Abstract: A lighting control system (1) comprising at least one lighting module (2) and a controller (3), the controller (3) being configured to cause the at least one lighting module to create a lighting scene for a lighting calendar event, the controller (3) further being configured to obtain first data by data mining social media content relating to the lighting calendar event, determine first lighting attributes from the first data, based on the first lighting attributes, control the at least one lighting module to generate at least one lighting scene and apply the at least one lighting scene for the lighting calendar event, obtain second data by data mining social media content relating to the applied at least one lighting scene, determine second lighting attributes from the second data, and based on the second lighting attributes control the at least one lighting module to generate at least one updated lighting scene and apply the at least one updated lighting scene for the lighting calendar event.

Abstract: The invention relates to an operational state determination apparatus (1) for determining whether a variation in a determined electrical parameter of an electrical network (2) is caused by a variation in an operational state of an electrical consumer of the electrical network. The electrical network comprises multiple electrical consumers (3, 4, 5) and a voltage source (6), wherein a variation classification unit (10) determines whether a variation in the determined electrical parameter of the electrical network is caused by a variation in the operational state of an electrical consumer of the network depending on a decision variable which depends on a variation in a measured voltage and a variation in a measured current of the electrical network. This determination can be performed, without directly using the variation in the determined electrical parameter of the electrical network and is therefore less influenced by random voltage fluctuations in the electrical network.

Abstract: The invention relates to detecting commissioning errors in a commissioned sensor system, wherein the sensor system comprises a plurality of sensor devices installed so as to cover an area. The sensor devices capture sensor data from the area whilst at least one entity moves through the area. A computer system of the sensor system processes the sensor data to generate a set of location data, which identifies locations traversed by the at least one moving entity. A discrepancy in the set of location data in detected, the discrepancy caused by at least one of the sensor devices having been incorrectly commissioned. Based on this detection, a modification can be made to the sensor system to compensate for or correct the incorrect commissioning of the at least one sensor device.

Abstract: The invention relates to adjusting at least one of installed building service sensors (10) of a building service system. A sensor coverage area of at least one sensor (10) is adjusted based on information on a position of the installed sensor (10) relative to at least one other sensor (10). For example, to determine the position of the sensor (10) relative to said at least one other sensor (10), each sensor (10) establishes a wireless communication between said sensor (10) and at least one other sensor (10) via a wireless communication means (34) of the sensor (10). For example, information on the positions of the installed sensors (10) is used to assign to each sensor (10) at least one of installed building service supply devices (12) of the system.

Abstract: The invention provides a control system (1000) comprising an electrical power control system (100) for monitoring electrical power consumption by a target system (200), wherein: —the target system (200) comprises (i) one or more dimmable electronic devices (210), wherein each dimmable electronic device (210) comprises a lighting device (220), wherein the one or more dimmable electronic devices (210) are operable at a plurality of different dimming conditions thereby defining a dimming range of the one or more dimmable electronic devices (210) with a predetermined relation between the plurality of different dimming conditions and an electrical power consumption by the one or more dimmable electronic devices (210), (ii) a target control system (230) configured to control the dimming conditions of the one or more dimmable electronic devices (210), and (iii) a source of electrical power (240) configured to provide electrical power to the one or more dimmable electronic devices (210); —the electrical power control

Abstract: Method of detecting a change in a lighting system comprising a plurality of devices each comprising a luminaire and/or a sensor, wherein each respective one of the devices has a respective location recorded in a commissioning database in association with data reported by the respective device; the method comprising: identifying a subset of said devices located within a predetermined spatial demarcation; automatically monitoring a respective value of a characteristic of each of the devices in said subset, thereby forming a data cluster comprising the values of said characteristic for the subset; automatically detecting that one of one of the devices in the subset has been moved by detecting a shift in one of the cluster values relative to the rest of the values in the data cluster; and in response to said detection, automatically outputting an indication that the commissioning database is likely to require updating to reflect said change.

Abstract: Some embodiments are directed to an occupancy sensor calibration device (100) arranged to repeatedly detect an occupancy in vision data and a concurrent occupancy detection in the occupancy data, determine a location of the detected occupancy in the vision data, and store the location as part of the occupancy sensing region.

Abstract: The invention provides a control system (1000) comprising an electrical power control system (100) for monitoring electrical power consumption by a target system (200), wherein: —the target system (200) comprises (i) one or more dimmable electronic devices (210), wherein each dimmable electronic device (210) comprises a lighting device (220), wherein the one or more dimmable electronic devices (210) are operable at a plurality of different dimming conditions thereby defining a dimming range of the one or pot more dimmable electronic devices (210) with a predetermined relation between the plurality of different dimming conditions and an electrical power consumption by the one or more dimmable electronic devices (210), (ii) a target control system (230) configured to control the dimming conditions of the one or more dimmable electronic devices (210), and (iii) a source of electrical power (240) configured to provide electrical power to the one or more dimmable electronic devices (210); —the electrical power con

Abstract: Some embodiments are directed to a verification device (200) arranged to verify based on incomplete information. The verification device is arranged to compute an energy consumption estimate for one or more luminaires from occupancy data, and compare it to received energy consumption data. A signal is transmitted if a lack of dependency is found in the lighting system with other factors than occupancy.

Abstract: A method comprising: obtaining a respective measurement of a beacon signal transmitted wirelessly between the mobile device and each of a plurality of the reference nodes; for each of a plurality of different reference locations within the environment, distinct from the reference nodes, obtaining a corresponding measurement of a test signal previously transmitted or modelled to have been transmitted wirelessly between the reference location and each of the plurality of reference nodes; for each of the reference locations, determining for each of said plurality of beacon nodes a difference between the respective measurement of the beacon signal and the measurement of the test signal; for each of the reference locations, determining a value of a measure of statistical spread in these differences; and estimating the location of the mobile device in dependence on a comparison of the values of the measure of statistical spread determined for the different reference locations.

