EP0191048A1 - Signal transmission system intended particularly to the surveyance of a group of rooms to be protected - Google Patents

Abstract

Signal transmission system on a two-wire transmission line. The system is characterized in that it comprises a central unit (10) comprising a bidirectional control device (38) connected, on the one hand, to transmission and reception circuits (32, 33) respectively of code d identification and return codes and, on the other hand, to a two-wire transmission line (20), said bidirectional control device being controlled to transmit on said line in addition to said coded identification and response signals of other signals of information. The present invention finds application in particular in the surveillance of premises to be protected.

Description

Signal transmission system intended in particular for monitoring a set of premises to be protected

The present invention relates to a signal transmission system intended in particular for monitoring and protecting a plurality of dwellings in a complex such as a building or group of buildings.

Surveillance systems are already known comprising a central unit connected by a two-wire transmission line to a plurality of premises in a building to be protected and transmitting interrogation signals to detection devices each associated with a room and receiving in return a response signal from each room indicating that no anomaly such as a break-in has been detected in the room, the absence of a response signal resulting in the activation of visual signaling and / or sound.

However, such known systems are designed to transmit on the two-wire transmission line only signals relating to the surveillance of premises and the detection of a break-in in one of them. It is therefore necessary to provide in each building other transmission lines for example of intercom signals, call signals by a person outside the building of a person located inside a building premises, control signals for the opening of remote exits, such as landing doors, parking lot, from each room in the building. This then results in extremely expensive cabling costs.

The present invention aims to eliminate the above drawbacks by proposing a signal transmission system intended in particular for monitoring a set of premises to be protected, of the type comprising a central unit; a plurality of detection devices each associated with a room; a single two-conductor electrical transmission line connecting said central unit and said plurality of premises; and at least one detection means associated with each detection device; said central unit comprising a circuit transmitting sequentially to said plurality of detection devices, via the transmission line, a plurality of coded identification signals, each identifying a specific room; a circuit receiving sequentially from said plurality of detection devices, via the transmission line, a plurality of coded response signals, at least one coded response signal being received from each room after the transmission of at least one coded signal identifying said premises; an audible and / or visual alarm signal being emitted by the central unit when a response signal is not received following an anomaly detected by the detection means, said system being characterized in that the central unit further comprises a bidirectional control device connected on the one hand to said transmission and reception circuits and, on the other hand, to the two-wire transmission line, said bidirectional control device being controlled to be able to transmit, via the transmission line, and with coded identification and response signals, other information signals such as call signals by an outside person of a person located inside one of said local, intercom signals for communication between an outside person and a person in one of said premises, and signals for controlling the opening of remote exits from one of said premises.

According to a characteristic of the invention, the above-mentioned central unit is characterized in that it comprises a circuit, connected to the aforementioned transmission circuit, for inserting into an appropriate coded identification signals a coded information signal of the presence of a call signal and transmitted by the bidirectional control device to the room receiving the coded identification signal.

According to another characteristic of the invention, the aforementioned insertion circuit comprises a comparator circuit receiving the coded identification signals and the call signal previously coded and delivering to a connected insertion device. at the transmitting circuit a signal for controlling the insertion of the coded call presence signal into the appropriate coded identification signal.

According to yet another characteristic of the invention, the transmission and reception circuits are produced in a single integrated circuit comprising an encoder of identification signals, a decoder of the response signals and a control input connected to at least one output of the control circuit ensuring the above-mentioned sequential transmission and reception, said output also being connected to the bidirectional control device so that the bidirectional control device is in transmission mode and the decoder and the device bidirectional control devices are in reception mode according to the signal appearing on the output of the control circuit. The invention will be better understood, and other objects, characteristics, details and advantages thereof will appear more clearly during the explanatory description which follows, made with reference to the appended schematic drawings given solely by way of example illustrating a embodiment of the invention, and in which:

FIG. 1 represents a block diagram of an embodiment of the system of the invention,

FIG. 2 represents an embodiment of the central unit of the system of the invention,

FIG. 3 represents an embodiment of a detection device associated with each room to be protected, and

FIG. 4 represents electrical signals obtained at various points in the system of the invention.

Referring to FIG. 1, the system according to the present invention comprises a central unit 10 connected by a single electrical pair 20, for example an ordinary electric cable with two conductors (signal + ground) to at least one detection device 30, a detection device being associated with each apartment or room in a building.

The central unit 10 is associated with a keyboard 11 provided for example near the main access door of the building and which can in particular be of the hexa¬ decimal type, that is to say comprising sixteen keys respec¬ tively associated with the numbers 0 to 9 and the letters A to F. The lock or electric strike of the main door 12 can be controlled either from the keypad 11 or from the central unit 10 as will be explained later. The reference 13 represents a door of a garage of the building whose opening lock or electric strike can be controlled either directly from the central unit 10, or from a portable box 14 emitting signals over the air, such as infrared signals, received by a reception terminal 15 housed for example in the garage and comprising at least one infrared radiation receiver whose output signals are transmitted to door 13. A plurality of infrared receivers 17 arranged in suitable locations inside the garage of the building detects distress signals emitted by the portable box 14 carried by a person who is attacked. The electrical signal emitted by each of the infrared receivers 17 is transmitted to the central unit 10 and coded therein to inform either a caretaker or the occupants of the various apartments as will be seen later.

