Let đ�œ‡ rj = 2 in region 1, defined by 2x + 3y â€” 4z > 1, while p r2 = 5 in region 2 where 2 x + 3 y - 4z < 1. In region 1, H 1 = 50a x - 30a y + 20a z A/m. Find (o) HM 1 ; (b) H r1 (c)H r2; (d) H N2 (e) 0 1, the angle between H 1 and a N2 ; (f) 0 2, the angle between H 2 and a N2 ].

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Answer 1

Textbook Question

Chapter 8, Problem 8.27P

Let đ�œ‡_rj = 2 in region 1, defined by 2x + 3y â€” 4z >1, while p_r2 = 5 in region 2 where 2x + 3y - 4z < 1. In region 1, H₁ = 50ax - 30a_y + 20a_z A/m. Find (o) HM₁; (b) H_r1 (c)H_r2; (d) H_N2 (e) 0_1, the angle between H₁ and a_N2; (f) 0_2, the angle between H₂ and a_N2].

Expert Solution

To determine

(a)

The value of H→N1.

Answer to Problem 8.27P

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

Both regions are separated by the surface 2x+3y−4z=1 . So, the unit normal vector,

a^N=1 2 2 + 3 2 + 4 2 (2 ax+3 ay−4 az) =1 29(2 ax+3 ay−4 az)

So, the normal component of magnetic field intensity:

H→N1=(H →1⋅a ^N)a^N =(( 50 a x −30 a y +20 a z )⋅1 29 ( 2 a x +3 a y −4 a z ))1 29(2 ax+3 ay−4 az) =−7029(2 ax+3 ay−4 az) =−4.83 ax−7.24 ay+9.66 az A/m

Conclusion:

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Expert Solution

To determine

(b)

The value of H→t1.

Answer to Problem 8.27P

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→N1=−4.83 ax−7.24 ay+9.66 az A/m

Calculation:

The tangential component of magnetic field intensity:

H→t1=H→1−H→N1=(50 ax−30 ay+20 az)−(−4.83 ax−7.24 ay+9.66 az) =54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(c)

The value of Ht2.

Answer to Problem 8.27P

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t1=54.83 ax−22.76 ay+10.34 az A/m

Calculation:

The tangential components of magnetic field intensity are continuous across the surface between the regions. So:

:

H→t2=H→t1=54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(d)

The value of H→N2.

Answer to Problem 8.27P

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The normal components of magnetic flux density are continuous across the surface between the regions. So,:

B→N1=B→N1 ⇒μr1μ0H→N1=μr2μ0H→N2⇒ H→N2=μ r1μ r2H→N1=25(−4.83 ax−7.24 ay+9.66 az) =−1.93 ax−2.90 ay+3.86 az A/m

Conclusion:

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Expert Solution

To determine

(e)

The angle between H→1 and a^N21.

Answer to Problem 8.27P

The angle between H→1 and a^N21 is, θ1=102°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The unit normal vector:

aN21=129(2 ax+3 ay−4 az)

The required angle:

cosθ1=H →1| H 1|⋅aN21=( 50 a x −30 a y +20 a z ) 50 2 + 30 2 + 20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.21⇒θ1=102°

Conclusion:

The angle between H→1 and a^N21 is, θ1=102°.

Expert Solution

To determine

(f)

The angle between H→2 and a^N21.

Answer to Problem 8.27P

The angle between H→2 and a^N21 is, θ2=95°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t2=54.83 ax−22.76 ay+10.34 az A/mH→N2=−1.93 ax−2.90 ay+3.86 az A/m

Calculation:

The unit normal vector:

a^N21=129(2 ax+3 ay−4 az)

The magnetic field intensity:

H→2=H→t2+H→N2=(54.83 ax−22.76 ay+10.34 az)+(−1.93 ax−2.90 ay+3.86 az) =52.90 ax−25.66 ay+14.20 az A/m

The required angle,

cosθ2=H →2| H 2|⋅aN21=( 52.90 a x −25.66 a y +14.20 a z ) 50.9 2 + 25.66 2 + 14.20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.088⇒θ2=95°

Conclusion:

The angle between H→2 and a^N21 is, θ2=95°.

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Answer 2

Textbook Question

Chapter 8, Problem 8.27P

Let đ�œ‡_rj = 2 in region 1, defined by 2x + 3y â€” 4z >1, while p_r2 = 5 in region 2 where 2x + 3y - 4z < 1. In region 1, H₁ = 50ax - 30a_y + 20a_z A/m. Find (o) HM₁; (b) H_r1 (c)H_r2; (d) H_N2 (e) 0_1, the angle between H₁ and a_N2; (f) 0_2, the angle between H₂ and a_N2].

