Current Electricity Solutions for ICSE Class 10 Physics PDF

Summary

This document contains solutions to the practice questions on the chapter current electricity from class 10 physics. The solutions are concise and cover the key concepts of electric current, potential difference and resistance. The solutions are from Selina Publishers for ICSE board.

Full Transcript

ICSE Selina Solutions for Class 10
Physics
Chapter 8 – Current Electricity

Exercise (8A)

1. Define the term current and state its S.I. unit.
Ans: Electric Current is defined as the rate of flow of electric charges. Mathematically
it can be written as
I = q/t
where q is the charge and t is time. The SI unit of current is Ampere.

2. Define the term Electric Potential. State its S.I. unit.
Ans: Electric Potential at a point is defined as the amount of work done required by a
positive charge in bringing from infinity to a particular point. It can be formulated as
V= W/q
where W is the work done and q is the charge. The SI unit of potential is Volts.

3. How is the electric potential between two points defined? State its S.I. unit.
Ans: Electric Potential between two points is the amount of work done to bring the
unit positive charge from one point to the other.
Example If VA is the electric potential at point A and VB is the electric potential at
point B then
ΔV = VA -VB =W/q
where W is the work done and q is the charge. The SI unit of potential is Volts.

4. Explain the statement ‘the potential difference between two points is 1volt’.

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Ans: The statement ‘the potential difference between two points is 1volt’ is used when
1 Joule of work is done to move a charge of 1 coulomb from infinity to a particular
point in an electric circuit.

5. (a) State whether the current is a scalar or vector ? What does the direction of
current convey?
(b) State whether the potential is a scalar or vector? What does the positive and
negative sign of charge convey?
Ans: (a) Electric current is a scalar quantity those physical quantities which only have
magnitude associated with them are termed as Scalars. Although current has direction,
it only follows the algebraic laws of addition.
The direction of current signifies that electrons are flowing in the opposite direction as
that of current through the closed circuit.
(b) Potential is also a scalar quantity. According to the definition itself, it’s the amount
of work done required by a positive charge in bringing from infinity to a particular
point.
The sign of charge signifies the work done by either a positive or negative charge
against the electrostatic forces in bringing the charge from infinity to a particular
point.

6. Define the term resistance. State its S.I. unit.
Ans: Resistance is kind of opposition offered by the conductor to resist the flow of
charges flowing through it, The SI unit of resistance is ohm(Ω).

7. (a) Name the particles which are responsible for the flow of current in a
metallic wire.
(b) Explain the flow of current in a metallic wire on the basis of movement of the
particles named by you above in part(a)
(c) What is the cause of resistance offered by the metallic wire in the flow of
current through it?
Ans: (a) Electrons especially valence or free are responsible for the current flow in a
metallic wire.

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(b) When the ends of conductor are connected to a battery or some kind of external
current source the free electrons( those which are mainly present in the last shell of
atom) starts experiencing a internal force resulting to the movement of them in the
particular direction i.e. from the negative terminal to the positive terminal of battery.
During this passage they collide with the fixed positive ions, losing some kinetic
energy in the form of heat. This process continues leading to the flow of current in the
circuit from positive to the negative terminal.
Direction of current is always taken opposite to the flow of electrons in the circuit.
(c) The collisions suffered by the free electrons with the fixed positive ions are
responsible for the cause of resistance offered by the metallic wire in the flow of
current through it.

8. State Ohm’s law and draw a neat labelled circuit diagram containing a battery,
a key, a voltmeter, an ammeter, a rheostat and an unknown resistance to verify
it.
Ans: According to Ohm's law if the physical conditions and temperature of a
conductor is kept constant then the current flowing through the conductor is directly
proportional to the potential ends across the ends of conductor.
V=IR
where V is the potential difference, I is the current flowing through the conductor and
R is the constant called resistance.
Diagram used for the verification of Ohm’s law

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9. (a) Name and state the law which relates the potential difference and current in
a conductor.
(b) What is the necessary condition for a conductor to obey the law named above
in part (a)?
Ans: (a) Ohm’s law relates the potential difference and current in a conductor.
According to Ohm's law if the physical conditions and temperature of a conductor is
kept constant then the current flowing through the conductor is directly proportional to
the potential ends across the ends of conductor.
V = IR
where V is the potential difference, I is the current flowing through the conductor and
R is the constant called resistance.
(b) The physical conditions and temperature of the conductor should be kept constant
regarding the abeyance of Ohm's law.

10. (a) Draw a V-I graph for conductor obeying Ohm’s law.(b) What does the
slope of the V-I graph for a conductor represent?
Ans: (a)

(b)The slope of the V-I graph represents the resistance of the conductor.
Slope= Resistance=ΔV/ΔI

11. Draw an I-V graph for a linear resistor. What does its slope represent?

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Ans:

The slope of the I-V graph represents 1/Resistance of the conductor.

12. What’s an Ohmic resistor? Give one example of an ohmic resistor. Draw a
graph to show its current -voltage relationship. How is the resistance of the
resistor determined from the graph?
Ans: Those resistors which follow the Ohm’s law are termed as Ohmic Resistors.
These include all conductors like Copper, Aluminium, Nichrome, Tungsten etc.

The resistance for these resistors is calculated with the help of slope. The slope of the
straight line passing through the origin on the V-I graph gives the resistance.
Slope = Resistance =ΔV/ΔI

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13. What are non-ohmic resistors? Give one example and draw a graph to show
its current-voltage relationship.
Ans: Those resistors which don’t obey the Ohm’s law are called non-ohmic resistors.
For these the slope of V-I graph is a curve line not a straight one passing through
origin. These include solar cells, junction diode, transistor, filament of bulb and LEDs.

14. Give two differences between an Ohmic and Non-Ohmic resistor.
Ans:

S.no. Ohmic Resistor Non-Ohmic resistor
1 These obey Ohm’s law i.e. value These don’t obey Ohm’s law i.e.
of V/I is constant for all values of V/I is not same for all values of
V and I. V and I.
2 These mainly include all types of These include LEDs, junction
conductors like silver, nickel and diodes, transistors and filament
electrolytes with appropriate of bulb.
electrodes.
3 The slope of the V-I graph for The slope of the V-I graph for
these is a straight line passing these is a curve line that doesn’t
through the origin. pass through the origin.

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15. Fig shows I-V curves for two resistors. Identify the ohmic and non ohmic
resistors. Give a reason for your answer.

Ans: (a) is for non-ohmic resistor whereas (b) is the ohmic resistor.
Ohmic resistors are those which follow Ohm's law and the slope of the V-I graph for
these is a straight line passing through the origin.
Non-Ohmic are those resistors which don’t obey Ohm's law.For these the slope of the
V-I graph is a curve line not a straight one passing through the origin.

16. Draw a V-I graph for the conductor at two different temperatures. What
conclusion do you draw from your graph for the variation of resistance of the
conductor with temperature?
Ans: One can observe the nature of curves for both A and B. As T1>T2 the area under
the curve A is more than the area under the curve B. Hence the resistance for A is
more than B. This shows that resistance is directly proportional to temperature.

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17. (a) How does the resistance of a wire depend on its radius? Explain your
answer.
(b) Two copper wires are the same length, but one’s thicker than the other.
Which will have more resistance?
Ans: (a) R ∝ 1/area
Resistance of wire is inversely proportional to the cross sectional area of wire, which
means a thicker wire will offer less resistance as the electrons get a larger area of cross
section to flow as compared to thin wire which will offer more resistance due to lesser
area of cross section.
(b) The wire having a lesser area of cross-section will offer more resistance.

18. How does the resistance of the wire depend on its length? Give reason for
your answer.
Ans: R ∝ length
Resistance of wire is directly proportional to the length of wire. A long conductor
offers more collisions of free electrons with fixed positive ions leading to more
resistance and less flow of current in the wire.

19. How does the resistance of a metallic wire depend on its temperature?
Explain the reason.
Ans: R ∝ temperature

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Resistance of a metallic wire is directly proportional to the temperature.With the
increase in temperature the random motion of electrons increases resulting in more
collisions of free electrons with fixed positive ions. Hence resistance increases with
increase in temperature.

20. Two wires, one of copper and the other of iron, are of same length and same
radius. Which one will have more resistance? Give a reason.
Ans: The resistivity or specific resistance is the materialistic property of a conductor.
Iron has more value of specific resistance than that of copper hence if the length and
radius of both wires are same the resistance will depend directly on the specific
resistance of the material.
R ∝ resistivity

21. Name three factors on which resistance of a given wire depends and state how
it is affected by the factors stated by you.
Ans: Resistance mainly depends on the length of wire, cross-sectional area of wire
and the nature of material.
1. Resistance is in direct relation to the length of wire. (R ∝ length)
A longer wire will have more resistance than a shorter one of the same material as
more collisions will take place between electrons and the fixed positive ions leading to
more resistance.
2. Resistance is inversely proportional to the cross sectional area of wire.
(R ∝ 1/area)
Which means a thicker wire will offer less resistance as the electrons get a larger area
of cross section to flow as compared to thin wire which will offer more resistance due
to lesser area of cross section.
3. Resistance is directly proportional to the nature of material or R ∝ resistivity.
The resistivity or specific resistance is the materialistic property of a conductor. Iron
has more value of specific resistance than that of copper hence if the length and radius
of both wires are same.

