RU2747458C1 - Method for illumination of territory of spatially oriented object by modular light fixtures and autonomous intelligent information system for implementation thereof - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical engineering, namely to illumination control systems, and is intended for cost-efficient autonomous illumination of residential, public, industrial areas, roads, including automobile roads, and other transport infrastructure objects. The proposed method for illumination of the territory of a spatially oriented object with modular light fixtures and an autonomous intelligent information illumination system for implementation thereof involves uniform distribution and installation of light fixtures on the territory of a spatially oriented object with connection thereof to the outdoor electrical lighting network; the following recording by each of the fixtures of complete information about the illumination area thereof depending on the time of day and the weather conditions, namely: illumination intensity thereof, fires, smoke generation and natural disasters, as well as incoming and/or outgoing moving objects; analysis of this recorded information and making an independent decision based thereon on establishing for the light fixture the illumination intensity of the illumination area thereof and the corresponding value of light intensity thereof and the following adjustment thereof in the fixture. Additionally, after each light fixture sets the illumination intensity level thereof requests to send information about the decisions made to set the illumination level of the illumination areas of other light fixtures and the corresponding values of the light intensity level thereof are formed in each of the fixtures, and after these requests are formed they are sent to other light fixtures located in the same activity radius and in response the requested information is received from these other light fixtures, analyzed by comparing the illumination level set in the illumination area of the light fixture and the corresponding level of the light intensity thereof with the received similar information from other light fixtures, and based thereon an independent decision is made on adjusting or leaving unchanged the illumination intensity in the illumination area of the light fixture, depending on the time of day and weather conditions, and adjusting or leaving unchanged the corresponding light intensity level of the light fixture. The previously set light intensity level of the light fixture is then adjusted or left unchanged and the response is sent to other light fixtures requesting information on adjusting or leaving unchanged the light intensity level in the illumination area of the light fixture, while all responses received from other light fixtures located in the same communication signal range thereof are retransmitted, thus repeatedly interconnecting all the light fixtures within the same communication signal range, and thus forming one of local illumination networks interconnected multiple times from all the light fixtures located in the same communication signal range, wherein the network is part of a single self-regulated autonomous intelligent information illumination system that completely covers the entire territory from the first to the last light fixture, the viability and integrity whereof is constantly maintained by multiple overlapping with proportional relayed communication signals between the light fixtures of each formed local network.

EFFECT: accelerated decision-making on regulation of the light flow of each light fixture of the system by providing each of the light fixtures located within the same communication signal range with management functions in forming the local illumination network thereof, wherein the network is one of the parts of a single self-regulating autonomous intelligent information illumination system covering the entire territory from the first to the last light fixture, the viability and integrity whereof is constantly maintained by multiple overlapping with proportional relayed communication signals between the light fixtures thereof.

12 cl, 4 dwg

Description

The invention relates to the field of electrical engineering, namely to lighting control systems, and is intended for economical autonomous lighting of residential, public, industrial areas, roads, including automobile and other transport infrastructure facilities.

Currently, there are different ways to illuminate the territory of a spatially oriented object with modular lamps and intelligent information lighting systems for their implementation.

There is a method of lighting the territory of a spatially-oriented object with modular lamps and an automated lighting system controlled centrally from a remote center for its implementation, regulating street lighting and solving the problem of energy saving, ensuring uniform lighting when the automated system goes into energy-saving or standby "night" mode, as well as the possibility automatic two-stage increase in the luminous flux of each luminaire on the road section to the normalized level when the vehicle approaches this illuminated section, maintaining this level for the period of vehicle movement on the section in the conditions of existing three-phase power supply systems, and independent switching of the luminaires to full luminous flux when the weather deteriorates conditions: rain, snowfall, fog and ice, on a section of the road remote from the control point, which improves road safety conditions. In addition, this known lighting method and the system for its implementation provide a two-stage backup of the luminous flux of the luminaire in the event of failure of one or two drivers and protection of luminaires from exceeding the permissible outdoor temperature, reduce the cost of modernizing the lighting system, because The wiring diagram of street lighting lines in the conditions of existing automated outdoor lighting control systems does not change (Patent for invention of the Russian Federation No. 2453761, publ. 20.06.2012, Bul. No. 17).

