RU2620322C1 - Alarm location determining system - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: messages are transmitted to the base radio station using a radio contact objective radio station and an alarm button. The apparatus comprises an alarm button, which includes a control button connected to the first input of the alarm message shaper, GPS receiver connected to a second input of the alarm messages shaper, and object radio station, fixed radio station configured to receive alarm messages from object station by radio, a personal computer, the input of which is connected to the audio output of fixed radio stations; in structure of alarm button, sequentially introduced, amplifier and acoustical radiator, amplifier input is connected to the output of alarm message shaper, and a power source, connected with all alarm button elements, are included, wherein the acoustical radiator is located in close proximity to the microphone of object radio station; output signal of alarm messages shaper is formed on subcarrier frequency f in the frequency range of 300…3000 Hz, a stationary radio station is tuned to the frequencies F+f or the frequency F-f, where F is object radio station transmission carrier frequency.

EFFECT: increased system efficiency.

2 cl, 1 dwg

Description

The invention relates to devices for transmitting alarm messages over the air. Messages are transmitted to the base station using the object radio station of voice communication and the panic button.

The well-known “Alarm notification and location system”, patent RU No. 2259595, 10.21.2004, G08B 25/12, containing a GPS module and a subscriber device placed at the subscriber, which includes the first Bluetooth module and a GSM phone, including a microprocessor configured to exchange data with the first Bluetooth module, as well as a display connected to the microprocessor and an interface and a transceiver module connected to the microprocessor, capable of two-way data exchange via a standard communication and data network with the provider’s equipment associated with a dispatch center configured to interact with response forces and means and with the ability to turn on external alarm devices, a panic button with a second Bluetooth module is hidden to the subscriber, and the GPS module is an autonomous wearable device equipped with a third Bluetooth module.

The disadvantage of this device is the limited coverage area - it can only be used in the coverage area of stationary networks of GSM-telephone radio communications.

The well-known “Alarm notification and location system”, patent RU No. 2341826, 12/11/2006, G08B 25/12, containing a GPS module and a subscriber unit located at the subscriber, including an alarm button and a transceiver module and connected through the base station to the control room the center, configured to determine the location of the subscriber according to the coordinates measured using the GPS module, as well as with the ability to interact with the forces and means of reaction and the inclusion of external alarm devices, while the GPS module is in triplets to the subscriber unit, the subscriber unit comprises a balloon filled with gas, such as helium, and thus has an opportunity to rise to the height for direct radio base station.

The known device can provide the transmission of alarm messages outside the coverage area of stationary networks of GSM-telephone radio communications. Its disadvantage is the use of a balloon, which is technically quite difficult and difficult to do in difficult weather conditions, for example, in strong winds.

Of the known devices, the closest in technical essence to the claimed device is the “Personal Security Threat Alarm System”, patent RU No. 2288508, 01/18/2006, G08B 25/10, containing a wearable and / or transportable control button connected to the first the input of the shaper of the alarm message, the first output of which is connected to the input of the object radio transmitting device, a microphone and a noise reduction unit connected in series, as well as a remote control radio receiver set in the central security station A device configured to receive alarm messages from the object radio transmitter, a central monitoring console and an audio and / or light indication unit, the inputs of which are connected to the output of the radio receiver, a global satellite navigation system and a shot sound recognition unit, which is connected between the output of the noise reduction unit and the second input of the shaper of the alarm message, the third input of which is connected to the output of the receiver of the global satellite system navigation, the control input of which is connected to the second output of the alarm driver.

The disadvantage of this technical solution, chosen as a prototype, is the limited transmission range of alarm messages, because, as a rule, the alarm buttons try to make small dimensions, which does not allow placing an effective antenna in these dimensions, and a sufficiently powerful transmitter with a powerful battery. A small transmitter power and an ineffective antenna significantly reduce the range of radio communications.

The objective of the invention is to increase the transmission range of alarm messages and location. This is achieved by using conventional voice radio stations that the user already has for transmitting alarm messages and locations, which, as a rule, have a sufficiently high power (up to 5 W), a good antenna and a powerful battery, and also through the transmission of a conventional voice radio station through the tract formed narrowband message.

