(a) In Fig. 27-18a, with R 1 > R 2 , is the potential difference across R 2 more than, less than, or equal to the across R 1 ? (b) Is the current through resistor R 2 more than, less than, or equal to that through resistor R 1 ? Figure 27-18 Questions 1 and 2

Question

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Answer 1

Textbook Question

Chapter 27, Problem 1Q

(a) In Fig. 27-18a, with R₁>R₂, is the potential difference across R₂ more than, less than, or equal to the across R₁? (b) Is the current through resistor R₂ more than, less than, or equal to that through resistor R₁?

Chapter 27, Problem 1Q, a In Fig. 27-18a, with R1R2, is the potential difference across R2 more than, less than, or equal to

Figure 27-18 Questions 1 and 2

Expert Solution & Answer

To determine

To find:

a) The potential difference across R2 more than, less than or equal to that of across R1

b) The current across R2 more than, less than or equal to that of across R1

Answer to Problem 1Q

Solution:

a) The potential difference across R2 is same that of across R1.

b) The current across R2 is more than that of across R1.

Explanation of Solution

1) Concept:

If the resistances are connected in parallel, then the voltage across the resistances is same only the current gets divided. And the value of the current depends only on the resistance because the voltage is same in parallel arrangement.

V=IR where V is voltage, I is current and R is resistance.

As in parallel arrangement V is same so I=1R means greater the resistance, less is current and vise- versa.

2) Formula:

I=VR

3) Explanation:

a)

Here, in fig 27-18a, the resistance R1& R2 are in parallel arrangement. So, the voltage difference across them is same.

b)

As the voltage is same in parallel arrangement, the current depends only on the resistance from Ohm’s law.

I=VR

V is constant for parallel arrangement. So,

I ∝1R

in fig 27-18a, the resistance R1>R2 hence, I2>I1 because the current is inversely proportional to the resistance.

Conclusion:

We can compare the current and the potential difference across the resistances using the concept of parallel arrangement of the resistances and the equation of Ohm’s law.

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Answer 2

Textbook Question

Chapter 27, Problem 1Q

(a) In Fig. 27-18a, with R₁>R₂, is the potential difference across R₂ more than, less than, or equal to the across R₁? (b) Is the current through resistor R₂ more than, less than, or equal to that through resistor R₁?

Chapter 27, Problem 1Q, a In Fig. 27-18a, with R1R2, is the potential difference across R2 more than, less than, or equal to

Figure 27-18 Questions 1 and 2

Expert Solution & Answer

To determine

To find:

a) The potential difference across R2 more than, less than or equal to that of across R1

b) The current across R2 more than, less than or equal to that of across R1

Answer to Problem 1Q

Solution:

a) The potential difference across R2 is same that of across R1.

b) The current across R2 is more than that of across R1.

Explanation of Solution

1) Concept:

If the resistances are connected in parallel, then the voltage across the resistances is same only the current gets divided. And the value of the current depends only on the resistance because the voltage is same in parallel arrangement.

V=IR where V is voltage, I is current and R is resistance.

As in parallel arrangement V is same so I=1R means greater the resistance, less is current and vise- versa.

2) Formula:

I=VR

3) Explanation:

a)

Here, in fig 27-18a, the resistance R1& R2 are in parallel arrangement. So, the voltage difference across them is same.

b)

As the voltage is same in parallel arrangement, the current depends only on the resistance from Ohm’s law.

I=VR

V is constant for parallel arrangement. So,

I ∝1R

in fig 27-18a, the resistance R1>R2 hence, I2>I1 because the current is inversely proportional to the resistance.

Conclusion:

We can compare the current and the potential difference across the resistances using the concept of parallel arrangement of the resistances and the equation of Ohm’s law.

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Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Textbook Question

Chapter 27, Problem 1Q

(a) In Fig. 27-18a, with R₁>R₂, is the potential difference across R₂ more than, less than, or equal to the across R₁? (b) Is the current through resistor R₂ more than, less than, or equal to that through resistor R₁?

Chapter 27, Problem 1Q, a In Fig. 27-18a, with R1R2, is the potential difference across R2 more than, less than, or equal to

Figure 27-18 Questions 1 and 2

Expert Solution & Answer

To determine

To find:

a) The potential difference across R2 more than, less than or equal to that of across R1

b) The current across R2 more than, less than or equal to that of across R1

Answer to Problem 1Q

Solution:

a) The potential difference across R2 is same that of across R1.

b) The current across R2 is more than that of across R1.

Explanation of Solution

1) Concept:

If the resistances are connected in parallel, then the voltage across the resistances is same only the current gets divided. And the value of the current depends only on the resistance because the voltage is same in parallel arrangement.

V=IR where V is voltage, I is current and R is resistance.

As in parallel arrangement V is same so I=1R means greater the resistance, less is current and vise- versa.

2) Formula:

I=VR

3) Explanation:

a)

Here, in fig 27-18a, the resistance R1& R2 are in parallel arrangement. So, the voltage difference across them is same.

b)

As the voltage is same in parallel arrangement, the current depends only on the resistance from Ohm’s law.

I=VR

V is constant for parallel arrangement. So,

I ∝1R

in fig 27-18a, the resistance R1>R2 hence, I2>I1 because the current is inversely proportional to the resistance.

Conclusion:

We can compare the current and the potential difference across the resistances using the concept of parallel arrangement of the resistances and the equation of Ohm’s law.