Abstract: A wireless node for use in a network of wireless nodes, for performing a localization to determine a location of a mobile device based on respective beacon signals transmitted wirelessly between the mobile device and each of a plurality of the wireless nodes. The first wireless node is configured to: wirelessly transmit or receive the respective beacon signal for use in determining the location of the mobile device; and wirelessly transmit information vouching for one or more others of the wireless nodes as being trusted for use in the localization. This information is transmitted to a device performing the localization (e.g. the mobile device), for use in identifying one or more rogue versions of said wireless nodes.

Abstract: A method for identifying sensor units (3) at fault in a lighting system (1) performed using three or more sensor units (3), each respective one of the sensor units (3) comprising a respective sensor (116) configured to generate sensor data, the method comprising at an external processing apparatus (20) external to the sensor units (3): receiving from each of the sensor units (3) the sensor data; generating correlation parameters from the sensor data for selected pairs of neighbouring sensor units (3); and monitoring the correlation parameters to determine a sensor unit (3) at fault.

Abstract: A controller for controlling a battery-powered luminaire in a lighting network comprises: a network interface for communicating with the lighting network; and control logic for controlling at least one illumination source of the battery-powered luminaire; wherein the control logic is configured to: detect a failure of at least one mains-powered luminaire in the lighting network, determine that the mains-powered luminaire was emitting or had been instructed to emit a visual alert when the failure occurred, and control the at least one illumination source of the battery-powered luminaire to emit a version of that visual alert in response, the failure being detected based on a loss of communication, within the lighting network, with the mains-powered luminaire.

Abstract: In a people counting system, a plurality of vision sensors is arranged to provide sensor coverage of an area. Each is arranged to provide individual sensor coverage of a portion of the area within its field of view. Each of a plurality of local image processors is connected to a respective one of the vision sensors. Each of the local image processors is configured to apply a local person detection algorithm to at least one image captured by its respective vision sensor, thereby generating a local presence metric representative of a number of people detected in the at least one image. A central processor is configured to estimate the total number of people in the area covered by the vision sensors by applying an aggregation algorithm to the local presence metrics generated by the local image processors. As it is critical that user privacy be taken into account when utilising such people counting technology, an opt-out is enabled.

Abstract: Some embodiments are directed to a sensor control device (200) for a connected lighting system (100), said connected lighting system comprising multiple luminaires (122) arranged in a region, the sensor control device obtaining from received sensor data the occupant locations in sub-regions associated with the sensor data and/or multiple illuminance levels for multiple points in the sub-region, and defines a virtual sensor at a virtual sensor location. The occupancy state and/or illuminance level from the virtual sensor are used to control a luminaire of the multiple luminaires, the luminaire covering the virtual sensor location in the region.

Abstract: Some embodiments are directed to an occupancy sensor calibration device (100) arranged to repeatedly detect an occupancy in vision data and a concurrent occupancy detection in the occupancy data, determine a location of the detected occupancy in the vision data, and store the location as part of the occupancy sensing region.

Abstract: Some embodiments are directed to a sensor control device (200) for a connected lighting system (100), said connected lighting system comprising multiple luminaires (122) arranged in a region, the sensor control device obtaining from received sensor data the occupant locations in sub-regions associated with the sensor data and/or multiple illuminance levels for multiple points in the sub-region, and defines a virtual sensor at a virtual sensor location. The occupancy state and/or illuminance level from the virtual sensor are used to control a luminaire of the multiple luminaires, the luminaire covering the virtual sensor location in the region.

Abstract: A method comprising: obtaining a respective measurement of a beacon signal transmitted wirelessly between the mobile device and each of a plurality of the reference nodes; for each of a plurality of different reference locations within the environment, distinct from the reference nodes, obtaining a corresponding measurement of a test signal previously transmitted or modelled to have been transmitted wirelessly between the reference location and each of the plurality of reference nodes; for each of the reference locations, determining for each of said plurality of beacon nodes a difference between the respective measurement of the beacon signal and the measurement of the test signal; for each of the reference locations, determining a value of a measure of statistical spread in these differences; and estimating the location of the mobile device in dependence on a comparison of the values of the measure of statistical spread determined for the different reference locations.

Abstract: A verification device to detect malfunction in a connected lighting system, the connected lighting system comprising multiple luminaires and multiple occupancy sensors, the verification device comprising: —an input interface (301) arranged to connect to a database and obtain the sensor data obtained from the multiple occupancy sensors, —an aggregation unit (310) arranged to compute occupancy values which are indicative of occupancy over a specified time period at different hierarchical levels by applying a statistical measure, and —a processing unit (320) arranged to compare an occupancy value at a lower hierarchical level with an occupancy value at a higher hierarchical level, finding deviations that indicate a malfunction in the connected lighting system and producing a signal to communicate the malfunction.

Abstract: A method for identifying sensor units (3) at fault in a lighting system (1) performed using three or more sensor units (3), each respective one of the sensor units (3) comprising a respective sensor (116) configured to generate sensor data, the method comprising at an external processing apparatus (20) external to the sensor units (3): receiving from each of the sensor units (3) the sensor data; generating correlation parameters from the sensor data for selected pairs of neighbouring sensor units (3); and monitoring the correlation parameters to determine a sensor unit (3) at fault.