NL2010680C2 - LIGHTING SYSTEM WITH A MULTIPLE OF BALL LOADS. - Google Patents

Abstract

Lighting system provided with at least one lighting group wherein each lighting group is provided with at least one local control unit and multiple ballasts each provided with an electronic circuit for supplying at least one lamp which in use is connected with a ballast wherein each electronic circuit is provided with a ballast control unit which is communicatively connected with the local control unit, wherein each ballast control unit is arranged for obtaining parameters which characterize a status of the operation of the electronic circuit of the respective ballast, such as the magnitude of a voltage which is supplied to the at least one lamp and a magnitude of the current which runs through the at least one lamp, wherein each ballast is provided with an identification code and wherein the system is arranged such that, in use, each ballast control unit can supply at least one parameter determined by the ballast control unit together with an identification code of the respective ballast to which the at least one parameter relates, to the local control unit.

Description

Title: Lighting system with a multitude of ballasts.

The invention relates to a lighting system provided with at least one lighting group, wherein each lighting group is provided with a local control unit and a plurality of ballasts each provided with an electronic circuit for supplying at least one lamp which is in use with a bahast connected, each electronic circuit being provided with a ballast control unit which is communicatively connected to the local control unit. Such a system is known per se. With this known system, the local control unit is used to control the bahasts for switching the lamps on or off and / or dimming the lamps. The disadvantage of the known systems is that the reliability, efficiency, controllability and controllability of the systems is not optimal. The invention has for its object to provide a solution for at least a part of these problems, more in particular for each of the problems mentioned.

The lighting system according to the invention is accordingly characterized in that each ballast control unit is adapted to obtain parameters that characterize a state of operation of the electronic circuit of the ballast in question, such as the magnitude of a voltage applied to the at least one lamp and a magnitude of the current flowing through the at least one lamp, each ballast being provided with an identification code and the system being arranged such that, in use, each ballast control unit has at least one parameter determined by the ballast control unit together with a can supply identification code of the ballast in question to which the at least one parameter relates to the local control unit. Because the local control unit receives the relevant parameter together with an identification code from the relevant ballast, lighting systems can be obtained with a number of further special properties that solves one or more of the aforementioned problems, if desired. For example, it is possible that a parameter that is generated relates to diagnostic data of a ballast and / or diagnostic data of an at least one lamp associated with the ballast. Such a diagnostic data can for instance comprise a magnitude of the lamp current. This magnitude of the lamp current can say something about the status of the lamp, for example about an aging of the lamp. This allows, if desired, the local control unit to determine whether the lamp in question may need to be replaced. It is also possible that a parameter generated by a ballast control unit is also linked to information about a point in time at which the relevant parameter has been determined. The local control unit then receives the relevant parameter in combination with the identification code as well as with a time or period of time in which the relevant parameter is determined. This makes it possible for the local control unit to determine a trend or trend in such a parameter. If the relevant parameter is, for example, the lamp current at maximum power of the lamp, a certain conclusion can be drawn again over the status of the lamp due to the course of the lamp current over time.

More generally, the local control unit may be arranged to process the received parameters in combination per ballast or per lighting group. As stated, the relevant parameter may be a magnitude of the lamp current, the magnitude of a voltage applied to the lamp, but also, for example, the height of the temperature of the ballast, more particularly within a housing of the bahast and that with a temperature sensor can be measured, the height of a temperature of a lamp that can be measured with a temperature sensor and a magnitude of a pressure in a housing of the ballast that is measured with a pressure sensor. All these parameters can then, if desired, be processed per ballast to gain insight into the status of the ballast in question. Too high a temperature in the ballast can occur due to poor cooling or a too high ambient temperature.

Too high a temperature can be harmful to the lamp, so it can be important to measure this temperature. It is also possible that the relevant parameters are processed per lighting group in order to gain insight into the status of the relevant lighting group. In addition, it is possible that a lighting group is provided with a plurality of sub-lighting groups. A sub-lighting group may, for example, consist of the collection of bahasts that are hung in a certain room. A building can then be provided with different spaces, the bahasts of each room forming a sub-lighting group in which all the ballasts of the rooms concerned are communicatively connected to the relevant local control unit. The local control unit can then be arranged to process the received parameters per sub-lighting group in combination. This can always concern parameters that relate to a single time point. For example, all parameters at a certain time of a certain sub-lighting group can be determined and processed in combination. This also applies to all parameters of a lighting group. However, it is also possible that more than one parameter is delivered per ballast, such as the current, voltage and temperature mentioned. These parameters can then also be processed per ballast, whereby these parameters possibly belong to one and the same time or were obtained at different times. On the other hand, it is also possible that the local control unit is arranged to receive information spread over time from one and the same parameter. This can then be processed in combination per ballast, per sub-lighting group or per lighting group. As a result, for example, a change in the time of the relevant parameter can be determined. Such a change in time can be associated with, for example, an aging of a lamp. The course of a temperature within a housing of the ballast can also, for example, be associated with a leak in the housing of the ballast where cold outside air can penetrate into this housing. Leakage can be harmful to the lamb, for example when moisture penetrates. Too high a temperature can also arise due to poor cooling or a too high ambient temperature.

Too high a temperature can be harmful to the lamp. Of course, other parameters can also be used that relate to the ballast and lamp in question, such as, for example, a measured pressure within the housing of the ballast, an air humidity measured with an air humidity sensor within the housing of the ballast, or parameters that are measured with the aid of a gas sensor obtained in the lamp housing. Such variants are each understood to fall within the scope of the invention.

However, it is also possible that the parameter itself already contains diagnostic data of a bahast and / or at least one lamp associated with the ballast. For example, it is possible that the electronic circuit of a ballast itself is capable of determining diagnostic parameters. It is thus possible for the electronic circuit to determine, for example, on the basis of the course of time of the magnitude of the lamp current at full power when a lamp in question must be replaced. The relevant parameter can then indicate within which period the lamp must be replaced. The parameter can then, for example, run from three, to two, to one and to zero months.

According to a special embodiment, it holds that the local control unit is provided with information about the identification codes of the ballasts and the associated positions of the ballasts. For example, a position of a bahast can represent a (relative) position of a ballast within a building or a geographical (absolute) position such as a GPS code. This makes it possible for the local control unit not only to know when a specific lamp must be replaced, but also where the lamp in question is located. The diagnosis can be performed by the ballast itself.

However, it is also possible that the local control unit draws its own conclusions based on the parameters received, that is, performs a diagnosis itself or generates maintenance advice. For example, a diagnosis may be: the lamp is broken or outdated; where a maintenance recommendation may be: replace the lamp or replace the lamp within a certain time. Thus, it is possible that the local control unit is adapted to generate maintenance advice for the ballasts and / or the lamps on the basis of received parameters, more particularly that the local control unit is adapted to provide maintenance advice based on the parameters received to be generated per ballast and / or per lamp and / or that the local control unit is designed to generate maintenance advice for the ballasts and / or lamps based on the parameters received per lighting group and / or that a lighting group is provided with a multiple of sub-lighting groups in which the local control unit is arranged to generate maintenance advice for the ballasts and / or lamps based on the parameters received per sub-lighting group.

For example, if a parameter indicates that a lamp is aging, the maintenance advice generated by the local control unit may be that all lamps of a sub-lighting group must be replaced or that all lamps of the lighting group must be replaced within a certain period and / or that the lamps of such ballasts must be replaced within a certain period. It is also possible that the local control unit is adapted to diagnose the ballast and / or the lamp on the basis of the received parameters, more particularly that the control unit is adapted to determine per ballast and / or to perform a diagnosis per lamp and / or that the local control unit is designed to perform a diagnosis of the ballasts and / or lamps on the basis of the received parameters per lighting group and / or that a lighting group is provided with a plurality of sub-lighting groups, the local control unit being adapted to perform a diagnosis of the ballasts and / or lamps on the basis of the received parameters per sub-lighting group. The diagnosis may for example consist of analyzing the size of a parameter such as the aforementioned size of a lamp current or measured temperature within a ballast housing. For performing a diagnosis, the local control unit can, for example, compare a measured parameter with a predetermined reference value and / or compare a set of parameters with a set of reference values. The diagnosis can also be performed on the basis of the course of time of a parameter or of a collection of parameters. The speed of the passage of time of a parameter can be compared, for example, with a reference value for performing the diagnosis. Also, the rates of time course of a set of parameters can be compared to a set of reference values for performing the diagnosis.