This goal is achieved by the fact that in a known device containing an alarm button, which includes a control button connected to the first input of the alarm driver, a GPS receiver connected to the second input of the alarm driver, as well as an object radio station, a stationary radio station, configured to receiving over the air of alarm messages from an object radio station, a personal computer, the audio input of which is connected to the audio output of a stationary radio station, is an alarm of the button, the amplifier and the sound emitter are connected in series, the amplifier input is connected to the output of the alarm driver, and the power source is connected to all elements of the alarm button, the sound transmitter is located in the immediate vicinity of the microphone of the object radio station, the output signal of the alarm driver is generated on subcarrier frequency f in the frequency range 300 ... 3000 Hz, the stationary radio station tunes to the frequency F + f or to the frequency F - f, where F is the carrier h Frequency of transmission of an object radio station.

The solution to the problem contributes to the private essential feature of the proposed technical solution:

- a second stationary radio station has been introduced, configured to receive alarm messages from the object radio station, the audio output of which is connected to the second audio input of a personal computer, the first stationary radio station being tuned to frequency F + f, and the second stationary radio station being tuned to frequency F - f, where F is the carrier frequency of the transmission of the object radio station, f is the subcarrier frequency of the object radio station.

The operation of the proposed alarm system and location is illustrated by the example of the operation of the device, a block diagram of which is shown in Fig. one.

The device contains an alarm button 1, consisting of a series-connected GPS receiver 2, an alarm driver 3, an amplifier 4 and a sound emitter 5, as well as a button 6 and a power source 7. The alarm button 1 is located at a small distance of 5 ... 10 cm from the object radio station 8 (voice-activated radio transmitter), directly opposite its microphone 9. In the communication zone with the radio station 8 there are stationary radio stations 10 and 12, to the audio outputs of which a personal computer 11 is connected.

The device operates as follows. In the initial state, all nodes of the panic button 1 are connected to the power source 7 (battery), but are in the off state. If it is necessary to transmit an alarm message, the control button 6 is pressed, the signal of which triggers the alarm driver 3, which turns on all the nodes of the alarm button 1. When the GPS receiver 2 is turned on, it issues the coordinates of the location of the alarm button 1 to the driver of the alarm message 1. Alarm driver 3 converts them into a serial message signal containing, in addition to coordinates, additional service information, for example, the registration number of the panic button 1, e coding, etc. At the same time, the alarm driver 3 generates at its output connected to the input of the amplifier 4 an auxiliary subcarrier signal, for example, by using pulse width modulation followed by filtering, with a frequency located inside the range of modulating frequencies used by radio station 8 for voice radio communication (300 Hz ... 3 kHz). The alarm driver 3 modulates the auxiliary subcarrier signal with previously generated successive message signals. Moreover, the spectrum of the generated serial message signal is set much narrower than the band of modulating frequencies of the radio 8. When modulating the auxiliary signal of the subcarrier frequency, any known types of modulation can be used, for example, amplitude, phase, or frequency modulations. The modulated auxiliary signal of the subcarrier frequency is amplified by the amplifier 4 and is supplied to the sound emitter 5 (speaker). The sound emitter 5 generates acoustic sound waves with the frequency of the modulated subcarrier frequency signal. The panic button 1 is located at a distance of 5 ... 10 cm from the microphone 9 of the object radio station 8.

The object radio station 8 is included in the transmission mode, the signal coming from the microphone 9 modulates it, and the modulated signal at the carrier frequency F is transmitted to the radio air by the object radio station 8.

An alarm message transmitted by the object radio station 8 is received by the stationary radio stations 10 and 12, and in the form of an output audio signal from their outputs is fed to the audio inputs of the personal computer 11. In this case, the stationary radio station 10 is tuned to the frequency F + f, and the stationary radio station 12 is tuned to the frequency F - f where F is the carrier frequency of the transmission of the object radio station 8, f is the frequency of the auxiliary signal subcarrier frequency of the object radio station.

A special program is installed on the personal computer 11 for separate processing of two incoming audio signals, including filtering the received auxiliary subcarrier signals (for example, using fast Fourier transform methods), demodulating them in accordance with the selected modulation of the auxiliary subcarrier frequency signal, extracting the received information, and its display on the map in the form of coordinates of the panic button and its number, with automatic selection of more reliable data from the accepted.

When transmitting voice messages, the source of the message signals modulating the carrier signal of the object transmitter 8 is a microphone 9.

The panic button 1 can be made in the form of a small keychain with a control button 6.

