RU2271577C1 - Alarm signaling device for counteracting private safety threats - Google Patents

Abstract

FIELD: engineering of equipment for assuring private safety of civilians, can be used for notifying surrounding people and specialized services about necessity to provide emergency help to an individual in emergency situation (bandit attack, heart attack and the like).

SUBSTANCE: device has radio transmitting device carried by user, block for sensing parameters of physical state of threat subject, control button, and serially connected microphone and noise suppression block. Also, device has central microprocessor unit block for analyzing information and synthesizing commands, first Bluetooth module, sound and voice broadcasters and solving block, connected by input to block of indicators, and by output - to voice broadcaster. Inputs of central microprocessor unit block are connected to noise suppression block, solving block and controlling button, and outputs - to first Bluetooth module and sound broadcaster. Radio-transmitting device is made with utilization of cell phone, meant for operation in standard mobile communication network, and second Bluetooth module, connected to signaling input of cell phone and made with possible wireless data exchange with first Bluetooth module. Provided technical result is connected with utilization of modern central microprocessor unit equipment, making it possible to operatively determine character of suddenly appearing threat and generate adequate commands for controlling sound and voice broadcaster to attract attention of surrounding people and scare off potential malefactor, forcing him to abandon previously undertaken cause of action.

EFFECT: higher efficiency.

5 cl, 5 dwg

Description

The invention relates to techniques for ensuring personal safety of citizens and is intended to alert people around and specialized services about the need to provide a person with emergency assistance in an emergency (gangster attack, heart attack, etc.).

Known methods and devices for alarm, which use the so-called "panic button". The term “panic button” refers to a miniature radio transmitter with a control button on its body. The radio transmitter is activated by pressing the control button when there is a danger to a person’s life, health and material assets and, if necessary, call the quick response forces of the corresponding service (private security, rescue, emergency medical service) to it. The radio signal (alarm radio signal) emitted by the "alarm button" is received at the dispatch center of the corresponding service and, after processing and decryption, is displayed as an alarm message indicating the identification signs of the "alarm button" emitting an alarm radio signal. When indicating an alarm message in the indicated dispatch centers, sound and light alarms can be used. Various options for the technical implementation of this method are presented, for example, in the application US No. 2001/0052848, G 08 In 21/00 and in US patent No. 6310539, G 08 In 23/00.

To increase the range of the "panic button" use the transmission of alarm radio signals over a radio relay network and / or over wired telephone channels. So, according to patent RU No. 2184395, G 08 B 25/08, in the event of a dangerous situation, an alarm radio signal is transmitted via a personal radio signal module. The specified alarm radio signal is received at intermediate points connected to telephone lines and distributed in a controlled area, the received alarm radio signal is converted into a corresponding code message and transmitted to a message monitoring and receiving point where the location of the alarm radio source is determined, in accordance with the location of the intermediate points from which the code message arrived.

The same class of technical solutions includes radio channel systems for which the applicant company received patents RU No. 2182028, 60 R 25/10, G 08 B 25/00, RU No. 2201363, 60 R 25/10, G 08 B 25 / 08.

A common drawback of these technical solutions is the complexity of their technical implementation, due to the need for the location on the terrain of intermediate relay points, which is associated with large capital costs and organizational difficulties.

Another significant drawback of the aforementioned technical solutions is their low efficiency in cases of a sudden threat, for example, attacking a person “from around the corner”, tricking him into a car, and then throwing the owner out of the passenger compartment, etc. As a rule, in such cases, the person called hereinafter the user does not have time to use the "panic button".

Technical solutions are aimed at eliminating this drawback, in which, along with the panic button, sensors of changes in the physical state of the user are used, for example, motion sensors, drop sensors, etc., which ensure the automatic supply of an alarm radio signal in the event of threatening situations.

