DE102012204686B3 - Method for configuring lighting system in e.g. office building, involves producing live image of room by electronic camera, and performing identification based on live image that is modified by modification operation - Google Patents

Abstract

The method involves attaching actuators i.e. lamps, to a decentralized bus i.e. KNX bus. A lighting system is configured by a project planning software in which details of the actuators are stored. The actuators attached to the bus are read such that the read actuators are by successively addressed the software. The addressed actuators are identified with the associated actuators details stored in the software. A live image of a room (1) is produced by an electronic camera (K). An identification is performed based on the live image that is modified by a modification operation. The electronic camera is designed as a webcam or smart phones camera.

Description

The invention relates to a method for the configuration of a lighting system according to the preamble of claim 1.

It is known to project in a building, the lighting system by means of running on a computer software (configuration software). In particular, the devices of the lighting system are placed so that the software knows where each device is located. The devices include actuators (eg lights) and sensors (eg switches, motion detectors).

Today, all configured devices are connected to a decentralized bus for the lighting control. Specifically, a bus connecting device may be present, the z. B. a DALI bus (gateway) specifically for lights with a KNX bus for the other devices of the building connects, so you have to do it from the outside with a single bus. All devices connected to the bus can be read in by the software. After reading, there is a list of the connected devices, without it being known, which device of the list (list device) is located in the building (placed). The list devices must therefore still be identified.

The identification requires the activation of a list device by the software, so z. For example, switching on a list light on the bus. Thereafter, in the case of the lights, it is determined which of the placed lights is lit, and this is communicated to the software. Then the list light thus identified is switched off again and the next list light is switched on and the identification process is repeated until all list lights have been identified.

On a construction site, the luminaire switched on may need to be searched across several rooms / floors.

For the configuration of the lighting system, the placement in the software then determines which device corresponds to which list device (in the case of luminaires which list luminaire) in the real installation.

The disadvantage here is that the identification of many lights, z. B. in an office building or in a factory, can be very time-consuming and time-consuming.

Next is from the DE 10 2009 050 733 A1 a method and an addressing system for assigning operating addresses for luminaires, which are part of a lighting or media system. The addressing system comprises a control unit which can cause a luminaire to emit an optical signal for identification using an originating address. Furthermore, the position of the respective luminaire can be detected and assigned an operating address on the basis of the optical signals.

Furthermore, from the US 2010/0244745 A1 a light management system for the light effect identification of a home entertainment system known. The light management system is able to automatically create a lighting scene using an abstract light-experience description, using light-effects types at specific locations in relation to the home-entertainment system. The light effects are automatically registered by the light management system and controlled so that the registered lighting effects are automatically integrated into the lighting scene. This allows the light effects generated by light sources in a room to be automatically identified and controlled accordingly by the light management system.

The object of the invention is to provide the identification of the actuators, d. H. in particular the lights to simplify so that they can be done quickly with little effort.

The object is solved by the features of claim 1; the dependent claims represent advantageous embodiments.

The solution provides that an electronic camera generates a life image of the space and that the identification is carried out automatically on the basis of the life image altered by the response.

For the sake of simplicity, the placement of the actuators is based on at least one image taken before the physical construction of the lighting installation.

It is technically simple if the at least one image for the placement of the actuators on a screen of a computer is used as a background image and the actuators are placed on the background image.

The automatic implementation of the method is simpler if the life image on the screen is made to coincide with the background image, so that the actuators of the life image and the actuators placed in the software are superimposed.

The method is relatively easy to carry out, if the actuators are designed as lights, each one read-in light from the software is switched on and identified by the switched on by the power Life image of the software with the same place lamp.

The invention will be described in more detail with reference to an embodiment. Show it:

1 a room of a building with a camera,

2 the picture of the room according to 1 on the screen of a computer as a background image before the physical completion of the lighting system,

3 all devices after software placement on the background image according to 2 .

4 according to the room 1 after the physical completion of the lighting system and

5 a life picture of the room according to 4 with an addressed light.

1 shows a room 1 a building 2 , in which a large number of other rooms (not shown) is present. From the room 1 are in 1 two adjoining walls 3 . 4 as well as in one wall 4 a door 5 shown.

In the room 1 is still a camera K, with a picture 6 of the room 1 is recorded. When the camera K, it may be z. B. to act a webcam or a smartphone camera. Corresponding pictures are also taken of the other rooms including existing corridors and the like.

For the building 2 a lighting system is provided by means of a computer 8th running software (configuration software) is configured on the basis of the pictures taken. For this, the pictures are each on the screen 7 of the computer 8th displayed as wallpaper.

2 shows the picture 6 of the room 1 on the screen 7 of the computer 8th as a wallpaper.

The lighting system to be designed includes various devices (lighting devices), generally actuators and sensors, wherein the sensors z. B. include all types of switches.

