Abstract: The invention provides a lighting device comprising a transmitter, a controller and a sensor; wherein the controller is configured to control the transmitter to repeatedly transmit a second wireless message interleaved with a first wireless message, wherein the first wireless message has a first duration and comprises a first signal, wherein the second wireless message has a second duration and comprises a second signal; wherein the first duration and/or the second duration is adaptive during a lifetime of the lighting device; wherein the controller is configured to receive a measurement from the sensor and control the transmitter to transmit the second wireless message comprising the second signal comprising the measurement.

Abstract: A mobile object configured for movement in an area equipped with VLC illumination sources comprises a light sensor arranged to detect illumination from at least one of the illumination sources within the view of the light sensor; a computer arranged to determine from the detected illumination (i) a position of the mobile object relative to the at least one illumination source and (ii) the identifier of the at least one illumination source; and a transceiver. The transceiver can receive from another mobile object a message comprising the position of the other mobile object relative to a source of illumination, and the identifier of that source of illumination. From this, the computer determines from its position and the message a distance from the other mobile object. A mobile object which transmits such a message is also envisaged.

Abstract: A system is configured to obtain locations of a mobile device (1) and obtain presence detection information. The locations are determined using visible light signals and dead reckoning information recorded at different moments. The presence detection information indicates presence detected using presence sensor devices (31, 32) at the different moments. The system is further configured to obtain sensor locations and sensor fields of view, determine sensor orientations based on the locations of the mobile device, the sensor locations and the presence detection information, and determine a sensor coverage area (61, 62), comprising gaps in the sensor coverage area, based on the sensor locations, the sensor orientations and the sensor fields of view. The system is also configured to determine one or more parameters for presence detection based on the gaps in the sensor coverage area and output the parameters or a presence detection result which has been determined using the parameters.

Abstract: The invention provides a lighting device comprising a transmitter, a controller and a sensor; wherein the controller is configured to control the transmitter to repeatedly transmit a second wireless message interleaved with a first wireless message, wherein the first wireless message has a first duration and comprises a first signal, wherein the second wireless message has a second duration and comprises a second signal; wherein the first duration and/or the second duration is adaptive during a lifetime of the lighting device; wherein the controller is configured to receive a measurement from the sensor and control the transmitter to transmit the second wireless message comprising the second signal comprising the measurement.

Abstract: A mobile object configured for movement in an area equipped with VLC illumination sources comprises a light sensor arranged to detect illumination from at least one of the illumination sources within the view of the light sensor; a computer arranged to determine from the detected illumination (i) a position of the mobile object relative to the at least one illumination source and (ii) the identifier of the at least one illumination source; and a transceiver. The transceiver can receive from another mobile object a message comprising the position of the other mobile object relative to a source of illumination, and the identifier of that source of illumination. From this, the computer determines from its position and the message a distance from the other mobile object. A mobile object which transmits such a message is also envisaged.

Abstract: It is an object of the invention to provide an improved device for location based services.

Abstract: A lamp comprises a plurality of luminous segments each at a different position within the lamp, wherein each of the luminous segments is arranged to emit illumination modulated to transmit a different respective code. A controller is configured to control the codes of the different luminous segments so as to have a predefined relationship therebetween (e.g. one code is N and the other is N+1).

Abstract: A lighting system comprises multiple luminaries (4b) installed at known locations in an environment. Each is configured to emit a unique luminaire identifier (ID) into the environment. A database (28) holds multiple location identifiers, each of which identifies one of the known locations. A route (rA, rB, rC, rD) through the environment is identified based on the location identifiers, the route traversing a plurality of the known locations. Data generated by moving a photodetector (6) along the route though the environment is received, the data conveying a sequence of the luminaire identifiers detected by the photodetector from luminaries encountered in moving along the route, the sequence being in order of detection. A database update is performed by, for at least one luminaire identifier in the sequence: identifying its position in the sequence, and updating the database based on the at least one luminaire identifier and its identified position in the sequence.

Abstract: A lighting system comprises multiple luminaries (4b) installed at known locations in an environment. Each is configured to emit a unique luminaire identifier (ID) into the environment. A database (28) holds multiple location identifiers, each of which identifies one of the known locations. A route (rA, rB, rC, rD) through the environment is identified based on the location identifiers, the route traversing a plurality of the known locations. Data generated by moving a photodetector (6) along the route though the environment is received, the data conveying a sequence of the luminaire identifiers detected by the photodetector from luminaries encountered in moving along the route, the sequence being in order of detection. A database update is performed by, for at least one luminaire identifier in the sequence: identifying its position in the sequence, and updating the database based on the at least one luminaire identifier and its identified position in the sequence.

Abstract: The present invention relates to a system for commissioning an electronic shelf label (ESL) position using a commissioning device, a commissioning device for use in commissioning an ESL, a method for commissioning an ESL position using a commissioning device and a system backend position, a method for commissioning an ESL position using a commissioning device and a corresponding computer program product, wherein the commissioning device is arranged to acquire a first set of images comprising an ESL and extract an ESL identifier from the first set of images and a relative position of the ESL relative to the commissioning device, to acquire a second set of images comprising a luminaire emitting coded light, extract a relative position of the luminaire relative to the commissioning device from the second set of images, and to transmit the ESL identifier and the position information to the system back-end, the position information based on: the relative position of the ESL relative to the commissioning device and

Abstract: The invention relates to a system (1) comprising a controlling device (4) like a sensor for controlling a controlled device (5) like a luminaire, a trigger unit (7) for generating a trigger signal, and an assigning unit (6) for assigning the controlling device and the controlled device to each other, if the trigger signal has been generated, wherein the controlling device controls the controlled device, if they have been assigned to each other. This allows an installer to generate assignments between the controlling device and the controlled device very easily. The installer just needs to connect the controlling and controlled devices, which should be assigned to each other, to the system and actuate the trigger unit. For instance, it can relatively easily be defined which luminaires should react on signals from which sensors.

