Neʻe hāʻule manuahi - nā pilikia a me nā hoʻonā
1. A stone free fall from the height of 45 meters. If the ka wikiwiki ma muli o ka umekaumaha is 10 ms-2, what is the speed of the stone when hits the ground?
ʻIke ʻia:
Kiʻekiʻe (h) = 45 mika
Ka wikiwiki ma muli o ke koʻikoʻi (g) = 10 m/s2
Makemake ʻia: The final velocity of the stone when it hits the ground (vt)
Lōlā:
ʻO ke kaulike o neʻe hāʻule manuahi :
vt2 = 2 gh
The final velocity of the stone :
vt2 = 2 (10)(45) = 900
vt = √900 = 30 m/s2
2. An object free fall from a height without the initial velocity. The object hits the ground 2 seconds later. Acceleration due to gravity is 10 ms-2. Determine height
ʻIke ʻia:
Ka manawa (t) = 2 kekona
Ka wikiwiki ma muli o ke koʻikoʻi (g) = 10 m/s2
Makemake ʻia: kiʻekiʻe (h)
Lōlā:
The equation of the free fall motion :
h = ½ gt2
Maikaʻi:
h = ½ (10)(2)2 = (5)(4) = 20 mika
3.A 2-kg object free fall from a height of 20 meters above the ground. What is the time interval the object in air ? Acceleration due to gravity is 10 ms-2
ʻIke ʻia:
Kiʻekiʻe (h) = 20 mika
Ka wikiwiki ma muli o ke koʻikoʻi (g) = 10 m/s2
makemake : Ka wā manawa (t)
Lōlā:
The equation of free fall motion :
h = ½ gt2
Ka wā ma waena:
20 = ½ (10)(t2)
20 = (5)(t2)
20/5 = t2
4 = t2
t = √4
t = 2 kekona
4. Two objects, object 1 and object 2, are free fall from a height of h1 a me h2 at the same time. If h1 :h2 = 2: 1, what is the ratio of the time interval of the object 1 to the object 2.
ʻIke ʻia:
The height of the object 1 (h1) = 2
The height of the object 2 (h2) = 1
Acceleration due to gravity = g
Makemake ʻia: t1 : t2
Lōlā:
Object 1 :
h1 = 1/2 g t12
2 = 1/2 g t12
(2)(2) = g t12
4 = g t12
4/g = t12
t1 = √4/g
Object 2 :
h2 = 1/2 g t22
1 = 1/2 g t22
(2)(1) = g t22
2 = g t22
2/g = t22
t2 = √2/g
The ratio of the time interval :
t1 : t2
√4/g : √2/g
(√4/g)2 : (√2/g)2
4/g : 2/g
4: 2
2: 1
5. An object dropped from a height of h above the ground. The final velocity when object hits the ground is 10 m/s. What is the time interval to reach ½ h above the ground. Acceleration due to gravity is 10 m/s2.
ʻIke ʻia:
The final velocity (vt) = 10 m/s
Ka wikiwiki ma muli o ke koʻikoʻi (g) = 10 m/s2
Makemake ʻia: The time interval to reach 1/2 h above the ground
Lōlā:
The height of h :
vt2 = 2 gh
102 = 2 (10) h
100 = 20 hola
h = 100 / 20
h = 5 mika
The height of 1/2 h = 1/2 (5 meters) = 2.5 meters. The time interval needed to reach 2.5 meters above the ground :
h = 1/2 g t2
2.5 = 1/2 (10) t2
2.5 = 5 t2
t2 = 2.5 / 5 = 0.5 = (0.25)(2)
t = √(0.25)(2) = 0.5√2 = 1/2 √2 seconds
6.

The free fall motion of coconut (ke kiʻi 1) and the motion of a ball thrown vertically uphale to the highest point by a student (figure 2). Determine the ʻano nā ka nois.

Lōlā:
Figure 1 = neʻe hāʻule manuahi = Acceleration
Figure 2 = vertical motion = Deceleration
ʻO ka pane pololei ʻo A.