The disadvantage of this known method of lighting modular lamps and the known system for its implementation is their unreliability, due to the fact that the energy-saving mode in this lighting system is set by centralized disconnection of individual phases feeding a group of lamps through separate communication lines placed on the lamp supports, cluttering them ... In addition, the use of a three-phase network requires expensive equipment and costs for its safety due to the supply of high voltage and possible phase imbalance. At the same time, another disadvantage of this known lighting method and system for its implementation is the control of lighting of the luminaires from a remote center and the impossibility of establishing communication between the luminaires without using such control.

Closest to the proposed invention is a method of illuminating the territory of a spatially oriented object with modular lamps, which provides for the uniform distribution and installation of each lamp of the lighting system in the territory of a spatially oriented object with its connection to the outdoor lighting network; the subsequent fixation by each of them of complete information about the zone of their illumination, depending on the time of day and weather conditions, namely: its illumination, fires, smoke, and various natural disasters, as well as about the approach and / or distance of moving objects; he analyzes this recorded information and, on its basis, makes an independent decision to establish the level of illumination of the zone of its illumination, depending on the time of day and weather conditions and the corresponding value of the level of intensity of its light, and then its adjustment in the lamp (Patent for invention of the Russian Federation No. 2554073 , publ. 04/27/2014, bull. No. 12).

From the same source, the closest to the proposed invention is known intelligent information system for lighting the territory of a spatially oriented object with modular lamps, containing at least two supports located along the border of the illuminated area, for example, in the form of lamp posts, each of which has its own a luminaire with its own unique identifier, its own illuminator and its own connected structural network of nodes: with a power supply module connected to the outdoor lighting network; with at least one video camera that records in its field of view and the level of illumination, and fire, and smoke, and various natural disasters, as well as the approach or removal of moving objects; with a control unit for the intensity of illumination of the illuminator, which ensures the setting of the current value of the intensity of its light; with a communication module with its own radio modem, which generates a digital signal with its own coverage area, identical to the digital signals of the radio modems of the communication modules of other luminaires of the system; with an information processing module that collects and analyzes information received from the associated nodes of its luminaire, and on its basis a decision to establish the illumination level in the illumination zone of its luminaire, depending on the time of day and weather conditions and the current value corresponding to it the level of light intensity of the illuminator of its lamp.

These closest to the claimed invention technical solutions, namely: a method of lighting the territory of a spatially oriented object with modular lamps and an intelligent information system for its implementation are more reliable compared to the known above solutions: a method of illuminating the territory of a spatially oriented object with modular lamps and a lighting system for its implementation, because to power their network, they use a single-phase network that does not require expensive equipment and costs for their safety due to the connection of a lower voltage of 220 V. In addition, this method of lighting and the system for its implementation allows you to monitor and regulate lighting near the luminaire poles depending on the general illumination of the environment and road conditions. At the same time, the used video camera of each luminaire of the system constantly measures the level of illumination near its support and transmits this information to its information processing module, which, in turn, sends it to the Control Center, which analyzes the information received from all lamps and their sensors, processes it and sends it in the form of a signal indicating a sufficient illumination threshold near the lamp support to its information processing module. The signal received by the information processing module of each luminaire is transmitted to the luminaire illumination control processing unit, which analyzes the received information about the current illumination level near the luminaire support, depending on the time of day and weather conditions, determines the value of the light intensity level according to which the luminaire should be adjusted , and sends a corresponding signal to the lighting control unit of the luminaire, which adjusts the light intensity of its luminaire or leaves it the same. When an object appears in the video camera's viewing area, it signals this to the information processing module of its luminaire, which first processes this information, and then sends the processing result to the remote control center and to the information processing modules of neighboring luminaires, which, in turn, process the information they received, taking into account the actual illumination near the luminaire support, and send their signals to their lighting control units to adjust it as needed. Thus, the illumination of each luminaire of the lighting system can change during the day depending on the illumination of the environment and the traffic situation near the luminaire.

