WO2010049643A1

WO2010049643A1 - Power line communication box

Info

Publication number: WO2010049643A1
Application number: PCT/FR2009/052072
Authority: WO
Inventors: Matthieu Plantey; Pierre Violet
Original assignee: Poweo
Priority date: 2008-10-28
Filing date: 2009-10-27
Publication date: 2010-05-06
Also published as: FR2937814A1

Abstract

The invention relates to a power line communication box (18a-e) that is capable of implementing at least one Internet protocol for communication with at least one other identical box (18a-e) via a power grid (12). The box is also capable of implementing at least one home automation protocol.

Description

COMMUNICATION HOUSING BY CURRENT CARRIERS

The present invention relates to the field of in-line carrier boxes, known as CPL type. It is known, on the one hand from the state of the art a CPL housing comprising an electrical outlet. The socket is able to be connected to an electrical network and the housing is able to receive an RJ45 type connector connected to a computer. The CPL box is able to implement an Internet communication protocol with at least one other identical PLC box via the electrical network. Such a housing allows the creation of a logic network, said computer, using the existing electrical network and thus avoid the installation of specific cables for the creation of a physical network compatible with the Internet protocol.

There is, on the other hand, an electrical box for home use. Such a home automation box is able to implement one or more proprietary home automation protocols in order to control a home automation device connected to the housing, for example a lamp. This type of housing for home use operates at a relatively low rate ranging from a few kbits per second to a few hundred kbits per second.

But these CPL and home automation devices do not allow a device using an Internet communication protocol and a home automation device to communicate together via the power grid.

The object of the invention is to solve this problem.

For this purpose, the subject of the invention is an on-line carrier communication box, able to implement at least one Internet communication protocol with at least one other identical box via an electrical network, and to implement at less a home automation application protocol.

The box according to the invention allows messages to be exchanged between two devices using the Internet protocol, for example computers, via a logical network, called a computer network, formed on the electrical physical network. It also allows messages to be exchanged between home automation devices via a logical network called home automation, using the electrical physical network using the functionalities of the computer network. Finally, the housing according to the invention allows the exchange of messages between at least one home automation device and at least one device using the Internet protocol via a mixed logical network using the electrical physical network. Again, we use the features of the computer network to exchange messages for home use. The exchange of messages between these devices can take the form of data but also the form of instructions intended to trigger the implementation of the application protocol. home automation of one of the housings. Thus, it can be said that the electricity network supports the computer network, the computer network supporting the home automation network.

The housing according to the invention therefore makes it possible to communicate a command or a data item from a transmitting apparatus to a destination apparatus. When a command or data is sent by a device using the Internet protocol, it passes through the box to which the device is connected. This transmitter box determines the destination of the command or the data and translates it into a signal for transmission via the electrical network. The box to which the receiving device is connected receives the signal and in turn translates the signal in the opposite direction. The recipient box then reforms the command or data. In the case where the transmitting apparatus is a computer and the destination apparatus of the home automation type, for example a lamp, the housing according to the invention makes it possible to control a lamp from a computer via the electrical network by using the protocol. home automation application of the recipient box. In the case where the transmitting apparatus is of the home automation type and the receiving apparatus is a remote computer, the housing according to the invention also makes it possible to communicate a datum of the home automation transmitter device to the computer via the electrical network by using the Internet protocol for communicating the transmitter and receiver boxes.

In addition, the housing according to the invention uses the power grid and the technology of the carrier currents in line, which allows high-speed operation, for example according to technologies such as Homeplug or DS2 whose flow under ideal conditions varies. from 85 to 200 Mbit per second.