For example, WAIT UP® technology based on the use of a motion sensor (article “Step left, step right - WAIT UP®” in the 12 Volt magazine, No. 2, is used in the automobile security and anti-theft systems commercially available at the applicant plant) 2002, the article "WAIT UP" in the journal "12 Volts", No. 1, 2002, patent RU No. 2160196, 60 R 25/00). The WAIT UP relay blocks engine operation when unauthorized movement of a guarded vehicle begins. The reason for the activation of the WAIT UP relay is the unauthorized movement of the vehicle, including towing it or transporting it in a container by another vehicle.

The motion sensor is built directly into the WAIT UP relay, so the decision to block the movement is made without the participation of the central control unit of the anti-theft alarm system.

The well-known personal radio alarm system “radio button” (SPNK.425624.001 OM), commercially available from Argus-Spectrum, St. Petersburg (certificate of conformity POCC.RU.OC03.В00961) also belongs to this class of systems. Technical documentation is presented on the manufacturer's website www.argus-spectr.ru.

The main field of application of the alarm system of the "panic button" type is the centralized protection of people and real estate. An alarm radio signal is generated by pressing a control button located on the body of the radio transmitting device, as well as when sensors of physical state parameters are triggered:

- drop sensor (option 1);

- displacement sensor - when changing the location of the object radio transmitting device (option 2 - "radio doll");

- in case of violation of the alarm loop at the guarded property (option 3).

The transmitted alarm radio signal arrives at the dispatch center of the quick reaction forces, for example, to the remote control radio receiving device of private security. The alarm radio signal received by the radio receiver is displayed as an alarm message in the processing and display unit and in the remote indicator unit, and also activates the sound signal by the audible alarm unit. From the remote radio receiver, an alarm message can be sent to the central security console - for operational use by the quick reaction forces and to a personal computer - for additional processing and display to interested parties.

An even closer analogue of the present invention is a personal security threat alarm system presented by the applicant company in patent RU No. 2235365, G 08 R 23/00, B 60 R 25/10. This analogue is selected as a prototype of the proposed technical solution. The objective of the prototype is to increase the effectiveness of protection by increasing the speed of response to a sudden threat. To do this, in addition, as one of the sources of the alarm, a loud sound signal is used: a scream or whistle issued by the user.

The prototype consists of wearable and stationary parts.

The wearable part is with the user (in case of a sudden attack on him or a sharp deterioration in well-being). The source of the alarm sound is the user himself. The user is equipped with a microphone, to the output of which a noise reduction unit is connected. The output of the noise reduction unit through the microcontroller is connected to an additional (modulating) input of the radio transmitting device.

A control button is installed on the radio transmitter. It allows you to manually turn on and off the radio transmitter. The control button mechanism is protected against accidental pressing. Another control input of the radio transmitting device is connected to the outputs of the sensors of the parameters of the physical state of the user. In this case, the sensors of the parameters of the physical state of the user are located directly at the user. The fall sensor is designed to turn on the radio transmitting device in cases where an unexpected fall, for example, due to an impact, prevented the user from pressing the control button, and he was in a horizontal position.

The disadvantage of the prototype is the following.

The concept of building such systems is based on the belief that, after an alarm, quick response forces will be able to reach the user faster than their health and material values will be significantly damaged. However, this is not always possible, especially in large cities, where the movement of mobile quick reaction forces is hampered by traffic jams. In addition, due to the lack of means for measuring the user's current location in the wearable button of the panic button, the call of the quick reaction forces may not be useful at all, since the user's exact location remains unknown. In any case, the first time a user who has been attacked or suddenly feels bad will be alone with his threat and will have to seek his own escape (if possible).

These shortcomings of the above systems make us look for alternative ways to counter threats to personal security. One of such ways is the use of technical means to maximize attract the attention of people around him and psychologically influence an attacker in order to scare him away and force him to abandon his original intentions.

The fact is that at the time a crime is committed, it is very important for an attacker to be sure that his actions are not controlled by anyone. Any sharp sound alarms him, and an increased and increasing level of sound alarm over time can lead to a state of panic and a willingness to flee the scene of the crime.

