EP3782042A1 - Smart management system for connected objects in a city or territory, comprising at least one equipped site - Google Patents

Abstract

The invention describes a smart management system for connected objects in a city or territory, comprising at least one site equipped with: - a plurality of connected objects; - a local processor for controlling the processing of data supplied by the data acquisition means and delivering a digital message, for controlling the processing of messages from resources outside the connected object and for controlling the operation according to a digital message; a communications network; - a platform for storing and exchanging all the data generated by the connected objects. This system comprises an inference engine that generates at least one message computed according to a message received from a first connected object and broadcast to at least some of the other connected objects, the digital message being processed by the local processor of each receiving connected object to control at least one function of the connected object according to a structured data base stored in a local random-access memory and to the digital message.

Description

 INTELLIGENT MANAGEMENT SYSTEM FOR CONNECTED OBJECTS OF A CITY OR TERRITORY COMPRISING AT LEAST ONE EQUIPPED SITE

Field of the invention

The present invention relates to the field of computer systems intended in particular for the management of connected objects of a city or a territory.

Cities and territories are increasingly equipped with technical devices that capture and create information. These technical devices are organized in silo: equipment for security with video surveillance (camera, presence detectors ...), digital platforms and mobile applications to offer services to citizens, information systems specific to design and maintenance buildings, systems to control the elements of urban space: energy management, transport, street lighting etc. Each silo has its particular missions that it fills with the information that it has been able to make available.

As such, the design of a computer system or its evolution is extremely complex and must take all the specificities of a particular context in the form of a fixed and unique execution plan for each city or territory.

To facilitate the deployment of such computer systems, sometimes more flexible modeling is used, based on a representation of the context in the form of an ontology.

State of the art

For example, in the state of the art, the article appeared under the title "A Survey on Context-aware Systems (2007)" written by Matthias Baldauf, Schahram Dustdar and Florian Rosenberg in INTERNATIONAL JOURNAL OF AD HOC AND UBIQUITOUS COMPUTIN vol. 2 No. 4, January 1, 2007 pages 263-277, concerning contextual systems collecting context data and adapting the behavior of the systems accordingly. It is about a combination of mobile devices that we want to improve usability with a layered conceptual design framework to explain the different elements common to most context-aware architectures. This document concerns the problem of the usability of mobile connected objects (notebooks, PDAs, smart phones, pervasive Systems). The context of use is different from that of the invention, and the technical issues also.

We also know the article "A Semantic Autonomous Video Surveillance System for Dense Camera Networks in Smart Cities" authored Lorena Calavia, published in the journal SENSOR vol. 12, December 2, 2012, pages 10407-10429.

This article is about an intelligent video surveillance system that can detect and detect abnormal and alarming situations by analyzing the movement of objects.

The system is designed to minimize video processing and transmission, allowing a large number of cameras to be deployed on the system, making it suitable for use as an integrated security and security solution in smart cities. . The system uses a high level conceptual language, easy to understand human operators.

Also known is the article "A. Sanchez and R. Tercero," Smart Home Technologies: Uses and Abuses, "2010 Ninth Mexican International Conference on Artificial Intelligence, Pachuca, 2010, pp. 97-102. Doi: 10.1109 / MICAI .2010.10 This article is about using a smart home laboratory as a way to teach various AI paradigms that require a living interaction with one's environment. Here, the word smart is used in an appropriate context; Therefore, a connection with sensors and actuators is needed to provide the information bits needed for knowledge-based applications, such as ontologies, adaptive learning, and data mining. By providing a rich I / O environment to drive computer applications, our students can gain a good perspective on the field of AI and smart home technologies. We believe that students are able to distinguish the benefits of this approach to commercial advertising associated with smart home terminology.

Presentation of the invention

These solutions of the prior art remain inflexible and requires for each new implementation, specific modeling of context, features, equipment, etc.

The purpose of the present invention is to propose a solution for deploying a new implementation from generic technical bricks, and to allow adaptation to a new context by a very simplified modeling.

