FR2919946A1 - Urban lighting network for use in luminous spot teleprocessing field, has coordinator establishing communication with lighting sources via router for controlling operation of sources according to predetermined lighting scene - Google Patents

Abstract

The network (10) has wireless communication radio frequency routers (18, 20, 22) for defining sub-communication networks (24, 26, 28) of lighting columns (12) with light sources e.g. urban lighting source, in its communication range, respectively. Each lighting source communicates only with the radio frequency routers under normal operation. An autonomous and central programmable coordinator (32) establishes communication with the lighting sources via one of the radio frequency routers for controlling an operation of the lighting sources according to a predetermined lighting scene.

Description

FIELD OF THE INVENTION The present invention

  relating to the management of urban lighting, and in particular the remote management of the light points constituting such lighting.

  More particularly, the present invention relates to an urban lighting network comprising lighting sources, each of the lighting sources being equipped with a wireless communication module for receiving data relating to its operation and a module of control of its operation according to the data received by the communication module.

  PRIOR ART In traditional urban lighting, the lighting and extinguishing of the candelabra are carried out from the power supply cabinets thereof. These cabinets are usually equipped with brightness sensors and programmers that cut or connect the power supply of the candelabra according to a predefined lighting scenario.

  In such urban lighting, there is no tool to know the state of operation of the candelabra, except a visual inspection by an operator. In addition, the modification of the lighting scenario requires the reprogramming in situ of the 25 programmers and thus the movement of an operator.

  To overcome these disadvantages, urban lighting networks have been designed and operated remotely.

  EP-A-1 201 010 discloses an urban lighting network in which the candelabras are each equipped with a wireless radio transmission module and a control unit for their light source according to order. received by the radio transmission module.

  The candelabra powered from the same electrical cabinet form a communication sub-network with a control unit of their power supply arranged in the cabinet. The communication between the control unit and a particular candelabrum of this sub-network is done by repetition, each candelabrum performing the function of repetition of a message received, but not intended for it, to the candelabra which are neighbors. Thus a message sent by the control unit to a particular candelabra reaches the latter along a transmission chain formed candelabra arranged between the unit and the particular candelabra.

  Finally, the control units of the electrical cabinets of the lighting network are themselves connected by a radio link to a router, itself connected to a supervision station. This makes it possible to manage the lighting scenario of the network remotely and in a more flexible manner without this requiring in-situ reprogramming as in conventional lighting networks.

  However, in this type of network, if the communication chain is cut off, for example in the event of failure of the radio transmission module of a candelabrum, communication with the following candelabra in the communication chain is difficult.

  Moreover, in the case where it is desired that a candelabrum can communicate with candelabra other than its nearest neighbors to ensure that the failure of a single candelabrum does not cut the chain into two non-communicating islands, the communication protocol becomes more complex

  It is generally noted that this type of communication protocol is difficult and / or expensive to manage.

SUMMARY OF THE INVENTION

  The object of the present invention is to solve the aforementioned problem by providing a remote lighting network managed by remote using a simple and standardized communication protocol.

  For this purpose, the object of the invention is an urban lighting network comprising lighting sources, each of the lighting sources being equipped with a wireless communication module for receiving data relating to its operation and of a module for controlling its operation as a function of the data received by the communication module. According to the invention, this network comprises:

  at least one wireless communication unit, defining in its communication range a sub-network of lighting sources, each of the sub-network lighting sources being configured, in normal operation, to communicate only with the light source; communication unit; an autonomous and programmable coordinator, able to establish a wireless communication with each of the lighting sources of the lighting network, via the at least one communication unit, for controlling the operation of the lighting source according to a scenario predetermined lighting.

  In other words, the communication in the network is hierarchized into autonomous communication subnetworks, each subnet being configured in a star having a communication unit with which the lighting sources communicate directly. Each communication unit also interfaces between the lighting sources and a coordinator in charge of controlling their lighting.

  Thus, the failure of a lighting source does not jeopardize the communication of other lighting sources.

