• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a system (1) consisting of a biometric sensor (2) and a lighting system (3) with at least one lamp (4), the biometric sensor (2) being set up to support a person (6) by means of fingerprint recording (23) / or face detection, preferably an eye-iris detection (24). The biometric sensor (2) is set up to transmit the result of the identification to the lighting system (3) in a wired or wireless manner (5). The lighting system (3) is set up to set at least one personal operating parameter of the lighting system (3) and / or to activate an administration mode of the lighting system (3) as a function of the identified person (6).
    公开号:AT16870U1
    申请号:TGM385/2015U
    申请日:2015-12-22
    公开日:2020-11-15
    发明作者:
    申请人:Zumtobel Lighting Gmbh;
    IPC主号:
    专利说明:

    description
    LIGHTING SYSTEM WITH PERSONAL CONTROL
    The invention relates to a system consisting of a biometric sensor and a lighting system with at least one lamp. The invention also relates to an operating device for controlling a lighting system in a person-related manner.
    In modern lighting systems, the lighting is now controlled from a central control point. A large number of lights can be controlled and adjusted via this central control point. Modern lighting systems offer the possibility of controlling individual lights or groups of lights or the entire lighting system directly. In addition to the brightness, a programmed dimming process, the color temperature and / or a lighting scene concept can also be set individually using dimming commands.
    [0003] However, these setting options are rarely used. Thus, instead of an individualized, optimized lighting and an associated increased efficiency or an improved feel-good behavior of a person, the more disadvantageous standardized presetting of the lighting system is often used. This also means, for example, that lighting systems are operated independently of the course of daylight, as a result of which greater power consumption increases the costs for operating the lighting system.
    A main cause of this problem is that the lighting system can only be converted into individualized lighting situations with great difficulty via the central control point. For example, in an open-plan office, setting a specific luminaire is only possible by laboriously determining a network address assigned to this luminaire, this network address then having to be laboriously set in the central control point, with a large number of submenus having to be navigated for.
    [0005] A simplified control of a lighting system is known from DE 10 2013 204 479 A1. Here, a larger lighting system has a large number of lighting sub-systems that can be set by means of acoustic signals from a person. In particular in open-plan offices and with a correspondingly large number of people in the open-plan office, such acoustical control of the lighting system appears to be disadvantageous because, on the one hand, the background noise in open-plan offices is great per se and thus an acoustic sensor may carry out false detections or two acoustic control signals from different people could be.
    An often neglected but important factor in the modern world of work is the psychological balance, which also has an impact on physical health. Emotionality in particular is an important factor in the workplace and, not least, has an impact on the employee's work performance. For example, the color of light can have a very emotional effect on a human biology, especially on the human internal clock. DE 20 2011 108 475 U1 therefore proposes using a multisensory system that reacts to a momentary emotion of a person with a corresponding setting of the lighting system. For example, a reaction to a received e-mail can be recorded by means of an acoustic sensor and a lighting system can be adapted accordingly.
    All of these described controls for lighting systems are highly complex due to the large number of sensors and do not necessarily facilitate the control of the lighting system.
    It is therefore the object of the present invention to provide a lighting system which can be adjusted in a simple manner in a person-related manner. The effort involved in building and installing such a lighting system should be low. It is important that the lighting system is as easy to use as possible.
    The present object is described with the in the independent claims
    technical measures solved. Advantageous configurations are described in the respective dependent claims.
    This object is achieved in particular by a system consisting of a biometric sensor and a lighting system with at least one lamp. In this case, the biometric sensor is set up to identify a person by means of fingerprint recording and / or face recording, preferably eye / iris recording. The biometric sensor is also set up to transmit the result of the identification to the lighting system in a wired or wireless manner. Finally, the lighting system is set up to set at least one personal operating parameter of the lighting system and / or to activate an administration mode of the lighting system as a function of the identified person.
    With this system, a simplified lighting control is made possible. This increases the user-friendliness and the intuitive control of the lighting system. A higher level of security is also guaranteed since the lighting system, for example, can only be set individually by already registered people. The functionality of the lighting system is also increased because the mostly standardized setting can be varied very easily.
    [0012] In the following, for example, the color temperature, the brightness and / or a personalized scene setting of a lamp or a lighting subsystem or the entire lighting system are understood as personal operating parameters. The lighting system is thus set up to set an individualized lighting after a person has been identified by means of the biometric sensor.
