EP3378286B1 - Ballast for luminous means having a microprocessor and a programming interface - Google Patents

Description

The invention relates to a ballast for at least one light source and in particular an LED that can be largely and essentially freely configured by a user.

The document DE 10 2014 200 297 A1 shows a control gear and a communication adapter for outdoor lighting systems. In particular, the transfer of configuration data via one of several interfaces is shown.

The document US 2012/0086345 A1 shows a lighting system in which various components of the lighting system communicate with one another by means of encrypted optical signals.

The document U.S. 2015/0257229 A1 shows a lighting system in which the various components of the lighting system communicate with one another by means of encrypted wireless radio communication.

The document W. Caelli ET AL: "Cryptographic Application Programming Interfaces (APIs)", XP 055600804 , shows cryptographic methods, especially in relation to the control and programming of applications.

For this purpose, the ballast has a programmable Microprocessor that has a relatively large computing power and in different ways, ie can communicate with the aid of a variety of interfaces. A DALI, SPI, DSI, WLAN, Bluetooth, LAN or USB interface can be provided for this purpose.

Both sensors and signal transmitters can be connected to the ballast, and the microprocessor is connected to the interfaces in order, for example, to also evaluate sensor signals and signals from signal transmitters. Based on incoming signals from sensors and/or signal transmitters, or signals coming in via the interfaces, the microprocessor can then, for example, change the operating properties of the ballast and thus, for example, influence the light emission or other functionalities of the ballast. Communication with external communication partners is possible, for example, via LAN, Bluetooth, USB, DALI, WLAN, ....

In particular, the ballast has a programming interface via which application software can be transmitted to a memory unit provided in the ballast. This is a software and/or software component that can be executed and run by the microprocessor and that can be part of a firmware and/or the operating system or can be executed by it. The application software is then executed, inter alia, by the microprocessor. The operating system manages in particular a memory area divided into a user area ("user space") and a Operating system core area ("kernel space") can be divided. This division serves to allow protection of parts of the memory area. The operating system kernel area is then reserved for executing the operating system kernel, while the user area is provided for executing application software and/or drivers for interfaces and/or devices connected to the microprocessor. The memory area can be part of a memory provided by the memory unit.

By transferring the application software to the memory of the ballast and preferably the user area, a user can influence and define the manner in which the ballast behaves, or how, for example, signals from sensors or signal transmitters are evaluated and used to control the at least one light source will. It can also be configured how an evaluation for controlling components connected to the ballast via the interfaces is processed. In particular, the evaluation and processing of input signals can be configured or changed by means of the application software and, in particular, lighting control can be defined as a function of detected signals.

The invention thus provides a ballast and a luminaire according to the independent claims. Developments of the invention are the subject matter of the dependent claims.

Fig. 1

einen schematischen Überblick über ein Ausführungsbeispiel der Erfindung,

Fig. 2

exemplarische Anordnungen und

Fig. 3

eine Ausgestaltung der Erfindung.

The invention will now also be described with a view to the figures. Show it:

1

a schematic overview of an embodiment of the invention,

2

exemplary arrangements and

3

an embodiment of the invention.

A microprocessor 2 is therefore provided in the ballast V, which microprocessor is connected to at least one memory unit 3 so that it can access the memory unit 3 and read data from there and write data to it.

The microprocessor 2 (e.g. ARM Cortex-A5x, ARM Cortex-A7x, ...) is preferably provided on a circuit board 1, which preferably has at least one edge, and on which the memory unit 3 can also be mounted. The microprocessor 2 and/or the memory unit 3 can also be provided on a separate circuit board which is connected to the circuit board 1, for example by means of a socket connection. The board has a programming interface P on the at least one edge and at least one signaling interface S, which can also be attached to the at least one edge of the board, but also to another edge of the board.

At least the programming interface P is accessible from outside the ballast. The programming interface for a wired or set up wireless communication. In particular, the programming interface P can be a radio interface (Bluetooth, WLAN, ZigBee, RFID, ...) or a wired (parallel, RS323, USB, JTAG, GPIO, ...) interface. It is therefore not always necessary for the programming interface P to be exposed to the outside, for example. Rather, for example, the programming interface P can also be accessed inductively from the outside in order, for example, to transmit data from a programming device 4 to the memory unit 3 and/or the microprocessor 2 by means of the programming interface P. This ensures that the ballast V can be designed to suit its place of use and can have a prescribed degree of protection (International Protection Code (IP) certification), for example.