Expert Solution

To determine

(a)

The value of H→N1.

Answer to Problem 8.27P

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

Both regions are separated by the surface 2x+3y−4z=1 . So, the unit normal vector,

a^N=1 2 2 + 3 2 + 4 2 (2 ax+3 ay−4 az) =1 29(2 ax+3 ay−4 az)

So, the normal component of magnetic field intensity:

H→N1=(H →1⋅a ^N)a^N =(( 50 a x −30 a y +20 a z )⋅1 29 ( 2 a x +3 a y −4 a z ))1 29(2 ax+3 ay−4 az) =−7029(2 ax+3 ay−4 az) =−4.83 ax−7.24 ay+9.66 az A/m

Conclusion:

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Expert Solution

To determine

(b)

The value of H→t1.

Answer to Problem 8.27P

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→N1=−4.83 ax−7.24 ay+9.66 az A/m

Calculation:

The tangential component of magnetic field intensity:

H→t1=H→1−H→N1=(50 ax−30 ay+20 az)−(−4.83 ax−7.24 ay+9.66 az) =54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(c)

The value of Ht2.

Answer to Problem 8.27P

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t1=54.83 ax−22.76 ay+10.34 az A/m

Calculation:

The tangential components of magnetic field intensity are continuous across the surface between the regions. So:

:

H→t2=H→t1=54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(d)

The value of H→N2.

Answer to Problem 8.27P

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The normal components of magnetic flux density are continuous across the surface between the regions. So,:

B→N1=B→N1 ⇒μr1μ0H→N1=μr2μ0H→N2⇒ H→N2=μ r1μ r2H→N1=25(−4.83 ax−7.24 ay+9.66 az) =−1.93 ax−2.90 ay+3.86 az A/m

Conclusion:

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Expert Solution

To determine

(e)

The angle between H→1 and a^N21.

Answer to Problem 8.27P

The angle between H→1 and a^N21 is, θ1=102°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The unit normal vector:

aN21=129(2 ax+3 ay−4 az)

The required angle:

cosθ1=H →1| H 1|⋅aN21=( 50 a x −30 a y +20 a z ) 50 2 + 30 2 + 20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.21⇒θ1=102°

Conclusion:

The angle between H→1 and a^N21 is, θ1=102°.

Expert Solution

To determine

(f)

The angle between H→2 and a^N21.

Answer to Problem 8.27P

The angle between H→2 and a^N21 is, θ2=95°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t2=54.83 ax−22.76 ay+10.34 az A/mH→N2=−1.93 ax−2.90 ay+3.86 az A/m

Calculation:

The unit normal vector:

a^N21=129(2 ax+3 ay−4 az)

The magnetic field intensity:

H→2=H→t2+H→N2=(54.83 ax−22.76 ay+10.34 az)+(−1.93 ax−2.90 ay+3.86 az) =52.90 ax−25.66 ay+14.20 az A/m

The required angle,

cosθ2=H →2| H 2|⋅aN21=( 52.90 a x −25.66 a y +14.20 a z ) 50.9 2 + 25.66 2 + 14.20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.088⇒θ2=95°

Conclusion:

The angle between H→2 and a^N21 is, θ2=95°.

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Answer 3

Textbook Question

Chapter 8, Problem 8.27P

Let đ�œ‡_rj = 2 in region 1, defined by 2x + 3y â€” 4z >1, while p_r2 = 5 in region 2 where 2x + 3y - 4z < 1. In region 1, H₁ = 50ax - 30a_y + 20a_z A/m. Find (o) HM₁; (b) H_r1 (c)H_r2; (d) H_N2 (e) 0_1, the angle between H₁ and a_N2; (f) 0_2, the angle between H₂ and a_N2].

Expert Solution

To determine

(a)

The value of H→N1.

Answer to Problem 8.27P

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

Both regions are separated by the surface 2x+3y−4z=1 . So, the unit normal vector,

a^N=1 2 2 + 3 2 + 4 2 (2 ax+3 ay−4 az) =1 29(2 ax+3 ay−4 az)

So, the normal component of magnetic field intensity:

H→N1=(H →1⋅a ^N)a^N =(( 50 a x −30 a y +20 a z )⋅1 29 ( 2 a x +3 a y −4 a z ))1 29(2 ax+3 ay−4 az) =−7029(2 ax+3 ay−4 az) =−4.83 ax−7.24 ay+9.66 az A/m

Conclusion:

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Expert Solution

To determine

(b)

The value of H→t1.