22. Define the term specific resistance and state its S.I. unit.

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Ans: As per the knowledge R= ⍴l/a
Where ⍴ = resistivity or the specific resistance of the material
l = length of wire and a = cross sectional area
If the length = area = 1 then ⍴ = R which means the specific resistance is the resistance
of wire when the length and cross sectional area of wire is 1unit.
The SI unit of specific resistance is Ωm.

23. Write an expression connecting the resistance of a wire and specific resistance
of its material. State the meaning of the symbols used.
Ans: Formula connecting the resistance of a wire and specific resistance of its material
is R= ⍴l/a, where ⍴ = resistivity or the specific resistance of the material
l = length of wire and a = cross sectional area.

24. State the order of specific resistance of (i) a metal, (ii) a semiconductor and
(iii) an insulator
Ans: For the metals the order of the specific resistance is approximately equal to 10-8
Ωm.
(ii) For semiconductors order of resistivity is around 10-5 Ωm
(iii) Whereas for insulators it’s 1013 Ωm.

25. (a) Name two factors on which the specific resistance of a wire depends?
(b) Two wires A and B are made of copper. The wire A is long and thin, while the
wire B is short and thick. Which will have more specific resistance?
Ans: (a) The specific resistance is the characteristic property of material hence it is
dependent on the nature of material and also on the temperature of material.
For metals the specific resistance is directly proportional to the temperature whereas
for the semiconductors the specific resistance increases with decrease in temperature.
(b) Both the wires A and B will have the same value of specific resistance as it’s
independent of the length and cross- sectional area of wires.

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26. Name a substance of which the specific resistance remains almost unchanged
by the increase in temperature.
Ans: Manganin is an alloy of Copper, Nickel and Manganese and for certain alloys the
specific resistance almost remains constant.

27. How does the specific resistance of a semiconductor change with the increase
in temperature?
Ans: For the semiconductors the specific resistance decreases with the increase in
temperature which means it’s having a negative coefficient of resistance.

28. How does (a) resistance, and (b) specific resistance of a wire depend on its (i)
length, and (ii) radius?
Ans: (a) Resistance is in direct relation to the length of wire. (R∝length)
and is inversely proportional to the cross sectional area of wire (R∝1/area)
(b) Specific resistance of a wire is independent of both the length and radius as it
depends only on the nature and temperature of material.

29. (a) Name the material used for making connection wires. Give a reason for
your answer.
(b) Why should a connection wire be thick?
Ans: (a) The connection wires are mainly made of Copper or Aluminium as they have
very less value of specific resistance. Because of the low value of specific resistance
the current almost remains constant and hence the dissipation in heat is prevented.
(b) The connection wires should be made thick as a wire will be more will be the area
for electrons to face the collisions with the fixed positive ions, hence the resistance
will be less leading to less heat losses.
(R∝1/area)

30. Name a material which is used for making a standard resistor. Give a reason
for your answer.

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Ans: In order to make a standard resistor the material should have a high value of
resistance and their values should not change often with temperature. So, Manganin is
suitable for making standard resistors.

31. Name the material used for making a fuse wire. Give a reason.
Ans: Alloys of copper and tin are generally used for making the fuse wire. Because of
the low value of melting point and high value of specific resistance they are more
suitable for the flow of current upto the safe limit.

32. Name the material used for (i) filament of an electric bulb, and (ii) heating
element of a room heater.
Ans: (i) Tungsten is used mainly for the filament of the electric bulb because of the
high value of melting point.
(ii) Nichrome is used as the heating element of a room heater. The specific resistance
of nichrome is high and it also increases with increase in temperature.

33. What is a superconductor? Give one example of it.
Ans: Superconductors are those substances which have zero resistance at a very low
temperature. As the resistance of these materials is zero they will have infinite
conductance. Example: Lead below 7.25K.

34. A substance has zero resistance below 1K. What is such a substance called?
Ans: This substance is called Superconductor. Superconductors are those substances
which have zero resistance at a very low temperature.

MULTIPLE CHOICE TYPE

1. Which of the following is an ohmic resistance?
(a) LED
(b) junction diode
(c) filament of a bulb

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(d) nichrome wire
Ans: Correct option (d) Nichrome wire
Explanation:- LED, junction diode and filament of bulb are the examples of non
ohmic devices whereas nichrome wire is an ohmic resistance device.

2. For which of the following substances, resistance decreases with the increase in
temperature?
(a) Copper
(b) mercury
(c) Carbon
(d) platinum
Ans: Correct option (c) carbon
Explanation: Copper, mercury, platinum are the examples of metals and for those the
resistance always increases with the increase in temperature. Hence carbon is a
semiconductor material and for these the resistance decreases with the increase in
temperature.

NUMERICALS

1. In a conductor 6.25 × 1016 electrons flow from its end A to B in 2s. Find the
current flowing through the conductor. (e = 1.6 × 10-19 C)
Ans:No. of electrons flowing(n) = 6.25 × 1016
Charge on each electron =1.6 × 10-19 C
Hence current (i) = ne/t
Where n = no. of electrons flowing through the conductor.
e = electronic charge
t = time for which the electrons flow
i = 6.25 × 1016 × 1.6 × 10-19 /2
i = 5 × 10-3 A = 5mA
The current flowing through the end B to A is 5mA.

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2. A current of 1.6mA flows through a conductor. If charge on an electron is -1.6
× 10-19 C, find the number of electrons that will pass each second through the
cross section of that conductor.
Ans: Current (I) = 1.6mA = 1.6 × 10-3A
Charge on each electron = -1.6 × 10-19 C
No. of electrons = ?
Current (I) = ne/t
1.6 × 10-3 = 1.6 × 10-19 × n (taking the magnitude of charge only)
n= 1.6 × 10-3/1.6 × 10-19
n=1016 therefore no of electrons flowing through the conductor is 1016.

3. Find the potential difference required to flow a current of 200mA in a wire of
resistance 20Ω.
Ans: Current (I) = 200mA = 200 × 10-3 A = 0.2A
Resistance (R) = 20Ω.
According to Ohm’s law V = IR
Hence V= 0.2 × 20 =4
Therefore the potential difference required to flow the current is 4V

4. An electric bulb draws 1.2A current at 6.0V. Find the resistance of the filament
while glowing.
Ans: Current(I) = 1.2.A
Potential difference (V)=6V
Acc. to Ohm’s law V=IR
Hence R =V/I = 6/1.2 = 60/12 = 5Ω
Hence the resistance of the filament while glowing = 5Ω

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5. A car connected to a 12 volt battery draws 2A current when glowing.What is
the resistance of the filament of the bulb? Will the resistance be more,same or
less when the bulb is not glowing?
Ans:-Potential difference across car =12V
Current (I)=2A
According to Ohm’s law V=IR
Hence R=V/I = 12/2 =6Ω
Therefore the resistance of filament of the bulb is 6Ω.
The resistance will be more if the bulb is not glowing as there is no current flowing
through the bulb at that time.

6. Calculate the current flowing through the wire of resistance 5Ω connected to a
battery of potential difference 3V.
Ans: Potential difference across battery =3V
Resistance(R) = 5Ω
According to Ohm’s law V=IR
Hence I = V/R = 3/5 = 0.6A
The current flowing through the battery is 0.6A

7. In an experiment of verification of Ohm’s law, following observations are
obtained.

Potential difference V (in volt) 0.5 1.0 1.5 2.0 2.5
Current I (in ampere) 0.2 0.4 0.6 0.8 1.0

Draw a V-I graph and use this graph to find:
a) the potential difference V when the current I is 0.5A
b) the current I when the potential difference V is 0.75V
c) the resistance in the circuit

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Ans:

(a) When the current is 0.5A the potential difference = 1.25V
(b) when the potential difference is 0.75 V the current is 0.3A
(c) Resistance = slope of V-I graph = 1.0-0.5/0.4-0.2 = 0.5/0.2 = 2.5Ω

8. Two wires of the same material and same length have radii 1mm and 2mm
respectively. Compare
(i) their resistances
(ii) their specific resistance
Ans:
(i) radii(r1) = 1 mm = 1 × 10-3m
radii(r2) = 2mm =2 × 10-3m
Area(A1) = ℼ(r1)2
Similarly Area (A2) = ℼ(r2)2
As (R∝1/area)
so R1/R2= A2/A1
= ℼ(r2)2/ℼ(r1)2
= ℼ × 4 × 10 – 6/ℼ × 1 × 10-6 = 4:1
Hence, the resistances are in the ratio 4:1.

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(ii) Since the nature of material is the same, the specific resistances will also be the
same as it’s independent of length and radius. So the ratio will be 1:1.

