High-ER Polarization-Maintaining Fiber Optic Patch Cables
- High Polarization Extinction Ratio (ER)
- 780, 980, 1064, 1310, or 1550 nm Alignment Wavelength
- FC/PC, FC/APC, and FC/PC to FC/APC Connectors Available
- Custom Options Available
P3-1310PMP-2
1310 nm, FC/APC, 2 m Long
P5-1550PMP-2
1550 nm, FC/PC to FC/APC, 2 m Long
Connector Key Aligned to Slow Axis
Please Wait
PM Fiber Patch Cable Selection Guide |
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FC/PC to FC/PC |
FC/APC to FC/APC |
FC/PC to FC/APC Hybrid |
High-ER Cables FC/PC, FC/APC, and Hybrid |
AR-Coated FC/PC and Hybrid |
Dispersion-Compensating FC/APC |
HR-Coated FC/PC and FC/APC |
Features
- Typical Extinction Ratio at Alignment Wavelength:
- 30 dB for 780 nm Patch Cables
- 33 dB for 980, 1064, 1310, or 1550 nm Patch Cables
- Narrow Key (2.0 mm) Aligned to Slow Axis
- Typical Insertion Loss:
- 0.60 dB for 780 nm Cables
- 0.40 dB for 980 or 1064 nm Cables
- 0.20 dB for 1310 or 1550 nm Cables
- Typical Return Loss:
- 50 dB for FC/PC Connectors
- 60 dB for FC/APC Connectors
- Ceramic 8° Angled Ferrule on APC Connector
- Ø3 mm Blue PVC Furcation Tubing
Thorlabs High-Extinction-Ratio (ER) Polarization-Maintaining Fiber Optic Patch Cables are specially designed to have a high extinction ratio and low insertion loss, as compared to our standard PM patch cables (for specific differences between the standard and high-ER cables, please refer to the Comparison tab).
The ER of these polarization maintaining (PM) patch cables is specified as the ratio of the power propagating along the slow axis of the fiber to the power along the fast axis when a sufficiently linearly polarized input is aligned to the fiber's slow axis. Please note that the achievable extinction ratio in a system where these high-ER PM patch cables are implemented may be lower than the specified extinction ratio of the cable. The achievable ER will always be limited by the optical elements with the lowest ER in the system. These patch cables are assembled and tested for slow axis performance only. While the ER achievable with a fast axis launch should be similar, we do not test or guarantee performance for this usage case. For more information on how the extinction ratio was measured, please see the ER Measurement tab.
Each cable is individually tested* at the alignment wavelength listed below to ensure its extinction ratio and insertion loss at fiber-to-fiber junctions. Each patch cable includes two protective caps that shield the ferrule ends from dust and other hazards. Additional CAPF Plastic Fiber Caps and CAPFM Metal Threaded Fiber Caps for FC/PC- and FC/APC-terminated ends are also sold separately.
These cables are also available in other lengths and with different tubing than our stock offerings below. Please contact Tech Support for more information.
*Please note that the port "A" mentioned in the inspection report refers to the end of the patch cable with a white label attached to it.
