Use (g= -9.8 m/s/s) What was the average total time of your tossed directly into the air object? The average total time of my object tossed directly into the air object was 0.66 seconds.Question 4:How long does it take for the object to reach the maximum height? How long does it take to go from the maximum height to be caught again? Question 5:What is the final velocity of the object as it returns to the thrower's hand? Use the image labeled 4 attached to solve exactly like the problem for question 4. Use the image labeled 5 to solve question 5, exactly like the problem. 4Throwing Upwards: Break downVf.Time Going Up+ tut = 1.225Givens:x = 1.82m/t = wantupV₁ = 6 m/sOtopa = -9.8 m/s²2Vf=V₁ + at0 = 6 + (-98)t6-5.8= -9.8 t1615 = tupTime Going DownTime total-Time up = time down1.22 0.61 0.61 seconds to comedownFOR ALL Projectiles that have atotal vertical displacement of zero(they launch and land at sameheight)The total time in air is evenly splitbetween the time up, and the timedown.Max height is achieved at half oftotal time(vf - vi)tV = V₁ + atv² = v² + 2ax1x = v₁t + ² at²2• (³₁ +01) ₁t2 5 Throwing Upwards: Final VelocityGoing downGivens:Manx= 1.82morOt = 1.22 or 61V₁ = 6 m/s (5,978)Vf= wanta = -9.8m) 5²V top = 0-V ₂O=V;Vibitslets ignore the going up part, and turnit into a drop problemV₁ = V₁² + atV₁ = gtV₁ = (-9.8) (0.61)V₁ = -5.978 1/5-6~/5VF=-6m/sonly half thestory, use half thetotal time(vy-v₁)= v₁ + atv² = v² + 2ax1Ft +at²x = ("' + 1/²) ₁10

The average total time of flight, T=0.66 sec

se (g= -9.8 m/s/s) What was the average total time of your tossed directly into the air object? The average total time of my object tossed directly into the air object was 0.66 seconds. Question 4: How long does it take for the object to reach the maximum height? How long does it take to go from the maximum height to be caught again? Question 5: What is the final velocity of the object as it returns to the thrower's hand? Use the image labeled 4 attached to solve exactly like the problem for question 4. Use the image labeled 5 to solve question 5, exactly like the problem.

se (g= -9.8 m/s/s) What was the average total time of your tossed directly into the air object? The average total time of my object tossed directly into the air object was 0.66 seconds. Question 4: How long does it take for the object to reach the maximum height? How long does it take to go from the maximum height to be caught again? Question 5: What is the final velocity of the object as it returns to the thrower's hand? Use the image labeled 4 attached to solve exactly like the problem for question 4. Use the image labeled 5 to solve question 5, exactly like the problem.

Question 4:

How long does it take for the object to reach the maximum height? How long does it take to go from the maximum height to be caught again?

Question 5:

What is the final velocity of the object as it returns to the thrower's hand?

Use the image labeled 4 attached to solve exactly like the problem for question 4. Use the image labeled 5 to solve question 5, exactly like the problem.

4
Throwing Upwards: Break down
Vf.
Time Going Up
+ tut = 1.225
Givens:
x = 1.82m/
t = want
up
V₁ = 6 m/s
O
top
a = -9.8 m/s²
2
Vf=V₁ + at
0 = 6 + (-98)t
6
-5.8
= -9.8 t
1615 = tup
Time Going Down
Time total-Time up = time down
1.22 0.61 0.61 seconds to come
down
FOR ALL Projectiles that have a
total vertical displacement of zero
(they launch and land at same
height)
The total time in air is evenly split
between the time up, and the time
down.
Max height is achieved at half of
total time
(vf - vi)
t
V = V₁ + at
v² = v² + 2ax
1
x = v₁t + ² at²
2
• (³₁ +01) ₁
t
2

5 Throwing Upwards: Final Velocity
Going down
Givens:
Man
x= 1.82m
or
O
t = 1.22 or 61
V₁ = 6 m/s (5,978)
Vf= want
a = -9.8m) 5²
V top = 0-V ₂
O=V;
Vi
bits
lets ignore the going up part, and turn
it into a drop problem
V₁ = V₁² + at
V₁ = gt
V₁ = (-9.8) (0.61)
V₁ = -5.978 1/5
-6~/5
VF=-6m/s
only half the
story, use half the
total time
(vy-v₁)
= v₁ + at
v² = v² + 2ax
1
Ft +
at²
x = ("' + 1/²) ₁
10

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Use (g= -9.8 m/s/s) What was the average total time of your tossed directly into the air object? The average total time of my object tossed directly into the air object was 0.66 seconds. 2. What was the initial velocity of the object as it left the thrower's hand? (Use the image attached to solve this replacing the time with 0.66 seconds). 3. What was the maximum height reached above the thrower's hand?
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