For the circuit shown in Figure P27.22, we wish to find the currents I 1 , I 2 , and I 3 . Use Kirchhoff’s rules to obtain equations for (a) the upper loop, (b) the lower loop, and (c) the junction on the left side. In each case, suppress units for clarity and simplify, combining the terms. (d) Solve the junction equation for I 3 . (e) Using the equation found in part (d), eliminate I 3 from the equation found in part (b). (f) Solve the equations found in parts (a) and (e) simultaneously for the two unknowns I 1 and I 2 . (g) Substitute the answers found in part (f) into the junction equation found in part (d), solving for I 3 . (h) What is the significance of the negative answer for I 2 ? Figure P27.22

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Answer 1

Textbook Question

Chapter 27, Problem 22P

For the circuit shown in Figure P27.22, we wish to find the currents I₁, I₂, and I₃. Use Kirchhoff’s rules to obtain equations for (a) the upper loop, (b) the lower loop, and (c) the junction on the left side. In each case, suppress units for clarity and simplify, combining the terms. (d) Solve the junction equation for I₃. (e) Using the equation found in part (d), eliminate I₃ from the equation found in part (b). (f) Solve the equations found in parts (a) and (e) simultaneously for the two unknowns I₁ and I₂. (g) Substitute the answers found in part (f) into the junction equation found in part (d), solving for I₃. (h) What is the significance of the negative answer for I₂?

Figure P27.22

Chapter 27, Problem 22P, For the circuit shown in Figure P27.22, we wish to find the currents I1, I2, and I3. Use Kirchhoffs

(a)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the upper loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 1

By going counterclockwise around the upper loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the upper loop is,

[−(11.0 Ω)I2+12.0 V−(7.00 Ω)I2−(5.00 Ω)I1+18.0 V −(8.00 Ω)I1]=0(13.0 Ω)I1+(18.0 Ω)I2=30.0 V (1)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

(b)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the lower loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 2

By going counterclockwise around the lower loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the lower loop is,

[−(5.00 Ω)I3+36.0 V+(7.00 Ω)I2−12.0 V +(11.0 Ω)I2]=0(18.0 Ω)I2−(5.00 Ω)I3=−24.0 V (2)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

(c)

Expert Solution

To determine

The equation by using Kirchhoff’s rules at the junction on the left side.

Answer to Problem 22P

The equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 3

Apply the junction rule at the node in the left end of the circuit.

The equation for the junction on the left side is,

I1−I2−I3=0 (3)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

(d)

Expert Solution

To determine

To solve: The junction on the left side for I3 .

Answer to Problem 22P

The junction on the left side for I3 is I1−I2 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 4

Apply the junction rule at the node in the left end of the circuit.

Rearrange the equation (3) as,

I1−I2−I3=0I3=I1−I2

Conclusion:

Therefore, the junction on the left side for I3 is I1−I2 .

(e)

Expert Solution

To determine

To eliminate: The current I3 from the equation of part (b) by using equation of part (d).

Answer to Problem 22P

The equation after elimination\ for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 5

The equation for I3 is,

I3=I1−I2

Substitute I1−I2 for I3 in equation (2).

(18.0 Ω)I2−(5.00 Ω)(I1−I2)=−24.0 V(18.0 Ω)I2−(5.00 Ω)I1+(5.00 Ω)I2=−24.0 V(5.00 Ω)I1−(23.0 Ω)I2=24.0 V (4)

Conclusion:

Therefore, the equation after elimination for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

(f)

Expert Solution

To determine

The value of I1 and I2 from the equation of part (a) and part (e).

Answer to Problem 22P

The value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 6

Rearrange the equation (4) for I1 .

(5.00 Ω)I1−(23.0 Ω)I2=24.0 VI1=(24.0 V)+(23.0 Ω)I2(5.00 Ω) (5)

Recall the equation (1).

(13.0 Ω)I1+(18.0 Ω)I2=30.0 V

Substitute (24.0 V)+(23.0 Ω)I2(5.00 Ω) for I1 in above equation (1).

(13.0 Ω)((24.0 V)+(23.0 Ω)I2(5.00 Ω))+(18.0 Ω)I2=30.0 V(13.0 Ω)((24.0 V)+(23.0 Ω)I2)+(5.00 Ω)(18.0 Ω)I2=(5.00 Ω)(30.0 V)312 Ω⋅V+(299 Ω2)I2+(90 Ω2)I2=150 Ω⋅V(389 Ω2)I2=−162 Ω⋅V

Further, solve,

(389 Ω2)I2=−162 Ω⋅VI2=−162 Ω⋅V(389 Ω2)=−0.416 A

Thus, the value of I2 is −0.416 A .

