Displacement equation due to acceleration

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SUMMARY

The forum discussion focuses on the displacement equation under constant acceleration, specifically using the formulas s = ½αt², v = d/t, and a = v/t. It clarifies that velocity is derived from displacement and acceleration is derived from velocity, emphasizing the importance of calculus in understanding these relationships. The discussion highlights that instantaneous velocity differs from average velocity, and under constant acceleration, the average speed is half the final speed.

PREREQUISITES
  • Understanding of basic kinematics equations
  • Familiarity with calculus concepts, specifically derivatives and integrals
  • Knowledge of constant acceleration principles
  • Ability to interpret mathematical formulas
NEXT STEPS
  • Study the relationship between displacement, velocity, and acceleration using calculus
  • Explore the concept of derivatives in physics, particularly in motion analysis
  • Learn about integration techniques to derive velocity from acceleration
  • Investigate real-world applications of constant acceleration in physics problems
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Students of physics, educators teaching kinematics, and anyone interested in the mathematical foundations of motion under constant acceleration.

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Using the formulas: s = \frac{1}{2} \alpha t^2
v = \frac{d}{t}
a = \frac{v}{t}​

When we divide distance "s" by time we get velocity:
v = \frac{\frac{1}{2} \alpha t^2}{t} = \frac{1}{2} \alpha t
When we divide velocity "v" by time we get acceleration:
a = \frac{\frac{1}{2} \alpha t}{t} = \frac{1}{2} \alpha​

½a ≠ a
 
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You need to use calculus here. The instantaneous velocity is not the same as the average velocity.
 
Khashishi said:
You need to use calculus here. The instantaneous velocity is not the same as the average velocity.
So the velocity = the derivative with respect of time of acceleration?
 
You got that backwards. Acceleration is derivative of velocity wrt time
 
Khashishi said:
You got that backwards. Acceleration is derivative of velocity wrt time
So does that make v = ∫a ?
 
yeah, plus an integration constant
 
Khashishi said:
yeah, plus an integration constant
Thank you.
 
Note that under constant acceleration, the calculus is easy and you can probably even see without calculus that the average speed under a linear acceleration is half the final speed.
 

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