DE1766857A1 - Alarm system - Google Patents

Description

A 1 arm a n 1 a g e The invention relates to an alarm system which is used in Approaching or entering the warning area. The invention relates to in particular a system for the detection of the intrusion of unauthorized persons.

Systems for detecting the unauthorized Eindringene are known and at the moment for military or indus- trial purposes in general use. Men in such systems it is common practice to make use of radar technology, where the entrance or exit of an object in the region between a high-frequency transmitter and a radio frequency receiver matches the signal from the balance, which is received stands usually in the absence of such counter- . Such a display results when an object, for example a person, passes through the high-frequency field of the transmitter. In such systems it would be advantageous to have the entire monitoring chain within a fail-safe loop so that the entire system is continually self-monitoring. This could eliminate the manual checks that are used to determine if the system is operating and if the system is working properly. In addition, it would be advantageous not only to meet the above requirements, but at the same time to simplify the circuit, which would by itself compensate for a degradation of the system.

. The invention is thus based on the object of creating an improved system for detecting the intrusion of objects, which has a uniform logic alarm system, which has simplified logic circuits to achieve the disadvantages described above, and which above all has a simplified logic alarm circuit which the entire system continuously checks itself - and introduces it through the visual wave value properties * when it is determined and a degradation of the system is compensated for. The object on which the invention is based is achieved by a high-frequency receiver, by a driving circuit which is coupled to the high-frequency receiver and a hysteresis characteristic, by a first AC / DC converter which is coupled to the driving circuit and a first signal depending on alternating signals of opposite polarity of generated the entrainment circuit, by a second AC / DC converter, which is coupled to the radio frequency receiver and generates a second signal when the amplitude of the output signal of the radio frequency receiver is greater than a predetermined threshold, and by an alarm device, which is coupled to each of the two converters and responds when the second signal is present or the first signal is absent and emits an alarm signal.

In the invention, therefore the above-described disadvantages are plants by the use of simplified logical network avoided in which demodulates the information signals by a radio frequency receiver and simultaneously a 8echteekwellen generating circuit with Histereseeigenschaften, for example a Schmitt trigger, and finally being fed to an AC / DC converter . The output circuit following the Schmitt trigger is also connected to a second AC / DC converter. The Hiaterese.de8 Schmitt trigger circuit is dimensioned so that as long as the amplitude of the received signal is greater than the hysteresis value, no imbalance occurs due to the presence of an intruder, the output voltage of the transducer connected to the Schmitt trigger becomes remain essentially constant. If an intruder gets into the field generated by the high-frequency transmitter, the signal applied to the input of the Schmitt trigger is shifted so that the applied signal no longer causes the entrainment circuit to be repeatedly taken along. An alarm detector and a display circuit are coupled to the converter; in one embodiment of the invention, the operating potential for the alarm detector and the display network is derived directly from the AC / DC converter. Thus, if the voltage from the second transducer falls below a predetermined threshold value, an indication is effected. The system is based on the principle of failure safety, so that if the Schmitt trigger does not receive the required lower limit signal, the display network is not supplied with sufficient operating potential and an alarm signal is generated.

The first AC / DC converter connected directly to the output of the high-frequency receiver is connected in the same way to the alarm detector and to the display network, but its voltage is reversed with respect to the output voltage of the converter which is coupled to the Schmitt trigger. The arrangement is such that if the amplitude of the output signal of the high-frequency receiver exceeds a certain threshold value, as would be the case when receiving an enemy counter-measurement, the voltage generated by the converter with opposite polarity causes the alarm detector and the display network to be excited . In one embodiment of the invention, a voltage doubling and filtering network is used for the AC / DC converters.

The invention will be explained in more detail below with reference to the drawing: Big. 1 shows a block diagram of an expedient Austihrungsform of the invention, Äig. 2 shows a circuit diagram of the entrainment circles and the networks for doubling the voltage, as never before in the block diagram according to Big. 1 uses nind, Big. 3 shows a circuit diagram of a network for voltage doubling and filtering for use in the STntem according to 71g. 1, Fig. 4 shows a circuit which responds to signals of the circuits according to Figs. 2 and 3 and which corresponds to the alarm detector and the display network according to Fig. 1, Fig. 5 is a representation of the input and output signals of the Schmitt- Triggers according to Fig. 1 and Fig. 6 illustrates the form of a signal that the high-frequency receiver typically offers to the alarm network in the system according to Fig. 1.

