DE19817073A1 - Device for controlling a plurality of lighting elements - Google Patents

Abstract

Shown and described is a special device for controlling a plurality of lighting elements, in particular for controlling light scenes, with at least one input device for inputting lighting information, which is connected via a signal transmission device to a plurality of signal processing and storage modules, which at least partially as the transmitted signals Store lighting information in a retrievable manner, with several separate circuits leading to the lighting elements connected to the signal processing and storage modules, which can be controlled by the signal processing and storage modules.

Description

The invention relates to a device for control a plurality of lighting elements, in particular for Control of light scenes, with at least one Input device for entering Lighting information about a Signal transmission device with several Signal processing and storage modules is connected, which the transmitted signals at least partially as Store lighting information in a retrievable manner, with the Signal processing and storage modules several separate, Circuits leading to the lighting elements are connected by the signal processing and Memory modules are controllable.

Such a device by the applicant is under known as EOS, but not in print verifiable. Here is just an input device provided that is mobile and in by the user  transported and operated the affected room must become. This makes programming a big one Number of lighting elements, for example in different rooms relatively complicated.

Another comparable device for control a plurality of lighting elements is in DE-Z "The master electrician and German electrical craft", 1995, No. 24, page 2212 to page 2216. The one there an Instabus EIB as a signal transmission device Working device includes a REG bus coupler that centrally stores the light scenes. Programming the Light scenes is only possible via a central input device possible. Here there is a large number of connected Lighting elements the problem that in particular large halls at the desired simultaneous Turning on all lighting elements an undesirable "Running effect" of the light sets because the individual Lighting elements addressed one after the other in time become. In principle, several are already known Provide REG bus couplers (col. 1, p. 2214, 6. full paragraph, loc. cit.). On the causal relationship however, this REG bus coupler with the bus system is not received.

It is an object of the invention, starting from the above mentioned literature a device for control a plurality of lighting elements according to the Preamble of claim i to create the connection and control of a variety of lighting elements  allows flexible handling and malfunctions avoids.

The invention solves this problem with the features of Claim 1, in particular those of the identification part and is accordingly characterized in that several Input devices to the common Signal transmission device are connected to that each input device lighting information for each lighting element can be entered that the respective Input device the lighting information as Signals via the signal transmission device together with a signal address to all signal processing and Memory modules, each processing signal and memory module each by comparing its own Address with the signal address automatically checks whether an on this signal processing and storage module connected lighting element is affected, and only after a positive test that Signal processing and storage module this signal as Stores lighting information in a retrievable manner.

The principle of the invention is essentially therein, a decentrally organized device for To be made available by everyone Input devices address all lighting elements are and on the other hand those for the control of these Lighting elements decentralized necessary information in a particularly clever way only in each affected signal processing and memory modules get saved. The programming of light scenes is  thus possible from any input device. To this In this way, input devices can be fixed in several rooms be installed, so that a comfortable entry in each the space or the area for which one is possible Light scene is provided. The decentralized storage has the advantage that no unnecessary information be saved and lots of space for a big one Amount of lighting information is available.

For a call of the signal processing and memory modules stored Lighting information needs only little Amounts of information, namely only identification information about the signal transmission device are transported because the necessary for a light scene Lighting information already in the associated Signal processing and memory module is located. The check the respective signal processing and memory modules, whether their address matches the signal address and can then directly and quickly affect those affected connected circuits and switch the corresponding Activate lighting elements.

Multiple signal processing and storage modules can very quickly call up a light scene, namely in parallel and thus at the same time testing the Carry out the address and then the respective one switch connected circuits, so that even with a very large number of lighting elements none time delay of a signal flow and therefore none Running effect occurs.  

At the same time, the solution according to the invention the effort for cabling was kept low because the Lighting elements spatially close to them Signal processing and memory modules connected can be, even at a single, shared Signal transmission device are connected. Over there the signal transmission device only signals can be transferred with a very low Voltage operated, which reduces the assembly effort is reduced.

According to an advantageous embodiment of the Invention is a light scene identifier for the signal assigned that the respective signal processing and Memory module together with the lighting information available stores. This is particularly easy an assignment of certain lighting information to created a light scene, and easily with the Illumination information in the associated Signal processing and memory module saved.

