Laser Diodes: Ø3.8 mm, TO-46, Ø5.6 mm, Ø9 mm, and Ø9.5 mm TO Cans
- Ø3.8 mm, TO-46, Ø5.6 mm, Ø9 mm, and Ø9.5 mm Laser Diodes
- Center Wavelengths Ranging from 375 nm to 4.60 µm
- Output Powers from 0.2 mW to 2 W
Ø3.8 mm
Ø9 mm
Ø5.6 mm
Application Idea
Our Laser Diode Driver Kits Include an
LD Controller, TEC Controller,
LD/TEC Mount, and Accessories
Ø9.5 mm
(DPSS Laser)
Ø9 mm
(High Heat Load)
TO-46
(VCSEL Diode)
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Webpage Features | |
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Clicking this icon opens a window that contains specifications and mechanical drawings. | |
Clicking this icon allows you to download our standard support documentation. | |
Choose Item |
Clicking the words "Choose Item" opens a drop-down list containing all of the in-stock lasers around the desired center wavelength. The red icon next to the serial number then allows you to download L-I-V and spectral measurements for that serial-numbered device. |
Features
- Fabry-Perot (FP), Distributed Feedback (DFB), Volume Holographic Grating (VHG), Diode-Pumped Solid-State (DPSS), Quantum Cascade (QCL), Interband Cascade (ICL), and Vertical-Cavity Surface-Emitting Laser (VCSEL) Diodes
- Output Powers from 0.2 mW to 2 W
- Center Wavelengths Available from 375 nm to 9.5 µm
- Easily Choose a Compatible Mount Using Our LD Pin Codes
- Compatible with Thorlabs' Laser Diode and TEC Controllers
TO-packaged laser diodes are available in standard Ø3.8 mm, Ø5.6 mm, or Ø9 mm TO cans, as well as TO-46 or Ø9.5 mm cans. We have categorized the pin configurations into standard A, B, C, D, E, F, G, and H pin codes (see the diagram below). This pin code allows the user to easily determine compatible mounts.
Some of our diodes that are offered in header packages can be converted to a sealed TO can package by request, as indicated in the tables below. Please contact Tech Support for details.
Notes on Center Wavelength
While the center wavelength is listed for each diode, this is only a typical number. The center wavelength of a particular diode varies from production run to production run. Thus, the diode you receive may not operate at the typical center wavelength. Diodes can be temperature tuned, which will alter the lasing wavelength. A number of items below are listed as Wavelength Tested, which means that the dominant wavelength of each unit has been measured and recorded. For many of these items, after clicking "Choose Item" below, a list will appear that contains the dominant wavelength, output power, and operating current of each in-stock unit. Clicking on the red Docs Icon next to the serial number provides access to a PDF with serial-number-specific L-I-V and spectral characteristics. For products listed as Wavelength Tested that do not have the "Choose Item" option, please contact Tech Support with inquires about specific wavelengths.
Laser Mode and Linewidth
We offer laser diodes with different output characteristics (power, wavelength, beam size, shape, etc.). Most lasers offered here are single transverse mode (single mode, or SM) and a few are designed for higher-power, multiple-transverse-mode (multimode, or MM) operation. Our wavelength stabilized VHG laser diodes, sold below, have excellent single mode performance. Some single mode laser diodes can be operated with limited single-longitudinal-mode characteristics (see tables below for additional information). For better side mode suppression ratio (SMSR) performance, consider devices such as DFB lasers, VHG-stabilized lasers, DBR lasers, or external cavity lasers. Thorlabs single-frequency lasers are highlighted in green in the tables below; in particular, our VHG-stabilized, DFB, DBR, and external cavity lasers have very narrow linewidths (≤20 MHz for the VHG-stabilized and DFB lasers and <100 kHz for the DBR and ECL lasers). Please see our Laser Diode Tutorial for more information on these topics and laser diodes in general.
Laser diodes are sensitive to electrostatic shock. Please take the proper precautions when handling the device (see our electrostatic shock accessories). Laser diodes are also sensitive to optical feedback, which can cause significant fluctuations in the output power of the laser diode depending on the application. See our optical isolators for potential solutions to this problem. Tech Support staff are available to help you select a laser diode and to discuss possible operation issues.
Pin Codes
Laser Diode pin codes indicate which mounts and diodes are compatible. The drawings do not represent exact wiring diagrams.
Pin Code | Monitor Photodiode | Pin Code | Monitor Photodiode |
---|---|---|---|
A | Yes | E | No |
B | Yes | F | Yes |
C | Yes | G | No |
D | Yes | H | No |
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).
Video Insight: Setting Up a TO Can Laser Diode
Installing a TO can laser diode in a mount and setting it up to run under temperature and current control presents many opportunities to make a mistake that could damage or destroy the laser. This step-by-step guide includes tips for keeping humans and laser diodes safe from harm.
When operated within their specifications, laser diodes have extremely long lifetimes. Most failures occur from mishandling or operating the lasers beyond their maximum ratings. Laser diodes are among the most static-sensitive devices currently made and proper ESD protection should be worn whenever handling a laser diode. Due to their extreme electrostatic sensitivity, laser diodes cannot be returned after their sealed package has been opened. Laser diodes in their original sealed package can be returned for a full refund or credit.
Handling and Storage Precautions
Because of their extreme susceptibility to damage from electrostatic discharge (ESD), care should be taken whenever handling and operating laser diodes.
Wrist Straps
Use grounded anti-static wrist straps whenever handling diodes.
Anti-Static Mats
Always work on grounded anti-static mats.
Laser Diode Storage
When not in use, short the leads of the laser together to protect against ESD damage.
Operating and Safety Precautions
Use an Appropriate Driver
Laser diodes require precise control of operating current and voltage to avoid overdriving the laser. In addition, the laser driver should provide protection against power supply transients. Select a laser driver appropriate for your application. Do not use a voltage supply with a current-limiting resistor since it does not provide sufficient regulation to protect the laser diode.
Power Meters
When setting up and calibrating a laser diode with its driver, use a NIST-traceable power meter to precisely measure the laser output. It is usually safest to measure the laser diode output directly before placing the laser in an optical system. If this is not possible, be sure to take all optical losses (transmissive, aperture stopping, etc.) into consideration when determining the total output of the laser.
Reflections
Flat surfaces in the optical system in front of a laser diode can cause some of the laser energy to reflect back onto the laser’s monitor photodiode, giving an erroneously high photodiode current. If optical components are moved within the system and energy is no longer reflected onto the monitor photodiode, a constant-power feedback loop will sense the drop in photodiode current and try to compensate by increasing the laser drive current and possibly overdriving the laser. Back reflections can also cause other malfunctions or damage to laser diodes. To avoid this, be sure that all surfaces are angled 5-10°, and when necessary, use optical isolators to attenuate direct feedback into the laser.
Heat Sinks
Laser diode lifetime is inversely proportional to operating temperature. Always mount the laser diode in a suitable heat sink to remove excess heat from the laser package.
Voltage and Current Overdrive
Be careful not to exceed the maximum voltage and drive current listed on the specification sheet with each laser diode, even momentarily. Also, reverse voltages as little as 3 V can damage a laser diode.
ESD-Sensitive Device
Laser diodes are susceptible to ESD damage even during operation. This is particularly aggravated by using long interface cables between the laser diode and its driver due to the inductance that the cable presents. Avoid exposing the laser diode or its mounting apparatus to ESD at all times.
ON/OFF and Power-Supply-Coupled Transients
Due to their fast response times, laser diodes can be easily damaged by transients less than 1 µs. High-current devices such as soldering irons, vacuum pumps, and fluorescent lamps can cause large momentary transients, and thus surge-protected outlets should always be used when working with laser diodes.
If you have any questions regarding laser diodes, please contact Thorlabs Technical Support for assistance.
Laser Safety and Classification
Safe practices and proper usage of safety equipment should be taken into consideration when operating lasers. The eye is susceptible to injury, even from very low levels of laser light. Thorlabs offers a range of laser safety accessories that can be used to reduce the risk of accidents or injuries. Laser emission in the visible and near infrared spectral ranges has the greatest potential for retinal injury, as the cornea and lens are transparent to those wavelengths, and the lens can focus the laser energy onto the retina.
Safe Practices and Light Safety Accessories
- Laser safety eyewear must be worn whenever working with Class 3 or 4 lasers.
- Regardless of laser class, Thorlabs recommends the use of laser safety eyewear whenever working with laser beams with non-negligible powers, since metallic tools such as screwdrivers can accidentally redirect a beam.
- Laser goggles designed for specific wavelengths should be clearly available near laser setups to protect the wearer from unintentional laser reflections.
- Goggles are marked with the wavelength range over which protection is afforded and the minimum optical density within that range.
- Laser Safety Curtains and Laser Safety Fabric shield other parts of the lab from high energy lasers.
- Blackout Materials can prevent direct or reflected light from leaving the experimental setup area.
- Thorlabs' Enclosure Systems can be used to contain optical setups to isolate or minimize laser hazards.
- A fiber-pigtailed laser should always be turned off before connecting it to or disconnecting it from another fiber, especially when the laser is at power levels above 10 mW.
- All beams should be terminated at the edge of the table, and laboratory doors should be closed whenever a laser is in use.
- Do not place laser beams at eye level.
- Carry out experiments on an optical table such that all laser beams travel horizontally.
- Remove unnecessary reflective items such as reflective jewelry (e.g., rings, watches, etc.) while working near the beam path.
- Be aware that lenses and other optical devices may reflect a portion of the incident beam from the front or rear surface.
- Operate a laser at the minimum power necessary for any operation.
- If possible, reduce the output power of a laser during alignment procedures.
- Use beam shutters and filters to reduce the beam power.
- Post appropriate warning signs or labels near laser setups or rooms.
- Use a laser sign with a lightbox if operating Class 3R or 4 lasers (i.e., lasers requiring the use of a safety interlock).
- Do not use Laser Viewing Cards in place of a proper Beam Trap.