9. A given wire of resistance 1Ω is stretched to double its length. What will be its
new resistance?
Ans: Resistance =1Ω
Original length = l1
According to the ques it’s said that the new length l2= double of original length =
2l1………..(i)
The volume of wire will always remains constant hence A1l1=A2l2
So A1 l1 = A2 2 l1
Or A2 = A1/2……………..(ii)
As we know R1 = ₰l1/A1 and R2 = ₰l2/A2,
R1/R2 = l1A2/l2A1……………….(iii)
Substituting (i) and (ii) in (iii)
R1/R2 = 1/4 and since R1 = 1Ω the new resistance will be R2= 4Ω

10. A wire of resistance 3Ω and length 10cm is stretched to length 30cm.
Assuming that it has a uniform cross section, what will be its new resistance?
Ans: Resistance =3Ω
Original length = 10cm
According to the question it’s said that the new length l2 = 30cm
And the area of cross section is uniform which means (R∝length)2
Hence R2/R1 =(l2/l1)2
R2/R1=9 and since R1=3Ω the new resistance will be R2= 9Ω

11. A wire of resistance 9Ω having length 30 cm is tripled on itself. What is the
new resistance?
Ans: Resistance = 9Ω

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Original length = l1
According to the ques it’s said that the new length l2= tripled on itself = l1/3 = 30/3
=10cm………..(i)
The volume of wire will always remain constant hence A1l1=A2l2
So A1 × 30 = A2 × 10
Or A2=3A1……………..(ii)
As we know R1=₰l1/A1 and R2=₰l2/A2,
R1/R2= l1A2/l2A1……………….(iii)
Substituting (i) and (ii) in (iii)
R1/R2=9 and since R1=9Ω the new resistance will be R2= 1Ω

12. What length of copper wire of specific resistance 1.7 × 10-8 Ωm and radius
1mm is required so that its resistance is 1Ω?
Ans: Resistance of wire = 1Ω
Radius of wire = 1mm = 10-3 m hence Area = π × 10-6m2.
Specific resistance (₰)=1.7 × 10-8Ωm
As we know R=₰l/A
So the length of wire l=RA/₰
= 1× π × 10-6 / 1.7 × 10-8 = 1.847 × 102m = 184.7m

13. The filament of a bulb takes a current 100mA when the potential difference
across it is 0.2V. When the potential difference across it becomes 1.0V, the
current becomes 400mA. Calculate the resistance of the filament in each case and
account for the difference.
Ans: Potential difference across bulb = 0.2V
Current (I) = 100mA = 0.1A
According to Ohm’s law V=IR
Or R =V/I = 0.2/0.1 =2Ω
In the second case when the current becomes 400mA = 0.4A

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Potential difference =1V
Again by Ohm’s law V2=I2R2
Or R2=V2/I2 = 1/0.4 = 2.5Ω
Hence one can say that when the potential difference is increased the resistance also
increases.

Exercise (8B)

1. Explain the meaning of the term e.m.f., terminal voltage, and internal
resistance of a cell.
Ans:
e.m.f.: The electro-motive force (e.m.f.) is defined as the maximum potential
difference that can be applied in the circuit within which no current is flowing in it.
Terminal voltage: The potential difference between the electrodes of the cell when
current is drawn from a cell is called its terminal voltage or in other words the
potential difference across the points through the resistance R is called terminal
voltage.
Internal Resistance: The internal resistance of the cell is defined as the resistance
offered by the electrolyte inside the cell when current passes through it.

2. State two differences between the e.m.f. and terminal voltage of a cell
Ans:

s.no. e.m.f. terminal voltage
1 The electro-motive force (e.m.f) is The potential difference between
defined as the maximum potential the electrodes of the cell when
difference that can be applied in current is drawn from a cell is
the circuit within which no current called its terminal voltage. So
is flowing in it. So Emf is an open Terminal voltage is a closed-
circuit voltage. circuit voltage.
2 emf is calculated by given Terminal voltage is calculated by
formula: ε = I(R+r) given formula : V = IR
here, R- External resistance of the Here, I- Current flowing through

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 electrical circuit. the circuit
r- Internal resistance of the given R- External resistance of the
circuit electrical circuit.

3. Name two factors on which the internal resistance of a cell depends and state
how does it depends on the factors stated by you.
Ans: The factors on which internal resistance of a cell depends are given below:
(i) The surface area of the electrodes: if we take Larger the surface area of the
electrodes of the cell then its internal resistance would be less.
(ii) The distance between the electrodes: if we take a cell which has greater the
between the electrodes of the cell then it has more internal resistance.

4. A cell of e.m.f. ε and internal resistance r is used to send current to an external
resistance R. Write expression for
(a) the total resistance of circuit,
(b) the current drawn from the cell,
(c) the p.d. across the cell, and
(d) the voltage drop inside the cell.
Ans:
(a) Total resistance = R + r
(b) Current drawn from the circuit:
As we know that,
ε=V+v
ε = IR + Ir
ε = I(R+r)
I = ε/ (R + r)
(c) p.d. across the cell: (𝜀𝜀R)/(𝑅𝑅+𝑟𝑟)
(d) voltage drop inside the cell: (𝜀𝜀r)/(𝑅𝑅+𝑟𝑟)

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5. A cell is used to send current to an external circuit. (a) How does the voltage
across its terminals compare with its e.m.f.? (b) Under what condition is the
e.m.f. of the cell equal to its terminal voltage?
Ans:
(a) A cell is used to send current to an external circuit the voltage across its Terminal
(terminal voltage) is less than the emf.
(b) When no current is drawn in the circuit then emf of the cell is equal to the terminal
voltage.

6. Explain why the p.d. across the terminals of a cell more in an open circuit and
reduced in a closed circuit.
Ans: When an electric cell is in a closed circuit, the current flows in a circuit. There is
a decrease in potential through all internal cell resistance of the cell. Therefore, p.d.
across the terminals in a closed circuit is less than p.d. across the terminals in an open
circuit. And this decreased potential is equal to the potential drop across the internal
resistance of the cell.

7. Write the expressions for the equivalent resistance R of three resistors R1 R2
and R3 join in (a) parallel, and (b) series.
Ans:
(a) Total Resistance in series:
R = R1 + R2 + R3
(b) Total Resistance in parallel:
1/R = 1/R1 + 1/R2 +1/R3

8. How would you connect two resistors in series? Draw a diagram. Calculate the
total equivalent resistance.
Ans: Connections of two resistors in series –

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 R1 R2
A

+ -

If current I is drawn from the battery. We know that in series connections, the current
through all resistors will be the same as I.
On applying Ohm's law to the two resistors separately, we further have
V1 = I R1
V2 = I R2
V= V1 + V2
IR = I R1+ I R2
R = R1+ R2
Total Resistance in series R = R1+ R2
That is the sum of all resistances connected in series.

9. Show by diagram how two resistors R1 and R2 are joined in parallel. Obtain an
expression for the total resistance of the combination.
Ans: Two resistors R1 and R2 are joined in parallel shown in figure

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We know that in parallel combinations the potential across the resistors are the same ,
which is V and current is divided through all the resistors.
On applying Ohm's law to the two resistors separately, we further
Have
I1 = V / R1
I2 = V / R2
I = I1 + I2
V / R = V / R1+ V / R2
Then the total Resistance in parallel:
1/R = 1/R1 + 1/R2

10. State how are the two resistors joined with a battery in each of the following
cases when:
(a) same current flows in each resistor.
(b) potential difference is same across each resistor.
(c) equivalent resistance is less than either of the two resistors and
(d) equivalent resistance is more than either of the two resistances.
Ans:
(a) Two resistors joined in series with a battery, then the same current flows in each
resistor.
(b) Two resistors joined in parallel with a battery, then potential difference is same
across each resistor.
(c) Two resistors joined in parallel with a battery then equivalent resistance is less than
either of the two resistors
(d) Two resistors joined in series with a battery then equivalent resistance is more than
either of the two resistances.

11. The V-I graph for a series combination and for a parallel combination of two
resistors is shown in fig. 8.40. Which of the following two, A or B, represent the
parallel combination? Give a reason for your answer.

Class X Physics www.vedantu.com 23
 Y
B

A
V

X
I

Ans: As we know that the slope of the V-I graph gives resistance. From the diagram
straight line A is less steeper than line B. It means slope of line A is less than line B.
Therefore line A represents small resistance and line B represents more resistance.
And we also know that the equivalent resistance for two resistances in series
connection is more than in parallel connections.So straight line A represents the
parallel combination.

Multiple Choice Type:

1. In series combination of resistances:
(a) p.d. is same across each resistance.
(b) total resistance is reduced
(c) current is same in each resistance
(d) all above are true.
Ans: Option (c) is the correct answer.
We know that in series combination the current is the same in each resistance that is
connected in the circuit.

2. In parallel combination of resistances:
(a) p.d. is same across each resistance.
(b) total resistance is increased
(c) current is same in each resistance
(d) all above are true.