Item # Prefix | P1-780PMP | P3-780PMP | P5-780PMP | P1-980PMP | P3-980PMP | P5-980PMP | P1-1064PMP | P3-1064PMP | P5-1064PMP |
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Alignment Wavelength | 780 nm | 980 nm | 1064 nm | ||||||
Fiber Specs | |||||||||
Fiber Type | PM780-HP (PANDA) | PM980-XP (PANDA) | |||||||
Operating Wavelength | 770 - 1100 nm | 970 - 1550 nm | |||||||
Cutoff Wavelength | 710 ± 60 nm | 920 ± 50 nm | |||||||
Mode Field Diametera | 5.3 ± 1.0 µm @ 850 nm | 6.6 ± 0.5 µm @ 980 nm | |||||||
Numerical Apertureb | 0.12 | ||||||||
Patch Cable Specs | |||||||||
Insertion Lossc,d | 0.70 dB (Max) 0.60 dB (Typ.) |
0.50 dB (Max) 0.40 dB (Typ.) |
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Extinction Ratioc,d | 27 dB (Min) 30 dB (Typ.) |
30 dB (Min) 33 dB (Typ.) |
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Optical Return Lossc (Typical) |
50 dB | 60 dB | 50 dB (FC/PC) 60 dB (FC/APC) |
50 dB | 60 dB | 50 dB (FC/PC) 60 dB (FC/APC) |
50 dB | 60 dB | 50 dB (FC/PC) 60 dB (FC/APC) |
Connector Type | FC/PC | FC/APC | FC/PC to FC/APC | FC/PC | FC/APC | FC/PC to FC/APC | FC/PC | FC/APC | FC/PC to FC/APC |
Key Width | 2.0 mm (Narrow Key) | ||||||||
Slow Axis Alignment | Aligned to Connector Keye | ||||||||
Cable Length | 1.0 m for Item Numbers Ending in -1 2.0 m for Item Numbers Ending in -2 |
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Cable Length Tolerance | +0.1 / -0 m | ||||||||
Jacket Type | Ø3 mm Blue PVC Furcation Tubing | ||||||||
Operating Temperature | 0 to 70 °C | ||||||||
Storage Temperature | -45 to 85 °C |
Item # Prefix | P1-1310PMP | P3-1310PMP | P5-1310PMP | P1-1550PMP | P3-1550PMP | P5-1550PMP |
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Alignment Wavelength | 1310 nm | 1550 nm | ||||
Fiber Specs | ||||||
Fiber Type | PM1300-XP (PANDA) | PM1550-XP (PANDA) | ||||
Operating Wavelength | 1270 - 1625 nm | 1440 - 1625 nm | ||||
Cutoff Wavelength | 1210 ± 60 nm | 1380 ± 60 nm | ||||
Mode Field Diametera | 9.3 ± 0.5 µm @ 1300 nm | 10.1 ± 0.4 @ 1550 nm | ||||
Numerical Apertureb | 0.12 | 0.125 | ||||
Patch Cable Specs | ||||||
Insertion Lossc,d | 0.30 dB (Max) 0.20 dB (Typ.) |
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Extinction Ratioc,d | 30 dB (Min) 33 dB (Typ.) |
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Optical Return Lossc (Typical) |
50 dB | 60 dB | 50 dB (FC/PC) 60 dB (FC/APC) |
50 dB | 60 dB | 50 dB (FC/PC) 60 dB (FC/APC) |
Connector Type | FC/PC | FC/APC | FC/PC to FC/APC | FC/PC | FC/APC | FC/PC to FC/APC |
Key Width | 2.0 mm (Narrow Key) | |||||
Slow Axis Alignment | Aligned to Connector Keye | |||||
Cable Length | 1.0 m for Item Numbers Ending in -1 2.0 m for Item Numbers Ending in -2 |
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Cable Length Tolerance | +0.1 / -0 m | |||||
Jacket Type | Ø3 mm Blue PVC Furcation Tubing | |||||
Operating Temperature | 0 to 70 °C | |||||
Storage Temperature | -45 to 85 °C |
Alignment Wavelength |
PM Fiber Cable Type |
Extinction Ratioa (Typ. / Min) |
Insertion Lossa (Typ. / Max) |
---|---|---|---|
780 nm | High ER | 30 dB / 27 dB | 0.60 dB / 0.70 dB |
Standard | 22 dB / 20 dB | 0.70 dB / 1.00 dB | |
980 nm | High ER | 33 dB / 30 dB | 0.40 dB / 0.50 dB |
Standard | 24 dB / 22 dB | 0.50 dB / 0.70 dB | |
1064 nm | High ER | 33 dB / 30 dB | 0.40 dB / 0.50 dB |
Standard | 24 dB / 22 dB | 0.50 dB / 0.70 dB | |
1310 nm | High ER | 33 dB / 30 dB | 0.20 dB / 0.30 dB |
Standard | 25 dB / 23 dB | 0.30 dB / 0.50 dB | |
1550 nm | High ER | 33 dB / 30 dB | 0.20 dB / 0.30 dB |
Standard | 25 dB / 23 dB | 0.30 dB / 0.50 dB |
Standard vs. High-ER PM Patch Cable Comparison
Our high-ER cables are specified to have higher extinction ratios at their alignment wavelength compared to our standard cables (FC/PC, FC/APC, or hybrid). The high-ER patch cables also exhibit a lower insertion loss compared to their standard counterparts (see the table to the right for details).