In particular, statistics on apartment robberies in Russia show that in 40-65% of cases (depending on the region), the attackers escaped if at least some siren worked (newspaper "My house is my fortress", No. 1, September 2004 ) One can recall the practice of using an ordinary police whistle when protecting public order.

The indicated idea of psychological impact is the basis of the present invention.

The subject of the invention is a security alarm device for counteracting personal security threats, comprising a user-transmitted radio transmitting device, a block of sensors of physical state parameters of the user, a control button and a microphone and noise reduction unit connected in series, the microprocessor unit for analyzing information and synthesizing commands, the first input of which is introduced connected to the output of the noise reduction unit, the first Bluetooth module, sound and voice sirens and decisive lock, while the radio transmitting device is made using a cell phone designed to work in a standard mobile network, and a second Bluetooth module connected to the signal input of the cell phone and configured to wirelessly exchange data with the first Bluetooth module, the input of which is connected to the radio signal output of the microprocessor unit for information analysis and command synthesis, the input of the decision unit is connected to the output of the sensor unit of the parameters of the physical state of the user, and the output to oromu microprocessor unit input information and commands synthesis assay, the third input coupled with the control button, the audio output of microprocessor unit information analysis and synthesis commands coupled to the input of the siren sound, and voice annunciator input coupled to an output deciding unit.

Particular features of the invention are as follows.

The microprocessor unit for analyzing information and synthesizing commands contains an analyzer of the amplitude-frequency and time parameters of the alarm sound signal and a series-connected analog-to-digital converter (ADC), the input of which is the first input of the microprocessor unit for analyzing information and command synthesis, a control unit, a memory unit, a comparison unit , recognition unit, the second input of which is connected to the second output of the memory unit, and the third input is the third input of the microprocessor information analysis unit and the command line, and the emergency code message generator, the ADC output is connected to the input of the amplitude-frequency and time parameters analyzer of the alarm sound signal, the output of which is connected to the second inputs of the memory unit and the comparison unit, the second input and output of the emergency code message generator are, respectively, the second the input and radio signal output of the microprocessor unit for analyzing information and synthesizing commands, and the output of the recognition unit is the audio output of the microprocessor unit for analyzing information matsii and synthesis teams.

The recognition unit contains a series-connected memory register, the input of which is the first input of the recognition unit, a multiplier, the second input of which is the second input of the recognition unit, an adder and a threshold circuit, the second input and output of which are, respectively, the third input and output of the recognition unit.

The sound siren is made in the form of a series-connected controlled relay and siren, while the input of the controlled relay is the input of a sound siren.

The voice siren is made in the form of a series-connected unit for storing and selecting voice messages and a loudspeaker, and the input of the unit for storing and selecting voice messages is the input of a voice siren.

The objective of the present invention is to provide a security alarm device to counter threats to personal safety, which allows to increase the degree of personal protection of a person in situations associated with the sudden emergence of a threat to life, health and material values, for example, in a gangster attack "from around the corner", an acute heart attack etc.

The technical result achieved is associated with the use of modern microprocessor technology that allows you to quickly assess the nature of a threat that has suddenly arisen and form adequate control commands for sound and voice sirens in order to attract the attention of people around and scare away the attacker, forcing him to abandon his original intentions.

The invention is illustrated in figures 1-5.

Figure 1 presents a structural diagram of a security alarm device to counter threats to personal safety.

Figure 2 presents the structural diagram of a microprocessor unit for information analysis and command synthesis.

Figure 3 presents the structural diagram of the recognition unit.

Figure 4 presents the structural diagram of the sound siren.

Figure 5 presents the structural diagram of a voice siren.

