Understanding 1D Motion: Distance, Speed, and Velocity Basics
This guide covers the fundamental concepts of one-dimensional motion, including distance, displacement, speed, and velocity. Learn how to effectively interpret and convert units like meters, kilometers, and seconds, along with practical examples and conversions. The content differentiates between scalar and vector quantities, discusses average versus instantaneous speed, and highlights how to calculate acceleration. Gain insights on graphical analysis and how to apply equations for constant acceleration in real-world scenarios. Perfect for students and anyone interested in the dynamics of motion.
Understanding 1D Motion: Distance, Speed, and Velocity Basics
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Presentation Transcript
1D Motion Also known as linear motion
Units Base – Directly measured > • Distance (position) • Displacement • Time Meters (m) Kilometers (km) Seconds (s), Minutes (min) Hours (h) Derived - Calculated/Combination of Units > • Speed • Velocity Meters/second (m/s) Kilometers/hour (km/h) Meters / seconds2 (m/s2) • Acceleration
Dimensional Analysis(Converting Units) • Use factor label method (T chart) • Fraction • Same units must be OPPOSITE each other • So they will cancel out
Example #1 • If simply moving the decimal, can use KHDBDCH • Convert 2.1 cm to m • Start at C, move to B • Left 2 places • In the #, locate the decimal and move left 2 places • 2.1 cm becomes 0.021 m
Example #2 Convert 35 km/h to m/s 1000 m 1 h 35km 1min 35(1)(1)(1000) = 1 km 60min 1h 60s 1(60)(60)(1) 35000 9.72 = m/s 3600
Scalar vs. Vector Quantities • Scalar – number (magnitude) • Vector – number with direction
Examples • The student traveled to get to school on time. Scalar • The student traveled to get to school on time. Vector 55 mph 55 mph north
Distance vs. Displacement • Distance – TOTAL amount traveled • Displacement – DIFFERENCE between starting and ending points (-) direction South, West, Left, Down (+) direction North, East, Right, Up
Example During the Coca-Cola 600 held at Lowe’s Motor Speedway in May. How far do the cars travel during the race? What is the total displacement of each car during the race? Distance 600 miles Displacement 0 miles
Speed vs. Velocity • Speed – scalar • Velocity - vector (# only) (# & direction) Distance Time Average vs. Instantaneous Average – TOTAL D & TOTAL T Instantaneous – D & T at a SPECIFIC moment
You take a trip to your friends house that lives 370 km west of your house. You leave your house at 10 am and arrive at your friends house at 3 pm. What was your velocity as you traveled to your friends house? You take a trip to your friends house that lives 370 km west of your house. You leave your house at 10 am going west for 140 km before you stop to eat lunch at 12 pm. You get out of your car, stretch your legs, use the restroom, and eat lunch. You finish all of this and head out towards your friends house again by 12:45 pm. You travel another 100 km before you stop again to use the restroom. The line is long and you need a drink to refresh yourself, so your stop takes you about 10 minutes before you are off again. Finally, you arrive at your friends house at 3 pm. What was your velocity as you traveled to your friends house?
Graphical Analysis Positive Velocity Negative Velocity No Movement
Average Acceleration • The change in velocity an object undergoes in a certain amount of time. • Acceleration = final velocity – initial velocity final time – initial time a = v t • Vector • Positive • direction or speeding up Negative direction or slowing down
Example A shuttle bus slows to a stop with an average acceleration of -1.8 m/s2. How long does it take the bus to slow from 9.0 m/s to 0.0 m/s? a = v t -1.8 = 0.0 – 9.0 x -1.8 = -9.0 x X = -9.0 -1.8 x = t = 5.0 s
Constant Acceleration Equations used for constant acceleration problems (same throughout the movement) (no sudden take offs or brake slamming) x = ½ (vi + vf) t x = vi (t) + ½a (t)2 vf = vi + a(t) vf2 = vi2 + 2a(x)
