FR3118842A1 - METHOD FOR INTEGRATING A DETECTOR INTO AN ALARM SYSTEM - Google Patents

Abstract

Method for integrating a first type detector into an alarm center, the alarm center being connected to a gateway and being able to be connected to at least one second type detector by a first network, the gateway and the detector of the first type being connected to a service platform by a second network. The method includes receiving an integration request from the detector of the first type; generating a virtual device having characteristics of a detector of the second type and representing the detector of the first type; send the control panel a request to associate a detector of the second type identified as the virtual device; generating a transcoding procedure transforming each sensor message of the first type into a virtual device message; and when a message from the detector of the first type is received, transcoding said message and transmitting the transcoded message. Figure to be published with abstract: Fig. 2

Description

METHOD FOR INTEGRATING A DETECTOR INTO AN ALARM SYSTEM

The present invention relates to the field of alarm systems and relates more specifically to the integration of a detector in an alarm system.

STATE OF THE PRIOR ART

An alarm system generally includes one or more detectors whose role is to observe their environment and identify an intrusion by detecting variations such as movement or a variation in heat. An alarm system also includes an alarm center connected to each detector and which manages the monitoring of a site such as a property based on information transmitted in the form of messages by each detector. For example, when a detector detects a movement, said detector transmits a message containing information representative of an intrusion to the alarm center. Upon receipt of the message containing information representative of an intrusion, the alarm center decides whether or not to activate an alarm according to predetermined criteria, such as prior activation of a surveillance mode, a time of day or reception of information transmitted by another detector within a predefined period, for example.

In addition, more and more properties are equipped with sensors such as cameras that can be accessed remotely. Such a detector allows a user to observe in his absence what is happening in a property, by accessing, in real time and remotely, data from said detector. The user can thus view acquired images or receive messages containing information representative of an intrusion. Access to said data is possible via the internet by using, for example, a remote service of video platforms. Such a detector is easy to install since it suffices to connect it to the internet and to register an identifier of said detector on the video platform so that the video platform retrieves the data from the detector. The user can then access, at any time and via the internet, the data hosted on the video platform. In addition, such access is done in a secure manner by using, for example, a customer account protected by a password.

However, such a detector is not compatible with an alarm system. In particular, such a detector cannot communicate with the alarm center since said detector and the alarm center are not interconnected and are not configured to exchange information between them. The alarm center cannot therefore take into account a message containing information representative of an intrusion, sent by said detector.

It is desirable to overcome these drawbacks of the state of the art. It is particularly desirable to provide a solution that allows the alarm center to receive messages containing information representative of an intrusion coming from the remotely accessible camera. It is also desirable to provide a solution that allows the detector to send data to the control panel without requiring updates to the control panel and camera operating software.

An object of the present invention is to provide a method for integrating a detector, called a detector of a first type, into an alarm center, the alarm center being connected, via a first communication network using a first network protocol, a gateway, the alarm center being able to be connected, via the first communication network, to at least one detector, called a detector of a second type, the detector of the first type being connected to a remote service platform via a second communication network using a second network protocol, the gateway being connected to the remote service platform via the second communication network. The method comprises: receiving, via the gateway, from the remote service platform, a request for integration of the detector of the first type, said integration request comprising an identifier of said detector of the first type; generating, by the gateway, a virtual device comprising characteristics of a detector of the second type, said virtual device representing the detector of the first type; send, to the alarm center, a request for association with a detector of the second type, said detector of the second type being identified as being the virtual device; generate, by the gateway, a transcoding procedure making it possible to transform each message coming from the detector of the first type, adapted to the second network protocol, into a message transmitted by the virtual device and adapted to the first network protocol, when an acceptance of association to the virtual device is received from the alarm center; and, when a message from the detector of the first type is received via the remote service platform, transcoding, by the gateway, said message and transmitting the transcoded message to the alarm center.

Thus, the alarm center can receive messages from the first type detector, although said first type detector is not capable of sending messages to the alarm center using the first communication protocol and without modification of the installed products which are the central alarm unit or the first type detector. The alarm center can then receive information from the first type detector without having to update operating software. In addition, an update of the operating software of the first type detector is also not necessary.

According to a particular embodiment, the transcoding procedure comprises a routing table which applies to each message coming from the detector of the first type and further comprises a protocol adaptation from the second network protocol to the first network protocol.

