Abstract: There is provided a lighting system 100 comprising at least one lighting device 110, 120, 130 and a control unit 140 arranged for providing power P1,2,3 to each lighting device according to a control logic which is based on startup characteristics C1,2,3 of each lighting device. Thereby a lighting system is provided in which the individual characteristics of the lighting devices are taken into account when controlling the lighting devices. Since the control logic is based on startup characteristics for the lighting devices in the system, as an example, a reduction of the total standby power in the lighting system is achievable.

Abstract: A method of and system (110) for controlled activation of at least one function in a product or component at a remote location, which activation requires a correct activation data item to be available in the product or component. The method comprises receiving one or more noisy outputs of an unclonable element associated with the component from the remote location, and providing helper data to the remote location, which helper data transforms the one or more noisy outputs to a single value which corresponds to the correct activation data item.

Abstract: The invention relates to a method for controlling a lighting system, said lighting system comprising a plurality of luminaires (10, 12, 14, 16, 18), a plurality of sensors (24, 26), a central control unit (22) and a network (20) comprising networking devices for establishing a communication between the luminaires, the sensors and the central control unit. These luminaires, sensors and networking devices represent local units of the lighting system. In a standard operation mode, the luminaires (10, 12, 14, 16, 18) are controlled by the central control unit (22) on the basis of sensor data transmitted to the central control unit (22). In case of failure of operation of the central control unit (22), the lighting systems switches into a fallback mode, wherein each luminare (10, 12, 14, 16, 18) is controlled by a local unit associated to or represented by this luminaire (10, 12, 14, 16, 18).

Abstract: Coded light has been proposed to enable advanced control of light sources and transmit information using light sources. It is based on invisibly embedding of data and identifiers in their light output. Methods, devices and systems configured to efficient assignment of addresses in a coded lighting system, still allowing for unique identification, are proposed. More specifically, the assignment of addresses occurs in two phases, where in the initial phase wide area unique addresses are used, while in the second phase only local area unique addresses are used. Also, methods, devices and systems configured to efficiently distribute a set of addresses over a set of light sources in this second phase, to maximize the performance of the illumination contribution estimation, and positioning, are disclosed.

Abstract: A content distribution system (300) has access control according to a predefined data access format. The system has organizations (32) for providing content data and related meta data on record carriers (34), and a rendering device (39), and applications for manipulating the content data and related meta data. An access policy for the organization is set according to the predefined data access format, and has access parameters for controlling access to resources of the rendering device and to said content data and related meta data. An organization application (35) complying with the access policy of the organization for accessing said data is executed while accessing the resources of the rendering device according to the access policy of the organization. According to the invention a user access policy is maintained that restricts, for the organization application, access to the resources of the rendering device relative to the access policy of the organization.

Abstract: A remote controller is arranged for selecting a light source among a plurality of light sources. The remote controller has an omnidirectional transmitter and is arranged to instruct, by means of the omnidirectional transmitter, the light sources to transmit a directional signal comprising a code, which is unique for each light source. Further, the remote controller has a directional signal receiver, and is arranged to receive the directional signals from the light sources, and signal comparison circuitry connected with the directional signal receiver. The remote controller is arranged to select one of the light sources on basis of the received directional signals. Furthermore, the remote controller comprises a transmission indicator, which is arranged to generate an indication signal, indicative of a successful omnidirectional transmission, and it is arranged to initiate the selection of one of the light sources by means of the indication signal.

Abstract: A hybrid transmission/auto-conversion 3D format and scheme for transmission of 3D data towards various types of 3D displays is described. In the decoder (20) a stereo-to-depth convertor (24) generates a depth map. In the 3D video signal additional depth information called depth helper data (DH-bitstr) is sparsely transmitted both in time (partial depths in time) and/or spatially (partial depth within the frames). A depth switcher (25) selects the partial depths based on an explicit or implicit mechanism for indicating when these are to be used or when the depths must be automatically generated locally. Advantageously disturbing depth errors due to said stereo-to-depth convertor are reduced by the depth helper data.

Abstract: A method of selecting a light source among a plurality of light sources by means of a remote controller includes the remote controller: instructing, by omnidirectional transmission, the light sources to each transmit a directional signal comprising a code, which is unique for each light source; —receiving the directional signals from the light sources; and selecting one of the light sources on basis of the received directional signals. Furthermore, the method includes: generating, remotely of the light sources, codes to be transmitted by the light sources; and—the remote controller instructing each one of the light sources which one of the remotely determined codes to transmit.

Abstract: A 3D video system for transmission of 3D data towards various types of 3D displays is described. A 3D source device (40) provides a three dimensional [3D] video signal (41) to a 3D destination device (50). The 3D destination device receives the 3D video signal, and has a destination depth processor (52) for providing a destination depth map for enabling warping of views for the 3D display. The 3D source device generates depth signaling data, which represents depth processing conditions for adapting, to the 3D display, the destination depth map or the warping of views. The 3D video signal contains the depth signaling data. The destination depth processor adapts, to the 3D display, the destination depth map or the warping of views in dependence on the depth signaling data. The depth signaling data enables the rendering process to get better results out of the depth data for the actual 3D display.

Abstract: A system (300) has access control according to a predefined data access format. A studio (32) provides content data and related proprietary data on a record carrier (34) to be rendered by a rendering device (39). In the system, applications (35) are executed on the device for manipulating the content data and related proprietary data. An access policy is set for each studio that controls access to said content data and related proprietary data. A cross access policy is set for a virtual entity (42), and at least part of the proprietary data (43) is made available according to the cross access policy of the virtual entity. Also a cross studio application (41) is provided that complies with the access policy of the virtual entity for accessing said data.

