EP3120670A1 - Central unit of a bus system, bus system and method for locating bus subscribers - Google Patents

Abstract

The present invention relates to a central unit of a bus system (10), to a bus system (10) and to a method for locating bus subscribers (2) in the bus system. The central unit (1) stores a generated address list containing the addresses of the bus subscribers (2). In a commissioning mode, a control unit (3) transmits control commands to the bus subscribers (2) according to the address list. A bus subscriber (2) is preferably a luminous means or has at least one luminous display. The sequential control commands are preferably such that, at any time, a selected bus subscriber (2) assumes a first luminous state which differs from a second luminous state of all other bus subscribers (2).

Description

 Central unit of a bus system, bus system and method for locating bus subscribers

The present invention relates to a central unit of a bus system, a bus system and a method for locating bus subscribers in the bus system. In particular, the addresses of the bus users can be located, so that the central unit, the bus system and the method of the present invention are particularly well suited for picking the bus system.

It is known from the prior art to localize bus users, such as light sources or light sensors, in a bus system with respect to their address, for example by physical selection or by the individual reproduction of bus addresses.

For example, for the DALI industry standard, for locating bus addresses, it is known to randomly generate an address for each bus subscriber, to physically select each bus subscriber (eg, by removing bulbs from their socket or by dimming light sensors), and so the address of the corresponding bus subscriber and assign them to a specific location.

It is also known for the DALI industry standard to generate a random address for each bus subscriber, to select an address (manually or via a software interface), and by individually rendering the address (eg by modulating light at an address) a location to determine the address (eg by observing the light change).

However, the known picking methods are extremely time consuming. For example, for the DALI industry standard, the random selection of all 64 bus addresses and a corresponding individual representation of the addresses is a very time consuming process. Sometimes a picking process is not even possible. For example, physical selection is possible only if the bus users are also accessible. Bus subscribers such as bulbs are often installed on a high ceiling or have no access to the required interfaces.

In view of the above-mentioned disadvantages, the object of the present invention is to improve the prior art. In particular, it is the object of the present invention to provide a central unit for a bus system, a bus system and a method with which an address localization of bus users of the bus system is simple and fast. The present invention also seeks to simplify and speed up the picking of a bus system. Also, additional costs such as for converters or bulbs are to be avoided.

The above object of the present invention is solved by the appended independent claims. Preferred embodiments of the present invention are defined in the dependent claims. In particular, with the claimed central processing unit, the claimed bus system and the claimed method a More efficient, faster and easier localization of bus user addresses are performed.

The present invention relates to a central unit of a bus system for locating bus subscribers, comprising a memory in which an address list with the addresses of the bus subscribers is stored, and a control unit, which is designed in a picking mode, according to the address list sequential control commands to the bus subscribers send.

In the picking mode of the central unit, it is thus possible to control the bus subscribers one after the other in accordance with the stored addresses. Each of the different sequential control commands preferably drives one of the addresses differently than the other addresses. The effect of a specific control command on the bus subscribers makes it possible to deduce the address of a corresponding bus subscriber. In other words, a temporal concordance of the sending of a control command with the detection of the effect of the control command on the bus subscribers is used to locate the address of a bus subscriber. With the central unit of the present invention, the address of each bus user in a bus system can be easily and quickly located.

In particular, with the central unit of the present invention, address localization can also be performed for bus subscribers who are not readily available. For example, no bus subscribers have to be removed from the bus system. For example, the present invention lends itself well to a bus system mounted on a high building ceiling. Because the sequential Control commands can be sent very quickly according to all addresses of the address list, the address localization can also be performed with a significantly reduced amount of time.

Advantageously, a bus subscriber is a light source or has a light indicator.

The effects of the sequential control commands, which are for example different successive dimming commands, can thus be easily recognized visually or optically. A light source can be, for example, an incandescent lamp, a gas discharge lamp, an LED or an OLED. A bus subscriber with a light display may be, for example, a sensor (such as a motion detector, a temperature or humidity sensor, a smoke detector, a fire detector, etc.) having at least one indicator light means such as a display LED or a display.

Advantageously, the control unit is adapted to send such sequential control commands to the bus subscribers that at any given time a selected bus subscriber assumes a first lighting state which differs from a second lighting state of all other bus subscribers.

A luminous state, for example, the color or brightness of a light source or a

Indicator light, may be a light or flash pattern emitted by a bus user, or may be the brightness or color of a display. Advantageously, a lighting state is on

Light power state.

