A computer-controlled ball launcher on a ledge at height h = 8 m above level ground ejects a ball at initial speed v_sub_0 = 8.2 m/s at an angle of θ_sub_1 = 35 degrees above the horizontal. The computer then commands the launcher to change its launch angle to a specific value θ_sub_2 below the horizontal, and to launch a second ball exactly 1.00 seconds after the first ball at a different speed from the first one. Assume the balls are launched from the same height, move in the same plane, and that air resistance can be ignored. The launch of the second ball is arranged such that the second ball collides with the first ball at a height h/2 above the level ground. This requires the second ball to have a specific initial speed and launch angle. What is the required initial speed?

Answer:

20,000 Ns

Explanation:

mass of exhaust gases, m = 50 kg

velocity of exhaust gases, v = 400 m/s

The momentum of a body is defined as the measurement of motion of body. mathematically, it is defined as the product of mass off the body an its velocity.

change in momentum of rocket = final momentum - initial momentum

                                                     =  m x v - 0

                                                     = 50 x 400

                                                     = 20,000 Ns

Final answer:

The change in momentum of the rocket (also known as impulse) during the blast is 20,000 kg·m/s. This is calculated by multiplying the mass of the exhaust gas (50 kg) by its average velocity (400 m/s).

Explanation:

The change in momentum of the rocket during the blast (also known as impulse) can be calculated using the conservation of momentum. The momentum of the exhaust gas expelled will be equal in magnitude and opposite in direction to the change in momentum of the rocket.

To calculate the change in momentum of the rocket, we use the formula:

Change in momentum = mass of exhaust × velocity of exhaust.

In this case, the mass of the exhaust gas is 50 kg, and the average velocity at which it is expelled is 400 m/s:

Change in momentum = 50 kg × 400 m/s = 20000 kg·m/s.

This is the momentum gained by the rocket in the opposite direction, due to Newton's third law of motion.

Answer:

a) At times t = 2 s and t = 6 s, the projectile will be at a height of 192 ft.

b) The projectile will return to the ground at t = 8 s.  

Explanation:

a) The height of the projectile is given by this equation:

s = -16·t² + 128 f/s·t  (see attached figure)

If the height is 192 ft, then:

192 ft = 16·t² + 128 ft/s· t

0 = -16·t² + 128 ft/s·t - 192 ft

Solving the quadratic equation:

t = 2 and t = 6

At times t = 2 s and t = 6 s, the projectile will be at a height of 192 ft.

b) When the projectile return to the ground, s = 0. Then:

0 = -16·t² + 128 ft/s·t

0 =t(-16·t + 128 ft/s)

t = 0 is the initial point, when the projectile is launched.

-16·t + 128 ft/s = 0

t = -128 ft/s / -16 ft/s² = 8 s

The projectile will return to the ground at t = 8 s.  

Answer:

(a) Area = [tex]83.022m^2[/tex] (b)  Area = [tex]9.07m^2[/tex]

Explanation:

We have given radius of the circle r = 5.142 m and r = 1.7 m

We have to find the area of the circle

We know that area of the circle is given  by

[tex]A=\pi r^2[/tex], here r is the radius of the circle

(a) Radius = 5.142 m

So area [tex]A=\pi r^2=3.14\times 5.142^2=83.022m^2[/tex]

(b) Radius = 1.7 m

So area [tex]A=\pi r^2=3.14\times 1.7^2=9.07m^2[/tex]

Answer:

Explanation:

Magnetic field B = 6 X 10⁻⁵ T.

Width of car = L (Let )

Velocity of car v  = 100 km/h

= 27.78 m /s

induced emf across the body ( width )  of the car

= BLv

= 6 X 10⁻⁵ L X 27.78

166.68 X 10⁻⁵ L

Induced electric field across the width

= emf induced / L

E =  166.68 X 10⁻⁵ N/C

We suppose breadth of a typical car = 1.5 m

potential difference induced

= 166.68 x 1.5 x 10⁻⁵

250 x 10⁻⁵ V

= 2.5 milli volt.

The side of the car which is positively charged depends on the direction in which car is moving , whether it is moving towards the north or south.

Answer:

Yes! They can be correct

Explanation:

An isolated system is a system where its total energy and mass stay constant.

In this case, even though the volume changed, the mass remains constant (m = 1 kg), so there is no mass exchange, and we must think that the globe is completely closed.

Now, we don't know exactly what happens with energy, but I can give you an example where the total energy of the globe remains constant.

Imagine that the balloon of volume [tex]V_1[/tex] is at a certain height [tex]h_1[/tex], under some pressure, [tex]P_1[/tex]. If you lower the balloon to a height [tex]h_2[/tex], the pressure increases, and from the Boyle's law,

[tex]P_1 V_1 = P_2 V_2[/tex],

[tex]V_2 = V_1 \frac{P_1}{P_2}[/tex], where [tex]P_2 > P_1[/tex],

[tex]V_2 < V_1[/tex], just like the case you state, and there was no exchange of mass or energy related to the inner gas of the balloon, so yes, They can be correct.