Laser Classification
Lasers are categorized into different classes according to their ability to cause eye and other damage. The International Electrotechnical Commission (IEC) is a global organization that prepares and publishes international standards for all electrical, electronic, and related technologies. The IEC document 60825-1 outlines the safety of laser products. A description of each class of laser is given below:
Class | Description | Warning Label |
---|---|---|
1 | This class of laser is safe under all conditions of normal use, including use with optical instruments for intrabeam viewing. Lasers in this class do not emit radiation at levels that may cause injury during normal operation, and therefore the maximum permissible exposure (MPE) cannot be exceeded. Class 1 lasers can also include enclosed, high-power lasers where exposure to the radiation is not possible without opening or shutting down the laser. | |
1M | Class 1M lasers are safe except when used in conjunction with optical components such as telescopes and microscopes. Lasers belonging to this class emit large-diameter or divergent beams, and the MPE cannot normally be exceeded unless focusing or imaging optics are used to narrow the beam. However, if the beam is refocused, the hazard may be increased and the class may be changed accordingly. | |
2 | Class 2 lasers, which are limited to 1 mW of visible continuous-wave radiation, are safe because the blink reflex will limit the exposure in the eye to 0.25 seconds. This category only applies to visible radiation (400 - 700 nm). | |
2M | Because of the blink reflex, this class of laser is classified as safe as long as the beam is not viewed through optical instruments. This laser class also applies to larger-diameter or diverging laser beams. | |
3R | Class 3R lasers produce visible and invisible light that is hazardous under direct and specular-reflection viewing conditions. Eye injuries may occur if you directly view the beam, especially when using optical instruments. Lasers in this class are considered safe as long as they are handled with restricted beam viewing. The MPE can be exceeded with this class of laser; however, this presents a low risk level to injury. Visible, continuous-wave lasers in this class are limited to 5 mW of output power. | |
3B | Class 3B lasers are hazardous to the eye if exposed directly. Diffuse reflections are usually not harmful, but may be when using higher-power Class 3B lasers. Safe handling of devices in this class includes wearing protective eyewear where direct viewing of the laser beam may occur. Lasers of this class must be equipped with a key switch and a safety interlock; moreover, laser safety signs should be used, such that the laser cannot be used without the safety light turning on. Laser products with power output near the upper range of Class 3B may also cause skin burns. | |
4 | This class of laser may cause damage to the skin, and also to the eye, even from the viewing of diffuse reflections. These hazards may also apply to indirect or non-specular reflections of the beam, even from apparently matte surfaces. Great care must be taken when handling these lasers. They also represent a fire risk, because they may ignite combustible material. Class 4 lasers must be equipped with a key switch and a safety interlock. | |
All class 2 lasers (and higher) must display, in addition to the corresponding sign above, this triangular warning sign. |
Posted Comments: | |
家維 劉
 (posted 2024-11-21 00:05:35.037) I want to know about the bandwidth of this laser diode ksosnowski
 (posted 2024-11-20 01:33:06.0) Thanks for reaching out to us. L650P007's specification sheet has a sample spectrum from this laser. We do not specify an exact spectral bandwidth for this device, as the spectrum is not single mode and will depend on operating conditions like drive current and case temperature. Most laser diodes can be modulated with rise times less than 1 nanosecond however the driving electronics are the primary limiting factor in the modulation bandwidth of a laser system. Our LDC205C has the fastest direct modulation bandwidth at 250kHz however with some laser mounts like LDM56, a faster RF signal generator can be used in addition to a slower source like LDC series to extend the analog modulation range up to 600MHz. The LDM56's RF electrical power limits can limit this modulation depth for higher current lasers, however L650P007 has a relatively low maximum current level. user
 (posted 2024-10-15 14:41:55.807) Is this laser diode TM or TE polarized? mgarodia
 (posted 2024-10-16 01:36:31.0) Thank you for reaching out to us. The laser diode is TE-polarized. gokhan zengin
 (posted 2024-10-04 11:55:12.723) I want to order L904P010 laser diode and driver for this diode.Do you have driver for this laser diode as well (12 vdc) jpolaris
 (posted 2024-10-04 07:38:26.0) Thank you for contacting Thorlabs. I have reached out to you directly to discuss which mounting and driving options would be most suitable to the needs of your application. Our selection of laser diode current controllers can be found at the following link: https://www.thorlabs.com/navigation.cfm?guide_ID=112 YOUNGIN YU
 (posted 2024-08-14 19:10:30.76) Quantity: 1 piece
1. Is it possible to ship to South Korea?
2. If so, how long does it take to ship?
3. What is the payment method?
4. Do I need to enter my personal customs code when ordering? cdolbashian
 (posted 2024-08-26 09:03:14.0) Thank you for reaching out to us with this inquiry. We do have a distributor in South Korea, Jinsung Instruments. Our international distributors can be found on our website here (https://www.thorlabs.com/distributors.cfm). I have reached out to you directly to share their contact information, as well as address some of your other concerns. JINSEO PARK
 (posted 2024-08-06 15:07:26.323) Dear Thorlabs,
Hi, I'm Jinseo Park working on the Yonsei Univ. Lab.
I'm writing the mail to give your technical support for L650P007.
I'm doing the experiment with it, and I need 'Beam profile' of this LD.
I thought it would have gaussian profile, but it has double peaks.
I'm using EK1101/EK1102 driver purchased on Thorlabs.
If I should contact another route, please let me know.
Thank you,
Jinseo Park cdolbashian
 (posted 2024-08-14 11:07:53.0) Thank you for reaching out to us with this inquiry. The beam profile should certainly be single peaked Gaussian mode. I have contacted you directly to understand, more clearly, your implementation. user
 (posted 2024-05-06 19:04:48.3) 您好,我们想购买贵公司的L780P010的激光二极管制作776nm的激光器,目前对你们的产品有一些疑惑。
1、它是通过什么方式来调谐波长的(温度、工作电流或其他?)
2、它能用于制作外腔式半导体激光器中的LD吗?
以上就是我对疑惑,希望能得到你们的回复。谢谢! cdolbashian
 (posted 2024-05-24 10:31:29.0) Thank you for reaching out to us with these inquiries. Roughly translated your inquiries are as follows.1. How does it tune the wavelength (temperature, operating current or other?)
2. Can it be used to make LDs in external cavity semiconductor lasers?
The temperature tunability of this component is not exact, but can be found to approximately follow the rule of 0.20-0.25nm/°C. Regarding your second question, this is not a gain chip, so I do not think this could be used as you are indicating. We have contacted you directly to discuss your application and intents further. Jay Lin
 (posted 2023-12-25 18:09:52.63) I bought L840P200 few months ago and I would like to know if the coating of the laser mirror in the cavity has some kind of narrow band coating or not? Typically the regular multi longitudinal mode laser diode has wider spectral linewidth, but these products has the linewidth of around 60MHz, so I think the cavity mirror is not regular low reflectivity mirror. jpolaris
 (posted 2024-01-02 05:02:35.0) Thank you for contacting Thorlabs. Unfortunately, design details such as the presence of any narrowband coatings and cavity mirror reflectivity/ finesse are considered proprietary. I have reached out to you directly to discuss this topic further. lijiong shen
 (posted 2023-07-07 17:38:48.27) I saw many opnext laser diodes written as single frequency for example HL6501MG, is it real Single longitudinal mode laser and what is the linewidth? cdolbashian
 (posted 2023-07-14 04:35:11.0) Thank you for reaching out to us with this inquiry. Indeed this is both a single longitudinal mode and single transverse mode. We are planning to make this information a bit more explicit on the page in the near future. I have contacted you directly to discuss this. Brady Paradis
 (posted 2023-03-14 14:33:54.35) Hi,
Do you have recommended replacements or an ability to purchase some of these even though they are obsolete?
Thanks,
Brady jdelia
 (posted 2023-03-16 08:25:22.0) Thank you for contacting Thorlabs. I have reached out to you directly regarding the feasibility of ordering the L405P150 diode. Matthew Bissen
 (posted 2023-03-02 21:01:20.38) Hello Thorlabs,
I'm from a company in the Bay Area called Adventurous Sports. We're working on an online class package for kids 10+. It's a lazermaze at home project where the kids get to assemble their own laser and make an obstacle course around their home. We're looking to combine the following products and I was curious how much it would cost for Thorlabs to do it:
5m@ Laser Diode Red 3 Volt with De Anza plug, with an longer tougher plug to fit into a breadboard. Do you think you would be able to do anything like that?
Operations Manager,
Matthew Bissen ksosnowski
 (posted 2023-03-08 02:32:21.0) Hello Matthew, thanks for reaching out to Thorlabs. For this type of project I would suggest checking out our compact laser series like CPS635, PL202, and PL204. The CPS series uses a 2.5 mm phono-jack plug, and the PL series comes with a USB connector for power or with bare-wire leads options if you want to connect to your own power supply. These lasers come pre-collimated as well, while our bare laser diodes require additional lenses to create a parallel beam of output rays. We do not have any special plug options on the lasers, however are 2.5mm receptables commonly available and you can add some a breakout board, or the bare-wire option would allow any connector to be used. As lasers are sensitive to polarity, I would recommend using a polarized plug to avoid accidentally attaching the laser in reverse which can lead to damage. I have reached out directly to discuss this application further. user
 (posted 2022-11-02 10:31:04.38) Dear Sir/Madam!
We recently have purchased a HL6358MG TO Can 5.6 mm laser diode from you. We have a question about cleaning of the protecting glass of the laser diode module: which material is made from? Could you provide us a suggestion about the proper cleaning process (e. g. could we clean the glass with alcohol)?
If alcohol must be not used, what is the recommended material/method?
Thank you very much for advance!
Attila Andrásik
Semilab Zrt cdolbashian
 (posted 2022-11-08 01:56:43.0) Thank you for reaching out to us Attila. These diodes are from a vendor, and they do not share the window material with us. That being said, these diodes are ideally hermetically sealed, so they should be sealed against air and any solvent used on the surface. We would recommend using a similar cleaning procedure as cleaning a standard optic via our guide here:https://www.thorlabs.com/newgrouppage9.cfm?objectgroup_id=9025 Samuel Gebretsadkan
 (posted 2022-08-28 00:27:05.9) Is this diode AR coated? I couldn't find any information in the datasheet. cdolbashian
 (posted 2022-09-16 09:50:23.0) Thank you for reaching out to us! The facet is likely AR-coated, but not less than <1% reflectivity. If you intend to use this to build an external cavity laser, this is not designed to be used as an external gain chip. The window itself is certainly AR-coated, likely <0.25%. I have reached out to you directly to discuss this further. Marija Ćurčić
 (posted 2022-06-30 11:05:01.94) Dear Sir/Madam,
Could you please give me an information on whether the orientation of a laser diode is in any way related to the light polarization? Is the orientation of a pin on a bottom of a housing important for the output polarization?
Thank you in advance.
Best regards,
Marija Curcic
Institute of Physics Belgrade, Serbia jdelia
 (posted 2022-08-02 02:33:56.0) Thank you for contacting Thorlabs. The polarization direction will be along the long side of the chip. The long edge is nominally aligned to the 45 degree identification tab on the TO-can. However, this is a manual process so that alignment is not controlled and, therefore, we do not specify a tolerance for the alignment of the polarization axis. user
 (posted 2022-05-09 07:04:04.493) Hi, I have bought a M9-808-0150 diode to be used with the driver LD1255R. With a first test we obtained a power of 150 mW, but in a second test the power did not go higher than 10 mW, using a current close to the diode limit (200 mA). We do not know the cause of this malfunction. You could guide us with a solution or identifying the fault. Thanks a lot. cdolbashian
 (posted 2022-05-27 12:38:17.0) Thank you for reaching out to us. Based on our conversations, it seems like the device was potentially damaged due to insufficient cooling. I have reached out to you directly to discuss strategies to lengthen the lifetime of your active optical instrumentation. For future troubleshooting inquiries, please contact Techsupport@thorlabs.com. maomao zeng
 (posted 2022-02-11 11:34:31.55) Beam Deviation Angle 和 Beam Divergence两项参数的具体意义和区别是什么呢? user
 (posted 2021-12-25 04:38:58.63) this diode using agfa aventra imgesetter 44 cdolbashian
 (posted 2021-12-28 01:51:26.0) Thank you for reaching out to us with your laser diode inquiry. I have reached out to you directly to discuss your application. Narae Bae
 (posted 2021-10-18 14:38:00.27) 1064 nm Fabry-Perot Laser Diode, 200 mW
I want to know the graph (the ouput power of input current)
X: input current(mA)
Y: output power(mW) YLohia
 (posted 2021-12-22 02:56:11.0) Thank you for contacting Thorlabs. I have reached out to you with an LIV curve of the M9-A64-0200. This data can be requested by emailing techsupport@thorlabs.com. Edmond Wilson
 (posted 2021-10-16 14:54:15.74) I have 6 of these diode lasers and I use them for my Raman Spectrometer that I built. I am very happy with the laser and it exceeded my expectations because it produces 130 mW of optical power. Of course, I could use a more powerful laser. But in order to get a single mode diode laser that was more powerful. it would be much more expensive. YLohia
 (posted 2021-12-22 02:56:09.0) Hello, thank you for your feedback on this laser. We're quite happy to hear that it has exceeded your expectations. We will consider your comments about what an ideal laser for your application be as we release more laser diodes in the future. user
 (posted 2021-09-28 12:07:54.403) Dear Sir/Madam, I have bought a LD785-SH300 diode from your company, but somehow I lost the spec of it. The serial number is 785P300CK34.D04. Could you please offer me the specifications, like the center wavelength, wavelength VS temperature and so on? Thanks a lot! YLohia
 (posted 2021-10-11 02:51:05.0) Hello, thank you for contacting Thorlabs. The serialized spec sheet for LD785-SH300 (S/N 785P300CK34.D04) can be accessed here: https://www.thorlabs.com/Thorcat/SerialNumbers/LD785-SH300/LD785-SH300-785P300CK34.D04_FT.pdf. TATING TSAO
 (posted 2021-07-23 16:54:16.777) ML620G40 spec中說明符合IEC 60825-1,請問有通過此證明的電子檔可以提供? YLohia
 (posted 2021-07-26 11:18:48.0) Hello, the IEC 60825-1 requirements documentation can be accessed here on IEC's official website: https://webstore.iec.ch/publication/3587 Alvin KANG
 (posted 2021-07-22 17:44:17.613) Hi,
We would like to check whether this combination of things can work properly:
1. L450P1600MM
2. S7060R
3. SR9F (or SR9HF?)
Thanks. YLohia
 (posted 2021-07-29 02:12:07.0) Hello, thank you for contacting Thorlabs. We strongly discourage using the L450P1600MM with S7060R and SR9HF (HF because of the high compliance voltage requirement of this laser) because of the significantly reduced lifetime and output power due to lack of active cooling when using with this cable and/or socket. Instead, we suggest using the LDM56 mount with a temperature controller (TED200C). Yu-Pu LIN
 (posted 2021-05-18 02:52:06.63) Dear Sirs,
Do you have an idea of the rise/fall time of your 1370nm laser ? (L1370G1)
Thank you very much!