For this purpose, the invention relates, in its most general sense, to an intelligent management system for connected objects of a city or territory comprising at least one site equipped with: a plurality of connected objects each comprising at least one means for acquiring information, at least one means for controlling a function of said connected object, means for communicating digital messages, permanent memory for recording an identifier of said object, information geolocation A local computer for controlling the processing of the data provided by said acquisition means and delivering a digital message, and the processing of messages from external resources to said connected object and controlled by said function as a function of a digital message,

A communication network,

A platform for storing and exchanging all the data transmitted by all said connected objects,

Characterized in that said system comprises an inference engine generating at least one message calculated according to a message received from a first connected object and broadcast to at least part of the other connected objects, in the form of a message with a numeric descriptor of an event,

 said digital message being processed by the local computer of each receiver connected object to control at least one function of said connected object according to a structured information base stored in a local random access memory and said digital message.

Preferably, at least a portion of said connected objects comprise means for timestamping the transmitted messages.

According to variants:

at least one of said connected objects is constituted by a camera provided with motorized control means for the direction of the field of view. at least one of said connected objects is constituted by a smoke detector.

at least one of said connected objects is constituted by a physico-chemical sensor. at least a part of said connected objects comprise means for recording an identifier ID, a digital indicator of at least one INE state and a remote management module for controlling at least one action based on the received information and / or for communicating at least one information acquired by an equipment.

The invention also relates to a method for smart management of connected objects of a city or territory comprising at least one site equipped with a plurality of connected objects each comprising at least one means for acquiring information, at least one means for controlling a function of said connected object, means for communicating digital messages, permanent memory for recording an identifier of said object, geolocation information and a local computer for controlling processing the data provided by said acquisition means and delivering a digital message, and processing messages from external resources to said connected object and command by said function as a function of a digital message, characterized in that said messages are transmitted via a communication network to a storage and exchange platform of all the data transmitted by all said objects co assigned in that it comprises steps of generating by an inference engine at least one message calculated according to a message received from a first connected object and broadcast to at least part of the other connected objects , in the form of a message comprising a digital descriptor of an event, said digital message being processed by the local computer of each receiver connected object to control at least one function of said object connected according to a structured information base stored in a local random access memory and said digital message.

Preferably, the method provides for a server to manage a database for recording an ontological model for describing the connected objects and the behavior of the connected objects.

The invention also relates to a method for managing a system for managing the technical resources comprising:

at least one equipment network constituted by: a set of furniture items geolocated with respect to said reference space,

 each of said items of furniture being associated with one or more connected objects, each connected object comprising means for recording an identifier ID, a digital indicator of at least one INE state and a remote management module for controlling at least one action based on received information and / or to communicate at least one piece of information acquired by a piece of equipment.

a server communicating with each of said connected objects via a computer network, said server comprising a database for recording an ontological model for describing the connected objects and the behavior of the connected objects, characterized in that said ontological model comprises: a digital object associated with an identifier Id _bjet and a descriptor constituting the first class of said ontological model;

a plurality of digital services, each associated with at least one technical operation defined by a descriptor numerically of its execution context, said services constituting the second class of said ontological model; a plurality of digital functions, each associated with at least one numerical descriptor of an activity and the equipment to be controlled for carrying out said activity, said functions constituting the third class of said ontological model;

 a plurality of digital descriptors of equipment constituting the fourth class of said ontological model.

The method further includes steps of propagating the information between the different classes to inherit each object of a class from the properties of the attached objects of the previous class and service instantiation steps of creating a new digital object of the type. "Service", and to control the modification of the attributes of the digital functions associated with said new instantiated digital object and to modify the attributes of the associated equipment audite (s) numerical functions modified.

Detailed description of a non-limiting example of the invention

The present invention will be better understood on reading the following description referring to nonlimiting examples of implementation illustrated by the appended drawings in which:

FIG. 1 illustrates a network implementation of a system for identifying equipment to be deployed in a physical environment, in accordance with an embodiment of the present invention.

