Molded Glass Aspheric Lenses: 600 - 1050 or 650 - 1050 nm AR Coating
- High NA (0.15 to 0.7)
- Diffraction-Limited Design
- Broadband AR-Coated Optics in Stock
- Collimate or Focus Light with a Single Element
A375TM-B
A375-B
C140TMD-B
354140-B
C710TMD-B
354710-B
Application Idea
Aspheric Lens in a Fiber Launch Application
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Aspheric Lens Selection Guide |
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Uncoated |
350 - 700 nm (-A Coating) |
600 - 1050 nm (-B Coating) |
1050 - 1700 nm (-C Coating) |
1.8 - 3 µm (-D Coating) |
3 - 5 µm (-E Coating) |
8 - 12 µm (-F Coating) |
405 nm V-Coating |
1064 nm V-Coating |
Webpage Features | |
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Click for complete specifications. | |
Performance Hyperlink | Click to view item-specific focal length shift data and spot diagrams at various wavelengths. |
Zemax Files |
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Click on the red Document icon next to the item numbers below to access the Zemax file download. Our entire Zemax Catalog is also available. |
Features
- Molded Glass Aspheric Lenses Designed for Infinite Magnification
- Focus or Collimate Light Without Introducing Spherical Aberration
- Available Unmounted or Pre-Mounted in Non-Magnetic 303 Stainless Steel Lens Cells Engraved with the Item #
- Broadband AR Coating for Either 600 - 1050 nm or 650 - 1050 nm
Aspheric lenses focus or collimate light without introducing spherical aberration into the transmitted wavefront. For monochromatic sources, spherical aberration often prevents a single spherical lens from achieving diffraction-limited performance when focusing or collimating light. Aspheric lenses are designed to mitigate the impacts of spherical aberration and are often the best single element solution for many applications including collimating the output of a fiber or laser diode, coupling light into a fiber, spatial filtering, or imaging light onto a detector.
All of the molded glass lenses featured on this page are available with an antireflection coating for either the 600 - 1050 nm or 650 - 1050 nm range deposited on both sides. Other AR coating options are listed in the Aspheric Lens Selection Guide table at right.
These lenses can be purchased unmounted or premounted in non-magnetic 303 stainless steel lens cells that are engraved with the Item # for easy identification. All mounted aspheres have a metric thread that make them easy to integrate into an optical setup or OEM application; they can also be readily used with our SM1-threaded (1.035"-40) lens tubes by using our aspheric lens adapters. When combined with our microscope objective adapter extension tube, mounted aspheres can be used as a drop-in replacement for multi-element microscope objectives.
A selection of the lenses sold on this page are designed for collimating laser diodes. As seen in the tables below, a compatible laser window thickness is listed for these lenses. In these instances, the numerical aperture (NA), working distance (WD), and wavefront error of these lenses are defined based on the presence of a laser window of the indicated thickness (not included).
If an unmounted aspheric lens is being used to collimate the light from a point source or laser diode, the side with the greater radius of curvature (i.e., the flatter surface) should face the point source or laser diode. To collimate light using one of our mounted aspheric lenses, orient the housing so that the externally threaded end of the mount faces the source.
Molded glass aspheres are manufactured from a variety of optical glasses to yield the indicated performance. The molding process will cause the properties of the glass (e.g., Abbe number) to deviate slightly from those given by glass manufacturers. Specific material properties for each lens can be found by clicking on the Info Icon in the tables below and selecting the Glass tab.
Choosing a Lens
Aspheric lenses are commonly chosen to couple incident light with a diameter of 1 - 5 mm into a single mode fiber. A simple example will illustrate the key specifications to consider when trying to choose the correct lens.
Example:
Fiber: P1-630A-FC-2
Collimated Beam Diameter Prior to Lens: Ø3 mm
The specifications for the P1-630A-FC-2, 630 nm, FC/PC single mode patch cable indicate that the mode field diameter (MFD) is 4.3 μm. This specification should be matched to the diffraction-limited spot size given by the following equation:
Here, f is the focal length of the lens, λ is the wavelength of the input light, and D is the diameter of collimated beam incident on the lens. Solving for the desired focal length of the collimating lens yields
Thorlabs offers a large selection of mounted and unmounted aspheric lenses to choose from. The aspheric lens with a focal length that is closest to 16 mm has a focal length of 15.29 mm (Item # 354260-B or A260-B). This lens also has a clear aperture that is larger than the collimated beam diameter. Therefore, this option is the best choice given the initial parameters (i.e., a P1-630A-FC-2 single mode fiber and a collimated beam diameter of 3 mm). Remember, for optimal coupling, the spot size of the focused beam must be less than the MFD of the single mode fiber. As a result, if an aspheric lens is not available that provides an exact match, then choose one with a focal length that is shorter than the calculation above yields. Alternatively, if the clear aperture of the aspheric lens is large enough, the beam can be expanded before the aspheric lens, which has the result of reducing the spot size of the focus beam.