Advantageously, the home automation application protocol or at least one of the home automation application protocols is chosen from the SNMP, HVAC and Lighting controls protocols. These protocols are open type. As opposed to closed or proprietary protocols, these protocols do not require the acquisition of licenses, which reduces the selling price of the box and makes it easier to operate. In addition, these open protocols have known specificities that can be advantageously used in the context of the invention. The Lighting Controls and HVAC protocols (Heating, Ventilation and Air-Conditioning) respectively allow control of lighting and heating, ventilation and air conditioning devices. These protocols correspond to standard UPnP protocols, that is, protocols defined to allow greater connectivity between home appliances and the housing. According to an optional feature of the housing, it is able to implement a communication using a transport layer and an application layer above of the transport layer, the transport layer being able to implement each Internet protocol and the application layer being able to implement the or each home automation application protocol.

Optionally, the application layer is able to implement: - an action protocol on one element of the housing, and a communication protocol from one state of the element to the other housing via the electrical network using the internet protocol.

The housing thus makes it possible to control the state of the element of the housing and to change this state via a command issued by a customer, for example, from a computer. In addition, the housing communicates the state of the element so that the client knows the state of the element.

Advantageously, the application layer is able to implement: a protocol for measuring a data relating to an electrical consumption of a circuit connected to the box, and - a protocol for communicating the data to the other box via the power grid using the internet protocol.

The housing thus makes it possible to control the electrical consumption of the circuit connected to it. For example, it is possible to manage the power consumption of the circuit through power consumption control programs from a computer connected to a housing according to the invention itself connected to the power grid. These programs can affect the power consumption of the circuit by using in particular the action protocol on a housing element, for example a voltage converter or an electrical relay.

According to another optional feature of the housing, it comprises an electrical power supply socket adapted to cooperate with a socket of an appliance or the power supply of the appliance via the housing.

The invention relates to a set of an electrical network and a housing electrically connected to the electrical network, wherein the housing is as defined above.

The invention finally relates to a room, including a dwelling, comprising a housing as defined above or an assembly as defined above.

The subject of the invention is also a method of communication by carrier currents in-line between two boxes connected to an electrical network, in which an implementation of an Internet communication protocol between these two boxes is controlled via the electrical network and a network. implementation of a home automation application protocol within one of the housings. -AT-

According to an optional feature, a transmission of a state of an element of one of the housings is commanded: either after a change of state has been ordered or after a request has been sent of State. In one embodiment, the state of the element is communicated if a change of state occurs, thereby ensuring that the change of state has actually been executed by the housing. In another embodiment, the state is communicated regardless of whether a state change has been performed. The communication is preferably periodic. This embodiment makes it possible to control the state of the element at any time. According to another optional feature, it controls a transmission of data relating to an electrical consumption of an electrical circuit capable of being connected to one of the housings: either after a measurement of the data has been ordered, or after we have ordered a transmission of a query of the data. The invention further relates to a computer program comprising instructions able to control the implementation of a method as defined above.

The subject of the invention is also a method in which a step of making a program as defined above over a telecommunication network for downloading is carried out. The housing according to the invention can receive data from another identical housing connected for example to a computer itself connected to the telecommunication network, so it is easy to update the housing.

The invention will be better understood on reading the description which follows, given solely by way of nonlimiting example and with reference to the drawings in which: FIG. 1 is a diagram of a room comprising a plurality of housings according to FIG. invention; Figure 2 is a perspective view of a housing according to the invention; Figure 3 is a diagram of the hardware blocks of the housing of Figure 2; FIG. 4 is a diagram of the protocol blocks of the box of FIG. 2; Fig. 5 is a diagram of a network block of Fig. 4; Figure 6 is a diagram of a software architecture of the housing of Figure 2; Fig. 7 is a flowchart illustrating a method according to an embodiment of the invention; and FIG. 8 is a flowchart illustrating a method according to another embodiment of the invention. FIG. 1 shows a diagram of a room, for example a dwelling 10. The dwelling 10 comprises an electrical network 12. The dwelling 10 also comprises housings 18a-e according to the invention, one of which is shown in Figure 2. In this case, each housing 18a-e comprises a power supply plug 32, male in the present example. The electrical network 12 comprises electrical conductors 20a-d electrically connecting conventional electrical outlets 22a-e to which the housings 18a-e are respectively electrically connected.

