An intelligent Forcipomyia taiwana monitoring and management system comprises: a catching mechanism grabbing a to-be-identified target; a database storing a datum comprising pictures of a flying insect category; a model training module using the pictures to establish a training model; an image capture module shooting an image including the target; an identifying module selecting a first segmented region including the target by using YOLO detection framework technology, extracting a first identification feature from the target, and inputting the feature into the training model for deep learning to identify a flying insect category to which the target belongs and produce an identification result; a counting module recording a number of the target into the database; and a predictive tracking module obtaining a marked object based on the result marked with the target identified in the image, and using a Monte-Carlo category algorithm to track and predict the object.

The present invention relates to a portable insect and pest control and spray device. The device uses a non-chemical germicidal light for killing insects and pests. The device comprises a spray nozzle for scattering insects, while a vacuum attachment sucks and removes the dead insects and pests. A spray wand of the device can be positioned in hidden and hard-to-reach areas for scattering and killing insects and pests. Various types of germicidal lights such as ultraviolet light, blue light or white light are used. The device allows users to target a specific area with increased precision, including those areas that are often concealed or inaccessible.

The present invention relates to a portable insect and pest control and spray device. The device uses a non-chemical germicidal light for killing insects and pests. The device comprises a spray nozzle for scattering insects, while a vacuum attachment sucks and removes the dead insects and pests. A spray wand of the device can be positioned in hidden and hard-to-reach areas for scattering and killing insects and pests. Various types of germicidal lights such as ultraviolet light, blue light or white light are used. The device allows users to target a specific area with increased precision, including those areas that are often concealed or inaccessible.

A portable insect control trap has, in a single portable device, two modes of attracting insects, including a first mode adapted to attract flying insects (e.g. insect-attracting light) and a second mode adapted to attract crawling insects (e.g., bait). The same device has two modes of killing insects, including a first mode adapted to kill flying insects (e.g. an electrified grid) and a second mode adapted to kill crawling insects (e.g. an electric heating element). The first mode of attracting is associated with the first mode of killing, the second mode of attracting is associated with the second mode of killing.

A portable insect control trap has, in a single portable device, two modes of attracting insects, including a first mode adapted to attract flying insects (e.g. insect-attracting light) and a second mode adapted to attract crawling insects (e.g., bait). The same device has two modes of killing insects, including a first mode adapted to kill flying insects (e.g. an electrified grid) and a second mode adapted to kill crawling insects (e.g. an electric heating element). The first mode of attracting is associated with the first mode of killing, the second mode of attracting is associated with the second mode of killing.

A trap for use with a vacuum cleaner includes a trap body formed in a substantially cylindrical shape. The trap body includes a suction opening formed at one axial end to suck in a target to be trapped and an insertion opening formed at the other end to be inserted into a vacuum cleaner. An adhesive is provided on at least a portion of an inner surface of the trap body. The trap for use with a vacuum cleaner includes a net portion. The net portion blocks a plane orthogonal to an axial direction of the trap body. The net portion includes a net formed in at least a portion to transmit air sucked in through the suction opening. The trap body includes a protrusion formed on at least a portion in a circumferential direction of an outer surface thereof to protrude outward.

A trap for use with a vacuum cleaner includes a trap body formed in a substantially cylindrical shape. The trap body includes a suction opening formed at one axial end to suck in a target to be trapped and an insertion opening formed at the other end to be inserted into a vacuum cleaner. An adhesive is provided on at least a portion of an inner surface of the trap body. The trap for use with a vacuum cleaner includes a net portion. The net portion blocks a plane orthogonal to an axial direction of the trap body. The net portion includes a net formed in at least a portion to transmit air sucked in through the suction opening. The trap body includes a protrusion formed on at least a portion in a circumferential direction of an outer surface thereof to protrude outward.

A base assembly has an upward plate, a downward plate, a side wall, a front, a back, and laterally spaced sides. A drive assembly has drive wheels extending downwardly from the downward plate, a caster wheel, and proximity sensors. A vacuum assembly has a vacuum slit in the downward plate between the lateral sides and a vacuum-generating source capable of pulling a vacuum through the vacuum slit. A tower assembly is adapted to attract and kill insects while the base assembly and the tower assembly are being optionally driven by the drive assembly and the vacuum assembly is vacuuming up insects.

A drone with a high-voltage trap seeks, identifies, pursues and destroys flying insects within a patrolling area. During its passive attracting mode, the drone lands on a designated ground site and attracts insects with light, sound, and scents. Once insects are lured, the high voltage screens trap will immediately electrocute targeted insects. In its active offensive mode, the drone hovers closer to insect nests using its high-velocity propellers, producing strong downdraft jet streams to disturb the nest and force insects, such as mosquitoes and the like, to evacuate their nest. Once insects are airborne, the drone pursues fleeing insects from below or behind, making use of its propellers and vacuuming the fleeing insects. Slow flying insects that come in contact with the high-voltage electrified screens are immediately electrocuted. Insects that are vacuumed into the fast-spinning propellers blades are knocked down and killed. A rectified charging pad recharges the drone batteries.

A drone with a high-voltage trap seeks, identifies, pursues and destroys flying insects within a patrolling area. During its passive attracting mode, the drone lands on a designated ground site and attracts insects with light, sound, and scents. Once insects are lured, the high voltage screens trap will immediately electrocute targeted insects. In its active offensive mode, the drone hovers closer to insect nests using its high-velocity propellers, producing strong downdraft jet streams to disturb the nest and force insects, such as mosquitoes and the like, to evacuate their nest. Once insects are airborne, the drone pursues fleeing insects from below or behind, making use of its propellers and vacuuming the fleeing insects. Slow flying insects that come in contact with the high-voltage electrified screens are immediately electrocuted. Insects that are vacuumed into the fast-spinning propellers blades are knocked down and killed. A rectified charging pad recharges the drone batteries.