Systems and techniques are provided for sensor device. A sensor device may include a housing, a lens inserted into a first opening of the housing, a metal mask covering a portion of the interior of the lens, a passive infrared (PIR) sensor underneath the lens and the metal mask, and a light pipe around the PIR sensor, the lens, and the metal mask. Part of the light pipe may be positioned above an activation mechanism for a button. An airflow gasket may be around the PIR sensor. A filter circuit board may be under the PIR sensor and connected to leads of the PIR sensor. A control circuit board may include the activation mechanism for the button. A backplate may include a slot for attachment to a snap of a magazine in the housing of the sensor device.

Methods and apparatus for a security light having a remote photovoltaic module is set forth. The security light includes a primary rechargeable battery connected to the remote photovoltaic module while also having a backup battery system to be utilized when the rechargeable batteries condition require recharge. The security lighting unit functions as a security light to provide variable wide area illumination based upon environmental and battery conditions and also which power supply is optionally connected to the load, the load being the illumination sources and the various supportive electronics. The system further includes a controller which can not only operationally selects either the rechargeable batteries or backup batteries but also can monitor battery condition to preserve battery life. In operation, the security light may include a variable battery power supply for ease of installation.

Systems and methods for controlling electrical loads in one or more areas. The system includes a room controller having a microprocessor for accessing data and providing commands, memory for storing information operably connected to the microprocessor, a relay for powering a load based on commands from the microprocessor, and a port for connecting a peripheral device. The system also includes a peripheral device connected to the port and configured to send data including a device type and a device instance byte to the controller indicating the type of peripheral device. The device instance byte includes a port number identifying the port and a slot number identifying a time slot within a time domain multiplexing cycle. The system also includes a load connected to the relay.

Systems and methods for controlling electrical loads in one or more areas. The system includes a room controller having a microprocessor for accessing data and providing commands, memory for storing information operably connected to the microprocessor, a relay for powering a load based on commands from the microprocessor, and a port for connecting a peripheral device. The system also includes a peripheral device connected to the port and configured to send data including a device type and a device instance byte to the controller indicating the type of peripheral device. The device instance byte includes a port number identifying the port and a slot number identifying a time slot within a time domain multiplexing cycle. The system also includes a load connected to the relay.

The system, method and device for enabling remote-control of consumer electronic devices is disclosed. The system may comprise, a first communication device, a second communication device wherein the second communication device is communicatively coupled with the first communication device. The second communication device is capable of receiving one or more input control signals from the first communication device. The system further comprises, a docking station electronically coupled with the second communication device. The processor may perform demodulating and modulating of the one or more input control signals received by the second communication device from the first communication device. The processor may retrieve one or more infrared codes from a preconfigured database based upon the one or more modulated control signals and transmitting the one or more infrared codes to one or more consumer electronics device in order to remotely control the one or more consumer electronics.

A night-light control method in an electronic device comprises controlling a photosensitive sensor to detect a light intensity value and controlling an acceleration sensor to detect an acceleration value of the electronic device and thus movement. Acquiring the acceleration value from the acceleration sensor when the acquired light intensity value is in the first preset light intensity range; determining whether the acquired acceleration value is in a preset acceleration range and controlling an infrared sensor to detect whether a user of the electronic device is moving when the acquired acceleration value is in the preset acceleration range. A display unit of the electronic device is controlled to emit light or control a light emitting unit of the electronic device to emit light when the user of the electronic device is moving.

Implementations generally relate to systems, apparatuses, and methods for providing a modular sensor device in a residential environment. In some implementations, a modular sensor device includes a base that attaches to a wall in a living space. The modular sensor device also includes a power unit coupled to a first side of the base, where the power unit receives power from a power source, and where the power unit includes one or more devices that control conditions in an environment of the living space. The modular sensor device also includes a control module removably coupled to a second side of the base, where the module receives power from the power unit, and where the control module performs one or more predetermined control functions.

A device may include a first infrared sensor, a second infrared sensor, a temperature detecting component, and an occupancy detecting component. The first infrared sensor may connect to the temperature detecting component through a first temperature signal path and the occupancy detecting component through a first occupancy signal path. The second infrared sensor may connect to the temperature detecting component through a second temperature signal path and the occupancy detecting component through a second occupancy signal path. The temperature detecting component may determine a temperature measurement by calculating an average of a value received from the first temperature signal path and a value received from the second temperature signal path. The occupancy detecting component may determine an occupancy measurement by calculating a difference of the value received from the first occupancy signal path and the value received from the second occupancy signal path.

Method for the operation and the expansion of a network of lights, each light in the network including a control module which is assigned to a group, each control module being in communication with a group controller as well as control modules in the same group. The network can be expanded by installing (19) new lights with their associated control modules, and each new control module scans (20) its environment and transmits environmental information to a central server where the environmental information is analysed and the new control modules are allocated (21) into groups. After allocation to a group in which control modules may be moved from one group to another or a new group is formed, the new control modules are available for normal operation. This process is repeated for each new light and associated control module.

The invention relates to a control system for a lighting system comprising at least one control adapter having a digital interface for connection to an assigned digital control bus, to which a plurality of light-technology operating components such as control gear, ballast devices, sensor units, and/or switch units are connectable as bus users by means of a respective digital interface, wherein the at least one control adapter furthermore has a controller and a wireless interface for data coupling of the control adapter to a wireless network terminal. The control facility according to the invention is distinguished in that for at least one lighting system template, the respective comprised light-technology operating components and at least some of configurations and/or parameterizations assigned to the operating components are stored in a memory, which can be read out by the wireless network terminal, wherein the bus users connected to the digital control bus are detected for the configuration and startup of the lighting system. The invention furthermore relates to a method for the configuration and startup of such a facility.