according to the rules of continuity, if you are following a subject moving through space and the subject exits screen right (the right of the screen) where should he enter the next shot?

When standing on a scale in an elevator, if one notices an increase in their weight, it means that: the elevator is accelerating upwards.

This is due to the fact that the scale underfoot has to counter the upward acceleration of the elevator, which causes the weight measured on the scale to increase. The scale measures the normal force, which is the weight being exerted on the scale, which is equal to the mass of the individual multiplied by the gravitational acceleration on the surface of the earth.

This can be represented by the formula: W = mg,

where W is the weight, m is the mass of the object and g is the gravitational acceleration.

When the elevator is stationary or moving at a constant velocity, the gravitational acceleration is the same as the normal force and the weight of the individual remains constant. However, when the elevator begins to accelerate upwards, the normal force exerted by the scale must increase to counter the upward acceleration of the elevator.

This causes an increase in weight measured on the scale. Therefore, if one notices an increase in their weight while standing on a scale in an elevator, it indicates that the elevator is accelerating upwards.

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The speed of the cart is 4.0 m/s.

step by step explanation:

Force F is 10-N,

Distance d is 8.0-m, and

Mass m is 20-kg,

A constant 10-N horizontal force is applied to a 20-kg cart at rest on a level floor.

If friction is negligible, then the speed of the cart when it has been pushed 8.0 m can be calculated using the equation v = Fd/m,

where v is the speed of the cart,

F is the applied force,

d is the distance, and

m is the mass of the cart.

so the speed of the cart is v = (10 N × 8.0 m) / 20 kg = 4.0 m/s.

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The speed of the shark after it swallows the fish is calculated using the conservation of momentum principle. The total momentum before the collision is 5 kg * 1 m/s + 1 kg * 4 m/s = 9 kg * m/s. The total momentum after the collision is 5 kg * v, where v is the speed of the shark after the collision. Therefore, v = 9/5 m/s = 1.8 m/s. Thus, the speed of the shark after it swallows the fish is 1.8 m/s.

The speed of the shark after it has swallowed the 1-kg fish swimming toward it at 4 m/s is 3 m/s. This can be determined by conservation of momentum. Momentum is a vector quantity, meaning that the direction of the momentum must also be taken into account.

In this situation, the momentum of the shark before it swallows the fish is 5 kg⋅m/s due to its velocity of 1 m/s. After the shark has eaten the fish, the momentum is 6 kg⋅m/s due to the addition of the fish's momentum of 4 kg⋅m/s. Since momentum is conserved, the momentum of the shark after eating the fish is the same as the momentum of the shark before eating the fish. Since the mass of the shark does not change, the velocity must change to balance out the difference in momentum. This means that the velocity of the shark after eating the fish is 3 m/s.

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Most of the mass of the solar system is located in the Sun. The Sun accounts for over 99% of the total mass of the solar system, with the remaining mass distributed among the planets, asteroids, comets, and other objects.

The solar system is a collection of objects that orbit around the Sun. It consists of the Sun, eight planets and their natural satellites, dwarf planets, asteroids, comets, and other small bodies. The eight planets, listed in order from the Sun, are Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, and Neptune.

The Sun is at the center of the solar system and contains more than 99% of the mass of the solar system. It is a giant ball of gas, mostly hydrogen, and helium, and is the source of heat and light for the entire solar system.

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A front is the line separating two contiguous air masses. Two air masses having differing characteristics, such as temperature, humidity, and density, collide and interact in a small area known as a front.

Cold fronts, warm fronts, stationary fronts, and occluded fronts are the four primary types of fronts. As a cold front enters a region, it pushes the warm air mass out of the way, resulting in a sharp drop in temperature and frequently severe weather. On the other hand, when a warm front approaches a region, it forces the cold air mass out of the way, causing the air to gradually warm up and increasing the likelihood of rain or drizzle. When two weak air masses collide, stationary fronts develop. enough to push the other out of the way, resulting in a stationary boundary between them. Occluded fronts occur when a cold front overtakes a warm front, lifting the warm air mass above the ground and forming a new boundary between the cold air behind the cold front and the cool air ahead of the warm front.

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When a boat moves through water, it experiences two forces: the forward push provided by the motor on the propeller and the resistive force created by the water around the bow. The acceleration of the 1193 kg boat is 0.404 m/s².

