Calculate the electric field at ( 2 , − 2 , 3 ) .

Question

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Answer 1

Question

Chapter 6, Problem 69P

(a)

To determine

Calculate the electric field at (2, −2, 3).

(a)

Expert Solution

Answer to Problem 69P

The electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Explanation of Solution

Calculation:

Write the expression for the electric field.

E=E++E−=ρL2πεo(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, 10−936π F⋅m−1 for εo, (2,−2,3)−(3,−2,4) for aρ1, and (2,−2,3)−(3,−2,−4) for aρ2.

E=16 nC/m2π(10−936π F⋅m−1)((2,−2,3)−(3,−2,4)|(2,−2,3)−(3,−2,4)|2−(2,−2,3)−(3,−2,−4)|(2,−2,3)−(3,−2,−4)|2)1m=(18×16) [(−1,0,−1)2−(−1,0,7)50] {∵C=F⋅V}=−138.2ax−184.3ay Vm

Conclusion:

Thus, the electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

(b)

To determine

Find the induced surface charge density on the conducting plane at (5,−6,0).

(b)

Expert Solution

Answer to Problem 69P

The induced surface charge density is −1.018 nCm2_.

Explanation of Solution

Calculation:

Consider the expression for the induced surface charge density.

ρs=Dn (1)

Calculate the displacement field vector.

D=D++D−=ρL2π(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, (5,−6,0)−(3,−6,4) for aρ1, and (5,−6,0)−(3,−6,−4) for aρ2.

D=16 nC/m2π((5,−6,0)−(3,−6,4)|(5,−6,0)−(3,−6,4)|2−(5,−6,0)−(3,−6,−4)|(5,−6,0)−(3,−6,−4)|2)1m=(8π) [(2,0,−4)20−(2,0,4)20] nCm2 =−1.018az nCm2

The above equation is compared with the general expression D=Dnaz, the value of Dn is −1.018 nCm2.

Substitute −1.018 nCm2 for Dn in Equation (1).

ρs=−1.018 nCm2

Conclusion:

Thus, the induced surface charge density is −1.018 nCm2_.

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Generate the kinematic diagram of the following mechanisms using the given symbols. Then, draw their graphs and calculate their degrees of freedom (DoF) using Gruebler's formula. PUNTO 2. PUNTO 3. !!!

Answer 2

Question

Chapter 6, Problem 69P

(a)

To determine

Calculate the electric field at (2, −2, 3).

(a)

Expert Solution

Answer to Problem 69P

The electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Explanation of Solution

Calculation:

Write the expression for the electric field.

E=E++E−=ρL2πεo(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, 10−936π F⋅m−1 for εo, (2,−2,3)−(3,−2,4) for aρ1, and (2,−2,3)−(3,−2,−4) for aρ2.

E=16 nC/m2π(10−936π F⋅m−1)((2,−2,3)−(3,−2,4)|(2,−2,3)−(3,−2,4)|2−(2,−2,3)−(3,−2,−4)|(2,−2,3)−(3,−2,−4)|2)1m=(18×16) [(−1,0,−1)2−(−1,0,7)50] {∵C=F⋅V}=−138.2ax−184.3ay Vm

Conclusion:

Thus, the electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

(b)

To determine

Find the induced surface charge density on the conducting plane at (5,−6,0).

(b)

Expert Solution

Answer to Problem 69P

The induced surface charge density is −1.018 nCm2_.

Explanation of Solution

Calculation:

Consider the expression for the induced surface charge density.

ρs=Dn (1)

Calculate the displacement field vector.

D=D++D−=ρL2π(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, (5,−6,0)−(3,−6,4) for aρ1, and (5,−6,0)−(3,−6,−4) for aρ2.

D=16 nC/m2π((5,−6,0)−(3,−6,4)|(5,−6,0)−(3,−6,4)|2−(5,−6,0)−(3,−6,−4)|(5,−6,0)−(3,−6,−4)|2)1m=(8π) [(2,0,−4)20−(2,0,4)20] nCm2 =−1.018az nCm2

The above equation is compared with the general expression D=Dnaz, the value of Dn is −1.018 nCm2.

Substitute −1.018 nCm2 for Dn in Equation (1).

ρs=−1.018 nCm2

Conclusion:

Thus, the induced surface charge density is −1.018 nCm2_.

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Answer 3

Question

Chapter 6, Problem 69P

(a)

To determine

Calculate the electric field at (2, −2, 3).

(a)

Expert Solution

Answer to Problem 69P

The electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Explanation of Solution

Calculation:

Write the expression for the electric field.

E=E++E−=ρL2πεo(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, 10−936π F⋅m−1 for εo, (2,−2,3)−(3,−2,4) for aρ1, and (2,−2,3)−(3,−2,−4) for aρ2.

E=16 nC/m2π(10−936π F⋅m−1)((2,−2,3)−(3,−2,4)|(2,−2,3)−(3,−2,4)|2−(2,−2,3)−(3,−2,−4)|(2,−2,3)−(3,−2,−4)|2)1m=(18×16) [(−1,0,−1)2−(−1,0,7)50] {∵C=F⋅V}=−138.2ax−184.3ay Vm

Conclusion:

Thus, the electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

(b)

To determine

Find the induced surface charge density on the conducting plane at (5,−6,0).