Class X Physics www.vedantu.com 24
Ans: Option (a) is the correct answer.
We know that in parallel combinations of resistances the potential difference is the
same across each resistance that is connected in the circuit.

3. Which of the following combinations have the same equivalent resistance
between X and Y?
(a)

(b)

(c)

Class X Physics www.vedantu.com 25
(d)

Ans:
Option (a) and (d) are correct options.
In fig (a), the resistors are connected in parallel
Between X and Y.
Let R be the equivalent resistance.
the total Resistance in parallel:
1/R = 1/R1 + 1/R2
1/R = ½ + ½ = 1
R = 1 Ω ………………….(i)
In fig (d) a series combination of two 1Ω resistors is in parallel with another series
combination of two 1Ω resistors
Series resistance of two 1 Ohm resistors,
R=1+1=2Ω
Thus, we can say that across X and Y, two 2Ω resistors
are connected in parallel
Let R’ be the net resistance across X and Y then
1/R’ = ½ + ½
R’ = 1 Ω …………………… (ii)
From (i) and (ii), it is clear that (a) and (d) have the same equivalent resistance
between X and Y.

Class X Physics www.vedantu.com 26
Numericals -

1. The diagram in Fig. 8.40 shows a cell of e.m.f. ε = 2 volt and internal resistance
r = 1 ohm to an external resistance R = 4 ohm. The ammeter A measures the
current in the circuit and the voltmeter V measures the terminal voltage across
the cell. What will be the readings of the ammeter and voltmeter when (i) the key
K is open, (ii) the key K is closed.

Ans: (i) when the key K is open then there is no current so Ammeter reading would be
zero
Ammeter reading = 0
Voltage V = ϵ − Ir
V = 2 – (0 × 1) = 2 volt
So voltmeter reading = 2 volt
(ii) when the key K is closed then Ammeter reading:
I = ε / (R + r)
I = 2 / (4+1) = 2 / 5 = 0.4 A
Ammeter reading = 0.4 amp
Voltage reading:
Voltage V = ϵ - Ir
V = 2 - 0.4 x 1 = 2 - 0.4 = 1.6 V
Voltage reading = 1.6 V

Class X Physics www.vedantu.com 27
2. A battery of e.m.f. 3.0 V supplies current through a circuit in which the
resistance can be changed. A high resistance voltmeter is connected across the
battery. When the current is 1.5 A, the voltmeter reads 2.7 V. Find the internal
resistance of the battery.
Ans: Given e.m.f. = ε = 3 volt
I = 1.5 A
V = 2.7 V
By formula V = ε − Ir
Here r is the internal resistance of the cell or battery.
r = (ε - V) / I
r = (3 – 2.7) / 1.5 = 0.2 ohm

3. A cell of e.m.f. 1.8 V and internal resistance 2 Ω is connected in series with an
ammeter of resistance 0.7 Ω and a resistor of 4.5 Ω as shown in Fig.

(a) What would be the reading of the ammeter?
(b) What is the potential difference across the terminals of the cell ?
Ans: (a) Given emf = ε = 1.8 V
Total Resistance = R = 2 + 4.5 + 0.7 = 7.2 W
Current = I = ?
I = ε / R (total resistance)
I = 1.8 / 7.2 = 0.25 A
Reading of the ammeter Current = 0.25 A
Now, total resistance excluding internal resistance = 4.5 + 0.7 = 5.2 ohm

Class X Physics www.vedantu.com 28
V = IR = 0.25 x 5.2 = 1.3 V
Potential difference across the terminals of the cell is 1.3 V

4. A music system draws a current of 400 mA when connected to a 12V battery.
(a) What is the resistance of the music system?
(b) The music system is left playing for several hours and finally the battery
voltage drops and the music system stops playing when the current drops to
320mA. At which battery voltage does the music system stop playing?
Ans:
(a) Given: current = I = 400mA = 0.4A,
V=12V
By ohm’s law Resistance of the music system =
R = V/I
R = 12 /0.4
R = 30 Ω
(b) Given: I = 320 mA = 0.32A
Resistance of music system = 30Ω
According to Ohm's law,
V= IR = 0.32 ✕ 30 = 9.60V
The music system stops playing at 9.60 Volt.

5. A cell of e.m.f. ε and internal resistance r sends a current 1.0 A when it is
connected to an external resistance 1.9 Ω. But it sends current 0.5 A when it is
connected to an external resistance of 3.9 Ω. Calculate the values of ε and r.
Ans: In first case
I = 1 A, R = 1.9 Ω
ε = I(R + r) = 1(1.9+r)
ε = 1.9 + r------------(1)
In second case

Class X Physics www.vedantu.com 29
I = 0.5 A, R = 3.9 Ω
ε = I(R + r) = 0.5 (3.9 + r)
ε = 1.95 + 0.5r ----------------(2)
From eq. (1) and (2),
1.9 + r = 1.95 + 0.5r
r = 0.05/0.5 = 0.1 Ω
So internal resistance of the cell is o.1 Ω
Substituting value of r
ε = I(R + r) = 1( 1.9 + r) = 1.9 + 0.1 = 2 V

6. Two resistors having resistance 4 Ω and 6 Ωare connected in parallel. Find
their equivalent resistance.
Ans: Let R be their equivalent resistance of the 4Ω and 6Ω resistors connected in
parallel. Then by formula
1/R = 1/R1 + 1/R2
1/R = ¼ + ⅙ = 10/24
R = 24/10 = 2.4 Ω

7. Four resistors each of resistance 2 Ω are connected in parallel. What is the
effective resistance?
Ans: Given R1 = 2 Ω
R2 = 2 Ω
R3 = 2 Ω
R4 = 2 Ω
Now by formula of equivalent resistance in parallel combination
1/R = 1/R1 + 1/R2 + 1/R3 + 1/R4
1/R = ½ + ½ + ½ + ½
1/R = 2

Class X Physics www.vedantu.com 30
R = ½ = 0.5 Ω

8. You have three resistors of values 2Ω , 3Ω and 5Ω. How will you join them so
that the total resistance is less than 1 Ω ? Draw a diagram and find the total
resistance.
Ans: The three resistors (2Ω , 3Ω and 5Ω) should be connected in parallel
combination to get a total resistance less than 1Ω

Let R be the total resistance then by formula
1/R = 1/R1 + 1/R2 + 1/R3
1/R = ½ + ⅓ + ⅕
1/R = 31/30
R = 30/31 = 0.97 ohm

9. Three resistance each of 2 Ω are connected together so that their total
resistance is 3 Ω. Draw a diagram to show this arrangement and check it by
calculation.
Ans: A parallel combination of two resistors, in series with one resistor.

Given R1 = 2 Ω

Class X Physics www.vedantu.com 31
R2 = 2 Ω
R3 = 2 Ω
Let R’ be the total resistance then by formula
1/R’ = 1/R1 + 1/R2
1/R’ = ½ + ½ = 1
R’= 1 Ω
Now this resistance is in series with 2 ohm
R = 1 + R3
R = 1 +2 = 3 Ω

10. Calculate the equivalent resistance between the points A and B in Fig. 8.44 if
each resistance is 2.0 Ω.

Ans: Given R1 = R2 = R3 = R4 = 2 Ω
R’ = R1+ R2
R’ = 2 + 2 = 4 Ω
1/R’’ = 1/R3 + 1/R4
1/R’’ = ½ + ½ = 1
R’’= 1 Ω
Now equivalent resistance R = R’ +R’’
R=4+1=5Ω
Equivalent resistance between the points A and B is 5 ohm

Class X Physics www.vedantu.com 32
11. A combination consists of three resistors in series. Four similar sets are
connected in parallel. If the resistance of each resistor is 2 ohm, find the
resistance of the combination.
Ans: Given resistance of each resistor r = r1 = r2 = r3 = 2
Resistance of each set:
R1 = 2 + 2 + 2 = 6 Ω
R2 = 2 + 2 + 2 = 6 Ω
R3 = 2 + 2 + 2 = 6 Ω
R4 = 2 + 2 + 2 = 6 Ω
Now these resistances are arranged in parallel:
1/R = 1/R1 + 1/R2 + 1/R3+ 1/R4
1/R = ⅙ + ⅙ + ⅙ + ⅙
1/R = 4/6
R = 6/4 = 1.5 Ω
Resistance of the combination = R = 1.5 ohm

12. In the circuit shown below in figure, calculate the value of x if the equivalent
resistance between the points A and B is 4 Ω

Ans:
Given R1 = 4 Ω
R2 = 8 Ω
R3 = x Ω
R4 = 5 Ω
Equivalent resistance = R = 4 Ω

Class X Physics www.vedantu.com 33
R’ = R1+ R2
R’ = 4 + 8 = 12 Ω
R’’ = R3+ R4
R’’ = x + 5 = (x+5) Ω
Now R’ and R’’ are in parallel combination then by formula -
1/R = 1/R’ + 1/R’’
¼ = 1/12 + 1/(x + 5)
⅙ = 1/(x + 5)
X+5=6
X = 6 - 5 = 1 ohm

