Abstract: A housing for a luminaire or an operating device for the luminaire, wherein the housing is configured to accommodate at least one electronic component and/or a light source, and comprising a conductive housing component (2). The housing includes at least one line (1, 1?, 1?, 1??, 1??) for transmitting electric high frequency signals or for transmitting and/or receiving radio waves. The transmission line is formed by arranging a dielectric layer (4, 4a, 4b, 9) and a conductor (3, 3 . . . 3c, 7) on the housing component (2) such that the conductive housing component (2) serves as a reference plane, and the conductive housing component (2) and the conductor (3, 3 . . . 3c, 7) sandwich the dielectric layer (4, 4a, 4b, 9).

Abstract: The invention relates to an LED-driver, comprising an actively switched PFC circuitry and a bus interface for a wire-bound bus, wherein a voltage supply for the bus interface for powering the bus is tapped off the output voltage of the active PFC circuitry, further comprising a control circuitry for a feedback control of an output voltage of the actively switched PFC by controlling a switch of the PFC, wherein the time constant of the feedback control of the control circuitry is faster during time periods in which the bus interface is transmitting or receiving signals, compared to time periods without activity.

Abstract: An emergency converter device provides an interface for selecting an operation parameter for an emergency operation mode of the emergency converter device. The emergency converter device provides a supply current ILED to a load device, in particular to a lighting module including on or more light emitting diodes. The emergency converter device comprises a control circuit configured to set at least one operating parameter of the emergency converter device, an interface comprising a first terminal and a second terminal for connecting electrically a status indicator light emitting diode, and a detection circuit connected to the control circuit. The detection circuit is configured to detect a polarity of the status indicator light emitting diode connected to the first terminal and the second terminal, and the control circuit selects the at least one operating parameter of the emergency converter device based on the detected polarity.

Abstract: The invention relates to an isolated converter (100) for providing a current supply to an LED load, comprising: a galvanic isolation stage (101); a sensing circuit (103) on a primary side of the isolation stage (101), which is magnetically coupled to a secondary side of the isolation stage (101); wherein the sensing circuit (103) is configured to receive a feedback signal that is proportional to a secondary side current; and a control unit (105) configured to determine an output current of the converter (100) based on the feedback signal; wherein at least one electrical characteristic of the sensing circuit (103) and/or the control unit (105) is adjustable to convert the feedback signal from a first ratio to a second ratio to the secondary side current.

Abstract: A switched power converter (102) is arranged for supplying lighting means (108) as a load, having at least one (M40, M41) switch controlled by a control unit (106), wherein the control unit (106) comprises: a feedback controller, such as an ASIC or microcontroller, generating a switch control signal based on a feedback signal (Imeas), such as e.g. the load current (ILED), and a separate sweep block, supplied with a signal representing a characteristic of the load (LED), such as e.g. the load voltage (VLED), and modulating the switch control signal (tout-ctrl) by a cyclic sweep, wherein the modulated switch control signal (tout-sweep) is provided directly or indirectly to the at least one switch (M40, M41).

Abstract: The invention proposes a communication adaptor, comprising within one casing: a transmission antenna, a wired control interface connected to wired control interface terminals, a control circuitry for converting wirelessly received wireless communication signals into wired control interface signals and vice versa, wherein the adaptor is designed such that it can be brought in close contact with a reception antenna of a converter for lighting mean, such as e.g. LEDs, in order to establish a wireless communication, wherein the control circuitry and the wired control interface are powered by means of the wired control interface terminals.

Abstract: The invention relates to an isolated primary side switched converter (100), comprising a galvanic isolation stage (105) separating a primary side (101) and a secondary side (103) of the converter (100), a secondary side winding (107) of the isolation stage (105), wherein the secondary side winding (107) is coupled to a primary side winding, and wherein the secondary side winding (107) comprises a center tap, a first terminal (T1), a second terminal (T2) and a third terminal (T3) for connecting an LED load (LED1, LED2) on the secondary side (103) of the converter (100), a rectification circuit (109) on the secondary side (103) of the converter (100), wherein the rectification circuit (109) is configured to set the first terminal (T1) at a first electrical polarity, and to set the second and the third terminal (T2, T3) at a second electrical polarity that is different to the first electrical polarity, wherein the third terminal (T3) is electrically connected to the center tap, and wherein a voltage between the

