New 0095 Lecture Notes - Understanding Uniformly Accelerated … · 2020. 10. 6. · 0095 Lecture...

0095 Lecture Notes - Understanding Uniformly Accelerated Motion.docx page 1 of 1 Flipping Physics Lecture Notes: Understanding Uniformly Accelerated Motion We usually look at the dimensions for acceleration as: a = Δv Δt ⇒ m s 2 Today we are going to look at the dimensions for acceleration as: a = Δv Δt ⇒ m s s or m s every second Example #1: A ball is released from rest and has an acceleration of 2 meters per second every second. (a) What is the velocity of the ball at t = 1, 2, 3, 4 and 5 seconds? (b) If the initial position of the ball is zero, what is the position of the ball at t = 1, 2, 3, 4 and 5 seconds? Part (a): If the initial velocity of the ball is zero and the acceleration is 2 m s every second, then the velocity will increase by 2 m s every second. At t = 0 s, v = 0 m s ; at t = 1 s, v = 2 m s ; at t = 2 s, v = 4 m s ; at t = 3 s, v = 6 m s ; at t = 4 s, v = 8 m s & at t = 5 s v = 10 m s . Part (b): Δx = v i Δt + 1 2 aΔt 2 = 0 () Δt + 1 2 2 () Δt 2 ⇒Δx = Δt 2 ⇒Δx 1 = 1 2 = 1 m ; Δx 2 = 2 2 = 4 m Δx 3 = 3 2 = 9m ; Δx 4 = 4 2 = 16 m ; Δx 5 = 5 2 = 15 m Example #2: A ball is given an initial velocity of -10 m/s and has an acceleration of 2 meters per second every second. (a) What is the velocity of the ball at t = 1, 2, 3, 4 and 5 seconds? (b) If the initial position of the ball is 25 meters, what is the position of the ball at t = 1, 2, 3, 4 and 5 seconds? Part (a): If the initial velocity of the ball is -10 m s and the acceleration is 2 m s every second, then the velocity will increase by 2 m s every second. At t = 0 s, v = -10 m s ; at t = 1 s, v = -8 m s ; at t = 2 s, v = -6 m s ; at t = 3 s, v = -4 m s ; at t = 4 s, v = -2 m s & at t = 5 s v = 0 m s . Part (b): Δx = x f − x i = v i Δt + 1 2 aΔt 2 ⇒ x f − 25 ( ) = −10 ( ) Δt + 1 2 2 () Δt 2 ⇒ x f = 25 + −10 ( ) Δt + Δt 2 ⇒ x 1f = 25 + −10 ( ) 1 () + 1 2 = 16 m ; x 2 f = 25 + −10 ( ) 2 () + 2 2 = 9m x 3 f = 25 + −10 ( ) 3 () + 3 2 = 4 m ; x 4 f = 25 + −10 ( ) 4 () + 4 2 = 1 m ; x 5 f = 25 + −10 ( ) 5 () + 5 2 = 0 m

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Transcript of New 0095 Lecture Notes - Understanding Uniformly Accelerated … · 2020. 10. 6. · 0095 Lecture...

Page 1: New 0095 Lecture Notes - Understanding Uniformly Accelerated … · 2020. 10. 6. · 0095 Lecture Notes - Understanding Uniformly Accelerated Motion.docx page 1 of 1 Flipping Physics

0095 Lecture Notes - Understanding Uniformly Accelerated Motion.docx page 1 of 1

Flipping Physics Lecture Notes: Understanding Uniformly Accelerated Motion

We usually look at the dimensions for acceleration as: a = Δv

Δt⇒ m

Today we are going to look at the dimensions for acceleration as: a = Δv

Δt⇒

sor

every second

Example #1: A ball is released from rest and has an acceleration of 2 meters per second every second. (a) What is the velocity of the ball at t = 1, 2, 3, 4 and 5 seconds? (b) If the initial position of the ball is zero, what is the position of the ball at t = 1, 2, 3, 4 and 5 seconds?

Part (a): If the initial velocity of the ball is zero and the acceleration is 2

every second, then the velocity

will increase by 2

every second. At t = 0 s, v = 0

; at t = 1 s, v = 2

; at t = 2 s, v = 4

;

at t = 3 s, v = 6

; at t = 4 s, v = 8

& at t = 5 s v = 10

Part (b): Δx = v

iΔt + 1

2aΔt2 = 0( )Δt + 1

22( )Δt2

⇒Δx = Δt2 ⇒Δx1=12 =1m ; Δx

2= 22 = 4m

Δx3= 32 = 9m ; Δx

4= 42 =16m ; Δx

5= 52 =15m

Example #2: A ball is given an initial velocity of -10 m/s and has an acceleration of 2 meters per second every second. (a) What is the velocity of the ball at t = 1, 2, 3, 4 and 5 seconds? (b) If the initial position of the ball is 25 meters, what is the position of the ball at t = 1, 2, 3, 4 and 5 seconds?

Part (a): If the initial velocity of the ball is -10

and the acceleration is 2

every second, then the velocity

will increase by 2

every second. At t = 0 s, v = -10

; at t = 1 s, v = -8

; at t = 2 s, v = -6

;

at t = 3 s, v = -4

; at t = 4 s, v = -2

& at t = 5 s v = 0

Part (b): Δx = x

f− x

i= v

iΔt + 1

2aΔt2

⇒ x

f− 25( ) = −10( )Δt + 1

22( )Δt2

⇒ x

f= 25+ −10( )Δt + Δt2 ⇒ x

1f= 25+ −10( ) 1( ) +12 =16m ; x

2 f= 25+ −10( ) 2( ) + 22 = 9m

3 f= 25+ −10( ) 3( ) + 32 = 4m ; x

4 f= 25+ −10( ) 4( ) + 42 =1m ; x

5 f= 25+ −10( ) 5( ) + 52 = 0m

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