The dwelling 10 comprises two computers 24a, 24b. Each computer 24a, 24b is respectively connected to the socket 22e, 22d. The dwelling 10 also comprises a telecommunication gateway 26 connected to the computer 24b and to an external telecommunication network by ADSL for example, for example the Internet.

The dwelling 10 comprises electrical appliances suitable for home use 28a-c, in this case a lamp 28a, a heater 28b and a towel warmer 28c respectively connected to the housings 18a, 18b and 18c. With reference to FIG. 2, only the housing 18a will be described, the housings 18a-e being all identical.

The housing 18a comprises an outer plastic envelope 30, the male power supply plug 32 for connecting the housing 18a to the electrical network 12 and a female power supply plug 34 adapted to cooperate with the plug of the lamp 28a. or the power supply of the lamp 28a. In addition, the housing 18a includes a female computer connector 36. In this case, the connector 36 is of the RJ45 type.

The housing 18a allows messages to be exchanged between the two computers 24a, 24b, via a logical network, called computer network 14, formed on the physical electrical network 12. It also enables messages to be exchanged between home-automation devices 28a-c via a network. logic, said home automation 16, using the electrical physical network 12 and using the functionalities of the computer network 14. Finally, the housing 18a according to the invention allows the exchange of messages between at least one home automation device 28a-c and at least one 24a-b computer via a mixed logical network using the electrical physical network 12 and using the functionalities of the computer network 14. In this case, packets circulate from one box to another on the power grid using the current technology carriers online. These packets include messages intended for computers 24a, 24b and / or home automation devices 28a-c connected to boxes 18a-e. The housing 18a comprises hardware blocks 38-60 shown in FIG. 3. These hardware blocks comprise a connection block 38 comprising on the one hand the connector 36 and, on the other hand a passive circuit. The housing 18a also comprises a block for filtering and connecting 40 the in-line carrier currents, an Ethernet block 42, an in-line carrier block 44, a block 46 forming a microcontroller, a FLASH type memory block 48, a FIG. block 50 of RAM type memory, a block 52 forming a control circuit, a block 54 forming a conversion circuit and a block 56 forming an electrical relay. In this case, the relay 56 is of the electromechanical type. Alternatively, the relay may be of the static type. The choice of the type of relay is made according to the current passing through the housing 18a, the electromechanical relay being preferred for high currents. The housing 18a also comprises a block 58 forming a sensor. This sensor 58 is particularly capable of measuring a current intensity used by the home automation device connected to the housing 18a and the power used by this device. Finally, the housing 18a comprises a block 60 for feeding the blocks 42-58.

The hardware blocks 38-60 are able to implement the protocol blocks shown in FIGS. 4 and 5. The corresponding software layers are shown in FIG. 6. FIG. 4 shows the protocol architecture of the box 18a. The housing 18a is able to implement each of these protocols.

The protocol blocks comprise a network block 62, three layers of which are shown in greater detail in FIG. 5, a UPnP block 64, an actuator block 66 and a sensor block 68. In a conventional architecture, the blocks 64, 66 and 68 form a block. application layer. Each of these protocols is described in a reference document called Request For Comments (RFC). For example, the following reference documents are cited:

List of RFCs for the Ethernet Protocol: RFC 894 (A Standard for the Transmission of IP Datagrams on Ethernet Networks); RFC 894-err (Errata of RFC 894); RFC 3580 (IEEE 802.1X Remote Authentication Dial In

User Service (RADIUS) Usage Guidelines) and RFC 3748 (Extensible Authentication Protocol (EAP)).

- List of RFCs relating to the IP protocol: RFC 791 (Internet Protocol); RFC

815 (Ip Datagram Reassembly Algorithms); RFC 1071 (Computing the Internet Checksum); RFC 1340 (Assigned Numbers (Replaced by RFC 1700)); RFC

1700 (Assigned Numbers); RFC 1349 (Type of Service in the Internet Protocol

After); RFC 1517 (Applicability Statement for the Implementation of Classless

Inter-Domain Routing (CIDR)); RFC 1518 (An Architecture for IP Address

Allocation with CIDR); RFC 1519 (Classless Inter-Domain Routing (CIDR): an Address Assignment and Aggregation Strategy); RFC 1631 (The IP Network Address Translator (NAT)); RFC 1878 (Variable Length Subnet Table for IPv4) and RFC 1918 (Address Allocation for Private Internets).