According to a further advantageous embodiment of the Invention is for calling up a stored light scene a scene signal can be input to each input device, wherein the input device over the Signal transmission device to all signal processing and memory modules, and each Signal processing and memory module separately that Scene signal with the saved light scene identifiers compares and, if they match, the corresponding ones  connected lighting elements via the circuits controls. This enables particularly easy retrieval each light scene from all input devices, where only the scene signals for calling up a light scene, and thus small amounts of information about the Signal transmission device must be sent.

According to a further advantageous embodiment of the Invention is used as a signal transmission device conventional bus, such as LON (Local Operating Network) bus used, the signal address part of the Signal variable itself. The use of a conventional bus already allows use developed, commercially available and thus inexpensive components. Typical for a LON Addressing the number of possible addressees in principle is limited and circuits can not be controlled individually are part of the address in the transmission variable itself included.

According to a further advantageous embodiment of the Invention are to the signal transmission device Extensions connected, at least Scene signals can be entered. As extensions are Devices with very little construction are provided with which light scenes are available. Because the structure is clear is less complicated than that of an input device, can in the simplest case only one or more Switches are provided which can be operated manually and about the one or possibly several light scenes are available. It is especially thought of in large  For example, an input device for Programming the light scene and several, preferably in Extensions located near each hall entrance to provide.

Additional advantages result from the additional Subclaims and from the description below one shown in the drawings Embodiment. The drawings show:

Fig. 1 shows a schematic representation of an exemplary structure of an inventive device for controlling a plurality of lighting elements with two input devices, three extensions and two signal processing and -Speichermodulen,

Fig. 2 shows a schematic representation in the manner of a block diagram of a signal processing and memory module, and

Fig. 3 shows schematically the connections of a signal processing and memory module installed according to FIG. 2.

The device designated 10 in its entirety in FIG. 1 comprises two input devices 11 according to the exemplary embodiment shown as an example, which are connected to one another via a common signal transmission device 12 . In the simplest case, the signal transmission device 12 can be a two-wire electrical line. According to the invention, it is provided to use a four-wire line in which the voltage supply is supplied from two wires and in which the other two wires are used for signal transmission.

According to FIG. 1, two signal processing and storage modules 13 are also connected to the signal transmission device 12 . An interface for a computer that can be connected to the common signal transmission device 12 , for example a V24 interface, is not shown.

Each signal processing and storage module 13 has a limited number of analog outputs 14 and switching outputs 15 . The analog outputs 14 are circuits for connecting, for example, external dimming modules 16 for dimmable lights 19 , electronic ballasts 17 or similar devices. The switching outputs 15 , on the other hand, are used for the electrical connection of power relays 20 for the control of non-dimmable lights 18 , blackouts or screens.

All lighting elements 17 , 18 , 19 can be controlled individually from the two input devices 11 , which can be arranged, for example, in two different rooms. A large amount of lighting information such as brightness values, fading times and further special information, for example for controlling darkening, can be entered via a menu-controlled keyboard 21 . This information is output by the input device 11 to the common signal transmission device 12 and is sent there as signals to all the signal processing and storage modules 13 . The program for menu-guided programming is stored in the input device 11 . When the lighting information is entered into the input device 11 , the information is directly assigned a signal address by means of an electronic circuit, which enables the information to be assigned to a specific circuit, that is to say a specific analog output 14 or switching output 15 .

The signal passes via the signal transmission device 12 to each signal processing and storage module 13 , which has its own address that is special for the respective signal processing and storage module 13 . When a signal is received, each signal processing and storage module 13 independently and independently checks whether a circuit 14 , 15 assigned to this signal processing and storage module 13 is affected by the lighting information received as a signal by comparing its own address with the signal address associated with the signal. If this is not the case, the signal processing and storage module 13 takes no further action and returns to its idle state in order to wait for the reception of a new signal.

If it is found when checking the addresses that an analog output 14 or a switching output 15 of this signal processing and storage module 13 is affected, this signal is stored as lighting information in the signal processing and storage module 13 .

In principle, a very large amount of lighting information for different lighting elements 17 , 18 , 19 can be stored as the light scene . To call up a light scene, a scene signal can be entered, for example, via the keyboard 21 of an input device 11 , which is received by all signal processing and storage modules 13 via the signal transmission device 12 . Since a light scene identifier is stored with the lighting information in the respective signal processing and storage module 13 , each signal processing and storage module 13 can compare the received scene signal with the stored light scene identifier. If these do not match, the signal processing and storage module 13 in question takes no further action and returns to an idle state in which it waits for further signals to be received.

