RU2157546C1 - Recovery radio beacon - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: invention is proposed for transmission of information via artificial earth satellites of international system COSPAS-SARSAT to stations for information reception and processing to determine coordinates of aircraft in distress. Technical objective of invention lies in diminished probability of false operations, in increased precision of determination of coordinates of position of catastrophe and in reduced time of search for those in distress with simultaneous simplification of radio beacon design, reduced manufacturing cost and increased reliability of its operations. Recovery radio beacon includes unit for input of signal for activation of radio beacon, adder, permanent storage, time code former, parallel-to-series code converter, former of controlling voltage, transmitter of satellite channel, former of modulating signal, transmitter of homing channel, duplexer, antenna, receiver of navigation signals from Global Positioning System and/or GLONASS, on-line storage, independent power supply unit with switch-on device, unit forming signal of emergency overload. Unit for input of signal for activation of radio beacon, adder, permanent storage, time code former, parallel-to-series code converter, former of controlling voltage, former of modulating signal and on-line storage can be manufactured on base of microprocessor. Radio beacon can be equipped with remote control desk and can be placed into shock-proof and fire-resistant container. EFFECT: diminished probability of false operations, increased precision of determination of coordinates of position of catastrophe and reduced time of search for those in distress. 3 cl, 2 dwg

Description

 The invention relates to the field of radio engineering and can be used to transmit information (distress signals, membership codes and coordinates of objects in distress) via artificial Earth satellites of the international system “COSPAS-SARSAT” at a station for receiving and processing information to determine the coordinates of aircraft in distress .

 A known emergency beacon containing a beacon activation signal input unit (distress dialing device), the first output of which is connected to the input of the read-only memory unit, the outputs of which are connected to the first inputs of the first adder, the first master oscillator whose output is connected to the first input of the amplitude modulator, the second the input of which is connected to the first output of the beacon activation signal input unit, the output of the amplitude modulator is connected to the input of the first power amplifier, in addition, the beacon contains Ora specifies the crystal oscillator, the control voltage generator and a second power amplifier, the outputs of the first and second amplifiers are connected via a duplexer to an antenna. (International Space Radio Engineering Disaster Detection System. Edited by B. Shebshaevich. - M.: Radio and Communications, 1987, pp. 121-124, Figs. 6.4 and 6.5.).

 The disadvantages of the known device are the impossibility of its automatic inclusion according to indicators of emergency sensors, the inability to determine the time elapsed since the accident, the lack of manufacturability in the manufacture of a beacon and high overall dimensions.

 The closest in technical essence and the problem to be proposed is an emergency beacon containing a beacon activation signal input block, the first output of which is connected to the input of the permanent memory block, the outputs of which are connected to the first inputs of the first adder, the first master crystal oscillator, the output of which is connected to the first the input of the amplitude modulator, the second input of which is connected to the first output of the beacon activation signal input unit, the output of the amplitude modulator is connected to the input of the first amplifier a power amplifier, a second driving crystal oscillator, a control voltage driver and a second power amplifier, the outputs of the first and second amplifiers are connected to the antenna through a duplexer; at the same time, a time code shaper, a frequency divider block, a parallel to serial code converter, a modulating signal shaper, a phase detector, a second adder, a direct current amplifier, a controlled generator, a frequency multiplier by two, and a frequency divider with a division ratio of 40 are introduced into the emergency beacon (( RF patent N 2060512, G 01 S 1/68, 1996).

 The disadvantages of the known device are the relatively high probability of false alarms of the beacon, the low accuracy of determining the coordinates of objects in distress, the considerable time and cost of searching when using it, and the complexity of manufacturing the device.

 The objective of the invention is the creation of an emergency beacon for distressed aircraft, which will reduce the likelihood of false alarms, increase the accuracy of determining the coordinates of the crash site and reduce the search time for the victims of a disaster while simplifying the manufacture of the beacon, reducing cost and increasing the reliability of its operation.

 The essence of the invention lies in the fact that an emergency beacon containing an input block for activating a beacon signal, the second output of which is connected to the second input of the adder, a permanent memory unit, N outputs of which are connected to the first N inputs of the adder, a time code generator, N outputs of which are connected to the third N inputs of the adder, N outputs of which are connected to N inputs of the parallel code to serial converter, the output of which is connected to the input of the driver of the control voltage, the output of which is the series is connected to the input of the modulating signal of the satellite channel transmitter, the modulator of the modulating signal, the output of which is connected to the input of the modulating signal of the transmitter of the drive channel, and the outputs of the transmitters of satellite and drive channels through a duplexer are connected to the antenna, equipped with a receiver of navigation signals from the Global Positioning System (GPS) and / or GLONASS, a random access memory unit and an autonomous power supply unit with a switching device, the beacon activation signal input unit is equipped with a unit of alarm overload signal, the output of the navigation signal receiver through the random access memory unit is connected to the fourth input of the adder, the input of the self-contained power supply unit with the switching device is connected to the first output of the beacon activation signal input unit, and the outputs are connected to the inputs of the time code generator, read-only memory blocks , a shaper of the modulating signal and power inputs of the transmitters of the satellite and drive channels, while the emergency beacon can be placed in shockproof and fireproof ohm container and is equipped with a remote control connected to the input unit of the activation signal of the beacon.