Best regards,
Yu-Pu LIN YLohia
 (posted 2021-05-19 01:34:32.0) Hello Yu-Pu, I have reached out to you directly regarding this. I-Yun Chen
 (posted 2021-03-11 13:04:29.437) Hello. We used L520P50, but we want to automatically drive its operating current back and forth to achieve different power. Is this possible for L520P50? Or do you have any recommendation? YLohia
 (posted 2021-03-12 03:39:10.0) Hello, are you asking if it is possible to operate the L520P50 in a constant power mode at various set power levels? If so, the answer is yes, but will ultimately depend on the specs of your current driver. For example, our LDC205C driver can support such a mode. Please see page 15 of the manual: https://www.thorlabs.com/_sd.cfm?fileName=15988-D02.pdf&partNumber=LDC205C I-Yun Chen
 (posted 2021-01-19 03:53:22.743) Hello. We used DL5146-101S as a light source in our experiment. However, we have observed that after operating for 3 hours, the power of the laser seems to be drifting(the power becomes larger and larger). I wonder if there is any solution to this problem. Thanks a lot. YLohia
 (posted 2021-01-19 03:23:50.0) Hello, how much is the power drifting over time? Usually, such effects can be attributed to the lack of active cooling and/or improper heat-sinking. I have reached out to you directly to troubleshoot further. Josefine Lemke
 (posted 2020-10-22 06:39:12.87) L785 SH300 - what is the recommended operating temperature? In the spec sheet it is "20 - 50°C" but there is one small additional note that says T_CHIP=25°C. What is T_CHIP? Thank you, Josefine YLohia
 (posted 2020-10-22 01:46:55.0) Hello Josefine, thank you for contacting Thorlabs. T_Chip is the temperature of the laser diode chip (not case). All specs are taken at a chip temperature of 25 C. This can be considered the "recommended" operating temperature for most applications. Some applications may require slight differences in the output spectrum, which can be tuned by changing the temperature of the chip. For example, the temperature tuning coefficient of the LD785-SH300 is on the order of 0.20-0.25 nm/C. michael lee
 (posted 2020-09-10 13:12:20.473) L405P150 - 405 nm, 150 mW is a laser we want to try in our CBRNE instrument, but we need a different form factor. We are looking for 5.6mm - B package. Is this something you can do for us, without costing too much? YLohia
 (posted 2020-09-11 09:05:33.0) Thank you for contacting Thorlabs. We offer the DL5146-101S 405 nm laser diode in a 5.6 mm package. I have reached out to you directly to discuss the possibility of getting a custom laser. Mark Frederick
 (posted 2020-09-08 20:42:37.227) What is the window thickness of the L638P200? YLohia
 (posted 2020-09-09 11:18:57.0) Thank you for contacting Thorlabs. The window thickness for the L638P200 is ~0.25 mm. mohiniv. sontakke
 (posted 2020-07-30 04:44:26.697) Actually, I really wanted to know it's side-effects! Specifically, is it harmful for human? What's the time one can stay expose to certain laser! Is it harmful, do answer my queries!
Eagerly waiting for your reply😊 YLohia
 (posted 2020-07-30 03:37:05.0) Hello, thank you for contacting Thorlabs. We suggest contacting your local Laser Safety Officer (LSO) for accurate information regarding laser safety and human health. David Lowndes
 (posted 2020-06-11 07:30:49.667) Could you please advise the materials of the TO56 packages? YLohia
 (posted 2020-06-16 08:22:05.0) Thank you for contacting Thorlabs. We have reached out to you directly to discuss this. Warren Massey
 (posted 2020-01-08 13:15:34.467) Have you got anything like (package, wavelength, power) an L637P5 but with pin code "G"? In our application we cannot tolerate the connection of the circuit to the case of the diode. YLohia
 (posted 2020-01-08 02:07:22.0) Thank you for contacting Thorlabs. We offer the HL63133DG, which has a 170 mW typical output power, G pin code, and 5.6 mm package. Juwan Kim
 (posted 2020-01-07 00:24:10.747) Do you have any products with specially enhanced temperature characteristics?
I'm looking for a product that meets the specifications below.
1. Visible LD: 50 mw or higher, CW, temperature -40 to 50
2. Infrared LD: 200 mW or higher, CW, temperature -40 to 50 YLohia
 (posted 2020-01-07 11:37:55.0) Thank you for contacting Thorlabs. I have reached out to you directly to discuss possible solutions. Channarong Asavathongkul
 (posted 2019-11-18 02:36:04.657) L462P1400MM has been discontinued, what is the replacement product? YLohia
 (posted 2019-11-18 11:12:58.0) Thank you for contacting Thorlabs. The closest alternative to this item is the L450P1600MM. Steve Russell
 (posted 2019-11-15 14:08:06.383) Can you tell me what the electrical frequency response of this particular laser diode is? I never see this spec in any laser spec sheet of any type. YLohia
 (posted 2019-11-20 11:19:56.0) Hello, thank you for contacting Thorlabs. Unfortunately, we do not measure this parameter and it is hard to guarantee a certain level of performance as it varies between different pieces. Each diode would have to be individually tested in order to provide an accurate representation of the frequency response. That being said, we expect that the L850P010 can be modulated >100 MHz with the proper drive electronics. Ana R
 (posted 2019-10-18 17:51:38.667) Hi,
I have an L785H1 diode that I'm setting up as part of an ECDL. The specifications state that the threshold current should be around 50 mA, but I'm getting just above 25 mA free-running. Is this something to be concerned about? YLohia
 (posted 2019-10-18 02:49:38.0) Hello, thank you for contacting Thorlabs. A lower threshold current is not a cause for concern. We specify the typical threshold current to be 50 mA, but we do not specify a lower bound as this can vary and is not seen as a defect. user
 (posted 2019-10-17 09:26:55.633) Hello, do you provide tolerance data regarding the positioning (x y z & tilt) of these TO-46, TO-56, TO-90 packages ? What should be the most reliable reference surface ? (package cylinder diameter, cylinder front face, support back or front plane ?) YLohia
 (posted 2019-10-17 11:16:56.0) Hello, we do not provide this tolerance data as some of the laser diodes on this page are sourced from other manufacturers (these diodes have original manufacturer spec sheets on this page) and these tolerances are not consistent. I will reach out to you directly to discuss your requirements further. user
 (posted 2019-07-23 04:04:08.233) What is the lifetime characteristics of laser diode L520G1, particularly MTBF? YLohia
 (posted 2019-08-07 10:00:19.0) Hello, thank you for contacting Thorlabs. I have reached out to you directly with this information. user
 (posted 2019-06-24 03:51:37.793) Is it possible to order a HL6312G diode with a lasing wavelength known more accurately than the 625 - 640 nm range given by the data sheet ? YLohia
 (posted 2019-06-24 09:39:17.0) Hello, thank you for contacting Thorlabs. Unfortunately, these laser diodes are not tested individually for wavelength. You can, however, purchase one of the LPS-635-FC pigtailed diodes, which are individually tested for wavelength and power. PHANI PEDDIBHOTLA
 (posted 2019-06-10 10:28:24.897) Hello,
I bought L520P50 from Thorlabs. May I know the company which manufactures this diode? I am looking for a diode with TO56 package with a wavelength from 521-575 nm.
Best Regards,
Phani. Vladimir Makarov
 (posted 2019-05-30 15:28:02.717) Hello, I am using the PL450B laser diode as a point illumination source. Could you tell me what the length and width of the emission area is? In other words, the size of the area on the facet of the laser where the light is emitted. YLohia
 (posted 2019-05-30 04:37:22.0) Hello, the emitter width for this laser diode is 1.5um x 1.0 um. user
 (posted 2019-04-30 09:57:39.64) Could you please suggest me a collimation tube for 3.8mm laser diodes like L405P150, PL520 or L638P150 and other 3.8mm Laser diodes?
thanks in advance.
ibrahim YLohia
 (posted 2019-04-30 09:29:13.0) Hello Ibrahim, thank you for contacting Thorlabs. Unfortunately, we currently do not offer collimation tubes for 3.8mm package size laser diodes. That being said, you can build your own collimation tube with the
S05LM38 adapter for 3.8mm diodes and using appropriate SM05 lens tubes and aspheric lenses. michael.fitch
 (posted 2018-11-16 16:47:18.98) About the HL6750, when I look at the manufacturers spec sheet in the link, it appears to be pin code A. But it is listed as pin code C. Could you please check the listing? mmcclure
 (posted 2018-11-19 10:09:53.0) Hello, thank you for your inquiry. The pin configuration for the HL6750MG laser diode corresponds to pin code C, as shown in both the manufacturer's spec sheet and the blue "info" icon on the website. Should you have additional questions, our tech support team will happily assist you. paul.nachman
 (posted 2018-07-11 12:09:32.84) The drawings you provide in this image ...
https://www.thorlabs.com/images/popupimages/HL8338MG_DWG.gif
... don't label the pin numbers in the pin diagram for comparison with the bottom view.
It's lucky that you make the manufacturer's data available ...
https://www.thorlabs.com/drawings/fd0e8f0902043f28-6AFA1F67-E78D-AFDC-C6C2BB53EE55033C/HL8338MG-MFGSpec.pdf
... else I would have guessed wrong. YLohia
 (posted 2018-07-12 09:57:42.0) Hello, thank you for your feedback and bringing this issue to our attention. We are currently working on making all drawings for this item more consistent with each other. chih.hao.li
 (posted 2018-05-23 08:53:36.27) Hi We are wondering if there is AR coating on the laser diode front window. If no, how much do you charge for an AR coated laser diode? Thank you! YLohia
 (posted 2018-05-23 05:07:46.0) Hello, thank you for contacting Thorlabs. The windows on laser diode cans are almost always AR coated. user
 (posted 2018-03-12 15:35:01.523) The PL450B pin connections reported in the Thorlabs selling packages and datasheets are different from the one reported in pag. 7 of the PL450B MFG Spec. YLohia
 (posted 2018-03-22 08:25:57.0) Hello, thank you for your feedback. We took a look at this and, while they are labeled differently, the pin connections are still the same. The only thing that is different here is that the arbitrary pin numbers (Pin 1 and Pin 3) are switched in designation. robert
 (posted 2017-10-11 16:29:34.97) It should be made clear to prospective buyers that these diodes are exceptionally sensitive to optically feedback. To quote the Thorlabs Tech Support staff "Our engineers that designed this told me that any reflection with more than 2% of the power will kill diode." That is not typical of laser diodes in this wavelength range. tcampbell
 (posted 2018-03-23 02:17:13.0) Hello, thank you for contacting Thorlabs. After discussing with our engineers, we have added a warning for select laser diodes on this page. Please feel free to contact us if you have concerns about any other products on our site. vg.buesaquillo
 (posted 2017-06-03 13:17:19.2) Do you can give me the spectrum of the diode laser DL5146-101S?