Abstract: The present invention relates to a converter unit for providing a supply current to a load device (2) using an energy storage device (6). The converter unit (1) comprises a controlling means (7) configured to set at least one charging parameter and/or a charging mode and to control charging of the energy storage device (6) based on the set charging parameter and/or the set charging mode; and at least a first terminal (S1), a second terminal (S2) and a third terminal (S3) for electrically connecting a two-pole status indicator light (8), wherein the controlling means (7) is configured to detect to which of the first terminal (S1), the second terminal (S2) and the third terminal (S3) the two-pole status indicator light (8) is connected and is configured to set the at least one charging parameter and/or the charging mode based on the detection result.

Abstract: The invention relates to a system (400) comprising a data processing unit (402) and/or a central database (403), and a grid (100) of a plurality of building technology sensor modules (101a-d). Each of the sensor modules (101a-d) comprises light sensor (103), preferably a daylight sensor, an acoustic sensor (105), a motion sensor (107), a controller (109) which is configured to receive output signals from said sensors (103, 105, 107), and an interface, preferably a wireless interface (111), for a communication between the controller (109) and a gateway (401) for forwarding sensor information signals (130) to the data processing unit (402) and/or the central database (403), wherein said sensor information signals (130) comprise a timestamp, an identifier of a sensor module (101a-d) and a sensor value.

Abstract: The invention relates to a method (20) for monitoring the density and the movement of humans using a grid (100) of a plurality of luminaires (101a-d), each of the luminaires (101a-d) comprising an acoustic sensor (105), a motion sensor (107), preferably a Doppler sensor, a controller (109) supplied with output signals of said sensors (105, 107), and a wireless interface (111) for a communication between the controller (109) and a gateway (401) for forwarding sensor information signals (130) to a central database (403), wherein, based on the information in the database (403), the density and/or the movement of humans in an area covered by the grid (100) is estimated by generating a time series of sensor values, such as sound pressure, motion speed and/or motion intensity, of each luminaire (101a-d).

Abstract: The invention relates to grid (100) comprising at least one luminaire (101a-d), wherein at least one luminaire (101a-d) comprises one or more acoustic sensors (105), and preferably other sensors (103, 107); wherein the grid further comprises a controller (109) supplied with the output signals of said sensors (103, 105, 107), wherein the controller (109) is arranged for discriminating different sound categories in the output signals, including human voice sound, and to issue a sensor information signal (130) representing at least the sound category.

Abstract: The invention relates to an emergency lighting system (100), comprising a DC bus (103), at least one driver (101) for emergency lighting means that is connected to the DC bus (103), wherein the at least one driver (101) is further connected to a local battery (102), at least one central battery (105), a bus manager (104) connected to the at least one central battery (105), wherein the bus manager (104) further comprises output terminals for connecting the bus manager (104) to the DC bus (103). The bus manager (104) comprises a communication interface (104a) for communicating with the at least one driver (101), wherein the bus manager (104) is configured to receive an energy supply information from the at least one driver (101) and/or from the central battery (105), wherein the bus manager (104) is configured to control the at least one driver (101) to receive a power supply from the local battery (102) or from the central battery (105) based on the energy supply information.

Abstract: The invention relates to a method (20) for functional classification of luminaires (101a-d), the luminaires (101a-d) being arranged as a grid (100) of a plurality of luminaires (101a-d), each of the luminaires (101a-d) comprising at least two different sensors (103, 105, 107), preferably at least two of a light sensor (103), an acoustic sensor (105) and/or a motion sensor (107); the method (20) comprising the steps of: supplying (21) output signals of said sensors (103, 105, 107) to a controller (109), preferably wirelessly forwarding (23) sensor information signals (130) including timestamps and luminaire IDs to a central database (403), correlating (25) the sensor information signals (130) over a defined period of time, and generating (27) functional classification information based on the correlations found, wherein the functional classification information indicates a likelihood function of a certain usage of each luminaire, out of a given set of usage functions.