The central unit is also connected to a display or display unit 18 by means of a control device 19 which is also connected to a sound signaling device 21 such as for example a piezoelectric transducer. The display unit 18 includes, for example, 7-segment displays and can be installed in the caretaker's lodge or in any of the premises to be monitored, these locations also applying to the sound signaling device 21. The unit display 18 may also consist of large signage provided outside the building.

The reference 22 also indicates the presence of an event recorder in bidirectional relationship with the central unit 10 while the reference 23 represents an intercom device in bidirectional communication with the central unit as will be described later.

FIG. 2 shows in particular the internal arrangement of the central unit 10.

This includes a counter circuit 31, the reset input of which is connected to the common junction point of a resistor RI and of a capacitor C1 allowing automatic reset of the counter circuit in the event of a power failure. The counter circuit 31 includes a number of parallel outputs, in this case 10 in number, connected to the corresponding parallel inputs of an encoder 32, a decoder 33 and a comparator circuit 34. The output of the encoder 32 is connected, on the one hand, via a shaping circuit 32a, such as for example a monostable, to the clock input of a counter 34, and, on the other hand part, directly to an input of a first AND logic gate 35. The counter 34 is a counter of the decimal-decimal type binary coded or BCD, the BCD outputs being connected to a control circuit 36 constituted by a BCD-decimal decoder with 16 decimal outputs. The decimal outputs 1, 2, 3,4 are connected respectively to the anodes of four diodes D1 whose cathodes are connected in common to an input J of a rocker JK 37. The decimal outputs 5, 6, 7, 8 of the decoder 36 are respectively connected to the anodes of four diodes D2 whose cathodes are connected in common on the one hand to the control input of decoder 33 and, on the other hand, to a control input of a bidirec control device ¬ tional 38. The decimal outputs 9, 10, 11, 12 of the decoder 36 are respectively connected to the anodes of four diodes D3 whose cathodes are connected in common to the other input of the AND gate 35. The outputs 14 and 0 of the decoder 36 are connected to said other input of the AND gate 35 respectively via diodes D4 and D5, the output 14 being also connected to the anode another diode D6, the cathode of which is connected to a timing circuit 39. It should be noted that the cathodes of the diodes Dl are also connected to the other input of the AND gate 35. The decimal output 15 of the decoder 36 is connected to the anode of a diode D7 whose cathode is connected to the reset input of counter 34. This reset input is also connected to the cathode of a diode D8 whose anode is connected at the output Q of the flip-flop JK 37 and at the cathode of a diode D9 connected to the control input of circuit 31 and the anode of which is connected to the reset input of the counter circuit 31. L ' input of inhi¬ bition of the counter 34 is connected to the cathode of a diode D10 whose anode is connected to the output of the timing circuit 39.

The output of the decoder 33 is connected via an inverter 40 to the input K of the flip-flop 37 while the input of this decoder is connected to the bidirectional control 38. It should be noted that the decoder and the encoder 32 is in fact part of a single integrated circuit 41, the control input of which determines the operating mode of reception of the decoder according to the signal appearing at the output of the cathodes of diodes D2.

The comparator circuit 34 is connected via parallel inputs, 10 in number, to the corresponding outputs of a memory encoder circuit 42, the output of the comparator circuit being connected to an input of a second AND gate 43 whose the other input is directly connected to the decimal output 0 of the decoder 36. FIG. 2 shows the presence of the keyboard 11 and one of the infrared receivers 17 connected to the memory encoder circuit 42. The output of the second AND gate 43 is connected via a diode Dl to a timing circuit consisting of a resistor R2 and a capacitor C2 mounted in parallel and having a common junction connected to the input an inverter 44, the output of which is connected, on the one hand, to the inhibition input of the counter 34 via the diode D15 and, on the other hand, to the base of a transistor Tl via d 'a resistance R3. The emitter of transistor Tl is grounded while its collector is connected to an eleventh parallel input of encoder 32.

The output of the timing circuit 39 is connected via a diode D12 in series with a resistor R4 at the base of a second transistor T2 having its emitter to ground and its collector connected to the twelfth parallel input encoder 32.

The bidirectional control 38 has been shown schematically and does not need to be described in more detail since it is known per se. For example, such a bidirectional control is manufactured by the company Nationale Semiconducteur and referenced "4 bit bidirectional bus transceiver DP 8216 or 8226". The output of the bidirectional control 38 is connected to the two-wire transmission line 20.