In particular, it holds that a plurality of the ballasts are each provided with a motion detector, wherein at least one parameter generated by a ballast control unit relates to detected movements with the motion detector of the ballast in question. The relevant motion detector of a ballast can for instance be arranged to switch a lamp of the ballast on and off and / or to adjust the dim level (light level) of the lamp in response to movements detected by the motion detector. For example, the lamp can be switched on or the light level of the lamp can be reduced by dimming it when a movement is detected. However, as stated, the relevant parameter can also relate to this detected movement. The local control unit may, for example, be arranged to process the received parameters of the various ballasts relating to detected movements in combination. For example, it can be determined where movements take place within a certain building at a certain moment. After all, the local control unit can also contain information about a position of a ballast within a building. Because, for example, all positions of the ballasts are known within the building, whereby movements can be detected for each ballast with the aid of the movement sensor of the ballast in question, it is possible, for example, to follow the movements of a person within a building. It is also possible to determine where most movements take place within a building. In particular, it holds that to the parameter which is generated by a ballast control unit and relates to movements detected with the motion detector of the ballast in question, information is also coupled about times at which the movement in question was detected. In this way it is also possible to determine when (at what times) movements take place in a certain area or the intensity of certain movements within a certain area can be determined (amount of movement per unit of time and as a function of location). In particular, it holds that the local control unit is provided with a display wherein the local control unit is provided with information for generating a map of the area where the local control unit is adapted to generate a map on the display of the area in which the local control unit is further adapted to make detected movements visible on the map depending on the location. The map may, for example, comprise a map of a building showing movements detected in this map. This can happen with a color, for example. The color blue can, for example, indicate that movements have been detected somewhere at a specific time. The intensity of the movements can also be determined by determining how many movements are detected per unit of time. In this case one movement can be defined, for example, a movement that takes place uninterruptedly from a certain point in time until another point in time at which the movement disappears. The local control unit can thus be arranged, for example, to generate on the display the map of the area in which the detected movements on the map are made location-dependent (i.e. as a function of the location) visible in combination with information about the times at which the movements detected are displayed and / or where the local control unit is arranged to generate on the display the map of the area in which the displayed movement intensity of detected movements is made location-dependent (i.e. as a function of the location).

According to a practical variant, it holds that the local control unit is provided with a local sub-control unit connected to ballasts and a local server connected to the local sub-control unit and the display. The local sub-control unit is adapted to receive the parameters of the ballasts and in fact thereby functions as a router. The local server is arranged to process parameters received by the local sub-control unit as discussed above. The local sub-control unit can also send information to the ballasts that is supplied, for example, by the local server such as control information to switch lamps on and off and / or to dim them. The local control unit can thus practically be formed by two or more separate devices. In that case, the local server can be arranged to generate the card on the display as discussed above. Of course a card can relate to a complete lighting group or to a sub lighting group. Thus, for example, the display can show the total overview of the lighting group or optionally a sub-lighting group if desired.

The system may further be provided with a portable unit for reading the identification code of the relevant ballast at the location of a ballast and for storing this read-out identification code in the portable unit together with information about the location of the ballast in question and wherein the system is arranged to supply identification codes stored in the portable unit with associated positions to the local control unit. In this way the system can be constructed in a simple manner. The ballasts can thus be placed together with the lamp and the local control unit can be installed. At that time, the local control unit does not yet know which ballasts are located where. Using the portable unit, a person can determine a position and identification code for each of the bahasts and store it there (temporarily) and then store it in the local control unit by having the portable unit read out. This is therefore a handy tool for installing the lighting system. The portable unit may, for example, consist of a smartphone provided with an application) or may consist of a tablet provided with an application) for installing a ballast, which entails reading the identification code of the ballast and storing it in the portable unit of this identification code together with the information about the position of the ballast in question. This smartphone or tablet can then also be read out for supplying to the local control unit identification codes stored in the portable unit with associated positions. The identification code of a bahast can, for example, be stored in the electronic circuit, whereby reading takes place in a wireless manner. The identification code may, for example, be stored in an RFID chip of the electronic circuit of a ballast. However, it is also possible that the identification code of a ballast is not only arranged in the electronic circuit but also on an outside of the ballast in the form of a visible code, such as a barcode or URL code, and wherein the portable unit is arranged to display the visible code to read. In particular, it holds that the portable unit is provided with a receiver such as a GPS receiver, GSM receiver, UMTS receiver or a receiver for a GX network with X greater than 3 for determining the position of a ballast. The portable unit can thus determine its own position and thus the portable unit then determines the position of the ballast during reading of the identification code of the ballast. According to another important aspect of the invention, the connecting system can be arranged such that each ballast can be controlled individually or per lighting group by the local control unit, for example for switching on, switching off and / or dimming the lamp. It is also possible that the lighting group is provided with a plurality of sub-lighting groups as discussed above, wherein the system can then be arranged such that the ballasts per sub-lighting group can be controlled by the local control unit. The local control unit may again be composed of a local sub-control unit and a local server communicatively connected thereto. The local sub-control unit can, for example, be adapted for wireless communication with the ballasts via, for example, Wi-Fi, and in this case acts as a router, for example. The local sub-control unit can also be arranged for, for example, wired communication with the ballasts (by means of a wire or cable). The local sub-control unit can also be connected to the local server wirelessly (e.g. via WiFi) or wired (e.g. via a local network).

According to a very advanced embodiment of the connection system, the system is provided with a plurality of lighting groups, wherein each local control unit of the lighting group is provided with a group identification code and wherein the system is further provided with a central control unit communicating with each of the local control units. The central control unit may, for example, be located at the head office of a particular company while the local control units are located throughout the country at various branch offices of the company. This is only one example for an application of a central control unit. The local control unit can then be connected to a single building while the central control unit is positioned somewhere centrally and communicatively connected to each of the relevant local control units. In particular, it holds here that the central control unit is provided with information about the group identification codes of the local control units and the associated positions of the central control units. In this way the central control unit knows where a local control unit is located from which it receives parameters together with an identification code from the local control unit. The parameters may be parameters generated by the ballasts and received by the local control unit as previously discussed. If a local control unit has performed a diagnosis or has generated maintenance advice, as discussed above, this information can also be sent to the central control unit, possibly together with a group identification code of the local control unit.

In the event that a local control unit is added to the system that already comprises the central control unit, the system may be arranged such that the local control unit stores information on the group identification code stored in the local control unit. of the relevant local control unit to the central control unit. In this way the central control unit knows that the relevant local control unit has been added to the system. The local control unit can then also send information about the location of the local control unit so that the position of the added local control unit is also known in the central control unit. If the added local control unit also already contains information about the identification codes of ballasts that are communicatively connected to the local control unit, possibly linked to information about the positions of these ballasts (for example manually or with the help of the portable unit entered at the local control unit), the local control unit may optionally send these identification codes together with the corresponding positions of the ballasts to the central control unit for storage in the central control unit. In this way, a lighting group can be added to the system in a simple manner.