If the received light scene signal matches the stored light scene identifier, the corresponding connected lighting elements 17 , 18 , 19 are controlled via the analog outputs 14 or the switching outputs 15 .

In the exemplary embodiment according to FIG. 1, three extensions 22 are also provided, which are designed to be less complex than the input devices 11 . Although they do not include a display, they also have a keyboard 23 with which, in a simple manner, for. B. manually saved light scenes can be called up.

Another advantage of the control device 10 according to the invention is that the input devices 11 can be arranged spatially separated from the signal processing and storage modules 13 . As a result, the wiring effort is further reduced, since for the connection of the individual lighting elements 17 , 18 , 19 the respective signal processing and storage module 13 to a location close to the lighting elements 17 , 18 , 19 and the input device 11 at a conveniently accessible other for the user Place can be arranged in a building. For the connection between the input devices 11 and the signal processing and storage module 13 , only the four-wire line has to be laid. In this way, the light control device according to the invention has a modular structure with a small number of components.

The structure of a signal processing and storage module 13 according to the invention is shown by way of example in FIG. 2. The heart of the signal processing and storage module 13 is the microprocessor module 24 , which is commercially available as a LON chip 3150 . A bus coupling unit 25 is connected to module 24 and is also commercially available as an FTT10A module. The bus coupler 25 is connected directly to the signal transmission device 12 . Reference information about these two components can be obtained, for example, from Echelon GmbH, 58598 Baldham. In principle, other bus coupling units 25 and other microprocessors 24 can also be used.

A special second bus 25 is provided within the signal processing and storage module 13 , which operates in the exemplary embodiment in the manner of a MUX protocol. Information on this protocol or alternative protocols can be found, for example, in the "Neuron Chip Databook", February 1995, published by Echelon. An address decoder 27 , galvanic isolating elements 28 , digital / analog converter 29 , a memory unit 30 for address storage and an address switch 31 are connected to this second bus 26 .

An internal power supply 33 is also provided within the signal processing and storage module 13 .

A switching stage 42 shown with the switching output 15 and an amplifier module 43 with the analog output 14 are only shown by way of example for a large number of possible circuits and associated elements 42 , 43 .

Special galvanic isolating elements 18 are only necessary between the second bus 26 and the switching outputs 15 . No galvanic isolation is required for the area between the digital / analog converter 29 and the analog connecting line 14 , since the galvanic isolation of the power supply or the bus coupling unit 25 can be used here.

The illumination information is stored in the signal processing and storage module 13 in the storage unit 30 . A special battery storage 32 is provided here, which ensures permanent storage of the lighting information, in particular in the event of a power failure of the central power supply 44 . The lighting information is assigned to the individual analog outputs 14 and switching outputs 15 in the address decoder 27 . In addition, an address switch 31 is provided which enables the setting of the device or group address.

Within the signal processing and storage module 13 , software is also stored in the microprocessor 24 , which immediately performs all functions such as changing brightnesses, controlling screens or blackouts, etc., when requested to do so by the input devices 11 . It is therefore not only possible to store lighting information in the signal processing and storage module 13 , but also to directly address the individual analog outputs 14 and switching outputs 15 .

Fig. 3 shows an overview of several terminals of a signal processing and memory module installed. 13 A service button 34 with an LED display 34 a is shown schematically, which informs the user of the status of the LON chip. A battery monitoring display 35 is also provided, as well as a reset button 36 . When actuated, the reset button 36 causes the software to be restarted and a return to the last lighting state. The lighting information stored in the signal processing and storage module 13 is retained. In the exemplary embodiment according to FIG. 3, two switches 37 , 38 are provided for the selectable setting of the type of addressing. In the upper area of the signal processing and storage module 13 with respect to FIG. 3, the voltage connections 39 , the bus connections 40 and the output terminals 41 for controlling the external relays 20 are indicated.