The net force acting on the boat can be calculated by subtracting the resistive force from the forward force:

F_net = F_forward - F_resistiveF_net = 2103 N - 1586 NF_net = 517 N

The acceleration of the boat can be calculated using the formula: a = F_net/m Where F_net is the net force acting on the boat, and m is the mass of the boat. Substituting the values we know, a = 517 N / 1193 kg a = 0.404 m/s²Therefore, the acceleration of the 1193 kg boat is 0.404 m/s².

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Gravitational field near the surface of Mercury is approximately 3.7 N/kg

Gravitational field near the surface of Venus is approximately 8.87 N/kg.

Gravitational field near the surface of Mercury and Venus, we can use the formula:

gravitational field (g) = (G * M) / R^2

where G is the gravitational constant (6.67430 × 10^(-11) m^3 kg^(-1) s^(-2)), M is the mass of the planet, and R is the radius of the planet.

For Mercury:
M = 3.29E23 kg
R = 2.44E6 m

g = (6.67430 × 10^(-11) m^3 kg^(-1) s^(-2) * 3.29E23 kg) / (2.44E6 m)^2
g ≈ 3.7 N/kg

For Venus:
M = 4.87E24 kg
R = 6.05E6 m

g = (6.67430 × 10^(-11) m^3 kg^(-1) s^(-2) * 4.87E24 kg) / (6.05E6 m)^2
g ≈ 8.87 N/kg

So, the gravitational field near the surface of Mercury is approximately 3.7 N/kg, and the gravitational field near the surface of Venus is approximately 8.87 N/kg.

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Light intensity will be approximately 0.0796 eV/s*m2

The intensity of radiation (I) at a distance (r) from a point source of power (P) is given by the inverse-square law:

I = P / (4πr²)

where π is the mathematical constant pi (approximately 3.14159).

Assuming the radiation is in the form of photons with energy E, the light intensity in eV/s*m² can be calculated as follows:

Convert the power P into units of energy/time, where time is measured in seconds:

P = E × N,

where N is the number of photons emitted per second by the source.

Substitute P into the formula for intensity and solve for I:

I = E × N / (4πr²)

Express I in eV/s*m² by dividing by the elementary charge (e):

I (in eV/s*m²) = (E × N / e) / (4πr²)

Assuming a monochromatic source of light with energy E = 1 eV, the number of photons emitted per second N can be calculated from the power of the source using the formula:

N = P / E

Let's assume that the light source has a power of 1 watt (1 J/s), then N = 1 eV/s.

Substituting the values into the formula for intensity, we get:

I = (1 eV/s) / (4π × (1 m)²) = 0.0796 eV/s*m²

Therefore, the light intensity in eV/sm² at a distance of 1 m from a monochromatic source of light with energy E = 1 eV and power 1 watt is approximately 0.0796 eV/sm².

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The potential energy of a toolbox weighing 5 newtons is zero.

The potential energy of a toolbox weighing 5 newtons depends on its height relative to the ground.

Potential energy (PE) is equal to the mass of the object (m) multiplied by the acceleration due to gravity (g) multiplied by its height (h): PE = mgh.

Therefore, the potential energy of the toolbox is equal to 5*9.8*h (where h is the height of the toolbox above the ground).

Assuming that the toolbox is resting on the ground, it has zero potential energy since its height is zero. If the toolbox is lifted above the ground, however, then it will have a greater potential energy.

For example, if the toolbox is lifted to a height of 10 meters above the ground, then it will have a potential energy of 490 joules (5*9.8*10).

The potential energy of the toolbox when it is placed next to the sawhorse, the height of the sawhorse needs to be taken into consideration.

If the sawhorse is higher than the ground, then the toolbox will have a greater potential energy since it will be located at a greater height above the ground.

If the sawhorse is lower than the ground, then the toolbox will have a lesser potential energy than when it is resting on the ground.

The potential energy of a toolbox weighing 5 newtons when placed next to a sawhorse depends on the height of the sawhorse relative to the ground.

If the sawhorse is higher than the ground, then the toolbox will have a greater potential energy, and if it is lower than the ground, then the toolbox will have a lesser potential energy.

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When a pipe is filled with a liquid of higher density than air, the frequency of the normal modes of the pipe decreases.

This is due to the fact that the speed of sound is proportional to the square root of the ratio of the bulk modulus to the density of the medium in which it travels.

When the density of the medium inside the pipe increases, the velocity of sound decreases, causing the frequency of the normal modes to decrease.

he wavelength of the sound waves inside the pipe is shortened due to the increase in density, resulting in a lower frequency of the normal modes.