Answer to Problem 8.27P

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→N1=−4.83 ax−7.24 ay+9.66 az A/m

Calculation:

The tangential component of magnetic field intensity:

H→t1=H→1−H→N1=(50 ax−30 ay+20 az)−(−4.83 ax−7.24 ay+9.66 az) =54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(c)

The value of Ht2.

Answer to Problem 8.27P

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t1=54.83 ax−22.76 ay+10.34 az A/m

Calculation:

The tangential components of magnetic field intensity are continuous across the surface between the regions. So:

:

H→t2=H→t1=54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(d)

The value of H→N2.

Answer to Problem 8.27P

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The normal components of magnetic flux density are continuous across the surface between the regions. So,:

B→N1=B→N1 ⇒μr1μ0H→N1=μr2μ0H→N2⇒ H→N2=μ r1μ r2H→N1=25(−4.83 ax−7.24 ay+9.66 az) =−1.93 ax−2.90 ay+3.86 az A/m

Conclusion:

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Expert Solution

To determine

(e)

The angle between H→1 and a^N21.

Answer to Problem 8.27P

The angle between H→1 and a^N21 is, θ1=102°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The unit normal vector:

aN21=129(2 ax+3 ay−4 az)

The required angle:

cosθ1=H →1| H 1|⋅aN21=( 50 a x −30 a y +20 a z ) 50 2 + 30 2 + 20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.21⇒θ1=102°

Conclusion:

The angle between H→1 and a^N21 is, θ1=102°.

Expert Solution

To determine

(f)

The angle between H→2 and a^N21.

Answer to Problem 8.27P

The angle between H→2 and a^N21 is, θ2=95°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t2=54.83 ax−22.76 ay+10.34 az A/mH→N2=−1.93 ax−2.90 ay+3.86 az A/m

Calculation:

The unit normal vector:

a^N21=129(2 ax+3 ay−4 az)

The magnetic field intensity:

H→2=H→t2+H→N2=(54.83 ax−22.76 ay+10.34 az)+(−1.93 ax−2.90 ay+3.86 az) =52.90 ax−25.66 ay+14.20 az A/m

The required angle,

cosθ2=H →2| H 2|⋅aN21=( 52.90 a x −25.66 a y +14.20 a z ) 50.9 2 + 25.66 2 + 14.20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.088⇒θ2=95°

Conclusion:

The angle between H→2 and a^N21 is, θ2=95°.

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Answer 4

Textbook Question

Chapter 8, Problem 8.27P

Let đ�œ‡_rj = 2 in region 1, defined by 2x + 3y â€” 4z >1, while p_r2 = 5 in region 2 where 2x + 3y - 4z < 1. In region 1, H₁ = 50ax - 30a_y + 20a_z A/m. Find (o) HM₁; (b) H_r1 (c)H_r2; (d) H_N2 (e) 0_1, the angle between H₁ and a_N2; (f) 0_2, the angle between H₂ and a_N2].

Expert Solution

To determine

(a)

The value of H→N1.

Answer to Problem 8.27P

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

Both regions are separated by the surface 2x+3y−4z=1 . So, the unit normal vector,

a^N=1 2 2 + 3 2 + 4 2 (2 ax+3 ay−4 az) =1 29(2 ax+3 ay−4 az)

So, the normal component of magnetic field intensity:

H→N1=(H →1⋅a ^N)a^N =(( 50 a x −30 a y +20 a z )⋅1 29 ( 2 a x +3 a y −4 a z ))1 29(2 ax+3 ay−4 az) =−7029(2 ax+3 ay−4 az) =−4.83 ax−7.24 ay+9.66 az A/m

Conclusion:

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Expert Solution

To determine

(b)

The value of H→t1.

Answer to Problem 8.27P

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→N1=−4.83 ax−7.24 ay+9.66 az A/m

Calculation:

The tangential component of magnetic field intensity:

H→t1=H→1−H→N1=(50 ax−30 ay+20 az)−(−4.83 ax−7.24 ay+9.66 az) =54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(c)

The value of Ht2.

Answer to Problem 8.27P

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t1=54.83 ax−22.76 ay+10.34 az A/m

Calculation:

The tangential components of magnetic field intensity are continuous across the surface between the regions. So:

:

H→t2=H→t1=54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(d)

The value of H→N2.