 In FIG. 1 is a functional diagram of an emergency beacon; figure 2 - block input signal activation of the beacon.

 The emergency beacon (see Fig. 1) contains a signal input unit for activating the beacon 1, adder 2, read only memory 3, time code generator 4, parallel to serial converter 5, control voltage generator 6, satellite channel transmitter (Rx 406) 7 , modulator 8, drive channel transmitter (PRD 121.5) 9, duplexer 10, antenna 1, receiver of navigation signals from Global Positioning System (GPS) and / or GLONASS 12, random access memory unit 13, autonomous power supply unit 14 s switching device 15, the emergency overload signal generating unit 16 and can be equipped with a remote control 17. The beacon activation signal input unit 1, adder 2, read-only memory unit 3, time code generator 4, parallel code to serial converter 5, control voltage generator 6, driver modulating signal 8 and the block of RAM 13 can be performed on the basis of a microprocessor.

 The emergency beacon can be placed in a shockproof and fireproof container.

 The beacon activation signal input unit 1 (see Fig. 2) contains an automatic power-on sensor unit 18, a manual power-on button 19, an emergency overload sensor unit 20, a programmable read-only memory unit 21, two operational memory elements 22 and 23, an emergency overload pulse amplitude meter 24, an emergency overload pulse duration meter 25, a calculator 26, a threshold code adjuster 27, a comparison device 28, a three-input OR element 29, and a two-input OR element 30, the output of each sensor of automatic inclusion I block 18 is connected to the corresponding input of the programmable read-only memory 21, the output of which is connected to the input of the operational memory element 22, the output of the manual control button 19 is connected to the input of the operational memory element 23, the emergency overload sensor unit 20 contains emergency overload sensors along the "X" axes , "Y" and "Z", the signals from each of which are fed to the emergency amplitude pulse meter 24 and the emergency overload pulse meter 25, the outputs of which are connected to the inputs of the calculator 26, the stroke of which is connected to the first input of the comparison device 28, with the second input of which the output of the threshold code 27 setter is connected. The output of the operational memory element 22 is connected to the first inputs of the three-input element OR 29 and the two-input element OR 30, the output of the operational element of the memory 23 is connected to the second input of the three-input OR element 29, the output of the comparison device 28 is connected to the third input of the three-input element OR 29 and to the second input of the two-input element OR 30, the output of which is the second output of the signal input unit activating the beacon 1, and the output of the three-input OR 29 is the first output of the signal beacon activation unit 1. If the beacon is equipped with a remote control device 17, its output is connected to the output of the manual button 19 and the input is connected to the first output of the beacon activation signal input unit 1 .

 The time code generator 4 is made in the form of a programmable block forming a code containing information on the number of 15-minute intervals that have arrived since the accident.

 The parallel-to-serial code converter 5 can be made in the form of a shift register. Shaper control voltage 6 can be made in the form of a voltage amplifier.

 Shaper modulating signal 8 generates a common alarm signal "wow-wow", which is a frequency-modulated signal in the frequency range from 300 Hz to 3 kHz.

 The receiver of navigation signals from the GPS system and / or GLONASS 12 contains a receiving antenna.

 As an autonomous power unit, a replaceable cartridge is used, which includes, for example, thionyl chloride lithium batteries with a capacity of 16A / h.

 The remote control 17 contains buttons for changing the operating mode of the beacon and elements of light and sound indication.

 In the emergency beacon (see Fig. 1), the first output of the input unit for activating the signal of the beacon 1 is connected to the input of the switching device 15 of the autonomous power supply unit 14, the output of which is connected to the inputs of the time code generator 4, the constant 3 blocks and the main memory 13, the modulator signal 8 and power inputs of the transmitters of satellite 7 and drive 9 channels, the second output of the signal beacon activation signal input unit 1 is connected to the second input of the adder 2, N outputs of the read-only memory 3 are connected to the first N inputs of the sums torus 2, N outputs of the time code generator 4, are connected to the third N inputs of the adder 2, N outputs of which are connected to N inputs of the parallel code converter to serial 5, the output of which is connected to the input of the control voltage generator 6, the output of which is in turn connected to the input the modulating signal of the transmitter of the satellite channel 7, the output of the driver of the modulating signal 8 is connected to the input of the modulating signal of the transmitter of the drive channel 9, and the outputs of the transmitters of satellite 7 and driving 9 anal connected through duplexer 10 to antenna 11. The receiver output signals from the navigation system Global Positioning System and / or GLONASS 12 is connected to the input memory unit 13, whose output is connected to a fourth input of the adder 2.

