Under which of the following conditions is the magnitude of the average velocity of a particle moving in one dimension smaller than the average speed over some time interval?

Answer:

Explanation:

Given;

output power of the incandescent lightbulb , P = 120 W

input voltage, V = 200 V

The resistance of the filament is calculated as;

[tex]P = \frac{V^2}{R}[/tex]

Where;

R is the resistance of the filament

[tex]R = \frac{V^2}{P} \\\\R = \frac{200^2}{120} \\\\R = 333.33 \ ohms[/tex]

The rms current is given as;

[tex]P = I_{rms} V_{rms}\\\\I_{rms} = \frac{P}{V_{rms}} \\\\I_{rms} =\frac{120}{200}\\\\ I_{rms} = 0.6 \ A[/tex]

Answer:

Where is the picture

Explanation:

WHERE IS THE PICTURE

Complete Question

Due to blurring caused by atmospheric distortion, the best resolution that can be obtained by a normal, earth-based, visible-light telescope is about 0.3 arcsecond (there are 60 arcminutes in a degree and 60 arcseconds in an arcminute).Using Rayleigh's criterion, calculate the diameter of an earth-based telescope that gives this resolution with 700 nm light

Answer:

The diameter is  [tex]D = 0.59 \ m[/tex]    

Explanation:

From the question we are told that

      The best resolution is  [tex]\theta = 0.3 \ arcsecond[/tex]

       The  wavelength is  [tex]\lambda = 700 \ nm = 700 *10^{-9 } \ m[/tex]

Generally the

         1 arcminute  = >  60 arcseconds

=>      x arcminute =>   0.3 arcsecond

So

       [tex]x = \frac{0.3}{60 }[/tex]

=>    [tex]x = 0.005 \ arcminutes[/tex]

Now

         60 arcminutes  =>  1 degree

          0.005 arcminutes = >  z degrees  

=>       [tex]z = \frac{0.005}{60 }[/tex]

=>      [tex]z = 8.333 *10^{-5} \ degree[/tex]

Converting to radian  

           [tex]\theta = z = 8.333 *10^{-5} * 0.01745 = 1.454 *10^{-6} \ radian[/tex]

Generally the resolution is mathematically represented as

            [tex]\theta = \frac{1.22 * \lambda }{ D}[/tex]

=>    [tex]D = \frac{1.22 * \lambda }{\theta }[/tex]

=>     [tex]D = \frac{1.22 * 700 *10^{-9} }{ 1.454 *10^{-6} }[/tex]    

=>     [tex]D = 0.59 \ m[/tex]    

Answer:

(c) moves toward the shore.

Explanation:

Momentum can be defined as the multiplication (product) of the mass possessed by an object and its velocity. Momentum is considered to be a vector quantity because it has both magnitude and direction.

Mathematically, momentum is given by the formula;

[tex] Momentum = mass * velocity [/tex]

The law of conservation of momentum states that the total linear momentum of any closed system would always remain constant with respect to time.

In this scenario, a boy standing at one end of a floating raft that is stationary relative to the shore walks to the opposite end of the raft, away from shore. As a consequence, the raft moves toward the shore because the momentum of the closed system (boy and raft) has a zero magnitude and would remain constant.

Answer:

k. e= 1/2 mv^2

Ke = 1/2 * 1.5 * 10^5 * 70^2

3.675 *10^8 joules

Answer:

a. [tex]m' = \frac{m}{4}[/tex]

b. [tex]m' = \frac{m}{9}[/tex]

Explanation:

The frequency of a harmonic oscillator is given by the following formula:

[tex]\omega = \sqrt{\frac{k}{m}}[/tex]   ----------------- equation (1)

a.

In order to double the frequency of this oscillator:

ω' = 2ω

m' = ?

Therefore,

[tex]\omega ' = 2\omega = \sqrt{\frac{k}{m'}}[/tex]

using equation (1):

[tex]2 \sqrt{\frac{k}{m}} = \sqrt{\frac{k}{m'}}\\\\ \frac{4}{m} = \frac{1}{m'}[/tex]  

[tex]m' = \frac{m}{4}[/tex]

a.

In order to triple the frequency of this oscillator:

ω' = 3ω

m' = ?