(b)

Expert Solution

Answer to Problem 69P

The induced surface charge density is −1.018 nCm2_.

Explanation of Solution

Calculation:

Consider the expression for the induced surface charge density.

ρs=Dn (1)

Calculate the displacement field vector.

D=D++D−=ρL2π(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, (5,−6,0)−(3,−6,4) for aρ1, and (5,−6,0)−(3,−6,−4) for aρ2.

D=16 nC/m2π((5,−6,0)−(3,−6,4)|(5,−6,0)−(3,−6,4)|2−(5,−6,0)−(3,−6,−4)|(5,−6,0)−(3,−6,−4)|2)1m=(8π) [(2,0,−4)20−(2,0,4)20] nCm2 =−1.018az nCm2

The above equation is compared with the general expression D=Dnaz, the value of Dn is −1.018 nCm2.

Substitute −1.018 nCm2 for Dn in Equation (1).

ρs=−1.018 nCm2

Conclusion:

Thus, the induced surface charge density is −1.018 nCm2_.

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Answer 4

Question

Chapter 6, Problem 69P

(a)

To determine

Calculate the electric field at (2, −2, 3).

(a)

Expert Solution

Answer to Problem 69P

The electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Explanation of Solution

Calculation:

Write the expression for the electric field.

E=E++E−=ρL2πεo(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, 10−936π F⋅m−1 for εo, (2,−2,3)−(3,−2,4) for aρ1, and (2,−2,3)−(3,−2,−4) for aρ2.

E=16 nC/m2π(10−936π F⋅m−1)((2,−2,3)−(3,−2,4)|(2,−2,3)−(3,−2,4)|2−(2,−2,3)−(3,−2,−4)|(2,−2,3)−(3,−2,−4)|2)1m=(18×16) [(−1,0,−1)2−(−1,0,7)50] {∵C=F⋅V}=−138.2ax−184.3ay Vm

Conclusion:

Thus, the electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

(b)

To determine

Find the induced surface charge density on the conducting plane at (5,−6,0).

(b)

Expert Solution

Answer to Problem 69P

The induced surface charge density is −1.018 nCm2_.

Explanation of Solution

Calculation:

Consider the expression for the induced surface charge density.

ρs=Dn (1)

Calculate the displacement field vector.

D=D++D−=ρL2π(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, (5,−6,0)−(3,−6,4) for aρ1, and (5,−6,0)−(3,−6,−4) for aρ2.

D=16 nC/m2π((5,−6,0)−(3,−6,4)|(5,−6,0)−(3,−6,4)|2−(5,−6,0)−(3,−6,−4)|(5,−6,0)−(3,−6,−4)|2)1m=(8π) [(2,0,−4)20−(2,0,4)20] nCm2 =−1.018az nCm2

The above equation is compared with the general expression D=Dnaz, the value of Dn is −1.018 nCm2.

Substitute −1.018 nCm2 for Dn in Equation (1).

ρs=−1.018 nCm2

Conclusion:

Thus, the induced surface charge density is −1.018 nCm2_.

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Answer 5

Chapter 6, Problem 69P

(a)

To determine

Calculate the electric field at (2, −2, 3).

(a)

Expert Solution

Answer to Problem 69P

The electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Explanation of Solution

Calculation:

Write the expression for the electric field.

E=E++E−=ρL2πεo(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, 10−936π F⋅m−1 for εo, (2,−2,3)−(3,−2,4) for aρ1, and (2,−2,3)−(3,−2,−4) for aρ2.

E=16 nC/m2π(10−936π F⋅m−1)((2,−2,3)−(3,−2,4)|(2,−2,3)−(3,−2,4)|2−(2,−2,3)−(3,−2,−4)|(2,−2,3)−(3,−2,−4)|2)1m=(18×16) [(−1,0,−1)2−(−1,0,7)50] {∵C=F⋅V}=−138.2ax−184.3ay Vm

Conclusion:

Thus, the electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

(b)

To determine

Find the induced surface charge density on the conducting plane at (5,−6,0).

(b)

Expert Solution

Answer to Problem 69P

The induced surface charge density is −1.018 nCm2_.

Explanation of Solution

Calculation:

Consider the expression for the induced surface charge density.

ρs=Dn (1)

Calculate the displacement field vector.

D=D++D−=ρL2π(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, (5,−6,0)−(3,−6,4) for aρ1, and (5,−6,0)−(3,−6,−4) for aρ2.

D=16 nC/m2π((5,−6,0)−(3,−6,4)|(5,−6,0)−(3,−6,4)|2−(5,−6,0)−(3,−6,−4)|(5,−6,0)−(3,−6,−4)|2)1m=(8π) [(2,0,−4)20−(2,0,4)20] nCm2 =−1.018az nCm2

The above equation is compared with the general expression D=Dnaz, the value of Dn is −1.018 nCm2.

Substitute −1.018 nCm2 for Dn in Equation (1).

