Is the problem statement exactly as given to you?Jenny Physics said:
You are right, this was a misunderstanding. I edited the question.haruspex said:
I assume the upper rod joins the lower rod at its mid point.Jenny Physics said:
It doesn't depend on the length of the lower rod only because of the symmetry. But what if the pendulum were not attached right at the middle of the lower rod? How could I derive the equations without using torques?haruspex said:
It is provably impossible.Jenny Physics said:
The equation for this motion is known as the double pendulum equation and it is a set of coupled differential equations that describe the position and velocity of the two masses as they swing back and forth.
The motion of the masses is affected by factors such as the length of the rod, the mass of the masses, the angle at which the pendulum is released, and the gravitational force acting on the system.
The period of the motion, or the time it takes for the masses to complete one full swing, is dependent on the length of the rod and the acceleration due to gravity. It can be calculated using the formula T = 2π√(L/g), where T is the period, L is the length of the rod, and g is the acceleration due to gravity.
The initial conditions, such as the initial angle and velocity, have a significant impact on the motion of the pendulum. Small changes in these initial conditions can result in drastically different trajectories of the masses.
The double pendulum equation has been used to study chaotic systems and has applications in fields such as physics, engineering, and biology. It can also be seen in everyday objects such as grandfather clocks and amusement park rides.