For more information about the methods used to measure the ER, please refer to the ER Measurement tab.
Comparison of 1550 nm PM Patch Cables
The graphs below depict sample data comparing Thorlabs' 1550 nm, High-Extinction-Ratio (ER) PM FC/APC Patch Cables, and our standard 1550 nm PM FC/APC Patch Cables for 1 m and 2 m cable lengths.
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Cross-Polarizer Method
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In-Line Measurement Method
The extinction ratio (ER) of a polarization-maintaining (PM) fiber patch cable can be measured by the following two methods: the cross-polarizer method (CPM) and the in-line measurement method (ILM). While Thorlabs uses CPM to measure the ER of our high-ER patch cables, both methods are outlined below.
Please be aware that these methods require different optical sources - CPM requires an incoherent source while ILM requires a coherent source. The ER of the polarizers used in each measurement method should be at least one order of magnitude higher than the achievable ER of the PM cable under test to ensure the accuracy of measurement.
Cross-Polarizer Method
Before entering the PM patch cable under test, the output from an incoherent source (for example, an S5FC1005S Benchtop SLD is used for our 1550 nm cables) passes through a polarization controller (Item # FPC030 with SMF-28 fiber) and is then linearly polarized by an FBR-LPNIR Rotating Linear Polarizer Module. The linear polarizer is aligned with the slow axis of the PM patch cable under test. An additional FBR-LPNIR polarizer (the analyzer) is placed after the cable under test. The rotation angle of both polarizers is adjusted until minimum transmission is achieved, keeping the first polarizer aligned to the slow axis of the fiber. The ER is measured by rotating the analyzer to find the maximum and minimum transmission.
In-Line Measurement Method
Before entering the PM patch cable under test, the light from a coherent source (such as the S1FC1550 Single Mode Laser, for example) passes through an FPC030 Polarization Controller with SMF-28 fiber (for example) and is then linearly polarized using an FBR-LPNIR Rotating Linear Polarizer Module. When coherent, linearly polarized light travels along the fast and slow axes of a PM fiber, the phase shift of the light propagating along each axis will differ. This relative phase shift between the axes can result in an artificially high ER measurement. The PM patch cable under test is stressed or heated (by an external heat source) during the measurement to continuously change the phase shift, allowing the minimum ER value to be found. An extinction ratio meter is used to measure the ER values and the angle of misalignment between the polarization axis exiting the fiber and the cable's connector key.
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Mating Between a Narrow-Key Mating Sleeve and Connector
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Mating Between a Wide-Key Mating Sleeve and Connector
FC/PC and FC/APC Patch Cable Key Alignment
FC/PC and FC/APC Patch Cables are equipped with either a 2.0 mm narrow or 2.2 mm wide alignment key that fits into a corresponding slot on a mated component. These keys and slots are essential to correctly align the cores of connected fiber patch cables and minimize the insertion loss of the connection.
As an example, Thorlabs designs and manufactures mating sleeves for FC/PC- and FC/APC-terminated patch cables to precise specifications that ensure good alignment when used correctly. To ensure the best alignment, the alignment key on the patch cable is inserted into the corresponding narrow or wide-key slot on the mating sleeve.