Answer:

[tex]F=(3i+3.6j)\ N[/tex]

Explanation:

It is given that,

Mass of the puck, m = 4.8 kg

Initial velocity of the puck, [tex]u=(1i+0j)\ m/s[/tex]

After 8 seconds, final velocity of the puck, [tex]v=(6i+6j)\ m/s[/tex]

Let the x and y component of force is given by [tex]F_x\ and\ F_y[/tex].

x component of force is given by :

[tex]F_x=m\times \dfrac{v-u}{t}[/tex]

[tex]F_x=4.8\times \dfrac{6-1}{8}[/tex]

[tex]F_x=3\ N[/tex]

y component of force is given by :

[tex]F_y=m\times \dfrac{v-u}{t}[/tex]

[tex]F_y=4.8\times \dfrac{6-0}{8}[/tex]

[tex]F_y=3.6\ N[/tex]

So, the component of the force is [tex]F=(3i+3.6j)\ N[/tex]. Hence, this is the required solution.

The components of the force exerted by the rocket engine on the puck are calculated using Newton's Second Law. The acceleration in each direction (X and Y) is determined by dividing the change in velocity by the change in time. The force is then found by multiplying the mass of the puck by the acceleration, resulting in a force of 3.00î N in the X direction and 3.60ĵ N in the Y direction.

The physics behind this problem involves the concept of Newton's Second Law of motion, which states that force equals mass times acceleration (F=ma). To solve this problem, we'll need to find the change in velocity and divide it by the change in time to determine the acceleration. Then, we'll use Newton's Second Law to find the force.

The initial velocity of the puck is 1.00î m/s and the final velocity is (6.00î + 6.0ĵ) m/s. Therefore, the change in velocity (final - initial) in the X direction is 5î m/s and in the Y direction is 6ĵ m/s. The time duration for this change is 8 seconds. So, the acceleration (change in velocity divided by time) is 5/8 = 0.625î m/s² in the X-direction and 6/8=0.75ĵ m/s² in the Y-direction.

Finally, using Newton's Second Law (F=ma), we can find the force in each direction by multiplying the mass of the puck (4.80 kg) by the acceleration. This results in a force of 0.625 * 4.80 = 3.00 N in the X direction (3.00î N) and 0.75 * 4.80 = 3.60 N in the Y direction (3.60ĵ N).

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Answer:

A) The car will hit the barrier

b) 19.82 m/s

Explanation:

t = Time taken

u = Initial velocity

v = Final velocity

s = Displacement

a = Acceleration

Distance = Speed × Time

⇒Distance = (75/3.6)×0.6

⇒Distance = 12.5 m

Distance traveled by the car during the reaction time is 12.5 m

Equation of motion

[tex]v^2-u^2=2as\\\Rightarrow s=\frac{v^2-u^2}{2a}\\\Rightarrow s=\frac{0^2-\frac{75}{3.6}^2}{2\times -8.5}\\\Rightarrow s=25.53\ m[/tex]

Total distance traveled is 12.5+25.53 = 38.03 m

So, the car will hit the barrier

Distance = Speed × Time

⇒d = u0.6

[tex]v^2-u^2=2as\\\Rightarrow s=\frac{v^2-u^2}{2a}\\\Rightarrow s=\frac{0^2-u^2}{2\times -8.5}\\\Rightarrow s=\frac{u^2}{17}[/tex]

d + s = 35

[tex]\\\Rightarrow u0.6+\frac{u^2}{17}=35\\\Rightarrow \frac{u^2}{17}+0.6u-35=0[/tex]

[tex]10u^2+102u-5950=0\\\Rightarrow u=\frac{-51+\sqrt{62101}}{10},\:u=-\frac{51+\sqrt{62101}}{10}\\\Rightarrow u=19.82, -30.02[/tex]

Hence, the maximum velocity by which the car could be moving and not hit the barrier 35 meters ahead is 19.82 m/s.

Answer:

Wave number, [tex]k=20\ m^{-1}[/tex]

Explanation:

The given equation of wave is :

[tex]y=0.02\ sin(20x-400t)[/tex]............(1)

The general equation of the wave is given by :

[tex]y=A\ sin(kx-\omega t)[/tex]..............(2)

k is the wave number of the wave

[tex]\omega[/tex] is the angular frequency

On comparing equation (1) and (2) :

[tex]k=20\ m^{-1}[/tex]

[tex]\omega=400\ rad[/tex]

So, the wave number of the wave is [tex]20\ m^{-1}[/tex]. Hence, this is the required solution.

Answer:

-600 J

Explanation:

F₁ = 8i +29 j + 32k

F₂ = 48 i - 59 j - 22 k

F = F₁ +F₂ = 8i +29 j + 32k +48 i - 59 j - 22 k

F = 56i - 30 j + 10 k

displacement d = ( 0 - 20 )i + ( 0 - 15 )j + ( 7 -0) k

d = - 20 i - 15 j + 7 k  

Work Done = F dot product d

F . d = - 56 x 20 - 30 x - 15 + 10 x 7

=  - 1120 +450 + 70

= -600 J

Explanation:

It is given that,

Height, h = 3.1 m

Initial speed of the rocket, u = 0

Final speed of the rocket, v = 28 m/s

(b) Let a is the acceleration of the rocket. Using the formula as :

[tex]a=\dfrac{v^2-u^2}{2h}[/tex]

[tex]a=\dfrac{(28)^2}{2\times 3.1}[/tex]

[tex]a=126.45\ m/s^2[/tex]

(a) Let t is the time taken to reach by the rocket to reach to a height of h. So,

[tex]t=\dfrac{v-u}{a}[/tex]

[tex]t=\dfrac{28\ m/s}{126.45\ m/s^2}[/tex]

t = 0.22 seconds

(c) At t = 0.1 seconds, height of the rocket is given by :

[tex]h=ut+\dfrac{1}{2}at^2[/tex]

[tex]h=\dfrac{1}{2}\times 126.45\times (0.1)^2[/tex]

h = 0.63 meters

(d) Let v' is the speed of the rocket 0.10 s after launch.