Abstract: A remote controller is arranged for selecting a light source among a plurality of light sources. The remote controller has an omnidirectional transmitter and is arranged to instruct, by means of the omnidirectional transmitter, the light sources to transmit a directional signal comprising a code, which is unique for each light source. Further, the remote controller has a directional signal receiver, and is arranged to receive the directional signals from the light sources, and signal comparison circuitry connected with the directional signal receiver. The remote controller is arranged to select one of the light sources on basis of the received directional signals. Furthermore, the remote controller comprises a transmission indicator, which is arranged to generate an indication signal, indicative of a successful omnidirectional transmission, and it is arranged to initiate the selection of one of the light sources by means of the indication signal.

Abstract: This invention relates to an illumination system (100) comprising a plurality of luminaires (101a-d). The luminaires are each arranged to transmit in the light emitted an identification code ID. To ensure sufficient detection of the identification codes during selection with a selection device (120), the system further comprises a control unit (130) which is arranged for identification of any luminaire which has a nominal drive value equal to or below a minimum preset value, or equal to or above a maximum preset value. The control unit sets (or instructs a driver to set) the nominal drive value of such identified luminaire to a predetermined value to achieve a corresponding predetermined light output from the luminaire ensuring a sufficient signal for the transmission of the identification code ID.

Abstract: The invention relates to embedding data into a luminance output generated by an illumination system comprising a light source and a controller. The controller is configured to embed data by modulating a drive signal applied to the light source with an information signal comprising a shifted base code and a synchronization code. The synchronization code serves to provide synchronization for the receiver, while the shifted base code serves to carry the embedded data. A cyclic phase shift that is applied to a base code to generate the shifted base code corresponds to particular data, such as, for example, light source identification, that needs to be embedded into the luminance output of the illumination system. In this manner, data may be embedded into the luminance output generated by a light source without requiring synchronization of this light source with other light sources.

Abstract: An authentication system and method is presented for authenticating a first party to a second party, where an operation is performed on condition that the authentication succeeds. The authentication method verifies whether the first party is authenticated. If the first party is not authenticated, then it is determined if the first party qualifies for a sub-authorization. The sub-authorization depends on a value of a grace-counter associated with a number of times that first parties have been qualified for the sub-authorization. If the first party qualifies for the sub-authorization, the operation is performed and the grace counter is decremented. If the first party is authenticated, then the grace counter is set to a predetermined number.

Abstract: This invention relates to an authentication method for authenticating a first party to a second party, where an operation is performed on condition that the authentication succeeds. If the first party is not authenticated, then if the first party qualifies for a sub-authorization, the operation is still performed. Further, a device that comprises a first memory area holding a comparison measure, which is associated with time, and which is also used in said authentication procedure, a second memory area holding a limited list of other parties which have been involved in an authentication procedure with the device, and a third memory area, holding compliance certificates concerning parties of said list.

Abstract: There is provided a lighting system 100 comprising at least one lighting device 110, 120, 130 and a control unit 140 arranged for providing power P1,2,3 to each lighting device according to a control logic which is based on startup characteristics C1,2,3 of each lighting device. Thereby a lighting system is provided in which the individual characteristics of the lighting devices are taken into account when controlling the lighting devices. Since the control logic is based on startup characteristics for the lighting devices in the system, as an example, a reduction of the total standby power in the lighting system is achievable.

Abstract: The invention relates to a method for controlling a lighting system, said lighting system comprising a plurality of luminaires (10, 12, 14, 16, 18), a plurality of sensors (24, 26), a central control unit (22) and a network (20) comprising networking devices for establishing a communication between the luminaires, the sensors and the central control unit. These luminaires, sensors and networking devices represent local units of the lighting system. In a standard operation mode, the luminaires (10, 12, 14, 16, 18) are controlled by the central control unit (22) on the basis of sensor data transmitted to the central control unit (22). In case of failure of operation of the central control unit (22), the lighting systems switches into a fallback mode, wherein each luminare (10, 12, 14, 16, 18) is controlled by a local unit associated to or represented by this luminaire (10, 12, 14, 16, 18).

Abstract: A system (300) has access control according to a predefined data access format. A studio (32) provides content data and related proprietary data on a record carrier (34) to be rendered by a rendering device (39). In the system, applications (35) are executed on the device for manipulating the content data and related proprietary data. An access policy is set for each studio that controls access to said content data and related proprietary data. A cross access policy is set for a virtual entity (42), and at least part of the proprietary data (43) is made available according to the cross access policy of the virtual entity. Also a cross studio application (41) is provided that complies with the access policy of the virtual entity for accessing said data.

Abstract: Coded light has been proposed to enable advanced control of light sources and transmit information using light sources. Methods, devices and systems configured to operate a coded lighting control system, which is robust to interference from other sources of light are proposed. The method is based on sensing the light by a remote control device, and based on the sensing result adapting the identifiers used by the different light sources. By assigning a code identifier to the light source based on light received by the light receiver the code identifiers may be selected such that the influence of light interfering with the light source identifiers may be mitigated.

Abstract: The invention relates to a wireless remote controlled device selection system for selecting devices. Signal processing provides information for a remote control device. This information is indicative of the angle between the remote control device and the various devices from which a device should be selected. By analyzing the angular deviations, the desired device can be selected.