FIG. 2 also shows the presence of the intercom 23 comprising a microphone 230 connected via an amplifier 231 to a winding El of a transformer Tr inductively coupled to the output winding E2 having one from its ends to earth and its other end connected to the bidirectional control 38. The intercom 23 further comprises a circuit for demodulating the signals received on the transmission line 20 and coming from one of the detection of a room. This demodulation circuit is consisting of an operational amplifier 232 mounted as a comparator and having its input terminal (+) connected to the transmission line 20, a resistor R5 connecting the terminal (+) to the terminal (-) of the operational amplifier, the terminal (-) of this amplifier being also connected to a resistor R6 connected to ground. The demodulation circuit further comprises an operational amplifier 233 which is in fact a subtracting differential amplifier having the input terminal (+) connected to the terminal (+) of the operational amplifier 232 and its terminal (-) connected to the output of the operational amplifier 232. The output of the operational amplifier 233 is connected to the earpiece 234 in this case a speaker.

The event recorder 22 of Figure 1 has not been shown for the sake of clarity. However, this is connected via twelve lines parallel to the twelve input lines of the encoder 32.

With reference to FIG. 3, there will now be described structurally a detection device located in a room or apartment, it being understood that there are as many detection devices as there are apartments in the building.

The detection device 30 comprises a bidirectional control 45 identical to the bidirectional control 38 of the central unit and connected to the two-wire transmission line 20. The output of the bidirectional control 45 is connected to the input of a decoder 46 having 10 other parallel inputs to which is applied a 10-bit coded reference signal stored in a memory device 47 and identifying the detection device. Of course, each detection device has its appropriate reference identification code different from the other codes identification associated respectively with the other premises. The input of the bidirectional control 45 is connected to the output of an encoder 48 having 10 of its parallel inputs connected to the parallel outputs of the memory device 47. Preferably, the 10-bit coded signal appearing at the 10 inputs of the encoder 48 is identical to the coded reference identification signal supplied to the decoder 46. As for the encoder 32 and the decoder 33 of the central unit, the encoder 48 and the decoder 46 are produced in the same integrated circuit comprising a control input defining the operating modes of the encoder and the decoder and connected, on the one hand, to the output of an inverter 49 and, on the other hand, to the two control inputs of the bidirectional control device 45 The output of the decoder 46 is connected to a timing circuit 50 the output of which is connected to an input of a third AND gate 51 of which the other input is connected to the output of an inverter 52. The output of the scope T 51 is connected to the input of the inverter 49.

FIG. 3 also shows the presence of a means of detecting a break-in, in the present case a detection switch CP which can for example detect the opening, by break-in or not, of the entry door of the 'apartment. Of course, the detection means can be arranged in any other suitable place of the premises, such as for example a window and can also be constituted by any means capable of signaling an anomaly during a break-in. The contact CP is shown in the closed state and connects the common point of a voltage divider constituted by resistors R6 and R7 to an input of a comparator 53 whose other input is connected to a reference voltage Vrf. The output of comparator 53 is connected via a timer circuit 54 and a diode D13 at the input of the inverter 52 also connected to one end of a capacitor C3, the other end of which is connected to ground.

The activation or deactivation of a detection device 30 of a particular apartment can advantageously be carried out when the normal occupant thereof leaves the apartment or enters it, respectively, thanks to a keyboard 55 on which the occupant will strike a particular command code for each apartment which will actuate in the corresponding detection device the opening or closing of the interrupter 56 mounted in parallel with the switch CP, for example , via a relay or an analog switch (not shown). The keyboard 55 is arranged for example in the vicinity of the entrance to the apartment.

The transmission line 20 is directly connected to the input of an inverter 57, the output of which is connected to a circuit for controlling the occupation of the line referenced at 58. A push button BP, normally in the state open, controls, when pressed, circuit 58 so that it transmits on its two output lines two bits of information applied to the eleventh and twelfth parallel inputs of encoder 48. One of the output lines of circuit 58 is connected by via a diode D14 at the input of the inverter 49. The circuit 58 can be produced simply by using an encoder having as corresponding input the control input of the circuit 58 and two outputs connected respectively to a first input two AND gates, the second inputs of which are connected in common to the output of the inverter 57.

The transmission line 20 is directly connected to the control circuit 19 comprising a decoder 191 connected by its 12 outputs parallel to a memory 192 and in which the identification codes of all the apartments are stored. The memory 192 comprises 10 parallel outputs connected to the 10 corresponding inputs of the display device 18. The twelfth parallel output line of the decoder 191 is applied to an input of an exclusive OR gate 70 whose output is connected to the input for controlling the display device 18 and the sound signaling device 21 while the eleventh decoder output line is connected to an input of an AND gate 71, the output of which is connected via a circuit of command 59 to the loudspeaker 61 of the intercom circuit 60. The latter comprises a demodulator circuit 62 identical to the demodulator circuit of the intercom circuit 23 of FIG. 2 and having its input connected directly to the transmission line 20, its output being connected to the loudspeaker 61. The microphone 63 of the intercom is connected via an amplifier 64 to the input winding E3 of a transformer Tr2 whose winding of output E4, inductively coupled to the winding E3, is connected by one of its ends to the bidirectional control device 45, its other end being grounded.