- List of RFCs for the ARP / RARP protocol: RFC 826 (An Ethernet Address Resolution Protocol) and RFC 903 (A Reverse Address Resolution Protocol).

List of RFCs for IGMP: RFC 11 12 (Host Extensions for Ip Multicasting) and RFC 2236 (Internet Group Management Protocol, Version 2).

- List of RFCs for ICMP: RFC 792 (Internet Control Message Protocol); RFC 1256 (Icmp Router Discovery Messages). - List of RFCs related to TCP: RFC 793 (Transmission Control

Protocol); RFC 896 (Congestion Control in Ip / Tcp Internetworks); RFC 1071 (Computing the Internet Checksum); RFC 1340 (Assigned Numbers); RFC 1323 (TCP Extensions for High Performance) and RFC 2018 (Selective TCP Acknowledgment Options). - List of RFCs related to the UDP protocol: RFC 768 (User Datagram

Protocol); RFC 1071 (Computing the Internet Checksum) and RFC 1340 (Assigned Numbers).

List of RFCs for DHCP: RFC 951 (Bootstrap Protocol (Bootp)); RFC 1497 (Bootp Vendor Information Extensions); RFC 1541 (Dynamic Host Configuration Protocol); RFC 1542 (Clarifications and Extensions for the

Bootstrap Protocol); RFC 2131 (Dynamic Host Configuration Protocol) and RFC 2132 (Dhcp Options and Bootp Vendor Extensions).

List of RFCs for DNS: RFC 1033 (Domain adminstrators operations guide); RFC 1034 (Domain Names - Concepts and Facilities); RFC 1035 (Domain Names - Implementation and Specification) and RFC 1591 (Domain Name System)

Structure and Delegation).

- List of RFCs relating to the NTP protocol: RFC 868 (Time Protocol); RFC 1059 (Network Time Protocol (Version 1)); RFC 11 19 (Network Time Protocol (Version 2)); RFC 1305 (Network Time Protocol (Version 3)) and RFC 4330 (Simple Network Time Protocol (SNTP) Version 4).

- List of RFCs for SNMP: RFC 1155 (V1 - Structure and Identification of Management Information for TCP / IP-based Internets); RFC 1441 (v2c - Introduction to version 2 of the Internet-Standard Network Management Framework); RFC 1901 (V2 - Introduction to Community-based SNMPv2); RFC 3411 (An Architecture for Describing SNMP Management Frameworks) and RFC 3826 (The Advanced Encryption Standard (AES) in the SNMP User-based Security Model).

List of RFCs for the HTTP protocol: RFC 2616 (Hypertext Transfer Protocol - HTTP / 1.1) and RFC 2109 (HTTP State Management Mechanism). The network block 62 comprises four protocol layers 70-76. This block allows in particular the communication powerline online.

The layer 70 forms a so-called physical layer and is divided into two layers 70a, 70b. The layer 70a forms a translation layer of a binary logic signal of the computer network 14 into a physical signal supported by the medium of the housing 18a. The layer 70b is relative to the carrier currents and allows the translation of the physical signal in the opposite direction. The corresponding software layers 71a, 71b are here respectively formed by a 10BAS E-T / 100 BASE-TX layer and a conventional carrier current software layer.

The layer 72 forms a so-called link layer and allows communication between two devices of the computer network 14 or the home network 16. The corresponding software layers 73a-d are respectively formed by layers

Ethernet Data Link Control, SNAP (Sub Network Access Protocol), LLC (802.2 Logical

Link Control) and IEEE 802.3 CSMA / Media Access Control (MAC) CD.

