time (s) 0 1 2 3 4 5 6 7 8 9 speed (m/s) 4 3 2 1 (a)describe the motion shown on the speed time...
TRANSCRIPT
Time (s)
0 1 2 3 4 5 6 7 8 9
speed
(m/s)
4
3
2
1
(a)Describe the motion shown on the speed time graph.
(b)Calculate the acceleration for each part of the graph.
(c) Find the distance travelled in the first 4 seconds.
Time (s)
Velocity
m/s
1 2 3 4 5 6 7 80
1
2
3
-1
-2
-3
(a)Find the acceleration for each part of the graph.
(b)Draw an acceleration time graph
(c) Find the maximum displacement from the start.
(d)Find the final displacement.
Sketch graphs
a
v
t
t
Ball falling from rest – up direction is positive
v
t
In your group sketch a graph showing the motion of a ball which is thrown up. Start the instant after the ball leaves your hand. Take up as positive.
Now do tutorial questions 27 to 32
SAQ to Qu 24
2010 Higher paper Qu 1,2
Purple book Ex 1.2
Notes:
All red lines have same gradient – (on Earth this will be – 9.8 m/s2 as this is acceleration due to gravity).
Above the time axis the ball is moving upwards, below it is moving downwards
0
+
-
Equations of motion
Third year v = d ÷ t no acceleration
Fourth year a = (v – u) ÷ t uniform acceleration
distance = area under speed time graph
Advanced Higher - accelerations which are not uniform
- very fast speeds, relativity
Higher v = u + at uniform acceleration
s = ut + ½ at2
v2 = u2 + 2as
v = ½( u + v)
displacement = area under velocity time graph
Deriving Equations of motion
tt
v
u
v
t – time taken u - initial velocity
v – final velocity a – acceleration
s - displacement
Acceleration = gradient of graph
a = v – u so v = u + at equation 1
t
Displacement = area under the graph
s = ut + ½(v – u)t but v = u + at so (v – u) = (u + at – u) = at
s = ut +½at2 equation 2
Displacement = area under the graph
s = ut + ½(v – u)t = ut + ½vt -½ut
s = ½(u + v)To eliminate t v = u + at so t = ( v – u ) ÷ a
s = ½ ( u + v ) t
= ½ (u + v )( v – u ) ÷ a
2as = ( u + v ) ( v – u )
2as = uv – u2 + v2 – uv
2as = - u2 + v2
v2 = u2 + 2as equation 3
Note you are unlikely to be asked to derive this equation.
Examples
1. A car travelling at 20 m/s accelerates uniformly at 0.5 m/s2 until it is travelling at 30 m/s. Calculate the distance travelled by the car during this time.
2. A toy rocket is launched vertically and reaches a height of 60 m. What was its launch speed?
Now try tutorial questions 33 to 36
Qu 37 a challenge, there is more than one way to reach the same answer. Which do you find easier
Qu 39 to 42
Always check on signs + - + - + -
Up to SAQ 36
Purple book Chp 1.3
Projectiles
The only force which acts on a projectile is the force due to gravity ( weight)
v
v
We need to resolve the velocity into its horizontal and vertical components
t
vH
t
vv
Horizontal velocity Vertical velocity
Down
+ ve
No force in horizontal direction so constant velocity
Weight acts downward so accelerates at 9.8 m/s2
down
ExampleA car travelling with a horizontal speed of 20 m/s goes off the top of a cliff. It lands 30 m from the foot of the cliff (i) How high was the cliff? (ii) What was the car’s velocity just before it hit the ground ?
Tutorial questions 43 to 46
SAQs up to 39
Purple book Ex 1.4
Extra questionsatillite
ExampleA basket ball player throws the ball at 600 to the horizontal and scores a basket. The foot of the basket was 12m away. If the ball takes 2s to reach the basket find:-
(a) The initial speed of the ball.(b) The height of the basket above the initial position
of the ball.
Tutorial Qu 47 to 50
SAQ up to 41
Purple book Ex 1.5
Estimate your take off velocity in a standing long jump.
Step 1 Vertical jump Measure maximum vertical displacement, svCalculate initial vertical velocity, uv and then the
time for jump, t.
Step 2 standing long jumpsh maximum horizontal distanceassume you stay in the air for the same length of
time as your vertical jump ie uv and t will be the same as step 1.Calculate the horizontal velocity, vH
Step 3 calculate take off velocity from uv and uH
Do you think the assumption in step 2 is justified?If not, is the calculated value for horizontal velocity too big or too small?The world record for the standing long jump is 3.71 m