More particularly, it therefore holds that the system can be arranged such that a local control unit information stored in the local control unit, such as the group identification code of the relevant local control unit and a corresponding position of the local control unit unit can send to the central control unit. The local control unit therefore knows its position itself and reports this to the central control unit. However, it is also possible that the central control unit itself already knows where a local control unit is located (for example, manually entered) and therefore also knows where the local control unit is based on a group identification code that it receives from the relevant local control unit control unit is located. As stated, a position of the local control unit can again be a position within a building or a geographical position such as GPS code or a position of a building in which the local control unit is located. It is of course possible that the central control unit is also placed in the same building where the local control units are located. For example, a building can be so large that a plurality of local control units are inserted therein, for example in mutually different areas of the building, the central control unit being located in a central point of the building in question. Completely analogously as discussed for the local control units, a central control unit can then be provided with information about the identification codes of the ballasts and the associated position of the ballasts of the plurality of lighting groups. The system can be arranged such that a local control unit sends information stored in the local control unit about identification codes of the ballasts and the corresponding position of the ballasts to a central control unit. The central control unit can then store the information about identification codes and associated positions in a memory for later use. The system can further be arranged such that information on parameters generated by a ballast is supplied to the central control unit in a local control unit. It may also be that the system is arranged such that, in use, the information about the time at which the relevant parameter is determined and which is linked to the relevant parameter is also connected by the local control system in a manner linked to the relevant parameter. unit is supplied to the central control unit. The central control unit can then perform comparable operations on the basis of the received parameters and the possible times as discussed above for the local control unit such as the generation of maintenance advice and / or diagnoses per lamp and / or per ballast, per sub-lighting group, and / or per lighting group. Thus, it holds that the central control unit can be arranged to process the received parameters in combination per ballast or per lighting group and / or that the lighting group is provided with a plurality of sub-lighting groups, the central control unit being arranged to receive the received parameters in combination per sublighting group. It is also possible that the central control unit is arranged to process received parameters spread over time in combination with each ballast, per sub-lighting group or per lighting group, for example for obtaining a change in time of the relevant parameters as discussed above for the local control unit. The central control unit can also diagnose the local control units itself on the basis of the received parameters. For example, if the parameters received from a central control unit assume values that cannot match a ballast and / or lamp, this may mean that the local control unit itself is not functioning properly. However, it is also possible that a local control unit is arranged to generate parameters that relate to the operation of the local control unit itself, such as, for example, error codes that are generated by a microprocessor of the relevant local control unit. These error codes can therefore also be supplied to a central control unit for further processing, for example for generating an alarm that a local control unit is broken. Incidentally, it also applies to the local control units that they can generate an alarm when it is detected that a ballast and / or lamp no longer functions properly, or when it is detected that ballasts and / or lamps of a sub-lighting group do not function, or that it is detected that ballasts and / or lamps of a lighting group do not function properly. Such variants are also considered to fall within the scope of the invention.

The central control unit can also be arranged to control ballasts, per ballast, per sub-lighting group or per lighting group for, for example, switching lamps on and off and / or dimming lamps. According to a very advanced embodiment, it holds that the system is arranged to perform the control of the ballasts and / or lamps in response to information received from the system from an electricity provider, in particular that the system is arranged to control the energy consumption of the ballasts for example, in response to received information from the electricity provider such that the energy consumption of ballasts selected by the system is reduced when the electricity provider undergoes a peak in energy delivery. The information from the electricity provider can, for example, be received by a local control unit. The local control unit may, for example, dim and switch off lamps in response to this. However, it is also possible for the central control unit to receive the relevant information from the electricity provider, for example, that the electricity provider undergoes a nationwide peak of energy delivery which may disrupt an electricity network. The electricity provider can then ask the central control unit whether it is possible to save energy. The central control unit can then, for example, control ballasts via the local control units in such a way that lamps are dimmed and / or switched off. The central control unit can also send a request for power reduction to selected local control units, whereby the local control units themselves automatically analyze whether lamps belonging to the relevant local control unit can be switched off or dimmed. In this application, ballast is understood to mean, inter alia, a power supply or circuit for supplying a gas discharge lamp. However, a ballast can also be understood to mean a power supply or circuit for supplying other types of lamps such as LEDs, fluorescent tubes, Xenon lamps, halogen lamps, incandescent lamps and the like.

The invention will now be further elucidated with reference to the drawing. It shows:

Figure la shows a possible embodiment of a lighting system according to the invention;

Figure 1b shows a ballast with lamp of the system according to Figure 1

Figure 2 information that can be displayed on a display of a local control unit and / or central control unit of the system of Figure 1;

Figure 3 shows a map provided with ballasts and detected movements in an area that can be displayed on a display of a local central control unit and / or display of a central control unit of the system according to Figure 1;

Figure 4 shows the map of Figure 3 with selected information of a subgroup of a lighting group;

Figure 5 shows a map with information about the positions of lighting groups that can be displayed on a display of a central control unit of the system of Figure 1;

Figure 6 shows information about lighting groups that can be displayed on a display of a central control unit of the system of Figure 1; and

Figure 7 information about lighting groups that can be displayed on a display of a central control unit of the system of Figure 1 showing further information of one selected lighting group

In Figure 1 reference numeral 1 designates a lighting system according to the invention. The relocation system is provided with three lighting groups 2.1, 2.2 and 2.3. In this example, the lighting system comprises three lighting groups. However, the invention is not limited to this. The lighting system can be provided with one or more lighting groups. An example of the construction of a lighting group is shown in Figure 1 for the lighting group 2.1. The lighting groups 2.2 and 2.3. can be constructed in a similar way.

The lighting group 2.1 is provided with a local control unit 4 and a plurality of ballasts 6.i (i = 1, 2, 3, 4, 5). Every ballast 6.i.

in this example is provided with a lamp 8.i. It is of course also possible that a ballast 6.i is provided with a plurality of lamps. In this example, however, each ballast is provided with one lamp.

Figure 1b shows the ballast 6.i provided with the lamp 8.i in more detail. For each ballast 6.i it holds that it is provided with an electronic circuit 10i for supplying the at least one lamp 8.i. The lamp 8.i is thus connected to the electronic circuit 10i. The electronic circuit controls, among other things, the desired supply voltage and current for the lamp 8.i. The lamp 8.i is in this example a gas discharge lamp. In this example, the electronic circuit is arranged for starting the lamp 8.i, wherein the supply voltage and current are adjusted in a known manner in a heating phase. After heating, the lamp is supplied by the electrical circuit in a manner known per se with a nominal supply voltage and current. As can be seen in Figure 1a, all ballasts are supplied with energy via a supply line 12 which is connected to an energy source 14 such as an electricity network. The energy source may, for example, supply an alternating voltage of 230V while this alternating voltage is converted by the electronic circuit into a direct voltage suitable for the lamp.

In this example, the local control unit 4 is provided with a local sub-control unit 16 and a local server 18 connected to a local sub-control unit 16. The local sub-control unit 16 is communicatively connected to each of the electronic circuits 10.i. of the ballasts. To this end, each electronic circuit 10i is provided with a ballast control unit 20.i which can communicate wirelessly with the local sub-control unit 16. To this end, the local sub-control unit may be provided with, for example, a router which via WiFi with a ballast control unit 20.i. can communicate (in this example through two-way communication). The electromagnetic field used for WiFi is indicated in the figure by 22a with reference number 21.

Each ballast control unit 20.i. is adapted to obtain parameters that characterize a status of the operation of the electronic circuit of the ballast in question. The ballast control unit 20.i is arranged to obtain parameters that characterize a state of operation of the electronic circuit of the ballast in question.

Such parameters may therefore relate to a status of the lamp 8.i. In this example, the parameters that characterize the state of operation of the electronic circuit are the magnitude of the voltage applied to the lamp 8.i. is supplied and the magnitude of the current flowing through the at least one lamp 8.i. runs. These parameters can be determined in a manner known per se by the ballast control unit 20.1. On the basis of these parameters, something can be said about the status of the operation of the lamp. For example, if the current is zero while the voltage for the lamp is not, the lamp may be broken. If the voltage has a nominal value for the lamp while the current does not have this, this may be an indication that the lamp is out of date. The electronic circuit 10.i. for example, it may furthermore be provided with a temperature sensor 22.i. to a temperature of the lamp 8.i. to measure and / or to measure a temperature of a housing 24.i. in which the lamp is located. Such a temperature can also be one of the parameters obtained by the ballast control circuit with the aid of the temperature sensor. Other parameters can also be obtained with the ballast control unit, such as, for example, a pressure in the housing 24.i. representing the ballast control unit with the help of a temperature of a pressure sensor 26.i. is being measured. The parameters listed here are merely examples; other parameters are also conceivable.

It further applies that each ballast 6.i is provided with an identification code. In this example the relevant identification code is in the electronic circuit 10.i. saved. This can for example be stored in a memory of 28.i. of the electronic circuit. The system is further arranged such that, in use, each ballast control unit can supply at least one parameters determined by the ballast control unit together with an identification code of the relevant ballast to which the at least one parameter relates to the local control unit 4 Thus, for example, it may be that information about the voltage applied to the lamp 8.i. is supplied, the magnitude of the current flowing through the lamp 8.i. the measured temperature of the lamp 8.i., the measured pressure in the housing 24.i. together with the identification code of the ballast 6.i. is supplied via WiFi 21 to the local sub-control unit 16.