An Address Resolution Protocol (ARP) 73e layer and Reverse Address Resolution Protocol (RARP) enable the determination of addresses between the link layer 72 and the network layer 74.

The layer 74 forms a so-called network layer and allows the routing of packets between two devices of the same network or different networks. The corresponding software layers 75a, 75b are respectively formed by Internet Protocol (IP) and Internet Control Message Protocol (ICMP).

The layer 76 forms a so-called transport layer making it possible in particular to make reliable the data exchanges between the network block 62 and the UPnP block 64. The layer 76 comprises a protocol 76a operating in connected mode and a protocol 76b operating in non-connected mode. These protocols are open type. In this case, the protocols 76a and 76b are respectively the TCP protocols (Transmission Control

Protocol) and UDP (User Datagram Protocol). The TCP protocol makes it possible to ensure a data exchange for which high reliability is required, for example the exchange of data between the computers 24a, 24b while the UDP protocol makes it possible to ensure a fast data exchange, for example between computers 24a, 24b and home automation apparatus 28a-c. The box 18a is able to implement at least one of these Internet protocols for communication with the boxes 18b-e via the electrical network 12.

The UPnP block 64 comprises four protocol layers 64a-d. The protocol layer 64a comprises three protocols 64a1-3. The HyperText Transfer Protocol MUIticast protocol (HTTPT) 64a1 is used to send data to all elements of the power grid 12 using the UDP protocol. The protocol

64a2 HTTPT (HyperText Transfer Protocol Unicast) allows data to be sent to an element of the power grid 12 using the UDP protocol. The HyperText Transfer Protocol (HTTP) 64a3 enables data to be sent to an element of the power grid 12 using the TCP protocol.

The protocol layer 64b comprises three protocols 64b1-3. The Simple Service Discovery Protocol (SSB) 64b1 uses the HTTPMU and HTTPU protocols to advertise and configure the applications that will be used by the 18a.

The Simple Object Access Protocol (SOAP) 64b2 protocol uses the HTTP protocol to exchange data in XML format. The SOAP protocol forms a protocol base for the web-like applications that will be used by the box 18a.

The General Event Notification Architecture (GENA) 64b3 protocol uses the HTTP protocol to communicate data with applications that use the HTTP protocol. Thus, the protocol layer 64c comprises a UPnP protocol (Universal Plug and

Play) allowing the housing 18a to discover the home automation applications available on the home automation network, in particular those of the blocks 64, 66 and 68. In a variant, the protocol layer 64c comprises a Simple Network Management Protocol (SNMP). In addition, the layer 64c may comprise at least one protocol chosen from HVAC and Lighting controls.

Finally, the protocol layer 64d comprises at least one protocol forming a communication interface between the UPnP protocol layer 64c and the actuator and sensor blocks 66, 68. In this case, the layer 64d makes it possible to transmit requests for action of the UPnP layer 64c to the actuator and sensor blocks 66, 68. The layer 64d also makes it possible to transmit data from the actuator and sensor blocks 66, 68 to the UPnP block 64. The corresponding software layers 65a-d are respectively formed by DNS layers. (Domain Name System), Dynamic Host Configuration Protocol (DHCP), Bootstrap Protocol (BOOTP), and Network Time Protocol (NTP).

The actuator block 66 includes an interface 66a for receiving action requests from the UPnP layer 64c. The actuator block 66 also comprises a dialogue interface 66b between the interface 66a and at least one hardware actuator of the housing, for example the electrical relay 56. The interface 66b also allows to operate each hardware actuator. Finally, the actuator block 66 comprises a state recovery interface 66c of each hardware actuator. The interface 66c makes it possible to transmit the state of each hardware actuator of the actuator block 66 to the UPnP block, in this case in the FLASH memory block 48. Thus, the application layer, in this case the actuator block 66 , is able to implement: an action protocol of the interface 66b on an element of the housing 18a, for example the electrical relay 56, and a communication protocol of the interface 66c of a state of the element to the other 18b-e boxes via the electrical network 12 using the internet protocol.