Click to Enlarge
Reference Drawing
Aspheric Lens Design Formula
Definitions of Variables | |
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z | Sag (Surface Profile) as a Function of Y |
Y | Radial Distance from Optical Axis |
R | Radius of Curvature |
k | Conic Constant |
An | nth Order Aspheric Coefficient |
The aspheric surfaces of these lenses may be described using a polynomial expansion in Y, the radial distance from the optical axis. The surface profile or sagitta (often abbreviated as sag) is denoted by z, and is given by the following expression:
where R is the radius of curvature, k is the conic constant, and the An are the nth order aspheric coefficients. The sign of R is determined by whether the center of curvature for the lens surface is located to the right or left of the lens' vertex; a positive R indicates that the center of curvature is located to the right of the vertex, while a negative R indicates that the center of curvature is located to the left of the vertex. For example, the radius of curvature for the left surface of a biconvex lens would be specified as positive, while the radius of curvature for its right surface would be specified as negative.
Aspheric Lens Coefficients
Due to the rotational symmetry of the lens surface, only even powers of Y are contained in the polynomial expansion above. The target values of the aspheric coefficients for each product can be found by clicking either on the blue Info Icons in the tables below () or on the red documents icon () next to each lens sold below.
Choosing a Collimation Lens for Your Laser Diode
Since the output of a laser diode is highly divergent, collimating optics are necessary. Aspheric lenses do not introduce spherical aberration and therefore are commonly chosen when the collimated laser beam is to be between one and five millimeters. A simple example will illustrate the key specifications to consider when choosing the correct lens for a given application. The second example below is an extension of the procedure, which will show how to circularize an elliptical beam.
Example 1: Collimating a Diverging Beam
- Laser Diode to be Used: L780P010
- Desired Collimated Beam Diameter: Ø3 mm (Major Axis)
When choosing a collimation lens, it is essential to know the divergence angle of the source being used and the desired output diameter. The specifications for the L780P010 laser diode indicate that the typical parallel and perpendicular FWHM beam divergences are 8° and 30°, respectively. Therefore, as the light diverges, an elliptical beam will result. To collect as much light as possible during the collimation process, consider the larger of these two divergence angles in any calculations (i.e., in this case, use 30°). If you wish to convert your elliptical beam into a round one, we suggest using an anamorphic prism pair, which magnifies one axis of your beam; for details, see Example 2 below.
Assuming that the thickness of the lens is small compared to the radius of curvature, the thin lens approximation can be used to determine the appropriate focal length for the asphere. Assuming a divergence angle of 30° (FWHM) and desired beam diameter of 3 mm:
Θ = Divergence Angle | Ø = Beam Diameter | f = Focal Length | r = Collimated Beam Radius = Ø/2 |
Note that the focal length is generally not equal to the needed distance between the light source and the lens.
With this information known, it is now time to choose the appropriate collimating lens. Thorlabs offers a large selection of aspheric lenses. For this application, the ideal lens is a molded glass aspheric lens with focal length near 5.6 mm and our -B antireflection coating, which covers 780 nm. The C171TMD-B (mounted) or 354171-B (unmounted) aspheric lenses have a focal length of 6.20 mm, which will result in a collimated beam diameter (major axis) of 3.3 mm. Next, check to see if the numerical aperture (NA) of the diode is smaller than the NA of the lens:
0.30 = NALens > NADiode ≈ sin(15°) = 0.26
Up to this point, we have been using the full-width at half maximum (FWHM) beam diameter to characterize the beam. However, a better practice is to use the 1/e2 beam diameter. For a Gaussian beam profile, the 1/e2 diameter is almost equal to 1.7X the FWHM diameter. The 1/e2 beam diameter therefore captures more of the laser diode's output light (for greater power delivery) and minimizes far-field diffraction (by clipping less of the incident light).
A good rule of thumb is to pick a lens with an NA twice that of the laser diode NA. For example, either the A390-B or the A390TM-B could be used as these lenses each have an NA of 0.53, which is more than twice the approximate NA of our laser diode (0.26). These lenses each have a focal length of 4.6 mm, resulting in an approximate major beam diameter of 2.5 mm. In general, using a collimating lens with a short focal length will result in a small collimated beam diameter and a large beam divergence, while a lens with a large focal length will result in a large collimated beam diameter and a small divergence.
Example 2: Circularizing an Elliptical Beam
Using the laser diode and aspheric lens chosen above, we can use an anamorphic prism pair to convert our collimated, elliptical beam into a circular beam.
Whereas earlier we considered only the larger divergence angle, we now look at the smaller beam divergence of 8°. From this, and using the effective focal length of the A390-B aspheric lens chosen in Example 1, we can determine the length of the semi-minor axis of the elliptical beam after collimation:
r' = f * tan(Θ'/2) = 4.6 mm * tan(4°) = 0.32 mm
The minor beam diameter is double the semi-minor axis, or 0.64 mm. In order to magnify the minor diameter to be equal to the major diameter of 2.5 mm, we will need an anamorphic prism pair that yields a magnification of 3.9. Thorlabs offers both mounted and unmounted prism pairs. Mounted prism pairs provide the benefit of a stable housing to preserve alignment, while unmounted prism pairs can be positioned at any angle to achieve the exact desired magnification.
The PS883-B mounted prism pair provides a magnification of 4.0 for a 950 nm wavelength beam. Because shorter wavelengths undergo greater magnification when passing through the prism pair, we can expect our 780 nm beam to be magnified by slightly more than 4.0X. Thus, the beam will still maintain a small degree of ellipticity.