7. A stone free fall from a building. The time interval needed by a stone to reach the ground is 3 seconds and acceleration due to gravity is 10 m/s2. Determine the height of the building.
A. 15 m
B. 20 m
C. 30 m
D. 45 m
ʻIke ʻia:
Ka manawa (t) = 3 kekona
Ka wikiwiki ma muli o ke koʻikoʻi (g) = 10 ms-2
Makemake: Height of building (h)
Lōlā:
Known: time interval (t) and acceleration due to gravity (g), wanted: height (h) so use the equation of free fall motion: h = ½ g t2
h = ½ (10)(3)
h = (5)(3)
h = 15 metes
ʻO ka pane pololei ʻo A.
8. A fruit free fall from its tree at the height of 12 m above the ground. If acceleration due to gravity is g = 10 m/s2 and the friction of air ignored, then determine the height of the fruit above the ground after 1 second.
A. 7 m
B. 6 m
C. 5 m
D. 4 m
ʻIke ʻia:
Height of tree (h) = 12 meters
Ka wikiwiki ma muli o ke koʻikoʻi (g) = 10 m/s2
Time interval (t) = 1 second
Makemake: The height of the fruit above the ground
Lōlā:
After 1 second, fruit free fall as far as :
h = ½ gt2 = ½ (10)(1)2 = (5)(1) = 5 mika
The height of the fruit above the ground after 1 second :
12 meters – 5 meters = 7 meters
ʻO ka pane pololei ʻo A.
- What is free fall motion?
pane: Free fall motion refers to the motion of an object under the influence of gravitational force only, with no other forces (like air resistance) acting on it.
- How does the acceleration due to gravity, often represented as , affect a freely falling object?
pane: All objects in free fall near the surface of the Earth experience a constant acceleration due to gravity, , ka mea ma kahi o downward. This means that the object’s velocity increases by this amount for each second of free fall.
- If air resistance is negligible, how does the mass of an object influence its free fall acceleration?
pane: In the absence of air resistance, the mass of an object does not influence its free fall acceleration. All objects, regardless of their mass, will fall with the same acceleration due to gravity, .
- Why do astronauts appear to float inside the International Space Station (ISS) if gravity is still present there?
pane: Astronauts inside the ISS appear to float not because there’s no gravity, but because both the astronauts and the ISS are in a continuous state of free fall around the Earth. They’re essentially falling at the same rate as the ISS, creating a sensation of weightlessness.
- What is the difference between weight and mass in the context of free fall?
pane: Mass is a measure of the amount of matter in an object and remains constant regardless of its location. Weight, on the other hand, is the force exerted on an object due to gravity. It varies depending on the gravitational field. During free fall, an object feels weightless because there’s no normal force acting on it, but its mass remains unchanged.
- If an object is thrown upwards, what happens to its velocity as it rises? And what happens when it starts falling back down?
pane: When an object is thrown upwards, it decelerates under the influence of gravity. Its velocity decreases until it becomes zero at its highest point. As it starts falling back down, it accelerates due to gravity, increasing its velocity in the downward direction.
- What is terminal velocity in the context of free fall?
pane: Terminal velocity is the constant maximum velocity reached by a falling object when the downward force of gravity is balanced by the upward force of air resistance. At this point, the object no longer accelerates and continues to fall at a constant speed.
- How does the height from which an object falls influence the time it takes to reach the ground?
pane: The time it takes for an object to reach the ground is proportional to the square root of the height from which it falls (assuming no air resistance). An object dropped from a greater height will take longer to reach the ground than one dropped from a shorter height.
- What happens to the potential energy of an object as it falls freely under gravity?
pane: As an object falls freely under gravity, its potential energy (relative to the ground) decreases. This decrease in potential energy is converted into kinetic energy, causing the object’s speed to increase.
- If two objects of different shapes but the same mass are dropped from the same height in a vacuum, which will hit the ground first?
pane: In a vacuum, where there’s no air resistance, both objects will hit the ground at the same time. Their shape won’t matter because only gravity is acting on them, and their masses are the same.