Therefore,

[tex]\omega ' = 3\omega = \sqrt{\frac{k}{m'}}[/tex]

using equation (1):

[tex]3\sqrt{\frac{k}{m}} = \sqrt{\frac{k}{m'}}\\\\ \frac{9}{m} = \frac{1}{m'}[/tex]  

[tex]m' = \frac{m}{9}[/tex]

A) To double the Frequency of a harmonic oscillator ;

Divide the mass by four       i.e. m₁ = m / 4

B) To triple the frequency of a harmonic oscillator :

Divide the mass by nine (9)     i.e.  m₂ = m / 9

Given that The frequency of a harmonic oscillator is expressed as  

[tex]w = \sqrt{\frac{k}{m} }[/tex]  -- ( 1 )

A) Doubling the frequency

[tex]2w = \sqrt{\frac{k}{m_{1} } }[/tex]  ---- ( 2 )

Applying equation ( 1 ) and ( 2 )

[tex]2\sqrt{\frac{k}{m} } = \sqrt{\frac{k}{m_{1} } }[/tex]

squaring both sides

( 4 / m )  =  1 / m₁

∴ m₁ ( new mass ) = m / 4

B) Tripling the frequency

3w = [tex]\sqrt{\frac{k}{m_{2} } }[/tex]    ---- ( 3 )

applying equation ( 1 ) and ( 3 )

[tex]3 \sqrt{\frac{k}{m} } = \sqrt{\frac{k}{m_{2} } }[/tex]  

squaring both sides

( 9 / m ) =  1 / m₂

∴ m₂ = m / 9

Hence we can conclude that To double the Frequency of a harmonic oscillator   m₁ = m / 4  and To triple the frequency of a harmonic oscillator : m₂ = m / 9

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Answer: The red at the bottom represents the base of the tube, not the red liquid.

Explanation:

The densest materials have more weight per unit of volume.

This means that those elements will always flow to the bottom of the containers, like the one in the image.

The red liquid being the least dense one, can not go to the bottom by its own means.

There could be some cases, like:

The red liquid when solid, is way denser than in its liquid phase, and then the red at the bottom could be solid phase of the red liquid, but there is no mention of this in the question, then we can discard this idea.

Another trivial idea is that the red liquid at the bottom could be trapped by some kind of wall, but again, there is no mention of this, so again we can discard this idea.

The thing that makes sense is that the red at the bottom represents the base of the tube and not the red liquid.

Answer:

The leaves have a charge in each experiment, but the sign of the charge cannot be determined.

Explanation:

In the first experiment, A charged rod is brought near the sphere without touching it. As a result the leaves of the electroscope separate more.

Thus indicates that there are charges involved. Now, like charges would repel like what is happening here but we don't know if they are both positive or negative because in both cases, they will still repel.

Now for the second experiment, electroscope is grounded and the ground is removed before the rod is removed from near the sphere. The leaves end up being separated again.

Similar to the first time, it's clear there are charges but the charges repel. Thus, they are the same sign charges but we don't know if they are both positive or negative.

Thus, in both cases we can conclude that the leaves have charges but we don't know their signs.

Answer:

a. Potential energy of the sled is increased when height of sled is increased.

b. Potential energy of the sled is increased when height of sled is increased.

c. P.E₂₀ = 2 P.E₁₀

d. P.E₂₀₀ = 2 P.E₁₀₀

Explanation:

The potential energy of the sled can be given by the following:

[tex]Potential\ Energy = P.E = mgh\\[/tex]

where,

m = mass of sled

g = acceleration due to gravity

h = height of sled

a.

It is clear from the formula that potential energy of sled is directly proportional  to the height of sled.

Therefore, potential energy of the sled is increased when height of sled is increased.

b.

It is clear from the formula that potential energy of sled is directly proportional to the mass of sled.

Therefore, potential energy of the sled is increased when mass of sled is increased.

c.

[tex]P.E\ at\ 10\ m:\\P.E_{10} = 10mg\\P.E\ at\ 20\ m:\\P.E_{20} = 20mg\\\frac{P.E_{20}}{P.E_{10}} = \frac{20mg}{10mg}[/tex]

P.E₂₀ = 2 P.E₁₀

d.

[tex]P.E\ at\ 100\ kg:\\P.E_{100} = 100gh\\P.E\ at\ 200\ m:\\P.E_{200} = 200gh\\\frac{P.E_{200}}{P.E_{100}} = \frac{200gh}{100gh}[/tex]

P.E₂₀₀ = 2 P.E₁₀₀

Answer:

  15√2 N

Explanation:

The acceleration is given by ...

  a = F/m = 5t/5 = t . . . . meters/second^2

The velocity is the integral of acceleration:

  v = ∫a·dt = (1/2)t^2

This will be 9 m/s when ...

  9 = (1/2)t^2

  t = √18 . . . . seconds

And the force at that time is ...

