PhysicsOpticsMedium

Focal Length

Also known as:effective focal lengthEFL

Focal length (f) is the distance from the optical centre of a lens or curved mirror to its principal focus — the point where parallel rays of light converge (converging lens/mirror) or appear to diverge from (diverging lens/mirror) after passing through or reflecting off the optical element. A shorter focal length means stronger light-bending power, quantified as optical power P = 1/f in dioptres. Focal length governs image magnification, field of view, and is central to the design of cameras, telescopes, and corrective eyewear.

Key Formula

P = 1/f

LaTeX: P = \frac{1}{f}

SymbolMeaningUnit
POptical power of the lensDioptre (D = m⁻¹)
fFocal lengthmetres (m)

Worked Example

Problem

A converging lens has a focal length of 25 cm. What is its optical power in dioptres?

Solution

Step 1: Convert focal length to metres: f = 25 cm = 0.25 m Step 2: Apply power formula: P = 1/f = 1/0.25 Step 3: P = 4.0 D

Answer

Optical power = +4.0 dioptres (positive sign indicates a converging lens)

Focal Length vs. Optical Power and Common Optical Uses

Focal Length (cm)Power (D)Lens TypeTypical Application
5+20Strong convergingMicroscope objective
25+4Moderate convergingReading glasses
50+2Weak convergingPortrait camera lens
−50−2Weak divergingMyopia correction −2D
−25−4Moderate divergingMyopia correction −4D

Interactive Tools

PhET Geometric Optics

Adjust focal length dynamically and observe changes in image position and size.

Open Tool

WolframAlpha – Lens Focal Length

Solve lens equation numerically for any object/image distance and focal length.

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Brilliant.org – Optics

Conceptual and quantitative treatment of focal length and lens power.

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Ray diagram showing parallel light rays converging at the focal point of a convex lens

Wikimedia Commons, CC BY-SA

Related Terms

Physics

Lens (Optics)

In optics, a lens is a transmissive optical element, typically made of glass or transparent plastic, that refracts light to converge or diverge rays, thereby forming images. Lenses work by exploiting the refraction of light at curved surfaces, and their shape (convex or concave) determines whether rays are brought together (converging) or spread apart (diverging). Lenses are fundamental components of eyeglasses, cameras, microscopes, telescopes, and the human eye itself.

Physics

Convex Lens

A convex lens (also called a converging lens) is an optical element that is thicker at its centre than at its edges, causing parallel rays of light passing through it to converge toward a single real focal point on the far side. The converging power arises from refraction at both curved surfaces, and the focal length is positive. Convex lenses are used in magnifying glasses, cameras, projectors, the human eye's cornea and crystalline lens, and corrective spectacles for hyperopia (long-sightedness).

Physics

Concave Lens

A concave lens (also called a diverging lens) is an optical element that is thinner at its centre than at its edges, causing parallel rays of light passing through it to spread apart as if they originated from a virtual focal point on the same side as the incoming light. The focal length is negative, and the lens always produces a virtual, upright, and diminished image regardless of object position. Concave lenses are used to correct myopia (short-sightedness), in Galilean telescopes, and in laser beam expanders.

From Latin "focus" meaning "hearth" or "fireplace" — the burning point of a magnifying glass heated by converging the sun's rays. Johannes Kepler introduced the term "focus" in optics in his 1604 work "Ad Vitellionem Paralipomena". The combined term "focal length" emerged in 18th-century English optical literature.

opticsfocal lengthlenspowerdioptresimage formation