Consider the TE 11 mode in a rectangular guide having width a and height b. Using Eqs. (96d) and ( 96e), along with methods described in Chapter 2, Section 2.6, show that the equation for the streamlines for this field (at z = 0) is y = b π cos − 1 [ C cos ( π x / a ) ] ( 0 < x < a , 0 < y , b ) where C is a constant that identifies a given streamline.

Question

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Answer 1

Textbook Question

Chapter 13, Problem 13.22P

Consider the TE₁₁ mode in a rectangular guide having width a and height b. Using Eqs. (96d) and (96e), along with methods described in Chapter 2, Section 2.6, show that the equation for the streamlines for this field (at z = 0) is y = b π cos − 1 [ C cos ( π x / a ) ] ( 0 < x < a , 0 < y , b )

where C is a constant that identifies a given streamline.

Expert Solution & Answer

To determine

To prove:

The equation for the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Explanation of Solution

Given:

Width = a

Hight = b

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

Mode = TE11

TE11=TEmpm=1p=1

0≤x≤a0≤y≤b

Concept used:

Formula to calculate equation for the streamlines is shown below:

dydx=EyEx

Calculation:

Although,

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

∵km=mπakp=pπb

Therefore,

km=πakp=πb

Plugging value of k_m and k_p in transverse electric field equation,

Exs=jωμkpk mp2Acos(πax)sin(πby)e−jβ mpz V/mEys=−jωμkmk mp2Asin(πax)cos(πby)e−jβ mpz V/m

Since,

dydx=EyEx

Hence,

dydx=jωμ k p k mp 2 Asin( π a x)cos( π b y)e −j β mp z−jωμ k p k mp 2 Acos( π a x)sin( π b y)e −j β mp zdydx=bsin( π a x)cos( π b y)−acos( π a x)sin( π b y)dydx=−btan( π a x)atan( π b y)

tan(πby)dy=−batan(πax)dxIntegrating both sides with limits,∫tan( π b y)dy=−ba∫tan( π a x)dx[−bπlncosπby+c1]=−ba[aπlncosπax+c2]

For boundary condition of x and y final equivalent of above integral is shown below:

cos( yπb)⋅cos( xπa)=C (C=constant)y=bπcos−1[Ccos( πx/a)]

Conclusion:

Hence,the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

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Answer 2

Textbook Question

Chapter 13, Problem 13.22P

Consider the TE₁₁ mode in a rectangular guide having width a and height b. Using Eqs. (96d) and (96e), along with methods described in Chapter 2, Section 2.6, show that the equation for the streamlines for this field (at z = 0) is y = b π cos − 1 [ C cos ( π x / a ) ] ( 0 < x < a , 0 < y , b )

where C is a constant that identifies a given streamline.

Expert Solution & Answer

To determine

To prove:

The equation for the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Explanation of Solution

Given:

Width = a

Hight = b

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

Mode = TE11

TE11=TEmpm=1p=1

0≤x≤a0≤y≤b

Concept used:

Formula to calculate equation for the streamlines is shown below:

dydx=EyEx

Calculation:

Although,

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

∵km=mπakp=pπb

Therefore,

km=πakp=πb

Plugging value of k_m and k_p in transverse electric field equation,

Exs=jωμkpk mp2Acos(πax)sin(πby)e−jβ mpz V/mEys=−jωμkmk mp2Asin(πax)cos(πby)e−jβ mpz V/m

Since,

dydx=EyEx

Hence,

dydx=jωμ k p k mp 2 Asin( π a x)cos( π b y)e −j β mp z−jωμ k p k mp 2 Acos( π a x)sin( π b y)e −j β mp zdydx=bsin( π a x)cos( π b y)−acos( π a x)sin( π b y)dydx=−btan( π a x)atan( π b y)

tan(πby)dy=−batan(πax)dxIntegrating both sides with limits,∫tan( π b y)dy=−ba∫tan( π a x)dx[−bπlncosπby+c1]=−ba[aπlncosπax+c2]

For boundary condition of x and y final equivalent of above integral is shown below:

cos( yπb)⋅cos( xπa)=C (C=constant)y=bπcos−1[Ccos( πx/a)]

Conclusion:

Hence,the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

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Answer 3

Textbook Question

Chapter 13, Problem 13.22P

Consider the TE₁₁ mode in a rectangular guide having width a and height b. Using Eqs. (96d) and (96e), along with methods described in Chapter 2, Section 2.6, show that the equation for the streamlines for this field (at z = 0) is y = b π cos − 1 [ C cos ( π x / a ) ] ( 0 < x < a , 0 < y , b )

where C is a constant that identifies a given streamline.