In the drawings of figures 1-5, the following notation is used: 1 - user; 2 - microphone; 3 - block noise reduction; 4 - microprocessor unit for information analysis and command synthesis; 5 - ADC; 6 - analyzer of the amplitude-frequency and time parameters of the alarm sound signal; 7 - control unit; 8 - memory block; 9 - block comparison; 10 - recognition unit; 11 - shaper emergency code message; 12 - sound annunciator; 13 - memory register; 14 - multiplier; 15 - adder; 16 is a threshold circuit; 17 - a cell phone; 18 - second Bluetooth module; 19 - the first Bluetooth module; 20 is a block of sensors of parameters of the physical state of the user; 21 - a crucial unit; 22 - controlled relay; 23 - siren; 24 - control button; 25 - voice annunciator; 26 - block storage and selection of voice messages; 27 - loudspeaker.

The considered security alarm device to counter threats to personal safety (Fig. 1) contains 1:

- a microphone 2 and a noise reduction unit 3 connected in series, the output of which is connected to the first input of the microprocessor unit 4 for information analysis and command synthesis;

- block 20 of the sensors of the parameters of the physical state of the user, connected through the decision block 21 to the second input of the microprocessor unit 4 of information analysis and synthesis of commands, the third input of which is connected to the control button 24;

- a radio transmitting device, made in the form of a cell phone 17, designed to operate in a standard mobile network, to the signal input of which a second Bluetooth module 18 is connected, configured to wirelessly exchange data with the first Bluetooth module 19, the input of which is connected to the signal output microprocessor unit 4 analysis of information and synthesis of commands;

- sound siren 12, the input of which is connected to the sound output of the microprocessor unit 4 for information analysis and synthesis of commands;

- voice annunciator 25, the input of which is connected to the output of the decision block 21.

In the present embodiment, the implementation of the proposed security alarm device to counter threats to personal safety, the microprocessor unit 4 for information analysis and synthesis of commands (figure 2) contains:

- analyzer 6 amplitude-frequency and time parameters of the alarm sound signal;

- serially connected ADC 5, the input of which is the first input of the microprocessor unit 4 for information analysis and command synthesis, control unit 7, memory unit 8, comparison unit 9, recognition unit 10, and emergency code message generator 11.

The output of the ADC 5 is connected to the input of the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal, the output of which is connected to the second inputs of the memory unit 8 and the comparison unit 9. The second input of the emergency code generator 11 and the third input of the recognition unit 10 are, respectively, the second and third inputs of the microprocessor unit 4 for information analysis and command synthesis. In this case, the output of the emergency code message generator 11 and the output of the recognition unit 10 are, respectively, the radio signal and sound outputs of the microprocessor unit 4 for information analysis and command synthesis.

In the indicated embodiment, the construction of the microprocessor unit 4 for information analysis and command synthesis, the recognition unit 10 (Fig. 3) contains the following series-connected components:

- memory register 13, the input of which is the first input of the recognition unit 10;

- a multiplier 14, the second input of which is the second input of the recognition unit 10;

- adder 15;

- threshold circuit 16, the second input and output of which are, respectively, the third input and output of the recognition unit 10.

The siren 12 (figure 4) contains a serially connected controlled relay 22 and a siren 23, while the input of the controlled relay 22 is the input of the sounder 12.

The voice annunciator 25 (Fig. 5) comprises serially connected unit 26 for storing and selecting voice messages and a loudspeaker 27, while the input of unit 26 for storing and selecting voice messages is the input of voice annunciator 25.

The microphone 2, equipped with a noise reduction unit 3, is a typical audio channel, widely used in hands-free devices. In particular, it is part of the REEF HF-100 car kit, which is commercially available by the applicant company (certificate of conformity No. РОСС RU.ME30.B.01281). A similar technical solution is also used in the inventions for patents RU No. 2211159, 60 R 27/00, RU No. 2214933, 60 R 25/00, 60 R 27/00, previously obtained by the applicant company.

