Communication & Data Transmission Lasers:

High-Performance Solutions for High-Speed, Seamless Data/Telecom

          • Designed for Precision in Fiber Optic Networks & Free-Space Communications
          • Reliable, Customizable Platforms for Diverse Applications
          • Broad Selection of Technologies and Configurations

We’re experts at helping select the right configuration for you!

Why Choose a Datacom / Telecom Laser?

simple line art of four computer endpoints networked together with a center switch or server

Designed for Precision in Fiber Optic Networks & Free-Space Communications
    • Telecom wavelengths: 1310 & 1550nm for minimal fiber attenuation & “eye safe” options
    • Single spatial mode & single-frequency lasers for efficient dense wavelength multiplexing
    • Narrow linewidth options ensure high spectral stability & reduced signal interference

gear arrow and puzzle pieces representing highly flexible and easily integrated lasers

Reliable, Customizable Platforms for Diverse Applications
    • Telcordia grade fiber amplifiers & CW lasers tailored to your specifications
    • High-power solutions with customizable configurations: polarization, gain, outputs
    • Seamless integration with free-space, fiber-coupled & turnkey designs

simple line art illustrating many choices and options

Broad Selection of Technologies & Configurations
    • Components to OEM to turnkey – Many packaging options including custom solutions
    • Diode & CW fiber lasers & amplifiers, mW to >100W – short & long-haul communications
    • Modular designs ensure scalability for telecom, free-space, and RF data links

Over the last 30 years, RPMC has fielded thousands of communication & data transmission lasers, built to endure the toughest conditions, delivering reliable performance from the shop floor to outdoor environments. Designed to withstand humidity, heat, dust, and vibration, these lasers provide consistent output with low maintenance, ensuring your operations run smoothly. With a versatile range of power, energy, and wavelength options, our lasers can be tailored to meet the specific demands of your application, from precision tasks to high-power throughput. We’re not just providing a product—we’re partnering with you to find the perfect solution and support you through every stage of your project, dedicated to helping you achieve long-term success.

Let us help define the right solution for you!

