An awning is disclosed. The awning comprises a case assembly comprising a housing, configured to be mounted to a dwelling, and a lead rail, a roller assembly mounted in the case assembly and including a roll tube rotatable relative to the case assembly, a lead rail assembly coupled to the lead rail, the lead rail assembly movable relative to the housing between an extended position and a retracted position, a canopy having a leading edge and a trailing edge, the leading edge being connected to the lead rail assembly and the trailing edge being connected to the roll tube, and a spring arm assembly connecting the housing of the case assembly to the lead rail, the spring arms including a first arm and a second arm pivotable relative to one another, the spring arm assembly allowing the lead rail assembly to move between the extended position and the retracted position.

Certain aspects pertain to a combination sensor comprising a set of physical sensors facing different directions proximate a structure, and configured to measure solar radiation in different directions. The combination sensor also comprises a virtual facade-aligned sensor configured to determine a combi-sensor value at a facade of the structure based on solar radiation readings from the set of physical sensors.

A fabric selection tool provides an automated procedure for recommending and/or selecting a fabric for a window treatment to be installed in a building. The recommendation may be made to optimize the performance of the window treatment in which the fabric may be installed. The recommended fabric may be selected based on performance metrics associated with each fabric in an environment. The fabrics may be ranked based upon the performance metrics of one or more of the fabrics. One or more of the fabrics, and/or their corresponding ranks, may be displayed to a user for selection. The recommended fabrics may be determined based on combinations of fabrics that provide performance metrics for various façades of the building. Using the ranking system provided by the fabric selection tool, the user may obtain a fabric sample and/or order one or more of the recommended fabrics.

Motorized window treatments may each adjust a position of a covering material to allow light into a space in a building. The control information for controlling the motorized window treatments may be stored and/or accessed to understand how the motorized window treatments are operating. The control information may indicate a control state and/or a position of the covering material when an identified daylight intensity is being received at the space. The control information may inform a user of the operation of the motorized window treatments and allow the user to adjust various control parameters by which the motorized window treatments may be controlled. Recommended adjustments may also be provided to the user based on a user-identified problem with the operation of the motorized window treatments. The recommended adjustments to the control parameters may be accepted by the user and may be stored for being accessed and/or edited.

An intelligent control system for an electric curtain is provided. The intelligent control system includes a control apparatus, a monitoring apparatus, a sensing apparatus, a curtain apparatus, a lighting apparatus, and an air conditioning apparatus. The control apparatus is correspondingly coupled to the monitoring apparatus, the sensing apparatus, the curtain apparatus, the lighting apparatus, and the air conditioning apparatus. The monitoring apparatus is able to capture interior images, the sensing apparatus is able to sense exterior illuminance, and the control apparatus is configured to determine an opening degree of the curtain apparatus, illumination brightness of the lighting apparatus, and an air conditioning setting of the air conditioning apparatus by comparing different interior illuminance values, which are obtained from the interior images captured by the monitoring apparatus at different levels of interior illuminance, with an exterior illuminance value sensed by the sensing apparatus.

Various embodiments described herein relate to a self-contained, self-regulating intelligent automated window treatment with increased energy efficiency. In at least one embodiment, the window treatment consists of: (1) a headrail; (2) a tube located within the headrail; (3) a motor located within the headrail, preferably within the tube; (4) window treatment fabric with one terminus of the fabric affixed to the tube within the headrail, and with the fabric extending from the tube and out from the headrail; (5) a smart bottom rail attached to the terminus of the shade fabric furthest from the tube with the bottom rail containing, at least one sensor, at least one control button, and a battery that provides power to the sensor(s) and control button(s), and wherein the smart bottom rail communicates with the motor in the headrail. Types of sensors used may include environmental sensors, motion sensors, and inertial sensors. In another embodiment of the invention, the battery in the bottom rail may be a rechargeable battery. In a further embodiment, the bottom rail may contain at least one solar panel, which may be used to provide charge to the rechargeable battery. In another embodiment of the invention, the headrail further consists of a solar panel and a rechargeable battery that may be charged by the solar panel. In a further embodiment solar power stored in the rechargeable battery of the bottom rail may be transferred to the rechargeable battery-powered motor of the headrail.

A motor driven system for raising and lowering a window covering executes motor ramp trajectory speed control. The motor ramp trajectory limits acceleration of an external motor from the idle (stationary) state to full operating speed, and limits deceleration of the motor from full operating speed back to the idle state. This function reduces stresses on a continuous cord loop drive mechanism. A control system manages solar heating effects in response to sunlight entrance conditions such as system sensor outputs, external weather forecasts, and other data sources. The system automatically opens or close the window covering to increase or decrease admitted sunlight under appropriate conditions. The input interface of the control system includes a visual display and input axis, which are aligned vertically if the window covering mechanism raises and lowers the window covering, and are aligned horizontally if the window covering mechanism laterally opens and closes the window covering.

The present invention relates to a self-contained, self-regulating intelligent automated window treatment with increased energy efficiency consisting of: (1) a headrail; (2) a tube located within the headrail; (3) a motor located within the headrail, preferably within the tube; (4) window treatment fabric with one terminus of the fabric affixed to the tube within the headrail, and with the fabric extending from the tube and out from the headrail; (5) a smart bottom rail attached to the terminus of the shade fabric furthest from the tube with the bottom rail containing, at least one sensor, at least one control button, and a battery that provides power to the sensor(s) and control button(s), and wherein the smart bottom rail communicates with the motor in the headrail. Types of sensors used may include environmental sensors, motion sensors, and inertial sensors. In another embodiment of the invention, the battery in the bottom rail may be a rechargeable battery. In a further embodiment, the bottom rail may contain at least one solar panel, which may be used to provide charge to the rechargeable battery. In another embodiment of the invention, the headrail further consists of a solar panel and a rechargeable battery that may be charged by the solar panel. In a further embodiment solar power stored in the rechargeable battery of the bottom rail may be transferred to the rechargeable battery-powered motor of the headrail.

A door operating system includes a door operator; a laser transmitter; and an accessory device operatively connected to a laser receiver, the accessory device is powered, at least in part by, energy received by a laser shining at the laser receiver. A method of providing power to accessory devices associated with a door opening system includes: configuring a laser receiver to receive power from a laser; configuring the laser receiver to provide power to an accessory device; configuring a laser transmitter to convert AC power to a laser; controlling the laser transmitter with a controller that also controls a door operator.

The method comprises determining that the clear day exists in response to the apparent diameter of the solar disc being similar to the expected diameter of the solar disc on the clear day and determining that an overcast condition exists in the camera image in response to the apparent diameter of the solar disc being distorted. The method may further include receiving a camera image of a sky section from a camera at a first location; segmenting the camera image into a first portion around a known position of a solar disc and a second portion of the remainder of the sky section containing an horizon; determining that the solar disc is obstructed by the horizon; and establishing that the first location is experiencing shadow conditions based on the determining.