The ADC 5, an analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal, a control unit 7, a memory unit 8, a comparison unit 9, a recognition unit 10, which are part of the microprocessor unit 4 for analyzing information and synthesizing commands (FIG. 2 and FIG. 3) and the shaper 11 emergency code messages are made on a single board. The device in question can be used, for example, a highly economical motherboard of a 16-bit microcontroller MSP430F149 manufactured by Texas Instruments (USA), which is a part of the RZ-01 sound recognizer commercially available by the applicant company (for example, 12 Volt magazine, No. 9, 2003, p. 4). Technical information on this instrument is available at www.ti.com from Texas Instruments (USA).

The decision block 21 is a set of threshold circuits, the input of each of which is connected to the output of the corresponding sensor in the block 20 of the sensors of the parameters of the physical state of the user.

Block 20 sensors of parameters of the physical state of the user, sound 12 and voice 25 sirens are typical technical means of fire alarm systems (for example, "Directory of engineering and technical workers and electricians of technical means of security and fire alarms", section 5, Moscow, Ministry of Internal Affairs of Russia, 1997 )

In the inventive device, sensors are included in the block 20 of the sensors of the parameters of the user's physical condition to detect critical health conditions of the user 1 (for example, a state of acute heart failure or severe arrhythmia, which threatens to suddenly stop the heart). For example, a portable miniature cardiograph “Kardis-AS” developed by the applicant company (TU 9441-050-56723727-2004), which is currently undergoing medical tests for compliance with the type of measuring instrument, can be used as one of these sensors.

Cell phone 17, first 19 and second 18 Bluetooth modules are purchased products. In the inventive device, they can be used without significant modifications.

Thus, all the nodes used in the inventive security alarm device to counter threats to personal safety are well known. However, most of these nodes are serially produced by the applicant company. Therefore, the possibility of practical implementation of the claimed device is not in doubt.

Consider a security alarm device to counter threats to personal safety (figure 1) works as follows.

As in the prototype, the source of an alarm sound signal (in the form of a special scream or whistle) is user 1 himself - a person who was attacked by an attacker or suddenly felt bad.

An alarm sound picks up the microphone 2 and converts it into an electrical signal. From the output of the microphone 2, this electrical signal is supplied to the noise canceling unit 3, made, for example, in the form of an operational amplifier with an amplitude-frequency characteristic consistent with the spectrum of the expected electrical signal generated from an alarm sound signal. At the output of the noise reduction unit 3, an analog output signal is generated corresponding to the alarm sound signal given by user 1. The task of the noise reduction unit 3 is to increase the signal-to-noise ratio to provide further digital processing of its analog output signal in the microprocessor unit 4 for information analysis and command synthesis (Fig. 2).

In the embodiment of the microprocessor unit 4 for information analysis and command synthesis shown in the drawing of FIG. 2, the analog output signal of the noise reduction unit 3 is supplied to the ADC 5. The ADC 5 performs an integral assessment of this signal (for example, by level over a certain period of time) and determines the need for its further processing. When this need is identified, the ADC 5 generates a request signal that is sent to the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal and to the control unit 7. After that, the ADC 5 goes into analog-to-digital conversion mode (with the given bit depth and conversion frequency).

The sequence of samples of the digital message code generated at the output of the ADC 5 is supplied to the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal and to the control unit 7. In the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal, the sequence of samples of the digital message code is subjected to:

- spectral transformation, for example, Fast Fourier transform (B. Gold, C. Raider. Digital signal processing, M .: Soviet Radio, 1973, Ch.6);

- threshold processing;

- other special operations to determine a number of stable spectral and temporal parameters of the message (spectrum width, harmonic amplitude ratio, etc.).

Thus, the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal extracts from the sequence of samples of the digital code of the sound message a set of stable parameters. This set must be compared with similar sets obtained when tuning the microprocessor unit 4 for information analysis and command synthesis.

Setting up (training) of the microprocessor unit 4 of information analysis and command synthesis is carried out in a special training mode. The transition to the training mode and exit from it in the normal mode of operation are not the subject of the present invention and are not specifically considered.