FIG. 2 illustrates an implementation of an intelligent management system according to another embodiment of the present invention. Figure 3 shows a generic schematic view of the ontology of an object.

FIG. 4 represents a schematic view of the ontology of a service.

- Figure 5 shows a schematic view of the ontology of equipment.

- Figure 6 shows a schematic view of the ontology of furniture.

FIG. 7 represents a schematic view of the ontology of an urban space.

- Figure 8 shows a schematic view of a simple network of equipment.

FIG. 9 represents a schematic view of a hierarchical network of objects.

Background of the invention described as e

The invention relates to systems and methods for controlling the equipment of an urban space for example. Cities have developed infrastructure to organize life in urban, peripheral or rural areas. These infrastructures include equipment that renders services on these spaces. In doing so, they consume and emit data. This equipment is for example lighting street lights, traffic lights, sound equipment, video surveillance cameras, etc.

To have a global vision of the city, it is necessary to gather its data and connect them to each other and develop a specific system for each new implementation, or even for each evolution of the equipment. For example, each equipment can be identified by a IP address, and controlled by digital data related to the address of the equipment to be controlled. But this address is "neutral" and provides no information on the nature of the equipment, its position, etc. ; it is also static: if the environment of the equipment evolves, the identification of the equipment remains unchanged. It is therefore necessary to organize the operation centrally and comprehensively.

The objective is to de-skilate trades through transverse concepts:

• The technical features of each trade are modeled under one concept: equipment

• The activities and operations of these equipments are modeled under the notion of business service that these equipments render.

• Several concepts are defined to give all the context of the services: the different spaces in which its equipment operates, the networks or grouping of equipment so that they can function, the functions of each equipment etc ...

The definition of a business service meets the requirements:

• Equipment can render several services

• The same service can be delivered by multiple devices.

These business services are rendered on a territory that one wishes to control or analyze. This requires connecting these data and making them available. The objective of the invention is to have an urban language for:

• Connect all the data that could be received and sent by the different devices, applications that are on a given territory.

• Understand these data without being a specialist in each profession from which they emanate.

• Understand these data without having to translate the language specific to each device, but already having the information understandable.

Hardware architecture of the platform

FIG. 1 represents a schematic view of a system 100 according to the invention intended to drive a plurality of devices (201 to 208) deployed in a physical environment.

As an example, this equipment includes: traffic lights (201)

 multimedia kiosks (202)

 occupancy detection systems for a parking space (203)

 communicating containers (204)

 watering valves (205)

 CCTV cameras (206).

These equipments (201 to 208) are communicating and transmit and receive digital information by radiofrequency or by an electrical connection.

The system (100) includes a storage space (102) of a database that can be configured to store an ontological model described in more detail below, the data class and sub-object classes, as well as metadata and technical data for each device (201-208).

The database (102) may further be configured to derive information from the ontology and at least one of the data and metadata. The equipment information comprises at least one of thematic information, temporal information and spatial information and is organized according to an equipment ontology to define a relationship between the equipment and object data, the metadata and the information of the equipment. 'equipment.

The database (102) may further be configured to receive search queries and decompose the search query into at least one basic query component and an inferred query component. In one embodiment, the basic query component may be associated with the data of one or more objects or devices. In addition, the derived query component may be associated with the information of one or more devices (201-208). The database (102) may further be configured to execute the basic query component or the query component derived respectively on the data of one or more objects or devices and the knowledge repository to identify a device to order.

The system (100) further includes a server (101) as well as supervisory, administrative, or information presentation equipment, such as a portable computer (104), a desktop computer (105), or supervisory (106) or control (107) tablets. In one implementation, the system (100) can be implemented in a cloud environment (103). In one implementation, the network may be a wireless network, a wired network, or a combination thereof. The network 103 may be implemented as one of several types of networks, such as intranet, local area network (LAN), wide area network (WAN), the Internet, and the like. The network 103 may be a dedicated network or a shared network. The shared network represents an association of different types of networks that use a variety of protocols, for example, Hypertext Transfer Protocol (HTTP), Transmission Control Protocol / Internet Protocol (TCP / IP), and Wireless Application Protocol (WAP). communicate with each other. In addition, the network may include a variety of network devices, including routers, bridges, servers, computing devices, storage devices, and the like.