Alternatively, we can use the PS871-B unmounted prism pair to achieve the precise magnification of the minor diameter necessary to produce a circular beam. Using the data available here, we see that the PS871-B achieves a magnification of 4.0 when the prisms are positioned at the following angles for a 670 nm wavelength beam:
α1: +34.608° | α2: -1.2455° |
Refer to the diagram to the right for α1 and α2 definitions. Our 780 nm laser will experience slightly less magnification than a 670 nm beam passing through the prisms at these angles. Some trial and error may be required to achieve the exact desired magnification. In general:
- To increase magnification, rotate the first prism clockwise (increasing α1) and rotate the second prism counterclockwise (decreasing α2).
- To reduce magnification, rotate the first prism counterclockwise (decreasing α1) and rotate the second prism clockwise (increasing α2).
Posted Comments: | |
Yuqing ZHAO
 (posted 2024-09-24 14:08:34.23) Hi,
I would like to buy a lens of 350280-B - f=18.40mm 0.15NA Unmounted Geltech Aspheric Lens, ARC: 600-1050 nm, but on your site I find it's obsolete. So do you have lens which are similar to this one?
Thank you and wait for your reponse.
Best wishes,
Yuqing Mikhail Grishin
 (posted 2024-07-30 09:53:11.217) Is it possible to use A240TM-B assembly in the following conditions:
Operation temperature range from +20 deg. C to +45 deg. C;
Storage temperature range from minus 20 deg. C to +80 deg C.
Humidity is low for all the cases.
Please advise.
Best Regards,
Mikhail cdolbashian
 (posted 2024-08-14 11:38:26.0) Thank you for reaching out to us with this inquiry. Based on the conditions you have described within our direct communication, it does not seem like the performance will be directly affected. That being said, we have not tested your exact operating conditions, and thus cannot make any guarantees for these elements to maintain a specific performance. Jose Mejia
 (posted 2024-05-07 14:35:54.33) We have a C220TMD-B and the lens deattached from the mount. How can we put it back together? Thanks in advance cdolbashian
 (posted 2024-05-10 04:14:59.0) Thank you for reaching out to us with this inquiry. I would recommend carefully cleaning away the old adhesive with some solvent, such as acetone, and then finding some optical adhesive, such as the products found here:
https://www.thorlabs.de/newgrouppage9.cfm?objectgroup_id=4973 user
 (posted 2023-03-13 16:51:51.1) The maximum power density that can be tolerated ksosnowski
 (posted 2023-03-17 04:01:09.0) Thanks for reaching out to Thorlabs. At the moment we have not tested these optics for pulsed or CW damage threshold limitations. I have reached out directly to discuss your application in more detail. Thomas Marty
 (posted 2022-06-01 16:23:16.21) Hello
I would appreciate a TO5 adapter to the package
LTN330-B-AutoCADPDF.pdf.
This would allow to use the lens adapter directly on the DFB Laserdiode.
Kind Regards
Thomas Marty cdolbashian
 (posted 2022-06-17 04:41:47.0) Thank you for the request Thomas! I have reached out to you directly to discuss this application. user
 (posted 2019-09-24 17:28:49.043) Are the mounted aspheric lenses vacuum compatible and work at 60K? YLohia
 (posted 2019-09-30 12:02:57.0) Hello, thank you for contacting Thorlabs. In general, these mounted aspheres are not designed for vacuum compatibility and cryogenic use. We typically use NOA68 epoxy to mount the lenses to their mounts, which is not a vacuum-rated epoxy. giorgos.georgiou
 (posted 2018-01-03 10:31:25.793) Can you provide the Zemax files for the 354430-B lens? tfrisch
 (posted 2018-01-03 02:32:49.0) Hello, thank you for contacting Thorlabs. I can work on getting the file for you, but until then, the aspheric coefficients are as follows. R=2.838589, K=-0.576643. The center thickness is 0.99mm. The diameter is 2.00mm. I will reach out to you directly as well. gerald.auboeck
 (posted 2016-03-16 14:40:55.23) Does the -B coating (600 - 1050 nm) stand a temperature of about 250 °C ?
If not, can you provide alternative AR coatings which stand this temperature? besembeson
 (posted 2016-03-16 10:21:54.0) Response from Bweh at Thorlabs USA: The typical operating temperatures should be under 200 deg C. We don't have any alternatives at this time for higher temperatures. r.a.mccracken
 (posted 2015-05-08 17:28:21.327) Hi! Is it possible to get the Sellmeier formula and coefficients for this lens?
Thanks! Richard jlow
 (posted 2015-05-13 10:47:48.0) Response from Jeremy at Thorlabs: The lens is made from ECO-550 glass. We can provide the refractive indices for the material at different wavelengths. I will contact you directly to provide this. user
 (posted 2014-07-05 04:47:52.283) A280-B Zemax file? myanakas
 (posted 2014-07-11 03:27:08.0) Response from Mike at Thorlabs: Based on this feedback, we are currently working to have Zemax files added to our website for all of our molded glass aspheres. In the meantime, since no contact information was provided, please contact techsupport@thorlabs.com for the A280-B Zemax file. mchen
 (posted 2013-06-07 11:27:41.273) Hi,
I want to mount an A230TM-B lens to 0.5" lens tube, but can not find an adapter. Can you please give a suggestion?