It is of course also possible for the programming interface P to be exposed to the outside. The programming interface P can thus be accessed by means of a wired connection. A programming device 4 can thus be connected to the programming interface P by means of a cable and data can be transmitted to or from the memory unit 3 and/or the microprocessor 2 .

Data transmitted via the programming interface P, which can then be stored in the memory unit 3, can be used to configure the microprocessor 2 or its information processing. In particular, application software A (also called “app”) can be transferred to or into the storage unit will. This application software A is then executed by the microprocessor 2, it being understood that the microprocessor 2 can also execute a large number of application software components.

The programming interface P and the signaling interface S can, for example, also use the same hardware and only be separated in terms of software.

The application software A stored in the memory unit 3 and executed by the microprocessor 2 can then influence one of the following functionalities of the ballast V:
For example, the interaction or the evaluation of sensor data supplied by sensors interacting with the ballast V can be defined or changed. In particular, the sensors can transmit signals via the signaling interface S to the ballast. These signals are then evaluated by the at least one application software A and processed according to a definition specified by the application software A.

Instead of sensors, other signal transmitters such as switches, buttons or control input devices (also generally referred to as “controls” in the field of the invention) can of course also supply signals via the signaling interface S to the ballast V. These signals can, as described above for the signals supplied by sensors, then also corresponding to the at least one Specifications defined in the application software are evaluated and processed.

However, the application software A can also be used to specify how the ballast V interacts with the connected signal sources (sensors, signal transmitters, ...). In particular, it can be determined which signals are evaluated or processed and with which type of signal generator the ballast V works together. In this way, the signal sources can be defined whose signals are evaluated at all. Signal sources or interfaces can also be blocked or released and it is possible, for example, that the range of functions of the ballast V can be expanded or restricted in this way.

The at least one application software A can also influence the controller with which the ballast V controls the at least one light source, for example. The lighting means can thus be controlled by the application software A, in particular depending on the incoming signals from the signal sources. Here too, for example by transferring new application software A, the behavior of the connected lighting means and/or devices can be changed. An application software A, which is stored in the memory unit 3 of the ballast V, can of course also change the evaluation of the signals.

Another functionality of the application software A is that it can also be used to change the functionality provided by the ballast Vv, and In particular, provided interfaces can be activated or deactivated. The range of functions of the ballast V can also be controlled in this way. Likewise, communication protocols that are provided for communication between the ballast and communication partners, for example other ballasts, operating devices or central control units, can be activated or deactivated. In this way, the ballast V can be adapted for different application scenarios, for example by only requiring individual communication protocols. On the other hand, the functionality of the ballast V can also be expanded if additional communication protocols need to be added or deactivated. This can be the case, for example, if the application scenario for the ballast changes. Overall, the application software therefore allows the operating data and/or operating parameters of the ballast V to be recorded, defined, evaluated and changed.

It should be understood here that the at least one application software A in the memory unit 3 can also be updated and changed. This can then also be done via the programming interface P. In addition, it is possible for more than one application software A to be stored in the memory unit 3 and executed by the microprocessor. By adding an application software A, additional features of the ballast V can be activated or deactivated. For example, it is possible that an application only provides a basic functionality, while another application software A additional functionalities of the ballast V deactivated or activated.

The application software A can also provide or change an application programming interface. This application programming interface can then be used to add further software components to the application software, which also relate to functionalities of the ballast, and in particular to activate or deactivate functions.

The microprocessor 2 preferably executes a hardware abstraction subsystem (HAL, Hardware Abstraction Layer). The application software then preferably accesses the programming interface and/or the signaling interface via the hardware abstraction subsystem. The programming interface can be a wireless or wired interface.

The signaling interface S can likewise be a DALI or DSI, SPI or I ² C interface.

