A casting device may include a microcontroller, an inertial measurement unit in communication with the microcontroller, an actuator in communication with the microcontroller, and a power source for providing power to the casting device. The casting device may also include one or more indicators that provide user feedback regarding accurate use of the device.

A system for providing the location of a planer board is provided. In an embodiment, the system includes one or more computer devices and one or more computer processors. The system includes (A) a planer board application (planer board app) embodied in instructions stored by the one or more computer devices. When the planer board app is executed by the one or more computer processors, the planer board app is configured to: (i) receive inputs from a GPS locator module. The planer board app is further configured to receive user inputs for (ii) a lure line length for a planer board and (iii) a boat line length to the planer board. (B) The planer board app generates a planer board track based on the inputs from (i)-(iii). (C) The planer board app also includes a user interface, such that the planer board app is further configured to display the planer board track on the user interface.

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.

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.

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.

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.

A rotor brake mechanism includes a braking member, a moving member, an elastic member, and an adjustment member. The braking member is disposed in a reel body. The moving member is disposed in a rotor to move to a first position corresponding to a line-winding posture and a second position corresponding to a line-releasing posture, in conjunction with a bail arm, and includes an extended portion that extends toward the braking member when the moving member moves to the second position. The elastic member is disposed on the extended portion of the moving member, and comes into contact with an outer peripheral surface of the braking member when the moving member moves to the second position. The adjustment member is disposed between the extended portion of the moving member and the elastic member, and adjusts a position of the elastic member.

A rotor brake mechanism includes a braking member, a moving member, an elastic member, and an adjustment member. The braking member is disposed in a reel body. The moving member is disposed in a rotor to move to a first position corresponding to a line-winding posture and a second position corresponding to a line-releasing posture, in conjunction with a bail arm, and includes an extended portion that extends toward the braking member when the moving member moves to the second position. The elastic member is disposed on the extended portion of the moving member, and comes into contact with an outer peripheral surface of the braking member when the moving member moves to the second position. The adjustment member is disposed between the extended portion of the moving member and the elastic member, and adjusts a position of the elastic member.

Operating at constant depth, various embodiments are provided equipped with automatic depth-control mechanisms in dynamic devices such as lures and carriers that acquire and maintain a constant target depth when pulled through a medium such as water. The depth-control mechanism incorporates a mechanical pressure measurement of depth using a bladder with changing dimensionality and mechanical coupling to a variable angle dive plane. The measured pressure is compared with the target depth pressure causing the dive plane angle to adjust and converge to an adjustable target depth with forward motion due to retrieval or trolling. The dive plane extension is optionally a variable angle lip or bill protruding from the front of the lure or a pectoral fin-like configuration. Multi-purpose carriers are provided that can perform various underwater sensing and measuring tasks. Included are systems and methods for using a lure or platform equipped with a depth-controlling device.

In one embodiment, an intelligent fishing system is provided to enable more accurate fishing in different water types and conditions. The system includes a fishing rod having a reel, the reel comprising at least a portion of a fiber optic cable, and a first device connected at or near a first end of the fiber optic cable, the first device having a controller and at least one camera. The system further includes a fiber optic receiver located at or near the fishing rod, the fiber optic receiver coupled to a second end the fiber optic cable and configured to receive optical signals from the first device through the fiber optic cable. Further, the system includes and a processor operably coupled to the fiber optic receiver and to a display.