A ball is tossed straight up and later returns to the point trom which it was launched the ball is subject to ar resistance as well as gravity, which of the following statements is correct The speed at which the ball returns to the point of launch is less than its speed when it was initially launched The time for the ball to fall is the same as the time for the ball to rise The force of air resistance is directed downward botly when the ball istising and when it is falling The net work done by air resistance on the ball during its flight is zero E The net work done by gravity on the ball during its fight is greater than zero

Answers

Answer 1

The correct statement is: The force of air resistance is directed downward both when the ball is rising and when it is falling. When a ball is tossed straight up and later returns to its point of launch, it experiences the force of gravity pulling it downward throughout its entire trajectory.

Additionally, air resistance acts on the ball in the opposite direction of its motion, regardless of whether it is rising or falling. This means that the force of air resistance is directed downward both when the ball is rising and when it is falling. The other statements are not necessarily correct: The speed at which the ball returns to the point of launch may or may not be less than its speed when initially launched, depending on factors such as air resistance and the efficiency of energy conversion. The time for the ball to fall is generally longer than the time for the ball to rise due to the influence of air resistance. The net work done by air resistance on the ball during its flight is not zero, as air resistance opposes the ball's motion and dissipates some of its energy. The net work done by gravity on the ball during its flight depends on the trajectory and the change in potential energy. In some cases, it may be zero or negative, depending on the direction of motion.

To learn more about force, https://brainly.com/question/30507236

#SPJ11


Related Questions

does temperature affet how high a ball bounces?

Answers

Yes, temperature affects how high a ball bounces. Temperature has a significant impact on the bouncing behavior of a ball.

When a ball bounces, it compresses upon contact with the surface, storing potential energy. This potential energy is then converted into kinetic energy as the ball rebounds. However, temperature affects the elasticity of the ball's material, which in turn affects its ability to store and release energy during a bounce.

At lower temperatures, the material of the ball becomes stiffer and less elastic. As a result, it is less capable of compressing and deforming upon impact, leading to a reduced amount of potential energy being stored. Consequently, the ball will not rebound as high as it would at higher temperatures. Conversely, at higher temperatures, the material of the ball becomes more elastic and pliable. This allows it to compress more upon impact, storing a greater amount of potential energy. As a result, the ball will rebound higher compared to when it is at lower temperatures.

In conclusion, temperature affects the elasticity of the ball's material, which directly influences how high it bounces. Lower temperatures result in reduced elasticity and lower rebound heights, while higher temperatures lead to increased elasticity and higher rebound heights.

To learn more about temperature refer:

https://brainly.com/question/26866637

#SPJ11

A certain transverse wave is described by the following equation.
y(x, t) =(6.30 mm) cos2π(x/31.0 cm -t/0.0320 s)
(a) Determine the wave's amplitude.
1
mm
(b) Determine the wave's wavelength.
2
cm
(c) Determine the wave's frequency.
3
Hz
(d) Determine the wave's speed of propagation.
4
m/s
(e) Determine the wave's direction of propagation.
+x -x +y -y

Answers

(a)The amplitude of the wave is 6.30 mm

(b)The wavelength is 3.09 × 10⁵ m

(c)The frequency is 9.70 × 10⁶ Hz

(d)The speed of propagation is 3.00 × 10⁸ m/s

(e)The wave is propagating in the +x direction

Given equation for the wave

y(x, t) = (6.30 mm) cos2π(x/31.0 cm -t/0.0320 s)

The wave equation is,

y(x, t) = A sin(2π/λ (x - vt))

Here,

A = amplitude of wave

λ = wavelength

v = velocity of the wave

Comparing this with the given equation we get,

A = 6.30 mm

ω =  2πv/λ

We know that

v = λ f

v = 1/ T

v = λ / T

Substituting the given values,

v = λ / T

λ = vT

so,

ω = 2π f = 2π / T

Substituting the given values,

ω = 2π (31 cm) / (0.0320 s)

   = 6.14 × 10³ rad/s

Now,

T = 1 / (ω/2π)

T = 1 / (6.14 × 10³ / 2π)

T = 1.03 × 10⁻³ s

λ = vT

  = (3 × 10⁸ m/s) (1.03 × 10⁻³ s)

  = 3.09 × 10⁵ m

The wave speed is,

v = λ / T

v = (3.09 × 10⁵ m) / (1.03 × 10⁻³ s)

  = 3.00 × 10⁸ m/s

Therefore,

the amplitude of the wave is 6.30 mm,

the wavelength is 3.09 × 10⁵ m,

the frequency is 9.70 × 10⁶ Hz,

the speed of propagation is 3.00 × 10⁸ m/s.

The wave is propagating in the +x direction.

Learn more about the amplitude:

brainly.com/question/21632362

#SPJ11

a circular room with radius of 10 feet is to have a rectangular rug placed on floor

Answers

A rectangular rug with dimensions 20 feet by 20 feet would cover the floor of a circular room with a radius of 10 feet.

To determine the dimensions of the rectangular rug that would cover the circular room's floor, we need to find the length and width of the rectangle. The diameter of the circular room is twice the radius, so it would be 20 feet. Since the diameter of the circle is also the diagonal of the rectangle, we can use the diagonal length as the length of the rectangle. Using the Pythagorean theorem, we can calculate the diagonal length of the rectangle as the square root of the sum of the squares of the length and width. Given that the radius is 10 feet, the length and width of the rectangle should be equal to cover the entire floor. Thus, the length and width of the rectangular rug would be 20 feet, ensuring that it fully covers the circular room's floor.

To learn more about rectangular rug, Click here:

https://brainly.com/question/12085425

#SPJ11

In the elastic head-on collision, particle a with energy Ea. collides with a stationary particle b. Assume ma ≠ mb. (a) show that in the CM frame, the 4-vector p ini total = pa.+pb!" is a time-like 4-vector, i.e., ini ini Ptotal. Ptotal < 0

Answers

In the elastic head-on collision, the 4-vector of the total initial momentum, P_ini_total = p_a + p_b, is a time-like 4-vector in the center-of-momentum (CM) frame, i.e., P_ini_total² < 0.

To show that P_ini_total is a time-like 4-vector, we need to demonstrate that its magnitude squared, P_ini_total², is negative.

In the CM frame, the total initial momentum 4-vector, P_ini_total, can be expressed as the sum of the individual particle 4-vectors:

P_ini_total = p_a + p_b,

where p_a and p_b are the 4-vectors of particles a and b, respectively.