The frequency of the normal modes of a pipe is influenced by a variety of factors, including the diameter and length of the pipe, as well as the speed of sound in the medium inside the pipe. T

he frequency of the normal modes is inversely proportional to the length of the pipe, with longer pipes producing lower frequencies.

In the case of a pipe filled with a liquid of higher density than air, the frequency of the normal modes would be lower than if it were filled with air.

This is because the speed of sound in the liquid would be lower than in air, resulting in a decrease in the frequency of the normal modes.

When a pipe is filled with a liquid of higher density than air, the frequency of the normal modes of the pipe decreases.

This is due to the fact that the speed of sound in the liquid is lower than in air, resulting in a decrease in the frequency of the normal modes.

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Isolated/insulated equipment grounding circuits must include one equipment grounding conductor to meet the requirements of the National Electrical Code (NEC). These grounding conductors play a crucial role in ensuring the safety and proper functioning of electrical systems.

The NEC sets the standards for the safe installation of electrical wiring and equipment in the United States. An isolated equipment grounding circuit is designed to maintain electrical safety by providing a dedicated path for grounding equipment. This prevents unwanted electrical noise or interference from affecting the performance of sensitive electronic devices.

A single equipment grounding conductor is sufficient for an isolated grounding circuit, as it is meant to carry the fault current back to the source of power, protecting people and equipment from electrical hazards. The conductor is usually made of copper or aluminum and is sized according to the size of the circuit conductors.

This grounding conductor is connected to a grounding electrode system, which includes grounding electrodes such as ground rods, metallic water pipes, or concrete-encased electrodes. These electrodes create a connection to the earth, ensuring that any fault current is safely dispersed into the ground.

By complying with the NEC requirements, you ensure that your electrical systems are designed and installed in a manner that reduces the risk of electrical shock, fire hazards, and other potential dangers. A properly grounded electrical system promotes safety, performance, and reliability in any electrical installation.

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The radius of the flywheel and its rotational inertia will be 0.64m and 389kgm² respectively.

Rotational inertia, also known as moment of inertia, is a measure of an object's resistance to rotational motion. It is similar to the concept of mass in linear motion. Just as mass is a measure of an object's resistance to linear motion, the moment of inertia is a measure of an object's resistance to rotational motion.

The moment of inertia of an object depends on its shape and mass distribution. Objects with more mass distributed farther from the axis of rotation have a higher moment of inertia than objects with the same mass but a more compact distribution of mass. The moment of inertia is measured in units of kilograms square meters (kg m²) in the SI system.

The radius will be:

= 1000 / 15000(2πrad / 60)

= 0.64m

The inertia will be:

= 2(4.8 × 10^8) / 100 (2π/60)

= 389kgm²

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We need at least one pulley to lift the load of 200 lb with an overhead system using pulleys that have an efficiency of 0.9, given that we can provide a maximum input force of 103 lb.

Assuming that the weight of the pulleys and the rope is negligible, we can use the formula,

Load = (Input Force / Efficiencies) ^ Number of Pulleys

where Load is the weight of the load we want to lift, Input Force is the force we apply to the system, Efficiency is the efficiency of each pulley, and Number of Pulleys is the number of pulleys we need.

Plugging in the given values,

200 lb = (103 lb / 0.9) ^ Number of Pulleys

Simplifying the equation,

Number of Pulleys = log (base 2) (200 / (103/0.9))

Number of Pulleys = log (base 2) (200 x 0.9 / 103)

Number of Pulleys = log (base 2) 1.983495

Number of Pulleys = 1

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Explanation:

The option that best describes the image when an object is placed at a distance greater than twice the focal length in front of a concave mirror is:

"An inverted image which is smaller than the object and located between the focal point and the center of curvature of the mirror.

"When an object is placed at a distance greater than twice the focal length in front of a concave mirror, a virtual, upright, and magnified image is formed.

As per the rules of concave mirrors, when an object is placed beyond the center of curvature, an inverted and real image is produced.

As a result, option (A) is incorrect.

When the object is placed at the center of curvature, the size of the image is equal to that of the object, and it is inverted.

As a result, option (C) is incorrect.

When an object is placed at a distance that is less than twice the focal length, the image formed is virtual, erect, and magnified.

As a result, option (D) is incorrect.

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Uneven-diameter logs that float with 20.0% of their length above water have an average density of 0.8g/cm3. The density is the proportion of weight to capacity.

