Disclosed herein are systems, apparatuses, methods, and non-transitory computer readable media related to a display construct coupled to a structure (e.g., a vision window). The structure can be a supportive structure such as a fixture. The display construct is configured to facilitate media display and is at least partially transparent. The vision window may be a tintable window, e.g., a window in which its tint is electrically controllable (e.g., an electrochromic window). Various interactive capabilities with the display construct are disclosed (e.g., via a touch screen).

This disclosure provides connectors for smart windows. A smart window may incorporate an optically switchable pane. In one aspect, a window unit includes an insulated glass unit including an optically switchable pane. A wire assembly may be attached to the edge of the insulated glass unit and may include wires in electrical communication with electrodes of the optically switchable pane. A floating connector may be attached to a distal end of the wire assembly. The floating connector may include a flange and a nose, with two holes in the flange for affixing the floating connector to a first frame. The nose may include a terminal face that present two exposed contacts of opposite polarity. Pre-wired spacers improve fabrication efficiency and seal integrity of insulated glass units. Electrical connection systems include those embedded in the secondary seal of the insulated glass unit.

The LPSP invention comprises an array of solar panel slats called solar slats along with inter-digitized filler slats. The solar slates on the outside can be open to the outside air or behind a covering window. The solar slats, filler slats or both types of slats can rotate or be fixed in angle position with respect to the sun solar angle. In a window shade application, the filler slats can rotate to avoid blocking the sun's rays from impinging on the solar slats. Alternatively, the filler slats can be transparent, or be adapted with electrically activated films (electroactive) to change the degree of transparency. The solar slats comprise structural material adapted with or containing photovoltaic material, even semi-transparent solar photo electric glass, and further comprising accompanying electrodes and wiring to conduct the generated electricity to an electrical load. The LPSP can be used as elements in a LPSP systems that folds and allows walking support such as a deck. The LPSP flips sides exposed to the environment to offer a different functionality.

Disclosed herein are various clusters. A cluster comprises processing nodes that have supervisory roles and subordinate roles. A node in the cluster can have a supervisory or a subordinate role. The cluster can self-orchestrate its roles. The roles of the nodes can be assigned and/or reassigned (e.g., autonomously and/or automatically) by the cluster. Such system may achieve automatic commissioning of the cluster(s), e.g., in a facility.

A solar powered smart window includes a light diffuser configured to convert an incident direct solar radiation to a diffusive light toward interior direction, a light diffuser positioner, a driving mechanism, a solar panel, and a control unit. The control unit moved the light diffuser from a predetermined opened position to a closed position and to hold the light diffuser at the closed position with latch mechanism, when the output power of the solar panel exceeds a threshold for over a duration time. The controller releases the latch mechanism and to cause the light diffuser to return to the predetermined opened position when the output power lowers below threshold for over the duration time. A method includes storing a predetermined condition, monitoring the output power, comparing the output power with the predetermined conditions, making decision whether a positional transition is necessary, and causing the transitional transition or maintaining current position.

A component having a first, optically transparent pane and a second optically transparent pane, the first pane and the second pane being spaced apart from one another at least in some areas by means of a space. The component further comprises a separating device which divides the space into a first space area and a second space area; an introduction device for introducing fog, e.g., a colored gas, or a colored liquid that changes the passage of light at least through the first space area, at least in the first space area; and a means for removing the fog, the liquid or the gas at least from the first space area. In addition, the component further comprises an illuminating device for illuminating at least the interior of the first space area and/or the separating device is movable.

A fenestration system includes one or more of a light modulation controller or ventilation modulation controller. The light modulation controller is in communication with at least one light modulation element of a fenestration assembly having a frame and a panel. The light modulation controller includes a light prescription module configured to provide a specified light prescription for the building interior. A lighting difference module is configured to determine a prescription difference between the specified light prescription and ambient light. A dynamic light module of the light modulation controller operates the at least one light modulation element according to the prescription difference. The ventilation modulation controller is in communication with at least one operator configured to open and close the panel. A ventilation prescription module provides a specified ventilation prescription for the building interior, and a dynamic ventilation module implements panel closing and opening according to the specified ventilation prescription.

Layered assemblies are disclosed, that include a variable transmittance layer having opposing first and second sides; at least a first reflectance color-balancing layer positioned on the first side of the variable transmittance layer; and a transmittance color-balancing layer positioned on the first side or the second side of the variable transmittance layer. The variable transmittance layer may be variable between a dark state and a light state, and may have a dark state transmittance spectrum when in the dark state and a different light state transmittance spectrum when in the light state.

Disclosed herein as methods, apparatuses, non-transitory computer readable media, and systems relating to reduction and/or identification of one or more health risks in a facility. For example, by sensing a bodily characteristic of an individual in a facility, e.g., by sensing at least one environmental characteristic. For example, by sensing surface cleanliness. For example, by tracking personnel in the facility. For example, by suggesting routes in an enclosure based at least in part in personnel concentration in the facility. Disclosed herein as methods, apparatuses, non-transitory computer readable media, and systems relating to monitoring occupancy of a facility.

A privacy glass vision panel assembly includes a fixed first transparent panel having a plurality of spaced vertical non-transparent lines disposed between spaced vertical transparent lines. A movable second transparent panel is disposed next to the fixed first transparent panel and includes a plurality of spaced vertical non-transparent lines disposed between spaced vertical transparent lines. A bearing system supports the movable second transparent panel relative to the fixed first transparent panel. A first magnet unit is secured to the movable second vision panel and a second magnet unit is secured to and movable relative to the fixed first transparent panel in proximity to the first magnet unit to cause movement of the movable second transparent panel when the second magnet unit is moved relative to the fixed first transparent panel.