The light guide, especially for motor vehicle signal lamps, comprises a collimator with a collimating wall for binding and routing light rays, and a light guiding body that continues the collimating wall, is of a material with refractive index (n), and is integral, spatially shaped, planar, and fitted at its end with an output emitting surface providing a signal light function. The first height (d) of the body at its beginning where it adjoins the collimating wall, is bigger than its second height where it passes into the emitting surface. The body is adapted to emit light rays generally within angle (ω) of diffusion from the optical axis (x), and comprises a transitional surface that is, in its profile towards the emitting surface, inclined towards the longitudinal axis of the profile. The ratio of inclination height (a) and inclination length (b) of the transitional surface is defined as:

[00001]$\frac{a}{b}=\mathrm{tg}.Math..Math.\left(\frac{1}{2}.Math.\mathrm{arc}.Math..Math.\sin \left(\frac{\sin .Math..Math.\omega }{n}\right)\right)$

A modified sphere structure including: a sphere body with a groove formed on a surface of the sphere body along a distribution path; a light source module disposed in a containing space of the sphere body, wherein the groove is connected to the containing space to define a light releasing space and light emitted from the light source passes through the light releasing space; and a light guiding member filling to the light releasing space to allow the light emitted from the light source to be distributed on the light guiding member along the distribution path and transmitted to outside of the sphere body.

In a lightable fan structure for dissipating heat, a circuit board is arranged in a fan body, and the circuit board is sequentially provided with a first light-guiding frame and a second light-guiding frame, and the circuit board is provide with a plurality of side-light lighting elements. Every two side-light lighting elements is reversely arranged and spaced on a rim of the circuit board. A bottom of the first light-guiding frame is annually provided with a lighting reflection layer, and the side-light lighting elements are arranged below the lighting reflection layer. The lighting reflection layer reflects light sources of the side-light lighting elements to pass through an edge and a top of the first light-guiding frame and the second light-guiding frame, thereby uniformly scattering and forming a circular light source.

A monitoring apparatus includes a wearable electronic device having an audio port and a headset having at least one earbud, at least one physiological and/or environmental sensor, and circuitry that processes signals produced by the at least one physiological and/or environmental sensor and transmits the processed signals to the electronic device via the audio port. The headset may include a microphone in audio communication with the electronic device via the audio port, and the circuitry modulates audio signals produced by the microphone and signals produced by the at least one physiological and/or environmental sensor for transmission to the electronic device via the audio port. The circuitry may power the at least one physiological and/or environmental sensor via power supplied by the electronic device through the audio port and may include a processor that coordinates collection, modulation, and/or transmission of signals produced by the at least one physiological and/or environmental sensor.

Methods and devices for minimizing and maximizing displayed output associated with applications are provided. More particularly, an application presented across two or more screens of a device in a landscape mode can be minimized to present portion of the application in one of the screens. With respect to a maximization operation received with respect to a page of an application results in the expansion of the displayed portion of the application to multiple screens of the device. Input to effect minimization and maximization operations can be entered in one or more gesture capture regions associated with the screens.

The invention is an illumination system for a logo (20) on the front of an electronic device (1) such as a set top box. The logo (20) is part of a light pipe (23) and the logo (20) is illuminated by projecting light on the front surface (24) of the light pipe (23). The front surface (24) is textured or tinted to evenly distribute the light to a viewer. The light source (11) for illuminating the logo (20) is positioned at an entrance end of the light pipe (23) as shown in the figure. The shape of the light pipe (23) is substantially uniform throughout the length of the light pipe (23) and the shape is substantially the shape of the logo (20). The light pipe (23) can have a cut away region near the front surface to create localized lighting contrasts.

The present disclosure describes an annular light-guide integrated into a system, including a mesh network device. The system includes a lighting manager application that, when executed by a processor, causes the system to determine an operational status and select, based on the determined operational status, a color. The lighting manager application then causes the system to activate one or more light-emitting components to radiate light corresponding to the selected color and transmit, through an annular light-guide, the radiated light to provide an exterior glow under a bottom housing of the system.

The present disclosure relates to aerosol delivery devices comprising a power unit and a cartridge that is configured for engagement with the power unit. In particular, the cartridge can be configured for rotation about a longitudinal axis thereof so as to be insertable into a chamber of the power unit in a plurality of different orientations. Further, the aerosol delivery device can include processing circuitry that can be configured for detection of the cartridge orientation and execution of a control function assigned to the respective orientation.

A vehicle lighting system includes a light source, a first light guide, and a second light guide. The light source is arranged to emit light into the first light guide, which emits incident light from the light source into the second light guide. The second light guide is arranged to emit incident light from the first light guide. The second light guide has a light input surface arranged to receive the incident light from the first light guide, and a light output surface arranged to emit the light received through the second light input surface. The light output surface comprises a first light emitting surface section in a first plane and a second light emitting surface section in a second plane, wherein the first plane and the second plane are arranged at a first angle in relation to each other.

A waveguide display includes a source assembly, an output waveguide, and a controller. The source assembly includes a light source and an optics system. The light source includes source elements arranged in a 1D or 2D array that emit image light. The optics system includes a scanning mirror assembly that scans the image light to particular locations based on scanning instructions. The output waveguide receives the scanned image light from the scanning mirror assembly and outputs an expanded image light. In some embodiments, the waveguide display includes a source waveguide and the 1D array of source elements. The source waveguide receives a conditioned image light from the source assembly. The controller generates the scanning instructions and provides the scanning instructions to the scanning mirror assembly. In some embodiments, the controller provides the scanning instructions to an actuator assembly of the source waveguide.