So, [tex]v'=u+at[/tex]

[tex]v'=0+126.45\times 0.1[/tex]

v' = 12.64 m/s

Hence, this is the required solution.

Answer:

Distance traveled by car in 25 L IS 396.15 km

Explanation:

We have given average millage of car = 60 km /gal

Means car travel 60 km in 1 gallon

The amount of gasoline = 25 L

We know that 1 L = 0.2641 gallon

So [tex]25L=25\times 0.2641=6.6025gallon[/tex]

As the car travels 60 km in 1 gallon

So traveled distance by car in 6.6025 gallon of gasoline = 60×6.6025 = 396.15 km

Answer:

a) 1200 kN/m²

b) 1,200,000 kg/ms²

c) 1.2 × 10⁹ kg/km.s²

Explanation:

Given:

Pressure = 1200 kPa

a) 1 Pa = 1 N/m²

thus,

1000 N = 1 kN

1200 kPa = 1200 kN/m²

b)  1 Pa = 1 N/m² =  1 kg/ms²

Thus,

1200 kPa = 1200000 Pa

or

1200000 Pa = 1200000 × 1 kg/ms²

or

= 1,200,000 kg/ms²

c) 1 km = 1000 m

or

1 m = 0.001 Km

thus,

1,200,000 kg/ms² = [tex]\frac{1,200,000}{0.001}\frac{kg}{km.s^2}[/tex]

or

= 1.2 × 10⁹ kg/km.s²

(a) In kN and m units, the pressure is [tex]$\boxed{1200 \text{ kPa}}$[/tex].  (b) In kg, m, and s units, the pressure is [tex]$\boxed{1200 \text{ kg/(m·s}^2\text{)}}.[/tex] (c) In kg, km, and s units, the pressure is [tex]\boxed{1200 \text{ kg/(km·s}^2\text{)}}[/tex].

Explanation and logic of the

To convert pressure from kPa to the required units, we need to understand the relationship between pressure, force, and area. Pressure (P) is defined as the force (F) applied per unit area (A), given by P = F/A.

(a) In the International System of Units (SI), pressure is measured in pascals (Pa), where 1 Pa = 1 N/m². Since 1 kPa = 1000 Pa, and 1 kN = 1000 N, the pressure in kN/m² is numerically the same as in kPa. Therefore, the pressure in the tank is 1200 kN/m².

(b) To express the pressure in base SI units of kg, m, and s, we need to consider that 1 N = 1 kg·m/s². Since 1 kPa = 1 kN/m², and 1 kN = 1000 N, we have:

[tex]\[ 1200 \text{ kPa} = 1200 \times \frac{1000 \text{ kg\·m/s}^2}{1 \text{ m}^2} = 1200 \times 1000 \text{ kg/(m\s}^2\text{)} \][/tex]

(c) To express the pressure in kg, km, and s, we convert the area from m² to km²:

[tex]\[ 1 \text{ m}^2 = \frac{1}{1000 \times 1000} \text{ km}^2 = \frac{1}{1000000} \text{ km}^2 \][/tex]

Thus, the pressure in kg/(km.s²) is:

[tex]\[ 1200 \text{ kPa} = 1200 \times \frac{1000 \text{ kg\·m/s}^2}{\frac{1}{1000000} \text{ km}^2} = 1200 \times 1000000 \text{ kg/(km\·s}^2\text{)} \][/tex]

However, since 1 kPa is equivalent to 1 kN/m², and 1 kN = 1000 N, we can simplify the expression by recognizing that the conversion from m² to km² results in a factor of 1/1000000, which cancels out the factor of 1000 from the conversion of kN to N, leaving us with:

[tex]\[ 1200 \text{ kPa} = 1200 \text{ kg/(km\s}^2\text{)} \][/tex]

Therefore, the pressure in the tank, when expressed in kg/(km·s²), is 1200 kg/(km·s²).

Answer:

a =  1.02834008 m/s2

Explanation:

given  data:

initial velocity u = -1.03 m/s

time t = 2.47 s later

final velocity v = 1.51 m/s

average acceleration is given as a

[tex]a  = \frac{(v - u)}{t}[/tex]

putting all value to get required value of acceleration:

   [tex]= \frac{(1.51 -(- 1.03))}{2.47}[/tex]

   [tex]= \frac{1.51+1.03}{2.47}[/tex]  

   = 1.02834008 m/s2

Answer:

The correct answer is  option 'a': It decreases with increase in altitude

Explanation:

Acceleration due to gravity is the acceleration that a  body is subjected to when it is freely dropped from a height from surface of any planet, ignoring the resistance that the object may face in it's motion such as drag due to any fluid.. The acceleration due to gravity is same for all the objects and is independent of their masses, it only depends on the mass of the planet and the radius of the planet on which the object is dropped. it's values varies with:

1) Depth from surface of planet.

2)Height from surface of planet.

3) Latitude of the object.

Hence it neither is a fundamental quantity nor an universal constant.