Abstract: The invention relates to a method (20) for grouping luminaires (101a-d), the luminaires (101a-d) being arranged as a grid (100) of a plurality of luminaires (101a-d), each of the luminaires (101a-d) comprises one or more sensors (103, 105, 107); the method (20) comprising the steps of: supplying (21) output signals of said one or more sensors (103, 105, 107) to a controller (109), preferably wirelessly forwarding (23) sensor information signals (130) including timestamps and luminaire IDs to a central database, correlating (25) the sensor information signals (130) over a defined period of time, and generating (27) grouping information based on the correlations found, wherein the grouping information relates to a spatial arrangement of the luminaires (101a-d).

Abstract: The present invention relates to a luminaire (1), comprising a housing (2) having a diffusion panel (3) as light emission surface, comprising at least one illuminant (4) which is arranged within the housing (2) such that it is set up to emit light through the diffusion panel (3) to the area outside of the housing (2), and comprising at least two light sensors (S1, S2) arranged within the housing (2), the light sensors being set up to detect light. The at least two light sensors (S1, S2) have different detection regions (B1, B2) within the housing (2) and are set up to detect light (Et) which enters through the diffusion panel (3) into the housing interior from the area outside of the housing (2), wherein, on account of the different detection regions (B1, B2), one of the at least two light sensors (S1, S2) detects light (Er2) that was emitted by the at least one illuminant (4) and reflected from at least one wall of the housing interior.

Abstract: The invention relates to a method (100) for operating an isolated primary side switched converter (300) for providing a voltage supply to an LED load (401), wherein the converter comprises a galvanic isolation stage (301), the method comprising the steps of: detecting (101) a feedback signal at a primary side of the galvanic isolation stage (301), wherein the feedback signal corresponds to a secondary side voltage, determining (103) an LED supply voltage based on the feedback signal, calculating (105) a threshold value based on a constant reference voltage and an adjustment factor, wherein the adjustment factor is a dynamic factor whose absolute value increases with increasing LED current, and interrupting (107) the voltage supply to the LED load (401) if the determined LED supply voltage exceeds the threshold value.

Abstract: The invention relates to a power factor correction (PFC) circuit (20), comprising an inductor (21) which is configured to provide a discharge current, a capacitor (23) which is connected to the inductor (21) via a switch (24) and which can be charged with said discharge current, a control unit (14) which is configured to alternately switch the switch (24) on and off based on a feedback control, wherein the control unit (14) has an input interface (42) for receiving a feedback signal (ZXCS) which represents a discharge voltage of the inductor (21), wherein the control unit (14), in a DCM mode, is further configured to calculate a switch on time (Ton) of the switch (24) which is after a first local minimum of the discharge voltage, and wherein, after switching off the switch (24), the control unit is configured to: either switch on the switch (24) at a next or closest local minimum of the inductor voltage after Ton, in case Ton is less than a directly or indirectly set reference time (Tref), or close the switch

Abstract: The invention relates to a driver (100) for emergency lighting means (101), comprising output terminals (111a-b) for electrically supplying at least one emergency lighting means (101), and a test switch (103) for starting a test routine controlled by a controller (109) of the driver (100), wherein the driver (100) is settable to a commissioning mode if the test switch (103) is activated according to a predefined operation pattern defined by time durations and/or repetition criteria of the operation pattern.

Abstract: The present invention relates to a converter unit for providing a supply current to a load device (2) using an energy storage device (6). The converter unit (1) comprises a controlling means (7) configured to set at least one charging parameter and/or a charging mode and to control charging of the energy storage device (6) based on the set charging parameter and/or the set charging mode; and at least a first terminal (S1), a second terminal (S2) and a third terminal (S3) for electrically connecting a two-pole status indicator light (8), to wherein the controlling means (7) is configured to detect to which of the first terminal (S1), the second terminal (S2) and the third terminal (S3) the two-pole status indicator light (8) is connected and is configured to set the at least one charging parameter and/or the charging mode based on the detection result.

Abstract: The invention relates to an isolated driver (100) for lighting means (109), comprising: a primary circuit (100a), a secondary circuit (100b), an isolation barrier (106) separating the primary circuit (100a) and the secondary circuit (100b), wherein a ground potential of the primary circuit (100a) and a ground potential of the secondary circuit (100b) are connected via a capacitor (107), and a control circuit (111) on the secondary side (100b), monitoring a current to/from the capacitor (107) to the ground potential of the secondary circuit (100b) and issuing a mains (101) failure signal in case the current does not meet predefined conditions, preferably in case no such current is detected.