Thus, a message received from the first type detector can easily be transformed into a message as generated by a second type device.

According to a particular embodiment, the method further comprises: receiving, via the remote service platform, a request for activation of the detector of the first type, said activation request comprising an identifier of the detector of the first type; send, via the remote service platform, to the gateway a request for integration of the detector of the first type when a request for activation of the detector of the first type is received, said integration request comprising an identifier of said detector of the first type; sending, via the gateway, to the remote service platform, a confirmation of integration of the detector of the first type, when an acceptance of association with the virtual device is received from the alarm centre. The method further comprises, when an integration confirmation is received from the gateway by the remote service platform: transmitting, via the remote service platform, to the gateway each new message received from the detector of the first type ; and sending, via the remote service platform, an activation confirmation of the detector of the first type.

Thus, a first type detector can easily be integrated into the alarm centre.

According to a particular embodiment, the request for activation of the detector of the first type is received from a client application, said application being connected to the remote service platform via the second communication network, and the confirmation activation of the detector of the first type is sent to the client application.

Thus, a user of the first type detector and of the alarm panel can at any time request to integrate the first type detector into the alarm panel without carrying out any hardware or software installation.

According to a particular embodiment, the detector of the first type is a video camera and the second communication network is the Internet network.

Thus, an internet-connected video camera can easily be integrated into an alarm control panel so that the alarm control panel can rely on information transmitted in the form of messages from the video camera to manage alarm decisions.

The invention also relates to a gateway, connecting an alarm center via a first communication network using a first network protocol to a remote service platform via a second communication network making use of a second network protocol, the alarm center being able to be connected via the first communication network, to at least one detector of a second type, and the remote service platform being connected via the second communication network to a detector of a first type. The gateway comprises: means for receiving from the remote service platform a request for integration of the detector of the first type, said integration request comprising an identifier of said detector of the first type; means for generating a virtual device comprising characteristics of a detector of the second type, said virtual device representing the detector of the first type; means for sending, to the alarm center, a request for association with a detector of the second type, said detector of the second type being identified as being the virtual device; means for generating a transcoding procedure making it possible to transform each message originating from the detector of the first type, adapted to the second network protocol, into a message transmitted by the virtual device and adapted to the first network protocol, when an acceptance of association with the virtual device is received from the alarm center; and means for transcoding each message received from the detector of the first type via the remote service platform and for transmitting said transcoded message to the alarm center.

The invention also relates to an integration system comprising said gateway, comprising the remote service platform, the detector of the first type and the alarm centre. The gateway further comprises means for sending, to the remote service platform, a confirmation of integration of the detector of the first type, when an acceptance of association with the virtual device is received from the alarm center . The remote service platform further comprises: means for receiving an activation request from the detector of the first type, said activation request comprising an identifier of the detector of the first type; means for sending to the gateway a request for integration of the detector of the first type when a request for activation of the detector of the first type is received, said integration request comprising an identifier of said detector of the first type; means for transmitting to the gateway each new message received from the detector of the first type, and for sending an activation confirmation of the detector of the first type, when an integration confirmation is received from the gateway.

According to a particular embodiment, the integration system further comprises a client application, said application being linked to the remote service platform via the second communication network and comprising means for sending the activation request of the detector of the first type comprising an identifier of said detector of the first type, and in which the platform comprises means for sending the confirmation of activation of the detector of the first type to the client application when an integration confirmation is received in coming from the gateway.

The invention also relates to a computer program, which can be stored on a medium and/or downloaded from a communication network, in order to be read by a processor. This computer program includes instructions for implementing the method mentioned above in any of their embodiments, when said program is executed by the processor.

The invention also relates to an information storage medium storing such a computer program.

The characteristics of the invention mentioned above, as well as others, will appear more clearly on reading the following description of at least one embodiment, said description being made in relation to the attached drawings, among which:

schematically illustrates a system for integrating a detector of a first type;

schematically illustrates a method of integrating the first type detector;

schematically illustrates an activation method for the integration of the first type detector;

schematically illustrates a method of operating the integrated first type detector; And

schematically illustrates an example of hardware architecture of a processing module.

