Light Class 10 Quick Revision Notes for CBSE Board Exams

Light is one of the most important chapters in Class 10 Physics because it combines theory, ray diagrams, formulas, sign conventions, and numericals in one place. It is also one of the most frequently asked chapters in CBSE board exams, where students often see 3-mark or 5-mark questions based on mirrors, lenses, refraction, and image formation.

The best way to revise this chapter is not by reading long explanations again and again, but by focusing on the most important concepts: what light is, why we see objects, laws of reflection and refraction, image formation by mirrors and lenses, sign conventions, formulas, refractive index, and power of lens. Once these are clear, the chapter becomes much easier to handle in the exam.

At Deeksha Vedantu, we always encourage students to revise Light in a compact and visual way. This chapter is easiest when students remember the ray-diagram patterns and apply formulas calmly.

Why Light Is Important for CBSE Board Exams

Light is a high-value chapter because it appears regularly in board exams and tests both concept clarity and numerical accuracy.

Why Students Should Revise This Chapter Well

it is a regular CBSE board chapter
it includes 3-mark and 5-mark questions frequently
it contains formulas and diagram-based questions
it includes reflection, refraction, mirrors, and lenses
it is important for theory as well as numericals

Understanding Light and Vision

Light is a form of energy that helps us see the world around us. The chapter becomes easier when students first understand what light is, how it behaves, and why objects become visible to us.

Basic Ideas at a Glance

Concept	Quick explanation
Light	A form of energy that enables vision
Dual nature of light	Light can behave as a particle and as a wave
Why we see objects	Light reflects from objects and enters our eyes
Main phenomenon involved	Reflection of light

Dual Nature of Light

Light shows dual nature. It can behave as:

a particle
a wave

This behaviour depends on the situation.

Why Do We See Objects

We see objects because light falls on them, gets reflected, and then enters our eyes. This is why reflection of light is the first major idea in the chapter.

Reflection of Light and Plane Mirrors

Reflection is the bouncing back of light from a surface. When light falls on a reflecting surface and returns into the same medium, the phenomenon is called reflection.

Laws of Reflection

These are the most basic and important laws in the chapter.

Law	Statement
First law	The angle of incidence is equal to the angle of reflection
Second law	The incident ray, the reflected ray, and the normal at the point of incidence all lie in the same plane

Plane Mirror Image Summary

A plane mirror forms a simple image with fixed properties.

Property	Description
Nature	Virtual
Orientation	Erect
Size	Same as the object
Position	As far behind the mirror as the object is in front
Special effect	Lateral inversion

Spherical Mirrors

The chapter mainly studies two types of spherical mirrors: concave mirror and convex mirror.

Types of Spherical Mirrors

Mirror type	Description	Nature
Concave mirror	Reflecting surface is curved inward	Converging mirror
Convex mirror	Reflecting surface is curved outward	Diverging mirror

Important Terms for Mirrors

Students should revise these mirror terms clearly because they are used in ray diagrams and formulas.

Term	Meaning
Pole	The center point of the reflecting surface
Principal axis	The straight line passing through the pole and center of curvature
Center of curvature	The center of the sphere of which the mirror is a part
Radius of curvature	The distance between the pole and the center of curvature
Principal focus	The point where parallel rays meet or appear to meet after reflection
Focal length	Distance between pole and principal focus

Relation Between Focal Length and Radius of Curvature

This is one of the most important formulas for mirrors.

Formula

f = R/2

Ray-Diagram Rules for Mirrors

These rules are used to draw all mirror image-formation diagrams.

Rule number	Main idea
Rule 1	A ray parallel to the principal axis passes through the focus after reflection in a concave mirror and appears to come from the focus in a convex mirror
Rule 2	A ray passing through the focus in a concave mirror becomes parallel to the principal axis after reflection; in a convex mirror, a ray directed towards the focus reflects parallel to the principal axis
Rule 3	A ray passing through the center of curvature retraces its path after reflection
Rule 4	A ray striking the pole reflects with equal angles on both sides of the principal axis

Image Formation by Concave Mirror

Students must revise all six standard cases.

