Patent Document

This application is a continuation of application Ser. No. 07/436,241, filed Nov. 14, 1989, now abandoned. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention relates to the field of the transmission of signals with a view to transmitting information or messages. 
     An object of the present invention is to provide a process and a system which permit a considerable increase in the reliability of the transmission of signals or of information. 
     Another object of the present invention is to be able to detect when it is impossible to receive the signals or the information which is desired to be transmitted. 
     Another object of the present invention is to be able to bring about the coexistence of a plurality of networks for the transmission of signals or of information which are assigned to different functions, each comprising a plurality of independent emitters and a plurality of independent receivers, the emitters of one network not disturbing the receivers of another network, the networks nevertheless having the possibility of exchanging signals or information between them. 
     Another object of the present invention is to be able to combine the objectives set forth hereinabove. 
     Another object of the present invention is to be able to accomplish these objectives at very low costs, in particular by virtue of simple radio transmission means. 
     SUMMARY OF THE INVENTION 
     The present invention relates, first of all, to a process for signal transmission. 
     According to one subject, the present invention pertains to a process for the transmission of a signal having at least two conditions, such as a binary signal, which consists in emitting one of the conditions of the binary signal on a first transmission channel and its other condition on a second transmission channel and that it consists in detecting or receiving independently and respectively each condition of the binary signal on the corresponding transmission channel in such a manner as to be able to reconstruct the binary signal on the basis of the reception of a single one of its two conditions via one of the transmission channels. 
     The process set forth hereinabove may advantageously consist, furthermore, in producing a command signal when the two transmission channels are, for a determined duration, simultaneously activated or excited by one or more signals disturbing them. 
     The subject of the present invention is also a process for the transmission of a signal having at least two conditions, which consists in emitting each condition of the signal respectively on a plurality of transmission channels, simultaneously or successively, in detecting or receiving independently and respectively the conditions of the signal on the corresponding transmission channels, in such a manner as to be able to reconstruct the signal on the basis of the reception of a single one of its conditions via any one of the transmission channels, this process consisting, furthermore, in producing a command signal when all the aforementioned transmission channels are, for a determined duration, simultaneously activated or excited by one or more signals disturbing them. 
     The subject of the present invention is also a process for the transmission of a signal, which consists in emitting the signal on one or more occasions successively on a plurality of transmission channels, in detecting or receiving the signal independently and respectively on the said transmission channels in such a manner as to be able to supply this signal representing the information on the basis of its reception on any one of the transmission channels, and in producing a command signal when all the aforementioned transmission channels are, for a determined duration, simultaneously activated or excited by one or more signals disturbing them. 
     The subject of the present invention is, furthermore, a process for the transmission of a plurality of signals having at least two conditions, which consists in emitting one of the conditions of at least two of the signals on a common transmission channel, in such a manner as to be able to reconstruct these signals on the basis of the reception, via this common transmission channel, of a single one of their conditions. 
     The present invention also relates to a signal transmission system. 
     The subject of the present invention is a system for the transmission of a signal having at least two conditions such as a binary signal. This system comprises a device for the emission of signals comprising either two oscillators switched in amplitude alternately by the two conditions of the binary signal (B 1 ) and capable of emitting, one on a first frequency (f 0 ) and the other on a second frequency (f 1 ) or an oscillator switched in frequency by the binary signal and capable of emitting on a first frequency (f 1 ) only when the binary signal is in one of its conditions and on a second frequency (f 2 ) only when the binary signal is in its other condition. It further comprises a reception device comprising either two signals detectors sensitive respectively and independently to the said first and second frequencies (f 0 , f 1 ) or a single scanning or frequency scrutinizing detector capable of detecting independently the said first and second frequencies (f 1 , f 2 ), in such a manner as to supply at its output the binary signal or its inverse, which are received via the first or the second of the said frequencies. 
     According to the present invention, the system may further comprise a second device for the emission of signals comprising an oscillator switched in amplitude by one of the conditions of another binary signal (B 0 ) and capable of emitting on only one of the aforementioned frequencies (f 0 ), so that the reception device supplies this other binary signal (B 0 ) at its output. 
     According to the present invention, the system may likewise comprise a second device for the reception of signals comprising a detector sensitive only to one of the aforementioned frequencies (f 0 ), in such a manner as to supply the binary signal (B 1 ) at its output. 
