A bicycle alone only use up space. But a human riding a bicycle will have to use force to get the bicycle to do anything, by pushing on the pedals, pulling on the handlebar ASO.
The pedals could be one but none thing really resists a pulling force because gravity is a pulling force that acts on everything that has weight.
The bicycle would have the greatest impact force.
Gravity
yes
To measure the mechanical advantage of a bicycle, you would compare the input force applied by the rider to the output force produced at the wheels. The mechanical advantage is calculated by dividing the output force by the input force. In the case of a bicycle, the mechanical advantage helps determine how efficiently the rider's pedaling translates into forward motion.
Friction is the force that stops the bike.
Add the masses, then use the formula: force = mass x acceleration.
The force of gravity keep a bycicle on the ground.
The force that makes a bicycle move forward is generated by the rider pushing the pedals, which rotates the chain connected to the wheels. This rotational force is transmitted to the wheels, causing them to turn and propel the bicycle forward. friction between the tires and the ground helps to convert this rotational force into linear motion.
push pull turn
The applied forces on the bicycle would be balanced. The force applied by the rider in pedaling is equal and opposite to the forces of friction and air resistance acting on the bicycle. This results in a net force of zero, allowing the bicycle to move with constant velocity.
The net force on a bicycle is zero when the forces pushing forward (such as pedaling and friction) are balanced by the forces resisting motion (such as air resistance and friction). This typically occurs when the bicycle is moving at a constant speed on a level surface.