Guitar string has an overall length of 1.22 m and a total mass of 3.5 g before being strung on a guitar. Once it is used on the guitar, there is a distance of 70 cm between fixed end points. The guitar string is tightened to a tension of 255 N.What is the frequency of the fundamental wave on the guitar string?
Answers
Answer:
Fundamental frequency= 174.5 hz
Explanation:
We know
fundamental frequency=
velocity =
mass per unit length==0.00427
Now calculating velocity v=
=244.3
Distance between two nodes is 0.7 m.
Plugging these values into to calculate frequency
f = =174.5 hz
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Answers
Answer:
a).
b).
c). Δ
Explanation:
ΔE=kinetic energy
a).
b).
c).
net work= EkA+EkB
Answers
Answer: wavelength =3.52m
Explanation:
,λ=c/μ
where c=speed of the light,λ=wave length, μ=frequncy
c=3x10^8m/s
And
μ=83.5/MHz =85.3x10^6Hz==85.3x10^6Hz=
=85.3x10^6s-1
λ=c/μ
=3x10^8m/s/85.3x10^6s-1
=3.51699883
=3.52m
Answers
Answer:
Explanation:
We are given that
Amount of work needed to bring a point charge q0 from infinity to a point P=
We know that potential at point P=
Where U=Amount of work needed to bring a point charge q from infinity to a point P
Initially ,
New charge, q=
Then, work done,U=
Hence, the amount of work needed to bring a new charge 4q0 from infinity to point P=
Answer:
Explanation:
V = u / q,
Work = P = V
1U / 1/4 = 4U
Answers
Answers
Answer:
fem = - 4.50 10²² V
Explanation:
For the solution of this problem we must use the equation of the induced electromotive force or Faraday's law
E = - d Φ / dt = d (BA cos θ) dt
In this case they tell us that the magnetic field is perpendicular to the plane of the loop, as the normal to the surface of the loop is in the direction of the radius, the angle between the field and this normal is zero, so cos 0º = 1. The area of the loop is constant, with this the equation is
E = - A dB / dt (1)
To find field B, we have the relationships of electromagnetic waves
E = c B
The intensity or poynting vector for the wave is described by the equation
S = I = 1 / μ₀ E x B = 1 /μ₀ E B
We replace
I = 1 /μ₀ (cB) B = c /μ₀ B²
This is the instantaneous intensity.
B = √ (μ₀ I /c)
We substitute in equation 1
E = - A μ₀/c d I / dt
With the maximum value we are asked to change it derived from variations
E = -A c/μ₀ ΔI / Δt
It remains to find the time of the variation. Let's use the equation
c = λ f = λ / T
T = λ / c
T = 6.20 / 3 10⁸
T = 2.06 10⁻⁸ s
We already have all the values to calculate the fem
fem = - π r² c/μ₀ ΔI/Δt
fem = - (π 0.078²) (3 10⁸/(4π 10⁻⁷) (2.03 10² -0) / (2.06 10⁻⁸ - 0)
fem = - 4.50 10²² V