The output of the comparator 53 is also connected to the inverted input of the exclusive OR gate 70. The decoder 46 further comprises an eleventh parallel input connected to the memory device 47, the output of the decoder 46 also being connected to an inverted input of the gate AND 71.

The operation of the system according to the present invention shown in FIGS. 2 and 3 will now be described in detail and also with reference to FIG. 4. Assume first of all that there is no break-in committed to all the apartments, that is to say that all the contacts CP are closed, and that the output Q of flip-flop 37 has just passed to a high level thus triggering by its control input the counter circuit 31, this high level signal resetting the counter 34 at the same time. The counter circuit 31 then emits on its output lines a 10-bit coded signal at the enco ¬ Deur 32 which also receives on its eleventh and twelfth input lines low level signals because the transistors T1 and T2 are non-conductive under normal operating conditions. The encoder 32 is designed to then transmit series of high level pulses, four of them being referenced in FIG. 4a by II, 12, 13 and 14, each of these pulses being carrying the same signal coded at 12 serial information bits corresponding to the 12 bits appearing at the parallel inputs of the encoder 32. FIG. 4b shows by way of example one of the 12-bit coded signals carried by pulse II, the coded signal beginning in the present case with "1010 ..." followed by 6 other coded bits not shown for clarity and ending with the bits "... 00" corresponding to the eleventh and twelfth bits mentioned above. It should be noted that bit 1 of each coded signal is a high level pulse having a width greater than the width of the high level pulse representative of a bit 0 of the coded signal this differentiation between bits 1 and bits 0 being produced by the encoder 32. Each identical 12-bit coded signal carried by the pulses II to 14 is a coded signal identifying an individual detection device.

The pulses II to 14, after shaping by the monostable circuit 32a, are sent to the clock input of the counter 34 which codes in BCD each of these pulses. The decoder 36 by receiving the pulse II coded in BCD then emits at its decimal output 1 a high level signal transmitted to the second input of the AND gate 35 to validate the latter so that it can transmit at its output pulse II containing the identification signals of 12 bits appearing on its first entry. The bidirectional control device 38 being in transmission mode since its control input receives via the diodes D2 a low level signal, then transmits to the detection devices, via the transmission line 20, the pulse II containing coded identification signals. It should be noted that the passage to the high level of the signal appearing at the decimal output 1 of the encoder 36 resets the output Q of the flip-flop JK 37 to zero. The decimal output 2 of the decoder 36 then in turn emits a high level signal when a coded BCD signal appears at the output of the counter 34 following the appearance at its clock input of the pulse 12. The high level signal at the decimal output 2 again validates the gate ET35 so that it provides at its output the pulse 12 containing the coded identification signal appearing on the first input of the AND gate, the bi-directional control device again transmitting the coded i¬ dentification signal to the detection devices. The same process is repeated when the decimal outputs 3 and 4 of the decoder 36 transmit a high level signal to the second input of the AND gate 35. Thus, the same four coded identification signals are transmitted via the bidirectional control device 38 and line 20 to all detection devices. The sequential transmission of the same four identification signals is carried out for security reasons so that it is certain that at least one of them has been received by the detection devices. Of course, it is possible to transmit more or less than four coded identification signals. Since the CP contacts are closed, one of the detection devices will receive the four identification codes and will send in response four preferably response signals having the same code as the identification signals. FIG. 4a also shows the four coded response signals carried respectively by four high-level return pulses 15, 16, 17 and 18. The encoder 32 continues to transmit pulses identical to pulses II to 14 the counter 34 continues to count so that the decimal output 5 emits a high level signal putting in reception mode the bidirectional control device and the decoder 33. Of course, the width of the signal appearing at the decimal output 5 is sufficient so that we are sure of the reception by the bidirectional control device 38 of the first pulse 15 comprising the coded response signal which is then transmitted to the input of the decoder 33. Then, the decimal output 6 of the decoder 36 transmits in turn a signal of high level and of sufficient width to allow the transmission of the bidirectional control device 38 to the input of the decoder 33 of the second feedback pulse ur 16 including the coded response signal. This process is also repeated during the transmission by the decimal outputs 7 and 8 of the decoder 36 of the high level signals allowing the passage of the successive return pulses 17 and 18 comprising the coded return signals transmitted to the input of the decoder. 33. The latter is designed to compare the four coded signals of return to the coded signal of circuit 31 transmitted parallel to the parallel inputs of the decoder 33 which emits at its output a low level signal as represented in FIG. 2 during the equality between the four return pulses and the code at the output of the counter circuit 31. It should be noted that the eleventh and twelfth bits present in each of the coded return signals are not taken into account for the comparison of the -lo¬

fact that they are not significant. The low level signal transmitted at the output of the decoder 33 is transmitted via the inverter 40 to the TT input of the flip-flop 37 whose output Q then goes to a high level resetting the counter 34 and controlling the counter circuit 31 which then produces at its ten parallel outputs a new identification code for a detection device.

