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Numerical Aperture (NA)

Numerical Aperture (NA) defines how much light an optical system can collect. This article explains the formula, examples, and its impact on resolution and optical performance.

Written By: author avatar Tumisang Bogwasi
author avatar Tumisang Bogwasi
Tumisang Bogwasi, Founder & CEO of Brimco. 2X Award-Winning Entrepreneur. It all started with a popsicle stand.
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What is Numerical Aperture (NA)?

Numerical Aperture (NA) is a fundamental optical parameter that measures the light‑gathering ability of an optical system, such as a microscope objective or fiber optic cable. It determines how much light can enter the system and how well it can resolve fine details. Higher NA values correspond to greater light collection and improved image resolution.

Definition

Numerical Aperture (NA) is a dimensionless number that defines the range of angles over which an optical system can accept or emit light, representing its light‑gathering and resolution capability.

Table of Contents

Key takeaways

  • Higher NA = better resolution: More light enters the system, improving image sharpness.
  • Critical in microscopy and fiber optics: Determines imaging quality and transmission efficiency.
  • Dependent on refractive index: NA increases in media with higher refractive indices.
  • Defines acceptance angle: Determines how widely the system can capture light rays.
  • Affects depth of field: Higher NA reduces depth of field in microscopy.

The formula for Numerical Aperture

Optical systems:

NA = n × sin(θ)

Where:

  • n = refractive index of the medium (e.g., air, oil, glass)
  • θ = half-angle of the maximum cone of light entering the system

Fiber optics:

NA = √(n₁² – n₂²)

Where:

  • n₁ = refractive index of the fiber core
  • n₂ = refractive index of the fiber cladding

Why NA matters

In microscopy:

  • Determines resolving power
  • Influences depth of field
  • Affects brightness and image clarity

In fiber optics:

  • Defines coupling efficiency
  • Impacts data transmission performance
  • Determines bending tolerance

Examples

Microscopy

  • Low‑power lens: NA ≈ 0.10–0.25
  • High‑power dry lens: NA ≈ 0.65–0.95
  • Oil immersion objective: NA ≈ 1.2–1.4

Fiber optics

  • Step‑index fiber: NA typically 0.20–0.30
  • Graded‑index fiber: slightly lower NA for reduced dispersion

Limitations of NA

  • High NA objectives require short working distances.
  • Oil or water immersion may be needed for NA > 1.0.
  • Larger NA reduces depth of focus.

NA and resolution

Resolution (d) is inversely related to NA:
d ≈ λ / (2 × NA)

Where λ is wavelength.
Higher NA → smaller d → finer detail.

  • Refractive index
  • Diffraction limit
  • Optical resolution
  • Fiber optic coupling
  • Abbe’s diffraction theory

Sources

Frequently Asked Questions (FAQ)

1. Can NA be greater than 1?

Yes, when using immersion media with refractive index greater than 1 (e.g., oil).

2. Does a higher NA always mean better images?

Generally yes, but it reduces depth of field and working distance.

3. Why is NA important in fiber optics?

It determines the acceptance angle and affects coupling efficiency and transmission.

4. What limits the maximum NA?

Refractive index of the medium and lens design.

5. Is NA the same as magnification?

No. NA affects resolution, while magnification enlarges the image.

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Tumisang Bogwasi
Tumisang Bogwasi

Tumisang Bogwasi, Founder & CEO of Brimco. 2X Award-Winning Entrepreneur. It all started with a popsicle stand.

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