Thanks,
Mike jlow
 (posted 2013-06-07 12:23:00.0) Response from Jeremy at Thorlabs: The A230TM-B has M9x0.5 thread. The adapter to convert that to SM05 is the S05TM09, found at https://www.thorlabs.com/NewGroupPage9.cfm?ObjectGroup_ID=1749&pn=S05TM09. dgardner
 (posted 2012-10-01 15:34:00.0) A response from Dave at Thorlabs: Thank you for your feedback. The lenses sold on this page are coated for either 600 - 1050 nm or 650 - 1050 nm. We have updated the specs tables to include the correct AR coating range for each individual lens. user
 (posted 2012-10-01 15:40:57.0) Confusion! 600nm- or 650nm- starting wavelength of AR coating???? jlow
 (posted 2012-07-31 14:03:00.0) A response from Jeremy at Thorlabs: Thank you for your feedback. The reason the M12 threading is used is because of the size of the unmounted lens, which is about 9.94mm in diameter. With regard to adapters, we only have adapters to SM1 or RMS threading. The reason we do not have an M12 adapter for SM05 is because the wall of the adapter would then be too thin. I will contact you directly with regard to other alternative. paul.lauria
 (posted 2012-07-30 19:32:07.0) I should say, your *half-inch* lens tubes don't have an adapter for the M12x0.5. Why...? We're kind of tight on space is why I ask. paul.lauria
 (posted 2012-07-30 19:23:22.0) Your lens tubes don't have adapters for M12 x 0.5 threads, so why bother using this thread for your EFL=8mm lens'? is there some alternative? I'd like to use one of the M8 and M12 lens on this page in a tube. (specifically, C240TME-B and C390TME-B) jlow
 (posted 2012-07-30 13:20:00.0) Response from Jeremy at Thorlabs. The drop in refractive index is a result of the molding process used in making these molded aspheres. The aspheres are molded above the glass transition temperature and cooled rapidly. This results in a small amount of residual stress, which translates into a small index drop. This data can be found in the Zemax catalogs. clarafly
 (posted 2012-07-28 03:21:47.0) The index of H-LAK54 at 655 nm is 1.724 in the autocad pdf of A390-B, but http://refractiveindex.info/?group=CDGM&material=H-LAK54 and CDGM's database both give 1.72975 at 655 nm, why the difference? Can you provide your version of dispersion formula? bdada
 (posted 2012-02-24 15:07:00.0) Response from Buki at Thorlabs to acable:
Thank you for your feedback. The variable holds the units but the coefficients are unitless. We are currently looking into how best to unify the information in one document. bdada
 (posted 2012-01-23 08:50:00.0) Response from Buki at Thorlabs:
Thank you for your feedback. The housings of our mounted aspheric lenses are made from 303 stainless steel, which should be non magnetic. We can provide custom aluminum housings and have contacted you to get more information. p.nowik
 (posted 2012-01-19 11:06:41.0) Is there a possibility to get the lenses mounted in non magnetic materials, for example aluminium? acable
 (posted 2012-01-13 18:47:21.0) Do the aspheric coeficients have units, seem to be missing from your drawings.
It would be nice if the pdf "Spot Diagrams for Laser Quality Molded Glass Aspheric Lens 352230" had the drawing embedded in it so we don't have to open multiple documents. |
AR Coating Abbreviations | |
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Abbreviation | Description |
U | Uncoated: Optics Do Not have an AR Coating |
A | Broadband AR Coating for the 350 - 700 nm Range |
B | Broadband AR Coating for the 600 - 1050 nm or 650 - 1050 nm Range |
C | Broadband AR Coating for the 1050 - 1620 nm or 1050 - 1700 nm Range |
V | Narrowband AR Coating Designed for the Wavelength Listed in the Table Below |
The table below contains all molded visible and near-IR aspheric lenses offered by Thorlabs. For our selection of IR molded aspheres, click here. The Item # listed is that of the unmounted, uncoated lens. An "X" in any of the five AR Coating Columns indicates the lens is available with that coating (note that the V coating availability is indicated with the AR coating wavelength). The table to the right defines each letter and lists the specified AR coating range. Clicking on the X takes you to the landing page where that lens (mounted or unmounted) can be purchased.