13. Calculate the effective resistance between the points A and B in the circuit
shown in fig.

Ans: In the below figure,

Resistance between XY in upper arm of = (1 + 1 + 1) = 3 Ω (three resistance of 1 ohm
are in series)

Class X Physics www.vedantu.com 34
Resistance between XY in middle arm = 2 Ω
Resistance between XY in below arm = 2 + 2+ 2 + = 6 Ω (three resistance of 2 ohm
are in series)
Let R be the net resistance between points X and Y Then,
1/R = 1/2 + 1/3 + 1/6 = (3 + 2 + 1)/6
R = 6 /6 = 1 Ω
Thus, now we can say that between points A and B, Three 1 Ω resistors are connected
in series.
Let RAB be the net resistance between points A and B.
Then, RAB = (1 + 1 + 1) = 3 Ω

14. A uniform wire of resistance of 27 Ω is divided into three equal pieces and
then they are joined in parallel. Find the equivalent resistance of the parallel
combination.
Ans: It is given that a uniform Wire cut into three pieces. We know that the resistance
of a wire is directly proportional to the length of the wire.
So new resistance will be = 27/3 = 9 Ω
Now three resistance connected in parallel
1/R = 1/R1 + 1/R2 + 1/R3
1/R = 1/9 + 1/9 + 1/9
1/R = 3/9 = 1/3
R=3Ω

15. A circuit consists of a resistance of 1 ohm in series with a parallel
arrangement of resistors of 6 ohm and 3 ohm. Calculate the total resistance of the
circuit. Draw diagram of the arrangement.
Ans: Parallel arrangement of resistors of 6 ohm and 3 ohm gives the resistance by
formula -
1/R = 1/R1 + 1/R2
1/R = ⅙ + ⅓ = ½

Class X Physics www.vedantu.com 35
R=2Ω
Now this 2 ohm is in series connection with 1 ohm then total resistance of the circuit is
Req = R + 1 = 2 + 1 = 3 Ω
Diagram of the given arrangement is shown below,

16. Calculate the effective resistance between the points A and B in the network
shown below in figure.

Ans:
In the given figure 12 Ω, 6 Ω and 4 Ω resistances are in parallel combination then their
net resistances will be by formula -
1/R = 1/R1 + 1/R2 + 1/R3
1/R = 1/12 + 1/6 + 1/4
1/R = (1+2+3)/12 = 6/12 = ½
R=2Ω
Now this 2 Ω is in series with 2 ohm and 5 ohm
So equivalent resistance between points A and B will be -
RAB = 2 + R + 5 = 2 + 2 + 5 = 9 Ω

17. Calculate the equivalent resistance between the points A and B in figure.

Class X Physics www.vedantu.com 36
Ans: In the given figure we can see that the resistances 3 ohm and 2 ohm are in series
in the upper so their net resistance is
R’ = 3 + 2 = 5 Ω
the resistances 6 ohm and 4 ohm are in series in the lower so their net resistance is
R’’ = 6 + 4 = 10 Ω
Now this R’, 30 ohm and R’’ are in parallel connection then equivalent resistance will
be
1/R = 1/R1 + 1/R2 + 1/R3
1/R = 1/R’ + 1/30 + 1/R”
1/R = 1/5 + 1/30 + 1/10 = 10/30
R = 30 /10 = 3 Ω

18. In the network shown in fig., calculate the equivalent resistance between the
points (a) A and B, and (b) A and C

Ans: (a) As we can see from the diagram RAD RDC RCB are in series connection so net
resistance would be
R’ = 2 + 2 + 2 = 6 Ω

Class X Physics www.vedantu.com 37
Now this 6 ohm resistance is in parallel with 2 ohm resistance
1/R = 1/R1 + 1/R2
equivalent resistance between the points A and B-
1/RAB = ⅙ + ½ = 4/6
RAB = 6/4 = 1.5 Ω
equivalent resistance between the points A and B is 1.5 ohm
(b) Resistance RADC = RAD + RDC = 2 + 2 = 4 Ω
Resistance RABC = RAB + RBC = 2 + 2 = 4 Ω
RADC and RABC are connected in parallel
1/R = ¼ + ¼ = ½
RAC = 2 Ω
equivalent resistance between the points A and C is 2 ohm

19. Five resistors, each of 3 Ω, are connected as shown in fig. 8.50. Calculate the
resistance (a) between the points P and Q, and (b) between the points X and Y.

Ans: (a) Two resistance of 3 ohm of the triangle are in series connection -
R=3+3=6Ω
Now this 6 ohm is connected in parallel with 3 ohm (another resistance of triangle)
1/RPQ = ⅙ + ⅓ = ½
RPQ = 2 ohm
The resistance between the points P and Q will be 2 ohm
(b) The resistance between the points X and Y - the resistance RXP , RPQ and RPQ are in
series combination -
So RXY = RXP + RPQ + RPQ

Class X Physics www.vedantu.com 38
RXY = 3 + 2 + 3 = 8 ohm

20. Two resistors of 2.0 and 3.0 are connected (a) in series, (b) in parallel, with the
battery of 6.0 volt and negligible internal resistance. For each case draw a circuit
diagram and calculate the current through the battery.
Ans:
(a) When two resistors of 2 ohm and 3 ohm are connected in series

R1 =2 Ω
R2 =3 Ω
R = R1+R2 = 2 + 3 = 5 Ω
V=6V
Then by ohm law - V = IR
Current through the battery = I = V /R
I = 6 / 5 = 1.2 A
(b) When two resistors of 2 ohm and 3 ohm are connected in parallel-

R1 =2 Ω

Class X Physics www.vedantu.com 39
R2 =3 Ω
1/R = 1/R1+ 1/R2
1/R = 1/2 + 1/3 = 5/6 Ω
R = 6/5 = 1.2 Ω
V=6V
Then by ohm law - V = IR
Current through the battery = I = V /R
I = 6 / 1.2 = 5 A

21. A resistor of 6 Ω is connected in series with another resistance of 4 V. A
potential difference of 20 V is applied across a combination. Calculate:
(a) the current in the circuit, and
(b) the potential difference across the 6 Ω resistor.
Ans: (a) R1 = 6 Ω
R2 = 4 Ω
R = R1 + R2 = 6 + 4 (in series)
R = 10 Ω
V = 20 V (given)
I = V/R = 20/10 = 2 A
Current in the circuit will be 2 A
(b) R = 6 Ω
I=2A
V=?
By ohm's law
V = IR = 6 × 2 = 12 V
Potential difference across the 6 Ω resistor will be 12 volt

Class X Physics www.vedantu.com 40
22. Two resistors of resistance 4 Ω and 6 Ω are connected in parallel to a cell to
draw current 0.5 A from the cell.
(a) Draw a labelled diagram of the arrangement
(b) Calculate the current in each resistor.
Ans: (a) Labelled diagram of the arrangement -

Equivalent resistance in parallel combination by formula -
1/R = 1/R1 + 1/R2
1/R = 1/4 + 1/6
R = 2.4 Ω
By ohm law -
V = IR
Given current = I = 0.5 A
V = 0.5 × 2.4 = 1.2 v
(b) Current through R1 = 4 ohm
I = V / R1
I = 1.2 / 4 = 0.3 A
Current through R2 = 6 ohm
I = V / R1
I = 1.2 / 6 = 0.2 A

Class X Physics www.vedantu.com 41
23. Calculate the current flowing through each of the resistors A and B in the
circuit shown in fig.

Ans: For resistor A:
R = 1 ohm
V=2V
Current through resistance 1 ohm = I = V/R = 2/1 = 2A
For resistor B:
R = 2 ohm
V=2V
Current through resistance 2 ohm I = V/R = 2/2 = 1A

24. In fig., calculate:
(a) the total resistance of the circuit,
(b) the value of R, and
(c) the current flowing in R.

Class X Physics www.vedantu.com 42
Ans: (a) Given Voltage = V = 4 V
Current = I = 0.4 A
Total Resistance R' =?
By ohm law -
V = IR
Total Resistance = R' = V/I = 0.4/4 = 10 ohm
(b) R1 = 20 ohm
R' = 10 ohm
1/R' = 1/R1 + 1/R
1 /10 = 1/20 + 1/R
1/R = 1/10 - 1/20 = 1/20
The value of R = R = 20 ohm
(c) resistance R = 20 ohm
V=4V
current flowing in R = I = V/R = 4/20 = 0.2 A

25. A particular resistance wire has a resistance of 3.0 ohm per meter. Find: (a)
The total resistance of three lengths of this wire each 1.5 m long, joined in
parallel.
(b) The potential difference of the battery which gives a current of 2.0 A in each
of the 1.5 m length when connected in parallel to the battery (assume that the
resistance of battery is negligible)