Pig._1 shows an embodiment of a system designed according to the invention for detecting intruders in the block diagram. The system includes a high frequency converter with an antenna 11 which directs a beam 12 of high frequency energy onto an antenna 13 associated with a high frequency receiver 14. In practice, a low-frequency signal modulates the high-frequency signal, @ and the high-frequency receiver 14 demodulates the received signal and forwards it as signal 15 to an entrainment circuit 16 and a Weehseletrom / 6leiohetromwandler, which acts as a voltage doubler 1? is shown with filter properties . The signal 15 is an alternating current signal with a fixed amplitude on which a direct voltage is superimposed. In the embodiment according to Fig. 1, the entrainment circuit 1.6 is a Schmitt trigger, which responds to the signal 15 and emits a square-wave signal 18 to a second AC / DC converter, which is specified as a voltage doubler 19 with filter properties. The outputs of the two voltage doublers 17 and 19 are coupled to a network 20 for detection and display. The network 20 is designed so that when it receives no signal from the voltage doubler 19, or when it receives a signal from the voltage doubler 17, a visual or hearing display occurs.

As will be described in detail below, the Schmitt trigger 16 is suitably biased so that it emits square-wave pulses to the voltage doubler 19 as long as the signal 15 alternates between the two histeresis limit values of the Schmitt trigger. As long as this happens, the voltage doubler 19 generates an output direct current of essentially constant amplitude for the network 20. If a foreign object enters the path between the two antennas 11 and 13, or is removed therefrom, a shift occurs Schmitt trigger 16 guided signals 15, so that the repeated entrainment of the Schmitt trigger 'easily suspends. The operation q /, 3 $ instruction for the network 20 for Detection and display of an alarm state is then no longer generated by the voltage doubler 19, so that an alarm signal is emitted. If the voltage level of the signals received by the high frequency receiver 14 falls below a certain threshold value, the voltage doubler 19 no longer supplies the required operating potential for the network 20, so that an uninterrupted alarm signal is emitted. The voltage doubler 17 supplies an alarm signal to the network 20 in the event that the amplitude of the signal 15 applied thereto exceeds a predetermined threshold value. That will be the case the moment countermeasures would be taken by anyone trying to gain access to the area protected by the system. During the normal operation of paint that is without the application of tactical countermeasures, causing the voltage Ever doppler 17 no agitation of the network 20 for generating an alarm and indication signal.

2 shows the circuit of the Behmitt trigger circuit and the voltage doubler 19 with filter properties according to FIG . The Bohmitt trigger has the conventional form and has NPX transistors 25 and 26, the emitters of which are connected in front of one another by a resistor 27 , the emitter of the transistor 25 being connected via the resistor 28 to a general reference potential which is used as ground or ground potential . The operating potential is supplied by a battery 29 which is connected to the collectors of the transistors 25 and 26 via collector resistors 31 and 32. A series resistor 33 is located between the collector of transistor 25 and the base of transistor 26. A voltage divider is formed by resistors 34 and 35, the connection point of the two being connected to the base of transistor 25 to put the circuit in the initial operating position bring. It may be advantageous to insert the bias voltage for the Schmitt circuit at a more forward located point of the systems, for example in the high-frequency receiver 14. In any event, the to the base of the transistor 25 applied signal a solid Wechselepannungsignal, the raised by a DC voltage that moves up (positive) and down (negative) when an unauthorized person enters the high frequency field. This means that the change produced when an intruder enters the field is equal to that which would result from slowly changing the resistance 35 .

