Chapter 7. Steady magnetic field 1 EMLAB
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Chapter 7. Steady magnetic field
1
EMLAB
B (Magnetic flux density), H (Magnetic field)
• Magnetic field is generated by moving charges, i.e. current.
• If current changes with time, electric field is generated by time varying magnetic field.
• In chapter 7, we consider only steady state current. In this case, steady magnetic fields are generated and we need consider magnetic field only.
• If a charge moves in a region where magnetic flux density is non-zero, it experiences a force due to the field which is called Lorentz force.
)(
forceLorentz;q
MHB
BvF
• The force exerted on a moving charge is due to B (Magnetic flux density).
• B can be obtained from a magnet or cur-rent flowing coil.
• B due to current flowing coil only is de-fined to be H (magnetic field).
• B due to a permanent magnet is repre-sented by M (magnetization).
2
EMLAB
Biot-Savart law
This law is discovered by Biot and Savart. It enables us to predict magnetic field due to a current seg-ment.
This law is experimentally known. It is the counterpart of Coulomb’s law for electric field.
24
ˆ
R
Idd
Rs
H
'rrR 'r
r
sId
Direction of H-field
3
EMLAB
Current segment
;4
ˆ
;4
ˆ
;4
ˆ
2
2
2
S
S
C
R
d
R
da
R
Id
RJH
RKH
RsHsId
daK
dJ
Biot-Savart law : integral form4
EMLAB
Line current
surface current
Volume current
Magnetic field due to an infinitely long line current
• An infinitely long straight current flowing in the z-axis.
2
Iˆ
0sin2
sin2
Iˆ
dcos2
Iˆ
)/'z(1
/'dz
2
Iˆ
'z
'dz
4
Iˆ
'z
'dzˆ'zˆˆ
4
I
'4
'Id)(
2/
002/32
2/3222/322
'C3
zρz
rr
RsrH
dsec'dz
tan'z 2
odd function
zrρrrrR ˆ'z',ˆ,'
x
z
y
r
5
EMLAB
11
2212
z
z2/32
z
z2/322
z
z2/322
'C3
ztan,
ztansinsin
4
Iˆ
dcos4
Iˆ
)/'z(1
/'dz
4
Iˆ
'z
'dz
4
Iˆ
'z
'dzˆ'zˆˆ
4
I
'4
'Id)(
2
1
2
1
2
1
2
2
zρz
rr
RsrH
dsec'dz
tan'z 2
기함수
x
z
y
2
1
2z
1z
6
EMLAB
Magnetic field due to a finitely long current filament
x
z
y
)0for(
2ˆ
2ˆ'
4ˆ
]ˆ)'sinˆ'cosˆ(['
4
1
'
)ˆ''ˆ(''
4
1
'
)'ˆ'ˆ('ˆ''
4
1
'4
')(
2/322
22
02/322
2
2
02/322
2
02/322
2
02/322
'3
za
I
za
aId
za
aI
za
ayxzdaI
z
zdI
z
zdI
Id
C
z
zz
z
zρ
ρz
rr
RsrH
'ˆ'',ˆz,' ρrzrrrR
a
z
Magnetic field due to a loop current
• Magnetic field on the z-axis can only be found due to its simple shape. If the receiver’s position is located on the off-axis region, the integral can be evaluated.
7
EMLAB
Calculation of H of a solenoidzρrxrrrR ˆ'z'ˆ'',ˆx,'
)1(S0
S4
'
'dˆ
S0
SˆK
'
'dˆ
4
Kˆ
]'za'cosax2x[
)'cosxa('dz'da
4
Kˆ
]'za'cosax2x[
]'ˆ'zˆ)'cosxa[('dz'da
4
K
)'cosˆˆ)'cosy'sinx(ˆ'ˆ(
]'za'cosax2x[
)'ˆ'zˆaˆ'ˆx('dz'da
4
K
'
)ˆ'z'ˆaˆx('ˆ'dz'da
4
K
'
)ˆ'z'ˆ'ˆx('ˆ'dz'd'
4
K
'4
'ds)(
S2
S2
2
02/3222
2
02/3222
2
02/3222
2
03
2
03
'C3
적분
r
r
rr
aR
r
rz
rr
aRz
z
ρz
zxx
ρzx
rr
zρx
rr
zρx
rr
RKrHzH ˆKin
0extH
K
Surface current density
If a copper wire is wound around a cylinder N times in the length d and current I is flowing through it, it can be approximated by a surface current along direction with a magnitude K = NI/d.