Class X Physics www.vedantu.com 43
(c) The resistance of 5 m length of a wire of the same material, but with twice the
area of cross section.
Ans:
(a) Resistance of 1m of wire = 3 ohm
Resistance of 1.5 m of wire = 3 × 1.5 = 4.5 ohm
Now they are joined in parallel combination -
1/R = 1/R1+ 1/R2 + 1/R3
1/R = 1/4.5 + 1/4.5 + 1/4.5
1/R = 3/4.5
R = 1.5 ohm
(b) current = I = 2 A
V = IR = 2 × 4.5 = 9 V
(c) R = 3 ohm for 1 m
For 5 m length the resistance would be: R = 3 × 5 = 15 ohm
But Area A is double i.e. 2A and we know that Resistance is inversely proportional to
cross sectional area so Resistance will be half.
R = 15/2 = 7.5 ohm

26. A cell supplies a current of 1.2 A through two 2 Ω resistors connected in
parallel. When the resistors are connected in series, it supplies a current of 0.4 A.
Calculate:
(i) the internal resistance and
(ii) e.m.f. of the cell.
Ans: when two 2 ohm resistance are connected in parallel
1/R = ½ + ½ = 1
R=1Ω
Current = I = 1.2 A (given)
By formula -
ε = I(R + r)

Class X Physics www.vedantu.com 44
Here r is the internal resistance and ε is the emf.
ε = 1.2(1 + r) = 1.2 + 1.2 r
when two 2 ohm resistance are connected in series then
R=2+2=4Ω
Current in series connection = I = 0.4 A
ε = I(R + r) = 0.4(4 + r) = 1.6 + 0.4 r
By equating e.m.f.
1.2 + 1.2 r = 1.6 + 0.4 r
0.8 r = 0.4
r = 0.4 / 0.8 = ½ = 0.5 Ω
(i) Internal resistance r = 0.5 ohm
(ii)
ε = I(R + r)
Put the value of r
ε = 1.2(1 + 0.5) = 1.8
e.m.f. of the cell = 1.8 volt

27. A battery of e.m.f. 15 V and internal resistance 3 Ω is connected to two
resistors of resistances 3 Ω and 6 Ω connected in parallel. Find:
(a) the current through the battery,
(b) the p.d. between the terminals of the battery.
(c) the current in 3 Ω resistor,
(d) the current in 6 Ω resistor.
Ans: (a) 3 Ω and 6 Ω are in parallel so net resistance -
1/R = 1/3 + 1/6 = 1/2
So R = 2 Ω
Internal resistance = r = 3 Ω (given)
E.m.f. = ε = 15 V (given)

Class X Physics www.vedantu.com 45
By formula -
Put all the known values we can get current through the battery
ε = I(R + r)
15 = I(2 + 3)
I = 15/5 = 3 A
(b) p.d. between the terminals of the battery = V = ?
R=2 Ω
V = IR = 3 × 2 = 6 V
(c) Potential difference = V = 6 V
R=3Ω
Current in 3 Ω resistor = I = V/R = 6/3 = 2 A
(d) Potential difference = V = 6 V
R=6Ω
Current in 6 Ω resistor = I = V/R = 6/6 = 1 A

28. The circuit diagram in fig 8.53 shows three resistors 2Ω, 4Ω and RΩ
connected to a battery of e.m.f. 2V and internal resistance 3Ω if main current of
0.25 A flows through the circuit, find:
(a) the p.d. across the 4Ω resistor,
(b) the p.d. across the internal resistance of the cell,
(c) the p.d. across the RΩ or 2Ω resistor, and
(d) the value of R.

Ans: (a) R = 4 Ω

Class X Physics www.vedantu.com 46
Current in the circuit = I = 0.25 A (given)
From ohm's law -
V = IR = 0.25 × 4 = 1 V
The p.d. across the 4Ω resistor will be 1 volt
(b) Internal Resistance r = 3 Ω (given)
I = 0.25 A (given)
V = IR = 0.25 × 3 = 0.75 V
The p.d. across the internal resistance of the cell will be 0.75 volt
(c) Effective resistance of parallel combination of two 2 Ω resistances is 1 Ω
V = I/R
Voltage across parallel combination -
I = 0.25 A (given)
V = IR = 0.25 × 1 = 0.25 Volt
(d) Current = I = 0.25 A (given)
ε = 2V, internal resistance = r = 3 Ω
By formula -
ε = I(R' + r)
2 = 0.25(R' + 3)
R' = 5 Ω
R' - 4 Ω = parallel combination of R and 2 Ω (by the given diagram)
1 Ω = 1/R + ½
1/R = 1- ½ = ½
R=2Ω

29. Three resistors of 6.0 Ω, 2.0 Ω and 4.0 Ω are joined to an ammeter A and a
cell of emf 6.0 V as shown in fig 8.52 Calculate:
(a) the effective resistance of the circuit and
(b) the reading of ammeter.

Class X Physics www.vedantu.com 47
Ans:
(a) Given R1 = 6 Ω, R2 = 2 Ω , R3 = 4 Ω
R' = R2 + R3 = 2 + 4 = 6 Ω ( R2 and R3 are in series )
Now this R1 and R' in parallel:
1/ R = 1/ R1 + 1/R'
1/R = 1/6 + 1/ 6 = 2/6
R=3Ω
Effective resistance of the circuit = 3 ohm
(b) the reading of ammeter -
R=3Ω
V=6V
Current = I = ?
From ohm law
I = V/R = 6/3 = 2 A
Reading of ammeter - 2 ampere

30. The diagram below in Fig. shows the arrangement of five different resistances
connected to a battery of e.m.f. 1.8 V Calculate:

Class X Physics www.vedantu.com 48
(a) the total resistance of the circuit, and
(b) the reading of ammeter A.
Ans:

(a) In the figure above,
Let resistance between X and Y be Rxy then, by formula of resistance in parallel
combination -
1/Rxy = 1/10 + 1/ 40 = 5/40
Rxy = 8 Ω
Or, R 8 Ω
Let RAB be the net resistance between points A and B. Then by formula of resistance
in parallel combination -
1/RAB = 1/30 + 1/ 20 + 1/60 = 6/60
RAB = 10 Ω

Class X Physics www.vedantu.com 49
∴ Total resistance of the circuit = 8Ω+ 10Ω= 18Ω(8 and 1o ohm are in series )
(b)
By ohm law -
Current = I = Voltage /total resistance
I = 1.8 / 18 = 0.1 A
So the reading of ammeter would be 0.1 A

31. A cell of emf 2V and internal resistance 1.2 ohm is connected to an ammeter
of resistance 0.8 ohm and two resistors 4.5 ohm and 9 ohm as shown in fig.

Find:
(a) the reading of the ammeter,
(b) the potential difference across the terminals of the cell, and
(c) the potential difference across the 4.5 resistor.
Ans:
Given: emf = 2V,
Internal resdiatnce = r = 1.2Ω,
Resistance of ammeter = RA = O.8Ω,
R1 = 4.5Ω , R2 = 9Ω
(a)R1 and R2 are in parallel -
1/Rp = 1/R1 + 1/R2
1/Rp = 1/4.5 + 1/9 = ⅓
Rp = 3 Ω

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We know that for the circuit the total resistance of the circuit is -
R total = Rp + r + RA
R total = 3 + 1.2 + 0.8 = 5Ω
Hence, the current through the ammeter is I = V/Rtotal
I = 2/5 = 0.4A
(b) the potential difference across the terminals of the cell is
Vcell = emf - IRcell
Vcell = 2 – (0.4 × 1.2)
Vcell = 2 - 0.48
Vcell = 1.52 V
(c) The potential difference across the 4.5 resistor is -
V = Vcell - Vammeter
V = 1.52 – (0.4 × 0.8)
V = 1.52 - 0.32 = 1.2 V

Exercise (8C)

1. Write an expression for the electrical energy spent in flow of current through
an electrical appliance in terms of current, resistance and time.
Ans: H = I2 Rt
Where H is the electrical energy produced in the appliance
I is the amount of current flowing through appliance
R is the resistance
And t is the time for which the current flows.

2. Write an expression for the electrical power spent on flow of current through a
conductor in terms of (a) resistance and potential difference (b) current and
resistance.

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Ans: (a) P=V2/R
here P is electrical power in a conductor
V is the potential difference across the conductor and R is the resistance across the
same.
(b) P = I2R where P is electrical power in a conductor
R is the resistance across the conductor and I is the current through the conductor.

3. Electrical power P is given by the expression P = (Q × V) / time
(a)What do the symbols Q and V represent?
(b) Express the power P in terms of current and resistance explaining the
meaning of symbols used there in.
Ans: (a) Q here represents the charge whereas V is the voltage difference across the
conductor.
(b) P=VI, here P is electrical power in a conductor
V is the potential difference across the conductor and I is the current through the
conductor.

4. Name the S.I. unit of electrical energy. How is it related to Wh?
Ans: The S.I. unit of electrical energy is Joule.
1Wh= 3600J

5. Explain the meaning of the statement that the power of an appliance is 100W.
Ans: Power = Energy produced/time
If the power of the appliance is 100W it means 100J of electrical energy is consumed
by the appliance in 1 secs.

