A compaction machine system includes a compaction machine in communication with a remote control. The compaction machine includes a mobile chassis with a first and second subframes pivotably connected at a pivot connection, a steering angle sensor, a steering actuator for causing the first and second subframes to pivot, and a control unit in communication with the steering angle sensor and with the steering actuator. The control unit determines an operational stroke of the of the steering actuator and controls the steering actuator based on the input from the direction control and the determined operational stroke of the steering actuator. When the steering actuator is at a limit of its operational stroke, the control unit overrides commands from the direction control that otherwise would result in extending or retracting the steering actuator stroke beyond its operational limit. The control unit also returns the steering actuator to its neutral position in the absence of an operator-generated steering command.

A process of piloting an omnidirectional autonomous vehicle on a virtual pathway, the omnidirectional autonomous vehicle including at least one reference line, and steering wheels configurable to drive the omnidirectional autonomous vehicle on the virtual pathway independently of its orientation.

A control device for a model car is provided. The control device comprises: a rotation sensor configured to detect a rotation number of a first wheel and a rotation number of a second wheel of a model car; and a controller configured to perform driving control of a driving source of the model car such that a rotation number difference between the first wheel and the second wheel is reduced when the rotation number difference is greater than or equal to a threshold.

An autonomous skid-steer machine includes a chassis, a plurality of ground engaging elements supporting the chassis on a ground surface and one or more computing devices for controlling movement of the machine. The one or more computing devices are configured to generate a control signal for controlling operation of at least some of the plurality of ground engaging elements, the control signal being generated according to a control algorithm incorporating tuning parameters, and to automatically determine the tuning parameters in real time during operation of the machine such that the control algorithm is always optimized for a current speed of the machine. The tuning parameters are found using the machine's current speed, a natural frequency value and a damping value.

The guidepath includes: a magnet guide tape which carries S pole, and guides a carrier vehicle in a first direction by the S pole by being arranged on a floor so as to extend in the first direction; a magnet guide tape which carries S pole, and guides the carrier vehicle in a second direction by the S pole by being arranged on the floor so as to extend in a second direction which intersects the first direction; and a magnetic body tape which is arranged at a side of the magnet guide tape at a position above which a marker sensor passes upon the carrier vehicle being guided by the magnet guide tape, and suppresses N pole.

A steering control apparatus includes a processing unit configured to execute, a target steering angle variable acquiring processing of acquiring a value of a target steering angle variable, a target steering angle correcting processing of correcting the value of the target steering angle variable by a play compensation amount according to a steering direction, a gradually changing processing of gradually changing a magnitude of the play compensation amount, and a steering angle control of operating the motor through control with a steering angle according to a rotation angle of the steering shaft being as a control amount and with the value of the target steering angle variable being as a target value of the control amount.

A multidirectional wheel system, apparatus, and method to control one or more multidirectional wheels to provide multidirectional motion or movement for a movable apparatus, such as a skateboard, roller blades, a car, a motorcycle, a cleaning robot, to which the one or more multidirectional wheels are attached. The multidirectional wheel system includes a braking system to slow and/or stop the movement of the multidirectional wheel(s). At least one of the multidirectional wheels is an omnidirectional wheel, with a plurality of multidirectional wheels acting thereon to control movement thereof. The multidirectional wheel system includes a drone, wherein the omnidirectional wheel operates based on instructions from the drone.

A mobile machine having a chassis, a plurality of ground-engaging elements, a plurality of actuators for driving movement of the ground-engaging elements, and a controller for controlling each of the actuators to cause the mobile machine to follow a guidance path along a ground surface. The controller is configured to generate a first set of control values for driving the machine according to a first heading based on a reference heading error of the machine and generate a second set of control values for driving the machine according to a second heading based on a distance heading error of the machine, determine a weight scheme for the first set of control values and the second set of control values dependent on a distance of the machine from the guidance path, combine the control signals using the weight scheme and drive the machine using the combined control signals.

A mobile machine including a chassis, a plurality of ground-engaging elements, actuators for driving movement of the ground-engaging elements and a controller for controlling each of the actuators to cause the mobile machine to follow a reference path. The controller is configured to implement a cascading control loop for controlling movement of the mobile machine, the cascading control loop including an outer loop and an inner loop. The outer loop is configured to determine a set heading for reducing a distance between the mobile machine and the reference path, the set heading being determined using an error slope parameter. The inner loop is configured to drive the actuators so that the mobile machine follows the set heading determined by the outer loop. The controller is configured to automatically adjust the error slope value so that the rate of change of the set heading does not exceed a maximum yaw rate.

A mobile machine including a chassis, a plurality of ground-engaging elements, a plurality of actuators for driving movement of the ground-engaging elements, and a controller for controlling each of the actuators to cause the mobile machine to follow a guidance path along a ground surface. The controller is configured to generate a first set of control values for driving the machine according to a first heading based on a reference heading error of the machine, generate a second set of control values for driving the machine according to a second heading based on a distance heading error of the machine, generate a current machine velocity using a prescribed machine velocity, the reference heading error, and the distance heading error, and generate control signals for driving the machine by combining the first set of control values, the second set of control values, and the current machine velocity.