The energy-momentum 4-vector of a particle with mass m and energy E can be written as:

p = (E, p_x, p_y, p_z),

where p_x, p_y, and p_z are the components of momentum in the x, y, and z directions, respectively.

For particle a, with energy E_a, its 4-vector is:

p_a = (E_a, p_a_x, p_a_y, p_a_z).

Since particle b is initially at rest (stationary), its 4-vector is:

p_b = (m_b, 0, 0, 0),

where m_b is the mass of particle b.

Now, let's calculate the magnitude squared of P_ini_total:

P_ini_total² = (p_a + p_b)².

Expanding the square, we have:

P_ini_total² = (E_a + m_b)² - (p_a_x)² - (p_a_y)² - (p_a_z)².

Since we are considering an elastic collision, the energies, and momenta are conserved, which means E_a = E_b and p_a_x = -p_b_x, p_a_y = -p_b_y, p_a_z = -p_b_z (where E_b and p_b are the energy and momentum of particle b after the collision).

Substituting these relations into the expression for P_ini_total², we get:

P_ini_total² = (E_a + m_b)² - (p_a_x)² - (p_a_y)² - (p_a_z)²,

= (E_a + m_b)² - (p_a_x)² - (p_a_y)² - (p_a_z)²,

= (E_a + m_b)² - (p_a_x)² - (p_a_y)² - (p_a_z)²,

= E_a² + 2E_a m_b + m_b² - p_a_x² - p_a_y² - p_a_z²,

= E_a² + 2E_a m_b + m_b² - p_a².

Since we have conservation of energy and momentum, E_a = E_b and p_a = p_b, we can simplify further:

P_ini_total² = E_a² + 2E_a m_b + m_b² - p_a²,

= (E_a + m_b)² - p_a².

Now, consider that in a collision, the total energy is always greater than or equal to the rest mass energy, i.e., E_a + m_b ≥ m_a + m_b = E_rest_total, where m_a and E_rest_total are the mass and rest energy of the system before the collision, respectively.

Therefore, we have:

P_ini_total² = (E_a + m_b)² - p_a²,

≥ E_rest_total² - p_a²,

≥ (m_a + m_b)² - p_a²,

≥ m_a² + 2m_a m_b + m_b² - p_a²,

= (m_a + m_b)² - p_a²,

= E_rest_total² - p_a²,

> 0.

Thus, we conclude that P_ini_total² > 0, which means P_ini_total is a time-like 4-vector in the CM frame.

In the elastic head-on collision between particles a and b, where ma ≠ mb, the 4-vector of the total initial momentum, P_ini_total = p_a + p_b, is a time-like 4-vector in the CM frame, as shown by the calculation.

To learn more about momentum, visit    

https://brainly.com/question/402617

#SPJ11

In simple harmonic motion, when does the velocity have a maximum magnitude? a. when the magnitude of the acceleration is a minimum b. when the magnitude of the acceleration is a maximum c. when the displacement is a maximum d. when the potential energy is a maximum

Answers

Answer:

C

Explanation:

In simple harmonic motion, the velocity has a maximum magnitude when the displacement is zero.

In simple harmonic motion, the motion of an object is described by a sinusoidal function. The equation of motion for simple harmonic motion is given by:

x(t) = A * cos(ωt + φ)

where:

x(t) is the displacement of the object at time t,

A is the amplitude of the motion,

ω is the angular frequency, and

φ is the phase angle.

The velocity of the object is the derivative of the displacement with respect to time:

v(t) = dx/dt = -A * ω * sin(ωt + φ)

To find the maximum magnitude of the velocity, we need to determine when the absolute value of the velocity is at its maximum.

Since the sine function oscillates between -1 and 1, the maximum magnitude of the velocity occurs when the absolute value of sin(ωt + φ) is equal to 1.

From the equation of velocity, we can see that the magnitude of the velocity is maximum when sin(ωt + φ) is equal to 1.

This happens when ωt + φ is equal to ±π/2 or ±3π/2, which corresponds to the displacement being zero. Therefore, the answer is:

a. when the magnitude of the acceleration is a minimum

To know more about velocity visit:

https://brainly.com/question/20885248

#SPJ11

which of the following statements are true for photometric stereo? explain your reasoning in at most two sentences for the false statements.
(a) The first step in photometric stereo is computing normalized cross correlation. (b) Photometric stereo involves solving a set of quadratic equations. (c) Photometric stereo assumes that the surface being reconstructed is Lambertian. (d) Getting the depth from photometric stereo requires the assumption that the surface is continuous. (e) We need at least 9 different lighting directions to solve for photometric stereo. (f) Painting a surface white decreases its albedo

Answers

True statements for photometric stereo are: (c) Photometric stereo assumes that surface reconstructed is Lambertian. (d) Getting  depth from photometric stereo requires  assumption that surface is continuous.

(a) False. The first step in photometric stereo is typically capturing multiple images of the same subject under different lighting conditions, not computing normalized cross-correlation.

(b) False. Photometric stereo involves solving a set of linear equations, not quadratic equations.

(c) True. Photometric stereo assumes that the surface being reconstructed has Lambertian reflectance, meaning the surface reflects light uniformly in all directions.

(d) True. To estimate the depth from photometric stereo, the method assumes that the surface is continuous and does not have abrupt discontinuities.

(e) False. While having more lighting directions can improve the accuracy and robustness of the reconstruction, it is possible to perform photometric stereo with fewer than 9 lighting directions.

False. Painting a surface white increases its albedo, which is the measure of how much light it reflects. Increasing the albedo can make it easier to capture accurate photometric measurements.

The true statements for photometric stereo are that it assumes the surface being reconstructed is Lambertian (c) and getting the depth requires the assumption of surface continuity (d). The other statements are false and explained accordingly.

To know  more about  Lambertian visit:

https://brainly.com/question/29434481

#SPJ11

wire 2 is twice the length and twice the diameter of wire 1. what is the ratio r 2/r 1 of their resistances? quickcheck 27.10 a. 1/4 b. 1/2 c. 1 d. 2 e. 4

Answers

The ratio of r 2/r 1 of their resistances is 4.

So, the correct answer is E.

Let the resistivity of wire 1 be r 1, and resistivity of wire 2 be r 2. Let the length and diameter of wire 1 be l and d respectively.

Thus, length and diameter of wire 2 will be 2l and 2d respectively.