Wide-Key-Slot Mating Sleeves
2.2 mm wide-key-slot mating sleeves are compatible with both wide-key and narrow-key connectors. However, using a narrow-key connector in a wide-key slot will allow the connector to rotate slightly in the mating sleeve (as shown in the animation below and to the left). While this configuration is acceptable for patch cables with FC/PC connectors, for FC/APC applications, we recommend using narrow-key-slot mating sleeves to ensure optimum alignment.
Narrow-Key-Slot Mating Sleeves
2.0 mm narrow-key-slot mating sleeves allow for optimal alignment of angled, narrow-key FC/APC connectors, as shown in the animation below and to the right. Therefore, they are not compatible with connectors that have a 2.2 mm wide key. Please note that all FC/PC and FC/APC patch cables manufactured by Thorlabs use narrow key connectors.
Once a narrow key connector is inserted into a narrow-key-slot mating sleeve, the connector will not rotate. We therefore recommend these mating sleeves for FC/PC and FC/APC connectors with narrow keys.
When a narrow key connector is inserted into a wide-key-slot mating sleeve, the connector has room to rotate. For narrow key FC/PC connectors, this is acceptable, but for narrow key FC/APC connectors, significant coupling losses will result.
Quick Links |
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Damage at the Air / Glass Interface |
Intrinsic Damage Threshold |
Preparation and Handling of Optical Fibers |
Laser-Induced Damage in Silica Optical Fibers
The following tutorial details damage mechanisms relevant to unterminated (bare) fiber, terminated optical fiber, and other fiber components from laser light sources. These mechanisms include damage that occurs at the air / glass interface (when free-space coupling or when using connectors) and in the optical fiber itself. A fiber component, such as a bare fiber, patch cable, or fused coupler, may have multiple potential avenues for damage (e.g., connectors, fiber end faces, and the device itself). The maximum power that a fiber can handle will always be limited by the lowest limit of any of these damage mechanisms.
While the damage threshold can be estimated using scaling relations and general rules, absolute damage thresholds in optical fibers are very application dependent and user specific. Users can use this guide to estimate a safe power level that minimizes the risk of damage. Following all appropriate preparation and handling guidelines, users should be able to operate a fiber component up to the specified maximum power level; if no maximum is specified for a component, users should abide by the "practical safe level" described below for safe operation of the component. Factors that can reduce power handling and cause damage to a fiber component include, but are not limited to, misalignment during fiber coupling, contamination of the fiber end face, or imperfections in the fiber itself. For further discussion about an optical fiber’s power handling abilities for a specific application, please contact Thorlabs’ Tech Support.
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Undamaged Fiber End
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Damaged Fiber End
Damage at the Air / Glass Interface
There are several potential damage mechanisms that can occur at the air / glass interface. Light is incident on this interface when free-space coupling or when two fibers are mated using optical connectors. High-intensity light can damage the end face leading to reduced power handling and permanent damage to the fiber. For fibers terminated with optical connectors where the connectors are fixed to the fiber ends using epoxy, the heat generated by high-intensity light can burn the epoxy and leave residues on the fiber facet directly in the beam path.
Estimated Optical Power Densities on Air / Glass Interfacea | ||
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Type | Theoretical Damage Thresholdb | Practical Safe Levelc |
CW (Average Power) |
~1 MW/cm2 | ~250 kW/cm2 |
10 ns Pulsed (Peak Power) |
~5 GW/cm2 | ~1 GW/cm2 |
Damage Mechanisms on the Bare Fiber End Face
Damage mechanisms on a fiber end face can be modeled similarly to bulk optics, and industry-standard damage thresholds for UV Fused Silica substrates can be applied to silica-based fiber. However, unlike bulk optics, the relevant surface areas and beam diameters involved at the air / glass interface of an optical fiber are very small, particularly for coupling into single mode (SM) fiber. therefore, for a given power density, the power incident on the fiber needs to be lower for a smaller beam diameter.
The table to the right lists two thresholds for optical power densities: a theoretical damage threshold and a "practical safe level". In general, the theoretical damage threshold represents the estimated maximum power density that can be incident on the fiber end face without risking damage with very good fiber end face and coupling conditions. The "practical safe level" power density represents minimal risk of fiber damage. Operating a fiber or component beyond the practical safe level is possible, but users must follow the appropriate handling instructions and verify performance at low powers prior to use.