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Picture Part Number Wavelength (nm) Description Type
various configurations of compact, lightweight optical fiber amplifiers BK-FA-CW 1030-2054 Fiber Amplifiers, CW, 1030-2054 nm, -14 to +15 dBm input, up to 40 W output Narrow Linewidth, "Eye Safe", Turn-Key System
FL CW/CW Modulated Series BK-FL-CW 1060-2050 Fiber Laser, Single mode, 1060-2050nm, up to 100W CW Fiber Lasers, Broadband Lasers, Narrow Linewidth, "Eye Safe", Customizable
LDX LDX-IR-FC 750, 780, 797, 808, 830, 860, 915, 980, 1064, 1120, 1210, 1280, 1370 Laser Diode, Multimode, Fiber-coupled, Infrared, 750-1400nm, up to 12.8W Single Emitter, Fiber-Coupled, Made in the USA
LDX-IR-FS 750, 780, 797, 808, 830, 860, 915, 980, 1064, 1120, 1210, 1280, 1370 Laser Diode, Multimode, Infrared, 750-1400nm, up to 16W Single Emitter, Made in the USA
LDX LDX-SWIR-FC 1470, 1550, 1620, 1640, 1675, 1850 Laser Diode, Multimode, Fiber-coupled, SWIR, 1400-3000nm, up to 5.6W Single Emitter, "Eye Safe", Fiber-Coupled, Made in the USA
LDX-SWIR-FS 1470, 1550, 1620, 1675, 1850 Laser Diode, Multimode, SWIR, 1400-3000nm, up to 7W Single Emitter, "Eye Safe", Made in the USA
LDX LDX-VIS-FC 445, 520, 622, 630, 660, 685, 735, 750 Laser Diode, Multimode, Fiber-coupled, Visible, 400-750nm, up to 4W Single Emitter, Fiber-Coupled, Made in the USA
LDX-VIS-FS 445, 520, 622, 630, 660, 685, 735, 750 Laser Diode, Multimode, Visible, 400-750nm, up to 5W Single Emitter, Made in the USA
LGR-XXX 543, 594, 633 He-Ne Laser Replacement Tube, Single mode, 543-633nm, up to 20mW HeNe Lasers, Narrow Linewidth, Long Coherence Length, Single Longitudinal Mode (SLM), Collimated Beam, Fiber-Coupled
REPXXXX-DM 759-764, 1260-1310, 1500-1560, 1560-1600, 1635-1670, 1720-1770, 2300-2333 Laser Diode, Stabilized, 1278-2327nm, up to 20mW LD Module, Single Emitter, DFB, Narrow Linewidth, Single Longitudinal Mode (SLM), Fiber-Coupled
REPXXXX-FP 759-764, 1260-1310, 1500-1560, 1560-1600, 1635-1670, 1720-1770, 2300-2333 Laser Diode, Single mode, 1280-2300nm, up to 20mW LD Module, Single Emitter, "Eye Safe", Fiber-Coupled
RPK-IR-MM 793, 808, 976, 1064 Laser Diode, Multimode, Fiber-coupled, 793nm-1940nm, up to 300W Single Emitter, Multi-Emitter, Fiber-Coupled
RPK-IR-STAB 785, 808, 878, 976, 1064 Laser Diode, Wavelength Stabilized, Fiber-coupled, Infrared, 760-1400nm, up to 430W Multi-Emitter, VBG, Narrow Linewidth, Single Longitudinal Mode (SLM), Fiber-Coupled
RPK-TK 405, 445, 520, 635, 660, 690, 785, 808, 830, 915, 976, 1064 Laser Diode, Wavelength Stabilized, Fiber-coupled, 405-1064nm, up to 300W Multi-Emitter, Fiber-Coupled, Turn-Key System
RPK-VIS-MM 405, 525, 635 Laser Diode, Multimode, Fiber-coupled, Visible, 400-750nm, up to 200W Single Emitter, Multi-Emitter, Fiber-Coupled
RWLD 5.5mm Package Laser Diode RWLD-DFB 1064, 1270, 1460, 1485, 1660 Laser Diode, Wavelength Stabilized, SWIR, 1270-1600nm, up to 30mW Single Emitter, DFB, Narrow Linewidth, Single Longitudinal Mode (SLM)
RWLD 5.5mm Package Laser Diode RWLD-IR-MM 760, 780, 808, 850, 880, 915, 940, 980, 1064 Laser Diode, Multimode, Infrared, 760-1064nm, up to 20W Single Emitter
RWLD 5.5mm Package Laser Diode RWLD-IR-SM 760, 780, 808, 850, 880, 915, 940, 980, 1064 Laser Diode, Single mode, Infrared, 760-1400nm, up to 300mW Single Emitter
RWLD 5.5mm Package Laser Diode RWLD-SWIR-MM 1064, 1460, 1535, 1555 Laser Diode, Multimode, SWIR, 1450-1920nm, up to 3W Single Emitter, "Eye Safe"
RWLD 5.5mm Package Laser Diode RWLD-VIS-MM 445, 520, 635, 660 Laser Diode, Multimode, Visible, 445-660nm, up to 3W Single Emitter
RWLD 5.5mm Package Laser Diode RWLD-VIS-SM 405, 460, 480, 488, 495, 505, 510, 520, 635, 650, 660 Laser Diode, Single mode, Visible, 445-660nm, up to 300mW Single Emitter
RWLP-445-030m-4: 445nm Fiber Coupled Laser Diode RWLP-DFB 1270, 1310, 1410, 1460 Laser Diode, Wavelength Stabilized, Fiber-coupled, SWIR, 1270-1460nm, up to 100mW Single Emitter, DFB, Narrow Linewidth, Single Longitudinal Mode (SLM), Fiber-Coupled
RWLP-445-030m-4: 445nm Fiber Coupled Laser Diode RWLP-IR-MM 1064 Laser Diode, Multimode, Fiber-coupled, Infrared, 750-1400nm, up to 12W Single Emitter, Fiber-Coupled
RWLP-445-030m-4: 445nm Fiber Coupled Laser Diode RWLP-IR-SM 1064 Laser Diode, Single mode, Fiber-coupled, Infrared, 785-1310nm, up to 100mW Single Emitter, Fiber-Coupled
WSLP-1550-002m-9-DFB-ISO RWLP-SWIR-MM 1460 Laser Diode, Multimode, Fiber-coupled, SWIR, 1450-1570nm, up to 12W Single Emitter, "Eye Safe", Fiber-Coupled
RWLP-445-030m-4: 445nm Fiber Coupled Laser Diode RWLP-UV-MM 375 Laser Diode, Multimode, Fiber-coupled, Ultraviolet, 375nm, up to 100W Single Emitter, Fiber-Coupled
RWLP-445-030m-4: 445nm Fiber Coupled Laser Diode RWLP-VIS-MM 405, 445, 520, 660 Laser Diode, Multimode, Fiber-coupled, Visible, 405-660nm, up to 12W Single Emitter, Fiber-Coupled
RWLP-445-030m-4: 445nm Fiber Coupled Laser Diode RWLP-VIS-SM 405, 445, 520, 660 Laser Diode, Single mode, Fiber-coupled, Visible, 400-660nm, up to 100mW Single Emitter, Fiber-Coupled
brass colored laser diode housing with 14 pins and a fiber attached SMX-DFB 1310, 1550 Laser Diode, Wavelength Stabilized, 1310nm or 1550nm, up to 100mW Single Emitter, DFB, Narrow Linewidth, Single Longitudinal Mode (SLM), "Eye Safe", Fiber-Coupled, Made in the USA
SMX-MM 1310, 1350, 1450, 1470, 1550, 1650, 1940 Laser Diode, Multimode, 1310-1940nm, up to 75W Single Emitter, Triple-Junction, "Eye Safe", Fiber-Coupled, Made in the USA
SMX-SM 1310, 1470, 1550, 1625, 1640, 1650, 1660 Laser Diode, Single mode, 1310-1670nm, up to 800mW Single Emitter, "Eye Safe", Fiber-Coupled, Made in the USA
chip on carrier, straight, tilted, and curved waveguide chips, and a 14-pin butterfly package for semiconductor optical amplifiers SOAs SMX-SOA 1310, 1550 Semiconductor Optical Amplifier, SOA/RSOA, Fiber-coupled or Free Space, 1310nm or 1550nm, Up to 450mW "Eye Safe", Fiber-Coupled, Made in the USA, Customizable