THANKS tfrisch
 (posted 2017-06-30 01:11:14.0) Hello, thank you for contacting Thorlabs. The spectrum will change because of differences from one production lot to another and because of differences in use, such as operating temperature and drive current. I will reach out to you directly to discuss your application. dmitry.busko
 (posted 2016-11-16 11:59:52.17) In a datasheet for M9-940-0200 there is no any information about the LD and PD pin connections. tfrisch
 (posted 2016-11-22 08:21:01.0) Hello, thank you for pointing out the missing circuit information. We will correct the spec sheet, but until then, if you are looking at the bottom of laser diode (pins pointing towards you), and the square cutout is down, the left pin is the Photodiode Anode, the center pin ties the Photodiode Cathode to the Laser Diode Anode and the case, and the right pin is the Laser Diode Cathode. mitch
 (posted 2016-06-18 08:50:58.713) Hi, I would like to drive the L850P010 fast. Initially I will be using your bias-T and driver, but I plan on designing my own bias-T for 2.4GHz operation. I was wondering if you could provide details on this laser diodes approximate impedance and more importantly it's capacitance? Thanks besembeson
 (posted 2016-06-22 08:50:15.0) Response from Bweh at Thorlabs USA: Such high speed modulation will not be suitable with this diode. You may want to consider a VCSEL instead and we don't have one for your application at this time. pedrueze
 (posted 2016-02-02 13:23:02.757) Hi all,
I have your profile current and temperature controller "Profile PRO 8000" with a combined module LD/TE controller ITC 8052.
(I can send by email the pics of them.)
I also have a laser diode L9805E2P5, (50 mW, 980 nm, A Pin code).
The problem is that I need to choose an appropiate Temperature Controlled Laser Diode Mount for it.
I was checking the TCLDM9 device. The problem is that the output of the controller is DB-15 (15 pins), and very close to it is the LD output of 9 pins.
It is better understood if you can see the pics.
I need to be sure which are the appropiate cables to connect between my controller and the TE mount, regarding the pin congiguration of my LD,
and if they have enough space to put in the module.
Could you please help me with that?
Thank you very much. besembeson
 (posted 2016-02-04 10:21:59.0) Response from Bweh at Thorlabs USA: The cables you would need will be the CAB400 for the laser control and CAB420-15 for the temperature controller. These can be found at the following page: http://www.thorlabs.com/newgrouppage9.cfm?objectgroup_id=966&pn=ITC8052 cmrogers
 (posted 2015-12-07 21:36:29.773) I am looking for is a diode centered near 656nm, with as a wide a gain bandwidth as possible, for use in an ECDL. What is the gain bandwidth of the relevant diodes that you sell?
Also, are any of your diodes AR coated?
Thanks! besembeson
 (posted 2015-12-08 10:14:54.0) Response from Bweh at Thorlabs USA: The Fabry Perot lasers that you would need for your wavelength of interest will typically have optical bandwidth in the 5-10nm range. The high power diode lasers, for example the HL6545MG are AR coated. pedrueze
 (posted 2015-10-12 11:42:15.523) Hello. I just recently bought one L9805E2P5 laser diode + a cable SR9A-DB9.
We have a current controller whose pin diagram could be find here:
http://assets.newport.com/webDocuments-EN/images/70041001_LDC-37x4C_IX.PDF
(see please page 17)
As you may see, doesn't match with the pins of the cable, so we must re-wired it.
My concern is which pins should I re-wire. In principle, I wired 3, 5 and 9 to use the laser diode, cathode, anode and ground chassis.
Is this correct/enough to make the laser emitting? should I connect the PD cathode and Anode as well? What is the use of anode/cathode voltage sense pins in the manual?
Concerning the temperature, I will use the laser at low-power (for alignement).
Thanks a lot for your help. jlow
 (posted 2015-10-12 04:55:23.0) Response from Jeremy at Thorlabs: At a minimum, you will want to connect Pin2 and Pin7 on the SR9A-DB9 to your controller. If you want to use the internal photodiode for feedback, you will want to connect Pin4 as well. I will contact you directly via e-mail to help with this. hmagh001
 (posted 2015-05-08 10:53:27.903) We just bought L808P200 for our lab and it is supposed to have a maximum power of 200 mW, and the spec. file of Laser diodes says that the threshold current is 100 mA. However, when I set the current to 80 mW from the LD controller (bought from thorlab as well, LDC220C) and measure the power with an optical power meter, it shows only 5 mW. I was wondering, how can we reach to higher power numbers with this laser diode.
Thanks,
Hadi. jlow
 (posted 2015-05-13 11:05:19.0) Response from Jeremy at Thorlabs: The threshold current is the current needed for the LD to lase. To get to the 200mW power, you would need to drive this near the operating current (somewhere between 220 to 300mA for the L808P200). Please use an optical power meter to measure the output power instead of relying just on the supplied current. Also, the light from the LD is divergent so please make sure your optical power meter will capture all the light from the LD to get an accurate reading. rssi_2nava
 (posted 2014-11-24 19:25:25.74) Hello guys,
i was hoping you can tell me the amplitude reflection coefficients of the diode rear and front faces of the L1060P100J laser diode, i can't find them anywhere and i need them to compute the transmision function of the diode cavity. I'll appreciate reading from you soon
Kind Regards jlow
 (posted 2014-12-11 01:30:49.0) Response from Jeremy at Thorlabs: The coating information on the chip facet is proprietary and is not something that we can provide. jimzambuto
 (posted 2014-10-03 11:13:51.5) For the diode part number L404P400M, what is the extent of the SLOW AAXIS. I am trying to design a collimator and the residual divergence caused by the extent of the laser facet in the slow or multimode direction is very important. jlow
 (posted 2014-10-13 09:05:41.0) Response from Jeremy at Thorlabs: You can find the far-field emission pattern/angle on page 3 of the MFG spec sheet in the supporting documents. The direct link is http://www.thorlabs.com/thorcat/QTN/L404P400M-MFGSpec.pdf. ar_1348
 (posted 2014-04-26 15:03:07.077) i need a driver for M5-905-0100 cdaly
 (posted 2014-05-08 02:58:52.0) Response from Chris at Thorlabs: This laser can be mounted in TCLDM9 and driven with LDC202C which can provide 200mA, covering the M5-905-0100's max operating current of 170mA. I'd suggest using a temperature controller as well, such as TED200C. t.meinert
 (posted 2014-01-08 08:36:55.39) ask for Quotation:
LD Type: DL 5146-101s
Quantity: 100pcs/a
1000pcs/a jlow
 (posted 2014-01-08 10:15:34.0) Response from Jeremy at Thorlabs: We will contact you directly to provide a quote. |
The rows shaded green below denote single-frequency lasers. |
Item # | Wavelength | Output Power | Operating Current | Operating Voltage | Beam Divergence | Laser Mode | Package | |
---|---|---|---|---|---|---|---|---|
Parallel | Perpendicular | |||||||
L375P70MLD | 375 nm | 70 mW | 110 mA | 5.4 V | 9° | 22.5° | Single Transverse Mode | Ø5.6 mm |
L404P400M | 404 nm | 400 mW | 370 mA | 4.9 V | 13° (1/e2) | 42° (1/e2) | Multimode | Ø5.6 mm |
LP405-SF10 | 405 nm | 10 mW | 50 mA | 5.0 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L405P20 | 405 nm | 20 mW | 38 mA | 4.8 V | 8.5° | 19° | Single Transverse Mode | Ø5.6 mm |
LP405C1 | 405 nm | 30 mW | 75 mA | 4.3 V | 1.4 mrad | 1.4 mrad | Single Transverse Mode | Ø3.8 mm, SM Pigtail with Collimator |
L405G2 | 405 nm | 35 mW | 50 mA | 4.9 V | 10° | 21° | Single Transverse Mode | Ø3.8 mm |
DL5146-101S | 405 nm | 40 mW | 70 mA | 5.2 V | 8° | 19° | Single Transverse Mode | Ø5.6 mm |
L405A1 | 405 nm | 175 mW (Min) | 150 mA | 5.0 V | 9° | 20° | Single Transverse Mode | Ø5.6 mm |
LP405-MF300 | 405 nm | 300 mW | 350 mA | 4.5 V | - | - | Multimode | Ø5.6 mm, MM Pigtail |
L405G1 | 405 nm | 1000 mW | 900 mA | 5.0 V | 13° | 45° | Multimode | Ø9 mm |
LP450-SF25 | 450 nm | 25 mW | 75 mA | 5.0 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L450G3 | 450 nm | 100 mW (Min) | 80 mA | 5.2 V | 8.4° | 21.5° | Single Transverse Mode | Ø3.8 mm |
L450G2 | 450 nm | 100 mW (Min) | 80 mA | 5.0 V | 8.4° | 21.5° | Single Transverse Mode | Ø5.6 mm |
L450P1600MM | 450 nm | 1600 mW | 1200 mA | 4.8 V | 7° | 19 - 27° | Multimode | Ø5.6 mm |
L473P100 | 473 nm | 100 mW | 120 mA | 5.7 V | 10 | 24 | Single Transverse Mode | Ø5.6 mm |
LP488-SF20 | 488 nm | 20 mW | 70 mA | 6.0 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP488-SF20G | 488 nm | 20 mW | 80 mA | 5.5 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L488P60 | 488 nm | 60 mW | 75 mA | 6.8 V | 7° | 23° | Single Transverse Mode | Ø5.6 mm |
LP515-SF3 | 515 nm | 3 mW | 50 mA | 5.3 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L515A1 | 515 nm | 10 mW | 50 mA | 5.4 V | 6.5° | 21° | Single Transverse Mode | Ø5.6 mm |
LP520-SF15A | 520 nm | 15 mW | 100 mA | 7.0 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP520-SF15 | 520 nm | 15 mW | 140 mA | 6.5 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
L520A1 | 520 nm | 30 mW (Min) | 80 mA | 5.5 V | 8° | 22° | Single Transverse Mode | Ø5.6 mm |
PL520 | 520 nm | 50 mW | 250 mA | 7.0 V | 7° | 22° | Single Transverse Mode | Ø3.8 mm |
L520P50 | 520 nm | 45 mW | 150 mA | 7.0 V | 7° | 22° | Single Transverse Mode | Ø5.6 mm |
L520A2 | 520 nm | 110 mW (Min) | 225 mA | 5.9 V | 8° | 22° | Single Transverse Mode | Ø5.6 mm |
DJ532-10 | 532 nm | 10 mW | 220 mA | 1.9 V | 0.69° | 0.69° | Single Transverse Mode | Ø9.5 mm (non-standard) |
DJ532-40 | 532 nm | 40 mW | 330 mA | 1.9 V | 0.69° | 0.69° | Single Transverse Mode | Ø9.5 mm (non-standard) |
LP633-SF50 | 633 nm | 50 mW | 170 mA | 2.6 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL63163DG | 633 nm | 100 mW | 170 mA | 2.6 V | 8.5° | 18° | Single Transverse Mode | Ø5.6 mm |