DETAILED DESCRIPTION OF EMBODIMENTS

Fig. 1 thus schematically illustrates a system 100 for integrating a detector of a first type 104 with an alarm system 101.

The integration system 100 comprises the alarm system 101. The alarm system 101 is located on a monitoring site, such as a dwelling house, and comprises a central alarm 102 and at least one detector , said detector of a second type 103. The second type detector 103 is connected to the alarm center 102 via a first communication network 111, said first communication network using a first communication protocol. The first communication protocol is for example a proprietary communication protocol such as the protocol marketed by the applicant under the name X3D. In addition, the second type detector 103 is recognizable by the alarm center 102. In other words, the second type detector 103 is able to send messages to the alarm center 102 using the first communication protocol. communication and the alarm center 102 can receive and process said messages by itself. For example, the second type detector 103 is an infrared detector which sends a message to the alarm center 102 containing information representative of an intrusion when said infrared detector detects the presence of a living being on the site of surveillance. The alarm center 102 then processes said message and decides whether or not to issue an alarm according to other predetermined parameters. The second type detector 103 can alternatively be a code detector provided with a keyboard or a magnetic opening detector for example.

The integration system 100 further comprises the first type detector 104. The first type detector 104 is a detector which is located on the same monitoring site as the alarm system. Furthermore, the first type detector 104 observes and analyzes its environment in order to detect variations. When the first type detector 104 detects a variation exceeding a predefined threshold, the first type detector 104 sends an INTRUSION message 400 comprising information representative of an intrusion. According to a particular embodiment, the first type detector 104 is a video camera which acquires images of its environment and carries out an analysis of said images in order to detect movement or unusual elements. Unlike the second type detector 103, the first type detector 104 is not connected to the alarm center 102 via the first communication network 111. For example, the first type detector 104 cannot send messages using the first communication protocol. The first type detector 104 is therefore not recognizable by the alarm center 102.

The integration system 100 comprises a platform 105, which is a remote service platform, hosted for example by a remote server. The platform 105 allows remote access to messages sent by the first type detector 104 comprising, for example, acquired images or an INTRUSION message 400 comprising information representative of an intrusion. For this, the platform 105 is connected to the first type detector 104 via a second communication network 112 using a second communication protocol. The second communication network 112 is for example an extended communication network such as the Internet and the second communication protocol is for example the IP protocol. Thus, the platform 105 receives, in the form of packets, each message sent by the first type detector 104.

The integration system 100 further includes a client application 106. The client application 106 is linked to the platform 105 via the second communication network 112. In addition, the client application can access, via the platform 105 , to messages sent by the first type detector 104 by sending a request comprising an identifier of said first type detector 104, said identifier being for example an IP address (for "Internet Protocol" in English) of the first type detector 104 associated to a serial number of the first type detector 104. For example, the client application 106 is installed on a user's mobile telephone and retrieves a message comprising information representing an intrusion coming from the first type detector 104 or images acquired by the first type detector 104. According to a particular embodiment, the client application 106 securely accesses the first type detector 1 04 on the platform 105 thanks to an account number protected by a password, allowing secure access to the first type detector 104 and to a client account ensuring the legitimacy of the user to access said first type detector 104. Said client account is configured to connect the client application 106 to the platform 105 on which the first type detector 104 is connected. Thus, only the legitimate user can remotely access messages sent by the first type detector 104 while a third person cannot access said first type detector 104.

The integration system 100 further comprises a gateway 107 which connects the alarm system 101 to the second communication network 112 and thus makes it possible to connect the alarm system 101 to the platform 105. Thus, it is possible to access to information sent by the alarm system 101 from the client application 106. In addition, the platform 105 includes a management service such as a rule engine which makes it possible to execute actions according to information received in coming from the client application 106, coming from the first type detector 104 or coming from the alarm system 101 via the gateway 107. According to a particular embodiment, the platform 105 is divided into two sub-platforms which communicate between they. The first sub-platform is connected to at least one first type detector 104, receives messages sent by each first type detector 104, and broadcasts said messages in association with the identifier of said first type detector 104 to a second sub- platform. The second sub-platform comprises the management service which communicates with the client application 106, with the gateway 101 and with the first sub-platform. The second platform can be configured to associate the identifier of a first type detector 104 with a customer account number.

