the synchronization signal separating circuit 30 branches off the synchronization signal from the beat signal coming from the transmission line 27 . The output signals of the low-pass filter 28 and the synchronization signal separation circuit 30 control the camera 29 .

The overlay signal coming from the transmission line 27 is finally fed to an input-side high-pass filter 38 of the speech signal processor 58 . A demodulator 39 , a low-pass filter 40 and finally a loudspeaker 41 connect to the high-pass filter 38 .

The output signal of the camera 29 is fed via a low pass filter 32 to a signal superimposition circuit 31 . The signal superposition circuit 31 also receives the output signals of the code signal generator circuit 56 and the speech signal modulation circuit 57 .

The code signal generator circuit 56 has on the input side a switch 44 , for example a bell button, and the actual code signal generator 45 .

The speech signal modulation circuit 57 has a microphone 36 on the input side. Its output signal reaches a modulator 34 via a low-pass filter 35 . The modulator 34 modulates the signal coming from the low-pass filter 35 with the carrier wave of a carrier wave generator 37 . The output signal of the modulator 34 finally comes across a high-pass filter 33 to the signal overlay circuit 31st

The camera 29 essentially has the following elements: A high pressure generator 29 a, which was driven by a power feed 29 b and the synchronization signal 29 c, a deflection circuit 29 d and an image pickup tube 29 e.

As already shown, the signal transmission system according to the invention works as follows ( FIG. 2):

Once a visitor to the gate at the input located branch B operates the switch 6, the buzzer sounds 7 of the main body A. At the same time, the monitor 1 is thereby turned on in the home. An operator can then record the transmitter / receiver 2 of the main station A, talk to the visitor at the gate and watch him on the monitor 1 at the same time. The camera 3 of the branch B takes the face of the visitor and transmits it to the main station A during the conversation. The speech, the image and the power signal are transmitted via a signal line L 6 and a ground line L 7 transfer. Since the signal transmission system according to the invention requires fewer transmission lines than the known signal transmission system, it is easier and less expensive to install.

3 and 4, the invention will be explained again with reference to FIGS.. First, the superimposition of the power, speech and synchronization signals from main station A is discussed.

An alternating current coming from the socket is converted into a direct current via the transformer 10 and the rectifier 11 . The output signal of the rectifier 11 then reaches the signal superimposition circuit 12 , which also receives the synchronization signal of the synchro generator 13 and the sound signals of the receiver 14 . However, the output signals of the transmitter 14 are first filtered in the low-pass filter 15 . This is so constructed that its output signals only contain frequencies below 10 kHz. The low pass filter signal is then modulated in the modulator 16 with the carrier signal of the carrier wave generator 18 , then high pass filtered and finally supplied to the signal transfer circuit 12 . The transmission line 27 consists of the signal line L 6 and the ground line L 7 .

In order to be able to transmit the power signal, the image signal and the speech signal simultaneously, the following is provided: The image signal band, which originally extends to approximately 4 MHz, is reduced to 3 MHz and the corresponding image is displayed on a small screen. The speech signal, which usually has a frequency range between 20 Hz and 15 kHz, is low-pass filtered so that it only contains frequencies below 10 kHz. The speech signal must be heard or transmitted by the transmitter / receiver 14 and transmitted with the carrier signal.

Fig. 4 shows the individual signals and their superposition. FIG. 4a shows the image signal band, FIG. 4b the speech signal band, FIG. 4c the power signal (frequency: 0) and FIG. 4d finally the frequency distribution of the output signal of the signal superimposition circuit 12 . Due to the frequency distribution shown in FIG. 4, it is possible to transmit the speech signal, the image signal and the power signal simultaneously via a single line pair L 6 , L 7 .

In the branch office B, the synchronization signal coming from the transmission line 27 and the power signal first reach a low-pass filter 28 . This filters out the power signal and leads it to the power supply element 29 b in the camera 29 . The synchronization signal separation circuit 30 filters the synchronization signal from the beat signal and also feeds it to the camera 29 . The camera 29 depicts the visitor. The image output signal of the camera 29 is low-pass filtered in 32 , with a limit frequency of 3 MHz. The low-pass filtered image signal is then supplied via the signal superposition circuit 31 to the transmission line 27 .

If a visitor presses the bell button 44 , the code signal generator 45 generates a code signal. This is also supplied via the signal superposition circuit 31 to the transmission line 27 . The visitor's speech signal passes from the microphone 36 to a low-pass filter 35 and from there to the modulator 34 , in which it is modulated with the carrier signal of the carrier wave generator 37 . The modulated signal finally reaches the signal overlay circuit 31 via the high pass filter 33 . The image signal, the speech signal and the power signal are then transmitted as a common beat signal on the transmission line 27 . This signal also has the spectral distribution shown in FIG. 4.