An item it's far less compact that liquid may be supported up liquid water, and hence it floats. More dense objects can sink when submerged in water. Less dense logs float whereas more thick logs sink. A body can change its condition of rest or motion by the application of force

Instead of obliquely reading from either the side, read the scale stick straight from of the end of both the log. → The diameter of a log is only ever calculated within the bark. Employ a log measuring rod to determine the log's small end's "diameter from within bark," also known as "d.i.b."

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When Einstein's theory of gravity (general relativity) gained acceptance, it demonstrated that Newton's theory had been (b) incomplete.

Newton's theory of gravity is a law that governs the behavior of objects. The formula [tex]F = \frac {G m_1  m_2}{ d^2}[/tex] explains the force of gravity between two objects, where F is the force of gravity, G is the universal gravitational constant, m1 is the mass of one object, m2 is the mass of another object, and d is the distance between the centers of the two objects. This formula shows that gravity decreases as distance increases.

Einstein's theory of gravity (general relativity): It is a theoretical framework proposed by Albert Einstein in 1915. It combines special relativity and Newton's law of universal gravitation. General relativity is based on the notion that gravitation is not a force acting between two masses but rather a curvature of spacetime created by the presence of massive objects. It differs from Newton's law of universal gravitation, which states that gravitation is caused by an attractive force acting between two masses.

When Einstein's theory of gravity (general relativity) gained acceptance, it demonstrated that Newton's theory had been incomplete. Therefore the correct answer is b.

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The point at which the kinetic energy is lowest is 3 in the syringe containing an incompressible fluid that is vertically oriented and the plunger is slowly depressed.

The kinetic energy of an object is the energy it has due to its motion. When an object is in motion, it has kinetic energy. It is a scalar quantity that is proportional to the mass of the object and the square of its velocity. The formula for kinetic energy is given as follows:

                                KE = 1/2mv²

Where m is the mass of the object and v is its velocity.

Points 1 and 2 have higher kinetic energy because the incompressible fluid is still being compressed in the syringe. Point D is incorrect because the kinetic energy of the incompressible fluid is not the same at all three points. Point E is incorrect because enough information has been provided. Therefore, when a syringe containing an incompressible fluid is vertically oriented and the plunger is slowly depressed, the kinetic energy is lowest at point 3.

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While a car travels around a circular track at a constant speed, its (d) acceleration is non-zero and outward from the center.

When a car travels around a circular track at a constant speed, it is constantly changing direction, and therefore, constantly accelerating. This acceleration is known as centripetal acceleration and is directed towards the center of the circle.

However, according to Newton's third law, every action has an equal and opposite reaction. In this case, the car also experiences an equal and opposite acceleration, known as the centrifugal acceleration, which is directed outward from the center of the circle.

This is the non-zero acceleration experienced by the car, and it acts to counterbalance the centripetal acceleration, keeping the car moving in a circular path.

Therefore, the correct answer is (d) acceleration is non-zero and outward from the center.

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The radius of the cylindrical chamber in the amusement park ride can be calculated using  formula for centripetal force and the given values for velocity and force. In this case, the radius is approximately 14.3 meters.

The person is seated facing the axis, with their back against outer wall. At a given instant, the outer wall moves at a speed of 3.13 m/s, and the person feels a 578 N force pressing against their back.

To determine the radius of the chamber, we can use formula for centripetal force, [tex]Fc = (mv^2) / r[/tex].

Rearranging the formula to solve for r, we get r = (mv^2) / Fc. Substituting the given values, we get[tex]r = (83.6 kg * (3.13 m/s)^2) / 578 N,[/tex] which simplifies to  [tex]r = 14.3 m[/tex]. Therefore, the radius of the cylindrical chamber is approximately [tex]14.3 meters[/tex].

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Approximately [tex]1.31 \times 10^{20}[/tex] electrons are transferred in a strong lightning bolt carrying an electric charge of 21 C.

The electric charge of one electron is equal to [tex]-1.602 \times 10^{-19}[/tex] Coulombs (C). Therefore, we can calculate the number of electrons transferred by dividing the total charge transferred by the charge of a single electron:

Number of electrons = Total charge transferred / Charge of a single electron

Number of electrons = [tex]\frac{21 C }{-1.602 \times 10^{-19} C}[/tex]

The number of electrons ≈ [tex]1.31 \times 10^{20} electrons[/tex]

Hence the number of electrons transferred during the lightning bolt is [tex]1.31 \times 10^{20}[/tex].

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The specific heat of other liquid is 2.09 J/g°C.