6. State the S.I. unit of electrical power.
Ans: The S.I. unit of electrical power is Watt.

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Power is defined as the product of Voltage and current. When 1A current is produced
by the potential difference of 1V across the circuit then the resulting power produced
in the same is 1 Watt.

7. (i) State and define the household unit of electricity.
(ii) What is the voltage of the electricity that is generally supplied to a house?
(iii) What is consumed while using different electrical appliances, for which
electricity bills are paid.
Ans: (i) kWh is the household unit of electricity. It’s defined as the energy consumed
by the device of the power 1 kilowatt operated for 1hr.
(ii) Generally for domestic appliances 220V is the amount of voltage that is supplied.
(iii) Electrical energy is the quantity that’s consumed by using different appliances for
which the electricity bills are paid.

8. Name the physical quantity which is measured in (i) kW, (ii) kWh and (iii)Wh
Ans: (i) Power is usually measured in kW.
(ii) Electrical energy is measured in kWh as kWh is the commercial unit of electricity.
(iii) Electrical energy is the physical quantity that’s measured in Wh.

9. Define the term kilowatt-hour and state its value in S.I. unit.
Ans: kilowatt-hour is the commercial unit of electricity. It’s defined as the energy
consumed by the device of the power 1 kilowatt operated for 1hr.
1kWh = 3.6 × 106 J

10. How do kilowatt and kilowatt-hour differ?
Ans: kilowatt refers to the unit of electrical power whereas kilowatt-hour is the unit of
electrical energy.

11. Complete the following:-
(a) 1 kWh = 1 volt × 1 ampere × ………./1000

Class X Physics www.vedantu.com 53
(b) 1 kWh = ……….J
Ans: (a) 1 kWh = 1 volt × 1 ampere × 1000/1000
(b) 1kWh = 1000J

12. What do you mean by power rating of an electrical appliance? How do you
use it to calculate (a) the resistance of the appliance and (b) the safe limit of
current in it and while in use?
Ans: The power rating of any electrical appliance means the exact value of voltage
upon which the device actually works. Example if a device is written with the power
rating of 60W-230V it means 230V is the voltage at which the device will operate and
it will consume power of 60W.
(a) The resistance of the appliance is calculated by the formula
R=V2/P
Here V is the voltage rating on the appliance and P is the power rating on the
appliance.
(b) Safe limit of current is calculated by the formula
I=P/V
=Power rating on the appliance/Voltage rating on the appliance.

13. An electric bulb is rated ‘100W, 250V’. What information does this convey?
Ans: This statement means if the bulb is operated at 250V then it will consume
electrical power of 100W or 100J of electrical energy in 1 secs.

14. List the names of three electrical gadgets used in your house. Write their
power, voltage rating and approximate time for which each one is used in a day.
Hence find the electrical energy consumed by each in a month of 30 days.
Ans: Electric heater with the power rating as 1000W, Electric mixer with power rating
as 750W and Refrigerator with the power rating 150W are some of the electrical
gadgets used often in home. All these devices work on the domestic supply of 220V
for 1hour daily.

Class X Physics www.vedantu.com 54
In order to calculate the electrical energy consumed by each of them for a month of 30
days
Electric heater:- Power = 1000W
Time for which it’s used daily = 1hr
Power = Electrical energy consumed/time
Hence Electrical energy = Power × time
= 1000 W × 1 hr × 30 = 30000 Wh (for the month of 30 days)
Similarly for electric mixer Power = 750W
Time for which it’s used daily = 1hr
Power = Electrical energy consumed/time
Hence Electrical energy = Power × time
= 750 W × 1 hr × 30 = 22500 Wh (for the month of 30 days)
For Refrigerator Power = 150W
Time for which it’s used daily = 1hr
Power = Electrical energy consumed/time
Hence Electrical energy = Power × time
= 150 W × 1 hr × 30 = 4500Wh (for the month of 30 days)

15. Two lamps, one rated 220V, 50W and the other rated 220V, 100W, are
connected in series with mains of voltage 220V. Explain why the 50W lamp
consumes more power.
Ans: Power = I2/R here I is the current flowing through the lamp and R is the
resistance. Since both the lamps are connected in series, current flowing through both
will be the same, which means P∝1/Resistance
Hence 50W consumes more power than 100W as it’ll be having less resistance than
the other bulb.

16. Name the factors on which the heat produced in a wire depends when current
is passed in it, and state how does it depends on the factors stated by you.

Class X Physics www.vedantu.com 55
Ans: Heat produced in a wire depends on the following factors according to the
relation H = I2 Rt
a) Current flowing through the wire(I)
b) Resistance across the wire(R)
c) time for which the current flows(t)
The heat produced is directly proportional to the square of current flowing through it.
More is the current flowing the more heat will be generated.
Similarly the heat produced is also directly proportional to the resistance of wire and
the time for which current flows through the wire.

MULTIPLE CHOICE TYPE

1. When a current flows through a resistance R for time t, the electrical energy
spent is:
(a) IRt
(b) I2Rt
(c) IR2t
(d) I2R/t
Ans: Correct option is (b)I2Rt
This is the formula for Joule’s law of Heating.

2. An electrical appliance has a rating 100W,120V. The resistance of element of
appliance when in use is:
(a) 1.2Ω
(b)144Ω
(c) 120Ω
(d) 100Ω
Ans: Correct option is (b) 144Ω

Class X Physics www.vedantu.com 56
Given Power = 100W, Potential difference = 120V
According to the formula P=V2/R
Hence R = V2/P
=(120)2/100 = 144Ω

NUMERICALS

1. An electric bulb of resistance 500Ω draws a current of 0.4A from the source.
Calculate: (a) power of the electric bulb and (b) the potential difference at its end.
Ans: (a) Resistance = 500Ω
Current (I) = 0.4A
Power = I2R
Hence it’s equal to (0.4)2 × 500 = 80W
(a) According to Ohm’s law V=IR
= 0.4×500 = 200V

2. A current of 2A is passed through a coil of 75Ω for 2 minutes.(a) How much
heat energy is produced? (b) How much charge is passed through the resistance?
Ans:(a) Resistance = 75Ω
Current (I) = 2A
Time for which current flows (t) = 2mins = 2×60 = 120secs
Heat produced = I2Rt
Hence it’s equal to (2)2×75×120 = 36000J or 36kJ
(b) Current (I) = 2A
Time for which current flows (t) = 2mins = 2×60 = 120secs
I = Q/t
Where Q is the charge flowing through the resistance
Therefore Q =It = 2×120= 240C

Class X Physics www.vedantu.com 57
3. Calculate the current through a 60W lamp rated for 250V. If the line voltage
falls to 200V, how is the power consumed by the lamp affected?
Ans: Given Power = 60W, Potential difference = 250V
According to the formula P=V2/R
Hence R = V2/P
= (250)2/60 = 1041.67Ω
Similarly when the voltage falls to 200V the resistance of the lamp will remain same
hence the new power will be
P’=(V’)2/R
where V’ is the new voltage = 200V
=(200)2/1041.67
=38.4W
Hence the power consumption reduces to 38.4W

4. An electric bulb is rated ‘100W, 250V’. How much current will the bulb draw
if connected to a 250V supply?
Ans: Given Power = 100W, Potential difference = 250V
According to the formula P=VI
Where I is the current flowing through the bulb
Hence 100 = 250×I or I = 100/250 = 0.4A
The current flowing through the electric bulb is 0.4A.

5. An electric bulb is rated ‘220V, 100W’. (a) What is its resistance? (b) What
safe current can be passed through it?
Ans: (a) Given Power = 100W, Potential difference = 220V
According to the formula P=V2/R
Hence R = V2/P
= (220)2/100 =484Ω

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(b) The safe current is calculated by the formula P=VI
Where I is the current flowing through the bulb
Hence 100=220×I or I = 100/220 = 0.45A

6. A bulb of power 40W is used for 12.5h each day for 30 days. Calculate the
electrical energy consumed.
Ans: Given Power = 40W
Time = 12.5hr
According to the formula P=Energy produced /time
Hence electrical energy = P×time
= 40×12.5 = 500Wh.
This energy consumption is for a single day. For 30 days the total electrical energy
consumed will be 500×30 = 15000Wh or 15kWh.

7. A bulb of press is rated ‘750W, 230V’. Calculate the electrical energy
consumed by the press in 16 hours.
Ans: Given Power = 750W, Potential difference = 230V
According to the formula P=Energy produced /time
Hence electrical energy = P×time
= 750×16 = 12000Wh or it can be written as 12kWh.

