比利时专利BE1022640B1 Method for managing and extending a network of lamps

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专利摘要:
The present invention relates to a method for operating and expanding a network of lamps, each lamp in the network being assigned to a group, each control module being in communication with a group controller as well as control modules. controlled in the same group. The network can be extended by installing new lamps with their associated control modules (19), and each new control module scans its environment and transmits environmental information to a central server (20) in which the environmental information is analyzed and the new control modules can be divided into groups (21). After dividing into a group where only control modules can be moved from one group to another or a new group is formed, the new control modules are available for normal operation. This process is repeated for each new lamp and associated with the control module.
公开号:BE1022640B1
申请号:E2015/5018
申请日:2015-01-13
公开日:2016-06-23
发明作者:Helmut Schröder；Didier Wellens；Daniël Brand
申请人:Schreder；
IPC主号:

专利说明:

Method for managing and extending a network of lamps
The present invention relates to a method for the management, in particular for the control, and for the extension of a lamp array, in this case in particular for streetlights.
The lamp networks have more and more intelligent controls. For example, remote management systems are known for managing lamp arrays in which a segment controller connected to a management console on a PC controls a certain number of lamps through their control module. The segment controller that is too large to fit into a lamp should be placed so that the lamps to be controlled can communicate with a short distance communication module through it. Segment controller failure results in loss of maneuverability of the lamp array.
It is also known how to equip all the lamp control modules of a network to be controlled with a long distance communication module, for example based on GSM technology, enabling them to communicate with a central server. Given the large number of actively integrated control modules in a long distance communication network and / or operator, noticeable communication costs are generated for this network.
In addition, the commissioning of new lamps in known systems is expensive because the allocation in particular controllers supporting GPS technology to a lamp must be done manually. Finally, because of the large number of lamps that can be controlled by a segment controller, the latency in the network is comparatively high.
The object of the present invention is to create a method for the management and extension of a lamp network which is easier to put into operation, which guarantees a higher operating safety and whose management also costs less .
This object is achieved by a method according to claim 1 as well as an object according to claim 26. Advantageous embodiments of the invention are detailed in the related subclaims as well as in the following description.
The method according to the invention makes it possible to manage a network of lamps in a more economical and secure way against failures. The installation is simultaneously simpler. In the case of a method according to the invention, a plurality of control modules is provided, in which each of the control modules must respectively be assigned or assigned to a lamp, and in which the corresponding control module respectively comprises a long distance communication module (eg GSM, GPRS, iridium or other mobile data network or Ethernet connection), a short distance communication module (ZigBee, 6 LoWPAN or the like), preferably a communication module to near field (preferably with a near field sensor), a geographic module to determine a position of the control module based on a GPS, GLONASS, Galileo, BeiDou or other position determination systems, in satellite, a controller, preferably at least one sensor, and otherwise a control output (eg, based on DALI or 0 and / or 1 to 10 V), nde can be sent to a driver from a light source of the lamp, preferably from a lamp post, via the control output.
In addition, the network has at least one server that can be reached via the long distance communication module and on which a corresponding remote management software can operate. The long distance communication module can be based on different techniques. This may be for example mobile data networks, IP networks or p. ex. long distance peer-to-peer networks.
For the management of the network, the control modules are distributed in one or more groups of control modules, this distribution being done on the basis of the information of control module, environment and / or lamp made available by the modules control.
In addition to the geographic coordinates, the environment information also relates to the information on the neighboring control modules in the short-distance network (eg, the quality of the connection and other RF characteristics and / or neighborhood tables) or environment-specific information (eg ambient light). In the case of lamp information, it may be information about the lighting sources used, their driver and / or other details of the assigned lamp, eg. ex. the current light intensity or gradation. In the case of the information of the control module, it is in particular information relating to the clear identification of the control module as its IP address or another UID (Unique IDentifier).
According to the invention, one of the control modules of each group and / or only the group in the case of a single group is selected on the server to serve as a group controller. The latter allows the other control modules of the corresponding group to communicate using their short distance communication modules. In other words, the internal communication of the group is done using the corresponding short distance communication module. In the group, the control modules of a group respectively form a short distance network, preferably in the form of a mesh network, through the corresponding short distance communication modules. In the (normal) operating state of the network, only the group controller transmits through the long distance communication module to the server its own information, as well as information about the environment, lighting, and / or or control module received by the other control modules via the short distance communication module. The transmission of information is always carried out as indicated above and hereinafter by the transmission of the corresponding data on the basis of specific communication protocols.
In the normal operating state of the network, only the group controller transmits through the long distance communication module to the server its own information, as well as information about the environment, lighting, and / or control module received by the other control modules via the short distance communication module. By normal operating mode is understood here a regular operation of the network in which control modules of the network are respectively assigned to a group and perform their actual task: the control of the lamp,