Answer to Problem 8.27P

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The normal components of magnetic flux density are continuous across the surface between the regions. So,:

B→N1=B→N1 ⇒μr1μ0H→N1=μr2μ0H→N2⇒ H→N2=μ r1μ r2H→N1=25(−4.83 ax−7.24 ay+9.66 az) =−1.93 ax−2.90 ay+3.86 az A/m

Conclusion:

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Expert Solution

To determine

(e)

The angle between H→1 and a^N21.

Answer to Problem 8.27P

The angle between H→1 and a^N21 is, θ1=102°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The unit normal vector:

aN21=129(2 ax+3 ay−4 az)

The required angle:

cosθ1=H →1| H 1|⋅aN21=( 50 a x −30 a y +20 a z ) 50 2 + 30 2 + 20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.21⇒θ1=102°

Conclusion:

The angle between H→1 and a^N21 is, θ1=102°.

Expert Solution

To determine

(f)

The angle between H→2 and a^N21.

Answer to Problem 8.27P

The angle between H→2 and a^N21 is, θ2=95°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t2=54.83 ax−22.76 ay+10.34 az A/mH→N2=−1.93 ax−2.90 ay+3.86 az A/m

Calculation:

The unit normal vector:

a^N21=129(2 ax+3 ay−4 az)

The magnetic field intensity:

H→2=H→t2+H→N2=(54.83 ax−22.76 ay+10.34 az)+(−1.93 ax−2.90 ay+3.86 az) =52.90 ax−25.66 ay+14.20 az A/m

The required angle,

cosθ2=H →2| H 2|⋅aN21=( 52.90 a x −25.66 a y +14.20 a z ) 50.9 2 + 25.66 2 + 14.20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.088⇒θ2=95°

Conclusion:

The angle between H→2 and a^N21 is, θ2=95°.

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Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution

To determine

(a)

The value of H→N1.

Answer to Problem 8.27P

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

Both regions are separated by the surface 2x+3y−4z=1 . So, the unit normal vector,

a^N=1 2 2 + 3 2 + 4 2 (2 ax+3 ay−4 az) =1 29(2 ax+3 ay−4 az)

So, the normal component of magnetic field intensity:

H→N1=(H →1⋅a ^N)a^N =(( 50 a x −30 a y +20 a z )⋅1 29 ( 2 a x +3 a y −4 a z ))1 29(2 ax+3 ay−4 az) =−7029(2 ax+3 ay−4 az) =−4.83 ax−7.24 ay+9.66 az A/m

Conclusion:

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Expert Solution

To determine

(b)

The value of H→t1.

Answer to Problem 8.27P

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→N1=−4.83 ax−7.24 ay+9.66 az A/m

Calculation:

The tangential component of magnetic field intensity:

H→t1=H→1−H→N1=(50 ax−30 ay+20 az)−(−4.83 ax−7.24 ay+9.66 az) =54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(c)

The value of Ht2.

Answer to Problem 8.27P

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t1=54.83 ax−22.76 ay+10.34 az A/m

Calculation:

The tangential components of magnetic field intensity are continuous across the surface between the regions. So:

:

H→t2=H→t1=54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Expert Solution

To determine

(d)

The value of H→N2.

Answer to Problem 8.27P

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The normal components of magnetic flux density are continuous across the surface between the regions. So,:

B→N1=B→N1 ⇒μr1μ0H→N1=μr2μ0H→N2⇒ H→N2=μ r1μ r2H→N1=25(−4.83 ax−7.24 ay+9.66 az) =−1.93 ax−2.90 ay+3.86 az A/m

Conclusion:

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Expert Solution

To determine

(e)

The angle between H→1 and a^N21.

Answer to Problem 8.27P

The angle between H→1 and a^N21 is, θ1=102°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The unit normal vector:

aN21=129(2 ax+3 ay−4 az)

The required angle:

cosθ1=H →1| H 1|⋅aN21=( 50 a x −30 a y +20 a z ) 50 2 + 30 2 + 20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.21⇒θ1=102°

Conclusion:

The angle between H→1 and a^N21 is, θ1=102°.

Expert Solution

To determine

(f)

The angle between H→2 and a^N21.