The disadvantage of these closest to the claimed invention method of illuminating the territory of a spatially oriented object with modular lamps and an intelligent information system for its implementation is that the control of the illumination of each lamp, which ensures its energy-saving mode and the entire lighting system as a whole, is assigned to a remote control center , which entails a decrease in the speed of decision-making on the regulation of the luminous flux of each luminaire in the system - the main criterion of the lighting system, characterizing the safety of its use and reliability. In addition, the communication channel with the remote center in this system is controlled by a third party, for example, a telecom operator, which can lead to a complete shutdown of the entire lighting system from the remote center. Moreover, the operation of transmitting the luminaire signals to the remote control center requires a monthly subscription fee for this action. At the same time, the lighting network formed on the basis of street lighting elements does not use a communication channel that organizes access to the Internet, which does not allow ensuring the reliability and energy efficiency of communication between the luminaires of the system.

As a result, these disadvantages do not allow ensuring the safety, reliability and energy efficiency of this lighting method and the intelligent information system for its implementation.

The purpose of the present invention is to create a safe, reliable and energy-efficient way to illuminate the territory of a spatially oriented object with modular lamps, embodied in a safe, reliable and energy-efficient autonomous intelligent information system for its implementation.

The technical result of the proposed invention is to accelerate the decision-making on the regulation of the luminous flux of each luminaire of the system by endowing each of them, located within the same range of their communication signals, with management functions for the formation by them of their local lighting network, which is one of the parts of a single self-regulating autonomous intelligent a lighting information system covering the entire territory from the first to the last luminaire, the viability and integrity of which is constantly maintained by the repeated imposition of proportionate relayed communication signals between its luminaires.

The specified technical result is achieved by the fact that in the method of illuminating the territory of a spatially-oriented object with modular lamps, which provides for the uniform distribution and installation of lamps over the territory of a spatially-oriented object with its connection to the outdoor lighting network; the subsequent recording by each of them of complete information about their lighting zone, depending on the time of day and weather conditions, its illumination, fires, smoke and natural disasters, as well as the approximations and / or distances of moving objects; analysis of this recorded information and making on its basis an independent decision to establish the illumination level of its illumination zone in your luminaire, and then adjust it in the luminaire, ... additionally, after each luminaire sets the intensity level of its illumination, they begin to form in each of them requests for sending to his address information about the decisions made to establish the illumination level of the lighting zones of other lamps and the corresponding values of the intensity level of their light, and after they form requests, they are sent to other lamps located in the same range, and in response they receive the requested ones from these other lamps information, analyze them, comparing their level of illumination set in the lighting zone of their lamp and the corresponding level of intensity of its light with the received similar information from other lamps, and make an independent decision on adjusting or leaving without changes in the illumination level in the illumination zone of your lamp, depending on the time of day and weather conditions, and adjusting or leaving without changing the corresponding level of light intensity of your lamp, and then sending their response to other luminaires requesting information about adjusting or leaving without changing the level of light intensity in lighting zone of your luminaire, together with the retransmission of all responses received from other luminaires located within the same range of their communication signals, thus repeatedly interconnecting all the luminaires within the same range of their communication signals, and thereby forming, of all these luminaires that are within the same range of their communication signals, one of the multiply interconnected local lighting networks, which is part of a single self-regulating autonomous intelligent information lighting system that completely covers the entire territory from the first to the last of a single luminaire, the viability and integrity of which is constantly maintained by the repeated imposition of commensurate relayed communication signals between the luminaires of each formed local network.

For registration of persons who have appeared in the lighting zone of each lamp, their authorization is carried out.

The specified technical result is also achieved by the fact that an autonomous intelligent information system for lighting the territory of a spatially oriented object with modular lamps, containing at least two supports located along the border of the illuminated area, for example, in the form of lamp posts, each of which has its own lamp with its corresponding identifier for its ordinal number, its own illuminator and its associated structural network of nodes: with a power supply module connected to the outdoor lighting network; with at least one video camera, recording in its field of view and the level of illumination, and fire, and smoke, and natural disasters, as well as the approach or removal of moving objects; with a control unit for the intensity of illumination of the illuminator, which ensures the setting of the current value of the intensity of its light; with a communication module with its own radio modem, which generates a digital communication signal with its own coverage area, identical to the digital signals of the radio modems of the communication modules of other luminaires of the system; with an information processing module that collects and analyzes information received from the associated nodes of its lamp, and on its basis a decision to establish the illumination level in the lighting zone of its lamp, depending on the time of day and weather conditions, ... the communication module of each the luminaire of the system is connected by feedback to the corresponding equipment of the communication modules of other luminaires of the system, which are in the same range of their communication signals, while it is additionally equipped with a radio module with the function of receiving and transmitting communication signals over the local and / or global Internet network connected with its radio modem, and the radio modem of the communication module itself is equipped with a signal retransmission function and its information processing module is equipped with its own control unit, which forms its own local lighting networks from the lighting system lamps located in the same range of their communication signals, which are one of the multiply interconnected networks of a single self a regulated autonomous intelligent information system of lighting, the viability and integrity of which is constantly supported by the multiple imposition of commensurate relayed communication signals between the luminaires of the local networks formed by them.

