The embodiments disclosed relate to wild game traps that can be used to capture wild animals such as, for example, wild hogs, and more specifically to automated wild game traps.
Wild or feral pigs are a tremendous liability to the U.S. agriculture industry. In addition to spreading diseases, feral hogs have reached populations of over five million and cause over a billion dollars in damages each year. In Texas, where the feral pig problem is particularly concerning, there are over 2 million feral pigs causing over $500 million in damages per year. Other wild animals also cause similar problems in the U.S. As such, there is a need in the art for an efficient, cost-effective method and system for trapping or otherwise containing certain wild animals, including wild pigs.
Discussed herein are various embodiments relating to a novel wild game trapping system. Certain implementations include a catch trap, corral, at least two cameras, a feeder, and various associated components, configured to allow for a relatively low-maintenance, continuous trapping system. Other embodiments relate to alternative trapping systems, one-way gating systems, and rotational grazing systems.
In Example 1, an automatic animal trap comprises an enclosure, a first one-way gate disposed in an outer barrier of the enclosure, and a first camera disposed to capture a first view of an interior of the enclosure, wherein the first camera is operably coupled to the first one-way gate.
Example 2 relates to the automatic animal trap according to Example 1, wherein the enclosure comprises a trap cage, and a corral adjacent to the trap cage.
Example 3 relates to the automatic animal trap according to Example 2, further comprising a second one way gate disposed between the trap cage and the corral, wherein the first one-way gate comprises an external gate of the trap cage.
Example 4 relates to the automatic animal trap according to Example 3, wherein the first view of the interior of the enclosure is a view of an interior of the trap cage.
Example 5 relates to the automatic animal trap according to Example 4, further comprising a second camera disposed to capture a second view of an interior of the corral, wherein the second camera is operably coupled to the second one-way gate.
Example 6 relates to the automatic animal trap according to Example 1, further comprising a game feeder disposed adjacent to and external to the enclosure.
Example 7 relates to the automatic animal trap according to Example 1, wherein the first one-way gate is configured to close when an animal is detected in the first view by the first camera.
In Example 8, an automatic animal trap comprises an enclosure comprising a trap cage, and a corral adjacent to the trap cage. Further, the trap also comprises a first one-way gate disposed between the trap cage and an external area outside of the enclosure, a second one-way gate disposed between the trap cage and the corral, a first camera disposed to capture a view of an interior of the trap cage, wherein the first camera is operably coupled to the first one-way gate, and a second camera disposed to capture a view of an interior of the corral, wherein the second camera is operably coupled to the second one-way gate. The first one-way gate is configured to close when an animal is detected by the first camera in the view of the interior of the trap cage, and the second one-way gate is configured to open when the first one-way gate is closed.
Example 9 relates to the automatic animal trap according to Example 8, further comprising a game feeder disposed adjacent to and external to the enclosure.
Example 10 relates to the automatic animal trap according to Example 8, further comprising a power source operably coupled to the first and second one-way gates and the first and second cameras.
Example 11 relates to the automatic animal trap according to Example 8, further comprising a solar panel operably coupled to the power source.
Example 12 relates to the automatic animal trap according to Example 8, wherein the second one-way gate is configured to close when an animal is detected by the second camera in the view of the interior of the corral.
In Example 13, a one-way gating system comprises a first barrier separating a first area from a second area, a first one-way gate disposed in the barrier, the first one-way gate comprising an open configuration and a closed configuration, wherein the open configuration is a default position, and a first camera disposed to capture a view of the second area adjacent to the first one-way gate, wherein the first camera is operably coupled to the first one-way gate. The first one-way gate moves into the closed configuration when the first camera detects an animal in the second area adjacent to the first one-way gate.
Example 14 relates to the one-way gating system according to Example 13, wherein the system is incorporated into a fence in a park or wildlife area.
Example 15 relates to the one-way gating system according to Example 13, wherein the system is incorporated into a set of fences in a pasture having a plurality of lots.
In Example 16, a rotational grazing system comprises an enclosure disposed around a pasture, at least first and second lots disposed within the enclosure, wherein the first area is the first lot and the second area is the second lot, and the first one-way gate of claim 13, wherein the barrier is a first barrier disposed between the first and second lots.
Example 17 relates to the rotational grazing system according to Example 16, the system comprising a third lot disposed adjacent to the second lot, a second barrier disposed between the second and third lots, a second one-way gate disposed in the second barrier, the second one-way gate comprising an open configuration and a closed configuration, wherein the open configuration is a default position, and a second camera disposed to capture a view of the third lot adjacent to the second one-way gate, wherein the second camera is operably coupled to the second one-way gate. The second one-way gate moves into the closed configuration when the second camera detects an animal in the third lot adjacent to the second one-way gate.
Example 18 includes an automatic trap, including a pen. The automatic trap also includes at least one gate. The automatic trap also includes a camera. The automatic trap also includes where the gate is in operational communication with the camera. Other embodiments of this Example 18 include corresponding computer systems, apparatus, and computer programs recorded on one or more computer storage devices, each configured to perform the actions of the methods. In various implementations, a system including one or more computers and/or cameras can be configured to perform particular operations or actions by virtue of having software, firmware, hardware, or a combination of them installed on the system that in operation causes or cause the system to perform the actions. One or more computer programs can be configured to perform particular operations or actions by virtue of including instructions that, when executed by data processing apparatus, cause the apparatus to perform the actions.
While multiple embodiments are disclosed, still other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. As will be realized, the invention is capable of modifications in various obvious aspects, all without departing from the spirit and scope of the present invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive.
The embodiments disclosed herein relate to devices, systems and methods for trapping of wild game, including, for example, wild hogs. More specifically, various embodiments relate to a trapping system that provides for automatic baiting and automatic catching of wild animals, such that constant presence of a human being is not required in order to effectively catch multiple animals.
