Apparatus for an attachment device for a fishing line. The attachment device includes an in-line snap and a piece of tackle. The in-line snap includes a shank, a bend, and a point. The bend extends from the shank and folds over to join the point at a gap portion where the bend contacts the shank. The point extends away from the shank, forming a channel to receive a continuous section of fishing line. A shaft extends between the shank and the piece of tackle. In various embodiments, a second in-line snap cooperates with the first in-line snap to support a piece of tackle between the two in-line snaps.

Apparatus for an attachment device for a fishing line. The attachment device includes an in-line snap and a piece of tackle. The in-line snap includes a shank, a bend, and a point. The bend extends from the shank and folds over to join the point at a gap portion where the bend contacts the shank. The point extends away from the shank, forming a channel to receive a continuous section of fishing line. A shaft extends between the shank and the piece of tackle. In various embodiments, a second in-line snap cooperates with the first in-line snap to support a piece of tackle between the two in-line snaps.

A system comprises a rod holder, an input device, a driving device, and a controller. The rod holder holds one or more fishing rods. The driving device is coupled to drive the rod holder. The controller controls the driving device to move the rod holder based on stored rod movement information, based on a random generated movement sequence, or based on real time user input. In operation, the input device receives rod movement information that indicates at least one characteristic of rod movement, including position, timing, direction, angle, or speed. During recording of a jigging sequence, the controller stores rod movement information as stored rod movement information. During replaying of a jigging sequence, the controller controls the rod holder based on the stored rod movement information. The sequence is repeated until the user stops the replaying. The system is optionally controlled to perform a random jigging sequence.

The threading apparatus and methods of threading various types of fishing hooks and lures of this invention provide convenience and ease of use applicable to a wide range of hook sizes, shapes, and types. The threading apparatus is fabricated as a single molded part body made from an elastomeric material such as TPE with molded sectors including: slotted clip sector, chamfered frustoconical sector, non-chamfered frustoconical sector, slotted hook eyelet positioning curb, an at least one set of elongated hook shank holding ribs, and an exit sector. The invention provides simplified and enhanced threading operations which include hooks with particularly small eyelets or thin shank diameters, weighted hooks, and for fly hooks (lure hooks) or bodied hooks with particularly short exposed shank length. The facility for enhanced threading operations relies on the molded elastomeric material properties of the threading apparatus body including a durometer range comprehending flexibility without significant deformation memory.

The threading apparatus and methods of threading various types of fishing hooks and lures of this invention provide convenience and ease of use applicable to a wide range of hook sizes, shapes, and types. The threading apparatus is fabricated as a single molded part body made from an elastomeric material such as TPE with molded sectors including: slotted clip sector, chamfered frustoconical sector, non-chamfered frustoconical sector, slotted hook eyelet positioning curb, an at least one set of elongated hook shank holding ribs, and an exit sector. The invention provides simplified and enhanced threading operations which include hooks with particularly small eyelets or thin shank diameters, weighted hooks, and for fly hooks (lure hooks) or bodied hooks with particularly short exposed shank length. The facility for enhanced threading operations relies on the molded elastomeric material properties of the threading apparatus body including a durometer range comprehending flexibility without significant deformation memory.

Embodiments of the present invention seek to provide an accurate way to measure the length of a fish. Some embodiments of the present invention propose utilizing a known length of a marker within a camera view or picture to determine the length of the fish also shown in the same camera view or picture. This determination could be performed in real-time or later remotely. Further, the measurement of the length of the fish is reliable because it is not dependent on a zoom value or angle of the camera and there is no required measurement device. Further, the technique is easy to use and can be performed with a camera phone or tablet.

A fishing and hunting prediction system and method. The fishing and hunting prediction system may include a server, including a fishing and hunting prediction application, a controller, operating memory, and a communications interface, and wherein the server is accessible via a network. The fishing and hunting prediction system may further include, a data store in communication with the server; one or more data sources, wherein the one or more data sources are accessible to the fishing and hunting prediction application via the network; and wherein the controller is configured to execute stored program instructions, that may include providing access to a user; receiving user profile data; receiving waypoint data for one or more waypoints; receiving data from the one or more data sources; processing the received data; and generating fishing and hunting forecasting models based on the processed data.

The fishing rod line threading device includes an elongate shaft with a diameter suitable for passing through the rod guides on a fishing pole, and a gripping member on one end for gripping a fishing line to retain the line while passing through the rod guides. The gripping member includes a space within which the fishing line is retained while the device is passed through the rod guides. Slight pressure is required to release the retained line from the space. Alternate embodiments of the gripping member are disclosed. One or more feed ramps may guide the line into the space, or the line may be inserted into the space and retained by a positionable sleeve.

A cutting implement including a metal substrate and a coating is provided. The coating has zirconium PVD (ZrCRTiNO), which provides protection against corrosion of the metal substrate. In some instances, the zirconium PVD provides protection from corrosion for at least 200 hours. A layer of titanium nitride (TiN) can be added to the coating to increase the hardness of the metal substrate. In such an embodiment, the layer of titanium nitride (TiN) is applied before the zirconium PVD (ZrCRTiNO). Titanium nitride (TiN) coated steel is 3 to 5 times harder than uncoated steel. Thus, a combination of titanium nitride (TiN) and zirconium PVD (ZrCRTiNO) as a coating on a metal substrate can increase the life of the metal substrate by providing increased hardness and anti-corrosive properties.

A cutting implement including a metal substrate, carbide edge(s), and coating is provided. The coating is zirconium PVD (ZrCRTiNO), which provides protection against corrosion of the metal substrate. In some instances, the zirconium PVD provides protection from corrosion for at least 200 hours. A layer of carbide can be added to one or more cutting edges of the metal substrate prior to the deposition of the coating. The carbide increases the sharpness of the cutting edges and therefore increases the life or longevity of the cutting edges. Thus, a combination of zirconium PVD (ZrCRTiNO) as a coating and carbide edges on a metal substrate can increase the life of the metal substrate by providing increased hardness, sharpness, and anti-corrosive properties.