The use of LED luminaires in an intelligent autonomous system, which automatically respond to changes in the lighting parameters near them, makes it possible to simplify the system and increase its reliability.

The supply of the communication module with at least one luminaire of the system with a GSM-module enables the exchange of information via cellular communication channels between the information processing module and the website and / or mobile application.

Manufacturing of the information processing module for each luminaire with the ability to calculate the amount of energy consumed by the luminaire expands the functions of an intelligent autonomous system.

Equipping the power supply module of each luminaire of an intelligent autonomous system with a rechargeable battery and a solar battery ensures uninterrupted operation of all luminaire nodes in the absence of power from the mains.

Additional equipping of each luminaire of an intelligent autonomous system with different sensors, for example, a temperature sensor, a pressure sensor, a light sensor, connected to its lighting control unit through its information processing module allows adjusting the illumination level of each luminaire and making a decision on projecting additional information onto the surface illuminated by the luminaire. ...

Equipping each luminaire of an intelligent autonomous system with a device for projecting additional information onto the surface illuminated by the luminaire, for example, in the form of an image of a snowflake in icy conditions, or an indication of the permissible speed of a car, or an inscription "no entry", or an image of road markings "pedestrian crossing", expands the functionality system, and also allows you to increase the safety of its use.

Equipping an intelligent autonomous system with a paging facility with its own loudspeaker, beacon and microphone also enhances the functionality of the system.

The use by each luminaire of an intelligent autonomous system of a device for changing the color of the surface illuminated by the luminaire makes it possible to increase the safety of its use by focusing the attention of persons in the range of the system.

Completing the lighting system luminaire with an information storage device associated with its information processing module allows expanding the functionality of the system.

The invention is illustrated by the drawings shown in the figures:

FIG. 1 - Luminaire placed on a support (axonometry);

FIG. 2 - Block diagram of the luminaire nodes network, providing the ability to control the intensity of its illumination.

FIG. 3 - Block diagram of an intelligent autonomous network of distributed control of dynamic lighting of a luminaire.

FIG. 4 - Configuration of an autonomous intelligent distributed control system for dynamic lighting of a group of luminaires.

An autonomous intelligent information system for illuminating the territory of a spatially-oriented object with modular lamps contains a group of modular lamps, each with its own illuminator 1, which is used as a Led lamp (Fig. 1), located on their supports 2 along the border of the spatially-oriented territory illuminated by them. object (Fig. 3 and Fig. 4).

Each luminaire of the group is equipped with its own identifier C ₁ , C ₂ , C ₃ , corresponding to its ordinal number, etc. C _n by analogy (Fig. 3 and Fig. 4). In this case, each new luminaire installed along the border of the illuminated area is designated by the identifier C _n , and the idle luminaire is designated by the identifier C _x .

At the same time, each luminaire of the group is equipped with its own structural network of nodes 3 (Fig. 2), including:

Видеокамеру 4, фиксирующую и уровень освещенности вблизи опоры 2 светильника C_n, и возгорания, и задымления, и природные катаклизмы в ее зоне, а также приближение или удаление движущихся объектов;

A video camera 4, which records the level of illumination near the support 2 of the lamp C _n , and fire, and smoke, and natural disasters in its zone, as well as the approach or removal of moving objects;

Блок управления освещением 5 осветителя 1 светильника C_n, обеспечивающий установку определенного значения интенсивности его света;

The lighting control unit 5 of the illuminator 1 of the lamp C _n , providing the setting of a certain value of the intensity of its light;

Связанный со всеми узлами светильника C_n модуль электропитания 6 с аккумуляторной 6а и солнечной батареями 6б, присоединенный к электросети наружного освещения 7;

Connected to all nodes of the lamp C _n power supply module 6 with rechargeable 6a and solar batteries 6b, connected to the outdoor lighting network 7;