The bias voltage applied to transistor 25 is set to the range between the two drive levels of the Scehmitt circuit. If an input terminal 38 receives the alternating signal 15 in the absence of an intruder, the base of the transistor 25 is first controlled to a certain extent in the positive, so that the transistor 25 is conductive, then it is controlled in the negative, so that the transistor 26 heads. As is typical of a Schmitt trigger circuit, the transistor 25 remains conductive after it is brought into the conductive switching position, and the transistor 26 remains non-conductive, although the level of the signal 15 is reduced to a point which is below initial signal is that has brought the transistor 25 for hours. If the potential of the signal applied to the base 25 is further reduced, then these reverse. Newspaper conditions around. This can be seen more precisely from the curve shapes shown in FIG. In the circuit according to FIG. 2, the collector of the transistor 26 is connected via a resistor 40 to the base of a PNP transistor 41 , the emitter of which is connected to the positive terminal of the battery 29 and the collector of which is connected via a resistor 42 to Manne . The arrangement is such that as long as the base of the transistor 25. is repeatedly controlled above and below the Hyetereses voltage level on both sides of the bias voltage level, the voltage at the collector of the transistor 41 follows a square wave train , as denoted by the reference numeral 18 . A capacitor 45 deb voltage doubler 19 is connected to the collector of transistor 41. Diodes 46 and 47 together with a resistor 48 and a capacitor 49 form the remainder of the voltage doubler in a switching arrangement as is well known. As long as the transistor 41 is switched on and off repeatedly , an output terminal 50 is held at a positive DC voltage level which is sufficient to set the alarm detector into operation in the manner shown in FIG. The voltage doubler 17 according to Fig. 3 is made up of capacitors 55 and 59, diodes 5 and 57 and a resistor 58, in exactly the same way as the voltage doubler 19, with the exception that an output terminal 60 of the circuit according to Fig. 3 becomes negative when an incoming signal 15 is present.

Referring to Fig. 4, there is shown useful circuitry for a network 20 for plotting and indicating an alarm condition. The circuit has PNP transistors 70 and 71, the bits of which are connected to the output terminal 50 of the voltage doubler 19 via diodes 72 and 73, respectively. The collectors are each connected to ground via collector load resistors 74 and 75. The base of the transistor 70 is connected to the output terminal 60 of the first voltage doubler 17 via a resistor 76 and also to the collector of the transistor 71 via the resistor 77. The base of the transistor 71 is grounded via a resistor 79 and is also coupled to the collector of the transistor 70 via the capacitor 80. The arrangement is such that the transistor 71 is normally conductive as long as an operating potential from the voltage doubler 19 is transferred to the output terminal 50 and the output terminal 60 is not supplied with an overlaying nagative signal from the voltage doubler 17. A third transistor 81 has its base connected through a resistor 82 to the collector of transistor 71, and its emitter circuit is directly connected to ground. The collector of the transistor 81 is connected to the output terminal 50 via a relay winding 84 to which a protective diode 83 is connected in parallel. The transistor 81 is normally conductive, and accordingly contacts 85 controlled by a relay winding 84, which are closed, are kept inoperative. If there is insufficient operating potential at the output terminal 50, the holding relay winding 84 remains de-energized, and although an operating potential is applied to the output terminal 50, a superimposed negative signal at the output terminal 60 keeps the transistor 70 conducting. This in turn causes the transistors 71 and 81 are non-conductive and the contacts open 85th The alarm indicator 86 can be of any known type , for example it can be a flashing light or an acoustic signal which is switched on by opening the contacts 85.

For the purpose of better understanding, FIG. 6 shows a typical waveform of the signal 15 reaching the driver circuit 16 connected in the Schmitt trigger circuit. Assume that the bias voltage for the Schmitt trigger circuit is undulating, that the circuit has a hysteresis curve such as that indicated by the letter "B", and that the strength of the signal generated by hostile countermeasures is the Has a value corresponding to "A". It can be seen that during the time interval T1, in which there is no intrusion into the system, the incoming signal 15 repeatedly passes through the upper and lower threshold values in order to entrain the Schmitt trigger. The voltage doubler 19 at, de-output terminal 50 thus generates the necessary operating potential to keep the contacts 85 closed. It is assumed that take place during the time interval T2 the enemy countermeasures, so that the strength of the incoming signal 15 to a point increases practically that the Spannungsverdoppeler 17 an existing negative signal to measure the output terminal 60 outputs that the transitor 72 in the conductive state and the transistors 71 and 81 brings in the non-conducting state. The contacts 85 thus open in the manner previously described. For the time interval T3 it is assumed that an intruder has entered the high frequency field, so although the AC voltage component of the output signal of the receiver remains constant, the DC voltage level of the base of the transistor 25 is pushed up to a point at which the AC voltage signal is not the Schmitt trigger circuit repeatedly runs through the required entrainment level. The Schmitt trigger circuit therefore remains in one of its two switching states, so that the square-wave signal 18 supplied to the voltage doubler 19 ends. Thus, the operational potential required to prevent an alarm from network 20 is no longer present. Similarly, the Schmitt trigger circuit is not made to operate during the time interval T4, on the basis of a displacement of the signal level down caused by an intruder, and there is generated a Alarmeignsl. The upward and downward shift in the bias voltage of the transistor 25 due to the presence of an intruder is briefly referred to as positive and negative penetration. Of course, if an intruder enters the field and moves through it, positive and negative changes will naturally occur in the DC voltage level at the base of transistor 25 , as can be seen from FIG.

