Precisely reproduces dynamic trajectories, powerfully safeguarding core performance. 
The high-precision dual-axis dynamic simulation test platform, with its superior motion control algorithms and industrial-grade integrated structure, provides you with a highly controllable, stable, and reliable dynamic simulation environment. Whether it's accurately reproducing complex motion scenarios or endurance testing during long-term high-frequency operations, the platform consistently delivers a solid foundation for the core performance of navigation, sensing, and positioning systems.
Supporting flexible local and remote dual-mode operation, coupled with real-time data feedback and intuitive software interaction, puts the testing process under your complete control. We leverage intelligent tools and standardized processes to assist in R&D verification, production quality control, and cutting-edge research, becoming your trusted partner for improving product accuracy and verifying system reliability, jointly driving breakthroughs and innovations in sensing technology.

Why Choose Blue Equator?
I. Superior Simulation Accuracy and Dynamic Performance
High-Fidelity Simulation Capability: Accurately reproduces complex multi-dimensional motion trajectories, providing the tested system with a highly realistic, controllable, and repeatable dynamic input environment. This directly determines the validity and authority of the test results.
Precise and Stable Control: The core lies in advanced motion control algorithms, ensuring ultra-high precision and stability in speed and position control, providing a reliable motion benchmark, and is key to producing trustworthy test data.

II. Robust and Reliable Industrial-Grade Design and Load Capacity
Long-Term Stability and Durability: Utilizes a one-piece molded special alloy material, possessing excellent rigidity, wear resistance, and corrosion resistance, ensuring that the mechanical structure remains stable and accuracy does not diminish under long-term, high-frequency, and high-intensity testing tasks.
Wide Equipment Compatibility: The large-size load design boasts powerful load-bearing capacity and compatibility, adaptable to different specifications of test units from lightweight to medium-sized, meeting the diverse testing load needs of customers.

III. Intelligent User Experience and Process Integration
Flexible and Integrated Control Modes: Supports local and remote networked control, seamlessly integrating into automated testing pipelines or operating independently, significantly improving the efficiency and modernization of the testing process.
Transparent Testing Process: Through two-way communication and an intuitive software interface, a closed loop of real-time feedback of command issuance and motion data (attitude, speed, status) is achieved. Users have complete control and insight into the testing process, facilitating data recording, analysis, and problem tracing.

Products Features

I. Specifications and Features
Structural Form: Dual-axis design, supporting multi-dimensional composite motion simulation.
Load Compatibility: Utilizes a large-size load design, adaptable to various sizes of test equipment or units from light to medium-sized.
Control Modes: Supports both local control and remote networked control modes.
Interface and Communication: Equipped with a bidirectional communication interface for real-time transmission and feedback of commands and data.

II. Material Characteristics
Main Structure: Manufactured using a special alloy material through a one-piece molding process.
Core Attributes: Possesses high rigidity, high wear resistance, and corrosion resistance, ensuring the stability and accuracy of the mechanical structure under long-term high-load operation.

III. Performance Characteristics

Dynamic Simulation Performance:
High-Precision Positioning: Achieves precise control and measurement of angular position.
Continuous Rotation and Composite Oscillation: Capable of simulating complex real-world motion trajectories.
Smooth and Stable Control: Utilizes advanced motion control algorithms to achieve high-precision and smooth control of speed and position.
Reliability and Durability:
Mechanical Stability: Utilizing superior materials and manufacturing processes, ensuring accuracy and reliability under long-term, high-frequency use.
High Load Capacity: Robust design capable of stably operating test units within a certain weight range.
Intelligent and Operable:
User-Friendly Process: Supports integration with automated testing processes, improving testing efficiency.
Data Transparency: Real-time feedback of attitude, speed, and status data facilitates monitoring and analysis.
Convenient Management: The testing process and recorded data can be intuitively managed through a software interface.

IV. Applications and Features

Core Verification and Calibration:
Used for accuracy testing, calibration, and verification of motion-sensing-dependent navigation, positioning, and attitude measurement systems.
Evaluates their response characteristics under various simulated motion conditions.
Research and Development & Optimization:
Provides a repeatable and traceable dynamic testing environment for the research and development of new sensors or motion sensing systems.
Serves algorithm optimization, performance limit testing, and reliability verification.
Quality Control and Production Testing:
As a key inspection device on the production line, it performs consistency, stability, and functional compliance testing on finished products.
Education and Research:
Providing high-standard experimental and demonstration platforms for universities and research institutions in cutting-edge fields such as inertial technology, automatic control, and robotics.

This product is a high-precision dual-axis dynamic simulation test platform integrating cutting-edge engineering technology, intelligent control, and industrial reliability. It is specifically designed to provide a precise, reliable, and efficient dynamic performance verification environment for motion sensing and positioning systems. The platform uses advanced algorithms at its core to achieve high-precision motion control and complex trajectory simulation; it employs a special alloy unibody molding process to ensure mechanical stability and durability under long-term, high-frequency use; and it supports flexible and intelligent control modes and data closed-loop management, seamlessly integrating into the entire R&D, production, and research process. It serves not only as a standardized tool for dynamic testing but also as a strategic partner driving technological innovation, ensuring product quality, and empowering cutting-edge exploration, providing a solid and reliable testing benchmark and end-to-end support for the field of precision sensing and intelligent control.