Calculating the Effective Area for Single Mode Fibers
The effective area for single mode (SM) fiber is defined by the mode field diameter (MFD), which is the cross-sectional area through which light propagates in the fiber; this area includes the fiber core and also a portion of the cladding. To achieve good efficiency when coupling into a single mode fiber, the diameter of the input beam must match the MFD of the fiber.
As an example, SM400 single mode fiber has a mode field diameter (MFD) of ~Ø3 µm operating at 400 nm, while the MFD for SMF-28 Ultra single mode fiber operating at 1550 nm is Ø10.5 µm. The effective area for these fibers can be calculated as follows:
SM400 Fiber: Area = Pi x (MFD/2)2 = Pi x (1.5 µm)2 = 7.07 µm2 = 7.07 x 10-8 cm2
SMF-28 Ultra Fiber: Area = Pi x (MFD/2)2 = Pi x (5.25 µm)2 = 86.6 µm2 = 8.66 x 10-7 cm2
To estimate the power level that a fiber facet can handle, the power density is multiplied by the effective area. Please note that this calculation assumes a uniform intensity profile, but most laser beams exhibit a Gaussian-like shape within single mode fiber, resulting in a higher power density at the center of the beam compared to the edges. Therefore, these calculations will slightly overestimate the power corresponding to the damage threshold or the practical safe level. Using the estimated power densities assuming a CW light source, we can determine the corresponding power levels as:
SM400 Fiber: 7.07 x 10-8 cm2 x 1 MW/cm2 = 7.1 x 10-8 MW = 71 mW (Theoretical Damage Threshold)
7.07 x 10-8 cm2 x 250 kW/cm2 = 1.8 x 10-5 kW = 18 mW (Practical Safe Level)
SMF-28 Ultra Fiber: 8.66 x 10-7 cm2 x 1 MW/cm2 = 8.7 x 10-7 MW = 870 mW (Theoretical Damage Threshold)
8.66 x 10-7 cm2 x 250 kW/cm2 = 2.1 x 10-4 kW = 210 mW (Practical Safe Level)
Effective Area of Multimode Fibers
The effective area of a multimode (MM) fiber is defined by the core diameter, which is typically far larger than the MFD of an SM fiber. For optimal coupling, Thorlabs recommends focusing a beam to a spot roughly 70 - 80% of the core diameter. The larger effective area of MM fibers lowers the power density on the fiber end face, allowing higher optical powers (typically on the order of kilowatts) to be coupled into multimode fiber without damage.
Damage Mechanisms Related to Ferrule / Connector Termination
Plot showing approximate input power that can be incident on a single mode silica optical fiber with a termination. Each line shows the estimated power level due to a specific damage mechanism. The maximum power handling is limited by the lowest power level from all relevant damage mechanisms (indicated by a solid line).
Fibers terminated with optical connectors have additional power handling considerations. Fiber is typically terminated using epoxy to bond the fiber to a ceramic or steel ferrule. When light is coupled into the fiber through a connector, light that does not enter the core and propagate down the fiber is scattered into the outer layers of the fiber, into the ferrule, and the epoxy used to hold the fiber in the ferrule. If the light is intense enough, it can burn the epoxy, causing it to vaporize and deposit a residue on the face of the connector. This results in localized absorption sites on the fiber end face that reduce coupling efficiency and increase scattering, causing further damage.
For several reasons, epoxy-related damage is dependent on the wavelength. In general, light scatters more strongly at short wavelengths than at longer wavelengths. Misalignment when coupling is also more likely due to the small MFD of short-wavelength SM fiber that also produces more scattered light.
To minimize the risk of burning the epoxy, fiber connectors can be constructed to have an epoxy-free air gap between the optical fiber and ferrule near the fiber end face. Our high-power multimode fiber patch cables use connectors with this design feature.