Модуль связи 8 со своим радиомодемом 9 с функцией ретрансляции сигнала (проводной, оптический или беспроводный 2G, 3G, 4G, 5G), формирующим цифровой сигнал со своей зоной действия, идентичный цифровым сигналам радиомодемов модулей связи других светильников системы, своими радиомодулем 10 с функцией приемо-передачи данных по локальной или глобальной сети Интернет, и своим GSM-модулем 11 для обмена информацией по каналам сотовой связи между модулем обработки информации и сайтом и/или мобильным приложением (фиг. 3 и фиг. 4);

Communication module 8 with its radio modem 9 with a signal retransmission function (wired, optical or wireless 2G, 3G, 4G, 5G), which generates a digital signal with its own coverage area, identical to the digital signals of radio modems of communication modules of other system luminaires, with its radio module 10 with a receiving function - data transmission over the local or global Internet network, and its GSM-module 11 for exchanging information over cellular communication channels between the information processing module and the site and / or mobile application (Fig. 3 and Fig. 4);

Модуль обработки информации 12 (фиг. 2) каждого светильника C_n, предназначенный:

Information processing module 12 (Fig. 2) of each lamp C _n , designed:

- to generate requests to the address of communication signals of other luminaires located in the same range of action about sending to their address information processed by them about the illumination level near their supports 2 and the light intensity of their illuminators 1 and the direction of these requests together with information about the current light intensity level of the illuminator 1 its luminaire C _n through the radio modem 9 of its communication module 8 to all radio modems of the communication modules of other luminaires of the system at their addresses;

- for collecting, analyzing the complete information received to him from the nodes of his lamp C _n connected to it, and from other lamps located with him in the same range of communication signals, and based on this information, the level of light intensity of the illuminator 1 of his lamp C _n and making an independent decision to adjust or leave it unchanged;

- to direct this decision made by him to the address of other lamps that are within the range of their communication signals, as well as to his lighting control unit 5 of the illuminator 1 of his lamp C _n to set or adjust the value of the light intensity level of his illuminator;

- to transmit to all communication modules of other luminaires of the system information about the current level of light intensity of the luminaire 1 of his luminaire C _n and retransmission of the information received to it from the luminaires that have responded to the request;

- to authorize persons who are in the lighting zone of their luminaire.

Управляющий блок 13, входящий составной частью в модуль обработки информации 12 и формирующий из светильников системы освещения, находящихся в одном радиусе действия их сигналов связи, свои связанные между собой локальные осветительные сети 14, являющиеся одними из многократно связанных между собой сетей единой саморегулируемой автономной интеллектуально-информационной системы освещения, покрывающей полностью всю территорию от первого до последнего светильника, жизнеспособность и целостность которой постоянно поддерживается многократным наложением соразмерных ретранслируемых сигналов связи между светильниками сформированных ими локальных сетей;

The control unit 13, which is an integral part of the information processing module 12 and forms from the luminaires of the lighting system located in the same range of their communication signals, its interconnected local lighting networks 14, which are one of the multiply interconnected networks of a single self-regulating autonomous intelligent an information lighting system that completely covers the entire territory from the first to the last luminaire, the viability and integrity of which is constantly maintained by the repeated imposition of commensurate relayed communication signals between the luminaires of the local networks formed by them;

Разные датчики: датчик температуры 15, датчик давления 16, датчик точки росы 17 и др.;

Various sensors: temperature sensor 15, pressure sensor 16, dew point sensor 17, etc.;

Устройство проецирования дополнительной информации 18 на освещаемую светильником C_n поверхность, например, в виде изображения снежинки при гололеде, или указания допустимой скорости движения автомобиля, или надписи «проезд запрещен», или изображения дорожной разметки «пешеходный переход», установленное на опоре 2 и предоставляющее движущемуся объекту (пешеходу или водителю транспортного средства) возможность для принятия мер предосторожности при движении по освещаемой светильником C_n зоне;

A device for projection of additional information 18 onto the _{surface illuminated by the lamp C n} , for example, in the form of an image of a snowflake in icy conditions, or an indication of the permissible speed of a vehicle, or an inscription "no passage", or an image of a road marking "pedestrian crossing", mounted on a support 2 and providing for a moving object (pedestrian or vehicle driver) the opportunity to take precautionary measures when driving in the area illuminated by the lamp C _n ;

Средство оповещения 20 со своим громкоговорителем 20а, проблесковым маячком 20б и микрофоном 20в;

Notifier 20 with its own loudspeaker 20a, flashing beacon 20b and microphone 20c;

Устройство хранения информации 21.