The sensor unit 68 comprises an interface 68a for recovering a state of at least one hardware sensor, for example a sensor for the amount of energy consumed accumulated over a given period of time, or even an instantaneous power sensor consumed by the device. home automation connected to the housing 18a. The sensor unit 68 also comprises a dialogue interface 68b with the hardware elements of the housing 18a. The application layer, in this case the sensor unit 68, is able to implement: a protocol for measuring the interface 68a of a data relating to an electrical consumption of a circuit connected to the housing, and a communication protocol of the interface 68b of the data to the other box via the electrical network using the internet protocol.

Thanks to the application layer, the box is also able to implement at least one home automation application protocol.

We will now describe a communication method according to a first embodiment between two housings 18a-e with reference to FIG. 7. In this case, from the computer 24a, a transmission of a request for control 28a-c action in a step 701. The action request aims to control the closure of the relay 56 of each housing 18a-c so as to light respectively the lamp 28a, the radiator 28b and the towel heater 28c. The request coming from the computer 24a is translated into a physical signal by the box 18e, passes through the electrical network 12 and arrives at each box 18a-c where the physical signal is translated into a control signal. The request is received by the reception interface 66a in a step 703. The request is then translated by the dialogue interface 66b in order to close each relay 56 in a step 705. In a subsequent step 707, the interface 66b controls closing each relay 56. Then, in a step 709, the transmission of the state of each electrical relay of each housing 18a-c is controlled after having controlled the change of the open state for the closed state. In this case, a once the state of each relay has changed, it controls a transmission of the state of each relay 56 of each housing 18a-c to the recovery interface 66c and then to the computer 24a. The state of each relay 56 is maintained in the memory of each corresponding housing 18a-c in a step 711. Thus, it will be noted that, thanks to the method according to the invention, control of an implementation of the Internet communication protocol between two housings 18a-e the electrical network 12 and it controls an implementation of a home automation application protocol.

In a second embodiment, from the computer 24a, a request is issued from the state of each relay 56 of each box 18a-c. Unlike the first embodiment, the transmission of the request is not triggered by the change of state of each relay 56. In this second embodiment, control is preferably, periodically, a transmission of the state of each relay 56. In this case, this request is issued by the UPnP block 64.

We will describe a third embodiment with reference to FIG. 8. In this embodiment, a user of dwelling 10 wishes to know a piece of data relating to an electrical consumption of each home automation appliance 28a-c connected to each housing 18. vs. For this purpose, a transmission of the data is ordered after a measurement of the data has been ordered. In this case, it is controlled from the computer 24a the transmission of a request for the data in a step 801 to each box 18a-c via the network 12. Here, the data is the instantaneous power consumed by each home automation apparatus 28a-c. In a step 803, the UPnP block 64 of each box 18a-c sends the request to the consumer data recovery interface 68a. In a subsequent step 805, each interface 68b measures the instantaneous power consumed by each home automation device 28a-c. Then, in a step 807, the interface 68b transmits this power to the interface 68a, then to the UPnP block 64 and stores them in the corresponding memory of each box 18a-c. In a step 809, then a communication of the power to the box 18e via the electrical network. The user can then recover the power or the powers stored in the memory. Preferably, the data request can be issued periodically so that the communication of the data to the computer 24a is also periodic since it follows the data request.

In a fourth embodiment, a transmission of a request for power is commanded without necessarily having the request request preceded by a request for measuring the quantity consumed by the computer 24a. In this case, such a request is issued periodically by the UPnP 64 block. measured power is then communicated in a similar manner to the third embodiment.

In a fifth embodiment, a transmission of the amount of energy consumed accumulated over a given period is controlled. In the present case, it is ordered that the UPnP block 64 be made available with this quantity of energy. At regular intervals, the UPnP block 64 recovers the amount of energy and stores it in the memory 48 of each housing 18a-c. The memory 48 of each housing is sized to contain N measurements of the amount of energy. The given period and the number N therefore determine the time interval on which each housing 18a-c can measure the amount of energy consumed cumulative. Then, it controls a transmission of a query of the cumulative energy consumed amount values. In the present case, a user wishing to know the value of the quantity of energy consumed in the time interval corresponding to N given periods transmits, from the computer 24a, a request for the values of energy quantity and recovers the value analogously to the third embodiment.

