Abstract: A method of tracking a location of a mobile device based on measurements of beacon signals transmitted between the mobile device and wireless reference nodes of a localization network.

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: 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: A calibration method comprising, for each of one or more light sensors: (a) under influence of one or more substantially non-zero illumination levels in the target environment, using the light sensor to measure the sensed light level corresponding to each of these one or more illumination levels; (b) receiving a template light level value corresponding to each of the one or more illumination levels, representing the light level at a target location in the target environment substantially removed in space from the location of the light sensor, each of the one or more template light level values being assumed for the environment rather than measured by a light meter; and (c) determining a relationship between the sensed light level and the light level experienced at the target location, based on an evaluation of the one or more sensed levels relative to the one or more template light level values.

Abstract: A localization system comprising a plurality of wireless reference nodes for detecting a location of a mobile device within an environment. Each node transmits localization beacon signals to be detected by the mobile device, and/or listens for localization beacon signals from the mobile device. Further, the system also provides or contributes to providing another utility into the environment (e.g. each node being a luminaire); and transmits and/or listens for control-related signals, other than localization beacon signals, related to controlling the provision of said utility, the control related signals being communicated on a same or overlapping frequency band as the localization beacon signals, one or more controllers are configured to control the transmission of and/or listening for the control-related signals to be time-multiplexed into different time slots than the transmission and/or listening for the localization beacon signals, between the time-slots of the control-related signals.

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: A computer-implemented method of optimizing non-uniform quantization boundaries for a quantization unit of a sensor is provided. The method comprises: obtaining a digital representation of a model (120) for predicting the target metric (124) from an unquantized sensor signal (122), the model being defined by at least the quantization boundaries, the model comprising: a first layer (130) of multiple continuous quantization functions (142, 144, 146; ƒ1, . . . , ƒQ), the quantization functions approximating block functions on quantization intervals defined by the quantization boundaries and receiving as input an unquantized sensor signal, and a second layer (132) comprising a function taking as input the output of the multiple continuous quantization functions and generating as output a prediction of the target metric, and training (530) the model using the training data by iteratively updating (126) the quantization boundaries.

Abstract: An energy measurement system for a lighting system is disclosed. The lighting system may comprise multiple lighting units arranged in multiple lighting zones, multiple sensors associated with the lighting zones, and an energy measurement device. The lighting system may be arranged to switch on a lighting zone depending on at least a sensor associated with the lighting zone. Power-on energy uses of the multiple lighting zones associated with the multiple sensors is obtained from sensor data from the multiple sensors, and energy use data from the energy measurement device, the energy use data indicating an aggregated energy use of the multiple lighting zones at different times, and a processor circuit.

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: Devices (10) comprise target detectors (11) for detecting presences of targets in first areas (1) and transmitters (12) for in response to detected presences transmitting multicast messages to controllers (20) and lamps (21-24) in wireless networked lighting systems. Such multicast messages increase reliabilities of the systems. The multicast messages switch on the lamps (21-24). Preferably, the multicast messages are only transmitted in case relatively small amounts of light are detected in second areas (2). In case relatively large amounts of light are detected in the second areas (2), unicast messages are in response to detected presences transmitted from the devices (10) to the controllers (20) that in response control the lamps (21-24) to be switched on. The first and second areas (1, 2) may be at least partly overlapping areas.

Abstract: A system comprising a localization database mapping reference nodes to zones; and a localization module configured to determine a representative measurement based on a combination of measurements for the nodes of each zone (e.g. RSSIs), and to compare the representative measurements with one another in order to directly determine which one or more of the zones the mobile device belongs to. The system further comprises a lighting database mapping between lamps and zones, configured to receive an index of each of the one or more determined zones from the localization module, and based thereon to directly relate the one or more determined zones to one or more of the lamps in the lighting database; and a lighting access service configured to grant the mobile device with access to control of those lamps on condition of being related to the one or more determined zones by the lighting database.