d
a
8
EMLAB
14
sinˆˆ
4
')ˆ(ˆ
'4
'ˆ
'near is)2(
)'(0
''4
'ˆ
)'(0
')1(
','4
ˆ
'4
1)(
2
2
22
2
2
2
r
rr
RR
RR
rr
aR
rr
rr
arr
aR
rr
rr
rrRrr
R
rrr
R
ddR
R
dad
ford
dd
for
V
SSVr
(1) If r is outside V, the integral becomes zero in that Laplacian ϕ becomes zero.
S
r
(2) If r is inside V, the integral can be changed into a surface integral over a enclos-ing sphere, which has non-zero value.
integral volume:'r
면적분:'r
r
R'da
r 근방에서의 적분을 계산하기 위해서 r 을 중심으로 하고 반지름이 인 구면에서의 면 적분을 하면 결과는 1 이 나와서 앞 장의 결과가 나온다 .
Calculation of integral 19
EMLAB
Ampere’s law
• Ampere law facilitates calculation of mangetic field like the Gauss law for electric field..
• Unlike Gauss’ law, Ampere’s law is related to line integrals.
• Ampere’s law is discovered experimentally and states that a line integral over a closed path is equal to a current flowing through the closed loop.
• In the left figure, line integrals of H along path a and b is equal to I because the paths enclose cur-rent I completely. But the integral along path c is not equal to I because it does not encloses com-pletely the current I.
path closed
IdsH
10
EMLAB
Example- Coaxial cable
I
I
a b cI
I
002
)4(
2ˆˆ
1
ˆˆ
ˆ2
)3(2
ˆˆ2
)2(2
ˆˆ
ˆ
2ˆ
)1(
22
22
22
22
0
2
0
2
0
0
2
0
2
2
2
0
2
0
2
0
H
H
zJzJ
zJ
H
H
zJaJ
Hs
rH
cr
bc
rc
r
IH
Ibc
br
dddd
ddrH
crbr
IHIrH
braa
rIH
Ia
rddd
rHrddH
ar
a r
b
outin
r
in
r
in
S
C
zJ ˆa
I2in
zJ ˆ)bc(
I22out
H
• The direction of magnetic fields can be found from right hand rule.
• The currents flowing through the inner conductor and outer sheath should have the same magnitude with different polarity to minimize the magnetic flux leakage
11
EMLAB
Example : Surface current
nK
x
xH
s
ˆ20z
2
Kˆ
0z2
Kˆ
KL)L)(H(LHdH x
C
x
• The direction of magnetic field con be conjectured from the right hand rule.
12
EMLAB
Example : Solenoid
)0H(
ˆK
KL)L(HLHdH
out
out
C
in
zH
s
• The direction of magnetic field con be conjectured from the right hand rule.
• If the length of the solenoid be-comes infinite, H field outside be-comes 0.
d
I
13
EMLAB
Example : Torus14
EMLAB
A wire of 3-mm radius is made up of an inner material (0 < ρ < 2 mm) for which σ = 107
S/m, and an outer material (2mm < ρ < 3mm) for which σ = 4×107S/m. If the wire carriesa total current of 100 mA dc, determine H everywhere as a function of ρ.
100mA
2
2mm1
Example problem 8.18
E
1J
2J
EJ 11
]/[10133
)(
]mA[100)(
4
22
12
212
1
22
12
212
1
mVE
ErrEr
JrrJrI
]/[6652
2
1
12
12
mAE
H
EJH
mm2
mm3mm2
EEr
H
ErErH
221
21
22
12
12
1
2
1
2
)(
)(2
mm3
Err
H
ErrErH
2
)(
)(2
22
2212
1
22
12
212
1
15
EMLAB
Example problem 8.9
22
P
x
y
16
EMLAB
Example problem 8.6
S
]rad/s[z
17
EMLAB
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