The programming interface P can also be designed in such a way that programming or the transmission of application software is initially not possible. A programming interface that is initially blocked in this way can require that a code or an activation key, for example a cryptographic key, must first be transmitted to the ballast in order to activate the programming interface P. Especially the programming interface P can only be activated (for example for a predetermined period of time) if a corresponding activation of the programming interface P has taken place. For example, the application software can also be transmitted in encrypted form via the programming interface, with the ballast having a first code or activation key, eg a cryptographic key, which is stored in the ballast. For example, this first code or activation key, eg cryptographic key, is a public key that can be used to decrypt the application software transmitted on the programming interface. Preferably, only decryption is possible with this first code or activation key, eg cryptographic key, but no encryption. The programmer may have a second code or activation key, eg cryptographic key, which is a type of private key and which preferably can be used for both encryption and decryption. In this way, the programming device can enable encrypted transmission of the application software via the programming interface, with the ballast being able to receive and read out this encrypted application software.

In addition, the programming interface p can only be activated if, for example, a programming device 4 is positioned at a certain distance from the programming interface P or is connected to the programming interface P. The programming device 4 can then automatically receive an identifier or a key via the programming interface P transmitted to the microprocessor 2, which is recognized by this (e.g. using NFC). The microprocessor 2 can then allow data to be transferred to the memory unit 3 and thus enable the programming interface P to be activated.

The ballast V can also have wired and/or wireless communication interfaces in order to communicate with other ballasts or operating devices, for example. These communication interfaces are attached to an edge of the circuit board, for example. Likewise, the ballast V can have a converter interface via which one or more other ballasts or converters can be connected to the ballast. The application software A or the microprocessor 2 can thus control one or more other ballasts or converters connected to the ballast V. The microprocessor 2 is in particular a single-chip system (system on a chip, SoC). The interfaces made available in the ballast are all attached to at least one edge of the circuit board 1, for example.

The shape of the circuit board 1 essentially corresponds to an n-corner. Alternatively, a round or oval shape would also be possible. For example, the circuit board can be essentially rectangular, triangular or trapezoidal in shape, and the interfaces provided can be arranged along the edges of the circuit board 1 accordingly. The microprocessor 2 with the memory unit 3 can be connected wirelessly or by wire to the circuit board.

A corresponding, purely exemplary representation is in 1 shown. 1 shows a circuit board 1 of a ballast V, on which a microprocessor 2 and a memory unit 3 are arranged. The essentially trapezoidal design of the circuit board 1 shown as an example has four edges which are labeled a, b, c and d. Different interfaces can now be attached to the edges a, b, c, d of the circuit board 1, which can also be assigned to different functional groups. For example, the interfaces on a first edge a can be set up for communication with other ballasts (converters) or other participants in a lighting system. On the first edge a, interfaces are shown as examples, which are designed, for example, as a communication interface for communication using DALI, SPI and/or I ² C (inter-integrated circuit) buses/protocols. On the other hand, interfaces for communication with control units ("Controls") can be provided on a second edge b. a DALI, a Bluetooth (Bluetooth Low Energy, BLE) and a LAN interface are shown as examples on the second edge. An interface P is provided at a third edge c.

The interface P is preferably the programming interface. As already mentioned, this can be protected against access by mechanical or software-related measures, or can be activated selectively. A programming device 4 is also shown as an example, from which at least one application software A can be transmitted to and/or from the interface P, which is can also be a Bluetooth (e.g. BLE) interface.

Finally, interfaces are provided on a fourth edge d, which are used, for example, to connect sensors and/or other hardware that is to be connected to the ballast. A WLAN (or WiFi), a USB and a serial RS232 interface are shown here as examples. These can, for example, enable communication with a microphone arrangement 5, a moisture sensor 6 and/or a presence sensor 7. The sensors can be active or passive.

The programming interface P and the signaling interface S can, for example, also use the same hardware and only be separated in terms of software. For example, the signaling interface S can be used for the encrypted transmission of the application software A, with this encrypted transmission forming the programming interface P in this case. Thus, the signaling interface S is also used for encrypted transmission of the application software A and thus also forms the programming interface P. In this case, the signaling interface S and the programming interface P use the same hardware as infrastructure, but are separate in terms of software. The programming interface P can use the signaling interface S for data traffic, in particular for the transmission of the application software A.