We understand the foregoing explanations that the control circuit comprising the counter 34 and the decoder 36 makes it possible to transmit and receive sequentially, via the bidirectional control device 38, the coded identification and response signals.

The operation of the system according to the invention will now be described in the event that there is a break-in in one of the apartments, that is to say that the switch CP of the associated detection device 30 is open. The process of sequential transmission of the coded identification signals is carried out in the manner already described above. When the four coded identification signals corresponding to the room where the ef¬ fraction takes place have been sent, no coded response signal is received by the decoder 33 of the bidirectional control device. The counter 34 continues to count to optionally transmit on the transmission line 20 again four local identification codes from the high level signals appearing at the decimal outputs 9, 10, 11, 12 of the decoder 36 and even then command by decimal output 13 the bidirectional control device 38 in order to check and make sure that there is no coded response signal and therefore that there is indeed a break-in in the room considered. FIG. 4a also shows the four recall pulses 19, 110, 111 and 112 carrying the coded recall identification signals, the pulse 113 shown in dotted lines carrying the coded return signal transmitted to the decoder 33 via the bidirectional control device which would then be controlled by the decimal output 13 of the decoder 36. This additional identification step is optional and is not moreover not used in this case.

Following the absence of a response signal _^ , the decimal output 14 of the decoder 36 produces a high level signal transmitted to the second input of the AND gate 35 and to the timing circuit 39 which delivers a high level signal, during example 8 seconds, and which blocks the counter 34, the high level signal of the decimal output 14 then being maintained for 8 seconds. FIG. 4a shows by way of example the signal 114 appearing at the decimal output 14 during the detection of the absence of response. The output signal of the timing circuit controls the transis¬ tor T2 serving as an insertion device in a particular 10-bit coded signal at the output of circuit 31 of the twelfth information bit of an alarm. Thus, the encoder 32 transmits to the detection devices via the AND gate 35, the bidirectional control device 38 and the line 20 a coded identification signal comprising the twelfth significant bit. This signal thus coded is received and decoded by the decoders 191 of the detection devices to signal, by the display devices 18 and / or the sound signaling devices 21, to all the premises that there has been a break-in in one from them, each display unit 18 identifying the number of the apartment where said break-in took place. Advantageously, the alarm or alert signal mentioned above can be received by all the premises or apartments of the building with the exception of that in which the break-in is observed. This is made possible by the presence of the exclusive OR gate 70 emitting a high level signal inhibiting the unit 18 and the sound device 21 when the input of the latter receives the twelfth bit while its inverted input receives from the comparator 53 a high level signal following the opening of the contact CP due to break-in. Thus, the perpetrator committing the theft will in no way be informed that an alert or alarm has been triggered in the building or in the group of buildings. It is also advantageous that the emission of the sound signal by the device 21 is done in a discreet manner in order to awaken only the attention of the occupants of the apartments. Of course, the display unit 18 can be, as already indicated previously, large dimensions and in particular of the display column type in order to display outside and to indicate to passers-by, the building, the floor and the number of the apartment in which the break-in is committed, flashing lamps (not shown) may be provided to draw the attention of passers-by to the display column.

After eight seconds, the counter 34 restarts and the decimal output 15 delivers a high level signal resetting the counter 34 and controlling the counter circuit 31 for the continuation of the sequential transmission and reception cycles respectively of the coded signals d 'identification and return.

In summary, the central unit 10 continuously transmits on the transmission line 20, sequentially, a plurality of identification codes intended respectively to be recognized by the detection devices 30 with which they are associated. When no break-in is present, that is to say when the detection switch CP of a detection device is normally closed, the decoder 46 of each detection device receives in succession all the codes, that he compares with its stored reference code. When a detection device recognizes its own code, the latter sends back a second code, preferably identical to the first, intended to inform the central unit 10 that, the switch being still currently closed, no break-in is committed . The central unit can therefore receive, after each transmission of a code, this return code. When all the apartments have been explored, and all the return codes have been correctly received, then this exploration cycle is reset. If, on the other hand, one of the expected return codes has not been received by the central unit, then the latter transmits the alert signal to all the detection devices 30 as explained previously.

Furthermore, the system according to the present invention makes it possible to advantageously transmit signals other than the coded signals intended for monitoring premises.

Thus, for example, a person located outside the building can directly call a person located in a room by transmitting a corresponding coded signal on the transmission line 20 via the bidirectional control device.