The planned devices are first placed on the screen by means of the software, in the picture 6 in 2 for the lighting of space 1 the devices GL1, GL2, GS1, GS2. The devices GL1, GL2 are the actuators AGL1, AGL2 in the form of lights and the devices GS1, GS2 the sensors SGS1, SGS2 in the form of motion detectors. The lights (devices GL1, GL2) are each connected via a ballast (not shown) to the bus B.

In 3 are in the picture 6 all devices GL1, GL2, GS1, GS2 of space 1 after placing them on the screen, ie they are located in the software respectively at their assigned place. In this way, the software has the information on which place in which room, which device of the lighting system after its physical completion will be located, including which device GL1, GL2, GS1 and GS2 where in space 1 ,

4 shows the room 1 after the physical completion of the lighting system with the devices GL1, GL2, GS1 and GS2 attached to the walls 3 . 4 are arranged. The devices GL1, GL2, GS1 and GS2, like the devices of the other rooms, are connected to a decentralized bus B (schematically as a dashed line in FIG 4 shown) connected.

For configuration of the lighting system, all devices connected to bus B GL1, GL2, GS1 and GS2 are read by the software, so that in each case a list of connected devices (list devices) is present. For the room 1 For example, the devices L-G1, L-G2, L-G3, L-G4 are in this order immediately after one another in the list.

After reading the software is not yet known which placed device GL1, GL2, GS1 and GS2 corresponds to which list device L-G1, L-G2, L-G3, L-G4. The list devices L-G1, L-G2, L-G3, L-G4 still have to be identified.

The identification of the lights (in room 1 the two devices GL1, GL2 or actuators AGL1, AGL2) is automated, namely by the camera K again in the same place in the room 1 (and accordingly in the other rooms) is placed to the picture 6 corresponding life picture 6a to create. As an alignment aid, the previously recorded image 6 semi-transparent on the screen 7 displayed so that the life picture 6a placed over it and can be postponed until a homogeneous picture of the room 1 on the screen 7 is present, both pictures 6 . 6a so congruent superimposed. If necessary, the camera K has to be readjusted slightly differently.

The superimposed images 6 . 6a appear on the screen 7 as in 5 shown.

Then the software controls the list devices L-G1, L-G2, L-G3, L-G4 in the list order (sequence but irrelevant), ie the list device L-G1 first, then the list device L-G1. Device L-G2, etc. Through differential image calculation is detected by the camera K, which placed device GL1, GL2 lights up when the list device L-G2 is controlled. In the case of the list device L-G2, the device GL1 lights up, which is indicated in 5 is shown schematically.

The software automatically assigns the configured and placed device GL1 to the list device L-G2.

Then the L-G2 list device is switched off again and the next list device L-G3 of the list is switched on and the process is repeated for all L-G4,... List devices, that is to say also for the remaining rooms using their pictures and life pictures.

For identification of the devices GS1, GS2, these must each be on site, ie in the room 1 , z. B. be triggered by a person.

Finally, to configure the lighting system, the functions are configured (assignment of the devices to one another in the software) and the connections between the devices GL1, GL2 and the devices GS1, GS2 are made by means of the software and loaded into the devices GL1, GL2, GS1, GS2 so that they interact via the decentralized bus B as desired. The devices GL1, GL2, GS1, GS2 are combined into functions in the software. The software then calculates how each device GL1, GL2, GS1, GS2 must be configured and then loads that configuration into the respective device GL1, GL2, GS1, GS2.

Claims (5)

Method for configuring a lighting system comprising an arrangement of actuators (AGL1, AGL2) for at least one room ( 1 ) and in which the actuators (AGL1, AGL2) are connected to a decentralized bus (B), wherein the lighting system is configured by means of software and the actuators (AGL1, AGL2) are placed in the software, in which the to the bus (B) connected actuators (AGL1, AGL2) read, the read-in actuators (AGL1, AGL2) addressed by the software and the respective addressed actuators (AGL1, AGL2) in each case with the associated in the software placed actuator (AGL1 or AGL2) be identified, characterized in that an electronic camera (K) a life image ( 6a ) of the room ( 1 ) and that the identification is determined in each case on the basis of the life image altered by the response ( 6a ) he follows. Method according to Claim 1, characterized in that the placement of the actuators (AGL1, AGL2) is based on at least one image ( 6 ), which was taken before the physical creation of the lighting system. Method according to claim 2, characterized in that at least one image ( 6 ) for the placement of the actuators (AGL1, AGL2) on a screen ( 7 ) of a computer ( 8th ) is used as the background image and the actuators (AGL1, AGL2) are placed on the background image. Method according to claim 2 or 3, characterized in that the life picture ( 6a ) on the screen ( 7 ) is brought to coincide with the background image, so that the actuators (AGL1, AGL2) of the life image ( 6a ) and the actuators (AGL1, AGL2) placed in the software are superimposed. Method according to one of Claims 1 to 4, characterized in that the actuators (AGL1, AGL2) are designed as luminaires, in each case a read-in luminaire is switched on by the software and based on the life image (FIG. 6a ) is identified by the software with the luminaire at the same place.

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