RU2625806C1 - Method of transmission of alarm messages on radio broadcast - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: voice transmitter is used in which the carrier frequency signal of the voice transmitter is modulated, amplified by the modulated signal and transmitted to the radio, and the receiving side receives the modulated signal and demodulates it to receive messages, an auxiliary sinusoidal signal is generated at the transmitting side with a frequency within the range of modulating frequencies used by the voice transmitter, the mentioned auxiliary sinusoidal signal is pre-modulated in series with the message signals, for the formation of which a frequency band substantially narrower than the modulation frequency band of the voice transmitter is used, on the receiving side, reception is performed at a frequency associated with a linear conversion of the carrier frequency of the voice communication transmitter and the frequency of the auxiliary sinusoidal signal, the received signal is filtered in a band defined by a band frequencies of the auxiliary sinusoidal signal, and demodulation of the received signal is performed in accordance with the selected modulation of the auxiliary sinusoidal signal.

EFFECT: increasing the reliability of the transmission of alarm messages.

6 cl, 1 dwg

Description

The invention relates to methods for transmitting alarm messages over the air, in which a voice transmitter is used to transmit alarm messages in the case when the range of conventional voice radio communication is not enough.

Systems that transmit messages are described, for example, in patents RU No. 2074826, B60R 25/00, RU No. 2163871, B60R 25/00, G08C 17/02. However, messaging in known technical solutions involves the use of third-party transmitting devices, such as paging companies. Naturally, such use requires additional costs and, in addition, causes a restriction associated with the limited coverage of the territory of the paging company.

Therefore, it is advisable to refuse the services of third parties and directly transmit messages to the recipient using standard radio equipment. Such a standard, widespread radio equipment is, of course, a voice transmitter. Transmission of messages over the air using a voice transmitter does not have the disadvantages and limitations associated with the use of third-party transmitting devices.

The method of such a transfer has long been known and described in many publications, for example, in the classic monograph by I.S. Gonorovsky "Radio-technical circuits and signals", Textbook for universities, Moscow: Radio and communications, 1986, pp. 7-12.

In this method, on the transmitting side, the carrier signal of the voice transmitter is modulated using successive message signals, the modulated signal is amplified and transmitted to the radio, and on the receiving side, the modulated signal is received and demodulated to receive messages.

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

When transmitting a digital sequence using a voice transmitter, such a source of serial message signals modulating the carrier signal is a modem.

In both cases, the carrier frequency of the voice transmitter is modulated by signals whose spectrum lies in the band from 300 to 3000 Hz.

The carrier frequency modulation 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 FM voice transmitter in a portable transmitter, the transmitter power should not exceed 5 watts. Such parameters provide the opportunity for radio communication at a distance of not more than 4 km between wearable radio stations and not more than 15 km between wearable and stationary radio stations.

In many cases, this method of transmitting messages over the air provides an insufficient range of message transmission. 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.

Of the known methods, the closest in technical essence to the claimed one is the "Method of transmitting messages over the air", according to patent RU No. 2446480, B60R 25/00, G08C 17/02 of 03/31/2011, where the transmitter carrier frequency signal is modulated on the transmitting side voice communication using sequential message signals, amplify the modulated signal and transmit it to the radio, and on the receiving side receive a modulated signal and demodulate it to receive messages, on the transmitting side generate an auxiliary sinusoidal drove with a frequency within the range of modulating frequencies used by the voice transmitter, pre-modulate the specified auxiliary sinusoidal signal with successive message signals, for the formation of which use a frequency band significantly narrower than the baseband of the voice transmitter, the modulated signal is modulated when transmitting the signal carrier frequency of the voice transmitter, while on the receiving side, reception is carried out at those associated with a linear transformation of the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal, filter the received signal in the frequency band determined by the frequency band of the auxiliary sinusoidal signal taking into account its preliminary modulation by successive message signals, and said demodulation of the received signal is performed in accordance with the selected modulation of the auxiliary sinusoidal signal.

This method can significantly increase the transmission range of alarm messages, however, its disadvantage is the complexity of implementation, because the implementation of this method requires the supply of a modulating signal directly to the microphone input of the radio station, which is very inconvenient, because it is necessary to connect through the connector for the remote headset of the radio station. It is also necessary to take into account that different radio stations have different types of connectors for connecting a headset, and many radio stations simply do not have a connector for connecting an external headset. Connecting to the radio station via an additional cable also reduces the speed of transmitting alarm messages. In addition, when transmitting alarm messages, it is necessary to transmit the location coordinates of the transmitting radio station.