Thus, r ∝ (l/A).

The cross-sectional area of wire 1 is πd²/4.The cross-sectional area of wire 2 is π(2d)²/4 = πd².

Since r ∝ (l/A), we have:

r 1/r 2 = (l1/d²)/(l2/d²) = (l1/l2) = 1/2

Thus, the ratio of the resistances is:

r 2/r 1 = r 2/r 1 = 2/(1/2) = 4.

Hence, the answer is E.

Learn more about resistance at:

https://brainly.com/question/12025720

#SPJ11

In drawing arrows to represent energy transitions, which of the following statements are correct?
a) For emission, the arrow points down.
b) The head of the arrow is drawn on the final state.
c) It doesn't matter which direction you draw the arrow as long as it connects the initial and final states.
d) For absorption, the arrow points up.
e) The tail of the arrow is drawn on the initial state.

Answers

The correct statements regarding drawing arrows to represent energy transitions are a) For emission, the arrow points down, and e) The tail of the arrow is drawn on the initial state.

In energy diagrams or transitions, arrows are commonly used to represent the flow of energy. The direction and placement of the arrowheads and tails convey important information about the nature of the transition.

For emission, where energy is released or emitted from a system, the arrow is drawn pointing down. This signifies the downward movement of energy from a higher energy state to a lower energy state. The head of the arrow is placed on the final state, indicating the energy has been transferred to that state.

On the other hand, for absorption, where energy is absorbed by a system, the arrow is drawn pointing up. This represents the upward movement of energy from a lower energy state to a higher energy state. The tail of the arrow is placed on the initial state, indicating that the energy is being taken up by that state.

It is important to note that the direction and placement of the arrowheads and tails carry specific meanings and are not arbitrary. They provide a clear visual representation of the energy flow and help in understanding the directionality of energy transitions.

Learn more about  emission here:

https://brainly.com/question/14457310

#SPJ11

A wave passes through an opening in a barrier.

The amount of diffraction experienced by the

wave depends on the size of the opening and the

wave’s

(1) amplitude (3) velocity

(2) wavelength (4) phase

Answers

When a wave passes through an opening in a barrier, the wave's properties, such as its wavelength and phase, can be affected. The wave's wavelength and phase can affect the way the wave behaves as it passes through the opening.

A wave's wavelength is the distance between two consecutive crests or troughs in the wave. The wavelength of a wave passing through an opening in a barrier can be affected by the size of the opening. If the opening is smaller than the wavelength of the wave, then the wave will diffract around the edges of the opening and spread out. If the opening is larger than the wavelength of the wave, then the wave will pass through the opening without much diffraction.The phase of a wave is the position of a crest or trough in the wave relative to a fixed point. The phase of a wave passing through an opening in a barrier can also be affected by the size of the opening. If the opening is smaller than the wavelength of the wave, then the wave will diffract around the edges of the opening and the phase of the wave will be affected. If the opening is larger than the wavelength of the wave, then the phase of the wave will not be affected.In conclusion, when a wave passes through an opening in a barrier, the wave's wavelength and phase can be affected by the size of the opening. If the opening is smaller than the wavelength of the wave, then the wave will diffract around the edges of the opening and spread out. If the opening is larger than the wavelength of the wave, then the wave will pass through the opening without much diffraction, and the phase of the wave will not be affected.

For such more question on wavelength

https://brainly.com/question/24452579

#SPJ8

A wave passes through an opening in a barrier. The amount of diffraction experienced by the wave depends on the size of the opening and the wave’s wavelength.The amount of diffraction experienced by a wave when it passes through an opening in a barrier depends on the size of the opening and the wavelength of the wave.

The diffraction of a wave is the bending of the wave when it passes through an opening or around an obstacle. The smaller the opening, the greater the diffraction. The greater the wavelength of the wave, the greater the diffraction. The amount of diffraction experienced by a wave can be calculated using the diffraction equation. The diffraction equation states that the amount of diffraction is directly proportional to the size of the opening and the wavelength of the wave.

If the opening is small and the wavelength is large, the amount of diffraction will be significant. Conversely, if the opening is large and the wavelength is small, the amount of diffraction will be minimal.

To know more about wavelength visit :

https://brainly.com/question/31143857

#SPJ11

A motorcycle daredevil is attempting to jump from one ramp onto another. The takeoff ramp makes an angle of 18.0o above the horizontal, and the landing ramp is identical. The cyclist leaves the ramp with a speed of 33.5 m/s. What is the maximum distance that the landing ramp can be placed from the takeoff ramp so that the cyclist still lands on it?

Answers

Therefore, the maximum distance that the landing ramp can be placed from the takeoff ramp so that the cyclist still lands on it is 75.5 m. Hence, option C is correct.

We have to find the maximum distance that the landing ramp can be placed from the takeoff ramp so that the cyclist still lands on it, given that a motorcycle daredevil is attempting to jump from one ramp onto another. The takeoff ramp makes an angle of 18.00 above the horizontal, and the landing ramp is identical. The cyclist leaves the ramp with a speed of 33.5 m/s.

Let's begin with the solution:

Consider the diagram shown below:

Here, AB = Take off ramp, BC = Landing rampθ = 18.0°, Speed of the cyclist, u = 33.5 m/s

It is given that the landing ramp is identical to the takeoff ramp.

So, the angle between the ramp and horizontal is also θ = 18.0°.

The vertical and horizontal components of velocity at point A are given by:

v_y = u sin θ and v_x = u cos θ

The time of flight of the cyclist from A to C is given by:

t = [2v_y] / g Where g is the acceleration due to gravity= 9.81 m/s²

The horizontal distance covered by the cyclist in the time of flight is given by:

x = v_x t …..(1)

The height of the landing ramp (point C) from the ground is given by:

y = BC sin θ …..(2)

The cyclist has to land on the landing ramp (point C).

Therefore, the height of the landing ramp must be equal to the height at which the cyclist leaves the takeoff ramp (point A).

Therefore, from the diagram shown above, we have:

y = AB sin θ …..(3)

From (2) and (3), we have:

AB sin θ = BC sin θ

Or

AB = BC ... (identical ramps)

From equation (1),

we have:

x = v_x

t= u cos θ [2v_y / g]... (4)

Substituting the values of u, θ, v_y and g,

we get:

x = [33.5 m/s] cos 18.0° [2 (33.5 sin 18.0°) / 9.81 m/s²]= 75.5 m (approximately)

to know more about velocity visit:

https://brainly.com/question/30559316

#SPJ11

Your friend says goodbye to you and walks off at an angle of 47° north of east. If you want to walk in a direction orthogonal to his path, what angle, measured in degrees north of west, should you walk in?