Object position	Image position	Nature	Size
At infinity	At focus	Real, inverted	Highly diminished or point-sized
Beyond C	Between C and F	Real, inverted	Diminished
At C	At C	Real, inverted	Same size
Between C and F	Beyond C	Real, inverted	Enlarged
At F	At infinity	Real, inverted	Highly enlarged
Between F and P	Behind the mirror	Virtual, erect	Enlarged

Image Formation by Convex Mirror

A convex mirror has only two standard image cases and always forms a virtual, erect, and diminished image.

Object position	Image position	Nature	Size
At infinity	At focus behind the mirror	Virtual, erect	Highly diminished
At any finite distance	Between P and F behind the mirror	Virtual, erect	Diminished

Quick Summary of Mirror Images

Mirror type	Main image pattern
Concave mirror	Can form real and inverted images, and in one special case a virtual and erect image
Convex mirror	Always forms a virtual, erect, and diminished image

Sign Convention for Mirrors

This is extremely important for numericals.

Quantity or direction	Sign rule
Distances measured in the direction of incident light	Positive
Distances measured opposite to the direction of incident light	Negative
Heights above the principal axis	Positive
Heights below the principal axis	Negative
Object distance u	Always negative
Focal length of concave mirror	Negative
Focal length of convex mirror	Positive
Real image distance v	Negative
Virtual image distance v	Positive

Mirror Formula and Magnification

Concept	Formula
Mirror formula	1/f = 1/v + 1/u
Magnification for mirrors	m = -v/u = hᵢ/hₒ

Where:

m = magnification
hᵢ = height of image
hₒ = height of object

Refraction of Light and Refractive Index

Refraction is the bending of light when it passes from one medium to another. Refraction happens because the speed of light changes from one medium to another.

Refraction Rules at a Glance

Transition	Behaviour of light
Rarer to denser medium	Light bends towards the normal
Denser to rarer medium	Light bends away from the normal

Laws of Refraction

These are also called Snell’s laws.

Law	Statement
First law	The incident ray, the refracted ray, and the normal at the point of incidence all lie in the same plane
Second law	For a given pair of media, sin i / sin r = constant

Refractive Index

Refractive index measures how much light bends or how much its speed changes in a medium.

Formula for Refractive Index

If light goes from medium 1 to medium 2, then:

n₂₁ = v₁/v₂

Where:

n₂₁ = refractive index of medium 2 with respect to medium 1
v₁ = speed of light in medium 1
v₂ = speed of light in medium 2

Refraction Through a Glass Slab

When light enters a rectangular glass slab, it follows a standard pattern.

Observation	Result
On entering the slab	Light bends towards the normal
On leaving the slab	Light bends away from the normal
Emergent ray	Becomes parallel to the incident ray
Overall effect	A sideways shift is produced

Lateral Displacement

The sideways shift between the original path and the emergent path is called lateral displacement.

Lenses

The chapter studies two types of lenses: convex lens and concave lens.

Types of Lenses

Lens type	Description	Nature
Convex lens	Thicker at the center and thinner at the edges	Converging lens
Concave lens	Thinner at the center and thicker at the edges	Diverging lens

Important Terms for Lenses

Term	Meaning
Optical center	The center point of a lens through which a ray passes without deviation
Principal focus	The point where rays converge or appear to diverge from after refraction
F₁ and F₂	A lens has two principal foci, one on each side
Focal length	Distance between optical center and focus

Ray-Diagram Rules for Lenses

Rule number	Main idea
Rule 1	A ray parallel to the principal axis passes through the focus after refraction in a convex lens and appears to come from the focus in a concave lens
Rule 2	A ray passing through the focus of a convex lens emerges parallel to the principal axis; in a concave lens, a ray directed towards the focus emerges parallel
Rule 3	A ray passing through the optical center goes straight without deviation

Image Formation by Convex Lens

Students must revise all six standard cases here as well.

Object position	Image position	Nature	Size
At infinity	At focus on the other side	Real, inverted	Highly diminished
Beyond 2F₁	Between F₂ and 2F₂	Real, inverted	Diminished
At 2F₁	At 2F₂	Real, inverted	Same size
Between F₁ and 2F₁	Beyond 2F₂	Real, inverted	Enlarged
At F₁	At infinity	Real, inverted	Highly enlarged
Between F₁ and O	On the same side of lens	Virtual, erect	Enlarged

Image Formation by Concave Lens

A concave lens has only two standard image cases and always forms a virtual, erect, and diminished image.

