A solar powered lighting element with a simulated flame and an electric insect eliminator includes a lighting portion with a conducting grid and a light portion that simulates a flickering flame which are powered by a rechargeable battery that is recharged using a solar panel. One or more UV light elements are provided in addition to the flickering flame to attract insects.

The present utility model discloses a lighting mosquito killer lamp, which comprises a main body and a base that is joined with the main body. The main body comprises a housing, a lampshade arranged in the housing, and a high-voltage mesh wire arranged on the lampshade. The base is used for receiving power. The lighting mosquito killer lamp further comprises a lighting lamp and an ultraviolet lamp. The lighting lamp is different from the ultraviolet lamp, and the lighting lamp and the ultraviolet lamp are controlled independently of each other.

A solar powered lighting element with a simulated flame and an electric insect eliminator includes a lighting portion with a conducting grid and a light portion that simulates a flickering flame which are powered by a rechargeable battery that is recharged using a solar panel. One or more UV light elements are provided in addition to the flickering flame to attract insects.

Apparatuses, methods and systems provide technology to detect a pest-related fault or failure of an electronic control unit (ECU). The technology may also detect a presence of one or more pests via cameras, LiDAR sensors, RADAR sensors, motion sensors, one or more sound sensors, or one or more heat sensors. The technology may also provide countermeasures to disable, remove or eradicate the pests from the vehicle. The countermeasures may include one or more of a laser to target small pests, an electrical discharge insect control system to exterminate insects, and a vibration or sound emission system to target rodents.

A trap for immobilizing, killing, or containing arthropods comprises a housing having walls and at least one opening, where the walls define an interior space; and a light source comprising a directional light source mounted in the interior space. The light source is constructed to emit light at one or more wavelengths ranging from 350 to 500 nm. The light source is positioned so that a majority of the light emitted from the light source is directed at one or more surfaces in the interior space. The trap also comprises a suppression element mounted in the interior space and constructed to immobilize, kill, or contain arthropods.

One embodiment provides a system, including: a first end that screws into a light bulb socket; an internal light source; an electric insect control mechanism disposed around and proximate to the internal light source; and a visible light source disposed at an opposite end with respect to the first end. Other embodiments are described and claimed.

Systems and methods are provided for locating an insect in a space and for indicating to a user the location of the insect and/or for eliminating the insect. The system includes a camera to obtain an image of the space and a processor to detect an object by comparing at least two images of the space and determine that the object is an insect based on a characteristic of the object in an image of the space. In some embodiments an independently mobile device may be controlled to eliminate the insect at the location of the insect in the space.

An Internet-of-Things-based crop growth monitoring device includes a plurality of monitoring mechanisms. Each monitoring mechanism includes a base and a support rod fixed on the base. The support rod is provided with an electric element installation casing formed by snap-fitting an upper conical cover and a lower conical cover. A component for driving a swing cantilever to rotate is provided on the support rod at a position near a lowermost surface of the upper conical cover. A plurality of distance measuring laser sensors are provided on the swing cantilever. A component for driving an ultra-high-definition camera to rotate is provided on the support rod at the section of the upper conical cover. The images captured by the ultra-high-definition camera is used to obtain the leaf growth situation of the crops, and the data collected by the distance measuring laser sensors is used to determine the plant height of the crops.

The present invention relates to a mosquito killer, including a mounting base and a mosquito-killing bat unit, wherein the mosquito-killing bat unit, a handle portion and a movably arranged locking piece; and when a mosquito-killing portion of the mosquito-killing bat unit is inserted into an accommodating cavity of the mounting base, the mounting base drives a locking piece to move and unlock the handle portion, and the handle portion may be turned over to one side of the mounting base. By adoption of the above solution, when the mosquito-killing bat unit is arranged on the mounting base or is used singly, the handle portion of the mosquito-killing bat unit may be turned over for storage.

Aspects of the present invention determine a presence of insects at a location of a first device that comprises a computer processor, and in response to determining the presence of the insects at the location of the first device, apply a screen overlay that changes colors displayed by a display of the first device.