RPMC’s Communication and Data Transmission Lasers offer industry-leading performance tailored for the demands of modern fiber optic and free-space communication systems. Featuring telecom-standard wavelengths like 1550nm and 1310nm, including eye-safe 1.5µm options, our lasers deliver high spectral purity and minimal attenuation, essential for dense wavelength multiplexing and long-distance transmission. With technologies ranging from CW lasers and DFB diodes to high-power fiber amplifiers, RPMC ensures precision, stability, and reliability. Customizable configurations, including free-space or fiber-coupled designs, cater to diverse applications like telecommunications, RF data transmission, and optical transport networks. Our lasers are engineered to meet Telcordia standards, providing trusted solutions for high-speed data transmission and robust network infrastructure.

Let Us Help

With 1000s of fielded units, and over 25 years of experience, providing OEMs, contract manufacturers, and researchers with the best laser solution for their application, our expert team is ready to help! Working with RPMC ensures you are getting trusted advice from our knowledgeable and technical staff on a wide range of laser products.  RPMC and our manufacturers are willing and able to provide custom solutions for your unique application.

If you have any questions, or if you would like some assistance please contact us. Furthermore, you can email us at [email protected] to talk to a knowledgeable Product Manager.

Check out our Online Store: This page contains In-Stock products and an ever-changing assortment of various types of new lasers at marked-down/discount prices.