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Answer 4

Textbook Question

Chapter 27, Problem 1Q

(a) In Fig. 27-18a, with R₁>R₂, is the potential difference across R₂ more than, less than, or equal to the across R₁? (b) Is the current through resistor R₂ more than, less than, or equal to that through resistor R₁?

Chapter 27, Problem 1Q, a In Fig. 27-18a, with R1R2, is the potential difference across R2 more than, less than, or equal to

Figure 27-18 Questions 1 and 2

Expert Solution & Answer

To determine

To find:

a) The potential difference across R2 more than, less than or equal to that of across R1

b) The current across R2 more than, less than or equal to that of across R1

Answer to Problem 1Q

Solution:

a) The potential difference across R2 is same that of across R1.

b) The current across R2 is more than that of across R1.

Explanation of Solution

1) Concept:

If the resistances are connected in parallel, then the voltage across the resistances is same only the current gets divided. And the value of the current depends only on the resistance because the voltage is same in parallel arrangement.

V=IR where V is voltage, I is current and R is resistance.

As in parallel arrangement V is same so I=1R means greater the resistance, less is current and vise- versa.

2) Formula:

I=VR

3) Explanation:

a)

Here, in fig 27-18a, the resistance R1& R2 are in parallel arrangement. So, the voltage difference across them is same.

b)

As the voltage is same in parallel arrangement, the current depends only on the resistance from Ohm’s law.

I=VR

V is constant for parallel arrangement. So,

I ∝1R

in fig 27-18a, the resistance R1>R2 hence, I2>I1 because the current is inversely proportional to the resistance.

Conclusion:

We can compare the current and the potential difference across the resistances using the concept of parallel arrangement of the resistances and the equation of Ohm’s law.

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Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

To find:

a) The potential difference across R2 more than, less than or equal to that of across R1

b) The current across R2 more than, less than or equal to that of across R1

Answer to Problem 1Q

Solution:

a) The potential difference across R2 is same that of across R1.

b) The current across R2 is more than that of across R1.

Explanation of Solution

1) Concept:

If the resistances are connected in parallel, then the voltage across the resistances is same only the current gets divided. And the value of the current depends only on the resistance because the voltage is same in parallel arrangement.

V=IR where V is voltage, I is current and R is resistance.

As in parallel arrangement V is same so I=1R means greater the resistance, less is current and vise- versa.

2) Formula:

I=VR

3) Explanation:

a)

Here, in fig 27-18a, the resistance R1& R2 are in parallel arrangement. So, the voltage difference across them is same.

b)

As the voltage is same in parallel arrangement, the current depends only on the resistance from Ohm’s law.

I=VR

V is constant for parallel arrangement. So,

I ∝1R

in fig 27-18a, the resistance R1>R2 hence, I2>I1 because the current is inversely proportional to the resistance.

Conclusion:

We can compare the current and the potential difference across the resistances using the concept of parallel arrangement of the resistances and the equation of Ohm’s law.

Answer 8

Expert Solution & Answer

To determine

To find:

a) The potential difference across R2 more than, less than or equal to that of across R1

b) The current across R2 more than, less than or equal to that of across R1

Answer to Problem 1Q

Solution:

a) The potential difference across R2 is same that of across R1.

b) The current across R2 is more than that of across R1.

Explanation of Solution

1) Concept:

If the resistances are connected in parallel, then the voltage across the resistances is same only the current gets divided. And the value of the current depends only on the resistance because the voltage is same in parallel arrangement.

V=IR where V is voltage, I is current and R is resistance.

As in parallel arrangement V is same so I=1R means greater the resistance, less is current and vise- versa.

2) Formula:

I=VR

3) Explanation:

a)

Here, in fig 27-18a, the resistance R1& R2 are in parallel arrangement. So, the voltage difference across them is same.

b)

As the voltage is same in parallel arrangement, the current depends only on the resistance from Ohm’s law.

I=VR

V is constant for parallel arrangement. So,

I ∝1R

in fig 27-18a, the resistance R1>R2 hence, I2>I1 because the current is inversely proportional to the resistance.

Conclusion:

We can compare the current and the potential difference across the resistances using the concept of parallel arrangement of the resistances and the equation of Ohm’s law.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

To find:

a) The potential difference across R2 more than, less than or equal to that of across R1

b) The current across R2 more than, less than or equal to that of across R1

Answer 12

Answer to Problem 1Q

Solution:

a) The potential difference across R2 is same that of across R1.

b) The current across R2 is more than that of across R1.

Answer 13

Explanation of Solution

1) Concept:

If the resistances are connected in parallel, then the voltage across the resistances is same only the current gets divided. And the value of the current depends only on the resistance because the voltage is same in parallel arrangement.

V=IR where V is voltage, I is current and R is resistance.

As in parallel arrangement V is same so I=1R means greater the resistance, less is current and vise- versa.

2) Formula:

I=VR

3) Explanation:

a)

Here, in fig 27-18a, the resistance R1& R2 are in parallel arrangement. So, the voltage difference across them is same.

b)

As the voltage is same in parallel arrangement, the current depends only on the resistance from Ohm’s law.

I=VR

V is constant for parallel arrangement. So,

I ∝1R

in fig 27-18a, the resistance R1>R2 hence, I2>I1 because the current is inversely proportional to the resistance.

Conclusion:

We can compare the current and the potential difference across the resistances using the concept of parallel arrangement of the resistances and the equation of Ohm’s law.