Curious3141 said:The OP has not shown any work, but if this is the question he was given (verbatim), it's a piss poor question.
If friction is neglected, then I'd ask the question-setter to explain to me exactly how the boy is able to "run". And how would he be able to remain planted on the plank after he steps on it ?
Where is the plank sited ? Is it just lying at rest on the ice ? Or is it balanced on a fulcrum off the ground, like a see-saw ?
Using the former interpretation, and completely neglecting friction between plank and ice, why is this even a rotational movement problem ? There would be NO point on the plank remaining at rest with respect to the ice. Assuming the boy somehow remains on the plank without friction (thereby imparting all his momentum to the plank-boy combination), the plank-boy would travel with a velocity equal to [itex]v\frac{m}{M+m}[/itex] in the same direction as the boy's initial running.
That's the translational speed of the center of mass of the plank-boy. But the plank-boy will also rotate. So the question does make sense.Using the former interpretation, and completely neglecting friction between plank and ice, why is this even a rotational movement problem ? There would be NO point on the plank remaining at rest with respect to the ice. Assuming the boy somehow remains on the plank without friction (thereby imparting all his momentum to the plank-boy combination), the plank-boy would travel with a velocity equal to [itex]v\frac{m}{M+m}[/itex] in the same direction as the boy's initial running.
The boy jumps onn the plank at the end with contact with the ice and perpendicular to the surface.OlderDan said:If he jumps on the middle, you have solved the problem. If he jumps on off-center, the plank is going to rotate as well as slide, and one point initially at rest is a distinct possibility.
im really sorry i forgot to mention about the friction being neglected only between the plank and the ice but i do think that was OBVIOUS.Anyway you did figure that out later.Curious3141 said:If friction is neglected, then I'd ask the question-setter to explain to me exactly how the boy is able to "run". And how would he be able to remain planted on the plank after he steps on it ?
naznad said:The boy jumps onn the plank at the end with contact with the ice and perpendicular to the surface.
Rotational motion is the movement of an object around an axis or center point. It can involve spinning, rolling, or any other type of circular motion.
The key concepts related to rotational motion include angular velocity, angular acceleration, moment of inertia, torque, and rotational equilibrium.
Linear motion involves movement in a straight line, while rotational motion involves movement in a circular or curved path around a fixed point.
Rotational motion is measured using angular units, such as radians or degrees, and can also be measured using time units, such as revolutions per second or rotations per minute.
Some real-life examples of rotational motion include the rotation of the Earth on its axis, the spinning of a top, the movement of a Ferris wheel, and the rotation of a car tire.