Base Item # | AR Coating Options | Effective Focal Length |
NA | Outer Diameter of Unmounted Lens |
Working Distance | Clear Aperture of Unmounted Lens |
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U | A | B | C | V | Unmounted | Mounted | |||||
355465 | X | 0.5 mm | S1: 0.50 S2: 0.10 |
1.845 mm | S1: 0.3 mma S2: 2.9 mma |
- | S1: Ø0.40 mm S2: Ø0.70 mm |
||||
355915 | X | 0.8 mm | S1: 0.50 S2: 0.12 |
1.300 mm | S1: 0.7 mma S2: 3.9 mma |
- | S1: Ø0.77 mm S2: Ø1.00 mm |
||||
355200 | X | 1.1 mm | S1: 0.43 S2: 0.12 |
2.400 mm | S1: 0.5 mmb S2: 4.8 mma |
- | S1: Ø1.24 mm S2: Ø1.24 mm |
||||
355201 | X | 1.1 mm | S1: 0.12 S2: 0.43 |
4.929 mm | S1: 0.5 mmb S2: 4.8 mma |
- | S1: Ø1.24 mm S2: Ø1.24 mm |
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354450 | X | 1.2 mm | S1: 0.30 S2: 0.30 |
1.800 mm | S1: 1.7 mma S2: 1.7 mma |
- | S1: Ø1.14 mm S2: Ø1.14 mm |
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354710 | X | X | X | X | 1.5 mm | 0.5 | 2.650 mm | 0.5 mmb | 0.4 mmb,c | S1: Ø1.15 mm S2: Ø1.50 mm |
|
354140 | X | X | X | X | 1.5 mm | 0.6 | 2.400 mm | 0.8 mma | 0.8 mma | S1: Ø1.14 mm S2: Ø1.60 mm |
|
355755 | X | 1.9 mm | S1: 0.15 S2: 0.15 |
1.700 mm | S1: 3.6 mma S2: 3.6 mma |
- | S1: Ø1.10 mm S2: Ø1.10 mm |
||||
355151 | X | X | X | X | 2.0 mm | 0.5 | 3.000 mm | 0.5 mmb | 0.3 mmb,c | S1: Ø1.09 mm S2: Ø2.00 mm |
|
355440 | X | X | X | X | 2.8 mm | S1: 0.3 S2: 0.5 |
4.700 mm | S2: 7.1 mma |
S1: 1.8 mmb,c S2: 7.09 mma |
S1: Ø3.76 mm S2: Ø4.12 mm |
|
355392 | X | X | X | X | 2.8 mm | 0.6 | 4.000 mm | 1.5 mma | 1.0 mma,c | S1: Ø2.50 mm S2: Ø3.60 mm |
|
355390 | X | X | X | X | 2.8 mm | 0.6 | 4.500 mm | 2.2 mma | 2.0 mma,c | S1: Ø3.60 mm S2: Ø3.60 mm |
|
355660 | X | X | X | X | 3.0 mm | 0.5 | 4.000 mm | 1.6 mma | 1.3 mma,c | S1: Ø2.35 mm S2: Ø3.60 mm |
|
354330 | X | X | X | X | 3.1 mm | 0.7 | 6.325 mm | 1.8 mma | 1.8 mma,c | S1: Ø3.84 mm S2: Ø5.00 mm |
|
N414 | X | X | X | 3.30 mm | 0.47 | 4.50 mm | 1.94 mma | 1.83 mma,c | Ø3.52 mm | ||
354340 | X | X | X | 4.0 mm | 0.6 | 6.325 mm | 1.48 mmb | 1.2 mmb,c | S1: Ø3.77 mm S2: Ø5.10 mm |
||
357610 | X | X | X | 4.0 mm | 0.6 | 6.325 mm | 1.5 mmb | 1.1 mmb,c | S1: Ø3.39 mm S2: Ø4.80 mm |
||
357775 | X | X | X | 405 | 4.0 mm | 0.6 | 6.325 mm | 1.9 mmb | 1.5 mmb,c | S1: Ø3.45 mm S2: Ø4.80 mm |
|
354350 | X | X | X | 4.5 mm | 0.4 | 4.700 mm | 2.2 mma | 1.6 mma,c | S1: Ø2.05 mm S2: Ø3.70 mm |
||
355230 | X | X | X | X | 1064 | 4.5 mm | 0.6 | 6.325 mm | 2.8 mmb | 2.4 mmb,c | S1: Ø3.93 mm S2: Ø5.07 mm |
A230 | X | X | X | X | 4.51 mm | 0.55 | 6.34 mm | 2.91 mma | 2.53 mma,c | Ø4.95 mm | |
354453 | X | X | X | X | 4.6 mm | 0.5 | 6.000 mm | 2.0 mmb | 0.9 mmb,c | S1: Ø3.38 mm S2: Ø4.80 mm |
|
A390 | X | X | 4.60 mm | 0.53 | 6.00 mm | 2.70 mma | 1.64 mma,c | Ø4.89 mm | |||
354430 | X | X | X | 5.0 mm | 0.2 | 2.000 mm | 4.4 mma | 4.0 mma,c | S1: Ø1.40 mm S2: Ø1.60 mm |
||
354105 | X | X | X | X | 5.5 mm | 0.6 | 7.200 mm | 3.1 mmb | 2.0 mmb,c | S1: Ø4.96 mm S2: Ø6.00 mm |
|
354171 | X | X | X | X | 6.2 mm | 0.3 | 4.700 mm | 3.4 mmb | 2.8 mmb,c | S1: Ø2.72 mm S2: Ø3.70 mm |
|
355110 | X | X | X | X | 1064 | 6.2 mm | 0.4 | 7.200 mm | 2.7 mmb | 1.6 mmb,c | S1: Ø2.93 mm S2: Ø5.00 mm |
A110 | X | X | X | X | 6.24 mm | 0.40 | 7.20 mm | 3.39 mma | 2.39 mma,c | Ø5.00 mm | |
A375 | X | X | X | 7.50 mm | 0.30 | 6.51 mm | 5.90 mma | 5.59 mma,c | Ø4.50 mm | ||
