- ZOOM LENSES 1:6.5 Zoom Ratio Continuous Industrial Zoom Lens
FALenses Technology will be your best partner
Product Description:
Industrial lenses are very important imaging components in machine vision systems. If the system wants to fully exert its functions, the industrial lenses must be able to meet the requirements. The continuous zoom lens adopts the world's mainstream optical system and building block mechanical mechanism, and the zoom process is coaxial and confocal throughout. It is specially designed by our company for digital imaging observation, detection and measurement in electronic equipment, semiconductors, LCD, LED and other fields. Various LED lighting can be used to meet the needs of observing different objects.
Features:
◆The entire zoom process is coaxial and confocal
◆Continuous magnification optional for long working object distance
◆Continuous zoom of objective lens from 0.7X to 4.5X
◆The matching size of the host machine is Φ40mm, and a socket of Φ45mm or Φ50mm can be added.
◆Optional objective lens fine-tuning functionality and positioning models
◆The standard C interface (the distance from the supporting surface to the CCD target surface is 17.53mm) can also be added with a CS interface.
◆CCD thread interface is 1 inch 32 threads
◆Can be connected to standard thread infinity metallographic lens
◆Can be connected to LED dimmable ring light source or LED coaxial lighting, etc.
◆Can be equipped with coaxial optical metallographic band laser
Concepts of Lens Parameters
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Resolution (LP/MM) Refers to the number of distinguishable black and white stripes within a 1mm range on the image side. Resolution is expressed in line pairs per millimeter (lp/mm). For example, 100lp/mm means that the distinguishable spacing between black and white stripes is 1/100mm (10um). The width of each black and white stripe is 1/200mm (5um). |
Focal Length f(mm), Back Focal Length/Front Focal Length The focal length refers to the distance between the optical system's center and its focus point. The back focal length is the distance from the vertex of the last lens element to the back focal point, while the front focal length is the distance from the vertex of the first lens element to the front focal point. |
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Chromatic Aberration: In optical lenses, the magnification of the image can vary based on the wavelength of light, leading to differences in where the image is formed. This variation is called chromatic aberration. Chromatic aberration along the optical axis is referred to as axial chromatic aberration, while chromatic aberration occurring off-axis is called lateral chromatic aberration or magnification chromatic aberration. |
Effective F# This value represents the effective brightness of a lens at a given finite distance, indicating the brightness during actual operation. As the optical magnification (β) increases, the lens becomes darker. The effective F-number (Effective F#) is calculated as V(2×NA) = 1/(2×NA), and Effective F# = (1+β) × Standard F#. |
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Floating Mechanism: This system is designed to compensate for image aberrations that occur during close-up photography. When a lens is moved (extended) for close-up shots or to adjust object distance, aberrations can vary depending on magnification or shooting distance, sometimes leading to a drop in sharpness. A floating mechanism minimizes the aberrations caused by moving the lens in varying shooting conditions, thereby correcting these aberrations. |
Depth of Focus(DOF) Depth of focus is the distance between the nearest and farthest points where the image remains acceptably sharp as the sensor moves back and forth from the optimal focus point. Unlike depth of field, which is a parameter on the object side, depth of focus is a parameter on the image side of the optical system. |
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Distortion (%): Distortion is the phenomenon where straight lines appear bent when imaging off-axis points. When straight lines bend inward toward the center, it's known as pincushion distortion. When they bend outward, it's called barrel distortion. |
Telecentric Optical System A telecentric optical system is one where the chief rays are parallel to the optical axis. If the light from the object traveling toward the lens remains parallel to the optical axis, even off-axis, it's called an object-side telecentric system. If the light traveling from the lens toward the image remains parallel to the optical axis, even off-axis, it's known as an image-side telecentric system. |
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Depth of Field (DoF) Depth of Field is the distance between the nearest and farthest points where the image remains acceptably sharp as the object moves toward or away from the optimal imaging distance. Depth of Field is influenced by factors like the lens's effective F-number, the circle of confusion diameter, and the optical magnification (β). The circle of confusion is the diameter of a blur circle that represents an acceptable level of sharpness. A common standard for an acceptable circle of confusion diameter is 0.04mm. |
Resolution (μm) Resolution is a measurement of the minimum distance between two points before they are no longer distinguishable. For example, a resolution of 1 μm means that two points separated by 1 μm can be resolved. The resolution values in this context refer to the theoretical resolution of a lens. Below is the formula used to calculate the theoretical resolution based on the diffraction limit for an aberration-free lens.
where λ is the design wavelength, typically 550 nm, and NA is the numerical aperture of the lens. |
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Field of View (mm) Field of view refers to the size of the object that can be captured when the lens is mounted on a camera. The field of view is determined by the sensor size divided by the optical magnification (β). (Example Calculation) If the optical magnification is 0.2x and the camera sensor size is 1/2" (4.8mm length, 6.4mm width): Field of view length = 4.8 / 0.2 = 24 (mm) Field of view width = 6.4 / 0.2 = 32 (mm) |
Working Distance (WD) (mm) Working distance is the distance from the bottom surface of the lens to the object being inspected. |
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Back Focal Distance (mm) Back focal distance is the distance from the front edge of the lens mount flange to the image plane. |
Numerical apertureNA/NA'
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C-Mount Specifications · Name: C-Mount · Standard Outer Diameter: 25.400 mm · Thread Pitch: 32 threads per 25.4 mm · Back Focal Distance: 17.526 mm C-Mount is a standard specification for lens mounts used in cameras and other optical systems. It is characterized by a specific outer diameter, thread pitch, and back focal distance, facilitating compatibility among various lenses and cameras designed with this specification. |
F.NO (F-Number) This parameter represents the light-gathering capability of a lens. It is calculated by dividing the focal length of the lens by the diameter of the entrance pupil D. It can also be derived through the optical magnification from the lens's numerical aperture (NA). A smaller F-number indicates a brighter image. The formula to calculate F-number is: F# = \frac{{f}}{{D}} Where f is the focal length, and D is the diameter of the entrance pupil. |
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TV Distortion (%) TV distortion refers to the distortion in the vertical direction of a TV screen (chip). A lower value indicates better performance, ideally approaching zero. TV distortion (%) is calculated as: \text{TV distortion (%) = (Distortion Depth/Screen Height) × 100} Where "Distortion Depth" refers to the curvature deviation along the longer edge, and "Screen Height" is the perpendicular measurement of the display.
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Optical magnification (β)
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