A light power state for a lighting device or a bus subscriber with display lighting means is easy to change by means of corresponding dimming commands and can be recognized easily and simply visually or optically.

The present invention further relates to a bus system for locating bus subscribers, comprising a central unit as described above, a plurality of addressable bus subscribers, and a bus, preferably a DALI bus, which connects the bus subscribers to the central unit.

In the bus system, the addresses of the individual bus subscribers can be easily and quickly located with the advantages mentioned above for the central unit.

Advantageously, the bus system further comprises a connected to the central unit, preferably unidirectionally connected, light sensor which is adapted to detect a luminous state of each bus subscriber, wherein the central unit is adapted to a change of the luminous state of a bus user from the second to the first light state Timing with a sent control command to locate the address of the bus station.

As a result of the preferably unidirectional connection of the light sensor to the central unit, a detected change in the luminous state of a specific bus subscriber can be transmitted quickly to the central unit and with the sequential control commands be synchronized to determine a simultaneous control command and thereby locate the address of the particular bus station. With the sequential control commands in accordance with the address list, ie with the drive cycle of all the addresses of the bus subscribers, the address of a specific or even several specific bus subscribers can thus be located in an extremely short time. If, for example, the DALI industry standard (ie a DALI bus) is used as the bus, all permissible 64 bus addresses of the DALI bus system can be traversed in a period of about 3.2 to 6.4 seconds. Thus, the localization of a desired bus subscriber can take place almost instantaneously, ie with a maximum waiting time in the seconds range.

Advantageously, the central unit is designed to remove a localized address from the stored address list.

This means that the localized address is no longer used for the further control of the bus subscribers, for example a further drive cycle and the further modulation of the light power of the bus subscribers. As a result, the address list for each pass becomes smaller and the localization of the bus subscriber addresses can be completed more quickly. Advantageously, the central unit is designed to pick bus subscribers according to their localized addresses. For example, certain bus subscribers can be changed with regard to their addresses for picking, can be assigned to logical groups, or can be entered in a building plan.

Advantageously, the first lighting state is a first light power state and is detected by the light sensor for a bus subscriber when its light power reaches a certain threshold, or its light output differs from the light power of each other bus at least a certain threshold.

For example, all bus users, except for one bus user for each control command, are set to a specific dimming level. The one bus subscriber is set to a different dimming level. If the light sensor detects this difference between the dimming levels for a selected bus subscriber, the address of the dimming command used at the same time is recognized for this selected bus subscriber. The dimming commands can, for example, cause a complete or partial dimming or increase in the light output in each case at one bus subscriber at any one time.

Advantageously, the threshold is adaptively set after one pass of sequential control commands in accordance with all addresses of the address list.

Advantageously, the light sensor is adapted to be spatially assigned to each bus subscriber, and after a passage of sequential control commands according to all addresses of the address list, the spatially assigned bus subscriber becomes the address according to that Associated with the control command for which the light sensor has detected the strongest light output for the bus subscriber.

It can not be ruled out that in the detection range of the light sensor, even if it is spatially assigned to a bus subscriber, there are several bus subscribers. Therefore, it is advantageous to set the threshold adaptive. For example, first of all, the passage of all addresses takes place before the threshold value is set adaptively. Advantageously, the detection range of the light sensor can be limited to a single bus user.

Advantageously, the light sensor comprises a photosensor or a camera.

With a camera can advantageously be limited by optical or virtual zooming the detection area to a bus subscriber. A direct selection of the detection area in the camera image without zooming is also conceivable, for example by manual interaction on a touch screen.

Advantageously, the light sensor is a portable device, preferably a smartphone.

It is important that the time of detection of the change in the light output of a bus station can be assigned exactly in time to the time of sending a corresponding control command. Therefore, the portable device is preferably in a wireless and / or unidirectional connection with the

Central unit, so that the time of detection of the Light power change sufficiently fast

Central unit can be transmitted.

Advantageously, the light sensor is designed to represent localized addresses of bus subscribers in a room layout plan.

The room distribution plan can be, for example, a building plan in which each address-localized bus subscriber is entered.

The present invention further relates to a method for locating bus subscribers in a bus system, comprising: generating an address list with addresses of the bus subscribers, and sending sequential control commands to the bus subscribers in accordance with the address list.