To do this, the outside person presses the keys on the keyboard 11 to dial the code, for example decimal, of the person to be called. The call signal output from the keyboard is then applied to the memory encoder 42 which produces at its 10 parallel outputs a coded call signal transmitted to the comparator circuit 34. When the latter detects equality between the code of the call signal and the coded identification signal emitted at the output of the counter circuit 31 and corresponding to the premises of the person to be called, it produces at its output a high level signal applied to the first input of the second AND gate 43. It should be noted that the appearance of the aforementioned coded information signal takes place immediately after the decimal output 15 of the decoder 36 has reset counter 34 if the coded signal previously issued identification did not give rise to the appearance of a coded return signal (case of a break-in) or immediately after the output Q of the flip-flop JK 37 had reset counter 34 in the case where the decoder 33 has detected a coded return signal after transmission of the previous coded identification signal. Under these conditions, the decimal output 0 of the decoder 36 then goes to a high level substantially at the same time as the command signal of the comparator circuit 34 appears on the second input of the AND gate. The high level signal of the output decimal 0 is applied to the second input of the AND gate 35 and allows the AND gate 43 to produce a high level signal which, via the timing circuit R2, C2 and the inverter 44 stops for a predetermined time the counter 34 thus maintaining at the high level the decimal output 0 to validate the AND gate 35. The signal at the output of the timing circuit also controls the transistor Tl serving as a device for inserting the eleventh information bit of call in the coded identification signal, the coded identification signal thus formed being transmitted via the AND gate 35, the bidirectional control device 38 and the transmission line 20 at the premises of the person call. At the end of the aforementioned predetermined time, the counter is restarted and the sequential transmission and reception process resumes with always transmission to the local concerned of the coded identification signal comprising the call signal as long as is maintained in encoder 42 output the call signal code. FIG. 4b shows by way of example a coded identification signal S comprising the eleventh significant call bit. The coded identification signal provided with the eleventh call bit is decoded by the decoder 191 of the device for detecting the premises of the person to be called, the eleventh bit at the output of the decoder then being at a high level and applied to the entry of the AND gate 71 to control the sound device 61 via the device 59. The person present in the room then picks up their intercom handset (microphone 63 and earphone 61) and can converse with the outside person who has at their disposal the intercom circuit 23. It should be noted that the inverted input of the AND gate 71 receives, simultaneously with the eleventh bit applied to the other input, the output signal from the decoder 46 shown in FIG. 3 and transmitted following equality between the reference code comprising the eleventh significant bit and the identification code received by the decoder 46 and also comprising the eleventh significant bit. The output of the AND gate 71 then goes high to control the device 59 as explained above.

It is important to note that when the outside person speaks into the microphone 230, the transmission of the coded identification signals to the detection devices is not disturbed. Indeed, the electrical signal representative of the human voice available at the output of the winding E2 of the transformer Tr serves as a signal carrying the coded identification signals. FIG. 4c also shows by way of example the manner in which the pulses I comprising the coded identification signals are transported by the electrical carrying signal SI on the transmission line 20. This mode of transmission is also carried out when a person in an apartment speaks while the coded reminder signals are being transmitted to the central unit 10. The operation of the demodulators incorporated in the intercom circuits 23 and 60 will now be described with reference to FIGS. 4c and 4f. The terminal ( ₊ ) of the comparator 252 receives from the transmission signal 20 the electrical signal SI of FIG. 4c carrying the pulses I comprising in the present case coded return signals. FIG. 4d shows the shape of the electrical signal S'1 carrying the pulses I 'appearing at the terminal (-) of the comparator 232. It can be seen that the signal S'1 and the pulses I' are identical to the signal SI and to the pulses I but have a lower amplitude. The results of the comparison between the signals of FIGS. 4c and 4d translate into the output at the output of comparator 232 of the signal represented in FIG. 4e and which is transmitted to the input (-) of the operational amplifier subtractor 233 whose input (+) receives the signal of figure 4c. The operational amplifier 233 therefore eliminates the pulses I by subtraction and provides at its output the electrical signal SI applied to the earphone 234.

The operation of the detection device 30 follows clearly from the preceding explanations and will be described briefly.

As already explained, the decoder 46 receives in succession all the identification codes transmitted by the central unit 10 and, after decoding, compares them with its reference code stored in the device 47. The decoder 46 then transmits at its output l 'low level pulse shown in Figure 3 when there is equality between the reference code and a received identification code. The pulse at the output of the decoder 46 is transmitted to the timing circuit 50 which delivers at its output a high level signal as shown and transmitted to an input of the AND gate 51, the width of the signal pulse at the output of the circuit 50 being identical to the width of pulses II to 14 comprising the identification codes. The CP switch being closed, the output of the inverter 52 is constantly maintained at a high level. The output of the AND gate 51 therefore delivers a high level signal identical to the signal at the output of the circuit 50. The inverter 49, whose output was previously at a low level, then goes to a high level so as to control, d on the one hand, the operation of the encoder 48 and, on the other hand, the bidirectional control device 45 so that it transmits on the transmission line 20 the return codes identical to the identification codes and intended to inform the 'central unit that no burglary is committed.