Determining Power Handling with Multiple Damage Mechanisms
When fiber cables or components have multiple avenues for damage (e.g., fiber patch cables), the maximum power handling is always limited by the lowest damage threshold that is relevant to the fiber component. In general, this represents the highest input power that can be incident on the patch cable end face and not the coupled output power.
As an illustrative example, the graph to the right shows an estimate of the power handling limitations of a single mode fiber patch cable due to damage to the fiber end face and damage via an optical connector. The total input power handling of a terminated fiber at a given wavelength is limited by the lower of the two limitations at any given wavelength (indicated by the solid lines). A single mode fiber operating at around 488 nm is primarily limited by damage to the fiber end face (blue solid line), but fibers operating at 1550 nm are limited by damage to the optical connector (red solid line).
In the case of a multimode fiber, the effective mode area is defined by the core diameter, which is larger than the effective mode area for SM fiber. This results in a lower power density on the fiber end face and allows higher optical powers (on the order of kilowatts) to be coupled into the fiber without damage (not shown in graph). However, the damage limit of the ferrule / connector termination remains unchanged and as a result, the maximum power handling for a multimode fiber is limited by the ferrule and connector termination.
Please note that these are rough estimates of power levels where damage is very unlikely with proper handling and alignment procedures. It is worth noting that optical fibers are frequently used at power levels above those described here. However, these applications typically require expert users and testing at lower powers first to minimize risk of damage. Even still, optical fiber components should be considered a consumable lab supply if used at high power levels.
Intrinsic Damage Threshold
In addition to damage mechanisms at the air / glass interface, optical fibers also display power handling limitations due to damage mechanisms within the optical fiber itself. These limitations will affect all fiber components as they are intrinsic to the fiber itself. Two categories of damage within the fiber are damage from bend losses and damage from photodarkening.
Bend Losses
Bend losses occur when a fiber is bent to a point where light traveling in the core is incident on the core/cladding interface at an angle higher than the critical angle, making total internal reflection impossible. Under these circumstances, light escapes the fiber, often in a localized area. The light escaping the fiber typically has a high power density, which burns the fiber coating as well as any surrounding furcation tubing.
A special category of optical fiber, called double-clad fiber, can reduce the risk of bend-loss damage by allowing the fiber’s cladding (2nd layer) to also function as a waveguide in addition to the core. By making the critical angle of the cladding/coating interface higher than the critical angle of the core/clad interface, light that escapes the core is loosely confined within the cladding. It will then leak out over a distance of centimeters or meters instead of at one localized spot within the fiber, minimizing the risk of damage. Thorlabs manufactures and sells 0.22 NA double-clad multimode fiber, which boasts very high, megawatt range power handling.
Photodarkening
A second damage mechanism, called photodarkening or solarization, can occur in fibers used with ultraviolet or short-wavelength visible light, particularly those with germanium-doped cores. Fibers used at these wavelengths will experience increased attenuation over time. The mechanism that causes photodarkening is largely unknown, but several fiber designs have been developed to mitigate it. For example, fibers with a very low hydroxyl ion (OH) content have been found to resist photodarkening and using other dopants, such as fluorine, can also reduce photodarkening.
Even with the above strategies in place, all fibers eventually experience photodarkening when used with UV or short-wavelength light, and thus, fibers used at these wavelengths should be considered consumables.
Preparation and Handling of Optical Fibers
General Cleaning and Operation Guidelines
These general cleaning and operation guidelines are recommended for all fiber optic products. Users should still follow specific guidelines for an individual product as outlined in the support documentation or manual. Damage threshold calculations only apply when all appropriate cleaning and handling procedures are followed.
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All light sources should be turned off prior to installing or integrating optical fibers (terminated or bare). This ensures that focused beams of light are not incident on fragile parts of the connector or fiber, which can possibly cause damage.
