Lenses are integral to optics, shaping how we perceive and engage with the world. Achromatic lenses, a longstanding fixture in optical technology, address chromatic aberration, a common optical flaw causing color fringing. Among these, color-corrected achromatic lenses specialize in enhancing this correction. This article delves into the advantages and drawbacks of employing color-corrected achromatic lenses.
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Achromatic lenses, crucial for color correction, are crafted by combining concave and convex lens elements of different dispersions. This results in an achromatic doublet, the most common type, although triplet lenses are also used. Leading manufacturers like Shanghai Optics follow a methodical process:
Different optical glasses are melted, stirred, and poured into molds to form lenses based on the desired correction.
Individual lenses are aligned and cemented to create an achromat capable of effectively correcting chromatic aberration.
The achromat is incorporated into lens assemblies for various applications, such as microscope objectives and telescopes.
Manufacturers may tailor the lens design, sometimes adding aspheric properties to address spherical aberration along with chromatic aberration. Shanghai Optics, adhering to ISO 9001 standards, utilizes advanced metrology equipment to ensure precise achromatic lens performance, meeting clients’ specifications reliably.
Specifications Factory Standards Manufacturing LimitDimension Tolerance
+/-0.03mm
+/-0.01mm
Center Thickness Tolerance
+/-0.03 mm
+/-0.02mm
Radius Tolerance
+/-0.3%
+/-0.2%
Surface Quality(S/D)
20-10
10-5
Irregularity
1/5Lambda
< 1/10 Lambda
Centration(arc min)
3′
1′
Ideal for portable devices, these lenses are more compact and lighter than comparable designs, meeting size and weight constraints.
Applicable in various optical systems, including cameras, microscopes, telescopes, and eyeglasses, these lenses are valuable across photography, astronomy, and microscopy.
Meticulously combining different lens elements, these lenses significantly improve image quality by eliminating distracting color fringing associated with chromatic aberration.
While not eliminating chromatic aberration entirely, these lenses are often more cost-effective than specialized designs like apochromatic lenses, making them accessible to a broader user base.
Beneficial in low-light conditions or for achieving a shallow depth of field, color-corrected achromatic lenses often allow wider apertures. The absence of chromatic aberration ensures sharp, distortion-free images at these wider apertures.
Despite being more compact and lighter than some lenses, color-corrected achromatic lenses may still be bulkier and heavier than basic single-element lenses, posing challenges in situations prioritizing minimized equipment size and weight.
Despite their proficiency in reducing chromatic aberration, color-corrected achromatic lenses may exhibit residual aberration, particularly at the image field edges.
While offering wider apertures, these lenses may lack the same aperture control as specialized lenses, impacting creative options for photographers and cinematographers.
Achromatic lenses, including color-corrected versions, may slightly diminish light transmission compared to simpler designs, a consideration in applications where maximizing light throughput is crucial.
Achieving effective color correction demands intricate and precise optical designs, leading to more challenging and expensive manufacturing and maintenance processes.
Color-corrected achromatic lenses significantly advance optics by effectively combating chromatic aberration. Their advantages, including improved image quality, wider apertures, versatility, and cost-effectiveness, make them popular in various optical systems. However, it’s vital to consider their limitations—limited correction, complex design, reduced light transmission, aperture control, and weight/size trade-offs—when selecting lenses for specific applications. Ultimately, lens choice depends on the optical system’s needs and acceptable trade-offs in cost, size, and performance. While color-corrected achromatic lenses are valuable, careful consideration of their pros and cons is essential for informed decisions and desired optical outcomes.
Achromatic cylindrical lenses are ideal for eliminating spherical and chromatic aberration at the image plane, for example using monochromatic light source, achromatic cylindrical lenses can form a 50-90% smaller spot compared to singlet.
For most severe laser or imaging applications which involve cylindrical components, such as anamorphic projection, anamorphic photography, and achromatic cylindrical lenses are introduced. Hyperion Optics can manufacture based on custom design doublet or triplet achromatic cylindrical cemented lenses by using centering alignment device with UV curing unit to process precision bonding and testing at the same time. Every singlet is fully inspected before bonding.
We are capable of producing up to 150mm in diameter with reliable anti-reflective coatings, centering strictly controlled on optical edging device, and surface accuracy is defined on Zygo. Further, we also help customer to adopt Chinese CDGM or NHG equivalents in achromatic cylindrical design, this is particularly flexible solution in LRIP cases.
If you are looking for more details, kindly visit optec.
Please check out our anamorphic lenses for more information. If you are in the stage of developing your own anamorphic lenses, don’t hesitate contacting one of our optical engineers for free consultation to receive assistant from manufacturing perspective. Talk to one of our skilled technicians for more details.
AchromaticCylindrical Lenses
COMMERCIAL GRADE
FACTORY STANDARD
PRECISION GRADE
Size Tolerance Length/Width(mm)
+0/-0.30
+0/-0.25
+0/-0.25
Diameter (mm)
+0/-0.15
+0/-0.10
±0.025
Wedge (along axis)
5 mrad
3 mrad
1 mrad
Focal Length Tolerance (%)
±2%
±2%
±1%
Cosmetic(MIL-C-13830A)
80-50
60-40
10-5
Irregularity (Lambda @ 632.8nm)
1 L
1/2 L
1/10 L
Centration (Arc min)
<5'
<3'
<1'
Coating (T% avg)
99%
99.5%
99.5%
Materials
Optical Glasses Depends On Design
Lenses are integral to optics, shaping how we perceive and engage with the world. Achromatic lenses, a longstanding fixture in optical technology, address chromatic aberration, a common optical flaw causing color fringing. Among these, color-corrected achromatic lenses specialize in enhancing this correction. This article delves into the advantages and drawbacks of employing color-corrected achromatic lenses.