The ballast V can have a first code or Activation key, eg cryptographic key, have that is stored in the V ballast. For example, this first code or activation key, eg cryptographic key, is a public key which can be used to decrypt the application software A transmitted on the programming interface P. Preferably, only decryption is possible with this first code or activation key, eg cryptographic key, but no encryption. The programmer may have a second code or activation key, eg cryptographic key, which is a type of private key and which preferably can be used for both encryption and decryption. In this way, the programming device can enable encrypted transmission of the application software A via the programming interface P, with the ballast being able to receive and read out this encrypted application software.

The application software A can be transmitted via the programming interface P in individual packages. For example, these packets can each be provided with a port address. The packets with the port address can be received by the ballast V and assigned to the appropriate port within the ballast. The individual packets can be transmitted via the programming interface P in encrypted form. The ballast V can receive the encrypted packets and be assigned to the appropriate port according to their port address.

In 1 is also another ballast (also Converter called) or at least one other participant of a lighting system 8 shown, which can be communicatively connected to one of the interfaces on the first edge a. In this respect, the interfaces at edge a can also be referred to as converter interfaces. A coupling element 9 (eg a switch or router) can be connected to the interfaces on the second edge b, for example, via which the ballast can be connected to other components/ballasts. A time control circuit 10 or time switch can also be connected to one of the interfaces on the second edge b. In addition, communication with a remote control 11 via radio or infrared and corresponding interfaces is also possible. In addition, the signaling interface is labeled S as an example. In principle, any interface that is different from the programming interface is to be regarded as the signaling interface S.

It should be understood that the circuit board 1 does not have to be a regular geometric body. The interfaces arranged on the at least one edge can also be arranged one above the other in the manner of a pyramid. In particular, a further interface arranged above/below an interface can be arranged slightly offset to the inside of the circuit board 1 . The programming interface can be protected against misuse in that it can be separated in terms of hardware and/or secured cryptographically.

The signaling interface S can be used to connect switches, timers, remote controls, etc.

A separate interface can be provided for other signal transmitters such as sensors (motion sensor, brightness sensor, humidity sensor, microphones, presence sensor, etc.). However, the corresponding signals can also be fed to the signaling interface.

The signaling interface S and optionally other further interfaces is preferably a USB interface, I2C interface or also a DALI interface. The microprocessor 2 can provide suitable microprocessor interfaces for connecting the interfaces. The processing by the microprocessor 2 can be configured via the application software A, as explained above, and this can thus change the ballast V and in particular a lighting system or its functionality. It is thus possible for a user to create application software A, which then enables specific functionalities of the ballast V. Using the hardware abstraction subsystem, the at least one application software A can then be used independently of an implementation of the interfaces and configurations used. For example, the microprocessor can be connected to another ballast or converter via a fourth interface. This interface can be in the form of a DALI, SPI or I ² C interface. Alternatively, the microprocessor can also be integrated in the additional ballast or converter.

In addition to the communication options already mentioned, other communication channels This is possible, for example, by signaling the light emitted by the light source or by communicating using a PLC (Power Line Communication).

As already explained, the ballast V can only have a single signaling interface S in terms of hardware, which at the same time forms further interfaces in terms of software. For example, the programming device 4, a microphone arrangement 5, a moisture sensor 6 and/or a presence sensor 7 can be connected to the signaling interface S. In addition or as an alternative, further subscribers T such as further ballasts of a lighting system, for example the lighting system 8, can be connected to the signaling interface S. Furthermore, a coupling element 9 can be connected to the signaling interface S in addition or as an alternative. Additionally or alternatively, a time control circuit 10 or time switch and/or a remote control 11 can be connected to the signaling interface S. As already explained, the signaling interface S can form the programming interface P at the same time.