In the integration system 100, each entity that are the gateway 107, the first type detector 104, the alarm center 102, the second type detector 103, the platform 105 and the client application 106, comprises a module processing 1000 (not shown) allowing each entity to participate in an implementation of the invention.

Fig. 2 schematically illustrates a method for integrating the first type detector 104 into the alarm system 101. The integration method is implemented by a processing module 1000 of the gateway 107.

In a step 202, the gateway 107 receives an integration request from the first type detector 104. The integration request includes the identifier of said first type detector 104. Said identifier is for example an IP address of said first type detector 104, used to communicate in the second communication network, associated with a serial number of said first type detector 104, said serial number making it possible to uniquely identify the first type detector 104. The request for integration of the detector of the first type 104 is received from the platform 105 and includes the identifier of the first type detector 104. Alternatively, the request for integration of the first type detector 104 is received from the client application 106.

In a next step 203, the gateway 107 temporarily generates a virtual device comprising characteristics of a second type detector 103. In other words, the gateway 107 creates a virtual entity capable of transmitting messages, in the form of packets, to of the alarm center 102 via the first communication network 111, said messages being able to be processed by the alarm center 102. The virtual device is for example recorded in a random access memory or temporary memory. Furthermore, the gateway 107 associates with said virtual device the identifier of the first type detector 104 so that said virtual device represents the first type detector 104. Thus, the virtual device makes it possible to emulate a suitable device 103 capable of communicating with the alarm center 102. In addition, the gateway 107 assigns to the virtual device an identifier of the virtual device recognized in the first communication network 111, and allowing the alarm center 102 to identify said virtual device among different detectors of second type 103 or other virtual devices. Thus, the alarm center 102 can communicate with the virtual device using said identifier of the virtual device. The gateway 107 is capable of assigning to said virtual device each message transmitted by the alarm center 102 and comprising said identifier of the virtual device.

The gateway 107 records permanently, in a database for example, the identifier of the first type detector 104 in association with the identifier of the virtual device.

In a next step 204, the gateway 107 sends, using the virtual device, an association request to the alarm center 102, said association request comprising the same characteristics as any association request sent by a second type detector 103.

In a step 206, the gateway 107 identifies whether it receives from the alarm center 102 confirmation of association with said virtual device in response to the association request. If it receives such a confirmation, the gateway 107 performs a step 207. Otherwise, the gateway 107 performs a step 220.

At step 220, the gateway 107 deletes the virtual device and sends a message representing a refusal of integration by the alarm system 101 to the platform 105, or alternatively to the client application 106.

At step 207, the gateway 107 saves the virtual device in a durable manner, for example by saving it in a non-volatile memory. The gateway 107 generates a transcoding procedure making it possible to transform each message from the first type detector 104, adapted to the second network protocol, into a message transmitted by the virtual device and adapted to the first network protocol. The transcoding procedure comprises a routing table which applies to each packet of a message received from the first type detector 104 and comprising the identifier of said first type detector 104. Said identifier of the first type detector 104 allows to uniquely identify the first type detector 104, such as for example the serial number of the first type detector 104. The transcoding procedure further comprises a protocol adaptation from the first network protocol to the second network protocol. The routing table indicates, for each message comprising the identifier of the first type detector 104, to send a message comprising the identifier of the virtual device to the first communication network 111. Thus, a message transmitted by the first type detector type 104 can be transformed in order to be communicated to the alarm center 102.

In a next step 211, the gateway 107 waits for a message from the first type detector 104.

In a step 212, the gateway 107 identifies whether an INTRUSION message 402 from the first type detector 104 is received via the platform 105. If so, a step 213 is performed. Otherwise, step 211 is repeated.

At step 213, the gateway 107 transcodes the INTRUSION message 402 from the first type detector 104 and thus generates an INTRUS_COD message 404 transmitted by the virtual device and interpretable by the alarm center 102 comprising information transmitted by the detector of first type 104 such as information representative of an intrusion.

In a step 214, the gateway 107 sends the INTRUS_COD message 404 transmitted by the virtual device to the alarm center 102. Thus, the alarm center 102 can receive and process a message comprising information generated by the detector of first type 104 as if said message came from a second type detector 103, which avoids performing updates to modify the configuration of a software of the alarm center 102.

Fig. 3 schematically illustrates an activation process for the integration of the first type detector 104.

