Maximum Acceleration: I Got the Correct Answer

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rashida564
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Homework Statement
Position of an object is given by y(X)=sin(x), and moves with constant speed v. Find the maximum speed given that, the acceleration at the top shouldn't exceed g.
Relevant Equations
a=dv/dt
I got the correct answer which is √g. I solved it as if it were a circular motion with radius of 1. But got no idea why my solution did work.
 
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rashida564 said:
Homework Statement:: Position of an object is given by y(X)=sin(x), and moves with constant speed v.
Please show your detailed work so we can check it.

Also, this problem statement is confusing to me. Is it saying that v(t) is constant, and the position y(x) follows a sinusoidal path? How can you find the "maximum speed" if the speed is constant?
 
berkeman said:
Is it saying that v(t) is constant, and the position y(x) follows a sinusoidal path? How can you find the "maximum speed" if the speed is constant?
It says the speed is a constant v. Whether you consider it v(t) or v(x) is immaterial. It asks for the maximum value of a constant given a constraint, not the maximum over time.
 
Thanks @haruspex -- I still am not understanding, but will just watch to see how the OP responds. Guess I'll learn something. :smile:
 
rashida564 said:
Homework Statement:: Position of an object is given by y(X)=sin(x), and moves with constant speed v. Find the maximum speed given that, the acceleration at the top shouldn't exceed g.
Homework Equations:: a=dv/dt

I got the correct answer which is √g. I solved it as if it were a circular motion with radius of 1. But got no idea why my solution did work.
I think you just got lucky. What if it had been A sin(ωx)?
 
haruspex said:
I think you just got lucky. What if it had been A sin(ωx)?
can you give me a hit of what should I do
 
The direction of the acceleration. It must be tangential to the curve
 
Is it true this way because it will be a rotating vector, or I just got it by pure luck again😭😭😭
not sure though why should it v times v
 

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You know that ##y = \sin{x}## describes the trajectory of the particle, and you want to find something relating to the acceleration in the ##y## direction, ##\frac{d^{2}y}{dt^{2}}##. What happens if you try finding the second derivative of ##y## with respect to ##t##? Then, what values can you substitute into this expression given the critical condition in the question?
 
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rashida564 said:
Is it true this way because it will be a rotating vector, or I just got it by pure luck again😭😭😭
not sure though why should it v times v
You'd need to justify dv/dt = v2. Where did that come from? Remember |v| is given as constant.
 
that's from the rotation of axis. Like any vector. dA/dt= A*w. where w is the rate in which it changes it's direction. Not sure why this vector change it's direction by magnitude of v
 
rashida564 said:
Like any vector. dA/dt= A*w. where w is the rate in which it changes it's direction.
If you want to justify it in terms of vectors you'll need to write it appropriately to be understood.
Do you mean that if ##|\vec A|## is constant then ##|\frac{d\vec A}{dt}|=|\vec A|\omega## where ω is .. what algebraically ?
 
rashida564 said:
Homework Statement:: Position of an object is given by y(X)=sin(x),

I got the correct answer which is √g. I solved it as if it were a circular motion with radius of 1. But got no idea why my solution did work.
It is not a circular motion.
Imagine it is a car going up a hill with constant speed v. The horizontal displacement of the car is x, the vertical one is y. The shape of the hill is y=sin(x). Determine the x and y components of acceleration at the top of the hill.
 
haruspex said:
If you want to justify it in terms of vectors you'll need to write it appropriately to be understood.
Do you mean that if ##|\vec A|## is constant then ##|\frac{d\vec A}{dt}|=|\vec A|\omega## where ω is .. what algebraically ?
Yes sir sorry for my messy writing, this what I am trying to figure out, the left hand side is " |d→Adt||dA→dt| clearly g, the ##|\vec A|\## is v, but I don't get what's w
 
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w must be equal to v, but I don't know how to define w. like what's it's formula
 
It's to the center and equal to v^2/r