It would also be possible that, in addition to the signaling interface S, there is at least one further interface in terms of hardware in order to connect further participants who cannot communicate according to a protocol of the signaling interface S. For example, the signaling interface S can be formed by a LAN interface or WLAN interface, which at the same time Programming interface P forms. In addition, the ballast V can also have an I2C interface, for example to forward the data transmitted via the LAN interface or WLAN interface to other participants connected to the I2C interface, such as other ballasts and/or sensors. It would be possible for both the LAN interface or WLAN interface and the I2C interface to form the signaling interface S, which forms the programming interface P at the same time. For example, data received from the ballast V via the LAN interface or WLAN interface, such as application software A transferred thereto, can be passed on to other participants connected there on the I2C interface. In addition or as an alternative, the ballast V can also have a DALI interface in order, for example, to communicate with DALI sensors and/or DALI ballasts connected there.

For example, it would also be possible for the ballast V to have a signaling interface S and for at least one additional interface to be hardware-based in order to connect additional participants who cannot communicate using a protocol of the signaling interface S. For example, the signaling interface S can be formed by a LAN interface or WLAN interface, which forms the programming interface P at the same time. In addition, the ballast V can have a DALI interface, for example with DALI sensors connected there and / or to communicate with DALI ballasts.

2 shows an example of a way in which the microprocessor 2 communicates with one or more ballasts 20, 21, 22, 23. where is in Figure 2a ) shows a lamp 24 with a ballast 20, which has the microprocessor 2 and the memory unit 3. In this example, the ballast 20 corresponds to the ballast V der 1 or the other examples. The memory unit 3 can be integrated into the microprocessor 2, for example. The microprocessor 2 and the memory unit 3 are preferably arranged within the ballast 20 . However, it would also be possible for the microprocessor 2 and the memory unit 3 to be arranged outside the ballast 20 but inside the lamp 24 . At least there is a connection of the microprocessor 2 to the ballast 20. Likewise, other ballasts (converters) 21, 22, 23 of lights (not shown) are shown, each of which has only one converter but does not itself provide a microprocessor. The various ballasts or converters can then communicate, for example, via a DALI bus or an I2C bus. However, only one of the lights or one of the ballasts can be expanded using application software A. However, the application software A can also determine the activation of the other ballasts (converters), so that, for example, depending on the configuration of the ballast (converter) 20, the application software A can carry out a situation- and site-specific configuration or such an operation.

In an alternative example, at least several ballasts can each have a microprocessor and a memory unit. In this case, the multiple ballasts can be connected via a signaling interface S, which can simultaneously form the programming interface P, so that the application software A can be transmitted to multiple ballasts.

As in Figure 2b ) shown, the microprocessor 2 does not necessarily have to be housed in a lamp or in a ballast, but can also be provided externally. The microprocessor can be connected to a number of stations and in particular to a number of ballasts, converters or lights 25, 26, 27 in a network using the coupling element 9, the coupling element 9 being, for example, a gateway with a LAN interface, a WLAN router or a May be DALI bus master to which several ballasts, converters or lights 25, 26, 27 can be connected. Communication with the ballasts, converters or lights 25, 26, 27 can then take place digitally via the connection provided, for example by means of I2C, DALI or DSI protocol. Of course, a microprocessor can also be provided in each ballast or in each lamp.

It would also be possible for the coupling element 9 to be designed in such a way that it has a LAN interface or WLAN interface. This LAN interface or WLAN interface can form the signaling interface S. In addition, the coupling element 9 can also have an I2C interface, for example via the LAN interface or WLAN interface forward the transmitted data to other participants connected to the I2C interface, such as a ballast V or ballast 20 and/or sensors. It would be possible for both the LAN interface or WLAN interface and the I2C interface to form the signaling interface S, which forms the programming interface P at the same time. For example, data received from the coupling element 9 via the LAN interface or WLAN interface, such as application software A transferred thereto, can be passed on to the ballast V or ballast 20 connected there on the I2C interface. In this way it would be possible for a signaling interface S and at the same time a programming interface P to be formed, so that application software A that can be configured via the programming interface P can be run on the ballast V or 20 . In addition or as an alternative, the coupling element 9 can also be designed to run the application software A. In addition or as an alternative, the coupling element 9 can also have a DALI interface in order, for example, to communicate with DALI sensors and/or DALI ballasts connected there.