In a step 300, the processing module 1000 of the client application 106 sends, intended for the platform 105, a request for activation ACTIV_RQ of a first type detector 104 to an alarm system 101. The request for Activation ACTIV-RQ includes an identifier of the first type detector 104, such as a serial number associated with an IP address. A user of the first type detector 104 and of the alarm system 101 can thus request the gateway 107 at any time to integrate said first type detector 104 into said alarm system 101.

In a step 301, the processing module 1000 of the platform 105 carries out a check in order to determine whether the first type detector 104 is accessible from the platform 105. If this is the case, the processing module 1000 of the platform 105 performs a step 302. Otherwise, the processing module 1000 of the platform 105 sends an activation refusal to the client application 106.

At step 302, the processing module 1000 of the platform 105 sends, to the gateway 107, an integration request INTEG_RQ of the first type detector 104. Said integration request INTEG_RQ includes the identifier of the detector of first type 104. According to a particular embodiment, step 302 is identical to step 202 of the .

In a step 303, identical to step 203 of the , the processing module 1000 of the gateway 107 temporarily generates a virtual device comprising characteristics of a second type detector 103. The virtual device is for example saved in a temporary memory such as a buffer memory. Furthermore, the processing module 1000 of the gateway 107 associates with said virtual device the identifier of the first type detector 104 so that said virtual device represents the first type detector 104. The processing module 1000 of the gateway 107 assigns in in addition to said virtual device, the identifier of the virtual device recognized in the first communication network 111 and allowing the alarm center 102 to identify said virtual device and to distinguish it among other virtual devices or other detectors of second type 103. The processing module of the gateway 107 records permanently, in a database for example, the identifier of the first type detector 104 in association with the identifier of the virtual device.

In a step 304, identical to step 204 of the , the processing module 1000 of the gateway 107 sends, via the virtual device, an association request ASSO_RQ to said virtual device intended for the alarm center 102, said association request ASSO_RQ comprising the identifier of the virtual device.

In a step 305, the processing module 1000 of the alarm center 102 accepts the association request and performs a step 306.

Note that in the case where the alarm center 102 does not accept the association request, for example, if the alarm center 102 is already connected to a number of suitable detectors 103 exceeding a predefined threshold, the processing 1000 of the alarm center 102 sends an association refusal to the virtual device. Upon receipt of the association refusal, the processing module 1000 of the gateway 107 does not save the virtual device in non-volatile memory and transmits an integration refusal to the platform 105 which returns an activation refusal to the application. customer 106.

In step 306, the processing module 1000 of the alarm center 102 sends in the first communication network 111 an association confirmation ASSO_CONFIRM comprising the identifier of the virtual device assigned in step 303. The confirmation of ASSO_CONFIRM association is thus received by the gateway 107 which assigns, thanks to the identifier of the virtual device, said ASSO_CONFIRM association confirmation to the virtual device.

In a step 307, identical to step 207 of the , the processing module 1000 of the gateway 107 saves the virtual device in a durable manner, for example in a non-volatile memory, and generates a transcoding procedure making it possible to transform each packet of a message received from the first type detector 104 , identified by its identifier (for example, its IP address and its serial number) in a packet transmitted by the virtual device, identified by the identifier of the virtual device assigned in step 303.

In a step 308, the processing module 1000 of the gateway 107 sends to the platform 105 an integration confirmation INTEG_CONFIRM of the first type detector 104 to the alarm system 101.

In a step 309, the processing module 1000 of the platform 105 implements an automatic transfer, to the gateway 107 of the alarm system 101, of each new message received from the first type detector 104. For this, a automatic transfer action is assigned to each message sent spontaneously by the first type detector 104 identified by the identifier of said first type detector 104.

In a step 310, the processing module 1000 of the platform 105 sends an activation confirmation ACTIV_CONFIRM of the first type detector 104 to the alarm system 101, intended for the client application 106.

According to a particular embodiment, when the first type detector 104 is disconnected, the platform 105 sends to the gateway 107 information representative of a disconnection of said first type detector 104. The gateway 107 then transmits to the central alarm 102, via the virtual device, information representing a disconnection or an absence of message received from the first type detector 104 for a predetermined duration, for example for two hours.