  F = 5(√18) = 15√2 . . . . newtons

Answer:

the correct one is the a,       U₂ = 2 U₁

Explanation:

The gravitational potential energy is

            U = m g h

if the stones reach the same height, the energy of the first stone is

            U₁ = m₁ g h

The second stone is twice the mass and reaches the same height

             m₂ = 2 m₁

potential energy is

           U₂ = m₂ g h

           U₂ = 2 m₁ g h

           U₂ = 2 U₁

therefore the energy is double.

When reviewing the statements, the correct one is the a

Answer:

The value is [tex]R = 0.321 \ \Omega[/tex]

Explanation:

From the question we are told that

   The diameter is  [tex]d = 8.252 \ mm = 0.008252 \ m[/tex]

    The length of the wire is  [tex]l = 1.0 \ km = 1000 \ m[/tex]

   Generally the cross sectional area of the copper wire is mathematically represented as

           [tex]A = \pi * \frac{d^2}{4}[/tex]

=>        [tex]A = 3.142 * \frac{ 0.008252^2}{4}[/tex]

=>         [tex]A = 5.349 *10^{ - 5} \ m^2[/tex]

Generally the resistance is mathematically represented as

      [tex]R = \frac{\rho * l }{A }[/tex]

Here [tex]\rho[/tex] is the resistivity of copper with the value  [tex]\rho = 1.72*10^{-8} \ \Omega \cdot m[/tex]

=>    [tex]R = \frac{1.72 *10^{-8} * 1000 }{5.349 *10^{ - 5} }[/tex]

=>    [tex]R = 0.321 \ \Omega[/tex]

Answer:

Average force = 67 mn

Explanation:

Given:

Initial velocity u = 0 m/s

Final velocity v = 67 m/s

Time t = 1 ms = 0.001 sec.

Computation:

Using Momentum theory

Change in momentum  = F × Δt

 (v-u)/t =  F × Δt

F × 0.001 = (67 - 0)/0.001

F= 67,000,000

Average force = 67 mn

Answer:

12345678901234567890

Answer:

Approximately [tex]1.69 \times 10^{30}\; \rm kg[/tex].

Explanation:

Let [tex]M[/tex] and [tex]m[/tex] denote the mass of the star and the planet, respectively.

Let [tex]G[/tex] denote the constant of universal gravitation ([tex]G \approx 6.67408 \times 10^{-11}\; \rm m^{3} \cdot kg^{-1}\cdot s^{-2}[/tex].)

Let [tex]r[/tex] denote the orbital radius of this planet (assuming that [tex]r\![/tex] is constant.) The question states that [tex]r = 1.65 \times 10^{10}\; \rm m[/tex].

The size of gravitational attraction of the star on this planet would be:[tex]\displaystyle \frac{G \cdot M \cdot m}{r^{2}}[/tex].

If attraction from the star is the only force on this planet, the net force on this planet would be [tex]\displaystyle \frac{G \cdot M \cdot m}{r^{2}}[/tex].

Let [tex]\omega[/tex] denote the angular velocity of this planet as it travels along its circular orbit around the star. The size of [tex]\omega\![/tex] could be found from the period [tex]T[/tex] of each orbit: [tex]\omega = (2\, \pi) / T[/tex].

In other words, this planet of mass [tex]m[/tex] is in a circular motion with radius [tex]r[/tex] and angular velocity [tex]\omega[/tex]. Therefore, the net force on this planet should be equal to [tex]m \cdot \omega^2 \cdot r[/tex].

Hence, there are two expressions for the net force on this planet:

Equate the right-hand side of these two equations:

[tex]\displaystyle \frac{G \cdot M \cdot m}{r^2} = {\left(\frac{2\pi}{T}\right)}^{2}\, m \cdot r[/tex].

Simplify this equation and solve for [tex]M[/tex], the mass of the star:

[tex]\displaystyle M = \frac{{(2\pi / T)}^2 \cdot r^3}{G}[/tex].

Notice that [tex]m[/tex], the mass of the planet, was eliminated from the equation. That explains why this question could be solved without knowing the exact mass of the observed planet.

Convert the orbital period of this star to standard units:

[tex]\begin{aligned}T &= 14.5\; \text{day} \times \frac{24\; \text{hour}}{1\; \text{day}} \times \frac{3600\; \text{second}}{1\; \text{hour}} \\ & = 1.2528 \times 10^{6}\; \rm \text{second}\end{aligned}[/tex].