8. An electrical appliance having a resistance of 200Ω is operated at 200V.
Calculate the energy consumed by the appliance in 5 minutes
(i) joules
(ii) in kWh
Ans: Given Resistance = 200Ω, Potential difference = 200V
According to the formula P=V2/R
Hence P = (200)2/200
= 200W

Class X Physics www.vedantu.com 59
Time for which the appliance works = 5 mins = 5×60 = 300 secs
(i) According to the formula P=Energy produced / time
Hence electrical energy = P×time
= 200×300 = 60000J
(ii) As per the conversion 1kWh = 3600000J
So 60000 J in kWh will be = 60000J/3600000 J = 0.167kWh

9. A bulb rated at 12V, 24W operates on a 12 volt battery for 20 minutes.
Calculate:
(i) the current flowing through it, and
(ii) the energy consumed.
Ans: Given Power = 24W, Potential difference = 12V
time for which current flows = 20 mins = 20×60 = 1200secs
(i)According to the formula P=VI
Where I is the current flowing through the bulb
24=12×I or I =24/12 = 2A
(ii) P=Energy produced /time
Hence electrical energy = P×time
= 24×1200 = 28800J

10. A current of 0.2A flows through a wire whose ends are at potential difference
of 15 V. Calculate
(i) the resistance of the wire, and
(ii) the heat energy produced in 1 minute.
Ans: Given Potential difference = 15V
Current flowing through wire = 0.2A
(i)According to Ohm’s law V=IR
Where R is the resistance of wire hence

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15 = 0.2×R or R = 15/0.2 = 75Ω

(ii) Heat produced in wire H= I2Rt
Time for which current flows = 1min = 60 secs
H=(0.2)2×75×60 = 180J

11. What is the resistance, under normal working conditions, of an electric lamp
rated ‘240V, 60W’? If two lamps are connected in series across a 240V mains
supply, explain why each one appears less bright.
Ans: Given Power = 60W, Potential difference = 240V
According to the formula P=V2/R
Hence R = V2/P
= (240)2/60 =960Ω
By Ohm’s law V=IR
Where I is the amount of current flowing through lamp
I=240/960 = 0.25A
If two lamps are connected in series then the current through each bulb will be 0.25/2
= 0.125 A due to which each one will appear less bright as the heat dissipation across
each bulb will be one fourth
H(through each bulb) = (I/2)2Rt = Rt/4

12. Two bulbs are rated ‘60W, 220V’ and ‘60W, 110V’ respectively. Calculate the
ratio of the resistances.
Ans: Given Power = 60W, Potential difference = 220V
According to the formula P=V2/R
Hence R = V2/P
= (220)2/60 =806.67Ω
For the second case Power (P’) = 60W, Potential difference (V’)= 110V
According to the formula P’=(V’)2/R’

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Hence R’ = (V’)2/P’
= (110)2/60 =201.67Ω
Finally R/R’= 806.67/201.67 = 3.99:1 or ~4:1
The ratio of the resistances is 4:1.

13. An electric bulb is rated ‘250W, 230V’. Calculate
(i) the energy consumed in one hour and
(ii) the time in which the bulb will consume 1.0kWh energy when connected to
230V mains.
Ans:
(i) Given Power = 250W, Potential difference = 230V
Time for which bulb glows = 1hr
According to the formula P=Energy produced /time
Hence electrical energy = P×time
= 250×1 = 250Wh
As 1Wh = 3600J so 250Wh = 250×3600 = 9×105J
(ii) Given electrical energy = 1.0kWh = 1000Wh
Power = 250W hence P=Energy produced /time
= 1000Wh/250 = 4hrs

14. Three heaters each rated ‘250W, 100V’ are connected in parallel to a 100V
supply. Calculate
(i) the total current taken from the supply.
(ii) the resistance of each heater.
(iii) the energy supplied in kWh to the three heaters in 5hours.
Ans: Given Power = 250W, Potential difference = 100V
(i) According to formula P=VI
Where I is the current flowing

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250 = 100 × I or I = 250/100 = 2.5A
(ii) Since all the three resistors are connected in parallel the voltage across each of
them will be same
P=V2/R
R=V2/P =(100)2/250 = 40Ω
This 40Ω is the resistance of each heater.
(iii) P=Energy produced /time
Hence electrical energy = P×time
= 250×3×5 = 3750Wh or 3.75kWh

15. A bulb is connected to a battery of p.d. 4V and internal resistance 2.5Ω. A
steady current of 0.5A flows through the circuit. Calculate
(i) the total energy supplied by the battery in 10 minutes.
(ii) the resistance of the bulb
(iii) the energy dissipated in the bulb in 10 minutes.
Ans: (i) Given internal resistance = 2.5Ω , Potential difference = 4V
Current = 0.5A
Time for which bulb glows = 10mins = 10×60 = 600secs
Power is calculated as P=VI
=4×0.5 = 2W
According to the formula P=Energy produced /time
Hence electrical energy = P×time
=2×600 = 1200J or 1.2kJ
(ii) According to Ohm’s law V=IR
Or R =V/I = 4/0.5 = 8Ω
Resistance of the bulb(R’) = Total resistance of battery - internal resistance =8-2.5 =
5.5Ω

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(iii) Energy dissipation in bulb = I2R’t
=(0.5)2×5.5×600 = 825J

16. Two resistors A and B of resistance 4Ω and 6Ω respectively are connected in
parallel. The combination is connected across a 6 volt battery of negligible
resistance. Calculate :(i) the power supplied by the battery, and (ii) the power
dissipated in each resistor.
Ans: Given RA = 4Ω, RB = 6Ω
Since both are connected in parallel combination hence R(eq) = 4×6/4+6
= 24/10 = 2.4Ω
Potential difference = 6V
(i) Power supplied by the battery P = V2/R
= (6)2/2.4 = 15W
(ii) Power dissipated in each resistor
As the resistances are connected in parallel combination the potential difference across
the resistances will be the same.
Hence PA = V2/RA
= (6)2/4 = 9W
Similarly PB = V2/RB
= (6)2/6 = 6W

17. A battery of emf 15V and internal resistance 2Ω is connected to two resistors
of resistance 4 ohm and 6 ohm joined in series. Find the electrical energy spent
per minute in a 6 ohm resistor.
Ans: Given R1 = 4Ω, R2 = 6Ω
Since both are connected in series combination hence R(eq) = 4+6 +2= 12Ω
Potential difference = 15V
According to Ohm’s law V=IR
Where I is the current flowing through the battery

Class X Physics www.vedantu.com 64
15 = 12×I or I = 15/12 = 1.25A
Voltage across 6ohm resistor = 1.25×6 = 7.5V
Electrical energy spent per minute = V2(t)/R
= (7.5)2×(60)/6
= 562.5J
Hence the electrical energy spent per minute in 6ohm resistor is 562.5J

18. Water in an electric kettle connected to a 220V supply takes 5 minutes to
reach its boiling point. How long will it take if the supply voltage falls to 200V?
Ans: Heat required by the electric kettle to boil water = V2(t)/R
Since the resistance of kettle is same in both cases therefore,
V12(t1) = V22(t2)
(220)2×5 = (200)2×(t2)
(t2)= [(220)2×5]/(200)2 = 6.05 minutes

19. An electric toaster draws current 8A in a circuit with source of 220V. It is
used for 2h. Find the cost of operating the toaster if the cost of electrical energy is
₹4.50 per kWh.
Ans: Given Current = 8A, Potential difference = 220V
time for which current flows = 2h
According to the formula P=VI
Hence P = 8×220 = 1760W
Also P = Energy produced /time
Hence electrical energy = P×time
= 1760×2 = 3520Wh or 3.52kWh
Cost of consuming energy per kWh is ₹ 4.50
Total cost of consuming 3.52 units = ₹ 4.50 × 3.52 = ₹ 15.84 (∵1kWh = 1unit)

Class X Physics www.vedantu.com 65
20 An electric iron is rated 220V, 2kW. If the iron is used for 3h daily, find the
cost of running it for one week if it costs ₹ 4.25 per kWh.
Ans: Given Power = 2kW = 2000W, Potential difference = 220V
time for which current flows = 3h
According to formula P = Energy produced /time
Hence electrical energy = P×time
= 2000×3 = 6000Wh or 6kWh
Cost of consuming energy per kWh is ₹ 4.25
Total cost of consuming 6 units for 1 week = ₹ 4.25 × 7 × 6 = ₹ 178.5 (∵1kWh =
1unit)

21. A geyser is rated ‘1500W, 250V’. This geyser is connected to 250V mains.
Calculate:
(i) the current drawn.
(ii) the energy consumed in 50hours and
(iii) the cost of energy consumed at ₹ 4.20 per kWh.
Ans: Given Power = 1500W, Potential difference = 250V
time for which current flows = 50hrs
(i) According to the formula P=VI
Where I is the current flowing through the bulb
1500 = 250╳I or I = 1500/250 = 6A
(ii) Also P = Energy produced /time
Hence electrical energy = P×time
= 1500×50 = 75000Wh or 75kWh
(iii) Cost of consuming energy per kWh is ₹ 4.20
Total cost of consuming 75 units = ₹ 4.20 × 75 = ₹ 315 (∵1kW h = 1unit)

Class X Physics www.vedantu.com 66