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The power-handling capability of an optical fiber is directly linked to the quality of the fiber/connector end face. Always inspect the fiber end prior to connecting the fiber to an optical system. The fiber end face should be clean and clear of dirt and other contaminants that can cause scattering of coupled light. Bare fiber should be cleaved prior to use and users should inspect the fiber end to ensure a good quality cleave is achieved.
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If an optical fiber is to be spliced into the optical system, users should first verify that the splice is of good quality at a low optical power prior to high-power use. Poor splice quality may increase light scattering at the splice interface, which can be a source of fiber damage.
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Users should use low power when aligning the system and optimizing coupling; this minimizes exposure of other parts of the fiber (other than the core) to light. Damage from scattered light can occur if a high power beam is focused on the cladding, coating, or connector.
Tips for Using Fiber at Higher Optical Power
Optical fibers and fiber components should generally be operated within safe power level limits, but under ideal conditions (very good optical alignment and very clean optical end faces), the power handling of a fiber component may be increased. Users must verify the performance and stability of a fiber component within their system prior to increasing input or output power and follow all necessary safety and operation instructions. The tips below are useful suggestions when considering increasing optical power in an optical fiber or component.
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Splicing a fiber component into a system using a fiber splicer can increase power handling as it minimizes possibility of air/fiber interface damage. Users should follow all appropriate guidelines to prepare and make a high-quality fiber splice. Poor splices can lead to scattering or regions of highly localized heat at the splice interface that can damage the fiber.
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After connecting the fiber or component, the system should be tested and aligned using a light source at low power. The system power can be ramped up slowly to the desired output power while periodically verifying all components are properly aligned and that coupling efficiency is not changing with respect to optical launch power.
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Bend losses that result from sharply bending a fiber can cause light to leak from the fiber in the stressed area. When operating at high power, the localized heating that can occur when a large amount of light escapes a small localized area (the stressed region) can damage the fiber. Avoid disturbing or accidently bending fibers during operation to minimize bend losses.
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Users should always choose the appropriate optical fiber for a given application. For example, large-mode-area fibers are a good alternative to standard single mode fibers in high-power applications as they provide good beam quality with a larger MFD, decreasing the power density on the air/fiber interface.
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Step-index silica single mode fibers are normally not used for ultraviolet light or high-peak-power pulsed applications due to the high spatial power densities associated with these applications.