Answer to Problem 8.27P

The angle between H→2 and a^N21 is, θ2=95°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t2=54.83 ax−22.76 ay+10.34 az A/mH→N2=−1.93 ax−2.90 ay+3.86 az A/m

Calculation:

The unit normal vector:

a^N21=129(2 ax+3 ay−4 az)

The magnetic field intensity:

H→2=H→t2+H→N2=(54.83 ax−22.76 ay+10.34 az)+(−1.93 ax−2.90 ay+3.86 az) =52.90 ax−25.66 ay+14.20 az A/m

The required angle,

cosθ2=H →2| H 2|⋅aN21=( 52.90 a x −25.66 a y +14.20 a z ) 50.9 2 + 25.66 2 + 14.20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.088⇒θ2=95°

Conclusion:

The angle between H→2 and a^N21 is, θ2=95°.

Answer 8

Expert Solution

To determine

(a)

The value of H→N1.

Answer to Problem 8.27P

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

Both regions are separated by the surface 2x+3y−4z=1 . So, the unit normal vector,

a^N=1 2 2 + 3 2 + 4 2 (2 ax+3 ay−4 az) =1 29(2 ax+3 ay−4 az)

So, the normal component of magnetic field intensity:

H→N1=(H →1⋅a ^N)a^N =(( 50 a x −30 a y +20 a z )⋅1 29 ( 2 a x +3 a y −4 a z ))1 29(2 ax+3 ay−4 az) =−7029(2 ax+3 ay−4 az) =−4.83 ax−7.24 ay+9.66 az A/m

Conclusion:

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Answer 9

Expert Solution

Answer 10

Expert Solution

Answer 11

Expert Solution

Answer 12

To determine

(a)

The value of H→N1.

Answer 13

Answer to Problem 8.27P

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Answer 14

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

Both regions are separated by the surface 2x+3y−4z=1 . So, the unit normal vector,

a^N=1 2 2 + 3 2 + 4 2 (2 ax+3 ay−4 az) =1 29(2 ax+3 ay−4 az)

So, the normal component of magnetic field intensity:

H→N1=(H →1⋅a ^N)a^N =(( 50 a x −30 a y +20 a z )⋅1 29 ( 2 a x +3 a y −4 a z ))1 29(2 ax+3 ay−4 az) =−7029(2 ax+3 ay−4 az) =−4.83 ax−7.24 ay+9.66 az A/m

Conclusion:

The required value is, H→N1=−4.83 ax−7.24 ay+9.66 az A/m.

Answer 15

Expert Solution

To determine

(b)

The value of H→t1.

Answer to Problem 8.27P

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→N1=−4.83 ax−7.24 ay+9.66 az A/m

Calculation:

The tangential component of magnetic field intensity:

H→t1=H→1−H→N1=(50 ax−30 ay+20 az)−(−4.83 ax−7.24 ay+9.66 az) =54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Answer 16

Expert Solution

Answer 17

Expert Solution

Answer 18

Expert Solution

Answer 19

To determine

(b)

The value of H→t1.

Answer 20

Answer to Problem 8.27P

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Answer 21

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→N1=−4.83 ax−7.24 ay+9.66 az A/m

Calculation:

The tangential component of magnetic field intensity:

H→t1=H→1−H→N1=(50 ax−30 ay+20 az)−(−4.83 ax−7.24 ay+9.66 az) =54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t1=54.83 ax−22.76 ay+10.34 az A/m.

Answer 22

Expert Solution

To determine

(c)

The value of Ht2.

Answer to Problem 8.27P

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t1=54.83 ax−22.76 ay+10.34 az A/m

Calculation:

The tangential components of magnetic field intensity are continuous across the surface between the regions. So:

:

H→t2=H→t1=54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Answer 23

Expert Solution

Answer 24

Expert Solution

Answer 25

Expert Solution

Answer 26

To determine

(c)

The value of Ht2.

Answer 27

Answer to Problem 8.27P

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Answer 28

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t1=54.83 ax−22.76 ay+10.34 az A/m

Calculation:

The tangential components of magnetic field intensity are continuous across the surface between the regions. So:

:

H→t2=H→t1=54.83 ax−22.76 ay+10.34 az A/m

Conclusion:

The required value is, H→t2=54.83 ax−22.76 ay+10.34 az A/m.

Answer 29

Expert Solution

To determine

(d)

The value of H→N2.

Answer to Problem 8.27P

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The normal components of magnetic flux density are continuous across the surface between the regions. So,:

B→N1=B→N1 ⇒μr1μ0H→N1=μr2μ0H→N2⇒ H→N2=μ r1μ r2H→N1=25(−4.83 ax−7.24 ay+9.66 az) =−1.93 ax−2.90 ay+3.86 az A/m

Conclusion:

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Answer 30

Expert Solution

Answer 31

Expert Solution

Answer 32

Expert Solution

Answer 33

To determine

(d)

The value of H→N2.