Abstract: The invention relates a system for controlling distribution of power to load elements via network connections (e.g. LAN). Low cost luminaires or other load elements can be powered via LAN connections (e.g. by power over Ethernet (PoE)) without featuring an Internet Protocol (IP) node. This is attractive because with such a system the installation cost down benefits of PoE can be applied also to installations that do not require advanced controls. This means that to switch them on or off, the power supply on the LAN port of the switch must be enabled or disabled. When load elements and load controllers (e.g. lighting controllers or light switches) are connected to the same switch, they are automatically paired to each other. This can be achieved through use of a network management protocol capability that some network switches have. This allows for easy installation and automatic intuitive commissioning.

Abstract: The present invention relates to a controller (30) for controlling the light-output of two light-emitting devices (10, 20). The two light-emitting devices are adapted to provide a McCandless effect on an illuminated object (40). The controller (30) comprises a first user interface for a user to set a first color (11) to be output by a first light-emitting device (10) and second user interface for a user to set a desired mixed color (81) of a common area (80) being illuminated by both light-emitting devices (10, 20). The controller (30) further comprises a processing circuitry for determining first lighting parameters resulting in said first color (11) when provided to the first light-emitting device (10), and for determining second lighting parameters resulting in a second color (21) when provided to a second light-emitting device (20). A mix of the first color (11) and the second color (21) provides the mixed color (81).

Abstract: The invention relates a system for controlling distribution of power to load elements via network connections (e.g. LAN). Low cost luminaires or other load elements can be powered via LAN connections (e.g. by power over Ethernet (PoE)) without featuring an Internet Protocol (IP) node. This is attractive because with such a system the installation cost down benefits of PoE can be applied also to installations that do not require advanced controls. This means that to switch them on or off, the power supply on the LAN port of the switch must be enabled or disabled. When load elements and load controllers (e.g. lighting controllers or light switches) are connected to the same switch, they are automatically paired to each other. This can be achieved through use of a network management protocol capability that some network switches have. This allows for easy installation and automatic intuitive commissioning.

Abstract: The invention relates to a system (1) comprising a controlling device (4) like a sensor for controlling a controlled device (5) like a luminaire, a trigger unit (7) for generating a trigger signal, and an assigning unit (6) for assigning the controlling device and the controlled device to each other, if the trigger signal has been generated, wherein the controlling device controls the controlled device, if they have been assigned to each other. This allows an installer to generate assignments between the controlling device and the controlled device very easily. The installer just needs to connect the controlling and controlled devices, which should be assigned to each other, to the system and actuate the trigger unit. For instance, it can relatively easily be defined which luminaires should react on signals from which sensors.

Abstract: Light-emitting devices (100) and methods for operating light-emitting devices are disclosed. Each of the light-emitting devices (100) comprises a plurality of light sources (112A-112F) for illuminating a target (120), wherein each of the light sources is configured to emit light within a predetermined color range. Each of the light-emitting devices comprises means (140) for automatically adjusting the spectral power distribution of light-emitted by the light-emitting device on basis of the color of the target or a region of the target illuminated by the light-emitting device, such that light emitted by the light-emitting device is made increasingly compliant or even compliant with a criteria of a predetermined color characteristics.

Abstract: The disclosed embodiments relate to a luminaire (100) comprising an array of LEDs (120). The array of LEDs (120) comprises LEDs chosen from the group of blue LED, green LED, red LED, yellow LED, amber LED, cyan LED, and white LED. The luminaire (100) further comprises a reflecting tube (140) and said array of LEDs (100) is arranged in an entrance aperture (142) of said reflecting tube (140). At least one light source (160) is arranged circumferentially around the reflecting tube (140). The at least one light source (160) comprises at least one LED chosen from the group of deep blue LEDs, royal blue LEDs, deep red LEDs and UV LEDs. An optical component (170), is arranged to transmit light emitted from the at least one light source (160) into light emitted from the array of LEDs (120).

Abstract: A lighting device comprising a plurality of light emitting elements (1), and a beam shaping optics (7) having an entrance aperture (6). Each light emitting element is optically connected to a set of optical fibers (5) each having a first end optically connected to the light emitting element and a second end optically connected to the entrance aperture (6), so as to guide collimated light from the light emitting element to the beam shaping optics (7). The light emitting elements are distributed over an area larger than the entrance aperture (6).

Abstract: The disclosed embodiments relate to a light structure (100, 200, 300, 400) comprising a heat sink (110, 210, 310, 410), a plurality of ceramic tiles (120, 220, 320, 420), at least one LED (130, 230, 330, 430) arranged on each ceramic tile (120, 220, 320, 420), a plurality of wires connecting the LEDs (130, 230, 330, 430), the plurality of ceramic tiles (120, 220, 320, 420) being in direct contact with the heat sink (110, 210, 310, 410).

Abstract: A system comprises a light source and an electrode device (20, 30, 60). The light source comprises a base (40) with a base surface (42) on which at least two contact elements are provided. The electrode device has at least two electrodes (23, 24, 34, 35), preferably of ferromagnetic or electromagnetic material and having a different polarity during operation. Adjacent electrodes are arranged at a predetermined electrode distance. Both electrodes are provided in one layer and are arranged in an interdigitated configuration. The light source has at least two, but preferably four contact elements (43, 53, 63) arranged at a mutual spacing which is essentially compatible with said electrode distance.