Fractal architecture of the system

FIG. 2 represents a schematic view of the overall architecture of a system according to the invention.

It comprises a central server (300) comprising an event processor (301), an artificial intelligence engine (302), a man-machine control and management interface (303) and an application programming interface (304) (API for "application programming interface" in English) consisting of a standardized set of classes, methods or functions that serves as a facade by which a software provides services to other software.

The server (300) includes an event database (340), a database (330) for registering the equipment and ontology repository, and a user database (320).

The server also has an interface (305) for communicating with external resources as well as business application type applications (306) and computer services (307).

A messaging server (308) provides interfacing with local servers (400, 500) and smart objects. Each local server (400, 500) comprises a replica (possibly partial) of the event database (340), of the database (330) for the registration of the equipment and ontology repository and of the user database. (320) and has its own event processor.

The local servers (400, 500) exchange information and messages directly with each other, and communicate with the central server (300) as well as with the connected objects of the corresponding local site.

These objects include for example:

intelligent sensors (410, 510) for example a fixed camera. These objects include a memory for the registration of an identifier, acquisition data, optionally a geolocation and a software application controlling the operation according to the messages from the local server (400, 500) as well as the transmission of messages. to this local server (400, 500), and a calculator for calculating operations based on received messages. a smoke detector, a temperature sensor or a fire detector. These sensors include a memory for the registration of an identifier, acquisition data, optionally a geolocation and a software application controlling the sending of messages to an intelligent object (440, 540). intelligent actuators (430, 530), for example a siren or a command for unlocking an airlock. These actuators include a memory for recording an identifier, acquisition data, optionally a geolocation and a software application controlling the operation according to the messages from an intelligent object (440, 540).

intelligent objects (440, 540) for example a mobile camera. These objects include a memory for the registration of an identifier, acquisition data, optionally a geolocation and a software application controlling the operation according to the messages from the local server (400, 500) as well as the transmission of messages. to this local server (400, 500), and a calculator for calculating operations based on received messages.

simple objects (450, 550) for example a fire detection unit. These objects include a memory for the registration of an identifier, acquisition data, optionally a geolocation and a software application controlling the operation according to the messages from the local server (400, 500) as well as the transmission of messages. to this local server (400, 500) and a computer to control the execution according to the received messages

simple sensors / actuators (460, 560) for example a smoke detector, a temperature sensor or a fire detector. These sensors / actuators comprise a memory for the recording of an identifier, acquisition data, optionally a geolocation and a software application controlling the operation according to the messages from the local server (400, 500) and the transmission. messages to this local server (400, 500) and for the actuators, a computer to control the execution according to the received messages.

Data structuring The systems and methods allow efficient and effective management of objects operated by the system from an ontology based on the requirements of a user.

In order to identify the equipment, time series data indicative of the measured values can be initialized. In addition, the metadata belonging to the plurality of devices can be captured. The metadata indicates additional information associated with the plurality of devices. In one example, the metadata may include detection parameters, detection characteristics, measurement and communication capabilities of each equipment, and the like. Time series data and metadata can be stored in a data store. On the basis of time series data and metadata, equipment information can be derived. The equipment information may indicate one or more concepts associated with the plurality of devices. The equipment information indicates annotations received from a plurality of subject matter experts in a field of equipment application.

The equipment information may include at least one thematic information, temporal information and spatial information.