     According to the present invention, the system may advantageously comprise a second device for the emission of signals (B 2 ) comprising either an oscillator switched in frequency by a second binary signal (B 2 ) and capable of emitting on the said second frequency (f 1 ) only when this second binary signal (B 2 ) is in one of its conditions and on a third frequency (f 2 ) only when this second binary signal (B 2 ) is in its other condition, or two oscillators switched in amplitude alternately by the two conditions of this second binary signal and capable of emitting, one on the said second frequency (f 1 ) and the other on a third frequency (f 2 ); as well as a second reception device comprising either a single scanning or frequency scrutinizing detector capable of detecting independently the said second and third frequencies (f 1 , f 2 ) or two detectors of signals sensitive respectively and independently to the said second and third frequencies (f 0 , f 1 ); in such a manner as to supply on the outputs of the reception devices the said binary signals (B 1 , B 2 ) or their inverse. 
     According to the present invention, the reception device preferably comprises means for supplying a command signal when the two frequencies to which it is sensitive are, for a determined duration, simultaneously excited or activated by one or more signals disturbing them. 
     The subject of the present invention is likewise a system for the transmission of a plurality of binary signals, which comprises emission devices adapted to emit respectively the said binary signals (B 0 , B 1 , B 2 ), as well as reception devices adapted to receive the binary signals emitted by the emission devices; at least two of the aforementioned emission devices being adapted to emit one of the conditions of the corresponding binary signals on a common frequency. 
     The subject of the present invention is also a system for the transmission of a plurality of binary signals between a plurality of emission devices and a plurality of reception devices. At least one first emission device comprises an oscillator switched in amplitude by one of the conditions of a first binary signal (B 0 ) and capable of emitting on a first frequency (f 0 ) and at least one second emission device comprises either an oscillator switched in frequency by a second binary signal and capable of emitting on the said first frequency (f 0 ) only when this second binary signal is in one of its conditions and a second frequency (f 1 ) only when this second binary signal is in its other condition, or two oscillators switched in amplitude alternately by the two conditions of the second binary signal and capable of emitting one on the said first frequency (f 0 ) and the other on a second frequency (f 1 ). At least one first reception device comprises a detector sensitive only to the first aforementioned frequency (f 0 ) in such a manner as to supply at its output the first binary signal (B 0 ) or the second binary signal (B 1 ), and at least one second reception device comprises either two detectors of signals sensitive respectively and independently to the first and second aforementioned frequencies (f 0 , f 1 ) or a single frequency scanning detector capable of detecting independently the said second and third frequencies (f 1 , f 2 ), in such a manner as to supply on its output the aforementioned binary signals (B 0 , B 1 ), or their inverse. 
     In the transmission system, the second reception device comprises means capable of supplying a command signal when the two frequencies (f 0 , f 1 ) are, for a determined duration, simultaneously excited or activated by one or more signals disturbing them. 
     In a variant of the invention, the emission devices and the reception devices are preferably connected by means of radio. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The present invention will be better understood on studying a signal transmission system formed of a plurality of networks, which is described by way of non-limiting example and illustrated diagrammatically in the accompanying FIG. 1, the accompanying FIG. 2 representing a mode of transmission of a signal. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The signal transmission system represented in the figure in a general way by the reference 1 comprises three independent devices for the emission of signals identified by the references 2, 3 and 4, as well as three independent devices for the reception of signals referenced respectively 5, 6 and 7. These emission devices and these reception devices are, in the example, connected by means of radio. 
     In the example, the emission devices are intended to transmit respectively binary signals B 0 , B 1 , B 2 . Each one of these binary signals is composed of a condition ONE and of a condition ZERO, this binary signal or a succession of binary signals representing information or messages to be transmitted. 
     The emission device 2 comprises an oscillator circuit 8 connected to an emitting antenna 9. It comprises an input 10 for the binary signal B 0 , which is connected to a switch 11, which is itself connected to a command input 12 of the oscillator circuit 8. 
     The emission device 2 operates in the following manner. When the binary signal B 0  is in its condition ONE, the switch 11 switches the oscillator circuit 8 in amplitude. This circuit 8 is controlled in such a manner as to oscillate on a frequency f 0  and the antenna 9 radiates this frequency f 0 . When the binary signal B 0  is in its condition ZERO, the oscillator circuit 8 is blocked and the antenna 9 does not radiate. Thus, the antenna 9 radiates the binary signal B 0  on the frequency f 0 . 
     Just like the emission device 2, the emission device 3 comprises an oscillator circuit 13 connected to an emitting antenna 14, an input 15 for the binary signal B 1 , which input is connected to a switch 16, which is itself connected to a command input 17 of the oscillator circuit 13. As in the case of the emission device 2, the oscillator circuit 13 is switched in amplitude by the binary signal B 1  and emits on the same frequency f 0  as the oscillator circuit 8 of the device 2. Thus, the antenna 14 radiates on the frequency f 0  when the binary signal B 1  is in its condition ONE. 