Expert Solution & Answer

To determine

To prove:

The equation for the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Explanation of Solution

Given:

Width = a

Hight = b

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

Mode = TE11

TE11=TEmpm=1p=1

0≤x≤a0≤y≤b

Concept used:

Formula to calculate equation for the streamlines is shown below:

dydx=EyEx

Calculation:

Although,

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

∵km=mπakp=pπb

Therefore,

km=πakp=πb

Plugging value of k_m and k_p in transverse electric field equation,

Exs=jωμkpk mp2Acos(πax)sin(πby)e−jβ mpz V/mEys=−jωμkmk mp2Asin(πax)cos(πby)e−jβ mpz V/m

Since,

dydx=EyEx

Hence,

dydx=jωμ k p k mp 2 Asin( π a x)cos( π b y)e −j β mp z−jωμ k p k mp 2 Acos( π a x)sin( π b y)e −j β mp zdydx=bsin( π a x)cos( π b y)−acos( π a x)sin( π b y)dydx=−btan( π a x)atan( π b y)

tan(πby)dy=−batan(πax)dxIntegrating both sides with limits,∫tan( π b y)dy=−ba∫tan( π a x)dx[−bπlncosπby+c1]=−ba[aπlncosπax+c2]

For boundary condition of x and y final equivalent of above integral is shown below:

cos( yπb)⋅cos( xπa)=C (C=constant)y=bπcos−1[Ccos( πx/a)]

Conclusion:

Hence,the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

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Answer 4

Textbook Question

Chapter 13, Problem 13.22P

Consider the TE₁₁ mode in a rectangular guide having width a and height b. Using Eqs. (96d) and (96e), along with methods described in Chapter 2, Section 2.6, show that the equation for the streamlines for this field (at z = 0) is y = b π cos − 1 [ C cos ( π x / a ) ] ( 0 < x < a , 0 < y , b )

where C is a constant that identifies a given streamline.

Expert Solution & Answer

To determine

To prove:

The equation for the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Explanation of Solution

Given:

Width = a

Hight = b

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

Mode = TE11

TE11=TEmpm=1p=1

0≤x≤a0≤y≤b

Concept used:

Formula to calculate equation for the streamlines is shown below:

dydx=EyEx

Calculation:

Although,

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

∵km=mπakp=pπb

Therefore,

km=πakp=πb

Plugging value of k_m and k_p in transverse electric field equation,

Exs=jωμkpk mp2Acos(πax)sin(πby)e−jβ mpz V/mEys=−jωμkmk mp2Asin(πax)cos(πby)e−jβ mpz V/m

Since,

dydx=EyEx

Hence,

dydx=jωμ k p k mp 2 Asin( π a x)cos( π b y)e −j β mp z−jωμ k p k mp 2 Acos( π a x)sin( π b y)e −j β mp zdydx=bsin( π a x)cos( π b y)−acos( π a x)sin( π b y)dydx=−btan( π a x)atan( π b y)

tan(πby)dy=−batan(πax)dxIntegrating both sides with limits,∫tan( π b y)dy=−ba∫tan( π a x)dx[−bπlncosπby+c1]=−ba[aπlncosπax+c2]

For boundary condition of x and y final equivalent of above integral is shown below:

cos( yπb)⋅cos( xπa)=C (C=constant)y=bπcos−1[Ccos( πx/a)]

Conclusion:

Hence,the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

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Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

To prove:

The equation for the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Explanation of Solution

Given:

Width = a

Hight = b

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

Mode = TE11

TE11=TEmpm=1p=1

0≤x≤a0≤y≤b

Concept used:

Formula to calculate equation for the streamlines is shown below:

dydx=EyEx

Calculation:

Although,

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

∵km=mπakp=pπb

Therefore,

km=πakp=πb

Plugging value of k_m and k_p in transverse electric field equation,

Exs=jωμkpk mp2Acos(πax)sin(πby)e−jβ mpz V/mEys=−jωμkmk mp2Asin(πax)cos(πby)e−jβ mpz V/m

Since,

dydx=EyEx

Hence,

dydx=jωμ k p k mp 2 Asin( π a x)cos( π b y)e −j β mp z−jωμ k p k mp 2 Acos( π a x)sin( π b y)e −j β mp zdydx=bsin( π a x)cos( π b y)−acos( π a x)sin( π b y)dydx=−btan( π a x)atan( π b y)

tan(πby)dy=−batan(πax)dxIntegrating both sides with limits,∫tan( π b y)dy=−ba∫tan( π a x)dx[−bπlncosπby+c1]=−ba[aπlncosπax+c2]

For boundary condition of x and y final equivalent of above integral is shown below:

cos( yπb)⋅cos( xπa)=C (C=constant)y=bπcos−1[Ccos( πx/a)]

Conclusion:

Hence,the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Answer 8

Expert Solution & Answer

To determine

To prove:

The equation for the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Explanation of Solution

Given:

Width = a

Hight = b

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

Mode = TE11

TE11=TEmpm=1p=1

0≤x≤a0≤y≤b

Concept used:

Formula to calculate equation for the streamlines is shown below:

dydx=EyEx

Calculation:

Although,

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

∵km=mπakp=pπb

Therefore,

km=πakp=πb

Plugging value of k_m and k_p in transverse electric field equation,

Exs=jωμkpk mp2Acos(πax)sin(πby)e−jβ mpz V/mEys=−jωμkmk mp2Asin(πax)cos(πby)e−jβ mpz V/m

Since,

dydx=EyEx

Hence,

dydx=jωμ k p k mp 2 Asin( π a x)cos( π b y)e −j β mp z−jωμ k p k mp 2 Acos( π a x)sin( π b y)e −j β mp zdydx=bsin( π a x)cos( π b y)−acos( π a x)sin( π b y)dydx=−btan( π a x)atan( π b y)

tan(πby)dy=−batan(πax)dxIntegrating both sides with limits,∫tan( π b y)dy=−ba∫tan( π a x)dx[−bπlncosπby+c1]=−ba[aπlncosπax+c2]

For boundary condition of x and y final equivalent of above integral is shown below:

cos( yπb)⋅cos( xπa)=C (C=constant)y=bπcos−1[Ccos( πx/a)]

Conclusion:

Hence,the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

To prove:

The equation for the streamlines for transverse electric field Exs and Eys for TE11 mode in a rectangular is

y=bπcos−1[Ccos(πx/a)]

Answer 12

Explanation of Solution

Given:

Width = a

Hight = b

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

Mode = TE11

TE11=TEmpm=1p=1

0≤x≤a0≤y≤b

Concept used:

Formula to calculate equation for the streamlines is shown below:

dydx=EyEx

Calculation:

Although,

Exs=jωμkpk mp2Acos(kmx)sin(kpy)e−jβ mpz V/mEys=−jωμkpk mp2Asin(kmx)cos(kpy)e−jβ mpz V/m

∵km=mπakp=pπb

Therefore,

km=πakp=πb

Plugging value of k_m and k_p in transverse electric field equation,

Exs=jωμkpk mp2Acos(πax)sin(πby)e−jβ mpz V/mEys=−jωμkmk mp2Asin(πax)cos(πby)e−jβ mpz V/m

Since,

dydx=EyEx

Hence,

dydx=jωμ k p k mp 2 Asin( π a x)cos( π b y)e −j β mp z−jωμ k p k mp 2 Acos( π a x)sin( π b y)e −j β mp zdydx=bsin( π a x)cos( π b y)−acos( π a x)sin( π b y)dydx=−btan( π a x)atan( π b y)