As already explained, the application software A can be transmitted in individual packets via the programming interface P in the various exemplary embodiments. For example, these packets can each be provided with a port address. The packets with the port address can be received by the microprocessor 2 of the ballast 20 and the corresponding port within of memory 3 can be assigned. The individual packets can be transmitted via the programming interface P in encrypted form. The microprocessor 2 of the ballast 20 can receive the encrypted packets and be assigned to the corresponding port of the memory unit 3 according to their port address.

For example, operating data can be recorded, set and/or evaluated by the application software A in the ballast V or 20 and/or operating parameters can be recorded, set and/or evaluated and specified, for example a dimming/lighting level for a room and/or set a maximum/minimum operating temperature, or define when an incoming signal is evaluated as detecting occupancy in a room. In addition, the limit and/or threshold values for a humidity, an air pressure, a CO ₂ content or a noise level of the environment can be specified, when they are reached specific actions are then to be carried out by the application software. Likewise, the application software can specify, for example, that an image is recorded via a camera module when certain operating data or operating parameters (for example supplied by a presence sensor) exceed a threshold value or level.

A DALI interface, a Bluetooth interface, a LAN interface, a PLC interface and/or a USB interface can be provided as signaling interface S on the hardware side for communication. Likewise, one or more Microphones can be provided. As already explained, the application software A can also specify how incoming signals are evaluated. For example, filters (noise filters, echo filters, etc.) can be applied to the signals. Parameters and evaluations can also be defined for specific application scenarios (e.g. large room with a large number of office room dividers (cubicles)) or picking situations. Also, for example, the room size in which an installation is to take place or the number of lights can be defined in an application software, which can then be selected or specified accordingly. The application software A can also be used to run test programs.

Various techniques and programming languages can be used as the programming platform for the application software A. For example, the application software can be created in JAVA, PYTHON, PEARL, C, C++, C#, RUBY, GO,...

It should be understood that the ballast mentioned above is representative of converters, sensors, lights and other participants in a lighting system. The techniques, configurations and protocols specified for the interfaces are essentially interchangeable. The interfaces can either be open to the outside or hidden. A selectively openable and closable cover of the respective interfaces is of course also possible.

While the circuit board 1 was described above primarily as being arranged in the ballast, it should be understood that the circuit board 1 can alternatively or additionally also be arranged in other participants and components of a lighting system, for example the lighting system 8 . For example, circuit board 1 can also be part of a sensor or an actuator.

An intelligent sensor IS is described below, which preferably includes circuit board 1 as described above. Consequently, the description of the ballast V and the 1 essentially also for the intelligent sensor IS.

In the 3 an integration of the intelligent sensor IS in a lighting system BS is shown as an example. The intelligent sensor can be connected to the BS lighting system. The intelligent sensor IS can also be connected to a higher-level bus system (eg an IPv6 bus system, overlay network, . . . ) and can have a microprocessor 2, a memory unit 3 and, in particular, application software A. Furthermore, the intelligent sensor IS can communicate with the microprocessor 2 in a wired or wireless manner (dashed double-headed arrow). The microprocessor 2 does not necessarily have to be part of the intelligent sensor IS. The intelligent sensor IS can read out and store data from a number of connected sensors NIS, which have no intelligence, ie in particular no microprocessor and memory, in a wired manner via a bus line BL or wirelessly. Read out data can be processed by the microprocessor 2. The lighting system BS can also have other intelligent sensors and thus connect at least two sensors to one another. The bus line BL can form the signaling interface S.

• Interaktion mit anderen Sensoren NIS und Teilnehmern T, insbesondere Vorschaltgeräten V, des Beleuchtungssystems BS,
• Auswertung von an die SignalisierungsSchnittstelle übermittelten Signalen,
• Ansteuerung eines oder mehrerer Vorschaltgeräte,
• Aktivierung/Deaktivierung von Schnittstellen des Sensors IS,
• Aktivierung/Deaktivierung von

Kommunikationsprotokollen, und

• Erfassen, Einstellen und/oder Auswerten von Betriebsdaten und / oder Betriebsparametern des Sensors IS und/oder der anderen Sensoren NIS,
• Aufbau eines Netzwerks,
• Verknüpfung von Netzwerken.