354240 | X | X | X | X | 1064 | 8.0 mm | 0.5 | 9.950 mm | 4.9 mmb | 3.8 mmb,c | S1: Ø6.94 mm S2: Ø8.00 mm |
A240 | X | X | X | X | 8.00 mm | 0.50 | 9.94 mm | 5.92 mma | 4.79 mma,c | Ø8.00 mm | |
354060 | X | X | X | X | 9.6 mm | 0.3 | 6.325 mm | 7.5 mmb | 7.1 mmb,c | S1: Ø5.13 mm S2: Ø5.20 mm |
|
354061 | X | X | X | X | 11.0 mm | 0.2 | 6.325 mm | 8.9 mmb | 8.5 mmb,c | S1: Ø4.63 mm S2: Ø5.20 mm |
|
A220 | X | X | X | 11.00 mm | 0.26 | 7.20 mm | 7.97 mma | 6.91 mma,c | Ø5.50 mm | ||
354220 | X | X | X | X | 1064 | 11.0 mm | 0.3 | 7.200 mm | 6.9 mmb | 5.8 mmb,c | S1: Ø4.07 mm S2: Ø5.50 mm |
355397 | X | X | X | X | 11.0 mm | 0.3 | 7.200 mm | 9.3 mmb | 8.2 mmb,c | S1: Ø6.24 mm S2: Ø6.68 mm |
|
A397 | X | X | X | 11.00 mm | 0.30 | 7.20 mm | 9.64 mma | 8.44 mma,c | Ø6.59 mm | ||
354560 | X | X | X | X | 13.86 mm | 0.2 | 6.325 mm | 12.1 mma | 11.7 mma,c | S1: Ø4.54 mm S2: Ø5.10 mm |
|
A260 | X | X | X | 15.29 mm | 0.16 | 6.50 mm | 14.09 mma | 13.84 mma,c | Ø5.00 mm | ||
354260 | X | X | X | X | 15.3 mm | 0.2 | 6.500 mm | 12.7 mmb | 12.4 mmb,c | S1: Ø4.61 mm S2: Ø5.00 mm |
|
A280 | X | X | X | 18.40 mm | 0.15 | 6.50 mm | 17.13 mma | 16.88 mma,c | Ø5.50 mm | ||
354280 | X | X | X | X | 1064 | 18.4 mm | 0.15 | 6.500 mm | 15.9 mmb | 15.6 mmb,c | S1: Ø5.15 mm S2: Ø5.50 mm |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354140-B | 1.5 mm | 0.58 | 2.400 mm | 0.8 mmd | S1: Ø1.14 mm S2: Ø1.60 mm |
1.020 mm | 780 nm | 600 - 1050 nm | - | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C140TMD-B | 6.2 mm | M6 x 0.5 | SPW306 | |||||||||||
354710-B | 1.5 mm | 0.53 | 2.650 mm | 0.5 mme | S1: Ø1.15 mm S2: Ø1.50 mm |
0.863 mm | 1550 nm | 600 - 1050 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C710TMD-B | 6.2 mm | 0.4 mme,f | M6 x 0.5 | SPW306 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
355151-B | 2.0 mm | 0.50 | 3.000 mm | 0.5 mmd | S2: Ø2.00 mm |
1.892 mm | 780 nm | 600 - 1050 nm | 0.250 mm | D-ZLaF52LA | Focal Shift / Spot Size Cross Section |
- | - | |
C151TMD-B | 2.00 mm | 6.2 mm | 0.3 mmd,f | M6 x 0.5 | SPW306 | |||||||||
355390-B | 2.8 mm | 0.55 | 4.500 mm | 2.2 mme | S1: Ø3.60 mm S2: Ø3.60 mm |
1.900 mm | 830 nm | - | D-ZLaF52LA | 390_Asph.pdf | - | - | ||
C390TME-B | 8.2 mm | 2.0 mme,f | M8 x 0.5 | SPW308 | ||||||||||
355392-B | 2.8 mm | 0.60 | 4.000 mm | 1.5 mme | S1: Ø2.50 mm S2: Ø3.60 mm |
2.240 mm | 830 nm | - | D-ZLaF52LA | 392_Asph.pdf | - | - | ||
C392TME-B | 6.2 mm | 1.0 mme,f | M6 x 0.5 | SPW306 | ||||||||||
355440-B | 2.8 mm | S1: 0.26 S2: 0.52 |
4.700 mm | S1: 2.0 mmd S2: 7.1 mme |
S1: Ø3.76 mm S2: Ø4.12 mm |
3.827 mm | 980 nm | 600 - 1050 nm | 0.250 mm | D-ZLaF52LA | Focal Shift / Spot Size Cross Section |
- | - | |
C440TMD-B | 8.2 mm | S1: 1.9 mmd,f S2: 7.1 mme |
M8 x 0.5 | SPW308 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
355660-B | 3.0 mm | 0.52 | 4.000 mm | 1.6 mmd | S1: Ø2.35 mm S2: Ø3.60 mm |
2.500 mm | 1550 nm | 600 - 1050 nm | - | D-ZLaF52LA | 660_Asph.pdf | - | - | |
C660TME-B | 8.2 mm | 1.3 mmd,e | M8 x 0.5 | SPW308 | ||||||||||
354330-B | 3.1 mm | 0.70 | 6.325 mm | 1.800 mmd | S1: Ø3.84 mm S2: Ø5.00 mm |
3.214 mm | 830 nm | 600 - 1050 nm | - | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C330TMD-B | 9.2 mm | 1.8 mmd | M9 x 0.5 | SPW301 | ||||||||||