After this information has been received by the local sub-control unit 16 and thus by the local control unit 4, this information can be processed in various ways. A number of examples will be given below, without the intention of giving an exhaustive list of the possibilities.

In the example, the lighting group 2.i. five ballasts 6.i. includes. It further applies in this example that the ballasts 6.1 and 6.2 belong to a first sub-lighting group 30.1 while the ballasts 6.3 to 6.5 belong to a second sub-lighting group 30.2. In this example, the ballasts of the first sublighting group 30.1 hang in a first room while the ballasts of a second sublighting group 30.2 hang in a second room, the first room and the second room belonging to one and the same building. In this example, the local control unit 4 is arranged in the same building. It may be that the local control unit 4 is arranged to process the received parameters per ballast. It is also possible that the received parameters per lighting group 2.1, 2.2 or 2.3 are processed. It is also possible that the received parameters are processed per sub-lighting group 30.1 or 30.2. In this example, it further holds that the local control unit is arranged to process received parameters spread over time in combination with each ballast, per sub-lighting group and per lighting group.

This makes it possible, for example, to monitor a change in time of the relevant parameters. The parameters received by the local sub-control unit 16 are passed through a local network 32 to the local server 18 which processes the relevant parameters and processes the relevant parameters in combination. By this last is meant that the parameters are combined to perform a processing. Thus, the voltage and current through the lamp can be processed in combination to determine a resistance of the lamp and thereby a status of the lamp. A variation of a single parameter in time can also be determined, for example the change of a parameter per unit of time. Such operations can be performed with the local server.

The local control unit 4 is furthermore provided with a display 32 which is connected to the local server 18. The local server 18 can, for example, generate an image on the display 32 as shown in figure 2. Herein, for example, it is indicated that the connection group 2.1 is provided with five lamps, one local control unit and two sub-lighting groups. Because the parameters in this example comprise the voltage and current per lamp as well as the times at which these measurements were taken, it can be determined how much the instantaneous power is taken by the lamps in question. This can also be determined per lamp. The server can also determine what the total power consumption of the five lamps has been during the past month. It can also be indicated how many hours per month the lamps have been on. It can also be indicated how many hours per lamp a lamp has been on during the past month. It is also possible to determine for each lamp the course over time of g = the power consumed. This too is a form of processing parameters in combination, more in particular determining the course of time of a set of parameters. If the current flowing through one of the lamps is currently equal to 0, it can also be concluded that one lamp is broken. The local control unit may, for example, generate an alarm for a user for this purpose. It can also be indicated how many lamps have been broken in the last month and what, on average, the availability of lamps has been in the last month. This is 96% in this example. In this example, a number of data are shown in Figure 2 from the past month. It is of course also possible to display data from other months. In addition, a number of data is shown that relate to the present, such as the fact that one lamp is broken. The fact that the local control unit can generate an alarm implies in this example that the local control unit, in this example the local server, is arranged to generate maintenance advice for the ballasts and also lamps based on the parameters received. It is also possible that maintenance advice is generated because the system knows how long a lamp has been burning in total. For example, the recommendation may be that the lamp must be replaced within a month. Such recommendations can be generated by the local control unit (in this example by the local server) on the basis of the received parameters per ballast and / or per lamp. However, it is also possible that the relevant advice is generated per lighting group. For example, the advice may be that all five lamps must be replaced. However, it is also possible that such advice is generated per sub-lighting group. For example, if the lamps 6.3 of 6.5 of the sub-lighting group 30.2 have been burning for a relatively long time, the advice may be that these lamps must be replaced within a month while this advice is not generated for the lamps of the sub-lighting group 30.1.

By comparing, for example, the voltage generated and the associated lamp current for a lamp or for each lamp, a diagnosis of a lamp can also be carried out by the local control unit.

For example, if the lamp current is too high or too low, the local server can be diagnosed as having broken or broken lamp. By looking at a pressure measured in a housing of the ballast, it can be concluded that the housing of the ballast is no longer airtight. This is also a type of diagnosis that can be performed by a local control unit. Based on the measured temperature, a conclusion can also be drawn about the status of the lamp. This is also a parameter that can be used to diagnose a lamp. Said diagnosis can be performed per ballast and / or per lamp. However, it is also possible that a local control unit is arranged to perform the relevant diagnoses per lighting group. If, for example, the sum of the currents flowing through the lamps deviates from what one would expect, it can be concluded that a lamp is broken, or is in danger of breaking, in this lighting group, and the advice may be that ahe lamps of the lamps in question lighting group must be replaced because ahe lamps of this group have the same lifespan. Of course, such an analysis can also be performed for a sub-lighting group. It therefore holds that the local control unit is arranged to perform a diagnosis of the lamp and / or ballast on the basis of the received parameters per ballast and / or per lamp and / or that the local control unit is arranged to to diagnose the ballasts and / or lamps on the basis of received parameters, more particularly that the control unit is designed to perform a diagnosis of the lamps and / or ballasts per ballast and / or per lamp on the basis of the received parameters and / or that the local control unit is adapted to perform a diagnosis of the ballasts and / or lamps on the basis of the received parameters per lighting group and / or that a lighting group is provided with a plurality of sub-lighting groups, the local control unit unit is arranged to perform a diagnosis of the ballasts and / or lamps on the basis of the received parameters per sub-lighting group.

One of the parameters generated by a ballast control unit may also relate to diagnostic data of the ballast and or at least one lamp associated with the ballast. Such a diagnostic data may, for example, consist of the magnitude of the aforementioned lamp current. In fact, it says something about the lamp if the lamp is supplied with a voltage known per se. However, it is also possible that the bahast control unit performs a diagnosis itself. In this context, consideration may be given to determining whether the magnitude of the lamp current is below or below a certain threshold. For example, it can be concluded that when the magnitude of the lamp current is below a certain threshold at a known voltage that is supplied to the lamp, the lamp in question is broken. In that case the bahast control unit can generate a parameter that indicates that the lamp is broken and supply this parameter to the local control unit. The diagnosis is then at least partly carried out by the ballast control unit itself. However, as discussed above, a diagnosis can also be performed on the basis of the parameters by the local control unit.

According to a special embodiment, it holds that the local control unit is furthermore provided with information about the identification codes of the ballasts and the associated positions of the ballasts. A position of a ballast can for example be a position of the ballast within a building or a geographical position such as a GPS code. Because the local control unit, in this example the local server 18, knows for example the position of the ballasts within the building as well as the associated identification codes of the ballasts, the local control unit, i.e. the local server, can display on a display. 32 generate a map of the area where the ballasts of the lighting group are present. For example, the map can indicate exactly where the ballasts are present within the area, as shown for example in Figure 3. It is noted that in Figure 1a the lighting group is provided with five ballasts. In practical terms, this will often be many more ballasts as shown in Figure 3.

Figure 3 shows the ballasts associated with a practical embodiment of the lighting group 2.1, i.e. with many ballasts. For each ballast, it is furthermore possible to display information which is determined on the basis of parameters received by the local control unit. For example, it has been indicated for ballasts 16.1 - 6.9 that they have been diagnosed in such a way that they must be replaced. For the ballast 6.10 it is indicated with an exclamation mark that it must be checked, and for the ballast 6.11 it is indicated that it is not lit. Such information is obtained on the basis of parameters received by the local control unit 4 from the ballasts. Figure 4 shows that specific information can also be shown on the display per combi ballast / lamp such as power of the lamp, identification code of the ballast (device ID) burning hours of a lamp (Lamp hours) etc.

In this example, it applies to the ballasts of the lighting group 2.1, which of course can also apply to the ballasts of the other lighting groups 2.2 and 2.3, that the ballasts are each provided with a motion detector 34 (indicated in Fig. La with 34.1 - 34.5), wherein at least one parameter that is generated by a ballast control unit of the ballast in question relates to a detected movement by the motion detector of the ballast in question. Each ballast is therefore provided with a motion detector and each ballast control unit of the relevant bahast generates information in the form of parameters about the detected movements. This information is sent to the local control unit 4 in the form of these parameters. In this example, it applies to each bahast that the motion detector is also used to switch the relevant lamp of the ballast on or off and / or to adjust the dimming level in response to movements detected by the motion detector. So if a movement is detected, the lamp will turn on or burn harder when it is dimmed. To the parameters generated by a ballast control unit and which relate to detected movements in an area around or near the relevant ballast, information is also coupled in this example about times at which the relevant movements were detected. The local control unit 4 is arranged in this example to process received parameters of the various ballasts that relate to detected movements in combination.

