Inertial and Non-Inertial Frames of Reference Question

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Homework Help Overview

The problem involves a rubber stopper suspended from a string in a subway car that is decelerating. The scenario requires understanding the forces acting on the stopper and the relationship between tension in the string and the acceleration of the train.

Discussion Character

  • Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss the relationship between tension, mass, and acceleration, with attempts to derive the acceleration of the train using trigonometric relationships. Questions arise regarding simplification of the expressions and the adequacy of given values.

Discussion Status

Some participants provide guidance on simplifying the expressions and suggest evaluating the numerical answer. There is a mix of confirmations and expressions of uncertainty regarding the approach taken.

Contextual Notes

Participants note the need for clarity on how to simplify the derived expressions and the potential for confusion regarding the values available for calculation.

Kaos_Griever
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Homework Statement


A rubber stopper of mass 25g is suspended by string from a handrail of a subway car traveling directly eastward. As the subway train nears a station, it begins to slow down, causing the stopper and string to hang at an angle of 13 degrees from the vertical. What is the acceleration of the train? Determine the magnitude of the tension in the string.

The attempt at a solution
Tension of String = (mass)(9.81) / cos 13 degrees
The Horizontal component of Tension = [(mass)(9.81) / cos 13 degrees] sin 13 degrees = (mass)(acceleration)
a = [[(mass)(9.81) / cos 13 degrees] sin 13 degrees] / mass
 
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That works. But simplify that answer!
 
I'm not sure how to simplify the answer because I do not have many values to use...
 
You have everything you need.

Cancel what can be canceled; use a single trig expression. Then evaluate to get the numerical answer.
 
Thank you very much! =D It took me a while to understand it.. I thought what I was doing was wrong.
 
Your solution is fine!

FYI, here's how I would do it:

Horizontal forces:
T\sin\theta = ma

Vertical forces:
T\cos\theta = mg

Combine (divide one by the other) to get:
a = g\tan\theta
 
Oh, thanks! I really appreciate your help.
 

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