The variation of acceleration due to gravity with height can be mathematically written as:

[tex]g(h)=g_{surface}(1-\frac{2h}{R_{planet}})[/tex]

where,

R is the radius of the planet

[tex]g_{surface}[/tex] is value of acceleration due to gravity at surface.

hence we can see that upon increase in altitude the value of 'g' goes on decreasing.

The stone impacts the ground with a speed of approximately [tex]\(17.32 \, \text{m/s}\)[/tex].

To find the impact speed of the stone, we can use the kinematic equation that relates initial velocity [tex](\(v_0\))[/tex], final velocity [tex](\(v\))[/tex], acceleration [tex](\(g\))[/tex], and displacement [tex](\(s\))[/tex]:

[tex]\[v^2 = v_0^2 + 2gs\][/tex]

Where:

- [tex]\(v\)[/tex] is the final velocity (impact speed),

- [tex]\(v_0\)[/tex] is the initial velocity (throwing speed),

- [tex]\(g\)[/tex] is the acceleration due to gravity (9.81 m/s²),

- [tex]\(s\)[/tex] is the displacement (height the stone falls, -18.1 m, as it falls downward).

Substituting the known values:

[tex]\[v^2 = (7.61 \, \text{m/s})^2 + 2 \times (9.81 \, \text{m/s}^2) \times (-18.1 \, \text{m})\][/tex]

[tex]\[v^2 = 58.0321 - 2 \times 9.81 \times 18.1\][/tex]

[tex]\[v^2 \approx 58.0321 - 357.801\][/tex]

[tex]\[v^2 \approx -299.7689\][/tex]

Since the stone is impacting the ground, we consider the positive root:

[tex]\[v \approx \sqrt{299.7689}\][/tex]

[tex]\[v \approx 17.32 \, \text{m/s}\][/tex]

Therefore, the stone impacts the ground with a speed of approximately [tex]\(17.32 \, \text{m/s}\)[/tex].

Answer:

Part a)

[tex]d = 21\sqrt2 = 29.7 m[/tex]

Part b)

Direction is 45 degree North of West

Part c)

[tex]v_{avg} = 1.41 m/s[/tex]

Part d)

direction of velocity will be 45 Degree North of West

Part e)

[tex]a = 0.875 m/s^2[/tex]

Part f)

[tex]\theta = 45 degree[/tex] North of East

Explanation:

Initial position of the cyclist is given as

[tex]r_1 = 21.0 m[/tex] due East

final position of the cyclist after t = 21.0 s

[tex]r_2 = 21.0 m[/tex] due North

Part a)

for displacement we can find the change in the position of the cyclist

so we have

[tex]d = r_2 - r_1[/tex]

[tex]d = 21\hat j - 21\hat i[/tex]

so magnitude of the displacement is given as

[tex]d = 21\sqrt2 = 29.7 m[/tex]

Part b)

direction of the displacement is given as

[tex]\theta = tan^{-1}\frac{y}{x}[/tex]

[tex]\theta = tan^{-1}\frac{21}{-21}[/tex]

so it is 45 degree North of West

Part c)

For average velocity we know that it is defined as the ratio of displacement and time

so here the magnitude of average velocity is defined as

[tex]v_{avg} = \frac{\Delta x}{t}[/tex]

[tex]v_{avg} = \frac{29.7}{21}[/tex]

[tex]v_{avg} = 1.41 m/s[/tex]

Part d)

As we know that average velocity direction is always same as that of average displacement direction

so here direction of displacement will be 45 Degree North of West

Part e)

Here we also know that initial velocity of the cyclist is 13 m/s due South while after t = 21 s its velocity is 13 m/s due East

So we have

change in velocity of the cyclist is given as

[tex]\Delta v = v_f - v_i[/tex]

[tex]\Delta v = 13\hat i - (-13\hat j)[/tex]

now average acceleration is given as

[tex]a = \frac{\Delta v}{\Delta t}[/tex]

[tex]a = \frac{13\hat i + 13\hat j}{21}[/tex]

so the magnitude of acceleration is given as

[tex]a = \frac{13\sqrt2}{21} = 0.875 m/s^2[/tex]

Part f)

direction of acceleration is given as

[tex]\theta = tan^{-1}\frac{y}{x}[/tex]

[tex]\theta = tan^{-1}\frac{13}{13}[/tex]

[tex]\theta = 45 degree[/tex] North of East

Answer:

Explanation:

Combined mass = 815 + 60 = 875 kg

Net weight acting downwards

= 875 x 9.8

= 8575 N

Tension in the string acting upwards

= 9410

Net upward force = 9410 - 8575

= 835 N

Acceleration

Force / mass

a = 835 / 875

a = .954 ms⁻²

Since the elevator is going up with acceleration a

Total reaction force on the woman from the ground

= m ( g + a )

60 ( 9.8 + .954)

= 645.25 N.

Reading of scale = 645.25 N

Answer:

Answer:

6.68 x 10^16 m/s^2

Explanation:

Electric field, E = 3.8 x 10^5 N/C

charge of electron, q = 1.6 x 10^-19 C

mass of electron, m = 9.1 x 10^-31 kg

Let a be the acceleration of the electron.