Substitute −0.416 A for I2 in equation (5).

I1=(24.0 V)+(23.0 Ω)(−0.416 A)(5.00 Ω)=2.88 A

Conclusion:

Therefore, the value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

(g)

Expert Solution

To determine

The value of I3 .

Answer to Problem 22P

The value of I3 is 3.29 A .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 7

The equation for I3 is,

I3=I1−I2

Substitute 2.88 A for I1 and −0.416 A for I3 in above equation to find I3 .

I3=(2.88 A)−(−0.416 A)=3.29 A

Conclusion:

Therefore, the value of I3 is 3.29 A .

(h)

Expert Solution

To determine

The significant of the negative sign of answer of I2 .

Answer to Problem 22P

The negative sign in the answer for I2 means that this current flows in the opposite direction.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 8

The negative sign in the answer for I2 means that this current flows in the opposite direction to that shown in the circuit diagram. That is the actual current in the middle branch of the circuit flows from right to left and has a magnitude of 0.416 A .

Conclusion:

Therefore, the negative sign in the answer for I2 means that this current flows in the opposite direction.

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Answer 2

Textbook Question

Chapter 27, Problem 22P

For the circuit shown in Figure P27.22, we wish to find the currents I₁, I₂, and I₃. Use Kirchhoff’s rules to obtain equations for (a) the upper loop, (b) the lower loop, and (c) the junction on the left side. In each case, suppress units for clarity and simplify, combining the terms. (d) Solve the junction equation for I₃. (e) Using the equation found in part (d), eliminate I₃ from the equation found in part (b). (f) Solve the equations found in parts (a) and (e) simultaneously for the two unknowns I₁ and I₂. (g) Substitute the answers found in part (f) into the junction equation found in part (d), solving for I₃. (h) What is the significance of the negative answer for I₂?

Figure P27.22

Chapter 27, Problem 22P, For the circuit shown in Figure P27.22, we wish to find the currents I1, I2, and I3. Use Kirchhoffs

(a)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the upper loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 1

By going counterclockwise around the upper loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the upper loop is,

[−(11.0 Ω)I2+12.0 V−(7.00 Ω)I2−(5.00 Ω)I1+18.0 V −(8.00 Ω)I1]=0(13.0 Ω)I1+(18.0 Ω)I2=30.0 V (1)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

(b)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the lower loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 2

By going counterclockwise around the lower loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the lower loop is,

[−(5.00 Ω)I3+36.0 V+(7.00 Ω)I2−12.0 V +(11.0 Ω)I2]=0(18.0 Ω)I2−(5.00 Ω)I3=−24.0 V (2)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

(c)

Expert Solution

To determine

The equation by using Kirchhoff’s rules at the junction on the left side.

Answer to Problem 22P

The equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 3

Apply the junction rule at the node in the left end of the circuit.

The equation for the junction on the left side is,

I1−I2−I3=0 (3)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

(d)

Expert Solution

To determine

To solve: The junction on the left side for I3 .

Answer to Problem 22P

The junction on the left side for I3 is I1−I2 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 4

Apply the junction rule at the node in the left end of the circuit.

Rearrange the equation (3) as,

I1−I2−I3=0I3=I1−I2

Conclusion:

Therefore, the junction on the left side for I3 is I1−I2 .

(e)

Expert Solution

To determine

To eliminate: The current I3 from the equation of part (b) by using equation of part (d).

Answer to Problem 22P

The equation after elimination\ for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 5

The equation for I3 is,

I3=I1−I2

Substitute I1−I2 for I3 in equation (2).

(18.0 Ω)I2−(5.00 Ω)(I1−I2)=−24.0 V(18.0 Ω)I2−(5.00 Ω)I1+(5.00 Ω)I2=−24.0 V(5.00 Ω)I1−(23.0 Ω)I2=24.0 V (4)

Conclusion:

Therefore, the equation after elimination for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

(f)

Expert Solution

To determine

The value of I1 and I2 from the equation of part (a) and part (e).

Answer to Problem 22P

The value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 6

Rearrange the equation (4) for I1 .

(5.00 Ω)I1−(23.0 Ω)I2=24.0 VI1=(24.0 V)+(23.0 Ω)I2(5.00 Ω) (5)

Recall the equation (1).