After the derivation of the equipment information, an ontology can be created for the plurality of equipment. The equipment ontology can define a relationship between time series data, metadata, and equipment information. The equipment ontology can reside in the data store as a knowledge repository. A semantic search request received from the user can be divided into a thematic query component, a time request component and a spatial query. In addition, the semantic search request may be decomposed into at least one basic query component and a derived query component. The basic query component may be related to the time series data while the inferred query component may be related to the one or more concepts in the equipment ontology. Therefore, depending on the context of the application and the user requirements, the base query component or the derived query component can be executed on the data store and the knowledge repository respectively to identify the user. 'equipment.

In one embodiment, the data store and a knowledge repository present in the data store may be reasoned to identify respectively a subset of the equipment data and a subset of the equipment information. In one aspect, the subset of the equipment data and the subset of the equipment information may correspond to at least one of the basic query component and the derived query component. In some embodiments, the equipment information in the knowledge repository can be classified based on the match of the equipment information with one or more search queries received frequently on the knowledge repository. In addition, the search query (s) may be classified according to the frequency of reception of the search query (s) on the knowledge repository. The one or more search queries are further classified according to the rank of the equipment information corresponding to the previous search queries received on the knowledge repository.

In one embodiment, the knowledge repository can be frequently enriched over a period of time. Enrichment can be obtained by extracting additional information corresponding to the plurality of Internet / Web equipments or an external resource. using web browsing techniques or data mining techniques or extracting additional concepts associated with one or more search terms, or user information, or adding time series data, metadata and concepts for a set of new equipment.

This feature makes it possible to propose an automatic enrichment of the ontological model of the object by using Rules Management and Artificial Intelligence, during the experience feedback phase (RETEX), linked to the re-play of 1 ' event.

The ontology of a given event induces a behavior and actions of the operator towards the equipments able to the management of this event, or even reflex actions of the said equipments.

However, the system through the Complex Event Processing (Régies) and the embedded IA detects and analyzes that the operator who manages the event, goes for example on the Net to search for weather information on the geographical area of the event .

Therefore, during the re-game phase of event management (RETEX), the system will automatically propose to the operator to enrich the ontological model of the event with local weather data.

Ontological model

A class is a definition model for objects with the same set of attributes, and the same set of operations.

From a class one can create one or more objects by instantiation; every object is an instance of a classroom. In known manner, the database (102) contains objects that can be processed according to different methods:

Encapsulation of data (attributes) and behaviors: Attributes and methods are defined in the same environment (capsule).

- Hiding information: the class user may not have direct access to the attributes.

- Inheritance: we can define a class from one or more (multiple inheritance) other class (es).

- Polymorphism: the same method may have a different behavior depending on the instance to which it is applied.

Figure 3 shows a schematic view of the ontology of an object.

Object (300) is the first class.

All subclasses (310 to 319) in Figure 3 will inherit its properties: technical and functional identifier, and a name (= Label).

These properties are recorded as a number sequence (320).

A service shown schematically in FIG. 4 is an operation (or a set of operations) whose entire execution context is known. This operation renders a service through a function of the equipment. The service (340) is defined by its relationships with equipment classes, generic functions, information transmitters. The service (340) can be rendered, or available.

The context is: A space on which the equipment is installed

• A function that qualifies the service and delivers an observation, information, or indicator that is output must be the same or aggregated.

• A domain

• A mission

• A period / a time

• A beneficiary

• An emitter

• A status

• The energy consumption of this service is sometimes measured

A function is the activity or a set of activities to provide a business service. It is defined by the information or indicators that will be collected and / or issued.

A function is an on-the-shelf activity, that is, the functional definition of the service, which can be exercised by different types of equipment. The goal is to standardize these functions, so as to be independent of the equipment that makes the service.

Example: The video stream is the information transmitted by a camera, the number of vehicles per minute is an indicator issued by a camera or a presence detector, etc.

Creating a function repository is defining all the functions that a smart city could have need. It is among these functions that the city or agglomeration will choose what it wants to set up as a service.

