Embodiments of unmanned, rotary wing drones are described herein that include an insect trap for luring and capturing mosquitoes or other insects. The drone can include a set of propulsion units, each having a motor and propeller, and that collectively provide sufficient lift when operating to allow the drone to fly. A flight controller can be used to send and receive information and control a flight of the drone according to a flight plan stored on the drone. The insect trap includes a funnel or other mechanism to allow only for one-way movement of an insect into a container. To lure the insect into the trap, ultraviolet light can be shone on high-surface titanium dioxide powder that is stored within a mesh bag. A battery or other power source can be used to power the various components, and solar panels can be used to charge the battery when the drone has landed.

Embodiments of unmanned, rotary wing drones are described herein that include an insect trap for luring and capturing mosquitoes or other insects. The drone can include a set of propulsion units, each having a motor and propeller, and that collectively provide sufficient lift when operating to allow the drone to fly. A flight controller can be used to send and receive information and control a flight of the drone according to a flight plan stored on the drone. The insect trap includes a funnel or other mechanism to allow only for one-way movement of an insect into a container. To lure the insect into the trap, ultraviolet light can be shone on high-surface titanium dioxide powder that is stored within a mesh bag. A battery or other power source can be used to power the various components, and solar panels can be used to charge the battery when the drone has landed.

A vacuum machine has a rectangular deck, having a centerline, a width and a length, an underside and an upper side, a front edge and a rear edge, and side edges. Sidewalls extend below the deck along the side edges. There is an opening through the deck, substantially centered between the front edge and the rear edge, and between the sidewalls, a powered air blower coupled through a plenum above the deck to the opening, such that operating the blower draws air through the opening from beneath the deck, a killing mechanism disposed at an outlet from the blower, adapted to kill insects entrained in air drawn through the plenum, and a horizontally-oriented passage coupled to the outlet from the blower, directing air having entrained insects dead or alive away from the machine. The machine travels in the direction of the centerline advancing the first front edge of the deck.

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.

A method of verifying product authenticity includes emitting, by an electromagnetic radiation source in communication with a processor, radiation to heat one or more pieces of ferromagnetic material in or on a product. The method also includes detecting, by a heat sensor in communication with the processor, heat emitted from the one or more pieces of ferromagnetic material that are in or on the product. The method further includes determining, by the processor, if the product is counterfeit based on the detected heat.

A method of verifying product authenticity includes emitting, by an electromagnetic radiation source in communication with a processor, radiation to heat one or more pieces of ferromagnetic material in or on a product. The method also includes detecting, by a heat sensor in communication with the processor, heat emitted from the one or more pieces of ferromagnetic material that are in or on the product. The method further includes determining, by the processor, if the product is counterfeit based on the detected heat.

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.

The present invention is to provide a system, a method, and a program for adjusting the balance of an insect killer hung from a robot that are capable to adjust the position of the insect killer. The system for adjusting the balance of an insect killer 1 hung from a robot 10 moving by a propeller 410 through a support arm 100 adjusts the balance of the insect killer 200 so that the angle between the support arm 100 and the direction of gravitational force from the robot 10 has a predetermined value or more; and adds a weight 300 to an end of the same support arm 100 as the support arm 100 in the negative direction to an angle of the predetermined value and calculates the weight 300 to adjust the balance of the insect killer 200.