(13.0 Ω)I1+(18.0 Ω)I2=30.0 V

Substitute (24.0 V)+(23.0 Ω)I2(5.00 Ω) for I1 in above equation (1).

(13.0 Ω)((24.0 V)+(23.0 Ω)I2(5.00 Ω))+(18.0 Ω)I2=30.0 V(13.0 Ω)((24.0 V)+(23.0 Ω)I2)+(5.00 Ω)(18.0 Ω)I2=(5.00 Ω)(30.0 V)312 Ω⋅V+(299 Ω2)I2+(90 Ω2)I2=150 Ω⋅V(389 Ω2)I2=−162 Ω⋅V

Further, solve,

(389 Ω2)I2=−162 Ω⋅VI2=−162 Ω⋅V(389 Ω2)=−0.416 A

Thus, the value of I2 is −0.416 A .

Substitute −0.416 A for I2 in equation (5).

I1=(24.0 V)+(23.0 Ω)(−0.416 A)(5.00 Ω)=2.88 A

Conclusion:

Therefore, the value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

(g)

Expert Solution

To determine

The value of I3 .

Answer to Problem 22P

The value of I3 is 3.29 A .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 7

The equation for I3 is,

I3=I1−I2

Substitute 2.88 A for I1 and −0.416 A for I3 in above equation to find I3 .

I3=(2.88 A)−(−0.416 A)=3.29 A

Conclusion:

Therefore, the value of I3 is 3.29 A .

(h)

Expert Solution

To determine

The significant of the negative sign of answer of I2 .

Answer to Problem 22P

The negative sign in the answer for I2 means that this current flows in the opposite direction.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 8

The negative sign in the answer for I2 means that this current flows in the opposite direction to that shown in the circuit diagram. That is the actual current in the middle branch of the circuit flows from right to left and has a magnitude of 0.416 A .

Conclusion:

Therefore, the negative sign in the answer for I2 means that this current flows in the opposite direction.

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Answer 3

Textbook Question

Chapter 27, Problem 22P

For the circuit shown in Figure P27.22, we wish to find the currents I₁, I₂, and I₃. Use Kirchhoff’s rules to obtain equations for (a) the upper loop, (b) the lower loop, and (c) the junction on the left side. In each case, suppress units for clarity and simplify, combining the terms. (d) Solve the junction equation for I₃. (e) Using the equation found in part (d), eliminate I₃ from the equation found in part (b). (f) Solve the equations found in parts (a) and (e) simultaneously for the two unknowns I₁ and I₂. (g) Substitute the answers found in part (f) into the junction equation found in part (d), solving for I₃. (h) What is the significance of the negative answer for I₂?

Figure P27.22

Chapter 27, Problem 22P, For the circuit shown in Figure P27.22, we wish to find the currents I1, I2, and I3. Use Kirchhoffs

(a)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the upper loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 1

By going counterclockwise around the upper loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the upper loop is,

[−(11.0 Ω)I2+12.0 V−(7.00 Ω)I2−(5.00 Ω)I1+18.0 V −(8.00 Ω)I1]=0(13.0 Ω)I1+(18.0 Ω)I2=30.0 V (1)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

(b)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the lower loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 2

By going counterclockwise around the lower loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the lower loop is,

[−(5.00 Ω)I3+36.0 V+(7.00 Ω)I2−12.0 V +(11.0 Ω)I2]=0(18.0 Ω)I2−(5.00 Ω)I3=−24.0 V (2)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

(c)

Expert Solution

To determine

The equation by using Kirchhoff’s rules at the junction on the left side.

Answer to Problem 22P

The equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 3

Apply the junction rule at the node in the left end of the circuit.

The equation for the junction on the left side is,

I1−I2−I3=0 (3)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

(d)

Expert Solution

To determine

To solve: The junction on the left side for I3 .

Answer to Problem 22P

The junction on the left side for I3 is I1−I2 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 4

Apply the junction rule at the node in the left end of the circuit.

Rearrange the equation (3) as,

I1−I2−I3=0I3=I1−I2

Conclusion:

Therefore, the junction on the left side for I3 is I1−I2 .

(e)

Expert Solution

To determine

To eliminate: The current I3 from the equation of part (b) by using equation of part (d).

Answer to Problem 22P

The equation after elimination\ for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 5

The equation for I3 is,

I3=I1−I2

Substitute I1−I2 for I3 in equation (2).