In the main station A, the DC isolating circuit 21 extracts those spectral components from the beat signal that do not contain any direct current. If a visitor presses the bell button 44 , the code signal is generated. This signal is detected by decoder 43 and supplied to switching driver 42 . As a result, the monitor 19 is switched on.

The image signal coming from the external station B passes through the low-pass filter 20 with a cut-off frequency of 3 MHz. The low-pass filtered image signal then generates an image of the visitor on the monitor 19 . The speech signal coming from the external station B is detected by the high-pass filter 22 after passing through the DC isolating circuit 21 . This only allows frequencies above 3.5 MHz to pass. The amplifier 25 amplifies the low-pass filtered signal and passes it on to the receiver 26 .

The speech signal from the main station A passes through the high-pass filter 38 , which also has a cut-off frequency of 3.5 MHz, that is to say the same cut-off frequency as the high-pass filter 33 in the external station B. After demodulation in the demodulator 39 , the signal reaches the loudspeaker 41 .

In summary, the invention has the following advantages:

The installation of the system is easier and less expensive than conventional systems. In addition, it is safer. This is achieved by a tailor-made frequency distribution of the beat signal ( Fig. 4), so that not five or six but only two lines 6 , 7 are required for its transmission.

The image signal, the speech signal, the energy supply and the synchronization signal are transmitted simultaneously via a single line between the branch office A and the branch office B. For this purpose, the signal frequencies of the speech signal and the image signal in the external unit A and the extension B are separated from one another and the image signal, the speech signal, the synchronization signal and the low-frequency power signal are superimposed on one another and the four signals thus obtained are transmitted simultaneously via the single transmission line 27 .

Claims (7)

1. Signal transmission system for a door televideophone for communication between a main station (A) in the house and a branch (B) located at the main gate, characterized by such an interpretation that

• a) the speech signal and the image signal are each modulated by means of different carrier frequencies and
• b) the speech signal, the image signal, a synchronization signal and low-frequency power signal in a signal superposition device ( 12 , 31 ) superposed and then transmitted simultaneously via a single transmission line ( 27 ).

2. Plant according to claim 1, characterized in that the main unit (A) has:

• a) a power circuit ( 51 ) having means ( 11 ) for rectifying an alternating current and then emitting a power signal;
• b) a synchro generator ( 13 ) which generates a synchronization signal;
• c) a signal superimposition circuit ( 12 ), the power signal ( 51 ) emitted power signal, the sync generator ( 13 ) emitted synchronization signal and the speech signal modulation circuit ( 52 ) emitted speech signal superimposed on each other;
• d) a direct current isolating circuit ( 21 ) which suppresses the direct current components in the code, speech and image signals supplied by the external unit (B) via the transmission line ( 27 );
• e) a code signal processor ( 53 ) which removes a code signal for activating a monitor ( 19 ) from the direct current isolating circuit ( 21 );
• f) an image signal processor ( 54 ), which takes the output signal of the DC isolating circuit ( 21 ), the image signal for image of a visitor; and
• g) a speech signal processor ( 55 ), the output signal of the DC circuit ( 21 ) takes the speech signal, demodulates and reproduces the visitor's voice via a receiver ( 26 ).

3. Plant according to claim 1 or 2, characterized in that the branch (B) has:

• a) a camera ( 29 ), which shows a visitor when controlled by the power signal and the synchronization signal of the main station (A);
• b) a code signal generator circuit ( 56 ) which generates a code signal when activated by a visitor;
• c) a speech tone modulation circuit ( 57 ) which modulates the visitor's speech signal;
• d) a signal superimposition circuit ( 31 ), the image signal of the camera ( 29 ), the code signal of the code signal generator circuit ( 56 ) and the modulated speech signal of the speech tone modulation circuit ( 57 ) superimposed on each other and the resulting overlay signal to the transmission line ( 27 ) forwards; and
• e) a speech tone processor ( 58 ) which, after demodulation of a speech signal supplied by the main unit (A) via the transmission line ( 27 ), reproduces the voice of the person operating the main unit (A) via a loudspeaker ( 41 ).

4. Installation according to claim 3, characterized in that the code signal generator circuit ( 56 ) has a switch which can be actuated by the visitor ( 44 ) for triggering the code signal. 5. Plant according to claim 4, characterized in that the switch ( 44 ) is a bell button. 6. System according to one of claims 3 to 5, characterized in that the power signal of the power circuit ( 51 ) via a low-pass filter ( 28 ) of the camera ( 29 ) is supplied. 7. Plant according to one of claims 3 to 6, characterized in that the synchronization signal for the camera ( 29 ) by means of a synchronization signal separating device ( 30 ) from the signal Überlagungssi the overlay line ( 27 ) is separated.