The present invention is aimed at simplifying the use of the known method for transmitting alarm messages and increasing the efficiency of its use.

The subject of the invention is a method for transmitting alarm messages over the air, in which the carrier signal of the voice transmitter is modulated using serial message signals on the transmitting side, the modulated signal is amplified and transmitted to the radio, and the modulated signal is received on the receiving side and demodulated to receive messages, an auxiliary sinusoidal signal with a frequency within the range of modulating frequencies used by the transmitter is generated on the transmitting side voice communication, pre-modulate the specified auxiliary sinusoidal signal with successive message signals, for the formation of which use a frequency band substantially narrower than the modulating frequency band of the voice transmitter, on the receiving side, reception is carried out at a frequency associated with a linear conversion of the carrier frequency of the voice transmitter and frequency auxiliary sinusoidal signal, filter the received signal in the frequency band determined by the auxiliary frequency band a sinusoidal signal, taking into account its preliminary modulation by successive message signals, and the aforementioned demodulation of the received signal is performed in accordance with the selected modulation of the auxiliary sinusoidal signal, the transmitter location coordinates are determined on the transmission side, they are converted into a message containing additional auxiliary information that modulates the auxiliary sinusoidal signal, then convert it into an acoustic signal, emit an acoustic signal, receive ayut acoustic signal and produce an acoustic signal inverse conversion into an electrical signal and this signal is modulated carrier signal is voice communication transmitter.

Partial essential features of the proposed method contribute to the solution of the problem:

- as the reception frequency, a frequency equal to the sum of the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal is used;

- the frequency equal to the difference between the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal is used as the reception frequency;

- the reception of the modulated signal is carried out simultaneously according to two algorithms, in one of which the sum of the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal is used as the reception frequency, and in the other, the difference between the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal is used signal, for each technique evaluate the quality of reception and choose a technique with the best quality of reception;

- when using a transmitter with frequency modulation as a voice communication transmitter, the modulation index is set in the range from 1.5 to 2.5 g

- when using a transmitter with amplitude or single-band modulation as a voice communication transmitter, the modulation depth is set close to 100%.

Implementation of the proposed method for transmitting alarm messages over the air is illustrated by the example of the operation of the device, a block diagram of which is shown in Fig. one.

The device contains a panic button 1, consisting of sequentially connected GPS receiver 2, processor 3, amplifier 4 and sound emitter 5, as well as button 6 and a power source 7. Panic button 1 is located at a small distance of 5 ... 10 cm from radio station 8 (transmitter voice radio communication), directly opposite its microphone 9. In the communication zone with the radio station 8 there is a stationary (mobile) radio station 10, to the audio output of which a personal computer 11 is connected.

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 processor 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 the radio station 8, any analogue wearable voice radio station can be used.

As the stationary (mobile) radio station 10, any analog stationary (mobile) voice radio communication station can be used.

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

The method is 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 button 6 is pressed, the signal of which starts the processor 3, which turns on all the nodes of the alarm button 1. When the GPS receiver 2 is turned on, it gives the coordinates of the location of the alarm button 1 to the processor 3. Processor 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, error-correcting coding, etc. At the same time, the processor 3 generates at its output connected to the input dy amplifier 4, the auxiliary sinusoidal signal, for example by using pulse width modulation, followed by filtration with a frequency situated within a baseband frequency range used for voice radio transceiver 8 (300 Hz to 3 kHz ...). The processor 3 modulates the auxiliary sinusoidal signal with previously generated sequential message signals. In this case, 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 sinusoidal signal, any known types of modulation can be used, for example, amplitude, phase or frequency modulations. The modulated auxiliary sinusoidal signal is amplified by amplifier 4 and fed to sound emitter 5 (speaker). Sound emitter 5 generates acoustic sound vibrations with the frequency of the modulated auxiliary signal. The panic button 1 is located at a distance of 5 ... 10 cm from the microphone 9 of the radio station 8.

The radio station 8 is included in the transmission mode, the signal coming from the microphone 9, modulates the carrier frequency of the radio station 8, which is amplified and transmitted to the radio by the radio station 8.

The alarm message transmitted by the radio station 8 is received by the stationary (mobile) radio station 10 and is transmitted to the audio input of the personal computer 11 as an output audio signal. In this case, the reception is carried out at a frequency connected by a linear transformation of the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal, the received signal is filtered in the band frequencies of the auxiliary sinusoidal signal, taking into account its preliminary modulation by successive message signals.

A special program for processing audio signals is installed on the personal computer 11, including filtering the received auxiliary sinusoidal signal, demodulating it in accordance with the selected modulation of the auxiliary sinusoidal signal, highlighting the received information and displaying it on the map in the form of the coordinates of the panic button and its number.