Advantageously, such sequential

Control commands sent that at any time a bus subscriber a first light condition, preferably a first light power state, which differs from a second light condition, preferably a second light power state, all other bus subscribers.

Advantageously, the address list is generated by picking up addresses which have been permanently assigned to the bus users during their manufacture, or randomly assigning addresses to the bus users.

Advantageously, the method further comprises: detecting a luminous state of each bus subscriber, and timing a change of the luminous state of a bus subscriber from second to the second first light condition with a sent control command to locate the address of the bus station. The inventive method achieves the same advantages as explained above for the central unit or the bus system. In particular, the method allows the address of each bus user of a bus system to be located at least semi-automatically, quickly and easily.

The present invention will now be described in detail with reference to the accompanying drawings. 1 shows a bus system according to an embodiment of the present invention comprising a central processing unit according to another embodiment of the present invention. 2 shows a bus system according to an embodiment of the present invention including a central processing unit according to another embodiment of the present invention and a light sensor. 3 shows steps of a method according to an embodiment of the present invention.

Fig. 4 shows a principle of light detection according to an embodiment of the present invention.

Fig. 5 shows a smartphone as a light sensor of the bus system of an embodiment of the present invention. Fig. 6 shows a bus system with a portable device as a light sensor.

Fig. 1 shows the possible structure of a bus system 10 of the present invention. In particular, the bus system 10 includes a central unit 1 according to the invention, which can be used to locate bus subscribers 2. The bus system 10 further comprises a plurality of addressed bus subscribers 2, which are connected via a bus 4 to the central unit 1.

The central unit 1 of FIG. 1 comprises a memory 7, in which an address list is stored, which contains the addresses of the individual bus subscribers 2 of the bus system 10. The address list, however, contains no information regarding the locations of the bus subscribers 2. The addresses of the address list can be fixed addresses, for example, which have already been assigned to the bus subscribers 2 during their production. Alternatively, at the beginning of a localization process, the central unit 1 may first assign a random address to each bus user 2. If bus 4 is a DALI bus, there are 64 such bus addresses to be assigned.

The central unit 1 further comprises a control unit 3, which can preferably operate both in an operating mode and in a picking mode. In particular, for the present invention, the

Picking mode important. By doing

Namely picking mode, the control unit 3 is adapted to send sequential control commands according to the addresses of the address list to the bus subscribers 2.

FIG. 2 shows a more concrete example of the bus system 10 from FIG. 1. The bus system 10 now has one optional light sensor 5, which is connected via a preferably uni-directional communication link with the central unit 1. Preferably, the unidirectional communication link is wireless.

In general, bus subscribers may be bulbs such as gas discharge lamps, incandescent lamps, LEDs or OLEDs and / or may be sensors such as motion detectors, smoke detectors, fire detectors, water level detectors, oxygen sensors, or other subscribers commonly used in building services engineering. The bus system 10 can be installed, for example, on the ceiling of a building. The individual bus subscribers 2 are then correspondingly distributed over a room or corridor. The bus subscribers 2 are preferably light-emitting means as shown in FIG. 2 or have at least one light-emitting display, such as a display LED or a display.

Hereinafter, the embodiments of FIGS. 2 to 5 will be described mainly with reference to bulbs as bus subscribers 2. However, as described above, the invention is not limited to such bus users 2.

The central unit 1 preferably also has a picking interface 8 in FIG. 2 in order, for example, to associate logical subscribers 2 with respect to their addresses, to change the addresses of bus subscribers 2, or to enter these in a room layout plan such as a building plan.

The bus system 10 preferably has the light sensor 5, which may be, for example, a camera, a portable device such as a smartphone or a tablet, or a mobile photo sensor. Preferably, the light sensor 5 Connected to the central unit 1 via a wireless connection such as a Wi-Fi network or a cellular network. Preferably, the light sensor 5 can be spatially assigned to each of the bus subscribers 2. For this purpose, the light sensor 5 can for example be moved toward each bus subscriber 2 or aligned with a single bus subscriber 2. If the light sensor 5 is, for example, a camera, it can be directed to individual bus subscribers 2 and preferably the detection range of the camera can still be limited to a single bus subscriber 2 by zooming or by selecting a sensitive area in the detection area. Each bus subscriber 2 can therefore preferably be selected by a user by walking around in a building and aligning the light sensor 5 with the bus subscriber 2.