In use, such a network structure is more secure against failures than previous network systems. Due to the redundant structure of the corresponding control modules in a group, a new group controller can be determined without problem on the server in the event of a failure of a group controller. Once the new group controller is known within a group, i.e. at the level of the short-distance network (PAN = Personal Area Network), the connection of the other control modules does not exist. have not been defined as a group controller is done precisely by this one. A system command on the server as well as a system monitoring on the server can therefore always be kept in this way. Since there is only one active control module (group controller) per group, the costs are significantly lower than when all the control modules communicate separately with the server via their long distance module. corresponding.
The structure of the network internal to the group as a mesh network makes the operational safety and / or the communication at the PAN level also more secure against failures.
Since "in which" is used above or hereinafter to explain process steps, this does not necessarily imply the existence of simultaneity of the related process steps. They can take place simultaneously (without this being an obligation). The extension of the network is also simplified when it automatically detects geographical information, in particular during the first commissioning, preferably generated by the first power up, and therefore by an automatic procedure after the control of a network. new control module. In the case of geographic information, it is location data, that is, coordinates as well as an exact time stamp. Geographic information is recorded by the geographic coordinate module. Simultaneously or successively, a connection is established with a network operator via the long distance communication module. This is preferably a provider of communication lines, for example a provider of a mobile data network. A long distance communication network is usually formed at least by a mobile data network. Communication can in particular be done in roaming conditions so that the same communication information must be predefined in the factory, regardless of where the different control modules will subsequently be installed. On the control module side, the controller and / or the long distance communication module thus has uniform access data.
After connecting to the network operator, the geographic information can then be transmitted to the server together with the new control module and / or lamp specific information. Automated data backup on the server in a corresponding database makes it easy to install streetlights. For reduced communication costs, operator access data specific to a locally available long distance network can be transmitted to the new control module after transmission of its information.
The procedures described above and below also apply to the integration of several new control modules.
In particular, the access data of the operator can be made available to the new control module if he has an electronic SIM card via a firmware. In this case, the new firmware is read on the controller and / or the long distance communication module so that commissioning of the control module is possible at low costs under local conditions. Flexible communication and installation of the corresponding control modules can therefore be achieved by preparing the server-side firmware without requiring equipment other than the new factory modules.
To simplify the management of a plurality of networks, in particular streetlights, it is advantageous that the allocation in a group and the exchange of data with them are done with a server designed as a project server, after the first one. commissioning of the new control module and its first connection to a registration server.
By server, it is not necessary to understand hardware separate means, but it can also be a separation simply related to the project in a remote management program. It can also be virtual servers on the same hardware or in a cloud.
For trouble-free operation after the first request, the project server can preferably obtain information from the registration server about the devices in service.
In order to reduce costs, an interface makes it possible to transmit from the server to the long distance network operator and / or to the network operator information relating to the control module to be activated, to suspend and / or to deactivate with respect to their long distance communications. On the operator side, this ensures that only a small number of control modules (one control module per group) is activated. The other control modules can communicate with the server only via the communication route in the mesh network and then with the server via the group controller. A suspension, in particular of an electronic SIM card, has the consequence that it can be activated in the short term in case of doubt, for example in case of failure of the group controller. The network compensates for the malfunction of a communication route, preferably automatically and thus only with a minimum delay, and establishes a new one. The new communication can be initiated by the control module via a corresponding request from the server or via a request based on time and the attempt to access the operator's network.
Information that other control modules communicate to the normal operating state with the new group controller can then be transmitted by the server to these other control modules.
For the establishment of the mesh network, it may be advantageous for the server to transmit data relating to the different members of the group, in particular to the new control modules, to the corresponding group controller, and that this controller is determined as a relative group controller. to other members of the group. Alternatively or additionally, data on the communication route and / or the desired group controller can be made available to other members of the group so that communication can be done without problem with the server.
Therefore, it can be for the information made available to the information server for the control modules for which they are informed of neighboring control modules of the same group. At the server, these data can be extracted for example taking into account the geographical coordinates of the various control modules.
After a successful initialization or an extension of the mesh network, the group controller can transmit this message to the server. The server can then continue to control the extended group in normal operating mode.