Answers

You should walk at an angle of 43° north of west in order to move in a direction orthogonal to your friend's path.

What is orthogonal?

"Orthogonal" refers to a mathematical concept that describes a relationship or arrangement that is perpendicular or at a right angle to each other. In a geometric sense, two lines or vectors are orthogonal if they meet at a 90-degree angle or form a right angle.

If your friend is walking off at an angle of 47° north of east, to walk in a direction orthogonal (perpendicular) to his path, you should walk in a direction orthogonal to the east direction, which is towards the north.

The angle you should walk can be found by subtracting 90° from the angle your friend is walking. Since your friend is walking 47° north of east, the angle you should walk would be:

90° - 47° = 43°

Therefore, you should walk at an angle of 43° north of west in order to move in a direction orthogonal to your friend's path.

To learn about orthogonal,

https://brainly.com/question/30772550

#SPJ4

Three point charges are placed an equal distance from each other asshown:
+q
-q -q
Draw the electric field and equipotential lines for the figure.

Answers

In the configuration you described, with three point charges placed an equal distance from each other, the electric field lines and equipotential lines would look as follows:

Electric Field Lines: The positive charge (+q) will have electric field lines radiating outwards, away from the charge. The negative charges (-q) will have electric field lines pointing towards them. The electric field lines will spread out from the positive charge and converge towards the negative charges. The electric field lines will be symmetric around the central line connecting the charges. Equipotential Lines: The equipotential lines will be perpendicular to the electric field lines. They will form concentric circles around the positive charge. The equipotential lines will be closer together near the positive charge and farther apart as you move away from it. The negative charges will also have concentric equipotential lines, but they will be closer together and have a smaller radius compared to the positive charge. Please keep in mind that the actual configuration of the electric field and equipotential lines will depend on the magnitudes and relative positions of the charges. The description provided is based on the assumption that the charges are equal in magnitude and placed equidistant from each other.

To learn more about charges, https://brainly.com/question/13871705

#SPJ11

A what frequency will a 20 mH inductor have an inductive reactance of 100 ohms?
a) 457.4 Hz
b) 225.4 Hz
c) 795.7 Hz
d) 654.8 Hz
e) none of the answers

Answers

The correct option for the frequency at which a 20 mH inductor will have an inductive reactance of 100 ohms is the option b) 225.4 Hz.

We can calculate the frequency of an inductor with a given inductance and inductive reactance using the formula given below;

f = (Xl/2πL)

Where,

f = frequency in Hertz

L = inductance in Henry

Xl = inductive reactance in Ohm

Given,

Inductance L = 20 mH = 20 x 10^-3 Henry Inductive

reactance Xl = 100 ohms

Substituting the given values in the above formula,

f = (Xl/2πL)f

= (100 / (2 x π x 20 x 10^-3))f

= (100 / 0.1257)Frequency,

f = 795.69 Hz (approx)

Therefore, the correct option for the frequency at which a 20 mH inductor will have an inductive reactance of 100 ohms is the option b) 225.4 Hz.

To know more about  inductive reactance refer to:

https://brainly.com/question/32092284

#SPJ11

Answer the following questions based on your observations in the lab only. Explain and justify your answers to each. a. How many types of charge are there? b. Could there be other type of charge? (1) Make a table as described in A7 and A8 illustrating how additional charges might interact with those you found.

Answers

a. There are two types of charge: positive and negative.

b. Based on observations in the lab, there is no evidence to suggest the existence of any other type of charge.

a. In the lab, based on our observations and experiments, we can determine that there are two types of charge: positive and negative. This is evident from the interactions between charged objects, such as the attraction between opposite charges and the repulsion between like charges. The existence of these two types of charge is fundamental to the understanding of electromagnetism and is supported by extensive experimental evidence.

b. Based on our observations in the lab, there is no indication or evidence to suggest the existence of any other type of charge beyond positive and negative. Our experiments consistently demonstrate the behavior and interaction of positive and negative charges, and no additional types of charge have been observed or measured.

To illustrate how additional charges might interact with the charges we found, we can create a table similar to the one described in A7 and A8. However, since there is no evidence or knowledge about any other type of charge, the table would remain hypothetical and speculative. Without experimental data or observations to support the existence of other charges, any interactions or behaviors attributed to them would be purely speculative and not based on empirical evidence.

Based on our observations in the lab, there are two types of charge: positive and negative. No evidence or observations suggest the existence of any other type of charge. While we can create a hypothetical table to explore potential interactions with additional charges, it would be speculative without experimental evidence. The understanding and explanation of electrical phenomena rely on the two established types of charge, and further investigations would be needed to explore the possibility of any new types of charge.

To know more about charge, visit

https://brainly.com/question/25923373

#SPJ11

pulling up on a rope, you lift a 7.92-kg bucket of water from a well with an acceleration of 1.20 m/s2. part a what is the tension in the rope?

Answers

The tension in the rope when lifting a 7.92 kg bucket of water with an acceleration of 1.20 m/s^2 is 96.84 N.

To find the tension in the rope, we need to consider the forces acting on the bucket of water. We have the weight of the bucket acting downwards, which is given by the equation:

Weight = mass * acceleration due to gravity

Weight = 7.92 kg * 9.8 m/s^2 (acceleration due to gravity)

Weight = 77.616 N

Since we are lifting the bucket with an acceleration of 1.20 m/s^2, we need to apply an additional force to overcome the gravitational force. This additional force is provided by the tension in the rope.

Using Newton's second law, we can calculate the tension:

Tension = mass * acceleration

Tension = 7.92 kg * 1.20 m/s^2

Tension = 9.504 N

Therefore, the tension in the rope is 96.84 N.

This tension is necessary to overcome the gravitational force acting on the bucket and provide the additional force required to lift it with the given acceleration.

To know more about Tension, visit

https://brainly.com/question/24994188

#SPJ11

how long would it take to purge a 10-mm section of a 20-cm diameter pipe using a flow rate of 17 l/min?

Answers

Therefore, it would take approximately 0.59 minutes or 35.3 seconds to purge a 10-mm section of a 20-cm diameter pipe using a flow rate of 17 l/min.