We’re experts at helping select the right configuration for you!

Component FAQs
Can I operate multiple laser diodes from the same power supply?

Can I operate multiple laser diodes from the same power supply?

The same power supply can drive multiple laser diodes if they are connected in series, but they must never be connected in parallel. When two diodes are connected in series, they will function properly as long as the compliance voltage is large enough to cover the voltage drop across each diode. For example, suppose you are trying to power two diode lasers, each with an operating voltage of 1.9 V, and connect the two in series. In that case, the pulsed or CW laser driver must have a total voltage capacity greater than 3.8 V. This configuration works because diodes share the same current when connected in series. In contrast, when two diodes are connected in parallel, the current is no longer shared between the two diodes. Get more details on the topic in this article: “Can I Operate Multiple Laser Diodes From the Same Power Supply?” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

Can laser diodes emit green, blue, or UV light?

Can laser diodes emit green, blue, or UV light?

The output wavelength of a semiconductor laser is based on the difference in energy between the valance and conduction bands of the material (bandgap energy). Since the energy of a photon is inversely proportional to its wavelength, this means that a larger bandgap energy will result in a shorter emission wavelength. Due to the relatively wide bandgap energy of 3.4 eV, gallium nitride (GaN) is ideal for the production of semiconductor optoelectronic devices, producing blue wavelength light without the need for nonlinear crystal harmonic generation. Since the mid-’90s, GaN substrates have been the common material utilized for blue LEDs. In recent years, GaN based laser technology has provided blue, green and UV laser diodes, now available in wavelengths from 375 nm to 521 nm, with output powers exceeding 100 watts. Read our article, titled “Gallium Nitride (GaN) Laser Diodes: Green, Blue, and UV Wavelengths” to learn more about GaN Based Laser Diodes, available through RPMC. Get more information from our Lasers 101, Blogs, Whitepapers, and FAQs pages in our Knowledge Center!

How long will a laser diode last?
How long will a laser diode last?

Honestly, it depends on several factors, and there is no simple chart to cover everything. Typical diode lifetimes are in the range of 25,000 to 50,000 hours. Though, there are lifetime ratings outside this range, depending on the configuration. Furthermore, there are a wide range of degradation sources that contribute to a shorter lifespan of laser diodes. These degradation sources include dislocations that affect the inner region, metal diffusion and alloy reactions that affect the electrode, solder instability (reaction and migration) that affect the bonding parts, separation of metals in the heatsink bond, and defects in buried heterostructure devices. Read more about diode lifetime and contributing factors in this article: “Understanding Laser Diode Lifetime.” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

What factors affect the lifetime of laser diodes?
What factors affect the lifetime of laser diodes?

There are a great many factors that can increase or decrease the lifetime of a laser diode. One of the main considerations is thermal management. Mounting or heatsinking of the package is of tremendous importance because operating temperature strongly influences lifetime and performance. Other factors to consider include electrostatic discharge (ESD), voltage and current spikes, back reflections, flammable materials, noxious substances, outgassing materials (even thermal compounds), electrical connections, soldering method and fumes, and environmental considerations including ambient temperature, and contamination from humidity and dust. Read more about these critical considerations and contributing factors in this article: “How to Improve Laser Diode Lifetime: Advice and Precautions on Mounting.” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

What is a laser diode?
What is a laser diode?

A Laser Diode or semiconductor laser is the simplest form of Solid-State Laser. Laser diodes are commonly referred to as edge emitting laser diodes because the laser light is emitted from the edge of the substrate. The light emitting region of the laser diode is commonly called the emitter. The emitter size and the number of emitters determine output power and beam quality of a laser diode. Electrically speaking, a laser diode is a PIN diode. The intrinsic (I) region is the active region of the laser diode. The N and P regions provide the active region with the carriers (electrons and holes). Initially, research on laser diodes was carried out using P-N diodes. However, all modern laser diodes utilize the double-hetero-structure implementation. This design confines the carriers and photons, allowing a maximization of recombination and light generation. If you want to start reading more about laser diodes, try this whitepaper “How to Improve Laser Diode Lifetime.” If you want to read more about the Laser Diode Types we offer, check out the Overview of Laser Diodes section on our Lasers 101 Page!