To signal to the operator staff the successful commissioning, for example the successful integration of a control module into the group network (PAN) or the successful contact with a server, when installing a new lamp , a new control module and / or after maintenance operations on the corresponding lamp, the control module, after reaching the desired state, can control the lamp with different brightnesses over a predefined period of time or can be defined.
Preferably, the new control module receives a group of parameters for controlling the lamp after the first installation and / or a new installation. This can be, for example, variation curves.
The management of a lamp array is further enhanced when the control modules of a group can be provided with software updates by means of software transmitted from the server to the group controller and subsequently or simultaneously passed on further. This makes it possible to obtain and / or where appropriate to activate, for example, new functions of the lamp.
As a variant, a server control module can directly obtain a new controller software, in particular a firmware, bypassing the group controller. However, for this purpose, the respective control module must first be reactivated at the operator.
In order for the network to be established as quickly as possible and without delay, any new control modules can automatically scan the short-distance network after the first activation to search for other control modules and thus create a table internally. of the neighborhood containing the next neighbors in the short distance network. The list can be passed on to a server later. After the establishment of a mesh network and the assignment of the group controller, this neighborhood information can in particular be transmitted to the server with other information specific to the lamps and / or the control module.
For fail-safe operation and trouble-free expansion of the network, it is advantageous that, depending on a predefined number of new modules, the spatial density of the new modules, the distance between the new modules and the group controller and / or the recurrence of the disturbing events, at least a part of the control modules, preferably of a group, and in particular on a request at the server level, records information relating to the neighboring control modules via the short distance communication module and the quality of the connection to these modules and transmits directly to the server this information via its short distance communication module and the group controller or via its long distance communication module, the distribution of the groups and the group controller being verified, performed and / or modified as appropriate.
The control modules can, if necessary, switch to another internal communication mode in the PAN, contact and detect the neighboring control modules via the corresponding short-distance communication module and record the quality of the connection to these modules. . Registration of neighborhood information may be time limited. At the end of a given period of time and / or after identification of a predefined number of next neighbors, this information may be transmitted to the group controller if appropriate with other information specific to the control module, the data and / or lamps through the corresponding short distance communication module or the server by the long distance communication module if the connection is activated. At the server level, the distribution of the groups and the group controller can be controlled and / or if necessary carried out again.
It is particularly advantageous for the installation of the network to use a method characterized in that an information carrier arranged on a part of the lamp for recording lamp-specific information is read by the control module automatically. and / or being triggered, preferably for the communication of specific information to the lamp. In the case of the information carrier, it may be a chip, a memory card, an RFID tag or a similar information medium that can be read without contact. The information carrier is in particular preferably read without contact by a field sensor close to the control module. This is for example here an RFID reader communicating with a transponder and / or an RFID tag. The information read can be used at the module for the selection of given operating parameters, they can nevertheless also be used only for transmission to the server for example to be given operating parameters. The maintenance of a lamp array according to the invention is furthermore improved when the lamp-specific information of the new control module is connected on the server side to an inventory list, the contents of this list being able to be displayed from preferably at least partially in case of failure of a part of the lamps. The different parts of the lamp can be provided with a link to an online store or another possibility to place an order so that the purchase of potentially unusable parts can be done without delay.
Instead of requesting fault-based group control modules and / or a number of new control modules, they may preferably observe information about their environment based on the short-distance network preferably a predefined time and / or because of an initialization at the server, it may be relevant here to limit in the short term the communication in the mesh network on the group controller towards the server and to allow only the observation and communicating with the next neighbor in the mesh network on the basis of the short distance module and the corresponding protocol. This is used to create tables and / or neighborhood lists, in which information about the signal strength and / or the quality of the connection with the corresponding neighbors can be recorded simultaneously. This information can be recorded (in the buffer memory) and then transmitted either directly to the server in the case of activation of all long distance communication modules of the control modules, or via the group controller.
For a targeted inspection or the control of the state of a series of control modules, these can be selected before the aforementioned request, preferably on the server side, a density of control modules being for example determined and controlled by the control module. using a predefined or predefined limit value. Information specific to the control module, the environment and / or the lamp can then be re-registered and initialised on the basis of exceeding the limit value.
To enable the server to select the group controller and to integrate the new control modules optimally, it may be advantageous for the corresponding control modules to record and store, during a scanning operation, data relating to to their UID in the short distance network, their IP address in the long distance network, their UID in the short distance radio network, lamp-specific information, data of a number of neighbors in the remote network in particular, up to 50 adjacent control modules, preferably up to 10, in the short-distance network, including any UIDs and / or the connection quality belonging to the neighboring control modules, and then transmit to the server at a preset time this information (data) via the group controller. Because the control module is active, that is, when it has long-distance network enabled access, the server can also receive information directly from the control module.