When the switch CP is open following a break-in, the comparator 53 emits a high level signal transmitted to the timing circuit 54 which, after a predetermined period of time, for example 10 seconds, transmits a high level signal at the input of the inverter 52, the output of which is then at a low level. In fact, when the decoder 46 detects the appearance of an identification code identical to its reference code, no command pulse is transmitted at the output of the AND gate 51 so that the encoder 48 does not transmit no coded return signal. The delay circuit 54 has the advantage of allowing a person entering the apartment to have sufficient time to inhibit the alarm system after opening the CP switch by dialing a particular code on the closing keyboard 55 thus the interrupter 56.

In addition, the person present in their apartment can remotely control the opening of a landing door or a parking door by actuating the push button BP so that the circuit 58 delivers at its output two high level signals applied to the eleventh and twelfth parallel lines of the encoder 48 which then transmits a twelve significant bit code on the transmission line 20. It it should be noted that one of the high level signals at the output of the circuit 58 is applied to the input of the inverter 49 in order to control the encoder 48 and the bidirectional control device 45, sending the coded signal from control of the opening of the exit being of course carried out after having checked by the inverter 57 that the transmission line 20 is free.

The insertion of a distress coded signal when one of the infrared receivers 17 has been energized is carried out in a similar manner to the insertion of a call signal and therefore need not be described more in detail.

The present invention therefore proposes a system making it possible not only to transmit signals on a two-wire transmission line for the surveillance of premises but also other signals on this same line without disturbing the operation of the surveillance system.

Claims

claims

1. Signal transmission system intended in particular for monitoring a set of premises to be protected of the type comprising a central unit; a plurality of detection devices each associated with a room; a single electrical transmission line with two conductors connecting together said central unit and said plurality of premises and a detection means associated with each detection device; said central unit comprising a circuit transmitting sequentially to the plurality of detection devices, via the transmission line, a plurality of coded identification signals, each identifying a predetermined room; a circuit receiving sequentially from said plurality of detection devices, via the transmission line, a plurality of coded response signals, at least one coded response signal being received from each room after the emission of at least one signal identification code for said room; an alarm and / or visual signal being emitted by the central unit when a response signal is not received following an anomaly detected by the detection means; characterized in that the central unit (10) further comprises a bidirectional control device (38) connected, on the one hand, to said transmission and reception circuits (32; 33) and, on the other hand, to the transmission line (20), said bidirectional control device being controllable for transmitting via the transmission line, and with the coded identification and response signals, other information signals, such as signals call by an outside person from a person inside one of said premises, intercom for communication between an outside person and a person in one of said premises, and control of the remote exit from one of the premises.

2. System according to claim 1, characterized in that the aforementioned central unit comprises a circuit (42, 34, 43, T1) connected to the aforementioned transmission circuit, for inserting coded signals of ident - Tification a coded information signal of the presence of an aforementioned call signal and transmitted by the aforementioned bidirectional control device to the room associated with the coded identification signal.

3. System according to claim 1 or 2, characterized in that the aforementioned insertion circuit comprises a comparator circuit (34) receiving the coded identification signals and the call signal previously coded in an encoder (42) and delivering to an insertion device (Tl) connected to the transmission circuit (32) a signal for controlling the insertion of the coded call presence signal into the appropriate coded identification signal.

4. System according to one of the preceding claims, characterized in that the aforementioned transmission and reception circuits are produced in a single integrated circuit comprising an encoder (32) of the identification signals, a decoder (33) of the signals response and a decoder control input connected to at least one output of the control circuit (34, 36) ensuring the aforementioned sequential transmission and reception, said output also being connected to the bidirectional control device (38) so that said bidirectional control device is in transmission mode and that the decoder and the bidirectional control device is in reception mode according to the signal appearing on the output of the control circuit.

5. System according to one of the preceding claims, characterized in that the aforementioned control circuit comprises a decimal-BCD counter (34) whose clock input is connected to the output of the above-mentioned encoder (32) and a BCD-decimal decoder (36) connected to said counter and having, in addition to at least the aforementioned decimal output, at least one decimal output connected to a first input of a first AND logic gate (35) connected to the bidirectional control device and delivering a signal for validation of the passage on the transmission line (20) of a coded identification signal appearing on the second input of said door (35) connected to the output of the encoder (32).

6. System according to one of the preceding claims, characterized in that the above-mentioned decoder (36) comprises another decimal output connected on the one hand to the first input of the first AND gate (35) above-mentioned and, on the other hand , at the first input of a second AND gate (43) of the aforementioned insertion circuit and the second input of which is connected to the output of the comparator circuit (34), the output of the second AND gate (43) being connected to the device for inserting (Tl) the coded call presence signal into the appropriate coded identification signal.