ρs=−1.018 nCm2

Conclusion:

Thus, the induced surface charge density is −1.018 nCm2_.

Answer 6

Chapter 6, Problem 69P

(a)

To determine

Calculate the electric field at (2, −2, 3).

(a)

Expert Solution

Answer to Problem 69P

The electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Explanation of Solution

Calculation:

Write the expression for the electric field.

E=E++E−=ρL2πεo(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, 10−936π F⋅m−1 for εo, (2,−2,3)−(3,−2,4) for aρ1, and (2,−2,3)−(3,−2,−4) for aρ2.

E=16 nC/m2π(10−936π F⋅m−1)((2,−2,3)−(3,−2,4)|(2,−2,3)−(3,−2,4)|2−(2,−2,3)−(3,−2,−4)|(2,−2,3)−(3,−2,−4)|2)1m=(18×16) [(−1,0,−1)2−(−1,0,7)50] {∵C=F⋅V}=−138.2ax−184.3ay Vm

Conclusion:

Thus, the electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Answer 7

Chapter 6, Problem 69P

(a)

To determine

Calculate the electric field at (2, −2, 3).

Answer 8

(a)

Expert Solution

Answer to Problem 69P

The electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Calculation:

Write the expression for the electric field.

E=E++E−=ρL2πεo(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, 10−936π F⋅m−1 for εo, (2,−2,3)−(3,−2,4) for aρ1, and (2,−2,3)−(3,−2,−4) for aρ2.

E=16 nC/m2π(10−936π F⋅m−1)((2,−2,3)−(3,−2,4)|(2,−2,3)−(3,−2,4)|2−(2,−2,3)−(3,−2,−4)|(2,−2,3)−(3,−2,−4)|2)1m=(18×16) [(−1,0,−1)2−(−1,0,7)50] {∵C=F⋅V}=−138.2ax−184.3ay Vm

Conclusion:

Thus, the electric field at (2, −2, 3) is −138.2ax−184.3ay Vm_.

Answer 13

(b)

To determine

Find the induced surface charge density on the conducting plane at (5,−6,0).

(b)

Expert Solution

Answer to Problem 69P

The induced surface charge density is −1.018 nCm2_.

Explanation of Solution

Calculation:

Consider the expression for the induced surface charge density.

ρs=Dn (1)

Calculate the displacement field vector.

D=D++D−=ρL2π(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, (5,−6,0)−(3,−6,4) for aρ1, and (5,−6,0)−(3,−6,−4) for aρ2.

D=16 nC/m2π((5,−6,0)−(3,−6,4)|(5,−6,0)−(3,−6,4)|2−(5,−6,0)−(3,−6,−4)|(5,−6,0)−(3,−6,−4)|2)1m=(8π) [(2,0,−4)20−(2,0,4)20] nCm2 =−1.018az nCm2

The above equation is compared with the general expression D=Dnaz, the value of Dn is −1.018 nCm2.

Substitute −1.018 nCm2 for Dn in Equation (1).

ρs=−1.018 nCm2

Conclusion:

Thus, the induced surface charge density is −1.018 nCm2_.

Answer 14

(b)

To determine

Find the induced surface charge density on the conducting plane at (5,−6,0).

Answer 15

(b)

Expert Solution

Answer to Problem 69P

The induced surface charge density is −1.018 nCm2_.

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Calculation:

Consider the expression for the induced surface charge density.

ρs=Dn (1)

Calculate the displacement field vector.

D=D++D−=ρL2π(aρ1|aρ1|2−aρ2|aρ2|2) {∵ρ1=|aρ1|2 ρ2=|aρ2|2}

Substitute 16 nC/m for ρL, (5,−6,0)−(3,−6,4) for aρ1, and (5,−6,0)−(3,−6,−4) for aρ2.

D=16 nC/m2π((5,−6,0)−(3,−6,4)|(5,−6,0)−(3,−6,4)|2−(5,−6,0)−(3,−6,−4)|(5,−6,0)−(3,−6,−4)|2)1m=(8π) [(2,0,−4)20−(2,0,4)20] nCm2 =−1.018az nCm2

The above equation is compared with the general expression D=Dnaz, the value of Dn is −1.018 nCm2.

Substitute −1.018 nCm2 for Dn in Equation (1).

ρs=−1.018 nCm2

Conclusion:

Thus, the induced surface charge density is −1.018 nCm2_.

Answer 20

Ch. 6.4 - Prob. 1PE Ch. 6.4 - Prob. 2PE Ch. 6.4 - Prob. 3PE Ch. 6.4 - Prob. 4PE Ch. 6.4 - Prob. 6PE Ch. 6.4 - Prob. 7PE Ch. 6.5 - Prob. 8PE Ch. 6.5 - Prob. 9PE Ch. 6.5 - Prob. 10PE Ch. 6.5 - Prob. 11PE

Calculate the electric field at ( 2 , − 2 , 3 ) .

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Calculate the electric field at (2, −2, 3).

Answer to Problem 69P

Explanation of Solution

Find the induced surface charge density on the conducting plane at (5,−6,0).

Answer to Problem 69P

Explanation of Solution

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