Commissioning of the network and / or distribution of groups and / or group controllers on the server is preferably automated. Alternatively or additionally, the distribution of groups and / or group controllers remains variable depending on the inputs of the user. This is for example advantageous when, because of a program running on the server, a group controller is not clearly selected.
To maintain latency in the network at a desired level, a predefined number of control modules is assigned to each preference group at the server level, with 200 control modules representing an upper limit. A test and simulation with up to 2000 lamps demonstrated that the latency of larger network groups was too great to ensure proper operation and regular monitoring of the network status.
Preferably, the number is less than 150 control modules per group, in particular less than 50 control modules.
The dependability of a system is also sufficiently optimized when the selection of a controller as a group controller is automatically based on fuzzy logic strategies. Therefore, the suspension or inactive allocation of a control module based on fuzzy logic strategies can also be automated.
The selection of the group controller and / or the assignment of the control modules to the different groups can in particular be done taking into account at least one of the rules for: - the ratio of the active to inactive control modules, - the availability neighbors in the short-distance network, - the number of network malfunctions, - network modifications (new control modules compared to deleted modules), - changes in the connection quality in the short-distance network, - the estimated connection costs in relation to the long distance network operator, - the communication of the sensor data between neighboring groups, - the internal latency of the group (also a delay depending on the distance), - the backup options (replacement of failed group controllers) and / or - for a stabilization element to account for time-based attenuation. Preferably, the rules are represented and linked by an artificial intelligence. These rules can be connected simply on the basis of logical connectors like AND / OR / NOR connectors.
In addition, the dependability is higher when at least one replacement group controller is defined on the server using the control policies, which server switches from a suspended state to active mode in the event of a failure. Current group controller.
For trouble-free recording of the short-distance network environment information and communication in the short-distance network for normal operation (communication with the server), it may be advantageous for the corresponding communication to take place in the network. short distance network on different frequency bands of the same network. The same antennas can preferably be used for this purpose (multiplexing mode).
According to another improvement of the method according to the invention, relevant information for the entire group can be exchanged between neighboring groups. In particular to be able to quickly transmit sensor information and / or data based on sensor information whose relevance concerns the entire group, for example when it comes to the lighting situation of a car itself. When moving or pedestrian, it is advantageous that the corresponding information is transmitted directly to a control module of a neighboring group bypassing the server via the long distance network. This information can in particular go directly from the control module whose sensor has produced the information. The communication can be done accordingly through the long distance network operator, but must not necessarily pass through the server. For the protocol, the server can be informed about the corresponding information. In particular, the information is passed here via the known group controllers in the long-distance network.
Alternatively, data based on the sensor information relevant to the entire group is transmitted by bypassing the server directly over the short distance network on a control module of a neighboring group, preferably by data transmission. on another frequency band than the normal internal operation of the group. A multiplexing mode of the short distance module can also be advantageous here. On the server side, it is advantageous that the control modules can be selected independently of the group in the corresponding software to exchange relevant data for the entire group. This selection can be supported by graphics so that the control modules which must exchange their sensor information are for example identified on an overall map. Large crossings equipped with control modules respectively belonging to different groups at the edge of the neighboring groups can be identified so as to quickly increase the light intensity in the driving direction of a vehicle approach.
The network according to the invention, designed as indicated above and below, also has the corresponding advantages.
The following description of the figures details other advantages and details of the invention. The figures represented schematically illustrate:
Fig. 1 a network according to the invention,
Fig. 2 another object according to the invention,
Fig. 3 a simplified diagram for a method according to the invention,
Fig. 4 another object according to the invention,
Fig. Part of an object according to the invention.
Various technical features of the exemplary embodiments described hereinafter can also be combined in association with embodiments described above as well as with the features of the independent claims and any other claims relating to the objects according to the invention. Insofar as this is relevant, elements with the same functionality have identical reference numbers. According to the method according to the invention for managing and extending a lamp array, the system shown in a simplified manner in FIG. 1 is obtained with a plurality of control modules 1 which are respectively assigned to a module. controller forming a group controller 2. On the hardware side, the group controller 2 is constructed in the same way as the control modules 1. Nevertheless, only the corresponding group controller 2 is able to interact with a server 4 over a long distance connection 3. The other control modules 1 of a group are in a suspended state and / or inactive with respect to long distance communication. Typically, this is access to a local mobile data provider via which the server then remains available on the basis of IP-WAN over the Internet. The communication between the server and the group controllers can for example be done via a conventional internet protocol (TCP / IP).