In the training mode, reference audio messages are sent to the microphone 2 (for example, loudly pronounced words, a whistle of a certain tonality, etc.). Reference audio messages using a microphone 2 are converted into electrical signals. In block 3 noise reduction for reference signals is an improvement in the signal-to-noise ratio. In the training mode, the request signal is not generated at the output of the ADC 5, and the reference audio message is immediately converted into a sequence of samples of a digital code. Further, the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal extracts from the sequence of samples of the digital code of the reference audio message a predetermined set of stable parameters. This set of stable parameters is supplied to the memory unit 8 and to the comparison unit 9. In the training mode, the control unit 7 sends commands to the corresponding input of the memory unit 8, according to which the obtained set of stable parameters is recorded as one of the sets of reference codes of the amplitude-frequency and time parameters of the alarm sound signal (hereinafter, for brevity, samples). The recording of samples is repeated a predetermined number of times. If necessary, in block 8 of the memory also adjust the set of weights used to recognize the alarm sound. This ends the training mode.

In the process of recognizing an alarm sound signal, as mentioned above, the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal extracts a set of stable parameters from the sequence of samples of the digital sound message code. This set is fed to the first input of the comparison unit 9. And at the request of the ADC 5 to the control unit 7, at the output of the control unit 7, commands are generated that are sent to the memory unit 8 (in which samples and weighting factors are stored). For these commands, sets of samples are supplied from the memory unit 8 to the second input of the comparison unit 9. Since various parameters can affect the result of the correct identification of the alarm sound signal in different ways, the comparison results are weighted and threshold processed in the recognition unit 10 and only after that they are sent to the emergency code message generator 11 and to the input of the sound siren 12.

The recognition method of the audible alarm in the recognition unit 10, shown in figure 3, is as follows.

The results of comparing the given sets of samples (from the memory unit 8) with the measured values of the amplitude-frequency and time parameters of the recognized signal (from the analyzer 6 of the amplitude-frequency and time parameters of the alarm sound signal) are received in the memory register 13, stored for a certain time interval, and then fed to the first input of the multiplier 14. In the multiplier 14, these results are multiplied by the weights coming from the memory unit 8 to the second input of the multiplier 14. The multiplication results are served with Exit multiplier 14 to the input of the adder 15. The adder 15 is determined by the sum of the multiplication results. The resulting amount goes to the first input of the threshold circuit 16, the output of which is the output of the recognition unit 10. In the threshold circuit 16, the resulting amount is compared with the value of the allowable threshold level. If the received sum exceeds the allowable threshold level set in the threshold circuit 16, an impulse is generated, which indicates the recognition of an alarm sound signal.

At the end of the recognition period of the alarm sound signal, the contents of the adder 15 are reset.

In particular, in the serial recognizer of the sound fragment RZ-01, created at the applicant enterprise, the set recognition time of the alarm sound signal is 5 s.

Samples and weights are stored in non-volatile memory of the memory unit 8. As indicated above, their values can be changed in the training mode.

As sound alarms, various sound fragments are used, characterized by high accuracy and stability of reproduction (constant playback speed and spectral composition). With the correct recognition of a given sound fragment, a negative pulse of about one second duration appears at the output of the threshold circuit 16 of the recognition unit 10, which is supplied, in particular, to the emergency code message former 11. At the same time, the emergency code message former 11 switches to the activation mode of the radio transmitting device.

As noted above, a conventional cellular telephone 17 is used as the radio transmitting device in the claimed device, providing stable communication with the dispatch center of the rapid reaction forces (private security and / or ambulance) via a standard mobile network, for example, a GSM network. Information for generating a sent message, for example, an SMS message, is supplied to the signal input of the cellphone 17 from the second Bluetooth module 18. The task of the second Bluetooth module 18 is to provide wireless reception of emergency code messages from the microprocessor unit 4 for information analysis and command synthesis and enter them to the cell phone 17. Emergency code messages in the activation mode of the radio transmitting device are automatically transmitted from the microprocessor unit 4 for information analysis and command synthesis using the first Bluetooth module 19. P In this case, the microprocessor information analysis and command synthesis unit 4 and the first Bluetooth module 19 can, for example, be in the user's pocket, and the second Bluetooth module 18 can be in the user's portfolio or in his belt. In any of these cases, the distance between the first 19 and second 18 Bluetooth modules is quite small (less than one meter), which ensures a stable connection between them.