The different functions listed so far:

• Illuminate

• Supply energy to equipment

• Count vehicles by vehicle type

• Counting vehicles

• Detect a presence

• Detect a line overflow

• To alert

• Save

• TV monitor = send a video stream)

• Driving a crossroads: Driving clean equipment at a crossroads

• Broadcast a message to citizens (broadcasting: broad broadcasting)

• Send information to a citizen by a personalized message.

• Send information to an administration Instantiation of a service With the function: illuminate the urban space: A luminous point illuminates the urban space at the crossroads whose name is Voltaire / Rembrand, on behalf of the city, in the sub area of public lighting, for the period of time from 18h to 6H, 30 September 2016.

This service may be issuing information:

Energy consumption indicators Information on ignition times

(to check) With the function and a mission: to film for the remote surveillance: A camera films the place of the media library for the account of the city, in the subfield of videoprotection, for the period of time from 18h to 6H, the September 30, 2016.

With the function: counting vehicles by type of vehicle, a camera counts the number of vehicles at the Voltaire / Souflot intersection for the city, in the traffic control sub-domain, for the period of time from 18h to 6h, September 30, 2016.

This service may be issuing information:

Number of vehicles per minute per type of vehicle (HGV, Tourist Vehicle).

With the function, counting vehicles, a presence detector counts the number of vehicles at the Voltaire / Souflot intersection on behalf of the city, in the traffic control sub-domain, for the XX period.

This service may be issuing information:

Number of vehicles per minute regardless of the type of vehicle (PL, VT).

In this case, the indicator is less accurate than that of the camera because it does not take into account the type of vehicle. But both are aggregable, for all vehicles, by the minute.

Description of equipment

The class of equipment gathers all the equipments whatever the profession which installed them or which maintains them, whatever the service they will render. Figure 5 shows a class "equipment" (350) and its subclasses (351 to 358).

A device (350) is an object that creates, receives and / or transmits data when it is installed on a territory, in a space.

Example: camera, detector, red light, point

Luminous

These are tangible objects

These are complex objects that can be composed of several parts or components.

Each piece of equipment is uniquely identified by an internal identifier and a (functional) identifier.

Each equipment (350) is geolocated.

They can be moved even if they are not moved often.

Otherwise :

• Each device has an identifier and a name (inherited from its root class: object)

• Each equipment has a status (active, inactive,)

Definition of Light Point (351) Under class of EQUIPMENT (= DEVICE)

It is the lighting equipment that provides the light fixture. It is an equipment in which we find several components such as lenses and LEDs for a LED light point. The stick that allows to hang is included in the bright spot, because each light point has a single stick.

The support (posts, facade) is not part of the luminous point. A support that can gather several points of light will be considered as street furniture.

If it has the property of being tele-managed (that is to say it has an associated remote management module), it is a device that manages consumption information, intensity, voltage, power .

Property on the 'bright spot'

• Each luminous point has a type (ballast, led ...)

• Each light point is tele-managed or not.

The complementary source of information on Luminous Point is of the form http: // www. public lighting .eu / lexicon_p.html:

Generic common name for a lighting fixture, candelabrum, fixture or projector in a lighting installation. [3] On a lighting installation, we distinguish the main light points (those that provide the main lighting, for example: On an avenue: the lighting of circulating streets) secondary light points (Those who provide secondary lighting Example: On an avenue: sidewalk lighting)

Synonym Luminaire = street lamp, candelabrum, lantern.

Definition Public Lighting Cabinet (= Light Point

Controller)

Under EQUIPMENT Class (= DEVICE)

It is an equipment that distributes energy to a set of light points or other equipment (billboard, camera, etc.) that are grafted onto the network of public lighting. This is the usual name.

Definition Traffic light (=)

Under class of EQUIPMENT (= DEVICE)

This is the equipment that signals the actions to be taken for the road users. The traffic lights are controlled by the intersection controller.

Definition Hub controller (=)

Under class of EQUIPMENT (= DEVICE)

It is the equipment that operates the traffic regulation and sends this information to a set of lights tricolor associated with it.