Achromatic lenses, crucial for color correction, are crafted by combining concave and convex lens elements of different dispersions. This results in an achromatic doublet, the most common type, although triplet lenses are also used. Leading manufacturers like Shanghai Optics follow a methodical process:
Different optical glasses are melted, stirred, and poured into molds to form lenses based on the desired correction.
Individual lenses are aligned and cemented to create an achromat capable of effectively correcting chromatic aberration.
The achromat is incorporated into lens assemblies for various applications, such as microscope objectives and telescopes.
Manufacturers may tailor the lens design, sometimes adding aspheric properties to address spherical aberration along with chromatic aberration. Shanghai Optics, adhering to ISO 9001 standards, utilizes advanced metrology equipment to ensure precise achromatic lens performance, meeting clients’ specifications reliably.
Specifications Factory Standards Manufacturing LimitDimension Tolerance
+/-0.03mm
+/-0.01mm
Center Thickness Tolerance
+/-0.03 mm
+/-0.02mm
Radius Tolerance
+/-0.3%
+/-0.2%
Surface Quality(S/D)
20-10
10-5
Irregularity
1/5Lambda
< 1/10 Lambda
Centration(arc min)
3′
1′
Ideal for portable devices, these lenses are more compact and lighter than comparable designs, meeting size and weight constraints.
Applicable in various optical systems, including cameras, microscopes, telescopes, and eyeglasses, these lenses are valuable across photography, astronomy, and microscopy.
Meticulously combining different lens elements, these lenses significantly improve image quality by eliminating distracting color fringing associated with chromatic aberration.
While not eliminating chromatic aberration entirely, these lenses are often more cost-effective than specialized designs like apochromatic lenses, making them accessible to a broader user base.
Beneficial in low-light conditions or for achieving a shallow depth of field, color-corrected achromatic lenses often allow wider apertures. The absence of chromatic aberration ensures sharp, distortion-free images at these wider apertures.
Despite being more compact and lighter than some lenses, color-corrected achromatic lenses may still be bulkier and heavier than basic single-element lenses, posing challenges in situations prioritizing minimized equipment size and weight.
Despite their proficiency in reducing chromatic aberration, color-corrected achromatic lenses may exhibit residual aberration, particularly at the image field edges.
While offering wider apertures, these lenses may lack the same aperture control as specialized lenses, impacting creative options for photographers and cinematographers.
Achromatic lenses, including color-corrected versions, may slightly diminish light transmission compared to simpler designs, a consideration in applications where maximizing light throughput is crucial.
Achieving effective color correction demands intricate and precise optical designs, leading to more challenging and expensive manufacturing and maintenance processes.
Color-corrected achromatic lenses significantly advance optics by effectively combating chromatic aberration. Their advantages, including improved image quality, wider apertures, versatility, and cost-effectiveness, make them popular in various optical systems. However, it’s vital to consider their limitations—limited correction, complex design, reduced light transmission, aperture control, and weight/size trade-offs—when selecting lenses for specific applications. Ultimately, lens choice depends on the optical system’s needs and acceptable trade-offs in cost, size, and performance. While color-corrected achromatic lenses are valuable, careful consideration of their pros and cons is essential for informed decisions and desired optical outcomes.
Achromatic cylindrical lenses are ideal for eliminating spherical and chromatic aberration at the image plane, for example using monochromatic light source, achromatic cylindrical lensachromatic cylindrical lenses can form a 50-90% smaller spot compared to singlet.
For most severe laser or imaging applications which involve cylindrical components, such as anamorphic projection, anamorphic photography, and achromatic cylindrical lenses are introduced. Hyperion Optics can manufacture based on custom design doublet or triplet achromatic cylindrical cemented lenses by using centering alignment device with UV curing unit to process precision bonding and testing at the same time. Every singlet is fully inspected before bonding.
We are capable of producing up to 150mm in diameter with reliable anti-reflective coatings, centering strictly controlled on optical edging device, and surface accuracy is defined on Zygo. Further, we also help customer to adopt Chinese CDGM or NHG equivalents in achromatic cylindrical design, this is particularly flexible solution in LRIP cases.
Please check out our anamorphic lenses for more information. If you are in the stage of developing your own anamorphic lenses, don’t hesitate contacting one of our optical engineers for free consultation to receive assistant from manufacturing perspective. Talk to one of our skilled technicians for more details.
AchromaticCylindrical Lenses
COMMERCIAL GRADE
FACTORY STANDARD
PRECISION GRADE
Size Tolerance Length/Width(mm)
+0/-0.30
+0/-0.25
+0/-0.25
Diameter (mm)
+0/-0.15
+0/-0.10
±0.025
Wedge (along axis)
5 mrad
3 mrad
1 mrad
Focal Length Tolerance (%)
±2%
±2%
±1%
Cosmetic(MIL-C-13830A)
80-50
60-40
10-5
Irregularity (Lambda @ 632.8nm)
1 L
1/2 L
1/10 L
Centration (Arc min)
<5'
<3'
<1'
Coating (T% avg)
99%
99.5%
99.5%
Materials
Optical Glasses Depends On Design