To determine how long it would take to purge a 10-mm section of a 20-cm diameter pipe using a flow rate of 17 l/min,

we can use the formula:

time = (length of section to be purged) / (flow rate)

Let's first convert the diameter of the pipe from centimeters to millimeters:

20 cm = 200 mm.

Now we can use the formula:

time = (10 mm) / (17 L/min)time = 0.58823529412 minutes (rounded to 11 decimal places).

to know more about time visit:

https://brainly.com/question/15356513

#SPJ11

A proton moves 0.10 m along the direction of the electric field of strength 3.0 N/C. The Electric potential difference between the protons initial and ending point is?
A. 4.8E-19 V
B. 0.30V
C. 0.33V
D. 30.0V
So I’m confused on which equation to use to solve this, I thought I could use this formula
Vi-Vf = Ed
Vi-Vf = 3 x .10 = 0.30V
But I also saw a different way to solve this doing
Q x E x d
= 1.6E-19 x 3 x .10 = 4.8E-20

Answers

The Electric potential difference between the proton's initial and ending point is 0.30V. Substituting the values in the above formula, we get V = Ed= 3 x 0.10= 0.30V.

Explanation: Electric field strength E = 3.0 N/C, The distance moved by proton d = 0.10 m. The charge on the proton q = 1.6 x 10^-19 C, The electric potential difference between the initial and ending points V = ?

We know that potential difference is given by:

V = Ed where E is the electric field strength, and d is the distance moved by the proton in the direction of the electric field.

Therefore, the electric potential difference between the proton's initial and ending point is 0.30V. So, the correct option is B: 0.30V.

to know more about electric field visit:

https://brainly.com/question/30544719

#SPJ11

using ampere’s law, determine the magnitude of the magnetic field:

Answers

∮B⋅dl = μ₀ × I is the formula to know the magnetic field. For a long solenoid it will be B = 2μ₀ n I.

To determine the magnitude of the magnetic field using Ampere's Law, you need additional information such as the current distribution and the geometry of the problem.

Ampere's Law relates the magnetic field along a closed loop to the current passing through that loop and the geometry of the loop.

Ampere's Law states that the line integral of the magnetic field B along a closed loop is equal to the product of the permeability of free space (μ₀) and the total current passing through the loop:

∮B⋅dl = μ₀ × I

Where:

∮ represents the line integral around a closed loop,

B is the magnetic field,

dl is an infinitesimal element along the path of integration,

μ₀ is the permeability of free space (approximately 4π × 10⁻⁷ T·m/A), and

I is the total current enclosed by the loop.

The magnetic field at any point on the axis inside the solenoid is given by:

B = 2μ₀ n I (cosθ₁ + cosθ₂)

where θ₁and θ₂ are the angles made by the line joining the point on the axis and the two ends of the solenoid with respect to the axis .

For a very long solenoid, θ₁= 0 and θ₂ = 90°. Therefore,

B = 2μ₀ n I

To know more about the magnetic field

https://brainly.com/question/14411049

#SPJ4

The complete question is

Write Ampere's circuital law.

Obtain an expression for magnetic field on the axis of current carrying very long solenoid.

At one instant the electric and magnetic fields at one point of an electromagnetic wave are E=(25i + 350j-50k) V/m and B = B0(7.2i-7.0j+ak)?T
A. what is the value of a?
B. what is the value of B0?
C. What is the poynting vector at this time and position? Find the x component? Sx =?
D. Find the y component. Sy=?
E. Find the z component. Sz=?

Answers

At one instant the electric and magnetic fields at one point of an electromagnetic wave are E=(25i + 350j-50k) V/m and B = B0(7.2i-7.0j+ak)?T.  a = -50, B0 = 1.18x10^-6 T, Sx = 4.81x10^-4 W/m^2, Sy = -3.44x10^-4 W/m^2, and Sz = 4.59x10^-4 W/m^2. These components describe the characteristics of the electromagnetic wave at the given time and position.

To determine the values and components of the given electromagnetic wave, we can analyze the provided electric and magnetic fields.

component in both expressions, we can conclude that a = -50

The value of B0 can be obtained by comparing the magnitude of the magnetic field vector B with the known electric field vector E. The relationship between the electric and magnetic fields in an electromagnetic wave is given by E = cB, where c is the speed of light. Comparing the magnitudes, we have |E| = c|B|, and

|E| = √[tex](25^2 + 350^2 + (-50)^2)[/tex] = 353.55 V/m. Since c ≈ [tex]3 x 10^8[/tex]m/s, we can solve for |B| as |B| = |E|/c = [tex]353.55/3 * 10^8 = 1.18 * 10^-6[/tex] T. Therefore, B0 = [tex]1.18x10^-6[/tex] T.

The Poynting vector (S) represents the direction and magnitude of energy flow in an electromagnetic wave. It is given by S = E x B, where x represents the cross product. To find the x-component of the Poynting vector, we can calculate Sx = EyBz – EzBy = (350)(1.18x10^-6) – (-50)(7.2x10^-6) = 4.81x10^-4 W/m^2.

Similarly, we can find the y-component of the Poynting vector as Sy = EzBx – ExBz = (-50)(7.2x10^-6) – (25)(1.18x10^-6) = -3.44x10^-4 W/m^2.

The z-component of the Poynting vector can be calculated as Sz = ExBy – EyBx = (25)(7.2x10^-6) – (350)(1.18x10^-6) = 4.59x10^-4 W/m^2.

In summary, the values obtained are: a = -50, B0 = 1.18x10^-6 T, Sx = 4.81x10^-4 W/m^2, Sy = -3.44x10^-4 W/m^2, and Sz = 4.59x10^-4 W/m^2. These components describe the characteristics of the electromagnetic wave at the given time and position.

Learn more about  magnetic fields here:

https://brainly.com/question/19542022

#SPJ11

What happens to the current supplied by the battery when you add an identical bulb in parallel to the original bulb?(Figure 1) The current stays the same The current doubles. The current is cut in half. The current becomes zero. Submit My Answers Give Up

Answers

When you add an identical bulb in parallel to the original bulb (Figure 1), the total current supplied by the battery increases. In a parallel circuit, each branch provides a separate pathway for current to flow.

Adding an identical bulb in parallel creates an additional path, decreasing the overall resistance in the circuit. According to Ohm's law (I = V/R), with the same voltage (V) and decreased resistance (R), the total current (I) increases.

As a result, the current supplied by the battery doubles when an identical bulb is added in parallel. This is because the current is divided between the two bulbs, with each bulb carrying half of the total current.

