A sensor assembly for a castable lure is provided including a pressure sensor configured to measure a water pressure applied to the castable lure when deployed in an underwater environment, a processor, and a memory including computer program code. The computer program code configured to, when executed on the processor, cause the processor to receive pressure data from the pressure sensor, correlate the pressure data with time stamp data, cause the pressure data and correlated time stamp data to be stored in the memory, determine a data connection status between a transceiver and a marine electronic device, and in response to determining that a data connection exists, cause the pressure data and the correlated time stamp data to be transmitted to the marine electronic device. The pressure data and correlated pressure data correspond to a depth profile for a cast of the castable lure.

Embodiments of the present disclosure relate generally to fishing lures that employ channeled water technology. Embodiments further relate to fishing lures with a vented head configured to allow removal and replacement of a swim body. In specific embodiments, the vented head is provided as a two-piece configuration having locational alignment features and lateral securement features for maintaining the swim body in a secured position.

Embodiments of the present disclosure relate generally to fishing lures that employ channeled water technology. Embodiments further relate to fishing lures with a vented head configured to allow removal and replacement of a swim body. In specific embodiments, the vented head is provided as a two-piece configuration having locational alignment features and lateral securement features for maintaining the swim body in a secured position.

A lure 1A of the present invention has a body 2 and a lip part 3 projecting from the body 2, and the lip part 3 is provided with a hologram sheet 4. As the hologram sheet 4 of the lure 1A reflects light while the hue IA dives and swims in water, a target fish is easily attracted by the lure 1A.

The present invention is directed to a novel jig trailer fishing lure. This novel jig trailer lure has a rigid trailer member of differently weighted segments. During use regular oscillations of the trailer member keep the hook substantially upright whilst the entire jig trailer fishing lure simulates the look and movement and sound of a living prey fish, which a target predator fish is attracted to strike.

A stickbait fishing lure includes an outer covering and an internal structure molded within the outer covering. The internal structure is of a material that is configured to be punctured by a fishing hook. With this configuration, a fishing hook can be passed through the outer covering and puncture the material of the internal structure. The internal structure helps secure the fishing hook within the fishing lure by providing an internal reinforcement that inhibits the inserted hook from ripping away from the fishing lure or otherwise tearing the outer covering.

A stickbait fishing lure includes an outer covering and an internal structure molded within the outer covering. The internal structure is of a material that is configured to be punctured by a fishing hook. With this configuration, a fishing hook can be passed through the outer covering and puncture the material of the internal structure. The internal structure helps secure the fishing hook within the fishing lure by providing an internal reinforcement that inhibits the inserted hook from ripping away from the fishing lure or otherwise tearing the outer covering.

A glide and leap system for fishing lure includes a floating lure, a channel, a first weight, and a compression spring. The floating lure includes a head section and a tail section as the head section and the tail section are oppositely positioned of each other about a transverse plane of the floating lure. The channel is internally integrated into the head section and concentrically positioned along a sagittal plane of the floating lure. The channel is angularly oriented from a frontal plane of the floating lure to the transverse plane at an acute angle. The compression spring is positioned within the channel and positioned adjacent to the transverse plane. The first weight is adjacently positioned to the compression spring and the frontal plane as the first weight is slidably positioned within the channel.

An elastomeric fishing lure is provided having a flexible body portion having first and second ends, wherein the body portion defines an axis extending along the centerline of the body portion. The elastomeric fishing lure has at least one elongate slot in the body portion, the at least one elongate slot defining first and second ends and a slot length extending therebetween, the at least one elongate slot defining a pair of opposed sidewalls, wherein the distance between the opposed sidewalls defines a slot width, the at least one elongate slot extending through the body portion along at least a portion of the slot length.

An elastomeric fishing lure is provided having a flexible body portion having first and second ends, wherein the body portion defines an axis extending along the centerline of the body portion. The elastomeric fishing lure has at least one elongate slot in the body portion, the at least one elongate slot defining first and second ends and a slot length extending therebetween, the at least one elongate slot defining a pair of opposed sidewalls, wherein the distance between the opposed sidewalls defines a slot width, the at least one elongate slot extending through the body portion along at least a portion of the slot length.