The discussion centers on the concept of displacement in Simple Harmonic Motion (SHM) for an oscillating pendulum. It is established that the displacement at the extreme position is represented by the arc length (Lθ), while the straight line distance from the mean position is an approximation valid only for small angles. The approximation arises from the Taylor series expansion of sinθ, where Lsinθ approximates Lθ for small θ. The conversation emphasizes that while both arc length and straight distance can be used as coordinates, the motion remains SHM only approximately for small angles.
PREREQUISITESStudents of physics, educators teaching oscillatory motion, and anyone interested in the mathematical foundations of pendulum dynamics.
andyrk said:For SHM of oscillating pendulum, when the pendulum is at the extreme position, what is considered as the displacement?
andyrk said:But shouldn't it be the straight line displacement from the mean position?
What do your textbooks tell you about these questions you are asking on PF? Yet again, this topic is well covered on line and in books.andyrk said:What if θ is not small?
SHM is a specific kind of oscillation - the simplest there is, in fact. SHM requires the restoring force to be directly proportional to the displacement and, for a simple pendulum, it is not. Look at this link, which shows that the motion of a simple pendulum 'approaches' pure SHM as the amplitude approaches zero.andyrk said:I don't know. They didn't mention if it was small or not. But they have taken the displacement to be ##lθ##. So I think that must mean that θ is small. Am I right?
You can use either one as a coordinate. You can also use the angle, as it was already mentioned.andyrk said:For SHM of oscillating pendulum, when the pendulum is at the extreme position, what is considered as the displacement? The curve/arc of the circle the bob is following or the straight line distance from the mean position?
Yes but, if you are using the arc in your equation, the restoring 'force' becomes a torque and that is not proportional to the angle in any case. It's still non linear with change of position.nasu said:You can use either one as a coordinate. You can also use the angle, as it was already mentioned.
In general, for a system, there is more than one way to choose the coordinates. Some may be more convenient but not in anyway "correct" or "wrong".
But even if you use the straight distance, the motions is SHM only approximately, for small angles.
And the length of the arc is Lθ for any value of the angle. Is not an approximation.
The straight distance though, is only approximately so, for small angles.
I don't know who the "they" you refer to were. If they were showing you the proper derivation of SHM, they would have included the limiting case for small angles.andyrk said:I don't know. They didn't mention if it was small or not.
It bothered me that it may have been interpreted wrongly. You were discussing a change of co ordinates. The result is that the non linearity turns up somewhere else and that point needs to be made constantly, IMO.nasu said:Did I say that it becomes linear if the angle is used?
The last part was a separate point. Someone said in a previous post that s=Lθ it is just an approximation for small theta, which is not true. I did not mean (and did not say)that the motion becomes SHM.