    In this way, the activation of a lamp assigned to this person can be activated in an open-plan office, in particular daylight gradients, timers or time settings for a special lamp or the lighting system can be activated individually.
    In a preferred embodiment, the biometric sensor is also set up to authenticate the person, with the administration mode of the lighting system being enabled if the person is successfully authenticated. The administration mode is in particular the activation of a maintenance function, a configuration function and / or a service function of the lighting system. In this way, different user groups can be defined in the lighting system, with a corresponding person-related functionality being enabled in the lighting system as a function of the authentication of the person. For example, it is possible for a caretaker to have access to all lighting settings of the lighting system and, in particular, to enable emergency lighting settings or complete operation by activating all lights integrated in the lighting system. The caretaker is also authorized to carry out system tests or maintenance tests, which are only activated after authentication by the lighting system. The administration mode is not visible and / or cannot be selected for non-authenticated persons. Alternatively, an employee classified according to an employment relationship can activate or deactivate more functionality in the lighting system. For example, a permanent employee or a division manager can activate the operation of a projector and the associated deactivation of additional lighting elements in the lighting system while a guest or a freelancer cannot make these settings. In addition, the lighting system can also be expanded, for example the purchase of updated or improved light applications, through authentication.
    In a preferred embodiment, the biometric sensor detects the identification parameters of the person, which are compared with stored identification parameters in order to identify the person. The stored identification parameters are either stored in the biometric sensor itself or after the identification parameters have been transmitted to the lighting system by means of the wired or wireless communication
    cation interface for identifying the person stored in the lighting system.
    In a preferred embodiment, a first set of identification parameters of the person is recorded by means of the biometric sensor in order to set first personal operating parameters of the lighting system. At least one second set of identification parameters of the person is recorded by means of the biometric sensor in order to set second person-related operating parameters of the lighting system.
    Various person-related operating parameters of the lighting system can thus be assigned to a person. For example, by capturing a fingerprint on the left hand, a person-related operating parameter different from capturing a fingerprint on the right hand can be set. For example, a color temperature can be set with a fingerprint on the left hand and the brightness in the lighting system can be varied with the fingerprint of a right hand. Alternatively, a first set of identification parameters of the person can also be recorded by means of a first biometric sensor, for example the fingerprint, and a second set of identification parameters can be carried out by means of a second biometric sensor, for example the iris detection. The setting of the personal operating parameters in the lighting system is therefore not limited to an identification data set, which increases the functionality in the lighting system. As an alternative or in addition, it can also be recorded whether an identification is to take place by means of a finger or a plurality of fingers, a corresponding personal operating parameter being set in the lighting system on the basis of the determined number of fingers.
    Alternatively, the selected identification parameter set of the person can be used by the system to identify whether the person should only be identified in the lighting system in order to set personal operating parameters or whether this person should also be authenticated in order to enter the administration mode of the lighting system to unlock.
    In a preferred embodiment, the detected identification parameters are compared with identification parameters stored locally in a memory area of the lighting system. For this purpose, the identification parameters are transmitted from the biometric sensor to the lighting system. An evaluation of the identification parameters and a comparison with stored identification parameters as well as the management of these identification parameters then takes place in the lighting system itself and is independent of a second lighting system that may be located in the building.
    In this way, the sensor data can be stored locally and a transmission of this sensitive data is avoided, so that the security and trustworthiness of the system are comparatively high.
    In an alternative embodiment, the detected identification parameters are compared with identification parameters stored centrally in a network memory. For this purpose, the biometric sensor is set up to transmit the recorded identification parameters to a central instance via a network, the personal data being compared, managed and activated in the central unit. Although this system reduces the security with regard to the sensitive data, it increases the user-friendliness, since these data records are now also available in different lighting systems in a building and an individualized lighting system is obtained immediately after the person has been successfully identified. A complex administration of a large number of lighting systems and / or updating by the person can thus be omitted.
    [0022] The personal operating parameters are preferably stored in the lighting system.
    In a preferred embodiment, an identified person is assigned an individual color which can be set across the board in the lighting system. Thus, for example, a set meeting room can already be assigned by assigning the color to a person
    be recognized. If, for example, an employee invites you to a meeting, this meeting room can be identified more easily by this individualized color after the person has been successfully identified. All invited persons can use the set color to see which meeting room was booked by the person for the respective meeting. In this way, the recognition of a meeting room can also be compared with a calendar color of the appointment and a meeting room color.