What is the difference between laser diodes and VCSELs?
What is the difference between laser diodes and VCSELs?

Laser Diodes and VCSELs are semiconductor lasers,  the simplest form of Solid State Lasers.  Laser diodes are commonly referred to as edge emitting laser diodes because the laser light is emitted from the edge of the substrate. The light emitting region of the laser diode is commonly called the emitter.  The emitter size and the quantity of emitters determine output power and beam quality of a laser diode. These Fabry Perot Diode Lasers with a single emission region (Emitter) are typically called laser diode chips, while a linear array of emitters is called laser diode bars. Laser diode bars typically use multimode emitters, the number of emitters per substrate can vary from 5 emitters to 100 emitters. VCSELs (Vertical Cavity Surface Emitting Laser) emit light perpendicular to the mounting surface as opposed to parallel like edge emitting laser diodes.  VCSELs offer a uniform spatial illumination in a circular illumination pattern with low speckle. If you want to read more about lasers in general, and help narrowing down the selection to find the right laser for you, check out our Knowledge Center for our Blogs, Whitepapers, and FAQ pages, as well as our Lasers 101 Page!VCSEL

What’s the difference between single transverse mode & single longitudinal mode?

What’s the difference between single transverse mode & single longitudinal mode?

Within the laser community, one of the most overused and often miscommunicated terms is the phrase “single mode.”  This is because a laser beam when traveling through air takes up a three-dimensional volume in space similar to that of a cylinder; and just as with a cylinder, a laser beam can be divided into independent coordinates each with their own mode structure.  For a cylinder we would call these the length and the cross-section, but as shown in the figure below for a laser beam, we define these as the transverse electromagnetic (TEM) plane and the longitudinal axis.   Both sets of modes are fundamental to the laser beam’s properties, since the TEM modes determine the spatial distribution of the laser beams intensity, and the longitudinal modes determine the spectral properties of the laser.  As a result, when a laser is described as being “single-mode” first you need to make sure that you truly understand which mode is being referred to.  Meaning that you must know if the laser is single transverse mode, single longitudinal mode, or both. Get all the information you need in this article: “What is Single Longitudinal Mode?” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

CW Lasers FAQs
How do I align my optical system?

How do I align my optical system?

Laser alignment can be a challenging task, but aligning a laser beam doesn’t have to be as complicated as it might seem with the right optical alignment tools and proper laser alignment techniques. Multiple optical alignment techniques have been developed over the years, utilized by technicians and engineers to simplify the alignment process. With the development of these universal laser beam alignment methods, along with some laser alignment tips and tricks, you don’t need to be a laser expert to perform your alignments with relative ease, ensuring your laser beam path is right where you want it to be and your beam is on target every time. Read our article, titled “Laser Alignment: HeNe Lasers, Methods, and Helpful Tips” to get the knowledge and advice you need for proper optical beam path alignment utilizing HeNe Lasers. Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

Should I choose multimode or single-mode for Raman spectroscopy?
Should I choose multimode or single-mode for Raman spectroscopy?

On the surface, this seems like a simple question since Raman is a nonlinear optical effect and therefore the tighter the beam can be focused the higher the conversion efficiency.  Seemingly a single-mode laser would be preferable, but in practice there are other factors that can complicate the situation. The first question you should ask yourself when considering which type of laser to choose is whether you are doing microscopy or bulk sampling.  If the answer to that question is microscopy, then you immediately should go with a single mode laser.  Since the goal of any microscopy system is to produce the highest resolution image possible, the number one consideration should be how tightly can the laser beam be focused down. However, there are several other considerations when choosing between multimode and single-mode. Learn which is best for you in this article: “Multimode vs Single-Mode Lasers for Raman Spectroscopy.” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

What is a CW Laser?
What is a CW Laser?