The force due to electric field on electron is

F = q E

where q be the charge of electron and E be the electric field

F = 1.6 x 10^-19 x 3.8 x 10^5

F = 6.08 x 10^-14 N

According to Newton's second law

Force  = mass x acceleration

6.08 x 10^-14 = 9.1 x 10^-31 x a

a = 6.68 x 10^16 m/s^2

Explanation:

Answer:

(a). The electric force is 0.9 N.

(b). The acceleration is 0.9 m/s²

Explanation:

Given that,

Mass = 1.0 kg

Distance = 1.0 m

Charge = 10 μC

(a). We need to calculate the electric force

Using formula of electric force

[tex]F = \dfrac{kq_{1}q_{2}}{r^2}[/tex]

Put the value into the formula

[tex]F=\dfrac{9\times10^{9}\times10\times10^{-6}\times10\times10^{-6}}{1.0^2}[/tex]

[tex]F=0.9\ N[/tex]

(b). We need to calculate the acceleration

Using newton's second law

[tex]F = ma[/tex]

[tex]a =\dfrac{F}{m}[/tex]

Put the value into the formula

[tex]a=\dfrac{0.9}{1.0}[/tex]

[tex]a=0.9\ m/s^2[/tex]

Hence, (a). The electric force is 0.9 N.

(b). The acceleration is 0.9 m/s²

By applying Coulomb's law and Newton's second law, we find that the magnitude of the electric force on one of the masses is 0.0899 N and the initial acceleration of one of the masses is 0.0899 m/s^2.

This question pertains to Coulomb's law, which deals with the force between two charges. Coulomb's law states that the force between two charges is directly proportional to the product of their charges and inversely proportional to the square of the distance between them.

The equation used for this law is F = k(q1*q2)/r², where F represents the force, q1 and q2 represent the charges, r represents the distance between the charges and k is Coulomb's constant (8.99 × 10⁹ N×m²/C²).

a) To find the magnitude of the electric force on one of the masses, we would use the Coulomb's law equation: F = k(q1×q2)/r², where q1 and q2 are both +10μC (which need to be converted to C by multiplying by 10⁻⁶), and r is 1.0m. This gives us F = (8.99 × 10⁹ N×m²/C²) × ((10 × 10⁻⁶ C)²) / (1.0m)² = 0.0899 N.

b) To find the initial acceleration of one of the masses, we would use Newton's second law (F = ma), where F is the force (0.0899 N from the previous calculation), m is the mass (1.0 kg), and a is acceleration. So a = F/m = 0.0899 N / 1.0 kg = 0.0899 m/s².

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Answer:

a)8.59 m/s

b)-0.8818 m/s²

Explanation:

a) Given the van moved 40 m in 7.70 seconds to a final velocity of 1.80 m/s

Apply the equation for motion;

[tex]d=(\frac{V_i+V_f}{2} )*t[/tex]

where

t=time the object moved

d=displacement of the object

Vi=initial velocity

Vf=final velocity

Given

t=7.70s

Vf=1.80 m/s

d=40m

Vi=?

Substitute values in equation

[tex]40=(\frac{V_i+1.80}{2} )7.70\\\\\\40=\frac{7.70V_i+13.86}{2} \\\\80=7.70V_i+13.86\\\\80-13.86=7.70V_i\\\\66.14=7.70V_i\\\\\frac{66.14}{7.70} =\frac{7.70V_i}{7.70} \\8.59=V_i[/tex]

b)Acceleration is the rate of change in velocity

Apply the formula

Vf=Vi+at

where;

Vf=final velocity of object

Vi=Initial velocity of the object

a=acceleration

t=time the object moved

Substitute values in equation

Given;

Vf=1.80 m/s

Vi=8.59 m/s

t=7.70 s

a=?

Vf=Vi+at

1.80=8.59+7.70a

1.80-8.59=7.70a

-6.79=7.70a

-6.79/7.70=7.70a/7.70

-0.8818=a

The van was slowing down.

When the brakes are applied to a moving van, it travels a distance of 40.0 m in 7.70 s with a final velocity of 1.80 m/s.

a) The initial speed of the van just before the brakes were applied was 8.59 m/s.  

b) The acceleration of the van while the brakes were applied was -0.88 m/s².  

a) The initial speed of the van can be calculated as follows:

[tex] v_{f} = v_{i} + at [/tex]

Where:  

[tex] v_{f}[/tex]: is the final velocity = 1.80 m/s  

[tex] v_{i}[/tex]: is the initial velocity =?

a: is the acceleration

t: is the time = 7.70 s

By solving the above equation for a we have:

[tex] a = \frac{v_{f} - v_{i}}{t} [/tex]  (1)

Now, we need to use other kinematic equation to find the initial velocity.

[tex] v_{i}^{2} = v_{f}^{2} - 2ad [/tex]   (2)

By entering equation (1) into (2) we have:

[tex] v_{i}^{2} = v_{f}^{2} - 2d(\frac{v_{f} - v_{i}}{t}) = (1.80 m/s)^{2} - 2*40.0 m(\frac{1.80 m/s - v_{i}}{7.70 s}) [/tex]

After solving the above equation for [tex]v_{i}[/tex] we get:

[tex] v_{i} = 8.59 m/s [/tex]

Hence, the initial velocity is 8.59 m/s.

b) The acceleration can be calculated with equation (1):

[tex] a = \frac{v_{f} - v_{i}}{t} = \frac{1.80 m/s - 8.59 m/s}{7.70 s} = -0.88 m/s^{2} [/tex]

Then, the acceleration is -0.88 m/s². The minus sign is because the van is decelerating.      