Additionally, other implementations include systems having a single panel capable of providing directional movement of animals. Such single panel embodiments can be used in place of traditional one-way gates. As a result, the single panel systems can be used in parks and wildlife areas to encourage directional movement of an animal, and further can be incorporated into sections of fenced pasture for rotational grazing such that animals may pass directionally from one pasture area to another.
One example of a trapping system 10 according to one embodiment is shown in
In certain embodiments, the system 10 also has a game feeder 30 that is positioned outside of the trapping pen 11 and is typically a slinging feeder 30 that spreads or otherwise distributes wild game food over an area surrounding the feeder 30, including into both the corral 14 and the trap cage 12. In one embodiment, the slinging feeder 30 is a corn-slinging feeder 30. Alternatively, the feeder 30 is any known feeder that can distribute food in a generally even distribution around the feeder 30.
The feeder 30, according to one embodiment, is positioned outside of and adjacent to the trapping pen 11 such that the feeder 30 is several feet from the pen 11. Alternatively, the feeder 30 can be positioned at a distance from the pen 11 ranging from about 0 to about 65 feet. In a further alternative, the feeder 30 can be positioned at any known distance from the pen 11 such that the feeder 30 can distribute food (such as, for example, corn) both into the corral 14 and the trap cage 12 from a position outside the pen 11.
In certain implementations, the system 10 also has a solar panel 32 positioned on or near the pen 11 that is connected to a rechargeable battery (not shown) such that the rechargeable battery (not shown) can be used as an energy source to power the actuators (not shown) that open and close the gates 16, 18. Alternatively, the power source can be a battery (not shown) that is recharged using some other method or apparatus. In a further alternative, the power source can be any known power source for powering known actuators such as those contemplated herein. It is understood that the actuators (not shown) can be any known motors or other types of actuators that can be used to open and close gates such as the gates 16, 18 disclosed or contemplated herein.
As best shown in
In accordance with one embodiment, the system 10 can be used to catch wild animals in a two-step process. First, the pen 11 is placed in “bait mode,” in which both the first and second gates 16, 18 are positioned in their open positions, as best shown in
One implementation of the camera 22 is configured to sense the size of the moving object. That is, the camera 22 is programmed or otherwise designed to distinguish between various sizes of the moving objects captured in its view. Further, this camera 22 can be pre-programmed to disregard any smaller moving objects, thereby only registering the movements of moving objects that are large enough to be the target wild animals, such as wild pigs.
In one embodiment, the camera 22 is preprogrammed to disregard any object that is smaller than desired targets. That is, various implementations of the system 10 comprise an image recognition system. In these implementations, the image recognition system evaluates captured images from the camera 22, such that candidate images from a motion detection algorithm can be classified for processing and execution of subsequent systems. For example, assuming that the trap has classified an image as a hog within a few minutes, the system is able to employ system logic to classify additional motion in the proximity of the identified hog as likely to be the same or another hog. Therefore, by using machine learning or other techniques, any new images passing the size threshold will be treated as hogs and the trap will respond accordingly.
Further, in certain of these implementations, the system 10 can be pre-programmed to execute one or more image classification filtering steps to prevent registering false positives and over-utilizing system resources. It is understood that an angled camera can distort the perceived size of objects and fast-moving animals or insects may register as a long, blurred object due to the long exposure time of each frame. Therefore, through the use of filtering implementations, the system 10 can implement image recognition processes via an algorithm prior to executing further image processing, such that the system 10 does not need to be very precise or robust to filter slow moving smaller moving objects—such as skunks, raccoons, birds and the like—and other noise. By filtering this “noise,” only sufficiently large and/or slow moving objects (target wild animals) can be sent to the image classifier part of the program which consumes more power and takes much more time to yield a classification. It is understood that these implementations ease system load and improve response times.
Alternatively, the camera 22 can be preprogrammed to disregard any desired size. While reference to programming the camera 22 is made here, it is understood that in certain implementations a supporting computer or other system in operational and electronic communication with the camera 22 may be programmed.
As mentioned above, when the corral camera 22 has sensed the predetermined number of movements of the predetermined size or other such predetermined parameters (such as speed, etc.) in the corral 14, the “catch mode” is triggered such that the system 10 actuates the second gate 18 to close, as shown in
Continuing with the “catch mode,” once the first gate 16 is closed and the animal is thereby trapped in the trap cage 12, the system 10 actuates the second gate 18 to open as best shown in
It is understood that the system 10 described above and the various other embodiments discussed elsewhere herein can have any known hardware components as necessary to allow for operation of the camera(s) as described, operable coupling of the camera(s) and the gate(s), and transmission of electrical and/or electronic communications therebetween to operate the components as described herein. One of ordinary skill in the art would understand that various known components could be used with the systems herein.
An alternative embodiment is shown in
According to a further alternative implementation in
Alternatively, the gate 62 of system 60 can have two cameras disposed on the gate 62, with one aimed toward side A and one aimed toward side B. In this embodiment, the default position of the gate 62 is closed, and when the side A camera senses a qualifying movement, the system 60 triggers the gate 62 to open, and when the side B camera senses a qualifying movement, the system 60 triggers the gate 62 to close.
In both of the above embodiments, the system 60 allows for passage of the animal from side A to side B, but prevents passage from side B to side A.
A further implementation is depicted in
Although the present invention has been described with reference to preferred embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.
This application claims the benefit under 35 U.S.C. § 119(e) to U.S. Provisional Application 62/587,146, filed Nov. 16, 2017 and entitled “Wild Game Trap and Associated Systems and Methods,” which is hereby incorporated herein by reference in its entirety.
Number | Date | Country | |
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62587146 | Nov 2017 | US |