N414-B | 3.30 mm | 0.47 | 4.50 mm | 1.94 mmf | S2: Ø3.52 mm | 3.87 mm | 670 nm | 600 - 1050 nm | 0.25 mm | H-ZLaF52 | N414_Asph.pdf | - | - | |
N414TM-B | 6.2 mm | 1.8 mme,f | 0.3 mm | M6 x 0.5 | SPW306 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
357610-B | 4.0 mm | 0.62 | 6.325 mm | 1.5 mmd | S2: Ø4.80 mm |
2.953 mm | 410 nm | 1.200 mm | D-LAK6 | Focal Shift / Spot Size Cross Section |
- | - | ||
C610TMD-B | 9.2 mm | 1.1 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
357775-B | 4.0 mm | 0.60 | 6.325 mm | 1.9 mmd | S1: Ø3.45 mm S2: Ø4.80 mm |
2.898 mm | 408 nm | 600 - 1050 nm | 0.250 mm | D-LAK6 | Focal Shift / Spot Size Cross Section |
- | - | |
C775TMD-B | 9.2 mm | 1.5 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
354340-B | 4.0 mm | 0.64 | 6.325 mm | 1.5 mmd | S1: Ø3.77 mm S2: Ø5.10 mm |
3.097 mm | 685 nm | 600 - 1050 nm | 1.200 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C340TMD-B | 9.2 mm | 1.2 mmd,e | 1.2 mm | M9 x 0.5 | SPW301 | |||||||||
354350-B | 4.5 mm | 0.40 | 4.700 mm | 2.2 mmf | S1: Ø2.05 mm S2: Ø3.70 mm |
3.649 mm | 980 nm | 600 - 1050 nm | - | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C350TMD-B | 8.2 mm | 1.6 mme,f | M8 x 0.5 | SPW308 | ||||||||||
355230-B | 4.5 mm | 0.55 | 6.325 mm | 2.8 mmd | S1: Ø3.93 mm S2: Ø5.07 mm |
2.708 mm | 780 nm | 600 - 1050 nm | 0.250 mm | D-ZLaF52LA | Focal Shift / Spot Size Cross Section |
- | - | |
C230TMD-B | 9.2 mm | 2.4 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
A230-B | 4.51 mm | 0.55 | 6.34 mm | 2.91 mmf | Ø4.95 mm | 2.94 mm | 780 nm | 650 - 1050 nm | 0.25 mm | S-NPH1 | A230_Asph.pdf | - | - | |
A230TM-B | 9.24 mm | 2.53 mme,f | M9 x 0.5 | SPW301 | ||||||||||
354453-B | 4.6 mm | 0.50 | 6.000 mm | 2.0 mmd | S1: Ø3.38 mm S2: Ø4.80 mm |
3.135 mm | 655 nm | 600 - 1050 nm | 0.275 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C453TMD-B | 9.2 mm | M9 x 0.5 | SPW301 | |||||||||||
A390-B | 4.60 mm | 0.53 | 6.00 mm | 2.70 mmf | Ø4.89 mm | 3.10 mm | 655 nm | 650 - 1050 nm | 0.275 mm | H-LaK54 | A390_Asph.pdf | - | - | |
A390TM-B | 9.24 mm | 1.64 mme,f | M9 x 0.5 | SPW301 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354430-B | 5.0 mm | 0.15 | 2.000 mm | 4.4 mmd | S2: Ø1.60 mm |
0.991 mm | - | D-ZK3 | 430_Asph.pdf | - | - | |||
C430TME-B | 6.2 mm | 4.2 mmd,e | SPW306 | |||||||||||
354105-B | 5.5 mm | 0.60 | 7.200 mm | S1: Ø4.96 mm S2: Ø6.00 mm |
2.937 mm | 633 nm | 600 - 1050 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | ||
C105TMD-B | 9.2 mm | 2.0 mme,f | M9 x 0.5 | SPW301 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354171-B | 6.2 mm | 0.30 | 4.700 mm | 3.4 mmd | S2: Ø3.70 mm |
3.484 mm | 633 nm | 0.275 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | ||
C171TMD-B | 8.2 mm | 2.8 mmd,e | M8 x 0.5 | SPW308 | ||||||||||
355110-B | 6.2 mm | 0.40 | 7.200 mm | 2.7 mmd | S1: Ø2.93 mm S2: Ø5.00 mm |
5.158 mm | 780 nm | 600 - 1050 nm | 0.275 mm | D-ZLaF52LA | Focal Shift / Spot Size Cross Section |
- | - | |
C110TMD-B | 9.2 mm | 1.6 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
A110-B | 6.24 mm | 0.40 | 7.20 mm | 3.39 mmf | Ø5.00 mm | 5.36 mm | 780 nm | 650 - 1050 nm | 0.275 mm | H-LaK54 | A110_Asph.pdf | - | - | |
A110TM-B | 9.24 mm | 2.39 mme,f | M9 x 0.5 | SPW301 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
A375-B | 7.50 mm | 0.30 | 6.51 mm | 5.90 mmd | Ø4.50 mm | 2.75 mm | 810 nm | 650 - 1050 nm | 0.275 mm | H-LaK54 | A375_Asph.pdf | - | - | |