The implementation of the communication method may be controlled by instructions from computer programs when these programs are run on a computer. These programs are stored in the memory 50 of the box and implemented by the microprocessor 46. It will be possible to record each program on a data recording medium such as a flash memory device or a CD type disk or DVD. Finally, it will be possible to make such a program available for download via the Internet for example. Updates of the program can thus be sent by this network to the various elements of the electricity network 12 via the gateway 26 and the computer 24b. Thus, we see that thanks to the housing according to the invention can be controlled home automation devices from a computer via the existing electrical network of a local. This electrical network can also be used to exchange data between two devices connected to two boxes according to the invention. These devices may be computers, peripherals such as printers, cameras, television decoders, electric meter organs, etc. Such a housing thus makes it possible, thanks to programs of management of electrical consumption that can be used via a computer, to control the general electrical consumption of the room via the electrical network.

Advantageously, the housing may be incorporated into a wall of the room so that only the power supply socket 34 and the RJ45 socket (or any other type of connector to the computer network) are visible on the wall. The housing thus provides the function of conventional electrical outlet and a power line housing in line allowing the exchange of messages between computers and home automation devices. The housings are here removable. They could be fixed permanently in the room and advantageously in the thickness of the wall.

Claims

1. Box (18a-e) for online power line communication, characterized in that it is able to implement at least one Internet communication protocol with at least one other identical box (18a-e) via a network. electrical system (12), and to implement at least one home automation application protocol.

2. Housing (18a-e) according to the preceding claim, wherein the home automation application protocol or at least one of the home automation application protocols is chosen from SNMP, HVAC and Lighting controls protocols.

3. Housing (18a-e) according to any preceding claim, adapted to implement a communication using a transport layer and an application layer above the transport layer, the transport layer being suitable to implement the or each Internet protocol and the application layer being able to implement the or each home automation application protocol.

4. Housing (18a-e) according to the preceding claim, wherein the application layer is adapted to implement: an action protocol on a housing element (18a-e), and a communication protocol of a state of the element to the other housing (18a-e) via the power grid (12) using the internet protocol.

5. Housing (18a-e) according to claim 3 or 4, wherein the application layer is adapted to implement: a protocol for measuring a data relating to an electrical consumption of a circuit (28a-c ) connected to the housing (18a-e), and a communication protocol of the data to the other housing (18a-e) via the electrical network (12) using the internet protocol.

6. Housing (18a-e) according to any one of the preceding claims, comprising a power supply plug (34) adapted to cooperate with a socket of a device or the power supply of the device via the housing (18a-e).

7. An assembly of an electrical network (12) and a housing (18a-e) electrically connected to the electrical network (12), characterized in that the housing is in accordance with any one of the preceding claims.

8. Local (10), particularly dwelling, characterized in that the room comprises a housing (18a-e) according to any one of claims 1 to 6 or an assembly according to claim 7.

9. In-line carrier communication method between two housings (18a-e) connected to an electrical network (12), characterized in that it controls an implementation of an Internet protocol for communication between these two boxes via the electrical network and implementation of a home automation application protocol within one of the housings.

10. Method according to the preceding claim, wherein controlling a transmission of a state of an element of one of the housings (18a-e): either after a change of state has been ordered, or after a request has been sent from the state.

1 1. Method according to any one of claims 9 or 10, wherein controlling a transmission of data relating to an electrical consumption of an electrical circuit capable of being connected to one of the housings (18a-e): either after we have ordered a measurement of the data, either after we have ordered a transmission of a query of the data.

12. A computer program comprising instructions adapted to control the implementation of a method according to any one of claims 9 to 11 when executed by a computer.

13. A method in which a step of providing a program according to the preceding claim on a telecommunication network for downloading is carried out.