A method of controlling tint of a tintable window to account for occupant comfort in a room of a building. The tintable window is between the interior and exterior of the building. The method predicts a tint level for the tintable window at a future time based on lighting received through the tintable window into the room at the future time and space type in the room. The method also provides instructions over a network to transition tint of the tintable window to the tint level.

A motor control apparatus (2) according to the present disclosure is configured to control motors (#1-#3), automatically acquire identification information of a plurality of encoders (#1-#5), the encoders (#1-#5) being configured to be connected in series under a control of the motor control apparatus (2) and to detect position information of the motors (#1-#3) or position information of a mechanical apparatus configured to be driven by the motors (#1-#3), and store the identification information and the motor control unit in a non-volatile memory (11) in association with each other.

A motor control apparatus (2) according to the present disclosure is configured to control motors (#1-#3), automatically acquire identification information of a plurality of encoders (#1-#5), the encoders (#1-#5) being configured to be connected in series under a control of the motor control apparatus (2) and to detect position information of the motors (#1-#3) or position information of a mechanical apparatus configured to be driven by the motors (#1-#3), and store the identification information and the motor control unit in a non-volatile memory (11) in association with each other.

A battery pack includes a housing, rechargeable battery cells disposed in the housing, a terminal block for detachably coupling the battery pack to a power tool, a controller, and a wireless communication circuit electrically coupled to the controller and configured to wirelessly receive information from an external device. The controller is configured to control a performance attribute of the battery pack according to the received information.

A battery pack includes a housing, rechargeable battery cells disposed in the housing, a terminal block for detachably coupling the battery pack to a power tool, a controller, and a wireless communication circuit electrically coupled to the controller and configured to wirelessly receive information from an external device. The controller is configured to control a performance attribute of the battery pack according to the received information.

Systems and techniques are described for providing control of a monitoring system. In some implementations, a monitoring device is located in a building and is configured to monitor at least a portion of the building based on output from one or more sensors. A monitoring server is located remote from the building and is configured to communicate with the monitoring device. The monitoring server may be configured to translate one or more parameters received from a client device into an interpreted monitoring script and a trigger that causes performance of the interpreted monitoring script. The monitoring device may include an interpreter configured to determine that the trigger has been met and initiate performance of the interpreted monitoring script to evaluate a monitoring rule in accordance with one or more configurable parameters.

Systems and techniques are described for providing control of a monitoring system. In some implementations, a monitoring device is located in a building and is configured to monitor at least a portion of the building based on output from one or more sensors. A monitoring server is located remote from the building and is configured to communicate with the monitoring device. The monitoring server may be configured to translate one or more parameters received from a client device into an interpreted monitoring script and a trigger that causes performance of the interpreted monitoring script. The monitoring device may include an interpreter configured to determine that the trigger has been met and initiate performance of the interpreted monitoring script to evaluate a monitoring rule in accordance with one or more configurable parameters.

Methods are described for receiving from a device at a server device resource dispensing system usage information and settings and sending from the server device ecorank information, wherein the ecorank information is derived from a comparison of usage of resource dispensing systems controlled by the device in comparison to a comparison group, the comparison group comprising other resource dispensing systems controlled by other devices. The comparison group is determined based on profile information describing the dwelling, dwelling size, dwelling location, dwelling occupants, resource dispensing system technology, and related information. In some embodiments, the ecorank information may be one or more of a numerical score, percentage, graphic, icon, color, letter, and an audio item. In some embodiments, the energy consumed by the resource dispensing systems may be reported by an associated energy measurement device or estimated by heating and cooling usage hours.

Methods are described for receiving from a device at a server device resource dispensing system usage information and settings and sending from the server device ecorank information, wherein the ecorank information is derived from a comparison of usage of resource dispensing systems controlled by the device in comparison to a comparison group, the comparison group comprising other resource dispensing systems controlled by other devices. The comparison group is determined based on profile information describing the dwelling, dwelling size, dwelling location, dwelling occupants, resource dispensing system technology, and related information. In some embodiments, the ecorank information may be one or more of a numerical score, percentage, graphic, icon, color, letter, and an audio item. In some embodiments, the energy consumed by the resource dispensing systems may be reported by an associated energy measurement device or estimated by heating and cooling usage hours.

The invention relates to a device for securing a safety area around at least one automatically operating machine (3), comprising an illuminating marking (4; 5) of the safety area and/or a boundary of the safety area, a sensor-based monitoring device for detecting a breach of the safety area, and a control device (1) for controlling the machine (3), for defining the safety area, for controlling a shape, structure and/or a location of the illuminating marking, and for changing the operating state of the machine (3) or the light source (6, 7) in a manner which is dependent on a detection of a breach of the safety area by way of the monitoring device. The device is characterised in that a multiplicity of light sources (6, 7) which can be actuated in a spatially resolved manner and in each case comprise an inactive and at least one active operating mode are arranged on or in the surface (2) which delimits the safety area, wherein the operating mode of the light sources (6, 7) can be controlled by way of the control device (1), and the illuminating marking (4; 5) is configured as at least one of the light sources (6, 7) in an active operating mode.