(18.0 Ω)I2−(5.00 Ω)(I1−I2)=−24.0 V(18.0 Ω)I2−(5.00 Ω)I1+(5.00 Ω)I2=−24.0 V(5.00 Ω)I1−(23.0 Ω)I2=24.0 V (4)

Conclusion:

Therefore, the equation after elimination for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

(f)

Expert Solution

To determine

The value of I1 and I2 from the equation of part (a) and part (e).

Answer to Problem 22P

The value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 6

Rearrange the equation (4) for I1 .

(5.00 Ω)I1−(23.0 Ω)I2=24.0 VI1=(24.0 V)+(23.0 Ω)I2(5.00 Ω) (5)

Recall the equation (1).

(13.0 Ω)I1+(18.0 Ω)I2=30.0 V

Substitute (24.0 V)+(23.0 Ω)I2(5.00 Ω) for I1 in above equation (1).

(13.0 Ω)((24.0 V)+(23.0 Ω)I2(5.00 Ω))+(18.0 Ω)I2=30.0 V(13.0 Ω)((24.0 V)+(23.0 Ω)I2)+(5.00 Ω)(18.0 Ω)I2=(5.00 Ω)(30.0 V)312 Ω⋅V+(299 Ω2)I2+(90 Ω2)I2=150 Ω⋅V(389 Ω2)I2=−162 Ω⋅V

Further, solve,

(389 Ω2)I2=−162 Ω⋅VI2=−162 Ω⋅V(389 Ω2)=−0.416 A

Thus, the value of I2 is −0.416 A .

Substitute −0.416 A for I2 in equation (5).

I1=(24.0 V)+(23.0 Ω)(−0.416 A)(5.00 Ω)=2.88 A

Conclusion:

Therefore, the value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

(g)

Expert Solution

To determine

The value of I3 .

Answer to Problem 22P

The value of I3 is 3.29 A .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 7

The equation for I3 is,

I3=I1−I2

Substitute 2.88 A for I1 and −0.416 A for I3 in above equation to find I3 .

I3=(2.88 A)−(−0.416 A)=3.29 A

Conclusion:

Therefore, the value of I3 is 3.29 A .

(h)

Expert Solution

To determine

The significant of the negative sign of answer of I2 .

Answer to Problem 22P

The negative sign in the answer for I2 means that this current flows in the opposite direction.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 8

The negative sign in the answer for I2 means that this current flows in the opposite direction to that shown in the circuit diagram. That is the actual current in the middle branch of the circuit flows from right to left and has a magnitude of 0.416 A .

Conclusion:

Therefore, the negative sign in the answer for I2 means that this current flows in the opposite direction.

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Answer 4

Textbook Question

Chapter 27, Problem 22P

For the circuit shown in Figure P27.22, we wish to find the currents I₁, I₂, and I₃. Use Kirchhoff’s rules to obtain equations for (a) the upper loop, (b) the lower loop, and (c) the junction on the left side. In each case, suppress units for clarity and simplify, combining the terms. (d) Solve the junction equation for I₃. (e) Using the equation found in part (d), eliminate I₃ from the equation found in part (b). (f) Solve the equations found in parts (a) and (e) simultaneously for the two unknowns I₁ and I₂. (g) Substitute the answers found in part (f) into the junction equation found in part (d), solving for I₃. (h) What is the significance of the negative answer for I₂?

Figure P27.22

Chapter 27, Problem 22P, For the circuit shown in Figure P27.22, we wish to find the currents I1, I2, and I3. Use Kirchhoffs

(a)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the upper loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 1

By going counterclockwise around the upper loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the upper loop is,

[−(11.0 Ω)I2+12.0 V−(7.00 Ω)I2−(5.00 Ω)I1+18.0 V −(8.00 Ω)I1]=0(13.0 Ω)I1+(18.0 Ω)I2=30.0 V (1)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

(b)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the lower loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 2

By going counterclockwise around the lower loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the lower loop is,

[−(5.00 Ω)I3+36.0 V+(7.00 Ω)I2−12.0 V +(11.0 Ω)I2]=0(18.0 Ω)I2−(5.00 Ω)I3=−24.0 V (2)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

(c)

Expert Solution

To determine

The equation by using Kirchhoff’s rules at the junction on the left side.

Answer to Problem 22P

The equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 3

Apply the junction rule at the node in the left end of the circuit.

The equation for the junction on the left side is,

I1−I2−I3=0 (3)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

(d)

Expert Solution

To determine

To solve: The junction on the left side for I3 .

Answer to Problem 22P

The junction on the left side for I3 is I1−I2 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 4

Apply the junction rule at the node in the left end of the circuit.

