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.

An insect vacuum and trap attachment system can include a tubular member having an elongate channel that extends along an outer surface of the tubular member. The system can also include a suction member that slideably receives the tubular member. The suction member can have a narrowed open tip that receives insects and a stem that extends along at least an outer surface of the suction member. The stem can be slideably received by the elongate channel to enable the suction member to slide with respect to the tubular member. The system can include a catch that protrudes from the stem. The catch may be arranged and configured to receive a portion of an insect filter pod and thereby couple the insect filter pod between the tubular member and the suction member.

An insect vacuum and trap attachment system can include a tubular member having an elongate channel that extends along an outer surface of the tubular member. The system can also include a suction member that slideably receives the tubular member. The suction member can have a narrowed open tip that receives insects and a stem that extends along at least an outer surface of the suction member. The stem can be slideably received by the elongate channel to enable the suction member to slide with respect to the tubular member. The system can include a catch that protrudes from the stem. The catch may be arranged and configured to receive a portion of an insect filter pod and thereby couple the insect filter pod between the tubular member and the suction member.

A system for sex sorting of mosquitoes generally comprises: (i) a plate or similar receptacle that includes multiple wells, with each of the multiple wells configured to receive a mosquito; and (ii) an imaging subsystem, including a camera for capturing images of the mosquito in each of the multiple wells and a computer for analyzing the captured images to determine whether each mosquito is male or female. Mosquitoes have distinct anatomical areas for identification, which are captured in the images and are used to determine if a mosquito is male or female. Furthermore, in some implementations, the system includes a suction device or other means for exterminating the unwanted mosquitoes after the determination of whether each mosquito is male or female.

A system for sex sorting of mosquitoes generally comprises: (i) a plate or similar receptacle that includes multiple wells, with each of the multiple wells configured to receive a mosquito; and (ii) an imaging subsystem, including a camera for capturing images of the mosquito in each of the multiple wells and a computer for analyzing the captured images to determine whether each mosquito is male or female. Mosquitoes have distinct anatomical areas for identification, which are captured in the images and are used to determine if a mosquito is male or female. Furthermore, in some implementations, the system includes a suction device or other means for exterminating the unwanted mosquitoes after the determination of whether each mosquito is male or female.

It is important to trap and identify mosquitos to ensure the safety of the population where mosquitos gather. The classification of a type of mosquito is typically accomplished by a unique wingbeat signature that is characteristic of different types of mosquitos. One of the goals of the trap is to quickly identify the mosquito and then quickly release the mosquito. This application will allow the user to obtain an approximate population so that the appropriate type and amount of insecticide can be applied to control the population to insure the health of the human and animal population while at the same time minimizing danger to the environment or surrounding ecosystem.

It is important to trap and identify mosquitos to ensure the safety of the population where mosquitos gather. The classification of a type of mosquito is typically accomplished by a unique wingbeat signature that is characteristic of different types of mosquitos. One of the goals of the trap is to quickly identify the mosquito and then quickly release the mosquito. This application will allow the user to obtain an approximate population so that the appropriate type and amount of insecticide can be applied to control the population to insure the health of the human and animal population while at the same time minimizing danger to the environment or surrounding ecosystem.

A method for sex sorting of mosquitoes generally comprises the steps of: providing a plate that includes multiple wells, with each of the multiple wells configured to receive a mosquito; filling each of the multiple wells with a predetermined volume of water; placing a mosquito in each of the multiple wells; capturing an image of each mosquito in each of the multiple wells; and analyzing each image to determine if each mosquito is male or female. Mosquitoes have distinct anatomical areas for identification, which are captured in the images and are used to determine if a mosquito is male or female. Furthermore, in some implementations, there is an additional step of exterminating each mosquito that is determined to be female.

A method for sex sorting of mosquitoes generally comprises the steps of: providing a plate that includes multiple wells, with each of the multiple wells configured to receive a mosquito; filling each of the multiple wells with a predetermined volume of water; placing a mosquito in each of the multiple wells; capturing an image of each mosquito in each of the multiple wells; and analyzing each image to determine if each mosquito is male or female. Mosquitoes have distinct anatomical areas for identification, which are captured in the images and are used to determine if a mosquito is male or female. Furthermore, in some implementations, there is an additional step of exterminating each mosquito that is determined to be female.

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.