Within a group 7, the control modules communicate with each other via short distance connections 6. This is preferably a communication based on a mesh network based on IEEE802.15.4, p. ex. ZigBee.
The corresponding groups 7 of the control modules 1, 2 can not generally be seen on the entire group and can thus interfere with each other. However, it can be provided for group-wide communications that neighboring control modules can share and / or exchange or transmit sensor data or corresponding information to one another over the entire group by the through a short distance 8 connection. This can result in actions such as increasing light intensity. Alternatively, this communication can also be done by the controllers 2 corresponding groups that can be seen on the Internet or in the intranet by their IP address. The information on which command module to communicate with which command module and / or the way this module must communicate is defined by the server and can be sent to the entire group, in particular by a unit. multiplexing each control module, for example in the case of short distance communication.
In addition to connecting one or more groups 7 of control modules 1, 2 forming a PAN, a server for managing a network according to the invention can also control a network according to the state of the art with a segment controller 8 (Figure 2). The latter manages a series of 9 lamp controllers. The connection of the segment controller 8 is via an interface 11 allowing data exchange with the server 4. In addition to a connection of several groups 7 via another interface 12 if necessary, the server 4 can manage a data exchange with a user. long distance network operator (operator) 14 via yet another interface (API) 13.
A database 16 interacting with different service modules (clients) generally operates on the actual server. A graphical user interface allows a user to access the server and / or its programs to manage and control the lamp groups.
Figure 3 briefly describes the progress of the construction of a network of streetlights. After the installation of a number of control modules on the street lamps, their environments are scanned in a second phase 20 initiated by the server and / or starting automatically and the corresponding environmental information as well as any other information. specific to the control module and / or lamps are transmitted to the server. This can be done either directly under roaming conditions with a first operator or, if necessary, with another predefined local network operator after a first request from the corresponding control modules. After the transfer of the environmental information and other information from the corresponding control modules of the street lamps, the control modules are determined and assigned in groups. At the PAN level, the integration of the new control module (s) can be done dynamically on the basis of the standard used. The system switches to an extended or regular normal operating mode 22 once the corresponding group controllers have transmitted to the server a data signal on the successful establishment of internal group communication with the new control module. Provided that another number of new, predefined server-level control modules are installed, the process can be restarted in accordance with the feedback loop 23, a new group or group controller allocation can be performed on the server. base of transmitted information and existing rules at the server level.
According to another exemplary embodiment of the invention according to FIG. 4, a plurality of lamps is arranged along a road 24 with corresponding control modules 23 and 23 '. The lamps are part of a group of lamps and / or control modules A predefined by the server. Group A is just as identifiable as group B with dotted lines 26 and / or 27. Lamps with corresponding control modules 28 and / or 28 'which mark a transverse street opening into the street 24 are part of the group B. Circles 31 and 32 internal black characterize a lamp with an active control module, a controller groups. The sensors S1 and S2 are assigned to the corresponding module 23 and / or 28. Radar sensors, infrared sensors (in particular passive infrared sensors) or even inductive loops in the street 24 and / or 29 come into play as sensors. They detect an object in approach, then the control modules adapt the light of the corresponding lampposts of the group to the situation that it is internally to the group or on all the groups.
An object approaching, p. ex. a vehicle is detected for example by the control module 23 of the street lamp with the sensor S1, this information is distributed in the group A, the light of the group A is increased via the control modules 23 and 23 'and this information or the information on the approaching vehicle is transmitted to the controller 28 'of groups of group B through the controller 23' groups. Moreover, the brightness in group B is also suitable for lamps with relevant control modules 28 and / or 28 ', that is to say selected on the server. In a variant, the control module 23 equipped with the sensor S1 can also communicate directly with the group controller of the group B or with the other module 28 and / or 28 'of control of a street lamp assigned to it, whereupon the information is distributed in the network and the corresponding reaction takes place in group B.
The server can proceed to the assignment to a first group of the various control modules and therefore corresponding street lights which must be powered by information from a sensor of a neighboring group and via which the information is transmitted on all the groups. Corresponding input masks are available for this purpose, especially on the server.
A control module according to the invention with which the method described hereinafter is to be converted may preferably be employed as a separate unit on a lamp head, for example a lamp post (see Fig. 7). The main parts of a control module that can be used externally are disclosed in more detail in FIG. 5. In the exploded view shown here, the control module comprises an upper housing portion 33 and a lower housing portion 34. . The lower housing portion must be attached by a gasket 35 to a pedestal to be placed on the upper face of the lamp. The connection to the base is provided by contacts 37 to turn like bayonets. The contacts 37 are fixed on the one hand in the housing 34 and on the other hand support a central platinum unit 38. A controller 39, a long distance remote short distance communication module and an acceleration sensor unit 41 are in particular placed thereon for detecting waves, in particular seismic waves.
An RFID reader that can be placed in a body-side base of the lamp to record lamp-specific data of an RFID transponder in the near field is not shown.