    In addition, service personnel can use the individual color to identify in which of the meeting rooms an ordered service, for example soft drinks, is to be delivered. A serving element, for example a tray, is preferably connected to the system. The serving element also includes a light source that can emit the individualized color. This makes it easier to identify where the service is to be delivered based on the individual color of the room and the serving element. This is particularly helpful in the case of short-term room changes or short-term meetings.
    Such an individualized use of a lighting system can also be used for the delivery of parcels, for example to mark a delivery point for a drone of a parcel delivery company, so that the drone recognizes on the basis of the individualized color where the package is to be delivered and thus the route to the delivery point is marked. In addition, the customer can also see whether a package has arrived if a corresponding color mark has been activated.
    In a preferred embodiment, the lighting system comprises a plurality of lighting sub-systems. The personal operating parameters of the lighting system assigned to the identified person are set. In this way, the relevant lights are automatically activated in an open-plan office. Instead of first finding out a network address of the luminaire and then laboriously selecting it in an operating element, only the luminaires assigned to the user are automatically displayed based on the identification of the person. This is solved by an assignment table in which each person is assigned the appropriate luminaires. In this way, flexible workplaces can be set up and individualized lighting can be activated very easily for each of these flexible work areas. In this way, both the control is accelerated and the setting of lighting that is optimized for the person is made possible. This increases employee satisfaction and the utilization of the functions of a lighting system.
    In addition, a personalized scene concept can be set with the system according to the invention. In this case, a scene can, for example, represent lighting during a projector presentation, during which an automated switching off of lights in a first area and dimming of lights in a rear area of a meeting room are set. Such scene settings can now be individualized and adapted for a user. Due to the biometric sensor, you can quickly and easily switch to a personalized scene concept.
    In a preferred embodiment, the biometric sensor is integrated into an operating element of the lighting system. The lighting system is thus individualized directly when a lighting system is activated. For example, if the person switches on the lighting system, the biometric sensor automatically recognizes the identification parameter sets of the respective person in order to transmit them wirelessly or wired to the lighting system. The identified identification parameters are then compared. The personal setting of operating parameters in the lighting system is thus made possible without additional operating steps.
    In a preferred embodiment, different functionalities are set in the lighting system as a function of the actuation of the operating element. For example, the duration of an actuation of the operating element or the location on the operating element can be evaluated in order to activate different functionalities. Thus, depending on the status of the lighting of the lighting system (on / off) and by detecting
    the length of the actuation, for example, a dimming can be activated or a change in the color temperature or a change in the brightness. A multiple activation of the operating element can also be evaluated, for example in order to activate different scenarios in a lighting system.
    In a preferred embodiment, the control element is a switching element for at least one of the lights of the lighting system. In this way, for example, floor lamps and also pendant lights can be activated directly in a lighting system and, at the same time, a person-related setting of the operating parameters can be made via the biometric sensor.
    The operating element is preferably a button with an integrated fingerprint sensor. On the one hand, this enables the lighting system to be identified and activated in a very simple manner.
    In an alternative embodiment, the operating element is a touch-sensitive screen with an integrated fingerprint sensor. Thus, on the one hand, basic functions can be activated by touching a surface of the control element, for example switching it on and off, and a dimming factor can also be set according to the length of the touch.
    In addition, a point of contact can be evaluated. For example, a first end face of a touch-sensitive surface of the operating element can be used to set the color temperature and an alternative end face can be used to set the brightness of the lighting system. For simplification, graphic markings can be arranged on the operating element in order to increase the user-friendliness. In addition, the number of fingers can also be determined so that, for example, by recognizing the finger, a corresponding personal setting of the lighting system takes place. The number of fingers can, for example, also mean the sequence for corresponding adjustable operating parameters.
    In a preferred embodiment, the operating element can be remotely controlled by means of a user device. The user device is, for example, an electronic user device such as a mobile phone or a portable computer, laptop or tablet PC. In this way, biometric sensors of the user device can be used in order to achieve personalized control of the lighting system. For example, the home button on a smartphone can be used to set the lighting systems in a person-related manner. A phone's camera can also be used to perform face recognition or eye iris recognition.
    In an alternative embodiment, the biometric sensor is introduced into the system as a separate element. In this way, existing systems do not have to be adapted, only a corresponding evaluation has to be stored in the lighting system.
    In a further aspect of the invention, an operating device for a lighting system for operating at least one lamp is provided. The operating device comprises an interface for obtaining identification parameters of a person, a control unit for setting personal operating parameters of the lighting system so that, depending on an identified person, at least one personal operating parameter of the lighting system is set by means of the control unit and / or an administration mode of the lighting system is enabled.
