Purchasing Advisor for Ball Lenses - RP Photonics

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To help you, we have already listed some aspects we recommend you consider when buying ball lenses. Of course, there may be other aspects that are relevant to your specific case.

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Ball lenses are essential optical components that enhance signal coupling between optical fibers, light emitters, and detectors. They are widely used in applications such as endoscopy, barcode scanning, sensor technology, and as pre-forms for aspheric lenses. These lenses are made from a single glass substrate and can either focus or collimate light, depending on the input source's characteristics. Additionally, half-ball lenses provide a compact alternative when space constraints limit the use of full ball lenses.

Essential Equations for Ball Lens Usage

To effectively use ball lenses, five critical parameters must be considered:

1. Diameter of the Input Source (d)

2. Diameter of the Ball Lens (D)

3. Effective Focal Length (EFL)

4. Back Focal Length (BFL)

5. Refractive Index (n)

Key Optical Parameters
The Effective Focal Length (EFL) of a ball lens is determined by the lens diameter and refractive index:

The Back Focal Length (BFL) is then calculated as:

For collimated light, the Numerical Aperture (NA) of a ball lens depends on its size, refractive index, and the input source diameter. Using the relation:

the NA can be expressed as:

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where the refractive index outside the ball lens (nm) is assumed to be 1. In cases where d/D is much smaller than 1, NA can be approximated as:

which simplifies to:

As d/D increases, the focused spot size at the back focal length also increases due to greater spherical aberration.

Application Examples

Example 1: Laser-to-Fiber Coupling

When coupling a laser beam into a fiber optic cable, selecting the right ball lens depends on the NA of the fiber and the laser beam's diameter. The NA of the ball lens must be equal to or lower than that of the fiber to ensure full light coupling. The lens should be positioned at a distance equal to its BFL from the fiber.

Initial Parameters:

• Input Laser Beam Diameter: 2 mm

• Refractive Index of Ball Lens: 1.

• Fiber Optic NA: 0.22

For an N-BK7 ball lens, an NA of approximately 0.22 corresponds to a d/D ratio of about 0.33. This means that a lens with a diameter greater than 6 mm is necessary for coupling a 2 mm laser beam into a 0.22 NA fiber optic. Adjusting the refractive index can help optimize the lens choice for better coupling efficiency.

Example 2: Fiber-to-Fiber Coupling

To transfer light between two fiber optics with similar NA, a pair of identical ball lenses can be used. Each lens should be positioned at a distance equal to its BFL from the fiber ends. If both fibers have the same NA, the same calculations from the laser-to-fiber coupling example apply.

Example 3: LED Collimation

Ball lenses are also useful for collimating light from LEDs, which typically produce highly divergent beams. A ball lens helps direct and shape the output light into a more parallel beam, making it valuable for applications like illumination systems, sensors, and optical communication.

Key Considerations:

• The LED source diameter affects collimation efficiency.

• The NA of the ball lens should match the desired output divergence.

• The lens should be positioned close to the LED emitting surface for optimal collimation.

Initial Parameters:

• LED Chip Size: 1 mm

• Ball Lens Diameter: 5 mm

• Refractive Index of Ball Lens: 1.8

By selecting the appropriate lens and placement, LED collimation can be optimized for applications such as structured light projection and optical sensing.

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