Storage device 21.

The proposed autonomous intelligent - information system for lighting the territory of spatially oriented objects with modular lamps operates as follows.

To start the lighting system, current is supplied from the outdoor lighting network 7 to all nodes of all lamps in the system.

The video camera 4 of each luminaire C _n constantly measures the illumination level near its support 2 (Fig. 2) and transmits this information to its information processing module 12. In this case, all sensors, including 15, 16 and 17, included in the distributed control system lighting, measure the corresponding parameters near the support 2 of the lamp C _n and also send them to its information processing module 12, which analyzes all the information received into it and decides on the current level of illumination near the support 2 of the lamp 1.

If an object appears in the viewing area of the video camera 4 of each lamp C _n (Fig. 3), it fixes this object and signals this to the information processing module 12, which receives information from all associated nodes of its lamp C _n , analyzes it and determines on the basis of this analysis the current value of the light intensity level of the illuminator 1 of its luminaire C _n .

Then, the information processing module 12 of each luminaire C _n generates requests to send information from other luminaires to its address about the decisions they made to establish the level of their illumination and the possible appearance of objects in the viewing area of video cameras 4 of their luminaires, and then sends these requests along with information about the level of light intensity of the illuminator 1 of its lamp C _n through the radio modem 9 of its communication module 8 (Fig. 3 and Fig. 4) to all radio modems of the communication modules of other lamps of the system at their addresses.

After that, the information processing module 12 of this luminaire C _n receives responses from the requested information processing modules of other luminaires of the system, which have processed their information about the illumination level near their supports 2 and the possible appearance of objects in the field of view of their video cameras 4.

Then, the information processing module 12 of this luminaire C _n proceeds to analyze all the information received to it and, on its basis, makes an independent decision to establish a sufficient illumination level near the support of its luminaire C _n and the light intensity level of its illuminator 1.

The information processing module 12 of the luminaire C _n sends this decision through the radio modem 9 of its communication module 8 to all radio modems of the communication modules of other luminaires of the system that are within the range of its radio signal, together with retransmission of the information received from them. This operation of the information processing module 12 of the luminaire C _n interconnects all the luminaires that are within the range of its radio signal, and forms from them by its action a local lighting network 14, which is part of a single autonomous intelligent information lighting system that completely covers the entire territory from the first to the last luminaire, the viability and integrity of which is constantly maintained by the repeated imposition of commensurate relayed communication signals between the luminaires of the formed local networks.

In addition, the decision taken by the information processing module 12 of the luminaire C _n to establish the illumination level that ensures the safety and comfort of motorists and pedestrians by compliance with standards, norms and requirements near the support of its luminaire C _n and the corresponding level of light intensity of its luminaire 1, together with the received With similar information from other luminaires of the system, who have sent their responses to this luminaire, he sends through his radio modem 9 to all the information processing modules of other luminaires in its coverage area, thus creating his own local network with them.

At the same time, the information processing module 12 of each lamp C _{n of the} system, after making an independent decision to establish a sufficient level of illumination near the support of its lamp C _n , made taking into account its comparison with the previously determined current value of the level of illumination near the support 2 of its lamp, directs it to the lighting control unit 5 of its illuminator 1 of the luminaire C _n , which, in turn, adjusts the current illumination level near the support 2 of its luminaire C _n or leaves it unchanged.

This is how information processing modules 12 of all luminaires of the system operate through their control units 13, which are within the same range of their communication signals, forming each separately, by their action on the constant transmission of their own and retransmission of information received to it from other luminaires, one of the connecting actions to build and the constant maintenance of their interconnected local lighting networks 14, which are collectively networks of a single autonomous intelligent information lighting system that completely covers the entire territory from the first to the last lamp, the viability and integrity of which is constantly supported by the repeated imposition of proportionate connections between the lamps of the formed local networks.