  According to particular embodiments of the invention, the network comprises one or more of the following features: a plurality of communication units defining a plurality of subnets, each communication unit being arranged to establish a direct wireless communication with the coordinator or to establish an indirect wireless communication with the coordinator via at least one other communication unit of the network; the network comprises means for measuring the ambient luminosity associated with the coordinator, and the coordinator transmits, for the illumination sources, data relating to the switching on and off thereof as a function of the measured brightness; the light sources are equipped with power variation means of their light source, the network includes means for measuring the ambient luminosity associated with the coordinator, and the coordinator transmits, for the light sources, data concerning the variation of

  power of the light source thereof according to the measured brightness; the network further comprises a data server capable of communicating, on the one hand with an operator, and on the other hand with the coordinator through a broadband high speed data communication network, said server and the coordinator being able to communicate for the update of the lighting scenario of the coordinator according to orders received from the operator; each light source further comprises means for producing and transmitting data relating to its operation, and the network further comprises a data server able to communicate with the coordinator through a high-speed communication network. data server, said server being able to list and / or locate faults in the lighting network according to the operating data transmitted by the lighting sources; the means for producing data relating to the operation of the lighting source comprise means for measuring the electrical intensity consumed by the latter; the lighting source comprises a module for diagnosing the operating state of its light source as a function of the measured electrical intensity; and the coordinator includes a wireless broadband communication module. BRIEF DESCRIPTION OF THE FIGURES

  The present invention will be better understood on reading the following description, given solely by way of example, and with reference to the appended drawings in which identical references designate identical or similar elements, and in which: Figure 1 is a schematic view of a network according to the invention; and FIG. 2 is a schematic view of a candelabrum of the network of FIG. 1.30 DETAILED DESCRIPTION OF THE INVENTION

  In Figure 1, an urban lighting network is illustrated under the general reference 10.

  The lighting network 10 comprises candelabra 12 supplied with electricity from electrical cabinets 14.

  Each candelabrum 12 comprises a light source and a unit 16 for managing its operation. This unit 16 comprises a radiofrequency module for the wireless transmission and reception of data concerning the operation of this source and a control module of the light source according to the data received by the radio frequency module, as will be explained in more detail. thereafter.

  According to the invention, the data communication in the street lighting network 10 is hierarchical according to a wireless communication network topology of the MESH type implementing, for example, the IEEE 802.15.4 standard, or a protocol inspired by this standard.

  More particularly, the lighting network 10 comprises a plurality of wireless communication radiofrequency routers 18, 20, 22. Each of these routers 18, 20, 22 defines in its communication range a sub-network 24, 26, 28 of communication. A router is also able to communicate with any other router located in its communication range.

  The candelabra 12, located in the sub-network 24, 26, 28 associated with a router 18, 20, 22, are configured to communicate, in their normal operating state, only with the router 18, 20, 22. L all the communications concerning the candelabra of a sub-network consequently pass through the corresponding router.

  The lighting network 10 also comprises a programmable central coordinator 32, connected according to a radio frequency wireless communication with each of the routers 18, 20, 22, and in charge of managing the lighting of the set of candelabra 12 according to a predetermined scenario.

  Furthermore, the routers 18, 20, 22 are arranged such that each of them is in direct communication with the coordinator 32 or with at least one other router.

  Thus, when a router 18, 20, 22 and the central coordinator 32 are in their respective communication range, the communication between them is established directly. This is for example the case of routers 20 and 22 of Figure 1 which communicate directly with the coordinator 32 because of their proximity to it.

  Otherwise, the data exchanges between the coordinator 32 and a router 18, 20, 22, too far away to establish direct communication with the coordinator, are made along a wireless communication chain whose links are made up of other links. routers. This is for example the case of the router 18 of the subnet 24 which communicates with the coordinator 32, via the router 20 of the subnet 26. The router 20 thus ensures the repetition of the message sent by the router 18 to the coordinator 32 .

  Preferably, the routers 18, 20, 22 are installed in the electrical cabinets 14, so as to cover the maximum of candelabra and maintain a link with the maximum of routers.

  Advantageously, each electrical cabinet 14 is also equipped with a power measurement module of the supply feeder (not shown), such as a power meter, to permanently know the consumption of candelabra it feeds. This power measurement module communicates with the router installed in this cabinet, for example by means of a wired connection, for the communication of these measurements to the coordinator 32.