More in particular, it holds that the local control unit is adapted to determine, on the basis of the information about the movements detected by the ballasts and the information about the positions of the ballasts concerned, where in an area where the ballasts of the lighting groups are situated movements have been detected. A parameter of a detected movement is accompanied by the identification code of the ballast that has detected the movement in question and possibly sent to the local control unit with the time at which the movement was detected. The local control unit knows where the respective ballast is located in an area and on the basis thereof a movement which is detected by a ballast can be displayed location-dependent, i.e. as a function of the location, on the map of, for example, figure 3. For example, with a circle as shown for ballast 6.13, it can be indicated that movement is currently being detected by ballast 6.13. Because the position of the ballast 6.13 on the map corresponds to a current position, it can thus be determined where a movement is detected in a certain area. If, as in this example, the moment at which movements are detected by a certain ballast is also sent as a parameter, the local control unit can also determine what the movement intensity around a certain ballast is. For example, if there is little movement on average over a day, the affected area around the ballast 6.13 can be colored light gray, for example. If a lot of movement has been detected in the relevant area covered by the motion detector of the ballast 6.14, for example during the last 24 hours, the area around the ballast 6.14 can be colored gray with a dark color. Thus, it is possible to color in the entire map with shades of gray corresponding to a certain movement intensity. As a measure of a movement intensity, for example, the percentage of the last 24 hours in which movements are detected can be taken. Another measure is to count the number of movements in the last hour where a single movement is defined as a continuous movement that starts at a certain point in time and stops again at a later time. The local control unit is thus adapted to make movements detected on the map that are displayed on the display dependent on location. This means that it can be seen per location whether and / or how many movements have been detected. In particular, it holds that the local control unit is arranged to make visible on the map that is displayed on the display information based on the received parameters relating to detected movements, in particular per ballast and / or lamp, per lighting group and / or per sub-lighting group when the lighting group is provided with a plurality of sub-lighting groups that are each provided with at least one ballast. For example, it can be indicated per sub-lighting group that a movement in the area covered by this sub-lighting group has been detected. It can also be indicated per lighting group that a movement has been detected within the area covered by the ballasts of the lighting group. In the example above, however, it applies that a movement is shown per ballast and / or per lamp.

It therefore applies here that the local control unit is arranged on the basis of the information about movements detected by the ballast and the information about the positions of the ballasts in question to determine where in an area where the ballasts of the lighting group are present, the movements are detected. This information can then be displayed in a map of the area as discussed above. Furthermore, as discussed above, it is true that the local control unit is arranged to generate on the display the map of the area in which the detected movements are made location-visible on the map in combination with information about the times at which the movements were detected . For example, at ballast 6.13 it can be stated that the time at which a movement was last detected by the ballast 6.13 is 11.30 a.m. of the relevant day to which the card relates. However, it is also possible, as discussed above, to determine a motion intensity on the basis of the times at which movements were detected, wherein this movement intensity is displayed location-dependent, as discussed above on the basis of the shades of gray. In this example, the combined processing of the relevant parameters and the generation of the card is performed by the local server. The local sub-control unit is therefore only designed for communication with the relevant ballasts.

In the foregoing it is assumed that the local control unit which knows the identification codes of the ballasts of a joining group together with the associated positions of the ballasts. This information is stored in a memory of the local control unit, in this case of the local server.

According to a special embodiment of the invention, this information can be stored in a particularly elegant manner in the relevant memory of the local server. For this purpose, the system is further provided with a portable unit 40. This portable unit 40 is adapted to read the identification code of the relevant ballast at the location of a ballast. This therefore concerns, for example, the situation in which ballasts are installed in front of a certain area and are suspended from a ceiling, for example. At that time it is not known what the exact position of the ballasts in question is and what the identification codes of the ballasts are. However, the portable unit is adapted to read out the identification code of the ballast in question.

As discussed above, the identification code of the ballast in question is located in the electronic circuit of the ballast in question. It may be that the ballast in question is furthermore provided with, for example, a barcode or another readable code such as a QR code that can be scanned with the aid of the portable unit. This then occurs when the ballast is at the position where it will be hung or when the ballast is already hung. The portable unit is furthermore arranged to determine the location of the portable unit. The location of the portable unit 40 then corresponds to the location of the respective ballast. The identification code of the ballast in question is then stored in the portable unit together with the location of the ballast in question. This operation can be repeated by a user for each of the ballasts. After this has been done, the portable unit can be read, whereby all this information is supplied to the local control unit 4 and, in this example, is stored in the local server 18. The portable unit may, for example, consist of a smartphone provided with an application or a tablet provided with an application for reading the identification code of a ballast at the location of a ballast and for storing this identification code in the portable unit, together with information about the position of the ballast in question. The portable unit may be provided with a receiver such as a GPS receiver, GPRS receiver, GSM receiver, UMTS receiver and / or a receiver for a Gx network for determining the position of the ballast. It is noted that the electronic circuit of a ballast can also be provided with an RFID chip in which the identification code of the ballast is stored. The portable unit can then be arranged to read the identification code from the RFID chip. In that case, applying the identification code as a visible code on the counterweight can also be omitted.

In this example it further holds that the system is arranged such that each ballast can be controlled individually and / or per exposure group by the local control unit, for example for switching on, switching off and / or dimming a lamp. In this example it further holds that it is possible to control the ballasts per sub-lighting group, for example for switching the ballasts of a sub-lighting group on and off and / or for dimming the ballasts of a sub-lighting group.

In this example, it further holds that the local sub-control unit 16 is communicatively connected via internet to an electricity provider 42. In this example, the internet connection is indicated by reference number 44. In this example, the system is arranged to perform the aforementioned control of the ballasts in response to information received from the system from the electricity provider 42. Thus, the electricity provider 42 can communicate via the internet connection 44 to the local sub-control unit 16 that the it is desired that the energy consumption of the lighting system 2.1 is reduced. On the basis of this request, the local server may, for example, decide to dim the lights of the sub-lighting group 30.2. The command for this is sent via the local sub-control unit 16.4 via wireless communication (for example with WiFi) or wired communication (for example with a cable or cable) to the relevant ballasts 6.3, 6.4 and 6.5.

For example, the energy consumption of the electricity provider may temporarily have a peak in response to which the electricity provider submits the said request to reduce the energy consumption of the lighting group 2.1. In this example, the electricity provider 42 is connected via internet to the local sub-control unit. It is of course also possible that the electricity provider 42 is connected directly to the local server 18 for passing on the above-mentioned request. Such variants are each understood to fall within the scope of the invention.

In the foregoing it has been indicated that the system, in addition to the lighting group 2.1, is also provided with a lighting group 2.2 and a lighting group 2.3. The structure of the lighting group 2.2 and 2.3 is entirely analogous to that based on lighting group 2.1. was discussed. The lighting group 2.2 is therefore also provided with a local control unit which is communicatively connected to a plurality of ballasts. The number of ballasts of the different relationship groups can, however, vary between themselves.

The lighting group 2.1 may, for example, be located in a different city than a lighting group 2.2. This also applies to the lighting group 2.3. For example, a store chain that is provided with a multiple n (n = 2, 3, 4, ...) of stores where a store Wi (i = 1, 2,3, ...., n) corresponds to a lighting group 2.i. The system of Figure 1 is thus provided in this example with a plurality of relationship groups 2.i where n = 3. Each local control unit 4 of a lighting group is furthermore provided with a group identification code. The system is further provided with a central control unit 50 which is communicatively connected to each of the local control units 4 of the respective relationship groups 2.1, 2.2 and 2.3. In this example, it holds that the central control unit is provided with a central server 52 and a central sub-control unit 54. The central sub-control unit is for example communicative via internet 44 with the local control units 4 of the lighting groups 2.1 - 2.3 connected. The central server is in turn communicatively connected to the central sub-control unit 54. The central sub-control unit thus has a similar function to the local sub-control units and can thus comprise a router and modem as described for the local sub-control unit 16 The central server stores and processes data and therefore has a comparable function as a local server. The central control unit further comprises a terminal 56 with a display 58, wherein the terminal 56 is communicatively connected to the local server via a communication line 60. The display has a similar function as the display of a local control unit, but this set up remotely from the central server. This can be a wire connection. However, it is also possible that the terminal 56 is connected via internet to the central sub-control unit so that the terminal is communicatively connected to the central server 52 in this way.