    The interface is preferably wired or wirelessly connected to a biometric sensor in order to obtain the identification parameters of the people.
    In a preferred embodiment, the interface is connected to a control center in order to receive the identification parameters of the person.
    The interface can be, for example, the DALI interface for operating and the operating device and for setting operating parameters. Alternatively, a WLAN, Bluetooth or USB interface can be used to set the corresponding identification pa-
    the person's parameters.
    In a preferred embodiment, the control unit is set up to authenticate the person in order to enable the administration mode of the lighting system.
    In a preferred embodiment, a memory unit is provided in the operating device, in which the personal operating parameters are stored for the recorded identification parameters of the person. In addition, different lighting scenes and also a large number of identification parameter sets associated with a person can be stored in the memory unit. In addition, authentication information can also be stored so that an administration mode can be selected automatically if the authentication is successful.
    In a preferred embodiment, the control unit is set up to control a driver circuit for the lighting system as a function of the user-related operating parameters.
    [0043] The driver circuit has, for example, a converter, in particular a step-up converter or a step-down converter. A secondary supply unit is preferably provided in order to be able to operate the lighting system in an emergency.
    The invention and further embodiments and advantages of the invention are explained in more detail below with reference to figures, the figures merely describing exemplary embodiments of the invention. The same components in the figures are provided with the same reference symbols. The figures are not to be regarded as true to scale; individual elements of the figures can be shown exaggeratedly large or exaggeratedly simplified.
    [0045] They show:
    Fig. 1 shows a first embodiment of a system according to the invention.
    2 shows a second exemplary embodiment of a system according to the invention.
    3 shows a first exemplary embodiment of an operating element according to the invention. 4 shows a second exemplary embodiment of an operating element according to the invention. 5 shows a third exemplary embodiment of an operating element according to the invention. 6 shows a fourth exemplary embodiment of an operating element according to the invention. 7 shows a fifth exemplary embodiment of an operating element according to the invention. 8 shows a sixth embodiment of an operating element according to the invention. 9 shows a third exemplary embodiment of a system according to the invention.
    10 shows an exemplary embodiment of an operating device according to the invention.
    Table 1 shows an example of an assignment table for a system according to the invention.
    A system 1 according to the invention is shown in FIG. 1. The system 1 comprises a biometric sensor 2 and a lighting system 3. The lighting system 3 is connected to the biometric sensor 2 via a communication interface 5. This communication interface can be wireless or wired. The lighting system 3 is also connected to at least one light 4.
    According to the invention, the number of lights 4 for a lighting system 3 is not limited. Thus, for example, a cascade of LEDs connected in series can be viewed as a light 4. In addition, cascades of LEDs connected in parallel can also be viewed as luminaire 4. The lamp is in particular a light source, for example a light-emitting diode.
    The person-related operating parameter is in particular a color temperature, a
    Brightness, a course of daylight, a scene concept, a timer setting of the light 4 or the like.
    If a user 6 is to be identified in the system 1 by means of the biometric sensor 2, an identification parameter set is transmitted to the lighting system 3 via the interface 5. A local controller 10, for example a control unit 19, is provided in the lighting system 3, which compares the detected identification parameters of the person 6 with the identification parameters stored locally in a memory 8 of the lighting system 3. If the comparison in the local control 10 results in a match, personal operating parameters of the lighting system 3 are set, with which the light 4 is then operated.
    In Fig. 2, a second embodiment of a system 1 according to the invention is shown. A biometric sensor 2 is also provided here in order to record identification data of a person. Here, the biometric sensor 2 is incorporated in an operating element 7. The introduction of the biometric sensor 2 into the operating element 7 is explained in more detail in the following exemplary embodiments. Thus, the identification of a person 6 by means of the biometric sensor 2 is carried out immediately with the activation of a lighting system 3. After a detected activation of the control element 7, the control element 7 communicates with the lighting system 3 via the interface 5 '. In contrast to FIG. 1, the detected identification data are transmitted to a central control 11 and compared there with the identification parameters stored in a memory 8. The management, control and storage of the identification parameters are thus carried out in a central instance 11 and are separate from the actual lighting system 3. In this way, different lighting systems 1 can be operated with the same identification parameters, so that complex administration of these identification parameters can be dispensed with.