LPS-635-FC | 635 nm | 2.5 mW | 70 mA | 2.2 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
LPS-PM635-FC | 635 nm | 2.5 mW | 60 mA | 2.2 V | - | - | Single Transverse Mode | Ø9.0 mm, PM Pigtail |
L635P5 | 635 nm | 5 mW | 30 mA | <2.7 V | 8° | 32° | Single Transverse Mode | Ø5.6 mm |
HL6312G | 635 nm | 5 mW | 50 mA | <2.7 V | 8° | 31° | Single Transverse Mode | Ø9 mm |
LPM-635-SMA | 635 nm | 8 mW | 50 mA | 2.2 V | - | - | Multimode | Ø9 mm, MM Pigtail |
LP635-SF8 | 635 nm | 8 mW | 60 mA | 2.3 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL6320G | 635 nm | 10 mW | 60 mA | 2.2 V | 8° | 31° | Single Transverse Mode | Ø9 mm |
HL6322G | 635 nm | 15 mW | 75 mA | 2.4 V | 8° | 30° | Single Transverse Mode | Ø9 mm |
L637P5 | 637 nm | 5 mW | 20 mA | <2.4 V | 8° | 34° | Single Transverse Mode | Ø5.6 mm |
LP637-SF50 | 637 nm | 50 mW | 140 mA | 2.6 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP637-SF70 | 637 nm | 70 mW | 220 mA | 2.7 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL63142DG | 637 nm | 100 mW | 140 mA | 2.7 V | 8° | 18° | Single Transverse Mode | Ø5.6 mm |
HL63133DG | 637 nm | 170 mW | 250 mA | 2.8 V | 9° | 17° | Single Transverse Mode | Ø5.6 mm |
HL6388MG | 637 nm | 250 mW | 340 mA | 2.3 V | 10° | 40° | Multimode | Ø5.6 mm |
L637G1 | 637 nm | 1200 mW | 1100 mA | 2.5 V | 10° | 32° | Multimode | Ø9 mm (non-standard) |
L638P040 | 638 nm | 40 mW | 92 mA | 2.4 V | 10° | 21° | Single Transverse Mode | Ø5.6 mm |
L638P150 | 638 nm | 150 mW | 230 mA | 2.7 V | 9 | 18 | Single Transverse Mode | Ø3.8 mm |
L638P200 | 638 nm | 200 mW | 280 mA | 2.9 V | 8 | 14 | Single Transverse Mode | Ø5.6 mm |
L638P700M | 638 nm | 700 mW | 820 mA | 2.2 V | 9° | 35° | Multimode | Ø5.6 mm |
HL6358MG | 639 nm | 10 mW | 40 mA | 2.4 V | 8° | 21° | Single Transverse Mode | Ø5.6 mm |
HL6323MG | 639 nm | 30 mW | 100 mA | 2.5 V | 8.5° | 30° | Single Transverse Mode | Ø5.6 mm |
HL6362MG | 640 nm | 40 mW | 90 mA | 2.5 V | 10° | 21° | Single Transverse Mode | Ø5.6 mm |
LP642-SF20 | 642 nm | 20 mW | 90 mA | 2.5 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP642-PF20 | 642 nm | 20 mW | 110 mA | 2.5 V | - | - | Single Transverse Mode | Ø5.6 mm, PM Pigtail |
HL6364DG | 642 nm | 60 mW | 120 mA | 2.5 V | 10° | 21° | Single Transverse Mode | Ø5.6 mm |
HL6366DG | 642 nm | 80 mW | 150 mA | 2.5 V | 10° | 21° | Single Transverse Mode | Ø5.6 mm |
HL6385DG | 642 nm | 150 mW | 250 mA | 2.6 V | 9° | 17° | Single Transverse Mode | Ø5.6 mm |
L650P007 | 650 nm | 7 mW | 28 mA | 2.2 V | 9° | 28° | Single Transverse Mode | Ø5.6 mm |
LPS-660-FC | 658 nm | 7.5 mW | 65 mA | 2.6 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP660-SF20 | 658 nm | 20 mW | 80 mA | 2.6 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LPM-660-SMA | 658 nm | 22.5 mW | 65 mA | 2.6 V | - | - | Multimode | Ø5.6 mm, MM Pigtail |
HL6501MG | 658 nm | 30 mW | 75 mA | 2.6 V | 8.5° | 22° | Single Transverse Mode | Ø5.6 mm |
L658P040 | 658 nm | 40 mW | 75 mA | 2.2 V | 10° | 20° | Single Transverse Mode | Ø5.6 mm |
LP660-SF40 | 658 nm | 40 mW | 135 mA | 2.5 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP660-SF60 | 658 nm | 60 mW | 210 mA | 2.4 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL6544FM | 660 nm | 50 mW | 115 mA | 2.3 V | 10° | 17° | Single Transverse Mode | Ø5.6 mm |
LP660-SF50 | 660 nm | 50 mW | 140 mA | 2.3 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL6545MG | 660 nm | 120 mW | 170 mA | 2.45 V | 10° | 17° | Single Transverse Mode | Ø5.6 mm |
L660P120 | 660 nm | 120 mW | 175 mA | 2.5 V | 10° | 17° | Single Transverse Mode | Ø5.6 mm |
L670VH1 | 670 nm | 1 mW | 2.5 mA | 2.6 V | 10° | 10° | Single Transverse Mode | TO-46 |
LPS-675-FC | 670 nm | 2.5 mW | 55 mA | 2.2 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
HL6748MG | 670 nm | 10 mW | 30 mA | 2.2 V | 8° | 25° | Single Transverse Mode | Ø5.6 mm |
HL6714G | 670 nm | 10 mW | 55 mA | <2.7 V | 8° | 22° | Single Transverse Mode | Ø9 mm |
HL6756MG | 670 nm | 15 mW | 35 mA | 2.3 V | 8° | 24° | Single Transverse Mode | Ø5.6 mm |
LP685-SF15 | 685 nm | 15 mW | 55 mA | 2.1 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL6750MG | 685 nm | 50 mW | 70 mA | 2.3 V | 9° | 21° | Single Transverse Mode | Ø5.6 mm |
HL6738MG | 690 nm | 30 mW | 85 mA | 2.5 V | 8.5° | 19° | Single Transverse Mode | Ø5.6 mm |
LP705-SF15 | 705 nm | 15 mW | 55 mA | 2.3 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL7001MG | 705 nm | 40 mW | 75 mA | 2.5 V | 9° | 18° | Single Transverse Mode | Ø5.6 mm |
LP730-SF15 | 730 nm | 15 mW | 70 mA | 2.5 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
HL7302MG | 730 nm | 40 mW | 75 mA | 2.5 V | 9° | 18° | Single Transverse Mode | Ø5.6 mm |
L760VH1 | 760 nm | 0.5 mW | 3 mA (Max) | 2.2 V | 12° | 12° | Single Frequency | TO-46 |
DBR760PN | 761 nm | 9 mW | 125 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
L763VH1 | 763 nm | 0.5 mW | 3 mA (Max) | 2.0 V | 10° | 10° | Single Frequency | TO-46 |
DBR767PN | 767 nm | 23 mW | 220 mA | 1.87 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DBR770PN | 770 nm | 35 mW | 220 mA | 1.92 V | - | - | Single Frequency | Butterfly, PM Pigtail |
L780P010 | 780 nm | 10 mW | 24 mA | 1.8 V | 8° | 30° | Single Transverse Mode | Ø5.6 mm |
DBR780PN | 780 nm | 45 mW | 250 mA | 1.9 V | - | - | Single Frequency | Butterfly, PM Pigtail |
L785P5 | 785 nm | 5 mW | 28 mA | 1.9 V | 10° | 29° | Single Transverse Mode | Ø5.6 mm |
LPS-PM785-FC | 785 nm | 6.5 mW | 60 mA | - | - | - | Single Transverse Mode | Ø5.6 mm, PM Pigtail |
LPS-785-FC | 785 nm | 10 mW | 65 mA | 1.85 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP785-SF20 | 785 nm | 20 mW | 85 mA | 1.9 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
DBR785S | 785 nm | 25 mW | 230 mA | 2.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DBR785P | 785 nm | 25 mW | 230 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
L785P25 | 785 nm | 25 mW | 45 mA | 1.9 V | 8° | 30° | Single Transverse Mode | Ø5.6 mm |
FPV785S | 785 nm | 50 mW | 410 mA | 2.2 V | - | - | Single Frequency | Butterfly, SM Pigtail |
FPV785P | 785 nm | 50 mW | 410 mA | 2.1 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LP785-SAV50 | 785 nm | 50 mW | 500 mA | 2.2 V | - | - | Single Frequency | Ø9 mm, SM Pigtail |
L785P090 | 785 nm | 90 mW | 125 mA | 2.0 V | 10° | 17° | Single Transverse Mode | Ø5.6 mm |
LP785-SF100 | 785 nm | 100 mW | 300 mA | 2.0 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
FPL785P | 785 nm | 200 mW | 500 mA | 2.1 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
FPL785S-250 | 785 nm | 250 mW (Min) | 500 mA | 2.0 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
LD785-SEV300 | 785 nm | 300 mW | 500 mA (Max) | 2.0 V | 8° | 16° | Single Frequency | Ø9 mm |
LD785-SH300 | 785 nm | 300 mW | 400 mA | 2.0 V | 7° | 18° | Single Transverse Mode | Ø9 mm |
FPL785C | 785 nm | 300 mW | 400 mA | 2.0 V | 7° | 18° | Single Transverse Mode | 3 mm x 5 mm Submount |
LD785-SE400 | 785 nm | 400 mW | 550 mA | 2.0 V | 7° | 16° | Single Transverse Mode | Ø9 mm |
FPV785M | 785 nm | 600 mW | 1100 mA | 1.9 V | - | - | Multimode | Butterfly, MM Pigtail |
L795VH1 | 795 nm | 0.25 mW | 1.2 mA | 1.8 V | 20° | 12° | Single Frequency | TO-46 |
DBR795PN | 795 nm | 40 mW | 230 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DBR808PN | 808 nm | 42 mW | 250 mA | 2 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LP808-SA60 | 808 nm | 60 mW | 150 mA | 1.9 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
M9-808-0150 | 808 nm | 150 mW | 180 mA | 1.9 V | 8° | 17° | Single Transverse Mode | Ø9 mm |
L808P200 | 808 nm | 200 mW | 260 mA | 2 V | 10° | 30° | Multimode | Ø5.6 mm |
FPL808P | 808 nm | 200 mW | 600 mA | 2.1 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
FPL808S | 808 nm | 200 mW | 750 mA | 2.3 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
L808H1 | 808 nm | 300 mW | 400 mA | 2.1 V | 14° | 6° | Single Transverse Mode | Ø9 mm |
LD808-SE500 | 808 nm | 500 mW | 750 mA | 2.2 V | 7° | 14° | Single Transverse Mode | Ø9 mm |
LD808-SEV500 | 808 nm | 500 mW | 800 mA (Max) | 2.2 V | 8° | 14° | Single Frequency | Ø9 mm |
L808P500MM | 808 nm | 500 mW | 650 mA | 1.8 V | 12° | 30° | Multimode | Ø5.6 mm |
L808P1000MM | 808 nm | 1000 mW | 1100 mA | 2 V | 9° | 30° | Multimode | Ø9 mm |
DBR816PN | 816 nm | 45 mW | 250 mA | 1.95 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LP820-SF80 | 820 nm | 80 mW | 230 mA | 2.3 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L820P100 | 820 nm | 100 mW | 145 mA | 2.1 V | 9° | 17° | Single Transverse Mode | Ø5.6 mm |
L820P200 | 820 nm | 200 mW | 250 mA | 2.4 V | 9° | 17° | Single Transverse Mode | Ø5.6 mm |
DBR828PN | 828 nm | 24 mW | 250 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LPS-830-FC | 830 nm | 10 mW | 120 mA | - | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LPS-PM830-FC | 830 nm | 10 mW | 50 mA | 2.0 V | - | - | Single Transverse Mode | Ø5.6 mm, PM Pigtail |
LP830-SF30 | 830 nm | 30 mW | 115 mA | 1.9 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
HL8338MG | 830 nm | 50 mW | 75 mA | 1.9 V | 9° | 22° | Single Transverse Mode | Ø5.6 mm |
L830H1 | 830 nm | 250 mW | 3 A (Max) | 2 V | 8° | 10° | Single Transverse Mode | Ø9 mm |
FPL830P | 830 nm | 300 mW | 900 mA | 2.22 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
FPL830S | 830 nm | 350 mW | 900 mA | 2.5 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
LD830-SE650 | 830 nm | 650 mW | 900 mA | 2.3 V | 7° | 13° | Single Transverse Mode | Ø9 mm |
LD830-MA1W | 830 nm | 1 W | 2 A | 2.1 V | 7° | 24° | Multimode | Ø9 mm |
LD830-ME2W | 830 nm | 2 W | 3 A (Max) | 2.0 V | 8° | 21° | Multimode | Ø9 mm |
L840P200 | 840 nm | 200 mW | 255 mA | 2.4 V | 9 | 17 | Single Transverse Mode | Ø5.6 mm |
L850VH1 | 850 nm | 1 mW | 6 mA (Max) | 2 V | 12° | 12° | Single Frequency | TO-46 |
L850P010 | 850 nm | 10 mW | 50 mA | 2 V | 10° | 30° | Single Transverse Mode | Ø5.6 mm |
L850P030 | 850 nm | 30 mW | 65 mA | 2 V | 8.5° | 30° | Single Transverse Mode | Ø5.6 mm |