Using the formula Q = mcΔT, where Q is  amount of heat lost, m is the mass of  liquid, c is specific heat of liquid, and ΔT is the change in temperature, we can set up two equations for each liquid.

For water, Q = (50 + 30)g × 4.18 J/g°C × (30 - 25)°C = 1045 J

For other liquid, Q = 100g × c × (30 - 25)°C = 500c J

Since both liquids lost same amount of heat, took same amount of time to cool, we can set these two equations equal to each other and solve for c: 1045 J = 500c J, c = 2.09 J/g°C

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--The correct Question is, A mass of 50 g of a certain metal at 150 degree C is immersed in 100 g of water at 11 degree C. The final temperature is 20 degree C. Calculate the specific heat capacity of the metal. Assume that the specific heat capacity of water is 4.2Jg −1 K−1 .--

The image formed by refraction is at a distance of 120cm behind the lens and its magnification is 4.

The image formation by refraction and magnification of an object in water 30 cm from the vertex of a convex surface made of plexiglass with a radius of curvature of 80 cm can be calculated using the following steps:

1. Determine the object's distance from the lens. Object distance (u) = -30 cm. (negative sign as per the convention of the mirror)

2. Determine the focal length of the lens using the formula:

f = R/2 where, f = focal length of the lens, R = radius of curvature of the lens.

So, f = 80/2 = 40 cm.

3. Use the mirror formula to determine the image distance from the surface:

1/f = 1/v + 1/u where,v = image distance from the surface.

Substituting the given values (with proper sign convention), we get:

(-1/40) = 1/v + (-1/30)

Solving for v, we get:

v = 120 cm.

5. Use the magnification formula to determine the magnification of the image:

m = -(v/u)

where,m = magnification, v = 120 cm, u = 30 cm

Therefore,m = -(120/-30) = 4

Therefore, the image will form at a distance of 120 cm from the lens on the water side of the lens and is magnified by a factor of 4.

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The statement "pry on the power steering reservoir to adjust the tension of the power steering belt" is: false.

The tension of the power steering belt is adjusted by adjusting the position of the power steering pump. There is a tension adjustment bolt on the power steering pump that is used to adjust the tension of the power steering belt. The adjustment bolt should be turned clockwise or counterclockwise to adjust the tension of the belt.

A belt tension gauge may be used to ensure that the belt is properly tensioned. A pry bar should not be used on the power steering reservoir to adjust the tension of the power steering belt. This could cause damage to the reservoir or other components of the power steering system. The reservoir should be inspected for damage or leaks, but it should not be used to adjust the tension of the belt.

In summary, the tension of the power steering belt should be adjusted by adjusting the position of the power steering pump, not by prying on the power steering reservoir.

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The maximum amplitude of the PWM voltage signal applied across the 500-ohm resistor is: Vmax=2*I*R=500*I

The power dissipated by a resistor during one cycle is given by the periodic signal. The PWM voltage signal applied across a 500 Ω resistor is analyzed in this question. The amplitude of the signal is determined below.

Pulse Width Modulation is the PWM. It's a process for varying the pulse width of a square wave, which changes the percentage of time the signal is high to low. The pulse width can be varied to create the desired output signal level. It is frequently utilized in applications where analog signals are required, including control systems, power supplies, and audio systems. The maximum voltage Vm of the PWM voltage signal can be found by calculating the RMS value of the pulse. The root-mean-square value is the square root of the mean of the square of the signal over a given period. If we use a pulse that has a duty cycle of 50%, this formula simplifies to: Vmax=Vm+0.5Vdc where Vdc is the average value of the pulse.

The maximum amplitude can be determined using this formula: Vmax=I*R where I is the current and R is the resistance. The current flowing through the resistor is proportional to the voltage applied to it, and the voltage is proportional to the duty cycle of the PWM signal, which varies from 0 to 1. Thus, the voltage applied to the resistor is proportional to the duty cycle and can be expressed as: V=Vmax*D where D is the duty cycle. Thus, the amplitude of the PWM voltage signal applied across a 500-ohm resistor is: Vmax=2*I*R=500*I. Using this equation, we can determine the maximum amplitude of the PWM voltage signal applied across the 500-ohm resistor.

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When a negatively charged point particle is placed initially at rest in a uniform electric field, it will move towards the direction of the electric field.