Rearrange the equation (3) as,

I1−I2−I3=0I3=I1−I2

Conclusion:

Therefore, the junction on the left side for I3 is I1−I2 .

(e)

Expert Solution

To determine

To eliminate: The current I3 from the equation of part (b) by using equation of part (d).

Answer to Problem 22P

The equation after elimination\ for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 5

The equation for I3 is,

I3=I1−I2

Substitute I1−I2 for I3 in equation (2).

(18.0 Ω)I2−(5.00 Ω)(I1−I2)=−24.0 V(18.0 Ω)I2−(5.00 Ω)I1+(5.00 Ω)I2=−24.0 V(5.00 Ω)I1−(23.0 Ω)I2=24.0 V (4)

Conclusion:

Therefore, the equation after elimination for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

(f)

Expert Solution

To determine

The value of I1 and I2 from the equation of part (a) and part (e).

Answer to Problem 22P

The value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 6

Rearrange the equation (4) for I1 .

(5.00 Ω)I1−(23.0 Ω)I2=24.0 VI1=(24.0 V)+(23.0 Ω)I2(5.00 Ω) (5)

Recall the equation (1).

(13.0 Ω)I1+(18.0 Ω)I2=30.0 V

Substitute (24.0 V)+(23.0 Ω)I2(5.00 Ω) for I1 in above equation (1).

(13.0 Ω)((24.0 V)+(23.0 Ω)I2(5.00 Ω))+(18.0 Ω)I2=30.0 V(13.0 Ω)((24.0 V)+(23.0 Ω)I2)+(5.00 Ω)(18.0 Ω)I2=(5.00 Ω)(30.0 V)312 Ω⋅V+(299 Ω2)I2+(90 Ω2)I2=150 Ω⋅V(389 Ω2)I2=−162 Ω⋅V

Further, solve,

(389 Ω2)I2=−162 Ω⋅VI2=−162 Ω⋅V(389 Ω2)=−0.416 A

Thus, the value of I2 is −0.416 A .

Substitute −0.416 A for I2 in equation (5).

I1=(24.0 V)+(23.0 Ω)(−0.416 A)(5.00 Ω)=2.88 A

Conclusion:

Therefore, the value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

(g)

Expert Solution

To determine

The value of I3 .

Answer to Problem 22P

The value of I3 is 3.29 A .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 7

The equation for I3 is,

I3=I1−I2

Substitute 2.88 A for I1 and −0.416 A for I3 in above equation to find I3 .

I3=(2.88 A)−(−0.416 A)=3.29 A

Conclusion:

Therefore, the value of I3 is 3.29 A .

(h)

Expert Solution

To determine

The significant of the negative sign of answer of I2 .

Answer to Problem 22P

The negative sign in the answer for I2 means that this current flows in the opposite direction.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 8

The negative sign in the answer for I2 means that this current flows in the opposite direction to that shown in the circuit diagram. That is the actual current in the middle branch of the circuit flows from right to left and has a magnitude of 0.416 A .

Conclusion:

Therefore, the negative sign in the answer for I2 means that this current flows in the opposite direction.

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Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

(a)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the upper loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 1

By going counterclockwise around the upper loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the upper loop is,

[−(11.0 Ω)I2+12.0 V−(7.00 Ω)I2−(5.00 Ω)I1+18.0 V −(8.00 Ω)I1]=0(13.0 Ω)I1+(18.0 Ω)I2=30.0 V (1)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

(b)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the lower loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 2

By going counterclockwise around the lower loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the lower loop is,

[−(5.00 Ω)I3+36.0 V+(7.00 Ω)I2−12.0 V +(11.0 Ω)I2]=0(18.0 Ω)I2−(5.00 Ω)I3=−24.0 V (2)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

(c)

Expert Solution

To determine

The equation by using Kirchhoff’s rules at the junction on the left side.

Answer to Problem 22P

The equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 3

Apply the junction rule at the node in the left end of the circuit.

The equation for the junction on the left side is,

I1−I2−I3=0 (3)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

(d)

Expert Solution

To determine

To solve: The junction on the left side for I3 .

Answer to Problem 22P

The junction on the left side for I3 is I1−I2 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 4

Apply the junction rule at the node in the left end of the circuit.

Rearrange the equation (3) as,

I1−I2−I3=0I3=I1−I2

Conclusion:

Therefore, the junction on the left side for I3 is I1−I2 .

(e)

Expert Solution

To determine

To eliminate: The current I3 from the equation of part (b) by using equation of part (d).