  However, a router can be installed anywhere, including a candelabrum. For example, when the range of a router installed in a cabinet does not reach all the candelabra powered by this cabinet, an additional router is installed to cover the candelabra out of reach. This is for example the case illustrated in Figure 1 by the router 20 which is arranged in a candelabrum powered from a cabinet itself equipped with the router 18.

  The coordinator 32 comprises a transmission / reception radiofrequency module 34 for data communication with the candelabra 12 via the routers 18, 20, 22, an autonomous wireless broadband communication module 36, connected to the radiofrequency module 34, and a brightness sensor 38 connected to the wireless broadband communication module 36 wired or by means of a wireless link.

  The module 36 comprises a microprocessor information processing unit 40 which implements, for example, a JAVA machine. This JAVA machine implements a scenario, preprogrammed in the unit 40, for controlling the lighting of the candelabra 12 as a function of the brightness measured by the sensor 38.

  The information processing unit 40 determines in particular the extinction and ignition times of the candelabra 12 as a function of the brightness measured by the sensor 38 and time stamp data (hour and month) coming from a clock embedded in the module 36. The unit thus sends, via the radiofrequency module 60 and to the candelabra, orders for switching on, extinguishing or varying the power of their light source. The candelabras 12 execute these commands once they have received them via the routers 18, 20, 22.

  The coordinator 32 is thus autonomous since it alone manages the operation of the light sources of the candelabra 12 from a predetermined lighting scenario, internally generated timestamp data and measurements of a brightness sensor which is associated.

  The network 10 also comprises a data server 44 connected to the coordinator 32 via a data communication network 46. For this purpose, the module 36 also comprises a wireless high-speed communication modem 42, such as for example a GPRS modem. , a 3G modem or an Edge modem for example, driven by the information processing unit 40

  All the operating data transmitted by the candelabra 12 are thus received, via the routers 18, 20, 22, by the coordinator 32 which retransmits them to the data server 44 via the communication network 46.

  The data server 44 lists and locates the defective candelabra according to the operating data transmitted by them. The result of this monitoring and of this fault location is for example displayed on the screen 48 of a terminal 49. For example, a graphic interface is implemented in which the candelabra are symbolized on a geographical map in association with information concerning their normal or faulty operation.

  In a preferred embodiment, the information on the candelabra, including their operating status and their geographical location, are stored in the form of a database. This database is downloadable and / or searchable from a personal digital assistant connected to the data server via the broadband wireless network. Thus, an operator in charge of the maintenance of the network has a portable means indicating to him during his travels which are the defective candelabra.

  Advantageously, the terminal 49 is also used by an operator to reprogram the lighting scenario implemented by the coordinator 32. An operator can thus define a scenario other than the current one and download the corresponding instructions in the coordinator 32. in response, updates the candelabrum control strategy 12.

  In addition, the coordinator 32 periodically polls the data server 44 for possible changes in the lighting scenario. In the event of any modification of the scenario, the coordinator 32 then executes a procedure for downloading this modification in order to update its own scenario.

  FIG. 2 is a schematic view of a candelabrum 12 of the lighting network of FIG. 1.

  The candelabrum 12 comprises a light source 50, for example a discharge lamp or a set of high intensity light emitting diodes, and a power supply module 52 supplying the light source 50 from an alternating electric grid 54. These bodies are conventional and will not be described in more detail.

  The candelabrum 12 also comprises a unit 56 for managing its operation, for example implemented in the form of a printed circuit board.

  This unit 56 comprises, for its power supply from the AC mains 54, a converter 58 transforming the AC voltage of the network 54 into a regulated DC voltage and filtered. The unit 56 also comprises, for the wireless transmission and reception of data, a radio frequency module 60 equipped with an antenna 62 and a controlled switch 62, such as a relay or a thyristor for example. The switch 62 is, for example, interposed in a supply line 64 between the supply module 52 and the AC network 54, and opens or closes the supply line 64 according to received commands.

  The management unit 56 further comprises a power variator (not shown) which controls the intensity of the brightness emitted by the light source 50, for example a dimmer.

  The unit 56 also comprises a current sensor 66, arranged in a power supply line between the light source 50 and the power supply module 52, as well as a microcontroller 68, connected to the radio frequency module 60, to the sensor 66 and to the piloted switch 62.