    In this way, all of the lighting systems 3 connected to the central controller 11 can be set in a person-related manner by means of an identification parameter set.
    A complex adaptation of each individual lighting system to the individualized settings can be dispensed with. For this purpose, however, each lighting system 3 must be connected to the central control 11 via a corresponding interface 9. This is done in particular via a network 9, for example a network assigned to the lighting system 3, which is also provided for transmitting lighting commands, for example the DALI interface or via a network 9 already present in building technology, for example a LAN connection.
    Using the systems according to the invention shown in FIGS. 1 and 2, different applications can now be implemented. Initially, by means of the combinations of biometric sensor 2 and operating element 7 shown in FIG. 2, the activation of the lighting system 3 can be combined with the identification of the person 6. In this way, the relevant lights 4 can be automatically displayed on an operating element 7 and / or the relevant light 4 can be set immediately. Instead of first finding out the luminaire address of the luminaire 4 in order to then laboriously search for it in a submenu of the operating element 7, only the relevant luminaires 4 that are assigned to the person 6 are automatically displayed. This is achieved via an assignment table, for example according to Table 1, in which the corresponding lamp 4 of the lighting system 3 is assigned to each person 6. In particular, this enables flexible workplaces to be set, so that a change of workplace within the building does not mean reconfiguring the lighting system 3 for the respective employee, but rather a user-related setting of the lighting system 3 can be made by merely identifying the person 6.
    If the control element 7 is activated, only the lights 4 assigned to the person appear automatically and are activated immediately. Switching, dimming or even setting the color temperature is therefore possible in an individualized manner. Thus, for example, the problem of finding the right luminaire 4 from a large number of luminaires 4 existing in an open-plan office can be greatly simplified.
    In particular, a personalized scene concept can also be implemented in this way. For example, in smaller rooms or in meeting rooms, scene concepts can now be personalized. A scene covers a specific situation, for example the setting of the lighting system 3 for a projector presentation, with an individualized setting of the lighting system 3 taking place. This can now be individualized. If a person changes the configuration of a scene, this is not automatically accessible to all persons and can only be called up by corresponding identification of person 6. Changes to the configuration of scenes can thus be automatically saved on a user-specific basis. For example, a brightness of 500 lux and a color temperature of 6500 K can be set for a person 1, while the brightness is set at 400 lux and the color temperature is set at 4500 K for a person 2.
    Authentication for different user levels can also be achieved with this system 1 according to the invention. A so-called administration mode can thus be activated in the lighting system when a person 6 has been appropriately authenticated by the lighting system 3. For example, the course of daylight, the setting of timers and / or the current time can only take place through appropriate authentication of the user. As a rule, this is an administrator of the building technology, for example a caretaker or a corresponding person, so that the lighting system 3 can be set up in a coordinated manner. This ensures that only authorized service technicians can administer the system and / or change the starting point of function or duration tests. Nowadays, this is solved with passwords, which can be omitted due to the identification and authentication carried out in the system 1 by means of the inventive use of a biometric sensor 2. The procedure is thus considerably simplified. After authentication, relevant menus are automatically activated for the respective user, for example a maintenance function, a configuration function or a service function. The ordering of light applications for a lighting system 3 is also provided as a service function, for example, so that a correspondingly authenticated user is able to load an updated and / or improved light management application into the lighting system 3.
    The operating element 7 is connected to a network 9 and leads to a faster, smoother maintenance of this light management application.
    The systems 1 shown in FIGS. 1 and 2 can be used to assign 6 individual colors to each person. This color can, for example, also be stored in a calendar entry and be visible to everyone who invites. The inviting person 6 then enters a meeting room and is recognized by the identification by means of the biometric sensor 2. As a result, room lighting can initially be set individually and a marking in the meeting room can also be set to this individualized color. People who were invited to the meeting can now easily identify the respective meeting room using the individual color coding.
    In Fig. 3, a first embodiment of an operating element 7 according to the invention is shown. The operating element 7 comprises a biometric sensor 2 below a touch-sensitive surface 71, for example a touch screen. Switching on or off the lighting system 3 can thus be combined with the inventive identification and authentication on the lighting system 3. When the operating element 7 is actuated, the person 6 is identified immediately. In addition, further evaluations can be carried out. For example, a long press of the button on the touch-sensitive surface 71 while the light 4 is switched off at the same time can cause the light 4 to be dimmed up. After pressing the button for 5 seconds, for example, a brightness of 100% is set. Alternatively, the lamp 4 can be dimmed down by pressing the key on the touch-sensitive surface 71 for a correspondingly long time and the lamp 4 is switched on. Furthermore, the number of keystrokes can also lead to a personal setting of the lighting system 3.