The detailed structure of an input device 11 is not shown in the drawings. As with the signal processing and storage module 13, it is a separate device in which a circuit board with a plurality of electronic components is accommodated. As with the signal processing and storage module 13, direct application to the signal transmission device 12 takes place via an FTT10A bus coupler and a LON chip 3150. However, the heart of this circuit arrangement is an additional SAB 80535 microcontroller from Siemens. A clock module, several I / O interface modules (input / output devices) and a display, preferably an LCD display, are connected to this microcontroller. In addition, the microcontroller is connected to three memory modules, an EPROM for permanently storing the software, another EPROM for storing the menu and a separate RAN module for storing data. In particular, the signal addresses are stored here, so that when a desired light scene is called up, the input device 11 automatically sends the corresponding signals to all the signal processing and storage modules 13 via the signal transmission device 12 .

In addition, there is one in each input device Infrared receiver module, for example a programmed one PIC 16C58, connected to the microcontroller that is used for Receive from an infrared remote control Serves infrared waves. In this way, a user can use corresponding infrared remote controls on very flexible Call up the saved light scenes.

Claims (9)

1. Device ( 10 ) for controlling a plurality of lighting elements ( 17 , 18 , 19 ), in particular for controlling light scenes, with at least one input device ( 11 ) for inputting lighting information, which via a signal transmission device ( 12 ) with a plurality of signal processing and -Speichermodulen (13) is connected, which store the transmitted signals at least partially as a lighting information available, wherein the signal processing and memory modules (13) a plurality of separate, leading to the illumination elements (17, 18, 19) through circuits (14, 15 are connected), which are controllable from the signal processing and -Speichermodulen (13), characterized in that a plurality of input devices (11) are connected to the common signal transmission device (12), that at each input device (11) lighting information for every lighting element (17 , can be entered 18 19), since the respective input device (11) sends the lighting information as signals via the signal transmission means (12) together with a signal address to all the signal processing and memory modules (13), wherein each signal processing and storage module (13) in each case by comparison of its own address with the The signal address automatically checks whether a lighting element ( 17 , 18 , 19 ) connected to this signal processing and storage module ( 13 ) is affected, and the signal processing and storage module ( 13 ) stores this signal as lighting information only after a positive test. 2. Device according to claim 1, characterized in that the signal is assigned a light scene identifier, which stores the respective signal processing and storage module ( 13 ) together with the lighting information. 3. Apparatus according to claim 1 or 2, characterized in that for calling up a stored light scene at each input device ( 11 ), a scene signal can be entered, which the input device ( 11 ) via the signal transmission device ( 12 ) to all signal processing and storage modules ( 13th ) sends, and that each signal processing and memory module ( 13 ) separately compares the scene signal with the stored light scene identifiers and, if they match, controls the corresponding connected lighting elements ( 17 , 18 , 19 ) via the circuits ( 14 , 15 ). 4. Device according to one of the preceding claims, characterized in that a conventional bus, such as LON bus, is used as the signal transmission device ( 12 ), the signal address being part of the signal variable itself. 5. The device according to claim 3, characterized in that to the signal transmission device ( 12 ) extensions ( 22 ) are connected, at least at which scene signals can be input. 6. Device according to one of the preceding claims, characterized in that a plurality of signal processing and memory modules ( 13 ) can be combined to form a group and their lighting elements ( 17 , 18 , 19 ) can be programmed and addressed as a group such that for setting a group address on signal processing and memory modules ( 13 ), for example a manually operable address switch ( 31 , 37 , 38 ) is provided, that a signal address is assigned to the signal addresses, and that when the address switches ( 31 , 37 , 38 ) are in the group addressing position each signal processing and storage module ( 13 ) compares the group address with a set device group address by checking the signal address and stores the signals as lighting information only if they match. 7. Device according to one of the preceding claims, characterized in that each signal processing and memory module ( 13 ) one Microprocessor 24 , such as LON chip 3150, which is connected on the one hand to the signal transmission device ( 12 ) via a bus coupler 25 , such as FTT10A component, and on the other hand via a second bus ( 26 ) at least to digital / analog converters ( 29 ) and / or galvanic isolating elements ( 28 ) are connected, to each of which the circuits ( 14 , 15 ) to the lighting elements ( 17 , 18 , 19 ) are connected. 8. The device according to claim 7, characterized in that between the second bus ( 26 ) and switching stages ( 20 ) for switching circuits ( 15 ) galvanic isolators ( 28 ) are arranged.