An electric field is a vector field that represents the force exerted by charged particles over each other. It is generated by charges, and it affects other charged particles that are in the space around it. The direction of the electric field is given by the direction of the force that is experienced by a small positive test charge placed in that field. If the force on the test charge is towards the positive charge that creates the field, the electric field will point towards the positive charge. If the force on the test charge is towards the negative charge that creates the field, the electric field will point towards the negative charge.

When a negatively charged particle is placed in the electric field, it experiences a force in the direction opposite to the direction of the electric field,  this is because the negatively charged particle is attracted towards the positively charged particles that generate the field, and so it moves towards them. Therefore, the negatively charged particle moves towards the direction of the electric field. When a positively charged particle is placed in the electric field, it experiences a force in the direction of the electric field. This is because the positively charged particle is attracted towards the negatively charged particles that generate the field, and so it moves towards them. Therefore, the positively charged particle moves towards the direction opposite to the direction of the electric field.

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The image size on the retina of a person of height 1.8 m standing 8.0 m away is: 0.094 cm.

The size of the image on the retina of a person of height 1.8 m standing 8.0 m away is determined by the size of the object, the distance between the object and the lens, and the distance between the lens and the retina.

The image size on the retina is inversely proportional to the distance between the object and the lens and is directly proportional to the distance between the lens and the retina. In this case, the object is 1.8 m away and the lens is 1.7 cm from the retina.

Therefore, the image size on the retina is (1.7 cm/1.8 m) times 8.0 m, or 0.094 cm. This means that the image size on the retina of a person of height 1.8 m standing 8.0 m away is 0.094 cm.

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Explanation:

To solve this problem, we can use the law of conservation of momentum, which states that the total momentum of a system is conserved in the absence of external forces.

Before the collision, the momentum of the blue clay is:

momentum of blue clay = mass of blue clay * velocity of blue clay

= 2 kg * 1.5 m/s = 3 kg*m/s to the east (positive)

Before the collision, the momentum of the red clay is:

momentum of red clay = mass of red clay * velocity of red clay

= 1.5 kg * (-2.5 m/s) = -3.75 kg*m/s to the west (negative)

The total momentum before the collision is:

total momentum before collision = momentum of blue clay + momentum of red clay

= 3 kgm/s - 3.75 kgm/s = -0.75 kg*m/s to the west (negative)

After the collision, the two clays stick together and move as one combined object. Let's assume that the final velocity of the combined clay pieces after the collision is v.

By the law of conservation of momentum, the total momentum after the collision is equal to the total momentum before the collision:

total momentum after collision = total momentum before collision

= -0.75 kg*m/s

The combined mass of the two clays after the collision is:

combined mass = mass of blue clay + mass of red clay

= 2 kg + 1.5 kg = 3.5 kg

Therefore, the final velocity of the combined clay pieces after the collision is:

v = total momentum after collision / combined mass

= (-0.75 kg*m/s) / 3.5 kg

= -0.214 m/s to the west (negative)

Since the negative velocity indicates a direction to the west, the final velocity of the combined clay pieces after the collision is 0.214 m/s to the west.

A 5 kg toy train car is connected to a 3 kg toy train car. the 3 kg car is given an external force of 16 n. the tension in the rope connecting the two cars is 29 N.

The tension in the rope connecting two toy train cars A toy train car with a mass of 5 kg is connected to a toy train car with a mass of 3 kg. An external force of 16 N is applied to the 3 kg car.

Tension in the rope between the two toy cars is what we need to calculate. According to Newton’s 2nd law, force equals mass multiplied by acceleration. If the two cars are moving in the same direction with the same acceleration, the tension in the rope can be calculated as follows:

Force acting on the two cars is the external force that is applied on the 3 kg car which is equal to 16 N. In this case, both cars will have the same acceleration.

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The magnitude of the force experienced by the electron is 1.92 x 10^-14 N.

The force experienced by a charged particle moving in a magnetic field is given by the formula,

F = qvB

where F is the force on the particle, q is the charge of the particle, v is the velocity of the particle, and B is the magnetic field.

In the given problem, the electron is moving parallel to the magnetic field, so the angle between the velocity vector and the magnetic field vector is 0 degrees. Therefore, the sine of the angle is 0, and the force experienced by the electron is simply,

F = qvB

where q is the charge of the electron (-1.6 x 10^-19 C), v is the speed of the electron (3 x 10^4 m/s), and B is the magnetic field (0.4 T).

Substituting the given values,

F = (-1.6 x 10^-19 C) * (3 x 10^4 m/s) * (0.4 T)

F = -1.92 x 10^-14 N

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