The central control unit 50 (here the central server) is provided with information about the group identification codes of the local control units and the associated positions of the local control units. A local control unit can supply information stored in the local control unit about the group identification code of the relevant local control unit to the central control unit. In this way the central control unit knows from which local control unit it receives information. For setting up the system it may be that the system is arranged such that a local control unit has information stored in a local control unit about the group identification code of the relevant local control unit, and a corresponding position of the local control unit. local control unit, to the central control unit. The central control unit then stores in its memory (in this example a memory of the central server) information about the various identification codes with corresponding positions of the local control units. A position of a local control unit may again be expressed as a position of the local control units within a building or a geographical position of the local control unit such as a GPS code, as discussed above. A position of a local control unit can also be a position of a building in which the relevant local control unit is located. As stated, a building can, for example, be a store of a retail chain.

Completely analogously as discussed above, the central control unit can further be provided with information about the identification codes of the ballasts and the associated positions of the ballasts of the plurality of joining groups. This information can be received by the central control unit from the local control units in which this information is also stored. Thus, it holds that the system is arranged such that a local control unit can send information stored in the local control unit about the identification codes of the ballasts and associated positions of the ballasts to the central control unit.

The central control unit stores this information upon receipt. In this example, the system is arranged such that information about parameters that are generated by a ballast control unit present in a local control unit can also be supplied to the central control unit. This feeding can then take place in combination with the identification codes of the ballasts concerned to which the information relates. Linked to this information, the group identification code of the relevant local control unit can also be supplied to the central control unit so that the central control unit also knows from which local control unit the relevant information has been received. Information about the time at which the relevant ballast parameters have been determined can also be supplied by the local control unit to the central control unit. The central control unit can therefore also receive the aforementioned parameters determined by the various ballasts and received by the local control unit from the local control unit in combination with the associated identification codes of the ballast and the possible time of day to which the relevant parameters relate.

It is also conceivable that the information (such as diagnostic information and maintenance advice) that is generated by the local control unit on the basis of the parameters of the various ballasts as discussed above is supplied to the central control unit.

The central control unit is arranged to process the received parameters in combination per ballast or per lighting group. This entirely analogously as described above for the processing of parameters by the local control unit. It is also possible that the central control unit is arranged to process the received parameters per sub-lighting group of a lighting group in combination. The central control unit is also arranged to process received parameters distributed in time per ballast, per sub-lighting group and / or per lighting group in combination, for example for obtaining a change in time of the relevant parameters, all entirely analogous as described by the local control units. Completely analogous as described above, the central control unit can generate maintenance advice for the ballast and / or lamps based on the parameters.

However, it is also possible that one of the parameters that the central control unit receives is an error code generated by the local control unit. The central control unit can in that case also be arranged to generate maintenance advice for local control units, for example when a local control unit is found not to function. The central control unit can be arranged to generate maintenance advice for the lighting loads of the relevant lighting group based on the parameters per lighting group. Completely analogously as discussed above for the local control unit, the central control unit (in this example the central server) can be arranged to diagnose the ballasts, lamps and / or local control unit on the basis of the parameters.

The central control unit may be arranged to diagnose the ballasts and / or lamps per ballast and / or per lamp on the basis of the parameters and / or that the central control unit is arranged to use the parameters per lighting group to diagnose the ballasts, lamps and / or local control units. It is also possible for a lighting group to be provided with a plurality of sub-lighting groups, the central control unit being adapted to diagnose the ballasts, lamps and / or local control units per sub-lighting group based on the received parameters.

It therefore applies that the central control unit can process the parameters of the ballasts per lighting group, per ballast or per sub-lighting group entirely analogously, as outlined above for the local control units. So it applies that the central server can perform the same operations as discussed for the local server. The central sub-control unit 54 also has the same function as the local sub-control units.

However, it is also possible that the local control units have already processed the parameters themselves and pass on the result of this processing to the central control unit. For example, on the basis of the magnitude of a lamp current through the local control unit (here by the local server), it can be concluded that the lamp in question is broken. The result of this operation, namely that the lamp is broken, can be transmitted to the central control unit, for example, together with the identification code of the lamp.

The central control unit in this example is also arranged to process the parameters of the various ballasts that relate to detected movements in combination. This operation can for example be carried out per lighting group. Completely analogous as described above, the central control unit can determine on the basis of the information about the movements detected by the ballasts and the information about the positions of the ballasts concerned, where movements are present in an area where the ballasts of a lighting group are present detected. The central control unit is in this example provided with the display 58, the central control unit being provided with information for generating a map of the area, the central control unit being adapted to generate 58 maps on the display the area. This card can then again look like discussed on the basis of Figure 3. Completely analogous to that discussed above, the central control unit may be arranged to display on the map displayed on the central display 58 positions where the ballasts of a particular lighting group are located, together with information about parameters received from the ballasts and / or information generated by the local or central control unit based on the parameters received from the ballast.

Completely analogous as discussed above, the central control unit can be further adapted to make detected movements on the map displayed on the central display 58 location-dependent. Completely analogous to that discussed above, this map can also show information about the times at which the movements were detected and / or it is possible that a movement intensity of the detected movements is made visible on the map. This movement intensity can be calculated by the central control unit (here by the central server) itself. However, it is also possible for the motion intensities already calculated by the local control unit (here by the local server) of one of the lighting groups to be fed via the Internet to the central server so that the central server does not have to perform this calculation again . It is thus also conceivable that a card generated by the relevant local server is supplied to the central server for display on the central display 56. In that case it is therefore not necessary for the central server to perform the calculations for generating the relevant card. However, it is possible that the central server performs all the calculations that the local server makes based on parameters received by the local server from the respective ballasts itself (again).

As shown, the central server in this example can also display the map of Figure 5 on which, by means of balloons 64, the positions of the various lighting groups are shown together with a list 66 with names of these lighting groups. The central server can also display information per lighting group as shown in figure 6. The first column contains a list of names or positions of the lighting groups. In each row there is a plurality of information and parameters mentioned per lighting group such as the number of lamps, sensors, errors, average availability of the lamps, etc. By entering a selection of a specific lighting group 2.i at the terminal 56, the control center can server more specific information in a block 62 are displayed on the display 58 as shown in figure 7.

The central control unit can be arranged to generate a card per lighting group and / or when a lighting group is provided with a plurality of sub-lighting groups, to generate a card per sub-lighting group. For example, if in figure 3 the ballasts 6.1 - 6.9 were to be located in a separate room that is separate from the room where the other ballasts are located, the ballasts 6.1 - 6.9 can be seen as a sub-lighting group where only a map of the area is displayed where the ballasts 6.1 -6.9 are located. Such a variant each fall within the scope of the invention.

In this example, the system is also arranged such that each ballast can be controlled individually and per exposure group by the central control unit. To this end, the central control unit can send commands via the central sub-control unit 54 to a local control unit 16, for example the local control unit of the lighting group 2.1. In this way, for example, the lamps 6.1-6-5 can be switched on, switched off and / or dimmed per lamp. Of course this can also be done per lighting group and / or per sub lighting group as well as for other lighting groups of the system. In the example above, the electricity provider 42 communication was connected to the local control unit 16 of the lighting group 2.1. Completely analogously, the electricity provider 42 can be connected to the local control unit 16 of the lighting group 2.2 or 2.3. However, it is also possible that the electricity provider 42 is connected, for example via the Internet, to the central control unit 50. If, for example, the electricity provider suffers from a peak load, it can send a request to the central control unit whether it is possible to reduce the energy consumption of reduce the lighting groups controlled by the central control unit 50. In response thereto, the central control unit may, for example, send a command to the local control unit 4 of the lighting group 2.1 to dim or switch off lamps belonging to the lighting group 2.1. Such variants each fall within the scope of the invention. In this example, it holds that the terminal 56 is connected to the central server 52 via a local network 60. It is of course also possible that the terminal is connected to the central server via the internet. Thus, for example, the terminal 56 may be located in a boardroom while the central server is located in a different building than the building in which the boardroom is located. It is noted that the processing of the parameters performed by the local control unit and / or the central control unit may also be in obtaining statistical data on the energy consumption of individual ballasts, lighting groups and sub-lighting groups. This can be carried out, for example, by energy consumption per month, per year, per day and the like. Statistical data can also be kept on the lifespan of ballasts and / or lamps and / or local control beds. Such variants are also considered to fall within the scope of the invention. In this example, the ballast is adapted to generate a supply voltage and current for a gas discharge lamp. However, a ballast can also be understood to mean a power supply or circuit for supplying other types of lamps such as LEDs, fluorescent tubes, Xenon lamps, halogen lamps, incandescent lamps and the like.