To know more about the identical bulb refer here :

https://brainly.com/question/30673650#

#SPJ11

Which of the following is an example of slow mass movement?
A
Landslides
B
Rockslides
C
Slumping
D
Soil creep

Answers

Soil creep is an example of slow mass movement.

Soil creep, also known as creep deformation, refers to the gradual movement or displacement of soil particles downhill or along a slope over time. It is a slow and continuous process that occurs due to the force of gravity acting on the soil mass.

Soil creep is primarily driven by the expansion and contraction of soil particles caused by changes in moisture content and temperature. When the soil gets wet, it swells and expands, causing the particles to move and shift. As the soil dries, it contracts and settles, further contributing to the downslope movement.

The movement in soil creep is usually imperceptible over short periods but becomes more noticeable over longer timescales. It can result in the tilting or bending of trees, fence posts, and other structures on hillslopes.

To know more about slow mass movement here

https://brainly.com/question/1698616

#SPJ4

A 1.5-cm-tall object is 18 cm in front of a concave mirror that has a 70 cm focal length.
A) Calculate the position of the image.
B) Calculate the height of the image.

Answers

(A)The position of the image is -70.005 cm

(B)The height of the image is 5.833 cm

Object height (h) = 1.5 cm

Distance of object from mirror (u) = -18 cm (negative sign indicates that the object is in front of the mirror)

Focal length of concave mirror (f) = -70 cm (negative sign indicates that the mirror is concave)

Mirror formula is,

1/v = 1/f - 1/u

A)

Putting the values in the mirror formula,

1/v = 1/-70 - 1/-18

    = 1/(-70) + 1/18

    = -0.01428

So,

v = -70.005 cm

This negative sign indicates that the image is formed behind the mirror, which means the image is virtual.

B)

The magnification of the mirror is,

Magnification = height of image (h') / height of object (h)

Magnification = -v/u

Putting the values,

Magnification = -(-70.005)/(-18)

                      = 3.889

Thus, the height of the image can be given as,

h' = Magnification × h

  = 3.889 × 1.5

  = 5.833 cm (approx)

Therefore, the position of the image is -70.005 cm and the height of the image is 5.833 cm (approx).

Learn more about the concave mirror:

brainly.com/question/20380620

#SPJ11

earth's atmosphere blocks short wavelengths of the electromagnetic spectrum. which telescopes do not need to be placed in orbit around earth to observe short-length radiation?

Answers

Ground-based telescopes are capable of observing short-wavelength radiation without the need for placement in orbit around Earth.

Telescopes that do not need to be placed in orbit around Earth to observe short-wavelength radiation are ground-based telescopes. These telescopes are located on the surface of the Earth and are designed to observe various wavelengths of the electromagnetic spectrum, including short wavelengths.

Ground-based telescopes can be equipped with instruments and detectors that are sensitive to different ranges of the electromagnetic spectrum. For example, optical telescopes are commonly used to observe visible light, which falls within the short-wavelength range of the spectrum. By using specialized mirrors, lenses, and detectors, ground-based optical telescopes can capture and study visible light from celestial objects.

In addition to optical telescopes, there are also ground-based telescopes designed for observing other regions of the electromagnetic spectrum. For example, radio telescopes can detect and study radio waves, which have much longer wavelengths compared to visible light. These radio telescopes are often large dish antennas that collect radio waves and convert them into signals that can be analyzed.

Unlike space-based telescopes, such as those placed in orbit around Earth, ground-based telescopes do not face the same atmospheric limitations. Although Earth's atmosphere does block some short-wavelength radiation, ground-based telescopes can still observe a wide range of wavelengths by utilizing windows in the atmosphere where transmission is better, or by using specialized techniques to compensate for atmospheric effects.

Therefore, ground-based telescopes are capable of observing short-wavelength radiation without the need for placement in orbit around Earth.

To learn more about telescopes click here

https://brainly.com/question/31634676

#SPJ11

You have two identical capacitors and an external potential source. For related problem-solving tips and strategies, you Compare the total energy stored in the capacitors when they are connected to the applied potential in series and in may want to view a Video Tutor Solution of Transferring charge and energy between capacitors parallel.

Answers

When two identical capacitors are connected to an external potential source, the total energy stored in the capacitors depends on whether they are connected in series or in parallel.

Series Connection: When the capacitors are connected in series, the total capacitance of the combination decreases, and the total energy stored is less compared to individual capacitors. The formula to calculate the total capacitance (C_series) in series is: 1 / C_series = 1 / C1 + 1 / C2. Once you have the total capacitance, you can calculate the total energy stored (E_series) using the formula: E_series = 0.5 * C_series * V^2 where V is the applied potential. Parallel Connection: When the capacitors are connected in parallel, the total capacitance of the combination increases, and the total energy stored is greater compared to individual capacitors. The formula to calculate the total capacitance (C_parallel) in parallel is: C_parallel = C1 + C2. Once you have the total capacitance, you can calculate the total energy stored (E_parallel) using the formula: E_parallel = 0.5 * C_parallel * V^2, where V is the applied potential. By comparing the total energies (E_series and E_parallel) for the given capacitors, you can determine which configuration stores more energy.

To learn more about capacitors, https://brainly.com/question/29835110

#SPJ11

Arrange the following in order of increasing radius: O2-, F- , Ne ,Rb+ ,Br- Rb+ < F- < Br- < O2- < Ne Br- < Rb+ < Ne < F- < O2- Ne < F- < O2- < Rb+ < Br- O2- < F- < Ne < Rb+ < Br- O2- < Br- < F- < Ne < Rb + Br- < F- < O2- < Ne < Rb+ F- < O2- < Ne < Br- < Rb + Rb+ < F- < Br- < Ne

Answers

Radii is a vital feature of the elements, and it can be useful in determining the characteristics of elements in various chemical and physical processes. The radii of atoms and ions of the same element differ due to their various charge and mass characteristics.

Atomic and ionic radii increase as you move down a group on the periodic table, and decrease as you move across a period from left to right due to increased nuclear charge, making the electrons closer to the nucleus. The size of an atom and ion also changes due to the number of electrons charge, and electronic configuration.In order of increasing radius, the arrangement of [tex]Ne, F-, O2-, Br-, Rb[/tex] is given as follows:

[tex]Ne < F- < O2- < Br- < Rb+[/tex]

Rb+ has the smallest radius due to its large nuclear charge and fewer electrons in the valence shell.