Abstract: The invention relates to controlling power consumption of a group of plurality of groups of power consuming devices by determining power consumption control value for controlling power consumption of devices of the group by use of at least one of the following: load shedding flexibility value of at least one group of plurality of groups, wherein the load shedding flexibility value of the corresponding group indicates maximum amount of power, by which power consumption of devices of the corresponding group can be reduced such that minimum power consumption permissible in the corresponding group is maintained; load restoration flexibility value of the at least one group of plurality of groups, wherein the load restoration flexibility value of the corresponding group indicates maximum amount of power, by which the power consumption of devices of the corresponding group can be increased such that maximum power consumption permissible in the corresponding group is maintained.

Abstract: The disclosure relates to an application server which provides a user of a mobile device with a location based service controlling functionality of an environment external to the mobile device, where the control of the functionality is conditional on an estimated location of the mobile device as estimated by a positioning algorithm. A feedback module is configured to infer a quality of the estimation from the behavior of the user, based on a manner in which the user interacts or attempts to interact with the functionality of the location based service. The feedback module then sends feedback of the inferred quality to the positioning algorithm.

Abstract: An energy measurement system for a lighting system is disclosed. The lighting system may comprise multiple lighting units arranged in multiple lighting zones, multiple sensors associated with the lighting zones, and an energy measurement device. The lighting system may be arranged to switch on a lighting zone depending on at least a sensor associated with the lighting zone. Power-on energy uses of the multiple lighting zones associated with the multiple sensors is obtained from sensor data from the multiple sensors, and energy use data from the energy measurement device, the energy use data indicating an aggregated energy use of the multiple lighting zones at different times, and a processor circuit.

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 relates to a method for managing light settings of a luminaire communicatively connected to a local coordinator. The method, performed by the luminaire, includes steps of providing to the local coordinator a control state of the luminaire (e.g. occupancy status), receiving from the local coordinator a power reduction factor for the luminaire, the factor being based on the control state of the luminaire and on control states provided to the local coordinator by one or more additional luminaires, determining new illuminance settings for the luminaire by applying the received factor to current illuminance settings, measuring luminance within a sensing region of a light sensor of the luminaire while one or more light sources of the luminaire emit light according to one or more operating parameters, and, based on the measured luminance, adjusting the operating parameters to achieve the new illuminance settings.

Abstract: The disclosure relates to a lighting system which can be controlled from a wireless device in dependence on complying with an access rule that the wireless device is determined to be within in a spatial region associated with the lighting system. The disclosure provides apparatus for securing against the lighting system being controlled from a device located outside the relevant region via a rogue relay device located in that region. The apparatus comprises a user location module configured to determine user location information indicative of whether a user is accompanying the wireless device in the region associated with the lighting system, and an access module which is configured with a further access rule: that it does not allow the control of the lighting system by the wireless device if the user location information is indicative of the wireless device being unaccompanied by a user.

Abstract: A method of tracking a location of a mobile device based on measurements of beacon signals transmitted between the mobile device and wireless reference nodes of a localization network.

Abstract: A wireless device comprising: a wireless interface for communicating with a network of reference nodes, and a location module configured to obtain a measurement of a respective signal communicated between the wireless interface and each of a plurality of said reference nodes. The location module is also supplied with a respective set of transformed coordinates for each of said plurality of reference nodes, transformed relative to their actual physical coordinates. Using said signal measurements and the transformed coordinates of said plurality of reference nodes, the wireless device then submits information indicative of a transformed location of the wireless device to an interpretation function. Based on the interpretation function, the wireless device is thereby able to access functionality relating to the physical location of the mobile terminal.

Abstract: A calibration method comprising, for each of one or more light sensors: (a) under influence of one or more substantially non-zero illumination levels in the target environment, using the light sensor to measure the sensed light level corresponding to each of these one or more illumination levels; (b) receiving a template light level value corresponding to each of the one or more illumination levels, representing the light level at a target location in the target environment substantially removed in space from the location of the light sensor, each of the one or more template light level values being assumed for the environment rather than measured by a light meter; and (c) determining a relationship between the sensed light level and the light level experienced at the target location, based on an evaluation of the one or more sensed levels relative to the one or more template light level values.