Claims (60)

A lighting system comprising at least one lighting group wherein each lighting group is provided with at least one local control unit and a plurality of ballasts each provided with an electronic circuit for supplying at least one lamp connected to a ballast in use, each of which electronic circuit is provided with a bahast control unit which is communicatively connected to the local control unit, characterized in that each ballast control unit is adapted to obtain parameters that indicate a status of the operation of the electronic circuit of the ballast in question characterize, such as the magnitude of a voltage applied to the at least one lamp, a magnitude of the current flowing through the at least one lamp and a pressure and / or temperature within a housing of the bahast, each ballast being provided with an identification code and wherein the system is arranged such that, in use, each ballast contour role unit can supply at least one parameter determined by the ballast control unit together with an identification code of the relevant ballast to which the at least one parameter relates to the local control unit. 2. Lighting system according to one of the preceding claims, characterized in that the local control unit is provided with information about the identification codes of the ballasts and associated positions of the ballasts. 3. Lighting system according to claim 2, characterized in that a position of a ballast represents a position within a building and / or a geographical position such as a GPS code. 4. Lighting system as claimed in any of the foregoing claims, characterized in that information is also linked to a parameter that is generated by a hallast control unit about a point in time at which the relevant parameter is determined. 5. Lighting system as claimed in any of the foregoing claims, characterized in that the parameters relate to diagnostic data of a ballast and / or an at least one lamp associated with the ballast. 6. Lighting system as claimed in any of the foregoing claims, characterized in that the local control unit is arranged to process the received parameters in combination per ballast and / or per lighting group and / or that a lighting group is provided with a plurality of sub-lighting groups, wherein the local control unit is arranged to process the received parameters per sub-lighting group in combination. 7. Lighting system as claimed in claims 4 and 6, characterized in that the local control unit is arranged to process received parameters spread over time in combination with each ballast, per sub-lighting group and / or per lighting group, for example for obtaining a change in time of the relevant parameters. 8. Lighting system as claimed in any of the foregoing claims, characterized in that the local control unit is adapted to generate maintenance advice for the ballasts and / or the lamps on the basis of the received parameters, more particularly that the local control unit is arranged to generate maintenance advice per ballast and / or per lamp on the basis of the received parameters and / or that the local control unit is designed to generate maintenance advice based on the parameters received per lighting group for the ballasts and / or lamps and / or that a lighting group is provided with a plurality of sub-lighting groups, the local control unit being adapted to generate maintenance advice for the ballasts and / or lamps based on the parameters received per sub-lighting group. 9. Lighting system as claimed in any of the foregoing claims, characterized in that the local control unit is adapted to diagnose the ballasts and / or lamps on the basis of the received parameters, more particularly that the control unit is adapted to perform a diagnosis of the lamps and / or ballasts on the basis of the received parameters per ballast and / or per lamp and / or that the local control unit is designed to diagnose the ballasts based on the received parameters per lighting group and / or to carry out lamps and / or that a lighting group is provided with a plurality of sub-lighting groups, the local control unit being arranged to perform a diagnosis of the ballasts and / or lamps on the basis of the received parameters per sub-lighting group. 10. Lighting system as claimed in any of the foregoing claims, characterized in that a plurality of the ballasts are each provided with a motion detector, wherein at least one parameter generated by a ballast control unit relates to detected movements with the motion detector of the ballast in question. 11. Lighting system as claimed in claim 10, characterized in that a motion detector of a ballast is adapted to switch a lamp of a ballast on and / or off and / or to adjust the dimming level of the lamp in response to a motion detector detected by the motion detector. movements. 12. Lighting system as claimed in claim 10 or 11, characterized in that to the parameter which is generated by a ballast control unit and which relates to detected movements, information is also coupled with the motion detector of the ballast concerned about times at which the movements concerned were detected. . Illumination system according to one of the preceding claims 10-12, characterized in that the local control unit is arranged to process the received parameters of the various ballasts relating to detected movements in combination. 14. Lighting system as claimed in claims 2 and 13, characterized in that the local control unit is adapted to determine on the basis of the information about the movements detected by the ballasts and the information about the positions of the ballasts concerned where in an area where the ballasts of the lighting group are present movements have been detected. An illumination system according to any one of the preceding claims, characterized in that the local control unit is provided with a display wherein the local control unit is provided with information for generating a map of the area in which the local control unit is arranged to generate a map of the area on the display. The lighting group according to claim 15, wherein the local control unit is further adapted to display on the map being displayed on the display the position where ballasts are located, together with information about parameters received from the ballasts and / or information that is received from the ballasts. based on parameters received from the ballasts generated by the local control unit. 17. Lighting group as claimed in claims 14 and 15, characterized in that the local control unit is arranged to make detected movements visible depending on the location and / or wherein the local control unit is further arranged to display on the map which is displayed on the display make detected movements visible per ballast and / or per lamp, per lighting group and / or per sub-lighting group when the lighting group is provided with a plurality of sub-lighting groups that are each provided with at least one ballast. An illumination system according to claims 12 and 17, that the local control unit is adapted to generate on the display the map of the area on which the detected movements are made visible on the map in combination with information about the times at which the movements are made detected and / or wherein the local control unit is arranged to generate on the display the map of the area in which location-dependent visualization of detected movements is made visible. The lighting system according to any of claims 15-18, characterized in that the local control unit is provided with a local sub-control unit connected to the ballasts and a local server connected to the local sub-control unit and the display connected where the local sub-control unit is adapted to receive the parameters from the ballasts and the local server is adapted to process the parameters received by the local sub-control unit. An illumination system according to any of claims 15-18 and according to claim 19, that the local server is provided with the information for generating the map of the area, wherein the local server is arranged to generate the map of the area on the display wherein the local server is arranged to make movements detected location-dependent (as a function of the location) visible on the map displayed on the display and / or wherein the local server is arranged to generate the map of the area on the display where on the map the detected movements are made location-dependent visible in combination with information about the times at which the movements are detected and / or where the local server is arranged to generate on the display the map of the area where the displayed intensity of movement of detected movements is shown made visible depending on location. A lighting system according to any one of the preceding claims 15-20, characterized in that a lighting group is provided with a plurality of sub-lighting groups which are each provided with at least one ballast and wherein the local control unit is adapted to generate the card per sub-lighting group . The lighting system according to claim 2, characterized in that the system is further provided with a portable unit for reading the identification code of the ballast in question at the location of a ballast and for storing this identification code in the portable unit together with information about the location of the ballast in question and wherein the system is adapted to supply identification codes stored in the portable unit with associated positions to the local control unit. The lighting system according to claim 22, characterized in that the portable unit consists of a Smart Phone provided with an application or a Tablet provided with an application for reading the identification code of the ballast at the location of a ballast and for inserting it into the Storing this identification code in a portable unit together with information about the position of the ballast concerned and for supplying to the local control unit identification codes with associated positions stored in the portable unit. An illumination system according to claim 22 or 23, characterized in that the identification code of a ballast is also arranged on the ballast in the form of visible code such as a barcode or QR code and wherein the portable unit is arranged around the visible code to read. The lighting system according to any of the preceding claims 22-24, characterized in that the portable unit is provided with a receiver such as a GPS receiver, GPRS receiver, GSM receiver, UMTS receiver and / or a receiver for a Gx -network with x> 3 for determining the position of a ballast. Lighting system according to one of the preceding claims, characterized in that the system is arranged such that each ballast can be controlled individually and / or per exposure group by the local control unit, for example for switching on, switching off and / or dimming a lamp and / or that a lighting group is provided with a plurality of sub-lighting groups, the system being arranged such that the ballasts per sub-lighting group can be controlled by the local control unit. A lighting system according to any one of the preceding claims, characterized in that the system is provided with a plurality of lighting groups, wherein each local control unit of a lighting group is provided with a group identification code and wherein the system is further provided with a central control unit unit that is communicatively connected to each of the local control units. The lighting system according to claim 27, characterized in that the central control unit is provided with information