During the time between the time intervals T4 and T5 , the amplitude of the signal 15 drops, and yet the signal strength is sufficient to bring about a repeated entrainment of the Schmitt trigger circuit. At the Syschtem_gem. According to the invention, the sensitivity of the system increases as the signal strength decreases. That is, if the peak-to-peak voltage of the fail-safe signal is FF, s volts, and if the Schmitt trigger circuit histeresis is Vh volts, the input signal must shift up or down to generate an alarm upon intrusion in the field vfle is 2h volts. If the sensitivity of the system is reduced to 50 percent of the normal sensitivity, the signal required in the event of an intrusion is only about half as great as the signal previously required. Thus, as the gain of the signal falls, the sensitivity increases until the point is reached where the sensitivity of the system is so great that the system is continually alarmed. This is shown in FIG. 6 for the time interval T5, where the system is continuously in the alarm state.

Claims (9)

P atent ans pr ü che 1. Alarm system that responds when approaching or entering the warning area, characterized by a high-frequency receiver (14), by a driving circuit (16) which is coupled to the high-frequency receiver (14) and a hysteresis characteristic, by a first AC / DC converter (19), which is coupled to the driving circuit (16) and generates a first signal as a function of alternating signals of opposite polarity from the driving circuit (16), through a second AC / DC converter (17) which is coupled to the high-frequency receiver and a second signal is generated when the amplitude of the output signal of the radio frequency receiver (14) is greater than a predetermined threshold value, and by an alarm device (20) which is coupled to each of the two transducers and responds when the second signal is present or the first signal is not available and emits an alarm signal. 2. Alarm system according to claim 1, characterized in that the DAB the alarm means (20) coupled to said first transducer (19) relay circuit (84), and a circuit (60) connected to the second transducer (17) and with the relay circuit (84) is coupled and the switching position of the relay circuit changes as a function of the second signal from the second converter (17). 3. Alarm system according to claim 1, characterized in that the driving circuit (16) is a Schmitt trigger. 4. Alarm system according to claim 1, characterized in that the converters (19, 17) are each voltage multiplier and filter. 5. Alarm system according to claim 1, characterized in that a relay (84) is provided which is coupled to the first transducer (19) and has a first group of contacts (84) which during the presence of the first signal from the first Converter (19) is normally closed. That the alarm device has a current regulator (81) which is in series with the winding of the relay (84), is coupled to the second converter (17) and, based on the second signal, a second converter (17) is non-conductive, and that said relay contacts (85) controls an alarm display device (86) in such a way that the alarm display device is put into operation when the contacts are opened. 6. System for determining the intrusion of unauthorized persons, characterized by a high frequency transmitter (10), by a high frequency receiver (14) for receiving signals from the high frequency transmitter (10), by a signal shaper (16) connected to the output of the high frequency receiver (14) and generates rectangular output signals as long as the amplitude of the output signals of the receiver repeatedly pass through first and second voltage levels, through first (19) and second (17) AC / DC converters, which are each connected to the signal shaper and to the high-frequency receiver and each has a rectified Generate an output signal in response to input signals, and respond by an alarm detector (20) and a display network (20), each coupled to the transducers, to a first signal from the second transducer or to the absence of a signal from the first transducer, and generate an alarm signal. 7. System according to claim 6, characterized in that the signal shaper is a Schmitt trigger. B. System according to Claim 6, characterized in that the converters have circuits for increasing the voltage which are coupled to the network with opposite polarity. 9. System according to claim 6, characterized in that the network has a monostable multivibrator which is coupled to the first transducer for feeding with operating potential and to the second transducer for feeding with driving signals, and that an alarm circuit is coupled to the multivibrator, which responds to its switching position and generates an alarm signal when the multivibrator is taken out of its stable frame.