An electronic rodent trap includes an outer housing forms a trap body having two entrances defined on opposite sides thereof and creates a tunnel therebetween extending longitudinally between the entrances. A high voltage killing circuit is arranged within the trap body, and includes a plurality of killing plates and a triggering element separate from the plurality of killing plates and spaced inwardly from the entrance. A removable tunnel module is received within the outer housing and includes opposed entrances in alignment with the two entrances of the trap body. A removable electronics module is received within the outer housing, the electronics module contains the voltage circuit operatively connected to the plurality of killing plates.

An apparatus for attracting an animal to an area includes a housing, recordable memory media contained within the housing for storing a pre-recorded ultrasonic sound and a prerecorded audible sound. An audible sound emitter contained within the housing is also provided for emitting the prerecorded audible sound. Further, an ultrasonic sound emitter contained within the housing for emitting the prerecorded ultrasonic sound and second pre-recorded sounds that simulate first and second distinct sounds each made by a species of animal in the environment. A user interface, such as a hand held unit, is also provided to play back the audible and ultrasonic sounds simultaneously to produce a blended sound for attracting an animal. The apparatus may further include a first amplifier for amplifying the audible sound and a second amplifier for amplifying the ultrasonic sound. A low pass filter for filtering the audible sounds and a high pass filter for filtering the ultrasonic sounds from a mono file may also be included. The ultrasonic sound simulates ultrasonic vocal sounds of animals and the audible pre-recorded sound simulates audible vocal sounds of animals.

A blind assembly and setup configurations for the blind assembly are disclosed. The blind assembly contains two sheets wound together into a roll that are configured for separate outstretching at an angle relative to each other, for being maintained under tension in an outstretched form, and for retraction back into the roll. The end of each sheet contains a handle rod used for handling the sheets and for anchoring to the ground by means of attaching to stakes inserted into the ground using ropes. The roll end of the assembly structure is likewise attached to a stake in the course of setting up the blind assembly. A tie rod provides added support for the structure and is set up at a distance from the sheet rolls to prevent uncontrolled wraparounds of the sheets when the sheets are retracted.

A precast dam structure includes at least two precast segments coupled together via linkages and a flow path structure. The flow path structure defines a flow path having an intake port and a draft port and is associated with at least one of the at least two precast segments. The flow path structure is configured to provide a change in flow direction, either internally or externally, from the at least one of the at least two precast segments.

A game scoring camera system is disclosed for capturing images of game animals for the purpose of scoring the antlers using an accepted scoring method. One or more cameras are used in a multiscopic arrangement for capturing two-dimensional (2-D) images which are then converted to three-dimensional (3-D) data models, the resulting 3-D data models being used for determining measurements of various antler structures for calculating a score for the set of antlers captured in the images, the score being based on existing antler scoring systems. Some embodiments include one or more cameras, each being mounted on an unmanned aerial vehicle or drone, for capturing images during an aerial survey of game animals located within a particular area. Other embodiments include at least two cameras mounted in a stationary configuration for capturing images of game animals located within a particular area.

A wind detection device with a flexible enclosure, and opening, and a dispensing tube, filled with powder or liquid and designed to be attached to hunting equipment, headgear, or clothing, wherein pressing on the outside of the device causes a puff of powder or vapor to be dispensed into the air, allowing the user to determine wind direction.

A wind detection device with a flexible enclosure, and opening, and a dispensing tube, filled with powder or liquid and designed to be attached to hunting equipment, headgear, or clothing, wherein pressing on the outside of the device causes a puff of powder or vapor to be dispensed into the air, allowing the user to determine wind direction.

A trap for capturing a plurality of animals is provided. The trap can comprise an enclosure having an opening through which the at least one animal can pass to enter the enclosure. A gate, movable between an open position and a closed position, is positioned therein the at least one opening and can be selectively moved from the open position to the closed position when desired. Methods are also provided for capturing at least one animal by providing a trap with a gate, positioning the gate in an open position, monitoring the trap until at least one animal has entered the trap, and remotely triggering the gate to move from the open position to a closed position.

A trap for capturing a plurality of animals is provided. The trap can comprise an enclosure having an opening through which the at least one animal can pass to enter the enclosure. A gate, movable between an open position and a closed position, is positioned therein the at least one opening and can be selectively moved from the open position to the closed position when desired. Methods are also provided for capturing at least one animal by providing a trap with a gate, positioning the gate in an open position, monitoring the trap until at least one animal has entered the trap, and remotely triggering the gate to move from the open position to a closed position.

The disclosed implementations offer techniques for using different motion sensitivity settings for a trail camera to flexibly control how the trail camera captures images. For instance, a trail camera can be provided with multiple motion sensors configurable to different sensitivities, and can have different image capture settings depending on which motion sensor triggers. In other implementations, a single motion sensor can output a magnitude of a detection signal to similarly control image capture settings.