Object position	Image position	Nature	Size
At infinity	At focus on the same side	Virtual, erect	Highly diminished
At any finite distance	Between optical center and focus	Virtual, erect	Diminished

Quick Summary of Lens Images

Lens type	Main image pattern
Convex lens	Can form real and inverted images, and in one special case a virtual and erect image
Concave lens	Always forms a virtual, erect, and diminished image

Sign Convention for Lenses

This is different from mirror sign convention in image distance.

Quantity or direction	Sign rule
Distances measured in the direction of incident light	Positive
Distances measured opposite to the direction of incident light	Negative
Heights above the principal axis	Positive
Heights below the principal axis	Negative
Object distance u	Always negative
Focal length of convex lens	Positive
Focal length of concave lens	Negative
Real image distance v	Positive
Virtual image distance v	Negative

Lens Formula, Magnification, and Power

Concept	Formula
Lens formula	1/f = 1/v – 1/u
Magnification for lenses	m = v/u = hᵢ/hₒ
Power of a lens	P = 1/f

SI Unit and Sign of Power

The SI unit of power is dioptre.

Lens type	Sign of power
Convex lens	Positive
Concave lens	Negative

Most Important Last-Minute Revision Points

This section is useful for final board revision.

Quick Revision Table

Topic	What to remember
Reflection	Angle of incidence = angle of reflection; incident ray, reflected ray, and normal lie in the same plane
Mirrors	Concave mirror is converging, convex mirror is diverging, f = R/2, mirror formula: 1/f = 1/v + 1/u, magnification: m = -v/u
Refraction	Rarer to denser bends towards normal, denser to rarer bends away from normal, Snell’s law: sin i / sin r = constant
Lenses	Convex lens is converging, concave lens is diverging, lens formula: 1/f = 1/v – 1/u, magnification: m = v/u, power: P = 1/f

Common Mistakes Students Make in Light

Common Mistakes Table

Mistake	Why it causes problems
Mixing up mirror and lens formulas	Mirror formula has + 1/u, while lens formula has – 1/u
Forgetting sign conventions	This causes direct errors in numericals
Mixing up concave and convex cases	It changes image nature and diagram logic
Confusing real and virtual image signs	Mirror and lens image signs are not the same
Forgetting the nature of images	Students miss whether the image is real or virtual, erect or inverted, enlarged or diminished

Best Strategy to Revise Light Before Boards

A quick but structured revision works best for this chapter.

Step-by-Step Revision Plan

Step	What to do
Step 1	Revise all ray-diagram cases in one go
Step 2	Learn sign convention separately as an independent table
Step 3	Revise the four main formulas: mirror formula, lens formula, magnification formula, and power formula
Step 4	Solve a few numericals right after revision
Step 5	Revise key differences such as concave mirror vs convex mirror, convex lens vs concave lens, and reflection vs refraction

Quick Practice Questions

Important Practice Questions

What is light?
State the two laws of reflection.
What is the difference between concave mirror and convex mirror?
Write the mirror formula.
Write the lens formula.
What is refractive index?
State Snell’s law.
What is lateral displacement?
What kind of image is always formed by a convex mirror?
What kind of image is always formed by a concave lens?

FAQs

Q1. What is light in Class 10 Physics?

Light is a form of energy that enables us to see objects around us.

Q2. Why do we see objects?

We see objects because light gets reflected from them and enters our eyes.

Q3. What are the two laws of reflection?

The angle of incidence is equal to the angle of reflection, and the incident ray, reflected ray, and normal lie in the same plane.

Q4. What is the mirror formula?

The mirror formula is 1/f = 1/v + 1/u.

Q5. What is the lens formula?

The lens formula is 1/f = 1/v – 1/u.

Q6. What is magnification for mirrors?

Magnification for mirrors is m = -v/u.

Q7. What is magnification for lenses?

Magnification for lenses is m = v/u.

Q8. What is the formula for power of a lens?

The formula is P = 1/f.

Conclusion

Light is one of the most important chapters in Class 10 Physics because it combines reflection, refraction, mirrors, lenses, formulas, diagrams, and numericals in one complete chapter. Once the core ideas are revised in a compact way, the whole chapter becomes much easier to handle during board preparation.

The best way to revise this chapter before CBSE boards is to keep the formulas, ray-diagram cases, image summaries, and sign conventions together in one place. At Deeksha Vedantu, we always remind students that Light is a scoring chapter when revision is visual, structured, and repeated calmly.