权利要求:
Claims (26)
[1]
A method for managing and extending an array of lamps, particularly street lamps, with a plurality of control modules (1,2,23,23 ', 28,28'), wherein each control modules (1,2,23,23 ', 28,28') is respectively assigned to a lamp and the control modules respectively comprising: - a long distance communication module, - a short distance communication module, preferably a near-field communication module, a geographical module, a controller, preferably at least one sensor and a control output for controlling a pilot of the lamp; with at least one server (4) connectable through the long distance communication module, wherein the control modules (1,2,23,23 ', 28,28') are divided into one or more groups (A, B) control modules (1,2,23,23 ', 28,28') for network management based on control module, environment and / or lamp information available control modules (1,2,23,23 ', 28,28'), one of the control modules (1,2,23,23 ', 28,28') of each group (A, B) being selected to serve as a controller (2,23 ', 28') of groups with which the other control modules (1,23,28) of this group (A, B) can communicate using their communication modules at short distance, the control modules (1,2,23,23 ', 28,28') constituting a short distance network, preferably in the form of a mesh network, within the groups via corresponding short distance communication modules, and in the At the operation of the network, only the group controller (2, 23 ', 28') transmits to the server (4) its own information, as well as the information of the environment, the lighting, and / or the module. control received by the other control modules (1,23,28) via the short distance communication module.
[2]
2. Method according to any one of the preceding claims, characterized in that during first commissioning of at least one new module, preferably by the first power on thereof, this module records geographical information. , established a connection with a network operator, preferably in roaming conditions, via the long distance communication module and transmits the geographical information as well as information specific to the control module and / or the lamps to the server ( 2).
[3]
3. Method according to claim 2, characterized in that the access data of a specific operator to a long distance network available locally are transmitted to the new control module after the transmission of its information.
[4]
4. Method according to claim 3, characterized in that the access data of the operator are made available via a firmware for an electronic SIM card of the new control module.
[5]
5. Method according to any one of the preceding claims, characterized in that by means of an interface (13) to the operator (14) information relating to the new control module is transmitted.
[6]
6. Method according to any one of the preceding claims, characterized in that the continuous data exchange with the new control module is done with a server (4) designed as a project server, after the first commissioning of the new control module and its connection to a recording server.
[7]
7. Method according to any one of the preceding claims, characterized in that the control modules of a group receive software updates by means of software transferred from the server (4) to the group controller.
[8]
8. Method according to any one of the preceding claims, characterized in that the new control module receives from the server (4) a controller firmware.
[9]
9. Method according to any one of the preceding claims, characterized in that the new control module receives from the server (4) a set of parameters to control the lamp.
[10]
10. Method according to any one of the preceding claims, characterized in that after the first power up, the control module controls the lamp with different brightnesses on predefined or predefined time intervals.
[11]
Method according to one of the preceding claims, characterized in that the new control module is assigned to a group (A, B) and the group controller is informed of the new control module.
[12]
12. Method according to any one of the preceding claims, characterized in that according to the number of new modules, the spatial density of the new modules, the distance between the new modules and the group controller and / or a recurrence of disturbing events, at least a portion of the control modules {1,2,23,23 ', 28,28'), preferably of a group {A, B), and in particular on a request of the server part, records information relating to the neighboring control modules via the short distance communication module and the quality of the connection to these modules and transmits this information via its corresponding short distance communication module and the controller (2, 23'28 ') of groups to the server (4) or via its long remote communication module directly to the server (4), the distribution of the groups (A, B) and the controller (2, 23', 28 ') of groups being checked, carried out and / or modified the case appropriate by the server.