Having received an emergency code message through the second Bluetooth module 18, the cell phone 17 converts it into a standard message (for example, an SMS message) and transmits it via a mobile cellular network to a dispatch center for quick reaction forces.

In the dispatch center of the rapid reaction forces, the same operations are performed as in the prototype. They are not the subject of the present invention and therefore are not considered in this application.

The purpose of the operations described above, which practically do not differ from similar operations performed in the prototype, is the timely radio notification of the dispatch center of the rapid reaction force about a threat to the user.

Along with these general operations, the proposed device carries out additional actions aimed at solving the problem posed to this invention, namely:

- in the event of a sudden deterioration in the well-being of the user (for example, when a cardiac arrest, loss of consciousness, or when user 1 falls to the ground), the sensor 20 of the parameters of the physical state of the user captures these changes in the state of user 1 and converts them into changes in the corresponding parameters of their output signals ( amplitude, frequency, etc.). The decision block 21 compares the magnitude of the indicated changes with predetermined threshold levels and, based on the totality of the results of these comparisons, generates a command message that carries information about the degree of threat to the health and life of user 1. After that, the corresponding emergency code message is sent to the dispatch center of the rapid reaction forces. In addition, voice messages are generated that are designed to attract the attention of people around that a person has become ill and needs emergency assistance (heart massage, artificial respiration, sending to the nearest hospital, etc.);

- in the event of a sudden gangster attack by attackers and the corresponding reaction of user 1 (screaming, whistling, etc.) by commands coming from the microprocessor unit 4 for analyzing information and command synthesis, the siren 12 emits powerful sound signals designed to deter the attackers and attracting the attention of people around the situation.

The inclusion of a sound siren 12 (figure 4) of a powerful sound signal is carried out by a command received from the output of the threshold circuit 16, which is part of the recognition unit 10. This is a response to a scream or to the user pronouncing certain code words transmitted through the microphone channel “microphone 2 - noise reduction unit 3” to the input of the ADC 5 and recognized by the microprocessor unit 4 for information analysis and command synthesis as alarm messages. The command to turn on the sound siren 12 (Fig. 4) is sent (in the form of a pulse of a certain duration) to the winding of the controlled relay 22 of the sound siren 12. As a result, the contacts (of the relay 22) are closed (or opened), which leads to the siren 23 turning on and giving it a powerful ( about 120 dB) of a sound signal of the notification.

If the threat has passed, the user using the control button 24 can block the audible warning signal generated by the siren 23. Blocking is carried out by applying (using the control button 24) the corresponding blocking pulse to the second input of the threshold circuit 16, which is part of the recognition unit 10. Upon receipt of the specified blocking pulse in the threshold circuit 16, a threshold is set at which the passage of the control signal to the input of the controlled relay 22 of the siren 12 and to the first input of the driver 11 of the emergency code message becomes impossible. Accordingly, the transmission of the emergency code message from the output of the emergency code generator 11 to the input of the first Bluetooth module 19 is also blocked.

Translation of voice messages is carried out using a voice annunciator 25 (Fig. 5) after the corresponding code message has been sent from the output of the decision block 21 to the input of the voice message storage and selection unit 26. If any of the parameters of the physical state of user 1 exceeds a predetermined threshold level, the threshold circuit corresponding to this parameter in the decision block 21 generates an alarm code message transmitted to the input of the voice siren 25. In accordance with this code message, the voice message storage and selection unit 26 selects the appropriate voice message, for example, the phrase “HELP, HEART PRESS” and speaks it using the loudspeaker 27. Thus, thanks to the voice siren 25, pr people on the street, seeing a person lying down, can understand that a person has a heart attack (rather than heavy alcohol intoxication) and give him first aid or take him to the nearest hospital. It can save a person’s life.