The sensor IS preferably has a microprocessor 2 or is connected to a microprocessor 2 . The sensor IS also has at least one storage unit 3 or is connected to a storage unit 3 . Furthermore, there is a programming interface P, which is preferably accessible from outside the sensor IS, and at least one signaling interface S, which is preferably also accessible from outside the sensor IS. The microprocessor 2 can be configured via the programming interface P. At least one application software A that can be executed by the microprocessor 2 can be transferred to the at least one memory unit 3 via the programming interface P. The application software A influences at least one of the following functionalities of the sensor IS:

• Interaction with other sensors NIS and participants T, in particular ballasts V, the lighting system BS,
• Evaluation of signals transmitted to the signaling interface,
• Control of one or more ballasts,
• Activation/deactivation of IS sensor interfaces,
• Activation/deactivation of

communication protocols, and

• Recording, setting and/or evaluating operating data and/or operating parameters of the sensor IS and/or the other sensors NIS,
• building a network,
• linking of networks.

The programming interface P and the signaling interface S can use the same hardware and only be separated in terms of software.

The intelligent sensor IS can also specify or adopt functions and/or limit values for the non-intelligent sensors NIS or other intelligent sensors IS. The intelligent sensor IS can control and/or configure one or more ballasts or converters depending on the data collected, e.g. from the non-intelligent sensors NIS and/or its own data.

For example, the non-intelligent NIS sensors can be designed as simple motion detectors (e.g. PIR) or light sensors (e.g. LDR). The intelligent sensor IS can be a thermal imaging camera. If a detection event is recorded by a non-intelligent sensor NIS, then this can transmit information to the intelligent sensor IS about the fact that a detection event has been recorded. The application software A of the intelligent sensor IS can evaluate the transmitted information in an application-specific manner and, depending on this, control at least one other subscriber T of the lighting system BS, preferably a ballast or a converter.

The intelligent sensor IS and / or the non-intelligent sensors NIS can also be in one or several ballasts or converters can be integrated.

Claims (9)

1. Control gear (V) for lighting units, in particular LEDs, comprising a microprocessor (2) having at least one memory unit (3) and a printed circuit board (1), having at least one programming interface (P) and at least one signaling interface (S),

   wherein the microprocessor (2) is configurable via the programming interface (P), and

   wherein at least one application software program (A) that is executable by the microprocessor (2) is transferable via the programming interface (P), wherein the at least one application software program (A) that is executable by the microprocessor (2) is stored in the at least one memory unit (3), wherein the application software (A) configures at least one of the following functionalities of the control gear (V):

   - evaluation of signals transmitted to the signaling interface,

   - control of the lighting unit,

   - activation/deactivation of interfaces of the control gear,

   - activation/deactivation of communication protocols, and

   - acquisition, setting and/or evaluation of operating data and/or of operating parameters of the control gear (V),

   characterized in that

   the programming interface (P) for transmitting the application software (A) is locked, and, by transmission of a cryptographic key to the control gear (V) for transmitting the application software (A) via the programming interface (P) into the memory unit (3), said programming interface can be activated for the configuration of the microprocessor (2).
2. Control gear (V) according to Claim 1, wherein the at least one application software program (A) provides and/or changes an application programming interface.
3. Control gear (V) according to Claims 1 or 2, wherein the microprocessor executes a hardware abstraction subsystem via which the at least one application software program (A) accesses the programming interface (P) and/or the signaling interface (S).
4. Control gear (V) according to any one of the preceding claims, wherein the programming interface (P) is a wireless or wired interface.
5. Control gear (V) according to any one of the preceding claims, wherein the signaling interface (S) is used to connect at least one signaling unit.
6. Control gear (V) according to any one of the preceding claims, wherein the signaling interface (S) takes the form of a DALI, DSI, SPI, USB or I2C interface.
7. Control gear (V) according to any one of the preceding claims, wherein the programming interface (P) and the signaling interface (S) use the same hardware and are only separated in terms of software.
8. Control gear (V) according to any one of the preceding claims, wherein all interfaces are arranged on the at least one edge (a, b, c, d) of the printed circuit board (1).
9. Control gear (V) according to any one of the preceding claims, wherein the microprocessor (2) is a single-chip system.

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