As a result, they are larger than Rb+. O2- has more electrons than Ne and is the largest among the given ions and atoms. It is important to note that in certain conditions, the trends in radii may not be valid because of hybridization and other factors. Nonetheless, this arrangement is valid for the given ions and atoms.

To know more about nuclear charge visit :

https://brainly.com/question/18028941

#SPJ11

An infinitely long wire carries a current of I = 185 A.. consider a circle with a radius r and centered on the wire. determine the magnitude of the magnetic field b at points along the circle in terms of i and r.

Answers

The magnitude of the magnetic field (B) at points along the circle, in terms of I and r, is given by:  B = 1.85 × 10⁻⁵ A·m / r.

The magnetic field created by an infinitely long wire carrying a current can be determined using Ampere's law.

Ampere's law states that the line integral of the magnetic field around a closed loop is equal to the product of the current enclosed by the loop and the permeability of free space (μ₀ = 4π × 10⁻⁷ T·m/A).

In this case, the loop is a circle centered on the wire, with radius r. Let's calculate the magnetic field at a point on the circle.

Consider a small section of the circle with length dl. The magnetic field at that point will be perpendicular to dl and the radius vector pointing from the wire to the point.

The magnitude of the magnetic field dB produced by this small section of wire is given by the Biot-Savart law:

dB = (μ₀ / 4π) * (I * dl) / r²

where I is the current, dl is the length element, and r is the distance from the wire to the point.

Since the wire is infinitely long, the contributions from different sections of the wire will cancel out except for those that are equidistant from the center of the wire. As a result, the magnitude of the magnetic field at points along the circle will be constant and given by:

B = (μ₀ / 4π) * (I / r)

Substituting the values, we have:

B = (4π × 10⁻⁷ T·m/A / 4π) * (185 A / r)

B = (10⁻⁷ T·m) * (185 A / r)

B = 1.85 × 10⁻⁵ A·m / r

Therefore, the magnitude of the magnetic field (B) at points along the circle, in terms of I and r, is given by:  B = 1.85 × 10⁻⁵ A·m / r

To learn more about Biot-Savart law visit:

brainly.com/question/13576053

#SPJ11

The enzyme aldolase catalyzes the conversion of fructose-1,6-diphosphate (FDP) to dihydroxyacetone phosphate (DHAP) and glyceraldehyde-3-phosphate (G3P). The reaction is:
FDP ? DHAP + G3P
with ?G0rxn,298 = 23.8 kJ. In red blood cells, the concentrations of these species are [FDP] = 35 ?M, [DHAP] = 130 ?M, and [G3P] = 15 ?M. Calculate ?Grxn in a red blood cell at 25oC. Will the reaction occur spontaneously in the cell?

Answers

The change in standard Gibbs free energy (∆G°) of the reaction FDP → DHAP + G3P in a red blood cell at 25°C is approximately 31.3 kJ.

The change in standard Gibbs free energy (∆G°) of a reaction can be calculated using the equation:

∆G° = -RT ln(K)

Where R is the gas constant (8.314 J/mol·K), T is the temperature in Kelvin (25°C = 298 K), and K is the equilibrium constant of the reaction. In this case, since the reaction is FDP → DHAP + G3P, the equilibrium constant (K) can be calculated using the concentrations of the species:

K = ([DHAP] [G3P]) / [FDP]

Substituting the given concentrations ([FDP] = 35 µM, [DHAP] = 130 µM, [G3P] = 15 µM) into the equation, we can calculate the value of K. Then, by plugging the values of R, T, and K into the equation for ∆G°, we can determine the change in standard Gibbs free energy of the reaction.

If the ∆G° value is negative, it indicates that the reaction is spontaneous in the forward direction. However, in this case, the calculated ∆G° value is positive (approximately 31.3 kJ), indicating that the reaction will not occur spontaneously in the red blood cell. External energy input or coupling with another favorable reaction would be necessary to drive the reaction forward in the cell.

Learn more about Gibbs free energy here:

https://brainly.com/question/13795204

#SPJ11

Determine whether the following are linear operators on R^(nxn). a. L(A) = 2A b. L(A) = A^T c. L(A) = A + I d. L(A) = A - A^T

Answers

L(A) = 2A is a linear operator on R^(nxn).

L(A) = A^T is a linear operator on R^(nxn).

L(A) = A + I is a linear operator on R^(nxn).

L(A) = A - A^T is not a linear operator on R^(nxn).

A linear operator satisfies two properties: additivity and homogeneity. To determine if a function is a linear operator on R^(nxn), we need to check if it satisfies two properties: additivity and homogeneity.

Additivity: A function L is additive if L(A + B) = L(A) + L(B) for any matrices A and B in R^(nxn).

Homogeneity: A function L is homogeneous if L(cA) = cL(A) for any matrix A in R^(nxn) and scalar c.

For part (a), L(A) = 2A is additive and homogeneous:

Additivity: L(A + B) = 2(A + B) = 2A + 2B = L(A) + L(B).

Homogeneity: L(cA) = 2(cA) = c(2A) = cL(A).

For part (b), L(A) = A^T is also additive and homogeneous:

Additivity: L(A + B) = (A + B)^T = A^T + B^T = L(A) + L(B).

Homogeneity: L(cA) = (cA)^T = c(A^T) = cL(A).

For part (c), L(A) = A + I is additive and homogeneous:

Additivity: L(A + B) = (A + B) + I = A + I + B + I = L(A) + L(B).

Homogeneity: L(cA) = (cA) + I = c(A + I) = cL(A).

However, for part (d), L(A) = A - A^T fails the additivity property:

L(A + B) = (A + B) - (A + B)^T

             = (A + B) - (A^T + B^T)

            = A - A^T + B - B^T ≠ L(A) + L(B).

To know more about the Linear operators, here

https://brainly.com/question/31696178

#SPJ4

Why do you think that countries using the metric system prefer the Celsius scale over the Fahrenheit scale? If you decide to travel outside the United States, which one of the two temperature conversion formulas should you take?

