Professional Certifications
We have obtained ISO 9001 quality management system and ISO 14001 environmental management system certifications and are actively pursuing IATF 16949 International Automotive Task Force quality management system certification, laying a solid foundation for the application of LiDAR products in the automotive field.
Customized Services
We can provide customized production services for optical fiber products according to customer needs. We implement strict quality control at every stage of the manufacturing process to ensure stable and reliable product performance.
Production Equipment
We have established advanced chip packaging production lines and automatic coupling production lines. Key equipment includes: eutectic die bonding machines, fully automatic eutectic machines, parallel sealing welding machines, TO automatic sealing machines, OSA automatic transmitter coupling machines, and OSA automatic receiver coupling machines.
Professional Team
We maintain close collaborations with renowned research institutions and universities such as the Fujian Institute of Research on the Structure of Matter, Chinese Academy of Sciences, Xiamen University, Shenzhen University, Fuzhou University, and Mingde Innovation Laboratory, bringing together a group of experts and technical personnel with long-term experience in optical device research and development.
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Item |
Description |
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Model Number |
909O-5620G-14FA |
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Brand Name |
Belycomm |
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Mounting Type |
Unniiversal type |
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Description |
14PIN 1560nm SOA Laser Device |
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Type |
Laser Diode |
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Place of Origin |
Fujian, China |
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Package Type |
Surface Mount |
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Package / Case |
Surface Mount |
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Operating Temperature |
-10~+70℃ |
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Application |
Optical instrument / Optical fiber sensor |
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Supplier Type |
Original manufacturer, ODM, agency, retailer |
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Media Available |
Datasheet, Photo |
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Package |
Butterfly |
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Power |
20mW |
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Wavelength |
1560nm |
The amplification factor of the SOA, which quantifies how much the signal strength is increased. It is a critical parameter for ensuring adequate signal power in optical networks.
The range of optical frequencies over which the SOA can provide gain. A broader gain bandwidth allows the amplifier to support a wider range of wavelengths, making it versatile for various applications.
The maximum power level at which the amplifier can operate without significant distortion or degradation of the signal. It determines the upper limit of the signal strength that the SOA can handle before saturation occurs.
A measure of the noise added by the SOA to the signal during amplification. It reflects the amplifier's ability to preserve signal quality and is crucial for maintaining high signal-to-noise ratios.
The variation in gain experienced by the SOA due to changes in the polarization state of the input signal. Lower PDG values indicate better performance in handling different polarization states, which is important for consistent signal amplification.
In-line
Higher gain, moderate Psat; lower NF and lower PDG, usually polarization independent Semiconductor Optical Amplifier.
Booster
Higher Psat, lower gain, usually polarization dependent.
Switch
Higher Extinction Ratio and faster rise/fall time.
Pre-amplifier
Good for longer transmission distance, lower NF and higher gain.

The resonator is replaced with a semiconductor material. When an optical input signal is introduced into the SOA, it interacts with excited electrons within the semiconductor's quantum wells or quantum dots. Through the process of stimulated emission, these electrons emit photons of the same wavelength as the input signal, creating a population inversion that generates gain within the semiconductor. This gain amplifies the optical signal as it travels through the SOA. The device's laser resonator structure aids in guiding and confining the optical signal, enhancing the interaction length and the overall amplification. The amplified optical output emerges from the SOA, maintaining the input signal's wavelength.
Communication Networks
The semiconductor optical amplifier (SOA) is a key component in modern fiber-optic communication networks. An SOA can be used as a stand-alone amplifier, as part of an amplifying optical fiber span, or as a repeater in an optical fiber link. Its versatility in different configurations enhances the flexibility of optical network design and operation.
Sensor Networks
The use of semiconductor optical amplifiers (SOA) in sensor networks is an emerging technology that has the potential to revolutionize how these networks are designed and operated. SOAs are compact, low-power, and high-speed optical amplifiers that can be seamlessly integrated into optical fibers and waveguides, making them suitable for various sensor network configurations. They can be used to amplify signals in a variety of different applications, including sensor networks that require real-time, high-fidelity data transmission.
Optical Switching
Semiconductor Optical Amplifier (SOA) is a key enabling technology for integrating optical amplifiers and transceivers on a single optical switching chip. It is widely used in high-speed optical fiber data communications for various applications, including repeaters that extend the reach of communication signals and pre-amplifiers that boost signal strength before detection. SOAs can also be used in all-optical signal processing, offering functionalities such as wavelength conversion, optical modulation, and optical reflection, which enhance the versatility of optical networks.
Direct Signal Amplification
Signal amplification refers to the process of increasing the strength of a signal to ensure its integrity during transmission. When signals are transmitted over long distances via optical fiber arrangements, they are susceptible to power loss due to constant optical reflections, scattering, and attenuation. This can degrade the quality of the data being transmitted. A Semiconductor Optical Amplifier (SOA) helps to mitigate these losses and continue the signal by actively amplifying the signal strength, ensuring that the signal remains robust and can travel longer distances without significant degradation.
External Modulation
SOA works as an efficient modulator, playing a crucial role in various optical communication systems. Modulating refers to the process of superimposing the amplitude, frequency, or phase parameters of one wave onto another wave, which is typically a carrier signal. This process is essential for encoding information onto light waves in fiber-optic networks. Thus, external modulation is one of the primary applications of semiconductor optical amplifiers, allowing SOAs to be used in tasks like wavelength conversion, phase shifting, and signal reshaping, enhancing the overall functionality of optical communication systems.
Optical Tests and Measurement Techniques
Optical tests and measurement techniques serve as a critical driving force for numerous industries today, offering precise and non-invasive methods of analysis. Semiconductor optical amplifiers play a vital role in these systems due to their exceptional speed, flexibility, and efficiency. These optical tests and measurement systems enable significant advancements across various fields, ranging from industrial production monitoring and quality control to forensics, environmental analysis, and research in natural sciences. The integration of SOAs enhances the performance and reliability of these systems, pushing innovation forward in these diverse applications.
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Quantity (pieces) |
1 - 10 |
11 - 100 |
101 - 1000 |
> 1000 |
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Lead time (days) |
21 |
30 |
45 |
To be negotiated |
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Selling Units |
Single item |
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Single Package Size |
20X15X5 cm |
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Single Gross Weight |
1.000 KG |


As one of the most professional soa manufacturers and suppliers in China, we're featured by quality products and good price. Please rest assured to buy customized soa from our factory.
14PIN 1560nm SOA Laser Device, soa