 Emergency beacon operates as follows. As a result of the action on the sensors of automatic inclusion of the block 18 or on the manual button 19, or on the sensors of the emergency overload 20 (see figure 2), the signal input unit activating the beacon 1 generates a potential signal for activating the beacon. This signal includes a switching device 15 of the independent power supply unit 14, which starts the permanent memory unit 3, which forms the constant part of the message transmitted by the beacon at a frequency of 406 MHz, the time code generator 4, which counts the time from the moment the radio beacon is activated, the modulating signal generator 8 and supplies power to transmitters of satellite 7 and drive 9 channels, thereby allowing the emission of a signal for a short-range drive of rescue equipment. In this way, periodic alternate operation of the beacon transmitters is organized.

 For the emergency beacon to operate on a satellite channel at a frequency of 406 MHz, a carrier frequency signal is generated in the satellite channel 7 transmitter, the signal from the output of the control voltage former 6 is fed to the modulating signal input of the satellite channel 7 transmitter, from the output of which through the duplexer 10 it enters the antenna 11.

 For the emergency beacon to operate on the drive channel at a frequency of 121.5 MHz, a carrier frequency signal is generated in the transmitter of the drive channel 9, to the input of the modulating signal of which the signal of the driver of the modulating signal 8 is received, and from the output of the transmitter of the drive channel 9, the signal through the duplexer 10 enters the antenna 11 .

 The signal from the receiver of navigation signals 12 is recorded in the block of RAM 13 and is supplied to the fourth input of the adder 2.

 Block input signal activation of the beacon 1 (see Fig. 2) operates as follows.

 When one or more sensors of the automatic switching on of the unit 18 are triggered, a parallel code appears on its output, which arrives at the corresponding address inputs of the programmable read-only memory block 21 and selects information at the address that is recorded in the operational memory element 22 and arrives at the first input of the two-input OR 30 and first input of a three-input OR 29.

 When you press the button 19 manual on or with the remote control 17, information is recorded in the operational element of the memory 23 and is fed to the second input of the three-input OR 29.

 When one or more emergency overload sensors 20 are triggered, the signals are sent to the meters of the amplitude of the emergency overload pulse 24 and the duration of the emergency overload pulse 25, from the outputs of which the signals are fed to the inputs of the calculator 26, where the product of the amplitude and the duration of the emergency overload pulse are calculated, from the output of the calculator 26 the current signal is fed to the first input of the comparison device 28, the second input of which receives a signal from the threshold code 27 setter. If the value of the current signal exceeds the threshold value from the setpoint signal, the output of the comparator 28 appears activation signal that is fed to the second input of the two-input OR 30 and OR trehvhodovogo third input 29, the outputs of which are the first and second output signal input activating one beacon respectively. The signal from the first output of the beacon activation signal input unit 1 is supplied to the switching device 15 of the autonomous power supply unit 14 and to the input of the remote control 17.

 Thus, the emergency beacon provides distress signals and data on aircraft at frequencies of 406 MHz and 121.5 MHz in automatic mode by triggering overload sensors and when you turn on the portable emergency beacon from the remote control manually by the surviving crew members or passengers.

 The industrial applicability of the emergency beacon is ensured by high demand at home and abroad due to the lack of market saturation with this type of product.

 The proposed device will reduce the likelihood of false positives, increase the accuracy of determining the coordinates of the disaster site and reduce the time of searching for disaster victims while simplifying the manufacture of the beacon, reducing the cost and increasing the reliability of its operation, including due to the implementation of the majority of the blocks of the beacon based on the microprocessor.

Claims (4)

 1. An emergency beacon containing an input block for activating a radio beacon, the second output of which is connected to the second input of the adder, a permanent memory unit, N outputs of which are connected to the first N inputs of the adder, a time code generator, N outputs of which are connected to the third N inputs of the adder, N the outputs of which are connected to the N inputs of the parallel code to serial converter, the output of which is connected to the input of the driver of the control voltage, the output of which, in turn, is connected to the input of the modulating drove the satellite channel transmitter, the modulating signal generator, the output of which is connected to the modulating signal input of the drive channel transmitter, and the outputs of the satellite and drive channel transmitters through a duplexer are connected to the antenna, characterized in that it is equipped with a navigation signal receiver from the Global Positioning System and / or GLONASS, random access memory blocks and an autonomous power supply unit with a switching device, the signal beacon activation signal input unit is equipped with an emergency signal conditioning unit overload, the output of the navigation signal receiver through the RAM block is connected to the fourth adder input, the input of the autonomous power supply unit with the switching device is connected to the first output of the radio beacon activation signal input unit, and the outputs are connected to the inputs of the time code generator, the constant and random access memory blocks, the modulator signal and power inputs of transmitters of satellite and drive channels.  2. The emergency beacon according to claim 1, characterized in that the beacon activation signal input unit, adder, read-only memory, time code generator, parallel code to serial converter, control voltage generator, modulating signal generator and random access memory are based on a microprocessor .  3. The emergency beacon according to claim 1 or 2, characterized in that it is equipped with a remote control connected to the input unit of the activation signal of the beacon.  4. The emergency beacon according to claim 1, or 2, or 3, characterized in that it is placed in a shockproof and fireproof container.

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