A CW or continuous-wave laser is any laser with a continuous flow of pump energy. It emits a constant stream of radiation, as opposed to a q-switched or mode-locked pulsed laser with a pulsed output beam. A laser is typically defined as having a pulse width greater than 250 ms. The first CW laser was a helium-neon (HeNe) gas laser, developed in 1960, which you can read more about in this blog “HeNe Lasers: Bright Past, Brighter Future.” If you want to read more about the types of CW Lasers we offer, check out the Overview of CW Lasers section on our Lasers 101 Page!

What is the best laser for optical surface flatness testing?
What is the best laser for optical surface flatness testing?

It is essential that the laser exhibit a high level of spectral stability, ensuring that any changes in the interference pattern are caused by features in the sample and not originating from the laser beam. In addition to spectral stability, high beam pointing stability ensures consistent measurements by mitigating any beam position drift concerning the position of the sample. Lasers with longer coherence lengths, and subsequently narrower linewidths, play an important role in determining the resolution of the measurement, as well as consideration of the wavelength used. Exhibiting both single longitudinal mode and single spatial mode has excellent benefits. To get more details on preferred laser sources for interferometry in this article: “Stable, Narrow Linewidth, CW DPSS Lasers for Precision Interferometry.” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

What type of laser do I need for confocal microscopy?
What type of laser do I need for confocal microscopy?

The short answer is: You have some flexibility, but the laser source should be PM fiber-coupled and have a low noise, TEM00 beam mode. The excitation bandwidth of the fluorophores used must overlap with the laser wavelength, as various fluorophores need different wavelengths. So, you may require multiple lasers, which means you’ve got a beam combining alignment challenge to tackle. One way to avoid this is through the convenience of Multi-Wavelength Beam Combiners.

If you want to learn more on the subject of confocal fluorescence microscopy, ideal laser sources, and the benefits of beam combiners, check out this white paper: “Multi-Wavelength Laser Sources for Multi-Color Fluorescence Microscopy.” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

What type of laser is best for Doppler LIDAR?

What type of laser is best for Doppler LIDAR?

Various LIDAR signal methods for measuring velocity have one critical requirement in common, the need for precise control over laser frequency. While a wide variety of single-frequency lasers have been used in Doppler LIDAR research, the industry as a whole has adopted single-frequency fiber lasers as the ideal light source. Fiber lasers have several advantages over traditional DPSS lasers, all of which derive from the geometry of the fiber optic itself, namely the innate ability to have an extremely long single-mode optical cavity. This geometry allows for the production of either extremely high-power, single-mode lasers producing unprecedented brightness, or extremely narrow band lasers, with near perfect single-frequency output. If you want to learn more about Doppler LIDAR, the critical considerations involved, and ideal laser sources, check out this whitepaper: “Single-Frequency Fiber Lasers for Doppler LIDAR.” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!

What’s the difference between single transverse mode & single longitudinal mode?

What’s the difference between single transverse mode & single longitudinal mode?

Within the laser community, one of the most overused and often miscommunicated terms is the phrase “single mode.”  This is because a laser beam when traveling through air takes up a three-dimensional volume in space similar to that of a cylinder; and just as with a cylinder, a laser beam can be divided into independent coordinates each with their own mode structure.  For a cylinder we would call these the length and the cross-section, but as shown in the figure below for a laser beam, we define these as the transverse electromagnetic (TEM) plane and the longitudinal axis.   Both sets of modes are fundamental to the laser beam’s properties, since the TEM modes determine the spatial distribution of the laser beams intensity, and the longitudinal modes determine the spectral properties of the laser.  As a result, when a laser is described as being “single-mode” first you need to make sure that you truly understand which mode is being referred to.  Meaning that you must know if the laser is single transverse mode, single longitudinal mode, or both. Get all the information you need in this article: “What is Single Longitudinal Mode?” Get more information from our Lasers 101, Blogs, Whitepapers, FAQs, and Press Release pages in our Knowledge Center!