maxwell’s equations
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Maxwell’s Equations. PH 203 Professor Lee Carkner Lecture 25. Transforming Voltage. We often only have a single source of emf We need a device to transform the voltage Note that the flux must be changing, and thus the current must be changing Transformers only work for AC current. - PowerPoint PPT PresentationTRANSCRIPT
Maxwell’s Equations
PH 203
Professor Lee Carkner
Lecture 25
Transforming Voltage
We often only have a single source of emf
We need a device to transform the voltage
Note that the flux must be changing, and thus the current must be changing Transformers only work for AC current
Basic Transformer
The emf then only depends on the number of turns in each
= N(/t)
Vp/Vs = Np/Ns
Where p and s are the primary and secondary solenoids
Transformers and Current
If Np > Ns, voltage decreases (is stepped down)
Energy is conserved in a transformer so:
IpVp = IsVs
Decrease V, increase I
Transformer Applications
Voltage is stepped up for transmission Since P = I2R a small current is best for
transmission wires Power pole transformers step the voltage down
for household use to 120 or 240 V
Maxwell’s Equations In 1864 James Clerk Maxwell presented to the Royal
Society a series of equations that unified electricity and magnetism and light
∫ E ds = -dB/dt
∫ B ds = 00(dE/dt) + 0ienc
∫ E dA = qenc/0
Gauss’s Law for Magnetism ∫ B dA = 0
Faraday’s Law
∫ E ds = -dB/dt
A changing magnetic field induces a current Note that for a uniform E over a uniform
path, ∫ E ds = Es
Ampere-Maxwell Law
∫ B ds = 00(dE/dt) + 0ienc
The second term (0ienc) is Ampere’s law
The first term (00(dE/dt)) is Maxwell’s Law of Induction
So the total law means Magnetic fields are produced by changing
electric flux or currents
Displacement Current
We can think of the changing flux term as being like a “virtual current”, called the displacement current, id
id = 0(dE/dt)
∫ B ds = 0id + 0ienc
Displacement Current in Capacitor
So then dE/dt = A dE/dt or
id = 0A(dE/dt) which is equal to the real
current charging the capacitor
Displacement Current and RHR
We can also use the direction of the displacement current and the right hand rule to get the direction of the magnetic field Circular around the capacitor axis Same as the charging current
Gauss’s Law for Electricity
∫ E dA = qenc/0
The amount of electric force depends on the amount and sign of the charge Note that for a uniform E over a
uniform area, ∫ E dA = EA
Gauss’s Law for Magnetism
∫ B dA = 0
The magnetic flux through a surface is always zero Since magnetic fields are
always dipolar
Next Time
Read 32.6-32.11 Problems: Ch 32, P: 32, 37, 44
How would you change R, C and to increase the rms current through a RC circuit?
A) Increase all three
B) Increase R and C, decrease C) Decrease R, increase C and D) Decrease R and , increase C
E) Decrease all three
How would you change R, L and to increase the rms current through a RL circuit?
A) Increase all three
B) Increase R and L, decrease C) Decrease R, increase L and D) Decrease R and , increase L
E) Decrease all three
How would you change R, L, C and to increase the rms current through a RLC circuit?
A) Increase all four
B) Decrease and C, increase R and L
C) Decrease R and L, increase C and D) Decrease R and , increase L and C
E) None of the above would always increase current