3 shows steps of a method according to an embodiment of the present invention. In this case, bulbs are again described as a bus subscriber 2 as an example. The steps of the method can be executed by the central unit 1 or in the bus system 10 of FIGS. 1 and 2. First, for example, generated by the central unit 1, an address list with addresses of the bulbs. This can be done, for example, by assigning a random address to each light source. Alternatively, a list can be created from the addresses of the individual luminous means determined during production. The address list is then stored, preferably stored in the memory 7 of the central unit 1. Preferably, all bulbs are then set to a specific output light state (for example, a minimum or maximum dimming level). However, it is also possible to select another specific dimming level as the initial lighting state.

Next, for example, from the central processing unit 1, sequential different control commands are sent to the lighting means according to the address list. By the sequential control commands each address of the address list is preferably sequentially controlled such that the luminous state of the corresponding light source is changed for this address. For example, the lighting conditions of the lighting means can be changed by switching off or by modulation (increase or decrease) of the dimming level. The control commands either only control one address in each case in order to change the luminous state of a specific luminous means or simultaneously control all addresses differently, however, in order to set all luminous elements into the same luminous state, with the exception of a specific luminous means which receives a different luminous state.

The light sensor 5 is initially spatially associated, for example, with a selected illuminant, i. preferably directed to this lamp. The light sensor 5 is now used to detect the lighting state of the selected light source. However, the light sensor 5 can also detect and measure several or all light sources 5 at the same time and assign their locations to a floor plan.

The luminous state (for example, the luminous power) of the selected illuminant is during the Address pass continuously measured by the light sensor 5 and stored a result preferably for each emitted control command. The intermediate storage can take place in the memory 7 of the central unit 1.

As soon as the light sensor 5 detects a change in the luminous state of the selected luminous means, in particular if a difference of the preferably cached results lies above a certain threshold value and / or reaches an absolute threshold value, then an address of the selected luminous means can be obtained by temporal comparison with the corresponding control command yes contains an excellent address can be determined.

Thereafter, the light sensor 5 may be directed to a next light source, for example, and the above-described steps may be repeated. Preferably, the picking process is terminated when all bulbs have been located in terms of their address. Each localized address is preferably removed from the address list, so fewer addresses need to be traversed for the next light source to determine its address.

FIG. 4 shows by way of example how a lighting state (in this case the luminous power) of light sources in the bus 4 can be detected by the light sensor 5 in order to detect which address a selected lighting device has. It can be seen on the time axis in FIG. 4 that, for example, one bus address is activated one after the other for the localization process, ie, sequential control commands corresponding to the entire addresses in the address list are traversed. On the vertical axis is an absolute luminous power measured by the light sensor 5 ("light ablation") as well as a relative change in the luminous power (light sensor rel.) At the activated addresses # 5, # 7 and # 9 the light sensor 5 detects a change in the luminous power of the For addresses # 5 and # 9, the relative change is above a certain threshold, the change is greatest for address # 7. For all other addresses, the light sensor does not show any appreciable relative change more preferably, the change must additionally reach a certain threshold value, ie the address # 7 would be assigned to the selected light source in FIG.

5 shows a possible embodiment of the light sensor 5, namely as a smartphone with an integrated camera. On the screen of the smartphone is detected by the camera part of the bus system 10 can be seen. Illuminants in this part of the bus system 10 can therefore be monitored with regard to their luminous state. In this case, it is also advantageously possible to use the smartphone to select or zoom an area in which the desired illuminant is located, as can be seen in the right-hand image. Thus, it is possible to select each illuminant individually and precisely, even if the illuminants are close to each other or relatively far away from the user.

A picking interface 8 can also be displayed directly on the smartphone. In this case, a building plan can be displayed on the screen, are entered in the bulbs. Localized addresses can be added. With the aid of the smartphone, an immediate picking of the lighting means, for example a division into groups or changes of address of certain lighting means, can also be carried out. For this purpose, at least one localized light source can be selected in the building plan. It can also be directed in accordance with the floor plan of the light sensor 5 to a selected light source. If the address of a selected light source has been determined with the picking process of the present invention, this may be displayed as being fully configured.

Finally, FIG. 6 shows a multitude of possible portable devices that can be used as the light sensor 5, in particular smartphone, tablet and camera. The portable device may be connected to the central unit 1 via a wireless interface such as Bluetooth, Wifi, Infrared, GSM, 3G. The portable device may even give the user haptic feedback, for example by vibration of the device, if a bus subscriber 2 has been located with regard to his address. The control of the devices can also be completely taken over the portable device. For this purpose, only an access of the portable device to the bus 4 is required. The portable device may also include both central unit 1 and light sensor 5. Central unit 1 and light sensor 5 can therefore be integrated.