[13]
13. The method of claim 12, characterized in that the recording of neighboring information is limited in time.
[14]
14. Method according to any one of the preceding claims, characterized in that the distribution of the groups (A, B) and / or the controller (2, 23 ', 28') groups is done automatically on the server ( 4).
[15]
15. Method according to any one of the preceding claims, characterized in that the distribution of the groups (A, B) and / or the controller (2, 23 ', 28') of groups is maintained at a variable level by the inputs of the user.
[16]
16. A method according to any one of the preceding claims, characterized in that the number of control modules assigned to each group is less than or equal to a predefinable number, in which the number is preferably less than 200.
[17]
17. Method according to any one of the preceding claims, characterized in that the selection of a control module (1,2,23,23 ', 28,28') as a group controller is done automatically on the basis of fuzzy logic strategies.
[18]
18. A method according to any one of the preceding claims, characterized in that the suspension or the inactive allocation of a control module is done automatically on the basis of fuzzy logic strategies.
[19]
19. The method as claimed in claim 17, wherein the selection is made taking into account rules for: ) from active to inactive control, b) the availability of the neighbors in the short distance network, c) the number of network malfunctions, d) the network modifications (new control modules compared to the deleted modules), e) the modification of the connection quality in the short distance network, f) the estimated connection costs to the long distance network operator, g) the communication of the sensor data between neighboring groups, h) the latency, in particular as a function of distance, i) the failure and replacement of the active group controllers and / or j) a stabilization element to account for the time-based attenuation, in which the rules are preferably represented and connected by a artificial intelligence and more particularly on the basis of logical connectors.
[20]
Method according to one of the preceding claims, characterized in that at least one replacement group controller is defined on the server by means of the control strategies, which switches from a suspended state to the active mode. controller failure {2,23,28) of current groups.
[21]
21. Method according to any one of the preceding claims, characterized in that the new control module automatically scans the short-distance network after the first activation to search for other control modules.
[22]
Method according to one of the preceding claims, characterized in that an information carrier arranged on a part of the lamp for recording lamp-specific information is read by the new control module automatically and / or being triggered.
[23]
23. The method of claim 22, characterized in that the information carrier is read via the near field communication module of the new control module.
[24]
24. Method according to any one of the preceding claims, characterized in that the lamp-specific information assigned to the new control module is connected to an inventory list whose content can be displayed at least partially and in particular in case failure of one of the parts of the lamp.
[25]
25. Method according to any one of the preceding claims, characterized in that the control modules transmit to the server data relating to their UID in the short distance network, their IP address in the long distance network, their UID in the network. short-distance radio network, lamp-specific information, data up to 50, preferably up to 10, adjacent control modules in the short-distance network, including any UIDs and / or the link quality belonging to neighboring control modules.
[26]
A lamp array formed by a method as claimed in any one of the preceding claims.

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同族专利:

公开号 | 公开日

AU2015345210B2|2020-12-24|

EP3018979A1|2016-05-11|

US20170311426A1|2017-10-26|

EP3493656A1|2019-06-05|

US20180132339A1|2018-05-10|

US10561002B2|2020-02-11|

AU2021201858A1|2021-04-22|

US9894739B2|2018-02-13|

CN107006105B|2019-05-31|

KR20170091624A|2017-08-09|

PL3018979T3|2019-08-30|

HUE042244T2|2019-06-28|

US20200253027A1|2020-08-06|

RS58565B1|2019-05-31|

AU2015345210A1|2017-06-29|

DK3018979T3|2019-04-15|

EP3018979B1|2019-02-27|

WO2016075107A1|2016-05-19|

CN107006105A|2017-08-01|

PT3018979T|2019-04-30|

JP6715244B2|2020-07-01|

JP2017533564A|2017-11-09|

ES2718373T3|2019-07-01|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

EP14192580.0A|EP3018979B1|2014-11-10|2014-11-10|Method for the operation and expansion of a network of lights|

EP14192580.0|2014-11-10|

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