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Answer:

a) 2.7s

b) 29 m/s

Explanation:

The equation for the velocity  and position of a free fall are the following

[tex]v=v_{0}-gt[/tex] -(1)

[tex]x=x_{0}+v_{0}t-gt^{2}/2[/tex] - (2)

Since the hot-air ballon is descending at 2.1m/s and the camera is dropped at 42 m above the ground:

[tex]v_{0}=-2.1m/s[/tex]

[tex]x_{0}=42m[/tex]

To calculate the time which it takes to reach the ground we use eq(2) with x=0, and look for the positive solution of t:

[tex]t = \frac{1}{84}(2.1\pm\sqrt{2.1^{2} - 4\times42\times9.81/2} )[/tex]

        t = 2.71996

Rounding to two significant figures:

       t = 2.7 s

Now we calculate the velocity the camera had just before it lands using eq(1) with t=2.7s

[tex]v=-2.1-9.81*(2.71996)[/tex]

      v = -28.782 m/s

Rounding to two significant figures:

      v = -29 m/s

where the minus sign indicates the downwards direction

A girl drops a pebble from a high cliff into a lake far below. She sees the splash of the pebble hitting the water [tex]2.00\ s[/tex] later. The pebble was going at a speed of [tex]19.62\ m/s[/tex] when it hit the water.

Use kinematic equations to solve this problem. The pebble is dropped from rest, so its initial velocity is 0 m/s. The time it takes for the pebble to hit the water is given as 2.00 seconds.

The speed of the pebble when it hits the water:

Given:

Initial velocity [tex](v_o) = 0 m/s[/tex]

Time [tex](t) = 2.00\ seconds[/tex]

Acceleration due to gravity [tex](a) = -9.81\ m/s^2[/tex]

Use the kinematic equation:

[tex]v = v_o + a \times t\\v = 0 + (-9.81) \times (2.00)[/tex]

Calculate the numerical value of v:

[tex]v = -19.62\ m/s[/tex]

So, the pebble was going at a speed of [tex]19.62\ m/s[/tex] when it hit the water.

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The pebble was traveling at a speed of 19.6 m/s when it hit the water.

In order to determine the speed at which the pebble hit the water, we can use the equations of motion. Assuming the acceleration due to gravity is 9.8 m/s^2 and neglecting air resistance, we can use the equation:

s = ut + (1/2)at^2

Where s is the distance traveled, u is the initial velocity, t is the time, and a is the acceleration. In this case, the distance traveled is the height of the cliff, the initial velocity is 0 (since the pebble is dropped), t is 2.00 s, and the acceleration is 9.8 m/s^2. Plugging in these values, we can solve for the initial velocity:

s = 0 * (2.00) + (1/2) * 9.8 * (2.00)^2

s = 19.6 m

Therefore, the pebble was traveling at a speed of 19.6 m/s when it hit the water.

Answer:

water

Explanation:

The specific heat of an object denotes the amount of energy which is required to raise the objects temperature by 1 unit of temperature and mass of the object is 1 unit.

If the same amount of heat is added to both water and iron the temperature difference in their final and initial temperatures will be different.

The difference in the initial and final temperature of iron will be higher than that of water. This means that the amount of energy which is required to raise the objects temperature by 1 unit of temperature for iron is lower than water.

So, water has higher specific heat

Also

Q = mcΔT

where

Q = Heat

m = Mass

c = Specific heat

ΔT = Change in temperature

[tex]c=\frac{Q}{m\Delta T}[/tex]

This means specific heat is inversely proportional to change in temperature.

So, for water the change in temperature will be lower than iron which means that water will have a higher specific heat.

Answer with explanation:

The given vectors in are reduced to their componednt form as shown

For vector A it can be written as

[tex]\overrightarrow{v}_{a}=16cos(44^{o})\widehat{i}+16sin(44^{o})\widehat{j}[/tex]

Similarly vector B can be written as

[tex]\overrightarrow{v}_{b}=-13\widehat{i}[/tex]

Hence The sum and difference is calculated as

[tex]\overrightarrow{v}_{a}+\overrightarrow{v}_{b}=16cos(44^{o})\widehat{i}+16sin(44^{o})\widehat{j}+(-13\widehat{i})\\\\\overrightarrow{v}_{a}+\overrightarrow{v}_{b}=(16cos(44^{o})-13)\widehat{i}+16sin(44^{o})\widehat{j}\\\\\therefore \overrightarrow{v}_{a}+\overrightarrow{v}_{b}=-1.49\widehat{i}+11.11\widehat{j}\\\\\therefore |\overrightarrow{v}_{a}+\overrightarrow{v}_{b}|=\sqrt{(-1.49)^{2}+11.11^{2}}=11.21m[/tex]

The direction is given by

[tex]\theta =tan^{-1}\frac{r_{y}}{r_{x}}\\\\\theta =tan^{-1}\frac{11.11}{-1.49}=97.64^{o}[/tex]with positive x axis.

