Why Does Cutting the String Change the Tension Ratio in a Pendulum?

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SUMMARY

The discussion centers on the tension ratio in a pendulum system when a supporting string is cut. Initially, the tension in the string holding the ball (T1) is calculated using the equilibrium condition, yielding T1 = mg/cos(theta). After the string is cut, the tension (T2) during the pendulum's swing is determined to be T2 = mg*cos(theta). The ratio of these tensions is established as T1/T2 = 1/cos^2(theta), clarifying that the tension changes due to the dynamics of the pendulum motion.

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  • Understanding of basic physics concepts, specifically forces and tension.
  • Familiarity with pendulum motion and centripetal acceleration.
  • Knowledge of trigonometric functions, particularly sine and cosine.
  • Ability to interpret vector diagrams in physics.
NEXT STEPS
  • Study the principles of pendulum dynamics and energy conservation.
  • Learn about vector decomposition in physics for analyzing forces.
  • Explore the effects of angular displacement on tension in pendulum systems.
  • Investigate the relationship between centripetal force and tension in circular motion.
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Physics students, educators, and anyone interested in understanding the mechanics of pendulum systems and the effects of forces on tension ratios.

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SO.

a ball is suspended by a string from the ceiling, and held at angle theta to the vertical by another string that is attached to the wall nearby... the string attched to the wall is cut and the ball swings like a pendulum, at the farthest it is theta from the vertical on both sides.

so. the book asks what is the ratio of the tension in the rope holding the rope to the ceiling before the other rope(attached to the wall) was cut, to when the ball is swinging and is at its farthest from the vertical(forming angle theta to it)

i thought it should be one to one, because the tension*sin(theta) would be supporting the ball in both cases, but it turns out the answer is cos^2(theta)

any ideas why?
 
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Check your vector diagram.
 
[tex]\begin{align*}\\<br /> Case\ 1 :\\<br /> Particle\ is\ in\ equilibrium. \\<br /> \sum \vec{F}=0\\<br /> T_1cos\theta + (-mg) = 0\\<br /> T_1=\frac{mg}{cos\theta}\\<br /> Case\ 2:\\<br /> Centripedal\ acceleration :\\<br /> T_2+(-mgcos\theta)=0\ since\ v=0\\<br /> T_2=mgcos\theta\\<br /> \frac{T_1}{T_2}=\frac{1}{cos^2\theta}\\<br /> Why\ the\ reciprocal\ ?\\<br /> \end{align}[/tex]
 

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