If no responses to the requests of the luminaire C _n from other luminaires of the system are received, including only from one of the luminaires, then this requesting luminaire C _n continues to work as an autonomous system, automatically sending requests to the radio

When installing a new luminaire C _n on its support 2 and connecting the power, the information processing module 12 of this new luminaire through its radio modem of the communication module 8 will automatically start sending its requests to other luminaires about the level of illumination near their supports 2, and then receive responses from luminaires of the system that are in the range of the radio signal of the communication module of the luminaire that sent requests. In addition, when a new user appears in the luminaire's radio signal coverage area, the network will authorize it once, and the subscriber will have access to the information network for use.

If the communication module 8 of any luminaire C _x ceases to transmit its requests to other luminaires in the system and to respond to requests from other luminaires in the system, then this "silent" luminaire, with which radio communication was previously established, is automatically excluded from the group of luminaires of a single lighting network that completely covers the entire territory from the first to the last lamp.

When a moving object (car or pedestrian) appears in the viewing area of the video camera 4 of the lamp C _n, it transmits the corresponding signal to the information processing module 12 about the appearance next to the support 2 with its own parameters (speed, direction, etc.), and the one in in turn, analyzes this information, together with information received from the luminaires that are within the range of its radio modem, about the level of illumination near their supports and makes an independent decision about the need to adjust the current level of illumination near the support of its luminaire C _n and then transmits a signal about this to lighting control unit 5 to increase the light intensity of the luminaire to the maximum.

Thereafter, the information about the appearance of a moving object (e.g., a vehicle or a pedestrian) is transmitted first lamp C ₁ information processing unit through its radio communication module of the second information processing modules C ₂ and C ₃ of the third lamps, downstream of the object. Thus, the object is accompanied in the direction of its movement in the coverage area of the declared autonomous distributed control system with dynamic lighting.

In parallel with the transmission of data on the illumination level of luminaires 1, the system allows data to be transmitted over a standard network, for example, WiFi, thereby providing a large coverage area for their transmission, including the international Internet zone, in the presence of specialized wired, optical or wireless 2G, 3G radio modules, 4G, 5G and others. When the user enters the coverage area of the radio module of the communication module 8 of the luminaire 1, his one-time authorization in the local network occurs. The user, moving from the coverage area of the radio module 10 of one luminaire 1 to the coverage area of another radio module of the communication module 8 of the luminaire 1, continuously receives the necessary information from the network, including about the territory of the object through which he will move, since he is a full-fledged participant in this network. However, the user himself is not involved in the process of relaying information from the lighting network. As in any local network, the user is protected by data encryption using standard protocols.

Thus, the user receives information, even if in the place where he is (pit, ravine) there are no communication signals of one of the luminaire modules of the system: GSM module 11 or radio module 10 by expanding the coverage area of the illuminated object by different telecom operators.

Created and inextricably linked with each other, claimed as an invention, technical solutions, due to the totality of their essential features reflected in their formulas of invention, make it possible to increase the speed of regulation of illumination by lamps of the territory of illuminated objects by endowing each of them, which is within the same range of the communication signal, management functions to regulate the intensity of its lighting by the formation of local lighting networks in individual sections of the illuminated territory from these lamps, which are continuously supported and strengthened by their multiple relayed communication signals with all lamps of the lighting system, which is a structural part of the formed single self-regulating autonomous intelligent information lighting system, viability and the integrity of which is constantly maintained by the imposition of multiple commensurate connections between the luminaires of each formed local network.

An autonomous intelligent information system of modular lighting based on the proposed lighting method has been successfully tested and is ready to be used to illuminate the territories of spatially oriented objects.

Claims (12)