As the GPS receiver 2, the corresponding module can be used.

As the shaper of the alarm message 3 can be used a microprocessor, with appropriate software.

As amplifier 4, a simple transistor power amplifier can be used.

As a sound emitter 5, any miniature speaker with a power of 5 ... 10 mW can be used.

As an object radio station 8, any wearable voice radio station can be used.

As stationary radio stations 10 and 12, any stationary voice radio communication stations can be used.

As a personal computer 11, any computer, laptop or tablet having audio inputs and the ability to install special software can be used.

The carrier frequency of the voice transmitter is modulated by signals, the spectrum of which, as a rule, lies in the band from 300 to 3000 Hz.

The carrier frequency modulation of analogue radio stations is carried out, as a rule, by the methods of frequency (FM) or amplitude modulation (AM, SSB).

The communication range for any radio channel is determined mainly by the transmitter power and receiver sensitivity. In this case, the receiver bandwidth must be at least the width of the spectrum of the transmitter signal.

For example, when using an ordinary portable FM radio station as an object radio station 8, the power of the communication transmitter does not exceed 5 watts. Such parameters provide the opportunity for radio communication at a distance of not more than 5 km between wearable radio stations and not more than 15 km between wearable and stationary radio stations.

This method of voice transmission of messages over the air provides an insufficient transmission range of messages. Often, in emergency situations, it is necessary to transmit an alarm message to a much greater distance when normal voice radio communication is no longer working.

This is achieved due to the higher sensitivity of the receiving complex, consisting of stationary radio stations 10 and 12 and a personal computer 11, as well as greater power used object radio stations 8.

So, the sensitivity of any receiver is determined by the minimum level S of the signal, distinguishable at the noise level. From radio engineering it is known (IS Gonorovsky "Radio Engineering Circuits and Signals", Textbook for Universities, Moscow, "Radio and Communications", 1986) that the value of S can be calculated by the formula, a generalized form of which can be represented as follows:

S = N⋅ (F-1) kT ₀ ⋅Δf,

where N is a constant coefficient - the signal-to-noise ratio at the input of the receiver, which must be ensured when receiving a signal (for a code signal, this value should be in the range from 5 to 10 dB, for voice communication this value is set to 12 dB);

F is the noise figure of the receiver;

k is the Boltzmann constant - 1,380,604 (24) ⋅10 ^-23 J / K;

T ₀ - ambient temperature (in degrees Kelvin);

Δf is the receiver bandwidth.

In this formula, all components are constant, or (as a temperature) are independent of the user, except for the passband Δf.

Thus, the real way to increase the sensitivity of the receiver is to reduce the bandwidth of the receiver. The noise of the receiver is close to white noise. Therefore, the intensity of the receiver noise floor is directly proportional to the frequency band selected for receiving messages. And the narrower the frequency band, the less noise power in this frequency band and the less signal power is required so that it is distinguishable from the background noise of the receiver.

Therefore, a significant increase in the range of message reception can be achieved with a significant reduction in the frequency band of the receiver, which is done because the spectrum of the transmitted message is chosen much narrower than the frequency band occupied on the radio by voice radio communication stations (10 ... 15 kHz).

When using amplitude (AM) or frequency (FM) modulation in voice radio stations, the radio spectrum contains two identically modeled sidebands. The receiver of the stationary radio station 10 is tuned to receive the upper or lower sideband of the frequency spectrum of the signal transmitted by the object radio station 8.

Since for the modulation of the auxiliary signal of the subcarrier frequency in the panic button 1, a sequential message signal with a frequency band substantially narrower than the modulating frequency band of the object radio station 8 was used when using voice communication, the receiving radio path of the stationary radio stations 10 and 12 is also selected significantly narrower than with conventional voice radio communication, due to which an increase in the range of radio communication is achieved, compared with conventional voice radio communication. At the same time, more narrow-band filtering can be carried out both in the stationary radio stations 10 and 12 themselves, by means of the subsequent digital filtering when processing signals by a personal computer 11.

The ratio of the bandwidth of the receiver, designed to receive voice information, to the bandwidth of the receiver, designed to receive part of the sideband of the spectrum of the modulated signal determines the gain in sensitivity of the receiver.