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Item # | Connector Type |
Alignment Wavelength |
Fiber Type | Operating Wavelength |
Cutoff Wavelength |
Extinction Ratioa,b |
Insertion Lossa,b |
Return Lossa (Typ.) |
Mode Field Diameterc |
Jacket | Length |
---|---|---|---|---|---|---|---|---|---|---|---|
P1-780PMP-1 | FC/PC | 780 nm | PM780-HP (PANDA) |
770 - 1100 nm | 710 ± 60 nm | 27 dB (Min) 30 dB (Typ.) |
0.70 dB (Max) 0.60 dB (Typ.) |
50 dB | 5.3 ± 1.0 µm @ 850 nm |
Ø3 mm Blue PVC Furcation Tubing |
1 m |
P1-780PMP-2 | 2 m | ||||||||||
P3-780PMP-1 | FC/APC | 60 dB | 1 m | ||||||||
P3-780PMP-2 | 2 m | ||||||||||
P5-780PMP-1 | FC/PC to FC/APC | 50 dB (FC/PC) 60 dB (FC/APC) |
1 m | ||||||||
P5-780PMP-2 | 2 m |
Item # | Connector Type |
Alignment Wavelength |
Fiber Type | Operating Wavelength |
Cutoff Wavelength |
Extinction Ratioa,b |
Insertion Lossa,b |
Return Lossa (Typ.) |
Mode Field Diameterc |
Jacket | Length |
---|---|---|---|---|---|---|---|---|---|---|---|
P1-980PMP-1 | FC/PC | 980 nm | PM980-XP (PANDA) |
970 - 1550 nm | 920 ± 50 nm | 30 dB (Min) 33 dB (Typ.) |
0.50 dB (Max) 0.40 dB (Typ.) |
50 dB | 6.6 ± 0.5 µm @ 980 nm |
Ø3 mm Blue PVC Furcation Tubing |
1 m |
P1-980PMP-2 | 2 m | ||||||||||
P3-980PMP-1 | FC/APC | 60 dB | 1 m | ||||||||
P3-980PMP-2 | 2 m | ||||||||||
P5-980PMP-1 | FC/PC to FC/APC | 50 dB (FC/PC) 60 dB (FC/APC) |
1 m | ||||||||
P5-980PMP-2 | 2 m |
Item # | Connector Type |
Alignment Wavelength |
Fiber Type | Operating Wavelength |
Cutoff Wavelength |
Extinction Ratioa,b |
Insertion Lossa,b |
Return Lossa (Typ.) |
Mode Field Diameterc |
Jacket | Length |
---|---|---|---|---|---|---|---|---|---|---|---|
P1-1064PMP-1 | FC/PC | 1064 nm | PM980-XP (PANDA) |
970 - 1550 nm | 920 ± 50 nm | 30 dB (Min) 33 dB (Typ.) |
0.50 dB (Max) 0.40 dB (Typ.) |
50 dB | 6.6 ± 0.5 µm @ 980 nm |
Ø3 mm Blue PVC Furcation Tubing |
1 m |
P1-1064PMP-2 | 2 m | ||||||||||
P3-1064PMP-1 | FC/APC | 60 dB | 1 m | ||||||||
P3-1064PMP-2 | 2 m | ||||||||||
P5-1064PMP-1 | FC/PC to FC/APC | 50 dB (FC/PC) 60 dB (FC/APC) |
1 m | ||||||||
P5-1064PMP-2 | 2 m |
Item # | Connector Type |
Alignment Wavelength |
Fiber Type | Operating Wavelength |
Cutoff Wavelength |
Extinction Ratioa,b |
Insertion Lossa,b |
Return Lossa (Typ.) |
Mode Field Diameterc |
Jacket | Length |
---|---|---|---|---|---|---|---|---|---|---|---|
P1-1310PMP-1 | FC/PC | 1310 nm | PM1300-XP (PANDA) |
1270 - 1625 nm | 1210 ± 60 nm | 30 dB (Min) 33 dB (Typ.) |
0.30 dB (Max) 0.20 dB (Typ.) |
50 dB | 9.3 ± 0.5 µm @ 1300 nm |
Ø3 mm Blue PVC Furcation Tubing |
1 m |
P1-1310PMP-2 | 2 m | ||||||||||
P3-1310PMP-1 | FC/APC | 60 dB | 1 m | ||||||||
P3-1310PMP-2 | 2 m | ||||||||||
P5-1310PMP-1 | FC/PC to FC/APC | 50 dB (FC/PC) 60 dB (FC/APC) |
1 m | ||||||||
P5-1310PMP-2 | 2 m |
Item # | Connector Type |
Alignment Wavelength |
Fiber Type | Operating Wavelength |
Cutoff Wavelength |
Extinction Ratioa,b |
Insertion Lossa,b |
Return Lossa (Typ.) |
Mode Field Diameterc |
Jacket | Length |
---|---|---|---|---|---|---|---|---|---|---|---|
P1-1550PMP-1 | FC/PC | 1550 nm | PM1550-XP (PANDA) |
1440 - 1625 nm | 1380 ± 60 nm | 30 dB (Min) 33 dB (Typ.) |
0.30 dB (Max) 0.20 dB (Typ.) |
50 dB | 10.1 ± 0.4 µm @ 1550 nm |
Ø3 mm Blue PVC Furcation Tubing |
1 m |
P1-1550PMP-2 | 2 m | ||||||||||
P3-1550PMP-1 | FC/APC | 60 dB | 1 m | ||||||||
P3-1550PMP-2 | 2 m | ||||||||||
P5-1550PMP-1 | FC/PC to FC/APC | 50 dB (FC/PC) 60 dB (FC/APC) |
1 m | ||||||||
P5-1550PMP-2 | 2 m |