Calculate the mass of the star:

[tex]\begin{aligned} M &= \frac{{(2\pi / T)}^2 \cdot r^3}{G} \\ &\approx \frac{\displaystyle {\left(\frac{2\pi}{1.2528 \times 10^{6}\; \rm s}\right)}^{2} \times \left(1.65 \times 10^{10}\; \rm m\right)^{3}}{6.67408 \times 10^{-11}\; \rm m^{3}\cdot kg^{-1} \cdot s^{-2}}\\ &\approx 1.69 \times 10^{30}\; \rm kg\end{aligned}[/tex].

A battery of 9 volts is connected to a resistor of 1000 ohms, then the value of current flowing through it will be 0.009 A.

Any flow of electrical charge carriers, such as ions, holes, or subatomic charged particles, is referred to as electrical current.

When electrons serve as the charge transfer in a wire, the amount of charge moving through any point of wire in a given amount of time is measured as electric current. Electric charges' motion is intermittently reversed in the alternating current, but not in direct current.

In many situations, the direction of movement in electric circuits is assumed to be the direction of positive charge flow, which is the way opposite of the real particle drift. When properly specified, the current is known as conventional current.

From the question,

V = ir

i = v/r

i = 9/1000

i = 0.009 A

Therefore, the value of the current flowing through it is  0.009 A.

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Answer:

Surface tension is the downward force acting on the surface of liquid due to presence of inter molecular forces or cohesive forces between the particles of liquid.

Surface tension decreases with increase in temperature as the forces among particles decrease due to increase in kinetic energy and thus the cohesive nature decreases and thus surface tension also decreases.

Surface tension may decrease or increase with increase in soluble impurities .Insoluble impurities decrease the surface tension.

Answer:

v₀ = 677.94 m / s ,   θ = 286º

Explanation:

We can solve this exercise using the kinematic expressions, let's work on each axis separately.

X axis

has a relation of aₓ = 5.10 m / s², the motor is on for a time of t = 675 s, reaching the speed vₓ = 3630 m / s, let's use the relation

         vₓ = v₀ₓ + aₓ t

         v₀ₓ = vₓ - aₓ t

let's calculate

         v₀ₓ = 3630 - 5.10 675

         v₀ₓ = 187.5 m / s

Y Axis

        [tex]v_{y}[/tex] = v_{oy} - a_{y} t

         v_{oy} = v_{y} - a_{y} t

let's calculate

        v_{oy}  = 4276 - 7.30 675

         v_{oy} = -651.5 m / s

we can give the speed starts in two ways

a)   v₀ = (187.5 i ^ - 651.5 j ^) m / s

b) in the form of module and angle

Let's use the Pythagorean theorem

            v₀ = [tex]\sqrt{v_{ox}^{2} + v_{oy}^{2} }[/tex]

            v₀ = [tex]\sqrt{187.5^{2} +651.5^{2} }[/tex]

            v₀ = 677.94 m / s

we use trigonometry

            tan θ = [tex]\frac{v_{oy} }{v_{ox} }[/tex]

            θ = tan⁻¹ \frac{v_{oy} }{v_{ox} }

            θ = tan⁻¹ ([tex]\frac{-651.5}{187.5}[/tex])

            θ = -73.94º

This angle measured from the positive side of the x-axis is

            θ‘ = 360 - 73.94

            θ = 286º

Answer:

The answer to your question is given below

Explanation:

To solve this problem, we'll assume that the plane is initially at rest.

Hence, the kinetic energy of the plane at rest is zero i.e Initial kinetic energy (KE₁) = 0

Next, we shall determine the final kinetic energy of the plan when the force was applied. This can be obtained as follow:

Force (F) = 5000 N

Distance (s) = 500 m

Energy (E) =?

E = F × s

E = 5000 × 500

E = 2500000 J

Since energy an kinetic energy has the same unit of measurement, thus, the final kinetic energy (KE₂) of the plane is 2500000 J

Finally, we shall determine the change in the kinetic energy of the plane. This can be obtained as follow:

Initial kinetic energy (KE₁) = 0

Final kinetic energy (KE₂) = 2500000 J

Change in kinetic energy (ΔKE) =?

ΔKE = KE₂ – KE₁

ΔKE = 2500000 – 0

ΔKE = 2500000 J

Hence, the change in the kinetic energy of the plane is 2500000 J.

Answer:

C) The spring constant of each half will be twice the spring constant of the original long spring since it will stretch only half as much under the same tension.

Explanation:

Hooke's law states that the force needed to extend or compress a spring by a distance is proportional to that distance. If is given as:

F = ke, where F is the force applied, k is spring constant and e is the extension.