    In Fig. 4, a second embodiment of an operating element 7 according to the invention is shown. Here too, the operating element 7 includes the biometric sensor 2. In addition to the touch-sensitive surface 71, location-dependent functions are also defined on the surface 71. For example, a warm white can be set on the right end face 72b of the operating element 7, whereas a cold white can be set using the left end face 72a of the touch-sensitive sensor 7. These surfaces can be fixed and provided with appropriate markings, as shown in FIG. 4. Alternatively, a variable display surface is also possible, with all scenes, colors, moods and dimming values as well as settings being arranged on defined parts of the touch-sensitive surface 71.
    In Fig. 5, a third embodiment of an operating element 7 according to the invention is shown. The operating element 7 in turn comprises a fingerprint sensor 23 as a biometric sensor 2. According to FIG. 5, a corresponding marking 22 for placing the hand in order to detect the identification parameters is displayed. On the basis of the operating element 7, it is recognized with which number and with which of the fingers the user 6 identifies himself on the lighting system 3. Various identification parameter data records can thus be stored for a person 6. A special user-related setting parameter can thus be stored for each of the stored identification parameter data records for the person 6. If, for example, the left hand is placed on, the brightness is varied, if the right hand is placed, the color temperature is set, etc. The sequence of the fingers can also be varied, whereby one can choose between scene setting and dimming values or other settings.
    In FIG. 6, an operating element 7 shown in FIG. 5 is integrated into a switch, so that the biometric sensor 2 with the corresponding marking 22 is introduced next to the touch-sensitive surface 71 of the operating element 7. The marking 22 is shown here. In addition, placement aids 21 are displayed with which the user 6 is enabled to correctly carry out the corresponding identification parameterization. Simplified operation is thus possible.
    In Fig. 7, a sixth embodiment of an operating element 7 according to the invention is shown. The operating element 7 has a multiplicity of operating switches, four of the six operating switches additionally being equipped with fingerprint sensors 23. In this way, time-consuming dimming and setting of the respective parameter can be omitted and the information about which operating element 7 was pressed is combined with the corresponding person-related parameter from the lighting system 3.
    8 shows a seventh exemplary embodiment of an operating element according to the invention. In contrast to the previous exemplary embodiments for operating elements 7, an iris recognition sensor 24 is shown here. The user thus imagines this control switch and shows his eye iris, whereupon the person 6 is identified.
    9 shows a third exemplary embodiment of a system 1 according to the invention. The system 1 comprises a plurality of operating elements 7, a first operating element 7 ′ being equipped with a touch-sensitive surface 71. A second operating element 7 ″ is equipped in accordance with the exemplary embodiment shown in FIG. 7. Instead of integrating biometric sensors 2 into the respective operating elements 7, the user 6 is authenticated using a user device and a corresponding remote control 13. The user can thus use a biometric sensor in the Identify the user device on the lighting system 3.
    An operating device 14 according to the invention is shown in FIG. 10. The operating device 14 comprises a primary supply with two connections 18. A mains voltage VIN of 230V is applied to the operating device 14 via this primary supply 18. A transformer 15 is provided to convert this primary supply 18 into a supply having a low voltage. A converter 16 is provided in order to operate the lighting means 4 by means of a control unit 19. The converter 16 is, for example, a step-up converter or a step-down
    setter.
    According to the invention it is provided that the control unit 19 has an interface 20 via which the identification parameters can be transmitted to the operating device 14. By means of the identification parameters, personal operating parameters are set in the control unit 19 in order to operate the lamp 4 individually for a user 6. According to the embodiment of FIG. 10, the operating device 14 has a memory unit 8 with which the detected identification parameters are compared with the identification parameters stored in the memory 8. The management, control or comparison of the identification parameters thus takes place locally in the operating device 14.
    An exemplary assignment table for a memory 8 is shown in Table 1. The identification parameters for personal operating parameters and also for an administration setting are shown here. According to a first entry in Table 1, a person 1 is identified and the person 1 is assigned the personal operating parameters of 500 lux brightness and a color of 6500 K. Person 1 is also authorized to order light applications. An individualized setting of the lighting system 3 is thus achieved for each entry and a user-specific administration setting is made possible. For example, according to entry 3, in addition to querying the battery status, the caretaker can also set an emergency light and carry out a function test.