Variable Message Panel Definition (=)

Under class of EQUIPMENT (= DEVICE)

It is equipment that displays light messages on the road based on context and events. It is controlled either by a hub controller or by other equipment.

Camera definition (= camera)

Under class of EQUIPMENT (= DEVICE)

It's the equipment that captures images. It's a sensor. She sends a video stream.

It can have addons that add functions: count vehicles, alert, record video stream.

Property on the class 'Camera':

• Each camera has a type (PTZ, ..)

• Each camera is tele-managed or not.

Definition Detector (=)

Under class of EQUIPMENT (= DEVICE)

It is an equipment that captures information from its environment

Property on the class 'Detector':

• Each detector has a type (detector of presence, heat, passing of a line ...)

Urban furniture

It is a silent object in the urban space. Unlike the equipment (350) that manipulates data, street furniture (312) does not manipulate data. It is the physical medium of equipment (s) communicating or containing it: • The cabinet (365) is the equipment container such as a public lighting cabinet and a Tricolore Signaling Controller.

• A mat (363) is the support of the light points and / or camera.

• The bus shelter supports a bright billboard.

Property on 'Urban Furniture' class (312):

• Geolocation, defined by a numerical sequence (362).

Definition support (363)

Subway of Street Furniture (312)

Street furniture whose sole function is to support equipment.

Property on the 'Supports' class:

• Each support has a type (facade, wooden poles, concrete ...)

• Each stand has a height.

Definition of Shelter (364)

Subway of Street Furniture (312)

It is a furniture whose primary use is to provide protection to the citizen, use of buses.

A bus shelter (364) can support a bright billboard.

Definition Wardrobe (365) Subway of Street Furniture (312)

It is a furniture whose first use is to contain equipment.

Description of spaces

The city is the territories are divided into space

(312).

Definition SPACE (= PLACE):

These are physical areas of cities and territories. These areas cut out cities and territories, often depending on their history and urbanization plans. Spaces are the low layer on which urban furniture and equipment are installed.

Buildings, crossroads, roads, motorway bridges are all spaces to describe cities and territories. These are the places you want to follow. These sites are often the location of equipment.

Property on the 'Space' class:

• A space has a 3D polygon

• A space has a geolocation

• A space is either private or public

Definition Crossroads (= intersection):

Space class (Place)

The intersection is identified as a particular space. It is geolocated and can carry street names. The intersection polygon is defined. The crossroads may have as equipment, located in this polygon:

Traffic lights

Camera

Presence detector

Building Definition:

Space class (Place)

A building is identified as a particular space. It is geolocated and can carry a name and / or a street number. The building can be subdivided into floor, group of rooms and infrastructure elements. Each subdivision of a building is a subclass of a building. The building and its subclass may be locations or equipment supports.

A building and its subclasses, like all spaces, can be public or private.

In this organization, the devices are geolocated in spaces but are not assigned to an urban space or a building. The same camera could offer services (remote surveillance, smoke detection, ...) for several urban spaces (street, crossroads, ...) and / or for buildings.

Definition Ways (=):

Space class (Place)

The roads are pavements for traffic. They have a name. Property on the class 'Path':

• One lane has one type (center, driveway, residential area, subdivision.)

• One lane has a width

• One lane can be pedestrian, cyclist, car or multiple

Channel types are used to determine the level of illumination to be provided for quality lighting.

Equipment networks

A multiplicity of relationships to group the equipment in a notion of park or mesh. All these relationships will be able to create sets that can serve as filters for future uses.

We have three types

Equipment networks

Set of equipment that shares the same support

Set of equipment that operate jointly on a particular space

For example :

A public lighting cabinet supplies a set of equipment such as light points, cameras, billboards, etc. Equipment is powered by a single cabinet.

A camera can be powered by a cabinet at night, and an autonomous system during the day. This relationship will give us all the bright spots for a cabinet, a light point being fed only by a cabinet.

Street furniture can support one or more equipment.

The equipment does not always have a support.

