The present invention relates to a mosquito-killing illuminating lamp which comprises a casing and a control unit. The casing comprises an illuminating portion and a mosquito-killing portion. The illuminating portion is provided with illuminating components therein. An electrolysis carbon dioxide generating device and a fan are provided inside the mosquito-killing portion. The control unit controls operation of the illuminating components, the carbon dioxide generating device and the fan. The electrolysis carbon dioxide generating device comprises a box body and electrolysis components. The electrolysis components are provided inside the box body. An electrolyte solution is provided inside the box body. The box body is provided with a venting hole. The electrolysis components comprise a graphite electrode and a cathode plate. After conduction between the graphite electrode and the cathode plate, electrolysis is performed on the electrolyte solution to generate carbon dioxide.

Disclosed herein are robotic devices which traverse a pre-defined coverage area in order to capture and eradicate ticks in the area. A vacuum mechanism provides a suction force for pulling ticks into the device through a frontal opening, after which the ticks are captured in a receptacle and crushed by a rotating arm. In certain embodiments, the devices include heat strips near the frontal opening of the device that mimic the human body temperature. Additionally, the device can include carbon dioxide emitters that pass carbon dioxide to the receptacle or through the frontal opening to increase attraction of ticks.

Disclosed herein are robotic devices which traverse a pre-defined coverage area in order to capture and eradicate ticks in the area. A vacuum mechanism provides a suction force for pulling ticks into the device through a frontal opening, after which the ticks are captured in a receptacle and crushed by a rotating arm. In certain embodiments, the devices include heat strips near the frontal opening of the device that mimic the human body temperature. Additionally, the device can include carbon dioxide emitters that pass carbon dioxide to the receptacle or through the frontal opening to increase attraction of ticks.

An insect trap including a main body having a suction fan, a first light emitting module mount disposed above the main body, a first light emitting module disposed on the first light emitting module mount, a roof disposed on the first light emitting module mount, an insect collection unit disposed under the main body, and an air collection unit disposed in the insect collection unit, the air collection unit having a substantially tapered shape to have a gradually decreasing diameter with an increasing distance from the suction fan, in which the first light emitting module mount includes a first light emitting module cover facing at least a portion of the first light emitting module, and the roof includes a pressing portion protruding from the roof and contacting at least one of the first light emitting module and the first light emitting module cover.

An insect trap including a main body having a suction fan, a first light emitting module mount disposed above the main body, a first light emitting module disposed on the first light emitting module mount, a roof disposed on the first light emitting module mount, an insect collection unit disposed under the main body, and an air collection unit disposed in the insect collection unit, the air collection unit having a substantially tapered shape to have a gradually decreasing diameter with an increasing distance from the suction fan, in which the first light emitting module mount includes a first light emitting module cover facing at least a portion of the first light emitting module, and the roof includes a pressing portion protruding from the roof and contacting at least one of the first light emitting module and the first light emitting module cover.

A system for monitoring an area includes a processor and an electromagnetic radiation source in communication with the processor. The electromagnetic radiation source is configured to emit radiation to heat a metallic object that is in or carried by a target. The system also includes an array of temperature sensors in communication with the processor, where the array of temperature sensors is configured to detect a first temperature associated with the target and a second temperature associated with the target. The first temperature is detected prior to emission of the radiation and the second temperature is detected subsequent to emission of the radiation. The processor is also configured to determine whether to trigger an alert based at least in part on a difference between the first temperature and the second temperature.

A system for monitoring an area includes a processor and an electromagnetic radiation source in communication with the processor. The electromagnetic radiation source is configured to emit radiation to heat a metallic object that is in or carried by a target. The system also includes an array of temperature sensors in communication with the processor, where the array of temperature sensors is configured to detect a first temperature associated with the target and a second temperature associated with the target. The first temperature is detected prior to emission of the radiation and the second temperature is detected subsequent to emission of the radiation. The processor is also configured to determine whether to trigger an alert based at least in part on a difference between the first temperature and the second temperature.

An apparatus for trapping flying insect pests, including: a device for diffusing in the surrounding ambient air a gaseous lure the composition of which is suitable for attracting the insects; a device for sucking a flow of surrounding ambient air containing the insects attracted by the diffused gaseous lure, an insect trap arranged with the suction device so the insects sucked by said device are retained in said trap.

An apparatus for trapping flying insect pests, including: a device for diffusing in the surrounding ambient air a gaseous lure the composition of which is suitable for attracting the insects; a device for sucking a flow of surrounding ambient air containing the insects attracted by the diffused gaseous lure, an insect trap arranged with the suction device so the insects sucked by said device are retained in said trap.

A system for luring pests including a pest detector and a pest lure. The pest detector may be adapted to generate a type detection signal having a value indicative of a type of a pest in proximity to the pest detector. The pest lure may be in electrical communication with the pest detector and adapted to activate responsive to the type detection signal.