Answer to Problem 22P

The equation after elimination\ for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 5

The equation for I3 is,

I3=I1−I2

Substitute I1−I2 for I3 in equation (2).

(18.0 Ω)I2−(5.00 Ω)(I1−I2)=−24.0 V(18.0 Ω)I2−(5.00 Ω)I1+(5.00 Ω)I2=−24.0 V(5.00 Ω)I1−(23.0 Ω)I2=24.0 V (4)

Conclusion:

Therefore, the equation after elimination for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

(f)

Expert Solution

To determine

The value of I1 and I2 from the equation of part (a) and part (e).

Answer to Problem 22P

The value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 6

Rearrange the equation (4) for I1 .

(5.00 Ω)I1−(23.0 Ω)I2=24.0 VI1=(24.0 V)+(23.0 Ω)I2(5.00 Ω) (5)

Recall the equation (1).

(13.0 Ω)I1+(18.0 Ω)I2=30.0 V

Substitute (24.0 V)+(23.0 Ω)I2(5.00 Ω) for I1 in above equation (1).

(13.0 Ω)((24.0 V)+(23.0 Ω)I2(5.00 Ω))+(18.0 Ω)I2=30.0 V(13.0 Ω)((24.0 V)+(23.0 Ω)I2)+(5.00 Ω)(18.0 Ω)I2=(5.00 Ω)(30.0 V)312 Ω⋅V+(299 Ω2)I2+(90 Ω2)I2=150 Ω⋅V(389 Ω2)I2=−162 Ω⋅V

Further, solve,

(389 Ω2)I2=−162 Ω⋅VI2=−162 Ω⋅V(389 Ω2)=−0.416 A

Thus, the value of I2 is −0.416 A .

Substitute −0.416 A for I2 in equation (5).

I1=(24.0 V)+(23.0 Ω)(−0.416 A)(5.00 Ω)=2.88 A

Conclusion:

Therefore, the value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

(g)

Expert Solution

To determine

The value of I3 .

Answer to Problem 22P

The value of I3 is 3.29 A .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 7

The equation for I3 is,

I3=I1−I2

Substitute 2.88 A for I1 and −0.416 A for I3 in above equation to find I3 .

I3=(2.88 A)−(−0.416 A)=3.29 A

Conclusion:

Therefore, the value of I3 is 3.29 A .

(h)

Expert Solution

To determine

The significant of the negative sign of answer of I2 .

Answer to Problem 22P

The negative sign in the answer for I2 means that this current flows in the opposite direction.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 8

The negative sign in the answer for I2 means that this current flows in the opposite direction to that shown in the circuit diagram. That is the actual current in the middle branch of the circuit flows from right to left and has a magnitude of 0.416 A .

Conclusion:

Therefore, the negative sign in the answer for I2 means that this current flows in the opposite direction.

Answer 8

(a)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the upper loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 1

By going counterclockwise around the upper loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the upper loop is,

[−(11.0 Ω)I2+12.0 V−(7.00 Ω)I2−(5.00 Ω)I1+18.0 V −(8.00 Ω)I1]=0(13.0 Ω)I1+(18.0 Ω)I2=30.0 V (1)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Answer 9

(a)

Expert Solution

Answer 10

(a)

Expert Solution

Answer 11

Expert Solution

Answer 12

To determine

The equation by using Kirchhoff’s rules in the upper loop.

Answer 13

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Answer 14

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 1

By going counterclockwise around the upper loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the upper loop is,

[−(11.0 Ω)I2+12.0 V−(7.00 Ω)I2−(5.00 Ω)I1+18.0 V −(8.00 Ω)I1]=0(13.0 Ω)I1+(18.0 Ω)I2=30.0 V (1)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the upper loop is (13.008 Ω)I1+(18.0 Ω)I2=30.0 V .

Answer 15

(b)

Expert Solution

To determine

The equation by using Kirchhoff’s rules in the lower loop.

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 2

By going counterclockwise around the lower loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the lower loop is,

[−(5.00 Ω)I3+36.0 V+(7.00 Ω)I2−12.0 V +(11.0 Ω)I2]=0(18.0 Ω)I2−(5.00 Ω)I3=−24.0 V (2)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Answer 16

(b)

Expert Solution

Answer 17

(b)

Expert Solution

Answer 18

Expert Solution

Answer 19

To determine

The equation by using Kirchhoff’s rules in the lower loop.

