Code | Material | AR Coating | D-mm | EFL-mm | Tc-mm | Te-mm | R-mm | BFL-mm |
---|---|---|---|---|---|---|---|---|
DCX116-01 | UV Fused Silica(Quartz) | Uncoated | Ф12.7 | f12.7 | 6.26 | 2.0 | 10.54 | 10.31 |
DCX116-02 | UV Fused Silica(Quartz) | Uncoated | Ф12.7 | f15.0 | 5.36 | 2.0 | 12.86 | 13.039 |
DCX116-03 | UV Fused Silica(Quartz) | Uncoated | Ф12.7 | f20.0 | 4.2 | 1.8 | 17.7 | 18.5 |
DCX116-04 | UV Fused Silica(Quartz) | Uncoated | Ф12.7 | f30.0 | 3.3 | 1.8 | 27.1 | 28.8 |
DCX116-05 | UV Fused Silica(Quartz) | Uncoated | Ф12.7 | f40.0 | 2.9 | 1.8 | 36.3 | 39.9 |
DCX116-06 | UV Fused Silica(Quartz) | Uncoated | Ф12.7 | f50.0 | 2.7 | 1.8 | 45.6 | 49.1 |
Uncoated Quartz Double-Convex Lenses
These Uncoated UV Fused Silica Double-Convex (DCX) Lenses are characterized by a positive focal length and consists of two convex surfaces of equal radius, and made from UV Fused Silica(Quartz).
UV Quartz has a wider spectral range than K9 optical glass (185nm-2100nm), has excellent transmittance in the ultraviolet band, has a lower refractive index, better uniformity, smaller thermal expansion coefficient, and has higher chemical resistance and very low fluorescence, can be used to make a variety of optical components.
They are often used in image ultimate systems and finite conjugate imaging systems. The greater the conjugation ratio is, the greater the aberration appears.
Tc----- Center Thickness
Te----- Edge Thickness
R1----- Radius
Dia---- Diameter
H'------ Principal Point
BFL ---------- Back Focal Length
EFL ---------- Effective Focal Length
f'--------------- Focus
The Focal Length of each lens can be calculated using the simplified thick lens formula:
f=(R1×R2)/(n-1)×(R2-R1)
Where n is the refractive index and R is the radius of curvature of the lens surface.
1 | 2 |
---|---|
Center Thickness Tolerance | ±0.2mm |
Surface Irregular Accuracy | λ/4 @632.8nm |
Centering Tolerance | <3 arcmin |
Bevelling | <0.2×45° |
1 | 2 |
---|---|
Design Wavelength | 587.6nm |
Focal Length Tolerance | ±2% |
Diameter Tolerance | +0.0/-0.1mm |
Surface Quality | 40/20-60/40 |
Double-Convex Lenses are commonly used in many finite imaging applications. This type of lens is best used when the object and image are on either side of the lens and the ratio of the distance to the object (conjugate ratio) is between 0.2 and 5.
Double-Convex Lenses can also be double coated with AR Coating
- -A: AR@250-450nm,
- -B: AR@350-700nm,
- -C: AR@650-1100nm,
- -D: AR@1000-1650nm,
anti-reflection coating can reduce the reflectivity of each surface of the lens.
Reviews
There are no reviews yet.