This provides a significantly greater range of transmission of alarm messages than the range when using a radio station 8 and a stationary (mobile) radio station 10 for normal voice radio communication. This is achieved due to the higher sensitivity of the receiving complex, consisting of a stationary (mobile) radio station 10 and a personal computer 11.

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 (I. S. Gonorovsky. Radio engineering circuits and signals, Textbook for high schools, 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 - 1,3806504 (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 (like temperature) are independent of the user, except for the passband Δf.

Thus, a real way to increase the sensitivity of a voice receiver is to reduce bandwidth.

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 air by radio stations of voice radio communication.

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

Since for the modulation of the auxiliary sinusoidal signal in the panic button 1, a sequential message signal with a frequency band substantially narrower than the modulating frequency band of radio station 8 was used when using voice radio communication, the receiving radio path of the stationary (mobile) radio station 10 is also significantly selected 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.

The ratio of the bandwidth of the receiver, designed to receive voice information, to the bandwidth of the receiver, designed to receive the sideband of the spectrum, determines the gain in the 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). At the same time, 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 radio station 8.

Similarly, when using FM modulation radios, two side bands similar to AM 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 .

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.

It can be seen from the above spectra of AM and FM signals that they contain two equally 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 (mobile) radio stations 10 (only one radio station is shown in Fig. 1), one of which is tuned to receive the upper, and the other, respectively, the lower side band, significantly increases the probability of correct reception, since one of the side bands may be hit by noise. In this case, the second stationary (transportable) radio station 10 is connected to the second audio input of the personal computer 11, which runs a program designed to simultaneously process two audio signals and output more reliable results. Moreover, more narrow-band filtering compared to voice radio communication can be carried out both in the stationary (mobile) radio station 10, and using the software of a personal computer 11, for example, when using digital filtering based on the fast Fourier transform.

The simplification of the application of the known method of transmitting alarm messages is achieved due to the fact that the transmission of alarm messages is carried out without using any adapter cables for connecting the panic button to the radio station. In addition, any simpler radio stations without an additional headset jack can be used. Additionally, the speed of transmission of alarm messages is also increased, because Now it is not necessary to connect the source of alarm messages to the microphone input of the radio station using a special cable, but simply bring the alarm button to the microphone of the radio station and turn it on for transmission.

Claims (6)

1. A method for transmitting alarm messages over the air using a voice transmitter, in which the carrier signal of the voice transmitter is modulated using serial message signals on the transmitting side, the modulated signal is amplified and transmitted to the radio, and the modulated signal is received and demodulated on the receiving side with the receipt of messages, an auxiliary sinusoidal signal with a frequency within the range of modulating frequencies is generated on the transmitting side, we use of the voice transmitter, pre-modulate the specified auxiliary sinusoidal signal with successive message signals, for the formation of which they use a frequency band that is significantly narrower than the baseband of the voice transmitter, on the receiving side, reception is carried out at a frequency associated with a linear transformation of the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal, filter the received signal in the frequency band determined by the frequency band from the auxiliary sinusoidal signal, taking into account its preliminary modulation by successive message signals, and the aforementioned demodulation of the received signal is performed in accordance with the selected modulation of the auxiliary sinusoidal signal, characterized in that the transmitter location coordinates are determined on the transmission side, they are converted into a message containing also additional service information which modulate the auxiliary sinusoidal signal, then convert it into an acoustic signal emit an acoustic signal, receive an acoustic signal and reverse-convert the acoustic signal into an electrical signal and modulate the signal with the carrier frequency of the voice transmitter. 2. The method according to p. 1, characterized in that the frequency of reception using a frequency equal to the sum of the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal. 3. The method according to p. 1, characterized in that the frequency of reception using a frequency equal to the difference between the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal. 4. The method according to p. 1, characterized in that on the receiving side the reception of the modulated signal is carried out simultaneously according to two algorithms, in one of which the sum of the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal is used as the reception frequency, and in the other - As the frequency of reception, the difference between the carrier frequency of the voice transmitter and the frequency of the auxiliary sinusoidal signal is used, for each technique, the quality of the reception is evaluated and the technique with the best reception quality is selected. 5. The method according to p. 1, characterized in that when using a transmitter with frequency modulation as a voice communication transmitter, the modulation index is set in the range from 1.5 to 2.5. 6. The method according to p. 1, characterized in that when using a transmitter with amplitude or single-band modulation as a voice communication transmitter, the modulation depth is set close to 100%.

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