For example, when generating a message at a speed of 25 bit / s and using AM, the spectrum width of the modulated sideband is about 50 Hz. To receive such a signal, the receiver band can be reduced to 100 Hz. The resulting gain in sensitivity N will be

N = 0.25 × 10000 Hz / 100 Hz = 25,

here the receiver bandwidth in conventional voice communication is taken to be 10,000 Hz.

It is known that the range of radio communications (in free space) is inversely proportional to the square root of the sensitivity of the receiver. Since the square root of 25 is 5, the use of the proposed method allows to increase the transmission range of an alarm message up to 5 times, compared with the transmission of alarm messages through radio stations of ordinary voice radio communication (in direct visibility). Moreover, to ensure maximum sideband power during AM modulation, the modulation depth should be close to 100%, which is ensured by placing the panic button 1 at a small distance (5 ... 10 cm) from the microphone 9 of the object radio station 8.

Similarly, when using FM radio stations for voice communications, two side frequency bands are also formed.

The spectrum of the FM signal depends on the frequency modulation index m. In particular, with m = 2, the sidebands have maximum energy. Therefore, from the point of view of achieving the maximum effect provided by the claimed method, the optimal frequency modulation index is about 2 (actually from 1.5 to 2.5) - in this case, the carrier is significantly suppressed and about 50% of all power is concentrated in two side bands of the modulated signal that is ensured by placing the panic button 1 at a small distance (5 ... 10 cm) from the microphone 9 of the object radio station 8.

If we discard the lateral components of higher orders, the spectrum of the FM signal becomes very similar to the spectrum of the AM signal, and, therefore, all of the above for AM signals is also true for FM signals.

From the above spectra of AM and FM signals it can be seen that they contain two identically modulated sidebands that can be received by two identical and independent receivers (the spectrum of one side will be inverse with respect to the spectrum of the other side). Reception by two independent stationary radio stations 10 and 12, one of which is tuned to receive the upper, and the other, respectively, the lower side band, significantly increases the likelihood of correct reception, since one of the side bands can be affected by interference. On a personal computer 11, a program is launched that is designed to simultaneously process two audio signals and display more reliable results on a monitor screen.

In order to simplify, it is possible to use only one stationary radio station 10 or 12, which will lead to some decrease in the reliability of reception, due to the reception of only one side band of the radio signal of the object radio station 8.

The goal - to increase the transmission range of alarm messages and location is achieved by using for the transmission of alarm messages and the location of conventional voice radios having a sufficiently high power (up to 5 W), a good antenna and a powerful battery, and also due to the fact that through the normal A specially formed narrow-band message on a subcarrier frequency is transmitted to a voice radio station, which is filtered and processed in a special way on the receiving side. The real gain in increasing the range of radio communications can reach 3 ... 5 or more times.

A narrow-band message is formed in the form of sound using the panic button, which can be made in the form of a small keychain and which is simply brought up to the microphone included in the transmission of the object radio station. In this case, any conventional analog radio station for voice radio communication can be used, without any alteration. The use of such panic buttons, together with conventional radio stations, is relevant for groups working in places of natural and technological disasters, where there is no cellular radio communication, and the range of ordinary radio stations may not be enough.

Claims (2)

1. The alarm system and positioning, containing an alarm button, which includes a control button connected to the first input of the shaper of the alarm message, a GPS receiver connected to the second input of the shaper of the alarm message, as well as an object radio station, a stationary radio station configured to receive on the air of alarm messages from the object radio station, a personal computer, the audio input of which is connected to the audio output of a stationary radio station, differing in we note that the amplifier and the sound emitter are sequentially connected to the alarm button, the amplifier input is connected to the output of the alarm driver, and the power source is connected to all elements of the alarm button, and the sound emitter is located in close proximity to the microphone of the object radio station, the output signal the shaper of the alarm message is formed on the subcarrier frequency f in the frequency range 300 ... 3000 Hz, the stationary radio station tunes to the frequency F + f or often that F-f, where F is the carrier frequency of the transmission of the object radio station. 2. The device according to claim 1, characterized in that a second stationary radio station is introduced into it, configured to receive alarm messages from the object radio station, the audio output of which is connected to the second audio input of a personal computer, the first stationary radio station being tuned to the frequency F + f and the second stationary radio station tunes to the frequency Ff, where F is the carrier frequency of the transmission of the object radio station, f is the subcarrier frequency of the object radio station.

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