If a force f is applied to a spring with a spring constant k and by a distance stretched (x) then:

k = F / x

For half the spring, if the same force F is applied, the stretch would be half (x/2), hence the spring constant C is:

C = F / (x/2)

C = 2 (F / x) = 2 * spring constant of original spring

alpha is the excess return on an investment after adjusting for market related volatility and random fluctuations.

beta is a measure of volatility relative to a benchmark ,such as the S&P 500.

Explanation:

alpha and beta are two different parts of an equation used to explain the performance of stocks and investments funds. But in maths alpha and beta is the Greek alphabet

Answer:

√2

Explanation:

From the question, we're given that the

Acceleration of the leaf is 1 m/s²

Change in displacement of the leaf is 1 m/s.

Again, from the question, we can tell that the initial velocity u = 0, since the object starts at rest

Now, to solve this, we don't the equation of motion to ur

S = ut + 1/2at², substituting the whole parameters, we then have

1 = 0 * t + 1/2 * 1 * t²

1 = 1/2 * t²

t²/2 = 1

t² = 2

t = √2 seconds

Therefore the time it takes the leaf to dislodge is 2 seconds

Answer:

Explanation:

we know that,

force = mass × acceleration

∴ since speed/velocity is constant, acceleration should be zero.

∴ f = m × 0

f = 0 N

∴ If we apply this to ,

work = force × displacement

we get ,

w = 0 × s

∴ we can say that the net work is zero.

and hence the answer is true!!!

Answer:

If a population exceeds carrying capacity, the ecosystem may become unsuitable for the species to survive. If the population exceeds the carrying capacity for a long period of time, resources may be completely depleted.

Answer:

A volcano fed by highly viscous magma is likely to be a greater threat to life and property than a volcano supplied with very fluid magma because with high viscous magma gas is trapped more in the magma so the gas will build up and then eventually explode, whereas with fluid magma the gas can escape allowing the magma.

HOPE THIS HELPS!!!

Explanation:

Less fluid magma done great damaged to the property and life as compared to highly viscus magma.

No, volcanoes that are fed by highly viscous magma are not a greater threat to life and property than volcanoes supplied with very fluid magma because the highly viscous magma can't move to a large distance due to its large viscosity.

While on the other hand, those volcanoes that supplied with very fluid magma do great damaged to the property due to its easily flowing on the surface of earth so we can conclude that less fluid magma done great damaged to the property and life as compared to highly viscus magma.

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Answer:

The value is  [tex]f_1 = 828 \ Hz[/tex]

Explanation:

From the question we are told that

    The speed is [tex]v = 25 \ m/s[/tex]

     The speed of the ambulance is [tex]u = 35 \ m/ s[/tex]

     The frequency of the siren is  [tex]f = 850 \ Hz[/tex]

Generally from Doppler effect equation we have that

        [tex]f_1 = \frac{v_s - v }{ v_s + u } * f[/tex]

Here [tex]v_s[/tex] is the velocity of sound with the value  [tex]v_s = 343 \ m/s[/tex]

  =>   [tex]f_1 = \frac{343 - 25 }{ 343 + 35 } * 850[/tex]

  =>   [tex]f_1 = 828 \ Hz[/tex]

The mass m of the object = 5.25 kg

Given

k = spring constant = 3.5 N/cm

Δx= 30 cm - 15 cm = 15 cm

Required

the mass m

Solution

F=m.g

Hooke's Law

F = k.Δx

[tex]\tt m.g=k.\Delta x\\\\m.10=3.5\times 15\\\\m=5.25~kg[/tex]

Answer:

The officer's unit detects this 135-mile-per-hour speed and should subtract the patrol car's 70-mile -per-hour ground speed to get your true speed of 65 miles per hour. Instead, the officer's ground-speed beam fixes on the truck ahead and measures a false 50-mile-per-hour ground speed.

Explanation:

A speedometer or speed meter is a gauge that measures and displays the instantaneous speed of a vehicle. Now universally fitted to motor vehicles, they started to be available as options in the early 20th century, and as standard equipment from about 1910 onwards.

Answer: the child's centripetal acceleration=24.50 m/s²

Explanation:

Given that mass of child= 50 kg

radius of merry go round= 2.25m

angular speed = 3.30 rad/s

Centripetal Acceleration  = v²/ r

  But  V= ωr

So Centripetal Acceleration  = v²/ r =  (ωr)²/ r

=(3.30)² x  (2.25)²/ 2.25 = (3.30)² x  2.25

=24.5025m/s²

=24.50 m/s²