    All shown, described or claimed features can be combined with one another as desired.
    REFERENCE LIST
    1 System 2 Biometric sensor 21 Placement aid 22 Marking for identification parameters 23 Fingerprint sensor 24 Iris recognition
    3 Lighting system 4 Light 5 Communication between sensor and lighting system 5 Communication between control element and lighting system 6 Person 7 Control element, control switch 71 Touch-sensitive surface 72 Location-dependent function
    8 memories
    9 network
    10 local control
    11 Central control 13 Remote control
    14 control gear
    15 transformer
    16 converters
    17 Secondary Supply 18 Primary Supply 19 Control Unit
    20 interface
    权利要求:
    Claims (10)
    [1]
    1. System (1) consisting of a biometric sensor (2) and a lighting system (3) with at least one lamp (4), wherein: the biometric sensor (2) is set up, a person (6) by means of fingerprint detection (23) and / or face detection, preferably an eye-iris detection (24); the biometric sensor (2) is set up to transmit (5) the result of the identification in a wired or wireless manner to the lighting system (3); the lighting system (3) is set up, depending on the identified person (6), to set at least one person-related operating parameter of the lighting system (3) and / or to activate an administration mode of the lighting system (3).
    [2]
    2, system (1) according to claim 1, wherein the biometric sensor (2) is also set up to authenticate the person (6) and wherein, if the person (6) is successfully authenticated, the administration mode of the lighting system (3) is enabled, in particular to a maintenance function, a configuration function and / or a service function of the lighting system (3).
    [3]
    3. System (1) according to one of the preceding claims, wherein the biometric sensor (2) detects identification parameters from the person (6), which are compared with stored identification parameters in order to identify the person (6).
    [4]
    4. System (1) according to claim 3, wherein by means of the biometric sensor (2) a first identification parameter set of the person (6) is recorded in order to set first personal operating parameters of the lighting system (3) and wherein by means of the biometric sensor (2) at least one second identification parameter set of the person (6) is detected in order to set second person-related operating parameters of the lighting system (3).
    [5]
    5. System (1) according to claim 3 or 4, wherein the detected identification parameters are compared with identification parameters stored locally in a storage unit (21) of the lighting system (3).
    [6]
    6. System (1) according to claim 3 or 4, wherein the system communicates with a network (9) in order to compare the detected identification parameters with identification parameters stored centrally in a network memory.
    [7]
    7. System (1) according to one of the preceding claims, wherein the personal operating parameters are stored in the lighting system (3).
    [8]
    8. System (1) according to one of the preceding claims, wherein an identified person is assigned an individual color which is set across lighting systems.
    [9]
    9. System (1) according to one of the preceding claims, wherein the lighting system (3) has a plurality of lighting subsystems and the personal operating parameters of the lighting subsystem are set, which is assigned to the identified person (6).
    [10]
    10. Operating device (14) for a lighting system (3) for operating at least one lamp (4) comprising: - an interface (20) for obtaining identification parameters of a person (6); - A control unit (19) for setting personal operating parameters of the lighting system (3) so that, depending on an identified person, at least one personal operating parameter of the lighting system (3) by means of the
    Control unit (19) is set and / or an administration mode of the lighting system (3) is enabled.