1. A method of illuminating the territory of a spatially-oriented object with modular lamps, providing for the uniform distribution and installation of lamps over the territory of a spatially-oriented object with its connection to the outdoor lighting network; the subsequent recording by each of them of complete information about their lighting zone, depending on the time of day and weather conditions, namely: its illumination, fires, smoke and natural disasters, as well as about the approach and / or distance of moving objects; analysis of this recorded information and making, on its basis, an independent decision to establish in its lamp the illumination level of its illumination zone and the corresponding value of the intensity level of its light, and after that its adjustment in the lamp, characterized in that, in addition, after each lamp has established its intensity level lighting, they begin to form in each of them requests for sending to him information about the decisions made to establish the illumination level of the lighting zones of other lamps and the corresponding values of the intensity level of their light, and after the formation of these requests they are sent to others who are in the same radius of action, luminaires and in response receive the requested information from these other luminaires, analyze them, comparing their illumination level set in the illumination zone of their luminaire and the corresponding level of its light intensity with the received similar information from other light sources. fixtures, and on its basis make an independent decision on adjusting or leaving without changing the level of illumination in the lighting zone of their lamp, depending on the time of day and weather conditions, and adjusting or leaving without changing the level of light intensity of their lamp corresponding to it, and then adjust or leave the previously set light intensity level of their luminaire unchanged and then send their response to other luminaires requesting information about adjusting or leaving without changing the light intensity level in the illumination zone of their luminaire, along with retransmission of all responses received from other luminaires located in the same radius of their action communication signals, thus repeatedly connecting with each other all the lamps that are in the same range of their communication signals, and thus forming one of the many of local lighting networks, which are closely connected to each other, which is part of a single self-regulating autonomous intelligent-information lighting system, which completely covers the entire territory from the first to the last lamp, the viability and integrity of which is constantly supported by the repeated imposition of commensurate relayed communication signals between the lamps of each formed local network. 2. The method of lighting according to claim 1, characterized in that after the final setting of the intensity level of its illumination by each luminaire, the persons in the area of its illumination are authorized. 3. An autonomous intelligent information system for lighting the territory of a spatially-oriented object with modular lamps, containing at least two supports located along the border of the illuminated area, for example, in the form of lamp posts, each of which has its own lamp with its corresponding ordinal number an identifier, its own illuminator and its associated structural network of nodes: with a power supply module connected to the outdoor lighting network; with at least one video camera, recording in its field of view and the level of illumination, and fire, and smoke, and natural disasters, as well as the approach or removal of moving objects; with a control unit for the intensity of illumination of the illuminator, which ensures the setting of the current value of the intensity of its light; with a communication module with its own radio modem, which generates a digital communication signal with its own coverage area, which is identical to the digital communication signals of radio modems of communication modules of other luminaires of the system; with an information processing module that collects and analyzes information received from the associated nodes of its luminaire, and on its basis the decision to establish the illumination level in the illumination zone of its luminaire, depending on the time of day and weather conditions and the corresponding intensity level light of the illuminator of its luminaire, characterized in that the communication module of each luminaire of the system is connected by feedback to the corresponding equipment of the communication modules of other luminaires of the system that are in the same range of their communication signals, while it is additionally equipped with a radio module with the function of receiving and transmitting communication signals via local and / or the global Internet network connected with its radio modem, and the radio modem of the communication module itself is equipped with a signal retransmission function and its information processing module is equipped with its own control unit, which forms from the lighting system lamps located in the same range of their communication signals, with your local lighting networks, which are, in aggregate, multiply interconnected networks of a single self-regulating autonomous intelligent information lighting system that completely covers the entire territory from the first to the last luminaire, the viability and integrity of which is constantly supported by the repeated imposition of commensurate relayed communication signals between the luminaires of the local networks formed by them ... 4. The system according to claim 3, characterized in that each luminaire of the system is made of LED, automatically responding to changes in the lighting parameters near its support. 5. The system of claim. 3, characterized in that the communication module of at least one lamp is additionally equipped with a GSM module for exchanging information via cellular communication channels between the information processing module and the website and / or mobile application. 6. The system of claim. 3, characterized in that the power supply module of at least one lamp contains a battery and a solar battery. 7. The system according to claim 3, characterized in that the power supply module of at least one lamp of this system is equipped with an energy meter. 8. The system of claim. 3, characterized in that each of its luminaires is additionally equipped with different sensors, such as a temperature sensor, a pressure sensor, a dew point sensor, connected to its lighting control unit through its information processing module. 9. The system according to claim 3, characterized in that at least one of its luminaires is equipped with a device for projecting additional information onto the surface illuminated by the luminaire, for example, in the form of an image of a snowflake in icy conditions, or an indication of the permissible vehicle speed, or the inscription "travel prohibited ", or images of road markings" pedestrian crossing ". 10. The system of claim. 3, characterized in that it is equipped with at least one means of notification with its own loudspeaker, flashing beacon and microphone. 11. The system of claim. 3, characterized in that each of its luminaires is equipped with a system for changing the color of the surface illuminated by the luminaire. 12. The system of claim. 3, characterized in that each of its luminaires is additionally equipped with an information storage device associated with its information processing module.

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