  The microcontroller 68 controls the state of the switch 62 according to commands received by the radio frequency module 60. The microcontroller 68 also diagnoses the operating state of the light source 50 as a function of the current measurement of the sensor 66. and controls the radio frequency module 60 for the latter to transmit information concerning the defective state of the light source 50 when such a state is diagnosed. This information is received by the data server 44 via the routers 18, 20, 22 and the coordinator 32. The data server 44 then lists the defective candelabra as a function of received fault state information.

  Finally, the microcontroller 68 examines the state of reception by the radio frequency module 60 and implements a security mode when it finds that no communication with the router on which it depends is possible. For example, the microcontroller controls the switch 62 and / or the power variation module of the intensity of the light source to keep it lighted.

  For example, the lighting network implements the Tiny One system from One RF. The radiofrequency module 60 of the candelabrum is then a Tiny One Plus Reduced Function Device (RFD) module and the routers and the network coordinator include for their communication TinyOne Plus high-power Full Function Device (FFD) modules. .

  In another example, the lighting network implements the Telegesis system of the company ETRX2.

  Preferably, the communication range of the radio frequency module 60 is at least 400 meters, and the communication range of the routers is at least 1000 meters.

  It has been described a lighting network with a single coordinator. However, several lighting networks can coexist (for example a network per district of a city), the network coordinators being however connected to the same data server for the surveillance and the location of the defective candelabra, as well as the update lighting scenarios.

  An application of the invention has been described to a network comprising candelabras. Of course, the present invention is applicable to all types of urban lighting sources, such as appliques, ground lights, light terminals, building lighting lights, etc ...

Claims (9)

  An urban lighting network (10) comprising illumination sources (12), each of the illumination sources (12) being equipped with a wireless communication module (60) for receiving data relating to its operation and a module (68) for controlling its operation as a function of the data received by the communication module (60), characterized in that it comprises: at least one communication unit (18, 20, 22) without wire, defining in its communication range a sub-network (24, 26, 28) of illumination sources, each of the illumination sources (12) of the sub-array (24, 26, 28) being configured, in operation normal, to communicate only with the communication unit (18, 20, 22); an autonomous and programmable coordinator (32), able to establish a communication with each of the lighting sources (12) of the lighting network (10), via the at least one communication unit, for controlling the operation of the lighting source (12) according to a predetermined lighting scenario.   2. Network according to claim 1, characterized in that it comprises a plurality of communication units (18, 20, 22) defining a plurality of sub-networks (24, 26, 28), each unit (18, 20, 20). , 22) being arranged to establish direct wireless communication with the coordinator (32) or to establish indirect wireless communication therewith via at least one other communication unit (18, 20, 22) of the network.   3. Network according to claim 1 or 2, characterized in that it comprises means (38) for measuring the ambient brightness associated with the coordinator (32), and in that the coordinator (32) transmits to the sources illumination (12), data relating to the switching on and off thereof according to the measured brightness.   4. Network according to any one of the preceding claims, characterized in that the light sources (12) are equipped with means of variation of power of their light source (50), in that it comprises means (38) measuring the ambient brightness associated with the coordinator (32), and in that the coordinator (32) transmits, to the light sources (12), data relating to the power variation of the light source (50) of these according to the measured brightness.   5. Network according to any one of the preceding claims, characterized in that it further comprises a data server (44) capable of communicating, on the one hand with an operator, and on the other hand with the coordinator (32). ) through a high-speed data broadband communication network (46), said server (44) and the coordinator (32) being able to communicate for updating the coordinator's lighting scenario (32) by function of orders received from the operator.   Network according to any one of the preceding claims, characterized in that each lighting source (12) further comprises means (60, 66) for generating and transmitting data relating to its operation, and in that it further comprises a data server (44) able to communicate with the coordinator (32) through a high-speed data communication network (46), said server (44) being able to list and / or locate faults in the lighting network according to the operating data transmitted by the lighting sources (12).   7. The network of claim 6, characterized in that the means for producing the data relating to the operation of the lighting source comprises means (66) for measuring the electrical intensity consumed by it.   8. Network according to claim 7, characterized in that the illumination source comprises a diagnostic module of the operating state of its light source (50) as a function of the measured electrical intensity.   9. The network of claim 5, 6, 7 or 8, characterized in that the coordinator (32) comprises a wireless broadband communication module (42).