Answer 34

Answer to Problem 8.27P

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Answer 35

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The normal components of magnetic flux density are continuous across the surface between the regions. So,:

B→N1=B→N1 ⇒μr1μ0H→N1=μr2μ0H→N2⇒ H→N2=μ r1μ r2H→N1=25(−4.83 ax−7.24 ay+9.66 az) =−1.93 ax−2.90 ay+3.86 az A/m

Conclusion:

The required value is, H→N2=−1.93 ax−2.90 ay+3.86 az A/m.

Answer 36

Expert Solution

To determine

(e)

The angle between H→1 and a^N21.

Answer to Problem 8.27P

The angle between H→1 and a^N21 is, θ1=102°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The unit normal vector:

aN21=129(2 ax+3 ay−4 az)

The required angle:

cosθ1=H →1| H 1|⋅aN21=( 50 a x −30 a y +20 a z ) 50 2 + 30 2 + 20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.21⇒θ1=102°

Conclusion:

The angle between H→1 and a^N21 is, θ1=102°.

Answer 37

Expert Solution

Answer 38

Expert Solution

Answer 39

Expert Solution

Answer 40

To determine

(e)

The angle between H→1 and a^N21.

Answer 41

Answer to Problem 8.27P

The angle between H→1 and a^N21 is, θ1=102°.

Answer 42

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/m

Calculation:

The unit normal vector:

aN21=129(2 ax+3 ay−4 az)

The required angle:

cosθ1=H →1| H 1|⋅aN21=( 50 a x −30 a y +20 a z ) 50 2 + 30 2 + 20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.21⇒θ1=102°

Conclusion:

The angle between H→1 and a^N21 is, θ1=102°.

Answer 43

Expert Solution

To determine

(f)

The angle between H→2 and a^N21.

Answer to Problem 8.27P

The angle between H→2 and a^N21 is, θ2=95°.

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t2=54.83 ax−22.76 ay+10.34 az A/mH→N2=−1.93 ax−2.90 ay+3.86 az A/m

Calculation:

The unit normal vector:

a^N21=129(2 ax+3 ay−4 az)

The magnetic field intensity:

H→2=H→t2+H→N2=(54.83 ax−22.76 ay+10.34 az)+(−1.93 ax−2.90 ay+3.86 az) =52.90 ax−25.66 ay+14.20 az A/m

The required angle,

cosθ2=H →2| H 2|⋅aN21=( 52.90 a x −25.66 a y +14.20 a z ) 50.9 2 + 25.66 2 + 14.20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.088⇒θ2=95°

Conclusion:

The angle between H→2 and a^N21 is, θ2=95°.

Answer 44

Expert Solution

Answer 45

Expert Solution

Answer 46

Expert Solution

Answer 47

To determine

(f)

The angle between H→2 and a^N21.

Answer 48

Answer to Problem 8.27P

The angle between H→2 and a^N21 is, θ2=95°.

Answer 49

Explanation of Solution

Given Information:

The region 1 is 2x+3y−4z>1 , and region 2 is 2x+3y−4z<1.

μr1=2μr2=5H→1=50 ax−30 ay+20 az A/mH→t2=54.83 ax−22.76 ay+10.34 az A/mH→N2=−1.93 ax−2.90 ay+3.86 az A/m

Calculation:

The unit normal vector:

a^N21=129(2 ax+3 ay−4 az)

The magnetic field intensity:

H→2=H→t2+H→N2=(54.83 ax−22.76 ay+10.34 az)+(−1.93 ax−2.90 ay+3.86 az) =52.90 ax−25.66 ay+14.20 az A/m

The required angle,

cosθ2=H →2| H 2|⋅aN21=( 52.90 a x −25.66 a y +14.20 a z ) 50.9 2 + 25.66 2 + 14.20 2 ⋅1 29(2 ax+3 ay−4 az) =−0.088⇒θ2=95°

Conclusion:

The angle between H→2 and a^N21 is, θ2=95°.

Answer 50

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Let đ�œ‡ rj = 2 in region 1, defined by 2x + 3y â€” 4z > 1, while p r2 = 5 in region 2 where 2 x + 3 y - 4z < 1. In region 1, H 1 = 50a x - 30a y + 20a z A/m. Find (o) HM 1 ; (b) H r1 (c)H r2; (d) H N2 (e) 0 1, the angle between H 1 and a N2 ; (f) 0 2, the angle between H 2 and a N2 ].

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