     The emission device 3 further comprises a second oscillator circuit 18, the output of which is likewise connected to the antenna 14, a switch 19 which is connected to the switching input 20 of the oscillator circuit 18 as well as an inverter 21 which connects the input 15 to the switch 19. When the binary signal B 1  input by the input 15 is in its condition ZERO, this condition is inverted by the inverter 21 and the switch 19 switches in amplitude the oscillator circuit 18, which is controlled in order to oscillate on a frequency f 1  different from f 0 , so that the antenna 14 radiates on this frequency f 1 . 
     Accordingly, the emission device 3 is constructed in such a manner that its antenna 14 emits on the frequency f 0  when the binary signal B 1  is in its condition ONE and emits on the frequency f 1  when the binary signal B 1  is in its condition ZERO. This mode of operation appears in FIG. 2. 
     Thus, the emission device 3 is adapted to emit simultaneously the binary signal B 1  and its inverse, on two different channels. 
     The emission device 4 differs from the emission device 3 in that it comprises only a single oscillator circuit 22 which, on this occasion, is a frequency hopping oscillator circuit, the output of which is connected to an antenna 23 and the command input 24 of which is connected to an input 25 by which the binary signal B 2  is input. The oscillator circuit 22 is controlled in such a manner as to oscillate at the same frequency f 1  as the oscillator circuit 18 of the emission device 3 when the binary signal B 2  is in its condition ONE. On the other hand, when the binary signal B 2  is in its condition ZERO, the oscillator circuit 22 oscillates at a frequency f 2  different from f 0  and f 1 . These frequencies f 1  and f 2  are radiated by the antenna 23. The emission device 4 is therefore likewise adapted to emit simultaneously the binary signal B 2  and its inverse, on two different channels. 
     The reception device 5 comprises an antenna 26 which is connected to the input of a reception circuit 27, which comprises a filter 28 and a detector 29, its output being connected to a signal output 30. This reception circuit 27 is locked or controlled in order to be sensitive to the radio signals appearing on the frequency f 0  in such a manner that it is sensitive to the signals emitted by the emission devices 2 and 3 on this frequency. Thus, the reception device 5 is capable of receiving and of supplying at its output 30 the binary signal B 0  emitted by the emission device 2 and likewise the binary signal B 1  emitted by the emission device 3. 
     The reception device 6 comprises an antenna 31 which is connected to two independent reception circuits 32 and 33 which comprise respectively filters 34 and 35 and detectors 36 and 37. The detection circuit 32 is locked in order to be sensitive to the radio signals appearing on the frequency f 0 , while the detection circuit 33 is locked in order to be sensitive to the radio signals appearing on the frequency f 1 . The output of the detection circuit 32 is connected to a signal output 40, while the output of the detection circuit 33 is connected to a second output 39. 
     Just like the reception device 5, the reception device 6 is capable of receiving, by virtue of its detection circuit 32 locked to the frequency f 0 , the signal B 0  emitted by the emission device 2 and the signal B 1  emitted by the emission device 3 and of supplying at its output 40 these binary signals B 0  and B 1 . 
     Furthermore, the reception device 6 is capable of receiving, by virtue of its reception circuit 33 locked to the frequency f 1 , the inverse of the binary signal B 1  emitted by the emission device 3 and of supplying this inverse at the output 39. 
     It should be observed that the signal B 1  and its inverse which are simultaneously emitted by the emission device 3 are simultaneously received by the reception device 6 and the reception device 6 is capable of supplying the signal B 1  or its inverse on the basis of the reception of a single one of the conditions of the signal B 1  via one of the frequencies f 0  or f 1 . 
     As has been seen, the emission device 4 emits likewise on the frequency f 1  to transmit the binary signal B 2 . As the reception device 6 is sensitive to this, it is likewise capable of receiving and of supplying at its output 39 the signal B 2  emitted by the emission device 4. 
     The reception device 6 likewise comprises an AND gate 41, the two inputs of which are respectively connected to the output of the reception circuits 32 and 33 and the output of which is connected to the input of a time delay circuit 42 connected to a command signal output 43. 
     When the two detection circuits 32 and 33 are excited at the same time during the duration of the time delay of the time delay circuit 42, a command signal appears at the output 43 of the reception device 6. The appearance of this command signal signifies that the transmission channels associated with the frequencies f 0  and f 1  to which the detection circuits 32 and 33 are respectively sensitive, are excited simultaneously and that in consequence no signal detection is validly capable of being carried out. 