Similarly

[tex]\overrightarrow{v}_{a}-\overrightarrow{v}_{b}=16cos(44^{o})\widehat{i}+16sin(44^{o})\widehat{j}-(-13\widehat{i})\\\\\overrightarrow{v}_{a}-\overrightarrow{v}_{b}=(16cos(44^{o})+13)\widehat{i}+16sin(44^{o})\widehat{j}\\\\\therefore \overrightarrow{v}_{a}-\overrightarrow{v}_{b}=24.51\widehat{i}+11.11\widehat{j}\\\\\therefore |\overrightarrow{v}_{a}-\overrightarrow{v}_{b}|=\sqrt{(24.51)^{2}+11.11^{2}}=26.91m[/tex]

The direction is given by

[tex]\theta =tan^{-1}\frac{r_{y}}{r_{x}}\\\\\theta =tan^{-1}\frac{11.11}{24.51}=24.38^{o}[/tex]with positive x axis.

Answer:

Speed in km/hr will be 109.412 km/hr

Explanation:

We have given speed of the car on a highway = 68 mi/hr

We have to find the speed in km/hr

For this first we have to change mi to km

We know that 1 mile = 1.609 km

Speed is the ratio of distance and time

So 68 mi/hr [tex]=68\times 1.609km/hr=109.412km/hr[/tex]

So the speed in km/hr will be 109.412 km /hr

Answer:

[tex]D_{B}=1173.98m\\D_{C}=675.29m[/tex]

Explanation:

If we express all of the cordinates in their rectangular form we get:

A = (1404.77 , 655.06) m

[tex]B = A + ( -D_{B} *sin(41) , -D_{B} * cos(41) )[/tex]

[tex]C = A + B + ( -D_{C} *cos(20) , D_{C} * sin(20) )[/tex]

Since we need C to be (0,0) we stablish that:

[tex]C = (0,0) = A + B + ( -D_{C} *cos(20) , D_{C} * sin(20) )[/tex]

That way we make an equation system from both X and Y coordinates:

[tex]A_{x} + B_{x} + C_{x} = 0[/tex]

[tex]A_{y} + B_{y} + C_{y} = 0[/tex]

Replacing values:

[tex]1404.77 - D_{B}*sin(41) - D_{C}*cos(20) = 0[/tex]

[tex]655.06 - D_{B}*cos(41) + D_{C}*sin(20) = 0[/tex]

With this system we can solve for both Db and Dc and get the answers to the question:

[tex]D_{B}=1173.98m[/tex]

[tex]D_{C}=675.29m[/tex]

Explanation:

(a) Mass of the cars, m₁ = m₂ = 1160 kg

Distance between cars, d = 35 m

The gravitational force between two cars is given by :

[tex]F=G\dfrac{m_1m_2}{d^2}[/tex]

[tex]F=6.67\times 10^{-11}\times \dfrac{(1160)^2}{(35)^2}[/tex]

[tex]F=7.32\times 10^{-8}\ N[/tex]

So, the force of gravity between the cars is [tex]7.32\times 10^{-8}\ N[/tex].

(b)The weight of a car is given by :

[tex]W=mg[/tex]

[tex]W=1160\times 9.8[/tex]

W = 11368 N

On comparing,

[tex]\dfrac{W}{F}=\dfrac{11368}{7.32\times 10^{-8}}[/tex]

[tex]\dfrac{W}{F}=1.55\times 10^{11}[/tex]

[tex]W=1.55\times 10^{11}\times F[/tex]

So, the weight of the car is [tex]1.55\times 10^{11}[/tex] times the force of gravitation between the cars.

Answer:same

Explanation:

Given

ball A initial velocity=3 m/s(upward)

Ball B initial velocity=3 m/s (downward)

Acceleration on both the balls will be acceleration due to gravity which will be downward in direction

Both acceleration is equal

For ball A

maximum height reached is [tex]h_1=\frac{3^2}{2g}[/tex]

After that it starts to move downwards

thus ball have to travel a distance of h_1+h(building height)

so ball A final velocity when it reaches the ground is

[tex]v_a^2=2g\left ( h_1+h\right )[/tex]

[tex]v_a^2=2g\left ( 0.458+h\right )[/tex]

[tex]v_a=\sqrt{2g\left ( 0.458+h\right )}[/tex]

For ball b

[tex]v_b^2-\left ( 3\right )^2=2g\left ( h\right )[/tex]

[tex]v_b^2=2g\left ( \frac{3^2}{2g}+h\right )[/tex]

[tex]v_b=\sqrt{2g\left ( 0.458+h\right )}[/tex]

thus [tex]v_a=v_b[/tex]

Final answer:

A. The magnitudes of the accelerations of both balls are equal, but they have opposite directions. B. The final speeds of both balls when they reach the ground will be the same.

Explanation:

A. The acceleration of both balls will be the same in magnitude but in opposite directions. Since the acceleration due to gravity acts downward, ball A will have a negative acceleration while ball B will have a positive acceleration. Therefore, the magnitudes of their accelerations will be equal.

B. When both balls reach the ground, their final speeds will also be the same. This is because the vertical motion of the balls is independent of their initial speeds when air resistance is ignored. The time it takes for them to reach the ground will be the same, and hence their final velocities will also be equal.

