I. Product Overview
Abner Fiber Alignment System adopts advanced optical design and high-precision control technology, specially optimized for fiber docking, precision calibration and signal transmission. The system delivers unparalleled accuracy to ensure optimal optical performance during fiber alignment, and is widely applied in fields such as optical communication, laser systems, optical inspection and laboratory research.
II. Functional Features
1. Multi-degree-of-freedom precision adjustment: Supports linear displacement adjustment along X, Y, Z three axes and angular adjustment of θx, θy, θz, meeting the requirements of complex optical path alignment.
2. High resolution and high repetitive positioning accuracy: The displacement resolution reaches the nanometer level with high repetitive positioning accuracy, suitable for applications requiring high coupling efficiency.
3. Multiple feedback modes: Compatible with optical power meter feedback, camera visual feedback, or a combination of both, enabling fast and reliable automatic or semi-automatic alignment.
4. Compatibility with various optical fibers and devices: Adaptable to single-mode optical fibers, multi-mode optical fibers, polarization-maintaining optical fibers, as well as various chips and optical modules.
5. Stable and reliable mechanical structure: Adopts low-drift and low-vibration design, suitable for long-term testing and packaging processes.
6. Expandability and automation: Optional electric control, software algorithms and automatic scanning functions are available to support system integration.
III. Application Scenarios and Fields
1. Optical Communication and Data Centers: Precision coupling between optical fibers and chips in optical modules and optical transceivers.
2. Integrated Photonics: Optical fiber coupling and performance testing of photonic chips such as silicon photonics, silicon nitride, and indium phosphide.
3. Optoelectronic Device Packaging: Collimation, coupling and packaging of devices including lasers, detectors and modulators.
4. Scientific Research and Laboratory Applications: Precision optical path alignment in experiments of nonlinear optics, quantum optics, ultrafast optics and other fields.
5. Sensing and Measurement: High-precision alignment and calibration in fiber optic sensors and interferometer systems.
IV. Technical Advantages
1. High Precision: Equipped with a high-rigidity platform and precision drive, it achieves alignment accuracy at the sub-micron level and even the nanometer level.
2. High Coupling Efficiency: Combined with real-time feedback and optimization algorithms, it can quickly reach and maintain the optimal coupling state.
3. Excellent Stability: Adopting thermal stability and low-drift design, it is suitable for long-term continuous operation.
4. Flexible Configuration: It supports multiple configuration modes including manual, electric and automatic to meet diverse application requirements.
5. Easy Integration: The modular design facilitates seamless integration with test systems, packaging production lines or vacuum environments.
V. Typical Models and Application Cases
Model | Features | Application Cases | Applicable Objects |
Manual Fiber Alignment System |
· Intuitive operation · High alignment accuracy · Suitable for low-frequency and non-batch usage scenarios
|
- Preliminary coupling test of single-mode optical fiber and integrated photonic chip - Verification experiment on laser-fiber coupling efficiency - Optical path alignment and demonstration in optics teaching experiments - Coupling verification at the prototype stage of new optical device principles
| University Teaching and Basic Scientific Research Laboratories |
Electric Precision Optical Fiber Alignment System |
· High repetitive positioning accuracy · Capable of forming closed-loop control with power meters and cameras · Suitable for scientific research and engineering development stages
|
· High-precision coupling of optical fibers and laser chips in the R&D of optical communication devices · Performance testing of silicon photonic / silicon nitride photonic chips · Precision alignment of multi-channel fiber arrays and waveguide arrays · Long-term stability test and aging test platform
| Users engaged in optical communication and integrated photonics R&D |
Automated Optical Fiber Alignment and Coupling System |
· Automatically search for the optimal coupling point · Significantly improve production efficiency and consistency · Suitable for integration into automated production lines
|
· Large-scale packaging of optical modules and optical transceivers · Automatic coupling and testing of chip-level optoelectronic devices · High-consistency fiber array coupling production line · Consistency evaluation of optical communication devices before mass production
| Enterprises specializing in optical module packaging and mass production |
High-Stability Research-Grade Fiber Alignment System |
· Low thermal drift and low mechanical vibration · Supports long-term stable operation · Tailored for high-end fundamental scientific research
|
· Single-photon source and optical fiber coupling in quantum optics experiments · Ultrafast optics and nonlinear optics experiments · Interferometers and high-precision optical fiber sensing systems · Weak optical signal detection and measurement platform
| High-end Basic Research and Quantum Optics |
Vacuum / Low Temperature Compatible Fiber Alignment System |
· Adapt to complex environments · High stability and reliability · Widely used in high-end scientific research platforms
|
· Low-temperature quantum device and fiber coupling test · Extraction and coupling of optical signals in vacuum cavity · Optical characterization of semiconductor devices under low temperature conditions · Optical path alignment for extreme environments in physical experiments
| Scientific Research and Physical Property Testing in Extreme Environments |
Working Principle Diagram
Appearance Drawing