FPV852S | 852 nm | 20 mW | 400 mA | 2.2 V | - | - | Single Frequency | Butterfly, SM Pigtail |
FPV852P | 852 nm | 20 mW | 400 mA | 2.2 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DBR852PN | 852 nm | 24 mW | 300 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LP852-SF30 | 852 nm | 30 mW | 115 mA | 1.9 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
L852P50 | 852 nm | 50 mW | 75 mA | 1.9 V | 9° | 22° | Single Transverse Mode | Ø5.6 mm |
LP852-SF60 | 852 nm | 60 mW | 150 mA | 2.0 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
L852P100 | 852 nm | 100 mW | 120 mA | 1.9 V | 8° | 28° | Single Transverse Mode | Ø9 mm |
L852P150 | 852 nm | 150 mW | 170 mA | 1.9 V | 8° | 18° | Single Transverse Mode | Ø9 mm |
L852SEV1 | 852 nm | 270 mW | 400 mA (Max) | 2.0 V | 9° | 12° | Single Frequency | Ø9 mm |
L852H1 | 852 nm | 300 mW | 415 mA (Max) | 2 V | 7° | 15° | Single Transverse Mode | Ø9 mm |
FPL852P | 852 nm | 300 mW | 900 mA | 2.35 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
FPL852S | 852 nm | 350 mW | 900 mA | 2.5 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
LD852-SE600 | 852 nm | 600 mW | 950 mA | 2.3 V | 7° (1/e2) | 13° (1/e2) | Single Transverse Mode | Ø9 mm |
LD852-SEV600 | 852 nm | 600 mW | 1050 mA (Max) | 2.2 V | 8° | 13° (1/e2) | Single Frequency | Ø9 mm |
LP880-SF3 | 880 nm | 3 mW | 25 mA | 2.2 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L880P010 | 880 nm | 10 mW | 30 mA | 2.0 V | 12° | 37° | Single Transverse Mode | Ø5.6 mm |
L895VH1 | 895 nm | 0.2 mW | 1.4 mA | 1.6 V | 20° | 13° | Single Frequency | TO-46 |
DBR895PN | 895 nm | 12 mW | 300 mA | 2 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LP904-SF3 | 904 nm | 3 mW | 30 mA | 1.5 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L904P010 | 904 nm | 10 mW | 50 mA | 2.0 V | 10° | 30° | Single Transverse Mode | Ø5.6 mm |
LP915-SF40 | 915 nm | 40 mW | 130 mA | 1.5 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
DBR935PN | 935 nm | 13 mW | 300 mA | 1.75 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LP940-SF30 | 940 nm | 30 mW | 90 mA | 1.5 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
M9-940-0200 | 940 nm | 200 mW | 270 mA | 1.9 V | 8° | 28° | Single Transverse Mode | Ø9 mm |
L960H1 | 960 nm | 250 mW | 400 mA | 2.1 V | 11° | 12° | Single Transverse Mode | Ø9 mm |
FPV976S | 976 nm | 30 mW | 400 mA (Max) | 2.2 V | - | - | Single Frequency | Butterfly, SM Pigtail |
FPV976P | 976 nm | 30 mW | 400 mA (Max) | 2.2 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DBR976PN | 976 nm | 33 mW | 450 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
L976SEV1 | 976 nm | 270 mW | 400 mA (Max) | 2.0 V | 9° | 12° | Single Frequency | Ø9 mm |
BL976-SAG3 | 976 nm | 300 mW | 470 mA | 2.0 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
BL976-PAG500 | 976 nm | 500 mW | 830 mA | 2.0 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
BL976-PAG700 | 976 nm | 700 mW | 1090 mA | 2.0 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
BL976-PAG900 | 976 nm | 900 mW | 1480 mA | 2.5 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
L980P010 | 980 nm | 10 mW | 25 mA | 2 V | 10° | 30° | Single Transverse Mode | Ø5.6 mm |
LP980-SF15 | 980 nm | 15 mW | 70 mA | 1.5 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
L980P030 | 980 nm | 30 mW | 50 mA | 1.5 V | 10° | 35° | Single Transverse Mode | Ø5.6 mm |
L980P100A | 980 nm | 100 mW | 150 mA | 1.6 V | 6° | 32° | Multimode | Ø5.6 mm |
LP980-SA60 | 980 nm | 60 mW | 230 mA | 2.0 V | - | - | Single Transverse Mode | Ø9.0 mm, SM Pigtail |
L980H1 | 980 nm | 200 mW | 300 mA (Max) | 2.0 V | 8° | 13° | Single Transverse Mode | Ø9 mm |
L980P200 | 980 nm | 200 mW | 300 mA | 1.5 V | 6° | 30° | Multimode | Ø5.6 mm |
DBR1060SN | 1060 nm | 130 mW | 650 mA | 2.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DBR1060PN | 1060 nm | 130 mW | 650 mA | 1.8 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DBR1064S | 1064 nm | 40 mW | 150 mA | 2.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DBR1064P | 1064 nm | 40 mW | 150 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DBR1064PN | 1064 nm | 110 mW | 550 mA | 2.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LPS-1060-FC | 1064 nm | 50 mW | 220 mA | 1.4 V | - | - | Single Transverse Mode | Ø9 mm, SM Pigtail |
M9-A64-0200 | 1064 nm | 200 mW | 280 mA | 1.7 V | 8° | 28° | Single Transverse Mode | Ø9 mm |
L1064H1 | 1064 nm | 300 mW | 700 mA | 1.92 V | 7.6° | 13.5° | Single Transverse Mode | Ø9 mm |
L1064H2 | 1064 nm | 450 mW | 1100 mA | 1.92 V | 7.6° | 13.5° | Single Transverse Mode | Ø9 mm |
DBR1083PN | 1083 nm | 100 mW | 500 mA | 1.75 V | - | - | Single Frequency | Butterfly, PM Pigtail |
L1270P5DFB | 1270 nm | 5 mW | 15 mA | 1.1 V | 7° | 9° | Single Frequency | Ø5.6 mm |
L1290P5DFB | 1290 nm | 5 mW | 16 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
LP1310-SAD2 | 1310 nm | 2.0 mW | 40 mA | 1.1 V | - | - | Single Frequency | Ø5.6 mm, SM Pigtail |
LP1310-PAD2 | 1310 nm | 2.0 mW | 40 mA | 1.0 V | - | - | Single Frequency | Ø5.6 mm, PM Pigtail |
LPS-PM1310-FC | 1310 nm | 2.5 mW | 20 mA | 1.1 V | - | - | Single Transverse Mode | Ø5.6 mm, PM Pigtail |
L1310P5DFB | 1310 nm | 5 mW | 16 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
LPSC-1310-FC | 1310 nm | 50 mW | 350 mA | 2 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
FPL1053S | 1310 nm | 130 mW | 400 mA | 1.7 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
FPL1053P | 1310 nm | 130 mW | 400 mA | 1.7 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
FPL1053T | 1310 nm | 300 mW (Pulsed) | 750 mA | 2 V | 15° | 28° | Single Transverse Mode | Ø5.6 mm |
FPL1053C | 1310 nm | 300 mW (Pulsed) | 750 mA | 2 V | 15° | 27° | Single Transverse Mode | Chip on Submount |
L1310G1 | 1310 nm | 2000 mW | 5 A | 1.5 V | 7° | 24° | Multimode | Ø9 mm |
L1330P5DFB | 1330 nm | 5 mW | 14 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
L1370G1 | 1370 nm | 2000 mW | 5 A | 1.4 V | 6° | 22° | Multimode | Ø9 mm |
BL1425-PAG500 | 1425 nm | 500 mW | 1600 mA | 2.0 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
BL1436-PAG500 | 1436 nm | 500 mW | 1600 mA | 2.0 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
L1450G1 | 1450 nm | 2000 mW | 5 A | 1.4 V | 7° | 22° | Multimode | Ø9 mm |
BL1456-PAG500 | 1456 nm | 500 mW | 1600 mA | 2.0 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
L1470P5DFB | 1470 nm | 5 mW | 19 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
L1480G1 | 1480 nm | 2000 mW | 5 A | 1.6 V | 6° | 20° | Multimode | Ø9 mm |
L1490P5DFB | 1490 nm | 5 mW | 24 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
L1510P5DFB | 1510 nm | 5 mW | 20 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
L1530P5DFB | 1530 nm | 5 mW | 21 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
LPS-1550-FC | 1550 nm | 1.5 mW | 30 mA | 1.0 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LPS-PM1550-FC | 1550 nm | 1.5 mW | 30 mA | 1.1 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
LP1550-SAD2 | 1550 nm | 2.0 mW | 40 mA | 1.0 V | - | - | Single Frequency | Ø5.6 mm, SM Pigtail |
LP1550-PAD2 | 1550 nm | 2.0 mW | 40 mA | 1.0 V | - | - | Single Frequency | Ø5.6 mm, PM Pigtail |
L1550P5DFB | 1550 nm | 5 mW | 20 mA | 1.0 V | 8° | 10° | Single Frequency | Ø5.6 mm |
ML925B45F | 1550 nm | 5 mW | 30 mA | 1.1 V | 25° | 30° | Single Transverse Mode | Ø5.6 mm |
SFL1550S | 1550 nm | 40 mW | 300 mA | 1.5 V | - | - | Single Frequency | Butterfly, SM Pigtail |
SFL1550P | 1550 nm | 40 mW | 300 mA | 1.5 V | - | - | Single Frequency | Butterfly, PM Pigtail |
LPSC-1550-FC | 1550 nm | 50 mW | 250 mA | 2 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
FPL1009S | 1550 nm | 100 mW | 400 mA | 1.4 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
FPL1009P | 1550 nm | 100 mW | 400 mA | 1.4 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
ULN15PC | 1550 nm | 140 mW | 650 mA | 3.0 V | - | - | Single Frequency | Extended Butterfly, PM Pigtail |
ULN15PT | 1550 nm | 140 mW | 650 mA | 3.0 V | - | - | Single Frequency | Extended Butterfly, PM Pigtail |
FPL1001C | 1550 nm | 150 mW | 400 mA | 1.4 V | 18° | 31° | Single Transverse Mode | Chip on Submount |
FPL1055T | 1550 nm | 300 mW (Pulsed) | 750 mA | 2 V | 15° | 28° | Single Transverse Mode | Ø5.6 mm |
FPL1055C | 1550 nm | 300 mW (Pulsed) | 750 mA | 2 V | 15° | 28° | Single Transverse Mode | Chip on Submount |
L1550G1 | 1550 nm | 1700 mW | 5 A | 1.5 V | 7° | 28° | Multimode | Ø9 mm |
DFB1550 | 1555 nm | 100 mW (Min) | 1000 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DFB1550N | 1555 nm | 130 mW (Min) | 1800 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DFB1550P | 1555 nm | 100 mW (Min) | 1000 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DFB1550PN | 1555 nm | 130 mW (Min) | 1800 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
L1570P5DFB | 1570 nm | 5 mW | 25 mA | 1.0 V | 7° | 9° | Single Frequency | Ø5.6 mm |
L1575G1 | 1575 nm | 1700 mW | 5 A | 1.5 V | 6° | 28° | Multimode | Ø9 mm |
LPSC-1625-FC | 1625 nm | 50 mW | 350 mA | 1.5 V | - | - | Single Transverse Mode | Ø5.6 mm, SM Pigtail |
FPL1054S | 1625 nm | 80 mW | 400 mA | 1.7 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
FPL1054P | 1625 nm | 80 mW | 400 mA | 1.7 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
FPL1054C | 1625 nm | 250 mW (Pulsed) | 750 mA | 2 V | 15° | 28° | Single Transverse Mode | Chip on Submount |
FPL1054T | 1625 nm | 200 mW (Pulsed) | 750 mA | 2 V | 15° | 28° | Single Transverse Mode | Ø5.6 mm |
DFB1642 | 1642 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DFB1642P | 1642 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
DFB1646 | 1646 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DFB1646P | 1646 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
FPL1059S | 1650 nm | 80 mW | 400 mA | 1.7 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
FPL1059P | 1650 nm | 80 mW | 400 mA | 1.7 V | - | - | Single Transverse Mode | Butterfly, PM Pigtail |
