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Krishna 0ffca9d739 almost all of 1D kinematics
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Vectors and Kinematics 2024-08-19

One must always start a study into the heavily crippled IB editions of the glorious subject of Physics with the initial understanding that the road ahead lead to pain immeasurable.

-> Prime of the Faith

Motion in 1D

In this rendering of motion, you will never need to use vector quantities to describe movement due to the scalar nature of all quantities discussed.

Reference Frames and Displacement

  • Any measurement about motion is taken in terms of a reference frame.

Note

Example: A train that moves with respect to the ground being held stationary, is not moving with respect to a stationary person inside that train. If a person were to walk, at let's say 5 km/s toward the back of the train while it moves forward at 80 km/h, the person is moving at 75 km/h with respect to the stationary ground.

  • In one dimension, only one axis, the $x$-axis of a coordinate plane is used.
  • the net distance an object has traveled is known as displacement
  • total distance is the overall distance traveled by the object/particle regardless of reference frame or initial/final positions
  • change in positions is described using \Delta x

Average Velocity

It is important to note that this equation was derived from the more complicated calculus variant of the velocity equation. There are 2 important terms here.


\text{average speed}=\frac{\text{distance traveled}}{\text{time elapsed}}=\frac{\Delta x}{\Delta t}

For any form of velocity, the speed is simply calculated by using the magnitude of the velocity vector ||\vec{v}||, but since we exist in one dimension now, we will use |v(t)|

Instantaneous Velocity

If the position equation is defined as x(t), then:


\text{instantaneous velocity} = \tfrac{\mathrm{d}x}{\mathrm{d}t} = v(t) = \lim_{\Delta t \to 0}{\tfrac{\Delta x}{\Delta t}}

Average Acceleration

The acceleration of an object is the rate at which the velocity of said object changes. Average Acceleration is defined as the change in velocity from 2 distinct points divided by the change in time between those 2 distinct points.


\text{average acceleration} = \frac{\text{change of velocity}}{\text{time elapsed}}

Or more mathematically:


a=\frac{v_2-v_1}{t_2-t_1}=\tfrac{\Delta v}{\Delta t}

Instantaneous Acceleration

If the velocity function is defined as v(t) (this notation only applies to 1 dimension):


a(t)=\tfrac{\mathrm{d}v}{\mathrm{d}t}=\lim_{\Delta t \to 0}{\tfrac{\Delta v}{\Delta t}}

Please take calculus/study calculus if you want a neuron or two to function during the course of this, well, course.

#physics