about the group identification codes of the local control units and associated positions of the central control units. The lighting system according to claim 27 or 28, characterized in that the system is arranged such that a local control unit can send information stored in the local control unit about the identification code of the relevant local control unit. An illumination system according to claim 29, characterized in that the system is arranged such that a local control unit has information stored in the local control unit about the identification code of the relevant local control unit and a corresponding position of the local control unit can send. A lighting system according to claim 28, 29 or 30, characterized in that a position of a local control unit represents a position within a building and / or a geographical position such as a GPS code, or a position of a building in which the local control unit is .. An illumination system according to any one of claims 27-31, characterized in that the central control unit is provided with information about the identification codes of the ballasts and associated positions of the ballasts of the plurality of lighting groups. An illumination system according to any one of claims 27-32, characterized in that the system is arranged such that a local control unit stores information stored in the local control unit about identification codes of the ballasts and associated positions of the ballasts. can send the central control unit. An illumination system according to any one of the preceding claims 27-33, characterized in that the system is arranged such that information present in a local control unit about parameters generated by a ballast control unit is supplied to the central control unit and / or that the system is arranged such that a local control unit sends information about the result of a processing of parameters by the relevant local control unit to the central control unit. Lighting system according to one of claims 27-34 and according to claim 4, characterized in that the system is arranged such that, in use, the information about a point in time at which the relevant parameter is determined and which is linked to the relevant parameter is also is fed by the local control unit to the central control unit in a manner linked to the relevant parameter. A lighting system according to any one of the preceding claims 27-35, characterized in that the central control unit is arranged to process the received parameters in combination per ballast or per lighting group and / or that a lighting group is provided with a plurality of sub-lighting groups wherein the central control unit is arranged to process the received parameters per sub-lighting group in combination. The lighting system according to claims 35 and 36, characterized in that the central control unit is arranged to process received parameters spread over time in combination with each ballast, per sub-lighting group or per lighting group, for example for obtaining a change in the time of the relevant parameters. A lighting system according to any one of the preceding claims 27-37, characterized in that the central control unit is adapted to generate maintenance advice for the ballasts, lamps and / or local control units based on the parameters. 39. Lighting system as claimed in claim 38, characterized in that the central control unit is arranged to generate maintenance advice for the ballasts and / or lamps of the relevant lighting group on the basis of the parameters per lighting group and / or that the central control unit is arranged to generate maintenance advice on the basis of the parameters per ballast and / or per lamp and / or that a lighting group is provided with a plurality of sub-lighting groups, wherein the central control unit is arranged for ballasts on the basis of the received parameters per sub-lighting group and / or lamps to generate maintenance advice. Lighting system according to one of the preceding claims 27-39, characterized in that the central control unit is adapted to diagnose the ballasts, lamps and / or local control units on the basis of the parameters. Lighting system according to claim 40, characterized in that the central control unit is adapted to diagnose the ballasts and / or lamps per ballast and / or per lamp on the basis of the parameters and / or that the central control unit is arranged to on the basis of the parameters per lighting group to diagnose the ballasts, lamps and / or local control units and / or that a relational group is provided with a plurality of sub-lighting groups, the central control unit being arranged to determine the ballasts based on the received parameters, diagnose lamps and / or local control units per sub-lighting group. Lighting system according to one of the preceding claims 27-41 and according to one of the preceding claims 10-21, characterized in that the central control unit is arranged to combine the parameters of the various ballasts relating to detected movements in combination . The lighting system according to claim 42, characterized in that the central control unit is arranged to process the parameters of the various ballasts that relate to detected movements per lighting group in combination. Lighting system according to claim 32 and according to claim 42 or 43, characterized in that the central control unit is adapted to determine on the basis of the information about the movements detected by the ballasts and the information about the positions of the ballasts in question where in an area where the ballasts of a lighting group are present movements have been detected. An illumination system according to any one of the preceding claims 27-44, characterized in that the central control unit is provided with a central display, wherein the central control unit is provided with information for generating a map of the area in which the central control unit local control unit is arranged to generate a map of the area on the central display. The lighting system of claim 45 wherein the central control unit is further adapted to display on the map being displayed on the display the position where ballasts are located together with information about parameters received from the ballasts and / or information based on parameters received from the ballasts generated by the local control unit or central control unit. Lighting system according to claims 44 and 45, characterized in that the central control unit is further adapted to make movements detected on the map displayed on the central display visible depending on the location. An illumination system according to claims 12, 35 and 47, that the central control unit is adapted to generate on the central display a map of the area in which on the map the detected movements are made visible location-dependent in combination with information about the times at which the movements are detected and / or wherein the central control unit is arranged to generate on the central display the map of the area in which the movement intensity of detected movements is made visible on the map depending on the location. An illumination system according to any of claims 45-48, characterized in that the central control unit is provided with a central sub-control unit communicatively connected to the local control unit and a central server connected to the central sub-control unit and the the central display is connected, the central local sub-control unit being adapted to receive the parameters from the local control unit ballasts, and the central server being adapted to process the parameters received by the central sub-control unit. A lighting system according to any of claims 45-48 and according to claim 49, that the central server is provided with the information for generating the map of the area, wherein the central server is arranged to generate the map of the area on the display wherein the central server is adapted to visualize movements detected on the map displayed on the central display and / or wherein the central server is adapted to generate on the central display the map of the area on which the detected movements are made location-dependent visible in combination with information about the times at which the movements are detected and / or where the central server is arranged to generate on the central display the map of the area in which the intensity of detected movements is made visible on the displayed display . The lighting system according to any of claims 45-50, characterized in that the central control unit is adapted to generate a card per lighting group and / or that a lighting group is provided with a plurality of sub-lighting groups, the central control unit being designed to generate the map per sub-lighting group. Lighting system as claimed in any of the foregoing claims 27-51, characterized in that the system is arranged such that each ballast can be controlled individually and / or per lighting group by the central control unit, for example for switching on, switching off and / or dimming of a lamp and / or that a lighting group is provided with a plurality of sub-lighting groups, the system being arranged such that the ballasts per sub-lighting group can be controlled by the central control unit. Lighting system according to one of the preceding claims 27-52, characterized in that a local control unit is communicatively connected to the central control unit via the internet. 54. Lighting system according to one of the preceding claims, characterized in that the communication connection between the bahast control unit of a ballast and a local control unit is wireless or wired. 55. A lighting system according to claim 26 or 52, characterized in that the system is arranged to perform control in response to information received from the system from an electricity provider, more particularly that the system is arranged to control the energy consumption of control the ballasts in response to information received from the electricity provider, such that the energy consumption of ballasts selected by the system is reduced when the electricity provider undergoes a peak in energy delivery. The lighting system according to claim 55, characterized in that the electricity provider is communicatively connected to a local control unit and / or central control unit for transmitting the information from the electricity provider to the lighting system. An illumination system according to any one of the preceding claims 27-56, characterized in that the central control unit is arranged to provide information about received parameters and / or about results of the processing of the received parameters by the local control unit and / or the central control unit, for example on a display. A lighting system according to any one of the preceding claims 27-57, characterized in that a central control unit is arranged to generate an alarm when based on the received parameters by the local control unit and / or the central control unit it is determined that a ballast and / or lamp is defective. An illumination system according to any one of the preceding claims, characterized in that a local control unit is adapted to output information about received parameters and / or about results of the processing of the received parameters, for example on a display. Lighting system according to one of the preceding claims, characterized in that a local control unit is arranged to generate an alarm when it is determined by the local control unit on the basis of the received parameters that a ballast and / or lamp is defective .