Answer 20

Answer to Problem 22P

The equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Answer 21

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 2

By going counterclockwise around the lower loop and suppressing the unites, the Kirchhoff’s law is applied.

The equation for the lower loop is,

[−(5.00 Ω)I3+36.0 V+(7.00 Ω)I2−12.0 V +(11.0 Ω)I2]=0(18.0 Ω)I2−(5.00 Ω)I3=−24.0 V (2)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules in the lower loop is (18.0 Ω)I2−(5.00 Ω)I3=−24.0 V .

Answer 22

(c)

Expert Solution

To determine

The equation by using Kirchhoff’s rules at the junction on the left side.

Answer to Problem 22P

The equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 3

Apply the junction rule at the node in the left end of the circuit.

The equation for the junction on the left side is,

I1−I2−I3=0 (3)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Answer 23

(c)

Expert Solution

Answer 24

(c)

Expert Solution

Answer 25

Expert Solution

Answer 26

To determine

The equation by using Kirchhoff’s rules at the junction on the left side.

Answer 27

Answer to Problem 22P

The equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Answer 28

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 3

Apply the junction rule at the node in the left end of the circuit.

The equation for the junction on the left side is,

I1−I2−I3=0 (3)

Conclusion:

Therefore, the equation by using Kirchhoff’s rules at the junction on the left side is I1−I2−I3=0 .

Answer 29

(d)

Expert Solution

To determine

To solve: The junction on the left side for I3 .

Answer to Problem 22P

The junction on the left side for I3 is I1−I2 .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 4

Apply the junction rule at the node in the left end of the circuit.

Rearrange the equation (3) as,

I1−I2−I3=0I3=I1−I2

Conclusion:

Therefore, the junction on the left side for I3 is I1−I2 .

Answer 30

(d)

Expert Solution

Answer 31

(d)

Expert Solution

Answer 32

Expert Solution

Answer 33

To determine

To solve: The junction on the left side for I3 .

Answer 34

Answer to Problem 22P

The junction on the left side for I3 is I1−I2 .

Answer 35

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 4

Apply the junction rule at the node in the left end of the circuit.

Rearrange the equation (3) as,

I1−I2−I3=0I3=I1−I2

Conclusion:

Therefore, the junction on the left side for I3 is I1−I2 .

Answer 36

(e)

Expert Solution

To determine

To eliminate: The current I3 from the equation of part (b) by using equation of part (d).

Answer to Problem 22P

The equation after elimination\ for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 5

The equation for I3 is,

I3=I1−I2

Substitute I1−I2 for I3 in equation (2).

(18.0 Ω)I2−(5.00 Ω)(I1−I2)=−24.0 V(18.0 Ω)I2−(5.00 Ω)I1+(5.00 Ω)I2=−24.0 V(5.00 Ω)I1−(23.0 Ω)I2=24.0 V (4)

Conclusion:

Therefore, the equation after elimination for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Answer 37

(e)

Expert Solution

Answer 38

(e)

Expert Solution

Answer 39

Expert Solution

Answer 40

To determine

To eliminate: The current I3 from the equation of part (b) by using equation of part (d).

Answer 41

Answer to Problem 22P

The equation after elimination\ for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Answer 42

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 5

The equation for I3 is,

I3=I1−I2

Substitute I1−I2 for I3 in equation (2).

(18.0 Ω)I2−(5.00 Ω)(I1−I2)=−24.0 V(18.0 Ω)I2−(5.00 Ω)I1+(5.00 Ω)I2=−24.0 V(5.00 Ω)I1−(23.0 Ω)I2=24.0 V (4)

Conclusion:

Therefore, the equation after elimination for I3 is (5.00 Ω)I1−(23.0 Ω)I2=24.0 V .

Answer 43

(f)

Expert Solution

To determine

The value of I1 and I2 from the equation of part (a) and part (e).

Answer to Problem 22P

The value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 6

Rearrange the equation (4) for I1 .

(5.00 Ω)I1−(23.0 Ω)I2=24.0 VI1=(24.0 V)+(23.0 Ω)I2(5.00 Ω) (5)

Recall the equation (1).

(13.0 Ω)I1+(18.0 Ω)I2=30.0 V

Substitute (24.0 V)+(23.0 Ω)I2(5.00 Ω) for I1 in above equation (1).

