Devices and computer technology are configured to enable enhanced simulated bicycle steering for use with a stationary training system. For example, one embodiment includes a device configured to support and enable simulated steering of a bicycle front wheel, for use with a stationary training system, optionally including a sensor device configured to provide a steering signal for user by a bicycle simulator software application. Further embodiments include computer technology configured to provide bicycle simulation functionality, including steering. Simulation of steering is in some embodiments based on a combination of handlebars turning and bicycle tilt, and may account for counter-steering motions.

A bicycle trainer, including a base, permitting fore and aft movement and a frame, supported by the base. Also, a seat and a handlebar assembly and a pedaling assembly is supported by the frame. The handlebar assembly is rotatably engaged to the frame, and is supported by a tongue, that is hinged to the base so as to permit horizontal rotation, and the handlebar assembly is attached to the tongue at a position removed from the hinge. Turning the handlebars causes the frame to move laterally.

A treadmill system includes a deck, an endless tread belt covering at least a portion of the deck, a position sensor that senses a position of a user when the user is on the tread belt, and a control module that adjusts a speed of the tread belt in response to an output of the position sensor.

A bicycle trainer provides variable resistance to pedaling and allows for a rider to simulate a real-world bicycle course. The trainer engages both the front tire and the back tire of the bicycle and adjusts each according to the rider's preferences during a training session. The front tire lifts up and down as the bicycle moves forward and backward on the trainer. The back tire is adjusted by incorporating magnets thereon in the form of magnetic elements on a sleeve or a clip that engages the back tire and/or the back tire rim. The magnets on the back tire may also be attached to the spokes. The trainer includes magnets as well, usually of opposite polarity, and adds resistance to pedaling when the magnetic fields of the magnets interact to resist back tire revolution.

A bicycle training system and methods of using the same. The system includes a movement platform that rests on a support surface and supports a bicycle in an upright manner with respect to the support surface. The movement platform includes a support frame having a base and at least one upstanding arm that supportably engages a portion of a frame of the bicycle, a resistance assembly operatively coupled to a portion of a drivetrain of the bicycle that applies varying levels of resistance to the portion of the drivetrain, and a plurality of bushings isolating the base from the support surface. The plurality of bushings are spherical thereby permitting the movement platform to move with respect to the support surface in response to forces applied to the bicycle frame during use of the bicycle training system.

An intelligent exercise bike includes a frame, and a front wheel and a rear motor wheel, wherein the frame is provided with a pedal motor electrically connected with the pedal, and the output shaft of the pedal motor is drivingly connected with the pedal; the pedal motor has a torque sensor and a Hall sensor that are electrically connected thereto for detecting the speed and force of the pedal; a bike controller is provided in the frame, and the torque sensor and the Hall sensor convert the detected pedal speed and force into transmission signals, and output them to the bike controller; the bike controller is connected to a power supply circuit of the rear motor wheel, and the bike controller outputs a control signal to adjust the output power value of the rear motor wheel after receiving the transmission signals.

A bicycle trainer for removably loading with a bicycle that is at least provided with a back wheel, which bicycle trainer comprises a floorstanding frame with a wheel supporting roller at its rear end and a fork supporting unit at its forward end, wherein the fork supporting unit is pivotally supported by the frame enabling it to move back-and-forth. The fork supporting unit and the frame connect to each other with a hinge enabling back-and-forth movement of the fork supporting unit in a longitudinal direction of the frame, wherein the fork supporting unit is spring-loaded with a spring at or near the hinge to provide the fork supporting unit with a preferential upright position at square angles with the frame so as to arrange that in use whenever the bicycle is moved forward or backward, said bicycle is inclined to return to an average position on the bicycle trainer wherein the fork support unit is perpendicular to the horizon.

Method for operating a bicycle trainer, and such a bicycle trainer comprising a stand with a seat, handlebars and rotatable pedals, or such a bicycle trainer comprising a stand for mounting a bicycle frame with a seat, handlebars and rotatable pedals, wherein the stand incorporates an electronically variable brake acting directly or indirectly on the rotatable pedals with a braking resistance that depends on a computer-controlled predetermined setting, wherein the pre-determined setting is variable and wherein said setting depends on selected parameters to reflect a simulated surface condition of a road.

A system and method for controlling an exercise device are provided herein. The system includes a memory having computer-executable instructions and at least one processor to execute the computer-executable instructions to wirelessly connect the exercise device, receive a training mode, receive at least one variable for determining a power set point, determine the power set point responsive to the training mode and the at least one variable and control a magnetic brake assembly in the exercise device responsive to the power set point.

A support device for a bicycle includes a support structure, a fixing group supported on the support structure and also includes a movable element and a retention element configured to hold the front fork of the bicycle. The support device also includes a lifting/lowering device of the fixing group, in which the retention element is integral in translation with the movable element. The support device further includes connection means configured for slidingly fixing said fixing group to the support structure in such a way as to allow displacements of the fixing group with respect to the support structure along a compensation direction transverse to the vertical direction.