    In addition 8 sheets of drawings
    类似技术:
    公开号 | 公开日 | 专利标题
    EP3166370B1|2019-06-12|Illumination system with personal control
    DE102017127239A1|2018-05-24|Server-supplied visual output on a voice interface device
    DE102017129939A1|2018-07-05|Conversational proactive notifications for a voice interface device
    DE102014010352A1|2016-01-14|Interactive mirror
    EP1849737B1|2012-04-04|Illumination device for a lift cage and method for transporting people in a lift
    EP2315503B1|2018-05-30|Method and system for allocating operating addresses to light sources or lights
    DE102017104960A1|2017-09-28|LIGHTING SYSTEM, TERMINAL AND METHOD FOR ADJUSTING THE LIGHTING SYSTEM
    DE102010032761A1|2012-02-02|Method for controlling controller for lighting system, involves detecting position or state of motion of person by using depth sensor camera
    DE102016210414B4|2021-09-23|Address assignment and configuration of components of a lighting system using transponders
    EP2437574B1|2018-08-29|Control device for controlling a multicolour light source and lighting device
    EP3106002B1|2018-11-28|Lighting system and method for operating a lighting system having an integrated safety concept
    EP2779801B1|2018-11-21|Lighting system and method for controlling a lighting system
    EP3217765B1|2019-06-26|Simplified commissioning concept for controlling actuators of an installation in a building
    EP2925098B1|2017-02-22|Luminaire adapted to communicate with mobile device
    DE102018109192A1|2018-10-31|Illuminant, lighting system and method of pairing in the lighting system
    DE202013101825U1|2014-07-29|HMI device for the control of lights, blinds and / or air conditioners
    EP3201703B1|2020-05-20|Control system for building lighting systems and other domestic engineering facilities
    DE102014117117B3|2015-11-19|Method for controlling at least one actuator with a portable control unit
    DE102016204167A1|2017-09-14|Door communication system, outdoor unit for a door communication system and method of operating a door communication system
    DE102018112882A1|2018-11-29|Optical workplace status display system
    AT16868U1|2020-11-15|Method for controlling a lighting device and lighting system
    EP3516462B1|2020-12-30|Room control system
    EP3657286B1|2021-01-06|Method for configuring an actuator device in a building automation system
    EP3120672B1|2019-12-25|System for actuating loads of a domestic control apparatus by means of muscle impulses of at least one user and corresponding method
    DE102004046582B4|2007-12-06|Control of a controllable device
    同族专利:
    公开号 | 公开日
    DE102015221746A1|2017-05-11|
    EP3166370B1|2019-06-12|
    EP3166370A1|2017-05-10|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20120086338A1|2005-12-30|2012-04-12|Seoul Semiconductor Co., Ltd.|Illumination system and method for controlling the same|
    WO2010079388A1|2009-01-07|2010-07-15|Koninklijke Philips Electronics N.V.|Intelligent controllable lighting networks and schemata therefore|
    WO2011001320A1|2009-06-30|2011-01-06|Koninklijke Philips Electronics, N.V.|Systems and methods for managing interaction with controllable lighting networks|
    EP2615774A1|2010-09-06|2013-07-17|Sk Telecom Co., LTD|Method and system for automatically controlling illumination in a building|
    EP2846202A2|2013-09-10|2015-03-11|Panasonic Intellectual Property Corporation of America|Method for controlling communications terminal and program|
    WO2015054611A1|2013-10-10|2015-04-16|Digital Lumens Incorporated|Methods, systems, and apparatus for intelligent lighting|
    DE10103948A1|2001-01-30|2002-08-01|Bsh Bosch Siemens Hausgeraete|Method and device for controlling household appliances|
    US6724159B2|2001-12-27|2004-04-20|Koninklijke Philips Electronics N.V.|Method and apparatus for controlling lighting based on user behavior|
    US7298871B2|2002-06-07|2007-11-20|Koninklijke Philips Electronics N.V.|System and method for adapting the ambience of a local environment according to the location and personal preferences of people in the local environment|
    EP2001223B1|2007-06-04|2016-09-21|fm marketing gmbh|Multi-media configuration|
    WO2014109891A2|2013-01-09|2014-07-17|Lsi Industries, Inc.|Lighting and integrated fixture control|
    WO2013001432A1|2011-06-29|2013-01-03|Koninklijke Philips Electronics N.V.|Intelligent lighting network for generating light avatars|
    DE202011108475U1|2011-11-30|2012-01-26|Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.|Adaptive lighting system|
    US9345103B1|2013-01-07|2016-05-17|Amazon Technologies, Inc.|Non-linear lighting system brightness control for a user device|
    DE102013204479A1|2013-03-14|2014-09-18|Zumtobel Lighting Gmbh|Lighting system and method for controlling a lighting system|
    US9795004B2|2014-04-14|2017-10-17|Abl Ip Holding Llc|Learning capable lighting equipment|DE102017215441A1|2017-09-04|2019-03-07|Tridonic Gmbh & Co Kg|Operating a lighting system|
    CN110337164B|2019-06-28|2021-03-30|杭州勇电照明有限公司|Intelligent light control method|
    CN113038663A|2021-04-22|2021-06-25|读书郎教育科技有限公司|Control method of intelligent desk lamp and intelligent desk lamp|
    法律状态:
    2021-08-15| MM01| Lapse because of not paying annual fees|Effective date: 20201231 |
    优先权:
    申请号 | 申请日 | 专利标题
    DE102015221746.9A|DE102015221746A1|2015-11-05|2015-11-05|Lighting system with personal control|
    [返回顶部]