(13.0 Ω)((24.0 V)+(23.0 Ω)I2(5.00 Ω))+(18.0 Ω)I2=30.0 V(13.0 Ω)((24.0 V)+(23.0 Ω)I2)+(5.00 Ω)(18.0 Ω)I2=(5.00 Ω)(30.0 V)312 Ω⋅V+(299 Ω2)I2+(90 Ω2)I2=150 Ω⋅V(389 Ω2)I2=−162 Ω⋅V

Further, solve,

(389 Ω2)I2=−162 Ω⋅VI2=−162 Ω⋅V(389 Ω2)=−0.416 A

Thus, the value of I2 is −0.416 A .

Substitute −0.416 A for I2 in equation (5).

I1=(24.0 V)+(23.0 Ω)(−0.416 A)(5.00 Ω)=2.88 A

Conclusion:

Therefore, the value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Answer 44

(f)

Expert Solution

Answer 45

(f)

Expert Solution

Answer 46

Expert Solution

Answer 47

To determine

The value of I1 and I2 from the equation of part (a) and part (e).

Answer 48

Answer to Problem 22P

The value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Answer 49

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 6

Rearrange the equation (4) for I1 .

(5.00 Ω)I1−(23.0 Ω)I2=24.0 VI1=(24.0 V)+(23.0 Ω)I2(5.00 Ω) (5)

Recall the equation (1).

(13.0 Ω)I1+(18.0 Ω)I2=30.0 V

Substitute (24.0 V)+(23.0 Ω)I2(5.00 Ω) for I1 in above equation (1).

(13.0 Ω)((24.0 V)+(23.0 Ω)I2(5.00 Ω))+(18.0 Ω)I2=30.0 V(13.0 Ω)((24.0 V)+(23.0 Ω)I2)+(5.00 Ω)(18.0 Ω)I2=(5.00 Ω)(30.0 V)312 Ω⋅V+(299 Ω2)I2+(90 Ω2)I2=150 Ω⋅V(389 Ω2)I2=−162 Ω⋅V

Further, solve,

(389 Ω2)I2=−162 Ω⋅VI2=−162 Ω⋅V(389 Ω2)=−0.416 A

Thus, the value of I2 is −0.416 A .

Substitute −0.416 A for I2 in equation (5).

I1=(24.0 V)+(23.0 Ω)(−0.416 A)(5.00 Ω)=2.88 A

Conclusion:

Therefore, the value of I1 and I2 from the equation of part (a) and part (e) is 2.88 A and −0.416 A respectively.

Answer 50

(g)

Expert Solution

To determine

The value of I3 .

Answer to Problem 22P

The value of I3 is 3.29 A .

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 7

The equation for I3 is,

I3=I1−I2

Substitute 2.88 A for I1 and −0.416 A for I3 in above equation to find I3 .

I3=(2.88 A)−(−0.416 A)=3.29 A

Conclusion:

Therefore, the value of I3 is 3.29 A .

Answer 51

(g)

Expert Solution

Answer 52

(g)

Expert Solution

Answer 53

Expert Solution

Answer 54

To determine

The value of I3 .

Answer 55

Answer to Problem 22P

The value of I3 is 3.29 A .

Answer 56

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 7

The equation for I3 is,

I3=I1−I2

Substitute 2.88 A for I1 and −0.416 A for I3 in above equation to find I3 .

I3=(2.88 A)−(−0.416 A)=3.29 A

Conclusion:

Therefore, the value of I3 is 3.29 A .

Answer 57

(h)

Expert Solution

To determine

The significant of the negative sign of answer of I2 .

Answer to Problem 22P

The negative sign in the answer for I2 means that this current flows in the opposite direction.

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 8

The negative sign in the answer for I2 means that this current flows in the opposite direction to that shown in the circuit diagram. That is the actual current in the middle branch of the circuit flows from right to left and has a magnitude of 0.416 A .

Conclusion:

Therefore, the negative sign in the answer for I2 means that this current flows in the opposite direction.

Answer 58

(h)

Expert Solution

Answer 59

(h)

Expert Solution

Answer 60

Expert Solution

Answer 61

To determine

The significant of the negative sign of answer of I2 .

Answer 62

Answer to Problem 22P

The negative sign in the answer for I2 means that this current flows in the opposite direction.

Answer 63

Explanation of Solution

Given info: The figure is given as,

Physics for Scientists and Engineers with Modern Physics, Chapter 27, Problem 22P , additional homework tip 8

The negative sign in the answer for I2 means that this current flows in the opposite direction to that shown in the circuit diagram. That is the actual current in the middle branch of the circuit flows from right to left and has a magnitude of 0.416 A .

Conclusion:

Therefore, the negative sign in the answer for I2 means that this current flows in the opposite direction.