Fig. 4 schematically illustrates a method of operating the first type detector 104 integrated into the alarm system 101. The first type detector 104 is considered to be integrated into the alarm system 101 when the processing module 1000 of the platform 105 sends an activation confirmation ACTIV_CONFIRM of the first type detector 104 to the alarm system 101, as previously indicated in relation to step 310.

In a step 400, the processing module 1000 of the first type detector 104 sends to the platform 105 an INTRUSION message comprising information representative of an intrusion.

In a step 402, the processing module 1000 of the platform 105 automatically transfers the INTRUSION message to the gateway 107.

In a step 403, the processing module 1000 of the gateway 107 performs a transcoding of the INTRUSION message coming from the first type detector 104 in order to generate a transcoded message INTRUS_COD transmitted by the virtual device, adapted to the second network protocol, and comprising the information representative of an intrusion included in the INTRUSION message generated by the first type detector 104.

In a step 405, the processing module 1000 of the alarm center 102 receives the transcoded message INTRUS_COD and processes the information representative of an intrusion of said transcoded message INTRUS_COD as if it were information representative of an intrusion of a second type detector 103 such as for example an infrared detector. The processing module 1000 of the alarm center 102 can then decide whether or not to generate an alarm, depending on other predetermined criteria.

Fig. 5 schematically illustrates an example of hardware architecture of a processing module 1000. The processing module 1000 then comprises, connected by a communication bus 510; a processor or CPU (Central Processing Unit) 501; a random access memory RAM 502; a ROM (Read Only Memory) memory 503; a storage unit 504, such as a hard disk HDD (“Hard Disk Drive” in English), or a storage medium reader, such as a card reader SD (“Secure Digital” in English); and a COM interface 505 making it possible to communicate with at least one other entity of the integration system 100.

When the processing module 1000 is included in the gateway 107, the communication interface COM 505 comprises a plurality of communication interfaces making it possible to communicate with the alarm center 102 via the first communication network 111 on the one hand and making it possible to communicate with the platform 105 and the client application 106 via the second communication network 112 on the other hand.

When the processing module 1000 is included in the alarm center 102, the communication interface COM 505 makes it possible to communicate with the second type detector 103 and the gateway 107 via the first communication network 111.

When the processing module 1000 is included in the second type detector 103, the COM 505 communication interface makes it possible to communicate with the alarm center 102 via the first communication network 111.

When the processing module 1000 is included in the first type detector 104, the communication interface COM 505 makes it possible to communicate with the platform 105 via the second communication network 112.

When the processing module 1000 is included in the platform 105, the communication interface COM 505 makes it possible to communicate with the first type detector 104, the client application 106 and the gateway 107 via the second communication network 112.

When the processing module 1000 is included in the client application 106, the communication interface COM 505 makes it possible to communicate with the platform 105 and, according to a particular embodiment, with the gateway 107, via the second communication network 112 .

CPU 501 is capable of executing instructions loaded into RAM 502 from ROM 503, external memory (such as an SD card), storage media, or a network of communication. When the entity (i.e. the gateway 107, the first type detector 104, the alarm center 102, the second type detector 103, the platform 105 or the client application 106) is powered up, the processor CPU 501 is able to read instructions from RAM 502 and execute them. These instructions form a computer program causing the implementation, by the processor CPU 501, of all or part of the steps described here in relation to the processing module 1000 of the entity considered.

All or part of said steps can thus be implemented in software form by execution of a set of instructions by a programmable machine, such as a DSP ("Digital Signal Processor" in English) or a microcontroller, or be implemented in hardware form. by a dedicated machine or component, such as an FPGA (Field-Programmable Gate Array) or an ASIC (Application-Specific Integrated Circuit). In general, each entity of the integration system 100 thus comprises electronic circuitry configured to implement all or part of the steps described here in relation to the processing module 1000 of the entity considered.