A375TM-B | 9.24 mm | 5.59 mmd,e | M9 x 0.5 | SPW301 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354240-B | 8.0 mm | 0.50 | 9.936 mm | 4.9 mmd | S1: Ø6.94 mm S2: Ø8.00 mm |
3.434 mm | 780 nm | 600 - 1050 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C240TMD-B | 12.2 mm | 3.8 mmd,f | M12 x 0.5 | SPW302 | ||||||||||
A240-B | 8.00 mm | 0.50 | 9.94 mm | 5.92 mme | Ø8.00 mm | 3.69 mm | 780 nm | 650 - 1050 nm | 0.25 mm | D-LaK6 | A240_Asph.pdf | - | - | |
A240TM-B | 12.24 mm | 4.79 mme,f | M12 x 0.5 | SPW302 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354060-B | 9.6 mm | 0.27 | 6.325 mm | 7.5 mmd | S1: Ø5.13 mm S2: Ø5.20 mm |
2.493 mm | 633 nm | 600 - 1050 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C060TMD-B | 9.2 mm | 7.1 mmd,e | M9 x 0.5 | SPW301 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354061-B | 0.24 | S2: Ø5.20 mm |
633 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | ||||||
C061TMD-B | 9.2 mm | 8.5 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
354220-B | 11.0 mm | 0.25 | 7.200 mm | 6.909 mmd | S1: Ø4.07 mm S2: Ø5.50 mm |
5.032 mm | 633 nm | 600 - 1050 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |
C220TMD-B | 9.2 mm | 5.8 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
A220-B | 11.00 mm | 0.26 | 7.20 mm | 7.97 mmf | Ø5.50 mm | 5.00 mm | 633 nm | 650 - 1050 nm | 0.25 mm | D-K59 | A220_Asph.pdf | - | - | |
A220TM-B | 9.24 mm | 6.91 mme,f | 0.275 mm | M9 x 0.5 | SPW301 | |||||||||
355397-B | 11.0 mm | 0.30 | 7.200 mm | 9.3 mmd | S1: Ø6.24 mm S2: Ø6.68 mm |
1.947 mm | 670 nm | 600 - 1050 nm | 0.275 mm | D-ZLaF52LA | Focal Shift / Spot Size Cross Section |
- | - | |
C397TMD-B | 9.2 mm | 8.2 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
A397-B | 11.00 mm | 0.30 | 7.20 mm | 9.64 mmf | Ø6.59 mm | 2.20 mm | 670 nm | 650 - 1050 nm | 0.275 mm | H-LaK54 | A397_Asph.pdf | - | - | |
A397TM-B | 9.24 mm | 8.44 mme,f | M9 x 0.5 | SPW301 |
Item # (Unmounted / Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354560-B | 13.9 mm | 0.18 | 6.325 mm | 12.1 mmd | S1: Ø4.54 mm S2: Ø5.10 mm |
2.773 mm | 650 nm | 600 - 1050 nm | - | D-ZK3 | 560_Asph.pdf | - | - | |
C560TME-B | 9.2 mm | 11.7 mmd,e | M9 x 0.5 | SPW301 |
Item # (Unmounted/ Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354260-B | 15.3 mm | 0.16 | 6.500 mm | 12.7 mmd | S2: Ø5.00 mm |
2.209 mm | 780 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | ||
C260TMD-B | 9.2 mm | 12.4 mmd,e | M9 x 0.5 | SPW301 | ||||||||||
A260-B | 15.29 mm | 0.16 | 6.50 mm | 14.09 mmf | Ø5.00 mm | 2.20 mm | 780 nm | 650 - 1050 nm | 0.25 mm | H-LaK54 | A260_Asph.pdf | - | - | |
A260TM-B | 9.24 mm | 13.84 mme,f | - | M9 x 0.5 | SPW301 |
Item # (Unmounted/ Mounted) |
Info | EFLa | NA | OD | WDb | CA | TC | DW | AR Range | LWTc | Glass | Performance | Thread | Suggested Spanner Wrench |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
354280-B | 18.4 mm | 0.15 | 6.500 mm | S2: Ø5.50 mm |
2.178 mm | 780 nm | 0.250 mm | D-ZK3 | Focal Shift / Spot Size Cross Section |
- | - | |||
C280TMD-B | 9.2 mm | 15.6 mmd,f | M9 x 0.5 | SPW301 | ||||||||||
A280-B | 18.40 mm | 0.15 | 6.50 mm | 17.13 mme | Ø5.50 mm | 2.17 mm | 780 nm | 650 - 1050 nm | 0.25 mm | H-LaK54 | A280_Asph.pdf | - | - | |
A280TM-B | 9.24 mm | 16.88 mme,f | - | M9 x 0.5 | SPW301 |