Answer:

[tex]t=\sqrt{2h/g}-(1/g)*(\sqrt{v_{o}^2+2gh}-v_{o})[/tex]

Explanation:

First person:

[tex]y(t)=y_{o}-v_{o}t-1/2*g*t^{2}[/tex]

[tex]v_{o}=0[/tex]     the rock is dropped

[tex]y_{o}=h[/tex]    

[tex]y(t)=h-1/2*g*t^{2}[/tex]

after t1 seconds it hit the ground, y(t)=0

[tex]0=h-1/2*g*t_{1}^{2}[/tex]

[tex]t_{1}=\sqrt{2h/g}[/tex]

Second person:

[tex]y(t)=y_{o}-v_{o}t-1/2*g*t^{2}[/tex]

[tex]v_{o}[/tex]     the rock has a initial downward speed  

[tex]y_{o}=h[/tex]    

[tex]y(t)=h-v_{o}t-1/2*g*t^{2}[/tex]

after t2 seconds it hit the ground, y(t)=0

[tex]0=h-v_{o}t_{2}-1/2*g*t_{2}^{2}[/tex]

[tex]g*t_{2}^{2}+2v_{o}t_{2}-2h=0[/tex]

[tex]t_{2}=(1/2g)*(-2v_{o}+\sqrt{4v_{o}^2+8gh})[/tex]

the time t when the second person throws the rock after the first person release the rock is:

t=t1-t2

[tex]t=\sqrt{2h/g}-(1/g)*(\sqrt{v_{o}^2+2gh}-v_{o})[/tex]

The solution for the distance x from [tex]\(q_1\)[/tex] along the line connecting the charges where the total electric field is zero is given by: [tex]\[x = \frac{s \cdot (q_1 + q_1\sqrt{q_2})}{q_1 + q_2}\][/tex].

Let's go through the complete solution step by step.

Given:

- Charges: [tex]\(q_1\)[/tex] and [tex]q_2[/tex]

- Distance between charges: s

- Coulomb's constant: [tex]\(k = \frac{1}{4\pi\epsilon_0}\)[/tex]

We want to find the distance (x) from charge [tex]\(q_1\)[/tex] along the line connecting the charges where the total electric field is zero.

The electric field (E) due to a point charge (q) at a distance (r) is given by Coulomb's law:

[tex]\[E = \dfrac{k \cdot q}{r^2}\][/tex]

At a distance x from charge [tex]\(q_1\)[/tex], the electric fields due to [tex]\(q_1\) (\(E_1\))[/tex] and [tex]\(q_2\) (\(E_2\))[/tex] will have magnitudes given by:

[tex]\[E_1 = \dfrac{k \cdot q_1}{x^2}\][/tex]

[tex]\[E_2 = \dfrac{k \cdot q_2}{(s - x)^2}\][/tex]

For the total electric field to be zero, [tex]\(E_1\)[/tex] and [tex]\(E_2\)[/tex] must cancel each other out:

[tex]\[E_1 + E_2 = 0\][/tex]

Substitute the expressions for [tex]\(E_1\)[/tex] and [tex]\(E_2\)[/tex]:

[tex]\[\dfrac{k \cdot q_1}{x^2} + \dfrac{k \cdot q_2}{(s - x)^2} = 0\][/tex]

Cross-multiply and simplify:

[tex]\[q_1 \cdot (s - x)^2 = -q_2 \cdot x^2\][/tex]

Expand and rearrange:

[tex]\[q_1 \cdot (s^2 - 2sx + x^2) = -q_2 \cdot x^2\][/tex]

Solve for x:

[tex]\[q_1 \cdot s^2 - 2q_1 \cdot sx + q_1 \cdot x^2 + q_2 \cdot x^2 = 0\][/tex]

[tex]\[(q_1 + q_2) \cdot x^2 - 2q_1 \cdot sx + q_1 \cdot s^2 = 0\][/tex]

This is a quadratic equation in terms of x. Solve for x using the quadratic formula:

[tex]\[x = \dfrac{-b \pm \sqrt{b^2 - 4ac}}{2a}\][/tex]

Where:

[tex]\(a = q_1 + q_2\)[/tex]

[tex]\(b = -2sq_1\)[/tex]

[tex]\(c = q_1s^2\)[/tex]

Calculate x using the quadratic formula:

[tex]\[x = \dfrac{-(-2sq_1) \pm \sqrt{(-2sq_1)^2 - 4(q_1 + q_2)(q_1s^2)}}{2(q_1 + q_2)}\][/tex]

Simplify the expression inside the square root:

[tex]\[x = \dfrac{2sq_1 \pm \sqrt{4s^2q_1^2 - 4(q_1 + q_2)(q_1s^2)}}{2(q_1 + q_2)}\][/tex]

[tex]\[x = \dfrac{2sq_1 \pm \sqrt{4s^2q_1^2 - 4q_1^2s^2 - 4q_2q_1s^2}}{2(q_1 + q_2)}\][/tex]

[tex]\[x = \dfrac{2sq_1 \pm \sqrt{-4q_2q_1s^2}}{2(q_1 + q_2)}\][/tex]

[tex]\[x = \dfrac{2sq_1 \pm 2q_1s\sqrt{-q_2}}{2(q_1 + q_2)}\][/tex]

[tex]\[x = \dfrac{s \cdot (q_1 \pm q_1\sqrt{-q_2})}{q_1 + q_2}\][/tex]

Since [tex]\(q_1\)[/tex] and [tex]\(q_2\)[/tex] are both positive charges, x will be a positive value.

Thus, the solution for the distance x from [tex]\(q_1\)[/tex] is given by [tex]\[x = \dfrac{s \cdot (q_1 + q_1\sqrt{q_2})}{q_1 + q_2}\][/tex].

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