A crossroads (370) is a space in the city or territory. To operate this crossroads, several equipments (350) will interact: lights, panels, cameras. All equipment (350) at a junction is not geolocated on the intersection polygon.

The operators

An operator is a subset of diverse and varied organizations. An operator is a type of organization or a role for an organization that will take responsibility for the management of a set of equipment and / or a set of sites, for the maintenance of infrastructure or the execution of services .

There are two types of operators currently:

Service operator

Infrastructure operator (like a network of cameras, or water management, ...).

Claims

 claims

1 - Intelligent management system for connected objects of a city or territory comprising at least one site equipped with: a plurality of connected objects each comprising at least one means for acquiring information, at least one means for controlling a function of said connected object, means for communicating digital messages, permanent memory for recording an identifier of said object, geolocation information

 a local computer for controlling the processing of the data provided by said acquisition means and delivering a digital message, and the processing of messages from external resources to said connected object and controlled by said function as a function of a digital message, d. a communication network of a platform for storing and exchanging all the data transmitted by all said connected objects

Characterized in that said system comprises an inference engine generating at least one message calculated according to a message received from a first connected object and broadcast to at least part of the other connected objects, in the form of a message with a numeric descriptor of an event,

Said digital message being processed by the local computer of each receiver connected object to control at least one function of said connected object according to a structured information base stored in a local RAM and said digital message.

2 - intelligent management system according to claim 1 characterized in that at least a portion of said connected objects comprise means for timestamping the transmitted messages.

3 - intelligent management system according to claim 1 characterized in that at least one of said connected objects is constituted by a camera provided with motorized control means of the direction of the field of view.

4 - intelligent management system according to claim 1 characterized in that at least one of said connected objects is constituted by a smoke detector.

5 - intelligent management system according to claim 1 characterized in that at least one of said connected objects is constituted by a physicochemical sensor.

6 - intelligent management system according to claim 1 characterized in that at least a portion of said connected objects comprise means for registering an identifier ID, a digital indicator of at least one INE state and a remote management module for order at least one action based on the information received and / or to communicate at least one piece of information acquired by a piece of equipment

7 - Process for intelligent management of connected objects of a city or territory comprising at least one site equipped with a plurality of connected objects each comprising at least one means for acquiring information, at least one means for controlling a function of said connected object, means for communicating digital messages, permanent memory for recording an identifier of said object, geolocation information and a local computer for controlling the processing of the data provided by said acquisition means and delivering a digital message, and the processing of messages from external resources to said connected object and controlling by said function as a function of a digital message, characterized in that said messages are transmitted via a communication network to a storage and exchange platform of all the data transmitted by all said connected objects in that it comprises steps of generation by an inference engine of at least one message calculated according to a message received from a first connected object and broadcast to at least part of the other connected objects, in the form of a message comprising a digital descriptor of an event, said digital message being processed by the local computer of each receiver connected object for controlling at least one function of said connected object according to an information base structured in a local RAM and said digital message.

8 - Process for smart management of connected objects of a city or territory according to the preceding claim characterized in that a server manages a database for the recording of an ontological model of description of connected objects and of behavior of connected objects, characterized in that:

said ontological model comprises: a digital object associated with an _object identifier Id and a descriptor constituting the first class of said ontological model; a plurality of digital services, each associated with at least one technical operation defined by a digital descriptor of its execution context, said services constituting the second class of said ontological model; a plurality of digital functions, each associated with at least one digital descriptor of an activity and the equipment to be controlled for carrying out said activity, said functions constituting the third class of said ontological model,

a plurality of digital descriptors of equipment constituting the fourth class of said ontological model,

 the method comprising steps of propagating the information between the different classes to inherit each object of a class from the properties of the attached objects of the previous class

 the method comprising service instantiation steps of creating a new service-type digital object, and controlling the modification of the attributes of the digital functions associated with said new instantiated digital object and modifying the attributes of the associated equipment audits (s) ) modified numeric functions.