In summary, the present invention allows bus users 2 of a bus system 10 to be quickly and easily located with respect to their address. In particular, the embodiment with a smartphone as a light sensor 5 is particularly advantageous because it can be widely used. In addition, that can Localization method of the present invention are carried out inexpensively and is extremely user-friendly and intuitive to use.

Claims

claims

1. central unit (1) of a bus system (10) for

Localization of bus subscribers (2), comprising

 a memory (7) in which an address list with the

Addresses of bus subscribers (2) is stored, and

 a control unit (3) operating in one

Picking mode is designed according to the

Address list sequential control commands to the

Bus subscribers (2) to send.

2. Central unit (1) according to claim 1, wherein a

Bus subscriber (2) is a light source or one

Indicates light.

3. Central processing unit (1) according to claim 1 or 2, wherein the control unit (3) is designed to be such

to send sequential control commands to the bus subscribers (2) that a selected one at any one time

Bus subscriber (2) assumes a first lighting state, which differs from a second lighting state of all others

Bus subscriber (2) differs.

4. Central unit (1) according to claim 3, wherein a

Luminous state is a light power state.

5. Bus system (10) for locating bus subscribers (2), comprising

 a central processing unit (1) according to one of claims 1 to 4,

 several addressable bus users (2),

a bus (4), preferably a DALI bus, which connects the bus users (2) to the central unit (1).

6. bus system (10) according to claim 5 with a

Central unit (1) according to claim 3 or 4, further

including

 one connected to the central unit (1),

preferably uni-directionally connected, light sensor (5) which is designed (5) to detect a luminous state of each bus subscriber (2),

 wherein the central unit (1) is adapted to time a change of the lighting state of a bus station (2) from the second to the first lighting state with a transmitted control command to locate the address of the bus subscriber (2).

7. bus system (10) according to claim 6, wherein the

Central unit (1) is designed to remove a localized address from the stored address list.

8. Bus system (10) according to claim 6 or 7, wherein the central unit (1) is adapted to pick bus subscribers (2) according to their localized addresses.

9. bus system (10) according to one of claims 6 to 8, wherein the first lighting state, a first

Light power state and is detected by the light sensor (5) for a bus subscriber (2), if

 its light output (2) a certain

Threshold reached, or.

 the light output of which differs from the light output of each other bus subscriber (2) by at least one specific threshold value.

10. bus system (10) according to claim 9 wherein the

Threshold after a pass of sequential Control commands according to all addresses of the address list is set adaptively.

The bus system (10) according to any one of claims 6 to 10, wherein the light sensor (5) is adapted to each

 Bus subscriber (2) to be spatially assigned, and

 being after a run of sequential

Control commands according to all addresses of the address list, the spatially assigned bus subscriber (2) is assigned the address according to the control command for which the light sensor (5) has detected the strongest light output for the bus subscriber (2).

12. bus system (10) according to one of claims 6 to 11, wherein the light sensor (5) has a photosensor or a

 Camera includes.

13. bus system (10) according to one of claims 6 to 12, wherein the light sensor (5) is a portable device,

preferably a smartphone.

14. Bus system (10) according to claim 13, wherein the

Light sensor (5) is designed to represent localized addresses of bus subscribers (2) in a room layout plan.

15. A method for locating bus subscribers (2) in a bus system (10), comprising

 Generating an address list with addresses of

Bus subscribers (2),

 Sending sequential control commands to the

Bus subscriber (2) according to the address list.

16. The method according to claim 15, wherein such

sequential control commands are sent, that at each time a bus subscriber (2) a first

Luminous state, preferably a first

Light power state, which assumes a second luminous state, preferably a second

Light power state, all other bus participants (2) differs.

17. The method according to claim 15 or 16, wherein the

Address list is generated by

 Picking up addresses which have been firmly assigned to the bus users (2) during their manufacture, or randomly assigning addresses to the bus users (2).

18. The method of claim 16 or 17, further comprising

Detecting a lighting condition of each

Bus subscribers (2), and

 time alignment of a change of the

 Adjusting the luminous state of a bus subscriber (2) from the second to the first luminous state with a transmitted control command to locate the address of the bus subscriber (2).