7. System according to claim 6, characterized in that a first timing circuit (R2, C2) is disposed between the output of the aforesaid second AND gate and the aforementioned insertion device for controlling said device for a predetermined time. insertion, said timing circuit also controlling during this same time the stop of the counter to maintain at the other aforementioned decimal output of the decoder (36) a signal validating the passage to the output of the first AND gate (35) of the coded signal of identification comprising the coded signal of call presence.

8. System according to one of the preceding claims, characterized in that it comprises a counter circuit (31) with parallel outputs on which the coded identification signals are transmitted and connected to corresponding parallel inputs of the encoder and decoder (32 ) and (33) above, the outputs of said counter circuit also being connected to corresponding parallel inputs of the comparator circuit (34) above.

9. System according to one of the preceding claims, characterized in that the aforementioned insertion device is a transistor (T1) having its base connected to the output of the above-mentioned timing circuit (R2, C2) and its collector connected to a parallel input of the encoder (32) not connected to the counter circuit (31).

10. System according to one of the preceding claims, characterized in that the above-mentioned encoder (42) is connected to the output of an alpha-numeric keyboard (11) delivering the call signal of a person of room to be called and / or at the outlet of at least one infrared radiation receiver (17) delivering a call signal to the person in the room representative of a distress signal transmitted by radio.

11. System according to one of the preceding claims, characterized in that it comprises an inter¬ phone device (23; 60) connected to the bidirec¬ tional control device (38) for the transmission of the above-mentioned intercom signal , said intercom signal serving as a signal carrying the coded identification and response signals.

12. System according to one of the preceding claims, characterized in that the output of the aforementioned control circuit delivering the validation signal of the passage a coded identification signal is also connected to the input J of a flip-flop JK (37), the input K of which is connected to the output of the decoder (33) by means of an inverter (40), the reverse output (Q) of said flip-flop resetting the counter (34) of the control circuit and controlling the counter circuit (31) so that it emits a new identification signal when a signal response code has been received by the decoder (33) after the transmission of the preceding coded identification signal.

13. System according to one of the preceding claims, characterized in that the aforementioned control circuit comprises a fourth decimal output transmitting a control signal to an insertion device (T2) of a coded signal indicating an alarm in an appropriate coded identification signal when no coded response signal has been received by the decoder (33) after transmission of a coded identification signal.

14. System according to claim 13, characterized in that the aforementioned insertion device is a second transistor (T2) having its base connected via a second timing circuit (39) to the aforementioned fourth decimal output and its collector connected to another parallel input of the encoder (32) not connected to the output of the counter circuit (31).

15. System according to one of the preceding claims, characterized in that each coded identification and response signal comprises 10 significant bits, eleventh and twelfth significant bits being inserted respectively by the first and second insertion devices (T1, T2).

16. System according to one of the preceding claims, characterized in that each detection device (30) comprises a decoder (46) and an encoder (48) produced in a single integrated circuit having a control input; a bidirectional control device (45) connected, on the one hand, respectively to the input and the output of the decoder and of the encoder and, on the other hand, to the transmission line (20), said decoder transmitting at its output a signal indicating the coincidence between a coded identification signal emitted by the central unit (10) and the coded signal identifying the room associated with said detection device, the control input of the integrated circuit receiving from a circuit (50) connected at the output of the decoder a signal controlling the encoder and the bidirectional control device for the transmission to the central unit of a coded response signal when no break-in has been observed by the aforementioned detection means (CP).

17. System according to claim 16, characterized in that the aforementioned circuit at the output of the decoder (46) comprises a timing circuit (50) whose output is connected to a first input, a third AND gate (51) having its output connected to the control circuit input via an inverter (44), the second input of the third AND gate (51) being at a high level as long as the detection means (CQ) has not detected no break-in.

18. System according to claims 15 and 16, characterized in that the above-mentioned detection means is a normally closed switch applying a predetermined voltage to a comparator (53), less than a reference voltage, the output of the comparator being connected via a fourth timing circuit (54) to an inverter (52) connected to the second input of the aforementioned third AND gate.

19. System according to one of the preceding claims, characterized in that each detection device (30) further comprises a circuit (191) decoding the coded identification signal comprising the coded alarm indicator signal for controlling the above visual and / or audible signaling.

20. The system of claim 19, characterized in that the aforementioned decoder circuit also decodes the identification signal comprising the coded call signal to control a sound signaling notably from the aforementioned intercom (60).

21. System according to one of the preceding claims, characterized in that each detection device

(30) above includes a control button (BP) connected to the output of the third AND gate (51) above to activate the above encoder (48) which transmits on the transmission line (20), via the control device bidirectional (45), a coded signal for controlling the opening of a remote exit such as a landing door, a parking door or the like.

22. System according to one of the preceding claims, characterized in that the means generating visual and / or audible signaling consist of a large display panel located on a public road adjacent to all of the aforementioned premises and arranged to react to the alert code issued by the central unit (10) when an anomaly has been detected.

23. The system of claim 22, characterized in that the aforementioned display panel is arranged to display location data of the place where la¬ said aforementioned anomaly detected occurred.