Claims (10)

Method for integrating a detector, called a detector of a first type, into an alarm center, the alarm center being connected via a first communication network using a first network protocol , to a gateway, the alarm center being able to be connected, via the first communication network, to at least one detector, said detector of a second type, the detector of the first type being connected to a service platform remote via a second communication network using a second network protocol, the gateway being connected to the remote service platform via the second communication network, the method being characterized in that it comprises :
- receive, via the gateway, from the remote service platform a request for integration of the detector of the first type, said integration request comprising an identifier of said detector of the first type,
- generate, by the gateway, a virtual device comprising characteristics of a detector of the second type, said virtual device representing the detector of the first type,
- send, to the alarm center, a request for association with a detector of the second type, said detector of the second type being identified as being the virtual device,
- generating, by the gateway, a transcoding procedure making it possible to transform each message originating from the detector of the first type, adapted to the second network protocol, into a message transmitted by the virtual device and adapted to the first network protocol, when an acceptance of association to the virtual device is received from the alarm center,
And in that, when a message from the detector of the first type is received via the remote service platform, transcoding, by the gateway, said message and transmitting the transcoded message to the alarm center. A method according to claim 1, wherein the transcoding procedure includes a routing table which applies to each message from the first type sensor and further includes protocol adaptation from the second network protocol to the first network protocol. Method for activating a detector of the first type at the alarm centre, characterized in that it comprises the method according to claim 1, and in that it further comprises:
- receive, via the remote service platform, a request for activation of the detector of the first type, said activation request comprising an identifier of the detector of the first type,
- send, by the remote service platform, to the gateway a request for integration of the detector of the first type when a request for activation of the detector of the first type is received, said integration request comprising an identifier of said detector of the first kind,
- send, via the gateway, to the remote service platform, a confirmation of integration of the detector of the first type, when an acceptance of association with the virtual device is received from the alarm center,
And, when an integration confirmation is received from the gateway by the remote service platform:
- transmit, via the remote service platform, to the gateway each new message received from the detector of the first type,
- sending, via the remote service platform, an activation confirmation of the detector of the first type. Method according to claim 3, characterized in that the request for activation of the detector of the first type is received from a client application, said application being connected to the remote service platform via the second communication network, and in that the confirmation of activation of the detector of the first type is sent to the client application. Method according to one of Claims 1 to 4, characterized in that the detector of the first type is a video camera and in that the second communication network is the Internet network. Gateway, connecting an alarm center via a first communication network using a first network protocol to a remote service platform via a second communication network using a second network protocol , the alarm center being able to be connected via the first communication network, to at least one detector of a second type, and the remote service platform being connected via the second communication network to a detector of a first type, the gateway being characterized in that it comprises:
- means for receiving from the remote service platform a request for integration of the detector of the first type, said integration request comprising an identifier of said detector of the first type,
- means for generating a virtual device comprising characteristics of a detector of the second type, said virtual device representing the detector of the first type,
- means for sending, to the alarm center, a request for association of a detector of the second type, said detector of the second type being identified as being the virtual device,
- means for generating a transcoding procedure making it possible to transform each message originating from the detector of the first type, adapted to the second network protocol, into a message emitted by the virtual device and adapted to the first network protocol, when an association acceptance to the virtual device is received from the control panel, and
- Means for transcoding each message received from the detector of the first type via the remote service platform and for transmitting said transcoded message to the alarm centre. Integration system characterized in that it comprises the gateway according to claim 6, in that it further comprises the remote service platform, the detector of the first type and the alarm center, in that the gateway comprises besides :
- means for sending, to the remote service platform, a confirmation of integration of the detector of the first type, when an acceptance of association with the virtual device is received from the alarm center,
and in that the remote service platform comprises:
- means for receiving a request for activation of the detector of the first type, said activation request comprising an identifier of the detector of the first type,
- means for sending to the gateway a request for integration of the detector of the first type when a request for activation of the detector of the first type is received, said integration request comprising an identifier of said detector of the first type,
- Means for transmitting to the gateway each new message received from the detector of the first type, and for sending an activation confirmation of the detector of the first type, when an integration confirmation is received from the gateway. Integration system according to the preceding claim further comprising a client application, said application being linked to the remote service platform via the second communication network and comprising means for sending the request for activation of the detector of the first type comprising an identifier of said detector of the first type, and in which the platform comprises means for sending the confirmation of activation of the detector of the first type to the client application when an integration confirmation is received from the gateway . Computer program which can be stored on a medium and/or downloaded from a communication network, in order to be read by a processor, and comprising instructions for implementing the method according to one of Claims 1 to 5, when said program is executed by the processor. Information storage medium storing a computer program according to the preceding claim.