DFB1650 | 1650 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DFB1650P | 1650 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
FPL1059C | 1650 nm | 225 mW (Pulsed) | 750 mA | 2 V | 15° | 28° | Single Transverse Mode | Chip on Submount |
FPL1059T | 1650 nm | 225 mW (Pulsed) | 750 mA | 2 V | 15° | 28° | Single Transverse Mode | Ø5.6 mm |
DFB1654 | 1654 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, SM Pigtail |
DFB1654P | 1654 nm | 80 mW | 900 mA (Max) | 3.0 V | - | - | Single Frequency | Butterfly, PM Pigtail |
FPL1940S | 1940 nm | 15 mW | 400 mA | 2 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
FPL2000S | 2 µm | 15 mW | 400 mA | 2 V | - | - | Single Transverse Mode | Butterfly, SM Pigtail |
FPL2000C | 2 µm | 30 mW | 400 mA | 5.2 V | 8° | 19° | Single Transverse Mode | Chip on Submount |
ID3250HHLH | 3.00 - 3.50 µm (DFB) | 5 mW | 400 mA (Max) | 5 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
IF3400T1 | 3.40 µm (FP) | 30 mW | 300 mA | 4 V | 40° | 70° | Single Transverse Mode | Ø9 mm |
ID3750HHLH | 3.50 - 4.00 µm (DFB) | 5 mW | 300 mA (Max) | 5 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QF3850T1 | 3.85 µm (FP) | 200 mW | 600 mA (Max) | 13.5 V | 30° | 40° | Single Transverse Mode | Ø9 mm |
QF3850HHLH | 3.85 µm (FP) | 320 mW (Min) | 1100 mA (Max) | 13 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Transverse Mode | Horizontal HHL |
QF4040HHLH | 4.05 µm (FP) | 320 mW (Min) | 1100 mA (Max) | 13 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Transverse Mode | Horizontal HHL |
QD4500CM1 | 4.00 - 5.00 µm (DFB) | 40 mW | 500 mA (Max) | 10.5 V | 30° | 40° | Single Frequency | Two-Tab C-Mount |
QD4500HHLH | 4.00 - 5.00 µm (DFB) | 80 mW | 500 mA (Max) | 11 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QF4050T2 | 4.05 µm (FP) | 70 mW | 250 mA | 12 V | 30° | 40° | Single Transverse Mode | Ø9 mm |
QF4050C2 | 4.05 µm (FP) | 300 mW | 400 mA | 12 V | 30 | 42 | Single Transverse Mode | Two-Tab C-Mount |
QF4050T1 | 4.05 µm (FP) | 300 mW | 600 mA (Max) | 12.0 V | 30° | 40° | Single Transverse Mode | Ø9 mm |
QF4050D2 | 4.05 µm (FP) | 800 mW | 750 mA | 13 V | 30° | 40° | Single Transverse Mode | D-Mount |
QF4050D3 | 4.05 µm (FP) | 1200 mW | 1000 mA | 13 V | 30° | 40° | Single Transverse Mode | D-Mount |
QD4472HH | 4.472 µm (DFB) | 85 mW | 500 mA (Max) | 11 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QF4600T2 | 4.60 µm (FP) | 200 mW | 500 mA (Max) | 13.0 V | 30° | 40° | Single Transverse Mode | Ø9 mm |
QF4600T1 | 4.60 µm (FP) | 400 mW | 800 mA (Max) | 12.0 V | 30° | 40° | Single Transverse Mode | Ø9 mm |
QF4600C2 | 4.60 µm (FP) | 600 mW | 600 mA | 12 V | 30° | 42° | Single Transverse Mode | Two-Tab C-Mount |
QF4600T3 | 4.60 µm (FP) | 1000 mW | 800 mA (Max) | 13 V | 30° | 40° | Single Transverse Mode | Ø9 mm |
QF4600D4 | 4.60 µm (FP) | 2500 mW | 1800 mA | 12.5 V | 40° | 30° | Single Transverse Mode | D-Mount |
QF4600D3 | 4.60 µm (FP) | 3000 mW | 1700 mA | 12.5 V | 30° | 40° | Single Transverse Mode | D-Mount |
QD4602HH | 4.602 µm (DFB) | 150 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QF4650HHLH | 4.65 µm (FP) | 1500 mW (Min) | 1100 mA | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Transverse Mode | Horizontal HHL |
QD5500CM1 | 5.00 - 6.00 µm (DFB) | 40 mW | 700 mA (Max) | 9.5 V | 30° | 45° | Single Frequency | Two-Tab C-Mount |
QD5500HHLH | 5.00 - 6.00 µm (DFB) | 150 mW | 500 mA (Max) | 11 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD5250C2 | 5.20 - 5.30 µm (DFB) | 60 mW | 700 mA (Max) | 9.5 V | 30° | 45° | Single Frequency | Two-Tab C-Mount |
QD5263HH | 5.263 µm (DFB) | 130 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD6500CM1 | 6.00 - 7.00 µm (DFB) | 40 mW | 650 mA (Max) | 10 V | 35° | 50° | Single Frequency | Two-Tab C-Mount |
QD6500HHLH | 6.00 - 7.00 µm (DFB) | 80 mW | 600 mA (Max) | 11 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD6134HH | 6.134 µm (DFB) | 50 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD7500CM1 | 7.00 - 8.00 µm (DFB) | 40 mW | 600 mA (Max) | 10 V | 40° | 50° | Single Frequency | Two-Tab C-Mount |
QD7500HHLH | 7.00 - 8.00 µm (DFB) | 50 mW | 700 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD7500DM1 | 7.00 - 8.00 µm (DFB) | 100 mW | 600 mA (Max) | 11.5 V | 40° | 55° | Single Frequency | D-Mount |
QD7416HH | 7.416 µm (DFB) | 100 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD7716HH | 7.716 µm (DFB) | 30 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QF7900HB | 7.9 µm (FP) | 700 mW | 1600 mA (Max) | 9 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Transverse Mode | Horizontal HHL |
QD7901HH | 7.901 µm (DFB) | 50 mW | 700 mA (Max) | 10 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD8050CM1 | 8.00 - 8.10 µm (DFB) | 100 mW | 1000 mA (Max) | 9.5 V | 55° | 70° | Single Frequency | Two-Tab C-Mount |
QD8500CM1 | 8.00 - 9.00 µm (DFB) | 100 mW | 900 mA (Max) | 9.5 V | 40° | 55° | Single Frequency | Two-Tab C-Mount |
QD8500HHLH | 8.00 - 9.00 µm (DFB) | 100 mW | 600 mA (Max) | 10.2 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QF8450C2 | 8.45 µm (FP) | 300 mW | 750 mA | 9 V | 40° | 60° | Single Transverse Mode | Two-Tab C-Mount |
QF8500HB | 8.5 µm (FP) | 500 mW | 2000 mA (Max) | 9 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Transverse Mode | Horizontal HHL |
QD8650CM1 | 8.60 - 8.70 µm (DFB) | 50 mW | 900 mA (Max) | 9.5 V | 55° | 70° | Single Frequency | Two-Tab C-Mount |
QD8912HH | 8.912 µm (DFB) | 150 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD9500CM1 | 9.00 - 10.00 µm (DFB) | 60 mW | 800 mA (Max) | 9.5 V | 40° | 55° | Single Frequency | Two-Tab C-Mount |
QD9500HHLH | 9.00 - 10.00 µm (DFB) | 100 mW | 600 mA (Max) | 10.2 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD9062HH | 9.062 µm (DFB) | 130 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QF9150C2 | 9.15 µm (FP) | 200 mW | 850 mA | 11 V | 40° | 60° | Single Transverse Mode | Two-Tab C-Mount |
QF9200HB | 9.2 µm (FP) | 250 mW | 2000 mA (Max) | 9 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Transverse Mode | Horizontal HHL |
QF9500T1 | 9.5 µm (FP) | 300 mW | 550 mA | 12 V | 40° | 55° | Single Transverse Mode | Ø9 mm |
QD9550C2 | 9.50 - 9.60 µm (DFB) | 60 mW | 800 mA (Max) | 9.5 V | 40° | 55° | Single Frequency | Two-Tab C-Mount |
QF9550CM1 | 9.55 µm (FP) | 80 mW | 1500 mA | 7.8 V | 35° | 60° | Single Transverse Mode | Two-Tab C-Mount |
QD9697HH | 9.697 µm (DFB) | 80 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD10500CM1 | 10.00 - 11.00 µm (DFB) | 40 mW | 600 mA (Max) | 10 V | 40° | 55° | Single Frequency | Two-Tab C-Mount |
QD10500HHLH | 10.00 - 11.00 µm (DFB) | 50 mW | 700 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD10530HH | 10.530 µm (DFB) | 50 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD10549HH | 10.549 µm (DFB) | 60 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
QD10622HH | 10.622 µm (DFB) | 60 mW | 1000 mA (Max) | 12 V | 6 mrad (0.34°) | 6 mrad (0.34°) | Single Frequency | Horizontal HHL |
The rows shaded green above denote single-frequency lasers. |
Item # | Info | Wavelength | Powera,b | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodec |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L375P70MLDd | 375 nm | 70 mW | 110 mA / 140 mA | Ø5.6 mm | F | Yes | - | No | Single Transverse Mode | |
L404P400M | 404 nm | 400 mW | 370 mA / 410 mA | Ø5.6 mm | G | No | S7060R | No | Multimode | |
L405P20 | 405 nm | 20 mW | 38 mA / 55 mA | Ø5.6 mm | B | Yes | S7060R | No | Single Transverse Mode | |
L405G2e | 405 nm | 35 mW | 50 mA / 75 mA | Ø3.8 mm | G | No | S038S | Yes | Single Transverse Mode | |
DL5146-101S | 405 nm | 40 mW | 70 mA / 100 mA | Ø5.6 mm | B | Yes | S7060R | No | Single Transverse Mode | |
L405A1 | 405 nm | 175 mW (Min) |
150 mA / 200 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L405G1 | 405 nm | 1000 mW | 900 mA / 1200 mA | Ø9 mm | G | No | S8060 | No | Multimode |
Item # | Info | Wavelength | Powera,b | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodec |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L450G3 | 450 nm | 100 mW (Min) |
80 mA / 110 mA | Ø3.8 mm | G | No | S038S | No | Single Transverse Mode | |
L450G2 | 450 nm | 100 mW (Min) |
80 mA / 110 mA | Ø5.6 mm | G | No | S7060R | No | Single Transverse Mode | |
L450P1600MM | 450 nm | 1600 mW | 1200 mA / 1500 mA | Ø5.6 mm | G | No | S7060R | No | Multimode | |
L473P100 | 473 nm | 100 mW | 120 mA / 150 mA | Ø5.6 mm | F+d | Yes | - | No | Single Transverse Mode | |
L488P60 | 488 nm | 60 mW | 75 mA / 110 mA | Ø5.6 mm | B | Yes | S7060R | No | Single Transverse Mode | |
L515A1 | 515 nm | 10 mW | 50 mA / 100 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L520A1 | 520 nm | 30 mW (Min) |
80 mA / 100 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
PL520 | 520 nm | 50 mW | 150 mA / 160 mA | Ø3.8 mm | G | No | S038S | No | Single Transverse Mode | |
L520P50 | 520 nm | 50 mW | 150 mA / 160 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L520A2 | 520 nm | 110 mW (Min) | 225 mA / 330 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
HL63163DG | 633 nm | 100 mW | 170 mA / 230 mA | Ø5.6 mm | G | No | S7060R | No | Single Transverse Mode | |
L635P5 | 635 nm | 5 mW | 30 mA / 45 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6312G | 635 nm | 5 mW | 50 mA / 85 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
HL6320G | 635 nm | 10 mW | 60 mA / 95 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
HL6322G | 635 nm | 15 mW | 75 mA / 100 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L637P5 | 637 nm | 5 mW | 20 mA / 25 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
HL63142DG | 637 nm | 100 mW | 140 mA / 180 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL63133DG | 637 nm | 170 mW | 250 mA / 320 mA | Ø5.6 mm | G | No | S7060R | No | Single Transverse Mode | |
HL6388MG | 637 nm | 250 mW | 340 mA / 430 mA | Ø5.6 mm | H | No | S7060R | No | Multimode | |