At the same time, an alarming code message from the deciding unit 21 is fed to an additional input of the emergency code message former 11, which is part of the microprocessor unit 4 for information analysis and command synthesis. In the emergency code message generator 11, the alarm code message is converted to the Bluetooth emergency code message format. The received emergency code message is transmitted through the first Bluetooth module 19 to the second Bluetooth module 18. From the second Bluetooth module 18, the specified emergency code message is sent to the signal input of the cell phone 17. Cell phone 17 dials the standard mobile cellular network to the dispatch center quick response forces (for example, to an ambulance station) and transmits there (for example, in the form of an SMS message) the specified emergency code message. This allows you to increase the likelihood of timely first aid to a person and often save his life.

Thus, the proposed technical solution allows us to solve the problem - to create a security alarm device to counter threats to personal safety. This device allows you to increase the degree of personal protection of the user in situations related to the sudden occurrence of a threat to his life, health and / or material values (for example, with a gangster attack by an attacker or with an acute heart attack on the street).

The technical result provided is associated with the use of modern microprocessor technology that allows you to quickly assess the nature of a sudden threat and generate adequate control commands for sound and voice sirens in order to scare an attacker and / or attract the attention of people around the situation.

Claims (5)

1. A security alarm device for countering threats to personal safety, comprising a user-transmitted radio transmitting device, a block of sensors for parameters of the user's physical condition, a control button and a microphone and noise reduction unit connected in series, characterized in that a microprocessor unit for analyzing information and synthesizing commands is introduced into it, the first the input of which is connected to the output of the noise reduction unit, the first Bluetooth module, sound and voice sirens and a decision unit, while the radio transmission The device is made using a cell phone designed to work in a standard mobile network and a second Bluetooth module connected to the signal input of the cell phone and configured to wirelessly exchange data with the first Bluetooth module, the input of which is connected to the radio signal output of the microprocessor unit information analysis and command synthesis, the input of the decisive block is connected to the output of the block of sensors of the parameters of the physical state of the user, and the output to the second input of the microprocess a unit of information analysis and synthesis of commands, the third input of which is connected to the control button, while the audio output of the microprocessor information analysis and synthesis of commands is connected to the input of the sounder, and the input of the voice siren is connected to the output of the decision block. 2. The device according to claim 1, characterized in that the microprocessor unit for analyzing information and synthesizing commands contains an analyzer of the amplitude-frequency and time parameters of the alarm sound signal and series-connected analog-to-digital converter, the input of which is the first input of the microprocessor unit for analyzing information and synthesis of commands , control unit, memory unit, comparison unit, recognition unit, the second input of which is connected to the second output of the memory unit, and the third input is the third input of the microprocessor the information analysis and command synthesis unit, and the emergency code message generator, the output of the analog-to-digital converter is connected to the input of the amplitude-frequency and time parameters analyzer of the alarm sound signal, the output of which is connected to the second inputs of the memory unit and the comparison unit, the second input and output of the generator emergency code messages are, respectively, the second input and the radio signal output of the microprocessor unit for information analysis and command synthesis, and the output of the recognition unit It is the audio output of microprocessor information analysis unit and the synthesis commands. 3. The device according to claim 2, characterized in that the recognition unit contains a series-connected memory register, the input of which is the first input of the recognition unit, a multiplier, the second input of which is the second input of the recognition unit, an adder and a threshold circuit, the second input and output of which are respectively, the third input and output of the recognition unit. 4. The device according to claim 1, characterized in that the siren is made in the form of a series-connected controlled relay and siren, while the input of the controlled relay is the input of a sound siren. 5. The device according to claim 1, characterized in that the voice siren is made in the form of a series-connected unit for storing and selecting voice messages and a loudspeaker, while the input unit for storing and selecting voice messages is the input of a voice siren.

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