     The reception device 7 is of a type different from that of the reception device 6 but exhibits the same functions. It is a scanning or frequency scrutinizing detection device which comprises an antenna 44 which is connected to the input of a frequency mixer 45, the output of which is connected to an intermediate frequency detection circuit 46 comprising a filter 47 and a detector 48. The output of this detection circuit 46 is connected to the input of a processing, command and feedback control circuit 49, one output of which is connected to the command input of a frequency controlled oscillator 50 which supplies the various local frequencies to the mixer 45. The circuit 49 exhibits a received signal output 51A and a command signal output 51B. 
     This reception device 7 is controlled or locked in such a manner as to be able to detect the radio signals appearing on the frequencies f 1  and f 2 . It is therefore capable of supplying at its output 51A the inverse of the binary signal B 1  and the binary signal B 2  emitted respectively by the emission devices 3 and 4 on the frequency f 1  as well as the inverse of the binary signal B 2  emitted by the emission device 4 on the frequency f 2 . It is moreover adapted to supply a command signal on its output 51B when the two transmission channels associated with the frequencies f 1  and f 2  are excited simultaneously for a determined duration, this function being performed by the processing circuit 49. 
     The transmission system 1 described hereinabove exhibits numerous advantages. In fact, its structure permits, in particular, the assurance, in a simple manner, of a very reliable transmission of signals and detection of when it is impossible to receive signals which are desired to be transmitted. 
     In fact, the binary signal B 1  or its inverse passes by means of radio from the emission device 3 to the reception device 6 through two independent transmission channels associated with the frequencies f 0  and f 1 , and this takes place simultaneously, so that if one of the transmission channels is disturbed, the binary signal B 1  or its inverse is nevertheless transmitted by the other transmission channel. This same objective is likewise achieved by the pair formed by the emission device 4 and the reception device 7, since the binary signal B 2  or its inverse may pass independently through the transmission channels associated with the frequencies f 1  and f 2 . 
     Furthermore, if the two transmission channels associated with the frequencies f 0  and f 1  are excited simultaneously for a duration at least equal to the delay time of the time delay circuit 42, this means that these two channels are at the same time disturbed or unavailable and that the transmission of the binary signal B 1  between the emission device 3 and the reception device 6 is impossible, this fact being indicated by the appearance of a command signal at the output 43 of this reception device 6. The pair formed by the emission device 4 and the reception device 7 likewise ensures this objective. 
     The binary signal B 0  emitted by the emission device 2 may be received by the reception devices 5 and 6, the binary signal B 1  or its inverse emitted by the emission device 3 may be received by the reception devices 5, 6 and 7 and the binary signal B 2  or its inverse emitted by the emission device 4 may be received by the reception devices 6 and 7, these links by means of radio utilizing only three transmission channels associated with the frequencies f 0 , f 1  and f 2 . 
     The objectives and advantages of the transmission system 1 which have been described hereinabove are particularly beneficial in the following application, in which a multiplicity of independent emitters may emit in a random and/or simultaneous manner. 
     The transmission system 1 may, in fact, constitute a system of linkage by means of radio to a plurality of networks, for example a network for the monitoring and control of household appliances and a network for the security of assets and of persons, this security system being, in a general way, an alarm system. In this case, the binary signals B 1  and B 2  might be generated by detectors linked to the security of the property and persons and the signal B 0  might be generated by emitters linked to the monitoring and to the control of household appliances. 
     As is evident from the aforegoing, a security signal, for example the signal B 1  or the signal B 2 , would be transmitted simultaneously and in a reliable and redundant manner on two transmission channels, it being possible for one channel to be disturbed or blocked without consequence upon the transmission of the said security signal. If the two transmission channels linked to this security signal are, for example, jammed at the same time, what is then involved would with a high degree of probability be a deliberate jamming and the command signal generated would then constitute an alarm command signal. The detection of jamming is not necessary where what is involved is the transmission of the signal B 0 , concerning which it can be considered that the function is less important than the function of the signals B 1  and B 2  which are linked to security. 
     The present invention is not limited to what has just been described. In particular, the transmission system 1 might comprise other emission devices and other reception devices. The signals B 0 , B 1  and B 2  might be signals having more than two conditions or concerning messages or concerning a repetition of messages each composed of a succession of signals, each one of these conditions or messages being capable of passing simultaneously or successively through more than two transmission channels, as might be done by the frequency hopping oscillator 22 in association with synchronized receivers, each channel permitting the reconstruction of the entirety of the message or of the information emitted. Each binary signal might, for example, be multiplexed between more than two transmission channels, each channel permitting the independent reconstruction of the entirety of the message or of the information emitted.

Technology Category: 5