Answers

Answer:

Celsius is a reasonable scale that assigns freezing and boiling points of with round numbers, zero and 100 making it easier .This makes it easy to calibrate instruments anywhere in the world.In Fahrenheit, those are, incomprehensibly, 32 and 212

A 1.2 kg ball drops vertically onto afloor, hitting with a speed of 20 m/s.It rebounds with an initial speed of 10 m/s.
(a) What impulse acts on the ball during thecontact?
kg·m/s
(b) If the ball is in contact with the floor for 0.020 s, what is the average force exerted on thefloor?
N

Answers

The impulse acting on the ball during the contact is -12 kg·m/s, indicating a change in momentum in the opposite direction. The average force exerted on the floor is 600 N, calculated using the impulse-momentum theorem.

(a) Impulse is defined as the change in momentum of an object. Since momentum is a vector quantity, impulse is also a vector quantity. The impulse acting on the ball can be calculated using the equation:

Impulse = Change in momentum

The initial momentum of the ball is given by the product of its mass and initial velocity:

Initial momentum = mass * initial velocity = 1.2 kg * 20 m/s = 24 kg·m/s

The final momentum of the ball is given by the product of its mass and final velocity:

Final momentum = mass * final velocity = 1.2 kg * (-10 m/s) = -12 kg·m/s

Therefore, the change in momentum is:

Change in momentum = Final momentum - Initial momentum = -12 kg·m/s - 24 kg·m/s = -36 kg·m/s

Hence, the impulse acting on the ball during the contact is -36 kg·m/s.

(b) The average force exerted on the floor can be determined using the impulse-momentum theorem, which states that the impulse acting on an object is equal to the average force applied to the object multiplied by the time of contact. Mathematically, this can be expressed as:

Impulse = Average force * Time

Rearranging the equation, we can solve for the average force:

Average force = Impulse / Time

Substituting the values given, we have:

Average force = -36 kg·m/s / 0.020 s = -1800 N

The negative sign indicates that the force is acting in the opposite direction. Taking the magnitude, the average force exerted on the floor is 1800 N.

Learn more about impulse-momentum theorem here:

https://brainly.com/question/14121529

#SPJ11

Other Questions
Which of the following bonds has the MOST reinvestment risk? a. 7-year bonds with a 7% coupon b. 10-year bonds with a 8% coupon c. 15-year zero coupon bonds d. 2-year bonds with an 20% coupon Describe how oral traditions, proverbs, and music are key features of Africa's cultural legacy. ==================================================================Even if you spam the question or just use it for points GodBless you!! : 3 A consumer group surveyed the prices for white cotton extra-long twin sheet sets in five different department stores and reported the average price as $16 with standard deviation $3.81. Assume that the population is normal and has a standard deviation equal to $3.81. 9. Provide a 95% confidence interval in order to estimate the average price of the white cotton extra-long twin sheets. z* is 1.96 Suppose Mary is willing to sell her house for as little as $350,000. Suppose Jeff is willing to pay as much as $410,000 for Mary's house. If they agree on a price of $390,000, what is Mary's producer surplus and Jeff's consumer surplus? Shauna runs the sub shop in town. She recently changed some things, where one employee will take the orders and payments, another assembles the subs, and a third packages them. Before these changes, e choose the answer that is written correctly and has a correct capitalization and punctuation The triangle has a height of 8 and a base of 14.What is the area of the triangle? Assume, on Jan 1, 20X5 P purchased equipment for $40,000 and sold it immediately to S for $100080 cash. The equipment is expected to be obsolete in 10 years. What is the value for Equipment on Consolidated Statement of Financial Position as at Dec 31, 20X6? A ray of light passes from air into water, striking the surface of the water with an angle of incidence of 45. Which of the following four quantities change as the light enters the water: (1) wavelength, (2) frequency, (3) speed of propagation, and (4) direction of propagation?a) 1 and 2 onlyb) 2, 3, and 4 onlyc) 1, 3, and 4 onlyd) 3 and 4 onlye) 1, 2, 3, and 4 A math equation. :!!!!! Enzymes are composed of what organic molecule? a. sugarsb. DNAc. proteinsd. lipids the higher the objects " ? ", the more kinetic energy solve the differential equation by variation of parameters, subject to the initial conditions y(0) = 1, y'(0) = 0. y'' 2y' 8y = 3e3x ex Determine whether the logic used in each question is inductive reasoning or deductive reasoning.a) Everyone in the Family Madrigal has a special gift. Luisa is in the Family Madrigal. Therefore, Luisa has a special gift.b) Every dog I have seen is covered in fur. Barky is a dog. Therefore, Barky is covered in fur. 13=X/4A. 13/4B. 4/13C. 52D. 9 Read this excerpt from The People Could FlyThere was a son named Anton. He dreamed that a girl placed a handkerchief over his face. He woke up but he saw no one. Anton told his mother what he had dreamed. His mother said, "Anton, you've dreamed of something enchanted."A few days later Anton dreamed the dream again and it was exactly the same: A girl placed a handkerchief over his face."Anton," his mother said, "you dream of a girl who lives with her father in the tower of the moon."How does the plot influence characterization in this excerpt?The exposition introduces Anton as a fortune teller.The exposition introduces Antons mother as a fanciful woman.The rising action shows Anton facing the challenges of finding the tower.The rising action shows Antons mother reacting to Antons travels. Jena is a full-time undergraduate student at State University and qualifies as a dependent of her parents. Her only source of income is a $10,000 athletic scholarship ($1,000, books; $5,500, tuition; $500, student activity fee; and $3,000, room and board). Jena's gross income for the year is: a.$3,000. b.$4,000. c.$500. d.$10,000. Reconstruction failed to establish racial equality and black freedom. Explain how the rapid industrialization of the United States under the system of "free labor" in the years after the Civil War led to a social crisis by the end of the nineteenth century in which the traditional American values of democracy, equality, and opportunity seemed to be disappearing, and in which class conflict threatened to tear society apart. How did the capitalists and working classes attempt to enhance their own power and interests in their struggle with each other? Why was the working class unable to achieve much, despite valiant efforts? How did the middle-class respond to the struggle between labor and capital as well as the changes that American society underwent during the late nineteenth century? Factor 16a + 10. (Please help) Two experiments are performed on an object to determine how much the object resists a change in its state of motion while at rest and while in motion. In the first experiment, the object is pushed with a constant known force along a horizontal surface. There is negligible friction between the surface and the object. A motion sensor is used to measure the speed of the object as it is pushed. In a second experiment, the object is tied to a string and pulled upward with a constant known force, and a motion sensor is used to measure the speed of the object as it is pulled upward. The student uses the data collected from the motion sensor to determine the mass of the object in both experiments. Required: What classifies the type of mass that was determined in each experiment?