L637G1 | 637 nm | 1200 mW | 1100 mA / 1500 mA | Ø9 mmc | G | No | Customc | No | Multimode | |
L638P040 | 638 nm | 40 mW | 92 mA / 115 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L638P150 | 638 nm | 150 mW | 230 mA / 300 mA | Ø3.8 mm | G | No | S038S | No | Single Transverse Mode | |
L638P200 | 638 nm | 200 mW | 280 mA / 330 mA | Ø5.6 mm | G | No | S7060R | No | Single Transverse Mode | |
L638P700M | 638 nm | 700 mW | 820 mA / 1000 mA | Ø5.6 mm | G | No | S7060R | No | Multimode | |
HL6358MG | 639 nm | 10 mW | 40 mA / 50 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6323MG | 639 nm | 30 mW | 100 mA / 130 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
HL6362MG | 640 nm | 40 mW | 90 mA / 110 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6364DG | 642 nm | 60 mW | 120 mA / 155 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6366DG | 642 nm | 80 mW | 150 mA / 175 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6385DG | 642 nm | 150 mW | 250 mA / 350 mA | Ø5.6 mm | H | No | S7060R | No | Single Transverse Mode | |
L650P007 | 650 nm | 7 mW | 28 mA / 35 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6501MG | 658 nm | 30 mW | 75 mA / 120 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
L658P040 | 658 nm | 40 mW | 75 mA / 110 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6544FM | 660 nm | 50 mW | 115 mA / 135 mA | Ø5.6 mm | G | No | S7060R | No | Single Transverse Mode | |
HL6545MG | 660 nm | 120 mW | 170 mA / 210 mA | Ø5.6 mm | H | No | S7060R | No | Single Transverse Mode | |
L660P120 | 660 nm | 120 mW | 175 mA / 210 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L670VH1 | 670 nm | 1 mW | 2.5 mA / 2.8 mA | TO-46 | H | No | S8060 | No | Single Transverse Mode | |
HL6748MG | 670 nm | 10 mW | 30 mA / 45 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6714G | 670 nm | 10 mW | 55 mA / 90 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
HL6756MG | 670 nm | 15 mW | 35 mA / 45 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
HL6750MG | 685 nm | 50 mW | 70 mA / 120 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
HL6738MG | 690 nm | 30 mW | 85 mA / 115 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
HL7001MG | 705 nm | 40 mW | 75 mA / 100 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
HL7302MG | 730 nm | 40 mW | 75 mA / 100 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L760VH1 | 760 nm | 0.5 mW | 3 mA (Max) | TO-46 | H | No | S8060 or S8060-4 | No | Single Frequencyc | |
L763VH1 | 763 nm | 0.5 mW | 3 mA (Max) | TO-46 | H | No | S8060 or S8060-4 | No | Single Frequencyc | |
L780P010 | 780 nm | 10 mW | 24 mA / 40 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L785P5 | 785 nm | 5 mW | 28 mA / 40 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L785P25 | 785 nm | 25 mW | 45 mA / 60 mA | Ø5.6 mm | B | Yes | S7060R | No | Single Transverse Mode | |
L785P090 | 785 nm | 90 mW | 125 mA / 165 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
LD785-SEV300d | 785 nm | 300 mW | 500 mA (Max)e | Ø9 mmf | E | No | S8060 or S8060-4 | Yes | Single Frequencyc | |
LD785-SH300g | 785 nm | 300 mW | 400 mA / 450 mA | Ø9 mm | H | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
LD785-SE400g | 785 nm | 400 mW | 550 mA / 600 mA | Ø9 mm | E | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
L795VH1 | 795 nm | 0.25 mW | 1.2 mA / 1.5 mA | TO-46 | H | No | S8060 or S8060-4 | No | Single Frequencyc |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
M9-808-0150 | 808 nm | 150 mW | 180 mA / 220 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
L808P200 | 808 nm | 200 mW | 260 mA / 300 mA | Ø5.6 mm | A | Yes | S7060R | No | Multimode | |
L808H1 | 808 nm | 300 mW | 400 mA / 450 mA | Ø9 mm | H | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
L808P500MM | 808 nm | 500 mW | 650 mA / 700 mA | Ø5.6 mm | A | Yes | S7060R | No | Multimode | |
LD808-SE500c | 808 nm | 500 mW | 750 mA / 800 mA | Ø9 mmd | E | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
LD808-SEV500e | 808 nm | 500 mW | 800 mA (Max)f | Ø9 mmd | E | No | S8060 or S8060-4 | Yes | Single Frequencyg | |
L808P1000MM | 808 nm | 1000 mW | 1100 mA / 1500 mA | Ø9 mm | E | No | S8060 or S8060-4 | No | Multimode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L820P100 | 820 nm | 100 mW | 145 mA / 210 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
L820P200 | 820 nm | 200 mW | 250 mA / 340 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
HL8338MG | 830 nm | 50 mW | 75 mA / 100 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
L830H1 | 830 nm | 250 mW | 400 mA (Max) | Ø9 mm | H | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
LD830-SE650c | 830 nm | 650 mW | 900 mA / 1050 mA | Ø9 mmd | E | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
LD830-MA1W | 830 nm | 1000 mW | 2000 mA (Max) | Ø9 mm | A | Yes | S8060 or S8060-4 | Yes | Multimode | |
LD830-ME2W | 830 nm | 2000 mW | 3 A (Max) | Ø9 mmd | E | No | S8060 or S8060-4 | Yes | Multimode | |
L840P200 | 840 nm | 200 mW | 255 mA / 340 mA | Ø5.6 mm | C | Yes | S7060R | No | Single Transverse Mode | |
L850VH1 | 850 nm | 1 mW | 6 mA (Max) | TO-46 | H | No | S8060 | No | Single Frequencye | |
L850P010 | 850 nm | 10 mW | 50 mA / 70 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L850P030 | 850 nm | 30 mW | 65 mA / 95 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L852P50 | 852 nm | 50 mW | 75 mA / 100 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L852P100 | 852 nm | 100 mW | 120 mA / 170 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
L852P150 | 852 nm | 150 mW | 170 mA / 220 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
L852SEV1f | 852 nm | 270 mW | 350 mA / 400 mAg | Ø9 mmd | E | No | S8060 or S8060-4 | Yes | Single Frequencye | |
L852H1 | 852 nm | 300 mW | 415 mA (Max) | Ø9 mm | H | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
LD852-SE600c | 852 nm | 600 mW | 950 mA / 1050 mA | Ø9 mmd | E | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
LD852-SEV600f | 852 nm | 600 mW | 1050 mA (Max)g | Ø9 mmd | E | No | S8060 or S8060-4 | Yes | Single Frequencye | |
L880P010 | 880 nm | 10 mW | 30 mA / 40 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L895VH1 | 895 nm | 0.2 mW | 1.4 mA / 2.0 mA | TO-46 | H | No | S8060 or S8060-4 | No | Single Frequencye |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L904P010 | 904 nm | 10 mW | 50 mA / 70 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
M9-940-0200 | 940 nm | 200 mW | 270 mA / 320 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
L960H1 | 960 nm | 250 mW | 400 mA / 430 mA | Ø9 mm | H | No | S8060 or S8060-4 | Yes | Single Transverse Mode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L976SEV1c | 976 nm | 270 mW | 350 mA / 400 mAd | Ø9 mme | E | No | S8060 or S8060-4 | Yes | Single Frequencyf | |
L980P010 | 980 nm | 10 mW | 25 mA / 40 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L980P030 | 980 nm | 30 mW | 50 mA / 70 mA | Ø5.6 mm | A | Yes | S7060R | No | Single Transverse Mode | |
L980P100A | 980 nm | 100 mW | 150 mA / 190 mA | Ø5.6 mm | A | Yes | S7060R | No | Multimode | |
L980H1 | 980 nm | 200 mW | 300 mA (Max) | Ø9 mm | H | No | S8060 or S8060-4 | Yes | Single Transverse Modeg | |
L980P200 | 980 nm | 200 mW | 300 mA / 400 mA | Ø5.6 mm | A | Yes | S7060R | No | Multimode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
M9-A64-0200 | 1064 nm | 200 mW | 280 mA / 350 mA | Ø9 mm | A | Yes | S8060 or S8060-4 | No | Single Transverse Mode | |
L1064H1 | 1064 nm | 300 mW | 700 mA / 900 mA | Ø9 mm | H | No | S8060 or S8060-4 | Yes | Single Transverse Mode | |
L1064H2 | 1064 nm | 450 mW | 1100 mA / 1200 mA | Ø9 mm | E | No | S8060 or S8060-4 | No | Single Transverse Mode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L1270P5DFBc | 1270 nm | 5 mW | 15 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1290P5DFBc | 1290 nm | 5 mW | 16 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1310P5DFBc | 1310 nm | 5 mW | 16 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
FPL1053Te | 1310 nm | 300 mW (Pulsed) | 750 mA / 1000 mA | Ø5.6 mm | E | No | S7060R | No | Single Transverse Mode | |
L1310G1 | 1310 nm | 2000 mW | 5 A / 8 A | Ø9 mm | G | No | S8060 or S8060-4 | No | Multimode | |
L1330P5DFBc | 1330 nm | 5 mW | 14 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1370G1 | 1370 nm | 2000 mW | 5 A / 8 A | Ø9 mm | G | No | S8060 or S8060-4 | No | Multimode | |
L1450G1 | 1450 nm | 2000 mW | 5 A / 8 A | Ø9 mm | G | No | S8060 or S8060-4 | No | Multimode | |
L1470P5DFBc | 1470 nm | 5 mW | 19 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1480G1 | 1480 nm | 2000 mW | 5 A / 8 A | Ø9 mm | G | No | S8060 or S8060-4 | No | Multimode |
Item # | Info | Wavelength | Powera | Typical/Max Drive Currenta |
Package | Pin Code | Monitor Photodiodeb |
Compatible Socket |
Wavelength Tested |
Laser Mode |
---|---|---|---|---|---|---|---|---|---|---|
L1490P5DFBc | 1490 nm | 5 mW | 24 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1510P5DFBc | 1510 nm | 5 mW | 20 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1530P5DFBc | 1530 nm | 5 mW | 21 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1550P5DFBc | 1550 nm | 5 mW | 20 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
ML925B45F | 1550 nm | 5 mW | 30 mA / 50 mA | Ø5.6 mm | D | Yes | - | No | Single Transverse Mode | |
FPL1055Te | 1550 nm | 300 mW (Pulsed) | 750 mA / 1000 mA | Ø5.6 mm | E | No | S7060R | No | Single Transverse Mode | |
L1550G1 | 1550 nm | 1700 mW | 5 A / 8 A | Ø9 mm | G | No | S8060 or S8060-4 | No | Multimode | |
L1570P5DFBc | 1570 nm | 5 mW | 25 mA / 40 mA | Ø5.6 mm | D | Yes | - | Yes | Single Frequencyd | |
L1575G1 | 1575 nm | 1700 mW | 5 A / 8 A | Ø9 mm | G | No | S8060 or S8060-4 | No | Multimode | |
FPL1054Te | 1625 nm | 200 mW (Pulsed) | 750 mA / 1000 mA | Ø5.6 mm | E | No | S7060R | No | Single Transverse Mode | |
FPL1059Te | 1650 nm | 225 mW (Pulsed) | 750 mA / 1000 mA | Ø5.6 mm | E | No | S7060R | No | Single Transverse Mode |