A system including a drone or unmanned vehicle configured to perform surveillance of a premises. The drone surveillance includes autonomous navigation and/or remote or optional piloting around the premises. The drone includes a controller coupled to a plurality of sensors configured to collect drone data and security data at the premises, wherein the controller is configured to generate control data for the drone and the premises using the drone data and the security data. A remote device coupled to the drone includes a user interface configured to present the drone data, the security data, and/or the control data.

A remote control device for remotely controlling a ship propulsion device provided in a ship. The remote control device includes a remote control device main body including a main body case installed on an installation surface provided in the ship, and a remote control lever attached to the main body case, a display unit provided outside the main body case, and including a display case and a display provided in the display case, and a support arm that couples the display unit and the remote control device main body to each other, and that supports the display unit such that the display unit is disposed at a position separated from the remote control device main body.

This application describes clutch mechanisms for use in a steering control system, e.g., a steering control system used to steer a trolling motor for a boat. Such clutch mechanisms can reduce and avoid damage to the steering control system (e.g., a steering motor) when the system is subjected to unusually large impact loads (e.g., when the trolling motor or boat contacts an obstruction). The clutches described in this application can be used to decouple the steering control system from a steering shaft (or other drive mechanism) upon application of a large impact load, thus reducing damage to and increasing the lifespan of such system. In some cases, the clutch is a ball and spring mechanism. In other cases, the clutch is a slip tooth mechanism.

An amphibious vehicle has a floatable vehicle body; ground engaging propulsion structure having a plurality of ground engaging elements powered by a hydraulic motor; a fluid pump for pumping liquid manure; a power source connected to a hydraulic pump and configured to provide power to both the ground engaging propulsion structure and the fluid pump; and, remote control structure for controlling the ground engaging propulsion structure and a flow of fluid from the fluid pump. The speed and/or direction of the vehicle is remotely controllable by an operator remote from the vehicle when the vehicle is ground engaging and when the vehicle is floating.

A system including a drone or unmanned vehicle configured to perform surveillance of a premises. The drone surveillance includes autonomous navigation and/or remote or optional piloting around the premises. The drone includes a controller coupled to a plurality of sensors configured to collect drone data and security data at the premises, wherein the controller is configured to generate control data for the drone and the premises using the drone data and the security data. A remote device coupled to the drone includes a user interface configured to present the drone data, the security data, and/or the control data.

A marine vessel maneuvering system includes an operator to receive both a propulsive force operation to change a propulsive force of a propulsion device and a steering operation to turn the propulsion device to steer a marine vessel, and a controller configured or programmed to perform a control to automatically drive the propulsion device to move the marine vessel in an automatic marine vessel maneuvering mode. The controller is configured or programmed to perform a control to transition to the automatic marine vessel maneuvering mode based on a transition operation being performed on the operator.

Example steering control systems for multiple devices are provided herein. A system includes a trolling motor assembly having a propulsion motor and a steering actuator and a sonar assembly comprising a transducer assembly and a directional actuator. The system further includes a user input assembly that is configured to detect user activity related to controlling operation of the trolling motor assembly and operation of the sonar assembly. The system further includes a processor that is configured to determine a direction of turn based on user activity, generate an electrical turning input signal indicating the direction of turn, and direct one of the steering actuator and the directional actuator, via the turning input signal, to rotate one of the propulsion motor and the transducer assembly, respectively, in a direction of turn based on the turning input signal.

A method of operating a handheld device for controlling a watercraft motor is provided. The method comprises determining whether the handheld device is operating in an anchor mode or a heading hold mode; receiving movement data when the joystick is in a non-neutral position that includes a direction of movement; generating steering command(s), with a steering command of the steering command(s) being based on the movement data; causing motor rotation based on the steering command; detecting the joystick shifting to the neutral position, with the watercraft being at a location when the joystick shifts to the neutral position; when in the anchor mode, causing the motor to cease operation proximate to the location after the joystick has shifted to the neutral position; and, when in the heading hold mode, causing the motor to continue operating so that the watercraft travels in the new heading direction after the joystick shifts.

Disclosed is a method for providing input to a vehicle control system to navigate, position and direct a vehicle, by use of a gesture sensing device. The gesture sensing device may be in the form of: a remote, a mobile computing device such as a smartphone, a tablet or smart-watch, or a direction/motion sensor. The vehicle control system with gesture sensing device is useful for the control of radio controlled vehicles, drones and driver and driverless vehicles. In preferred embodiments, the vehicle control system with gesture sensing device is used to control GNSS/GPS enabled electric steer trolling motors, such as motors utilizing the ProNav® Angler, Rhodan® HD GPS® Anchor, Minn-Kota® IPilot, and the MotorGuide® Pinpoint.

A system including a drone or unmanned vehicle configured to perform surveillance of a premises. The drone surveillance includes autonomous navigation and/or remote or optional piloting around the premises. The drone includes a controller coupled to a plurality of sensors configured to collect drone data and security data at the premises, wherein the controller is configured to generate control data for the drone and the premises using the drone data and the security data. A remote device coupled to the drone includes a user interface configured to present the drone data, the security data, and/or the control data.