The smart lamp combines an energy-efficient LED light with a flexible mounting arm for smartphones or tablets, a Bluetooth speaker, and a smartphone or tablet charger. The smart lamp uses less desk space by bundling three electronic devices into one convenient lamp. The user positions their cellular devices onto the mount at the end of the adjustable arm, thus keeping the phone within reach. Moreover, this modern device enables users to set ideal lighting, based on preference, while the universal phone charging ports allow for simultaneously charging up to (2) two phones. The disclosed invention ensures a fully operational, multi-purpose lamp that bundles up various electronic devices into one highly-functional product as a means to use less desk space and ensure a more versatile home accessory.

A night light assembly for soothing a child to sleep includes a housing that is structured to resemble a star to visually comfort a child. A light emitter is positioned within the housing to emit light outwardly through the housing thereby facilitating a child to be soothed by the light at night. A cassette reader is integrated into the housing and a cassette is provided that stores data comprising a pre-recorded audio message. The cassette is insertable into the cassette reader thereby facilitating the cassette reader to read the data on the cassette. A speaker is integrated into the housing to audibly emit the pre-recorded message outwardly through the sound slots.

A method and a device for simulating shadows of a person moving in a building, comprising basic lighting and intended to reproduce a particularly realistic simulation of a moving person in a simple manner. This is achieved by superimposing the at least two sequentially switched lamps on the basic lighting.

An electronic apparatus according to an embodiment comprises: a housing including a first surface, a second surface facing the first surface, and a third surface which surrounds the inner space between the first surface and the second surface; a support member extending from the housing to the outside of the housing to support the housing; a speaker module arranged in the inner space; a first window arranged between the first surface and the speaker module and including a first light-transmitting surface facing the first surface and a first reflective surface facing away from the first light-transmitting surface; a second window arranged between the first window and the first surface and including a second light-transmitting surface facing the first surface and a second reflective surface facing away from the second light-transmitting surface; a light source module arranged between the first window and the speaker module; and a light diffusion member arranged between the light source module and the first reflective surface. The first window may include a light-transmitting region formed on at least a portion of the first reflective surface, through which light diffused by the light diffusion member transmits. Other embodiments are possible.

A luminaire structure, comprises a plurality of housing segments, each with at least one lighting zone, and configured to be assembled to form a support structure defining at least one panel supporting zone for supporting at least one acoustic panel removably attached thereto, wherein each of the lighting zones in the support structure is oriented to be adjacent the at least one acoustic panel, and operable to receive a lighting module to deliver light to an interior space.

The disclosure is directed to a mounting assembly for the recessed installation of a voice-enabled device. The mounting assembly comprises a trim comprising an outer flange, an inner flange, and a wall section. At least a portion of the outer flange of the trim is designed to be positioned below a ceiling, and the inner flange is designed for positioning the voice-enabled device thereon. The mounting assembly also comprises retaining structures that are attached to the wall section. The retaining structures are designed to hold the voice-enabled device on the inner flange.

An electronic module group can include an electronic module including a first housing defining a housing cavity; a power supply driving module positioned within the housing cavity; and a first concentric terminal connected in electrical communication with the power supply driving module by a first wire and a second wire; and a second concentric terminal rotatably connected in electrical communication with the first concentric terminal, the second concentric terminal configured to transmit power to the first concentric terminal.

A light speaker structure with a ring handle includes a speaker body, a speaker enclosure, a lighting mechanism and an auxiliary mechanism. The speaker body is mounted within the speaker enclosure, and the auxiliary mechanism is mounted on the speaker enclosure. The lighting mechanism includes a lampshade, a light strip, and LED beads. The light strip is mounted within the lampshade. The LED beads are fixedly connected to the light strip and electrically connected to the speaker body. The light strip is disposed in a laterally inverted C-shape around the speaker enclosure. The lampshade covers the light strip, so that the light strip is held between the lampshade and the speaker enclosure. The light strip and the lampshade are so shaped that they can be arranged around the speaker enclosure, thereby achieving a better lighting effect, providing a larger lighting area and producing a stereoscopic effect.

In some embodiments, a system comprises a host computing device and an audio device communicatively coupled to the host device and including at least one speaker and a plurality of light emitters. The host computing device can include a processor(s) and one or more machine-readable, non-transitory storage mediums with instructions configured to cause the processor(s) of the host computing device to perform operations including receiving user environment data by one or more sensors of the host computing device, receiving user selection data corresponding to a selected mode of operation of the audio device, determining a characterization profile of a surrounding environment of the user based on the user environment data, and sending the characterization profile to the audio device, the characterization profile configured to cause the audio device to control the plurality of light emitters based on the characterization profile and the selected mode of operation.

Electrical equipment includes a badge positioned over a hole of the housing, the badge comprising a first portion made at least of a first material that is transparent or translucent to visible light, and a second portion made at least of a second material that is opaque to visible light and transparent or translucent to infrared light, the first and second portions forming respectively a pattern and a background distinct from the pattern on an outside surface of the badge; an emitter arranged to emit visible light signals through the badge so as to illuminate the pattern without illuminating the background, and a receiver arranged to receive infrared communication signals emitted by a device that is distinct from the electrical equipment and passing through the badge.