🚨 Industry Pain Points
In high-precision navigation and motion sensing applications, users often face critical challenges:
- Performance drift caused by temperature variations
- Installation misalignment errors affecting measurement accuracy
- Nonlinear sensor response under dynamic motion
- Limited stability in harsh vibration or shock environments
- High integration cost and difficulty replacing legacy IMU systems
- Dependency on expensive industrial-grade navigation modules
These limitations directly impact system reliability in UAVs, robotics, and industrial control systems.
⚙ Product Structure & Technology
This MEMS IMU is built with a highly integrated architecture:
- High-precision MEMS gyroscope chip for angular velocity sensing
- MEMS accelerometer chip for linear acceleration measurement
- Dedicated signal processing circuit for real-time data handling
- Robust mechanical structure for vibration resistance
- Embedded firmware for advanced compensation and calibration
It ensures high accuracy and stability across all operating conditions.
🧠 Core Compensation Algorithms
To guarantee measurement reliability, the system includes:
- ✔ Full temperature compensation (wide-range thermal stability)
- ✔ Installation misalignment compensation (mounting error correction)
- ✔ Nonlinear compensation (sensor response linearization)
- ✔ Static & dynamic error correction algorithms
These algorithms ensure consistent output quality even under extreme environmental variations.
🚁 Product Advantages
- ✔ High stability under static, dynamic, and harsh conditions
- ✔ Industrial-grade MEMS sensor integration
- ✔ Built-in multi-layer error compensation system
- ✔ Plug-and-play replacement for legacy systems
- ✔ Compatible with ADIS16505 / ADIS16507 interfaces
- ✔ Compact design for easy system integration
- ✔ High reliability for mission-critical applications
🚀 Product Applications
This MEMS IMU is widely used in:
- UAV navigation and flight control systems
- Autonomous robotics and AGV systems
- Industrial motion measurement and stabilization
- Marine and maritime navigation systems
- Gimbal stabilization and payload control
- Aerospace and defense-grade inertial systems
⭐ Why Choose Us
- Direct replacement compatibility with industry-standard IMUs
- Advanced multi-layer compensation algorithm system
- Strong performance stability in extreme environments
- High integration level reduces system complexity
- Cost-effective alternative to high-end navigation modules
- Professional support for integration and customization
We provide reliable, accurate, and easily deployable inertial sensing solutions for demanding engineering applications.
❓ Frequently Asked Questions (FAQ)
Q1: Is this IMU compatible with ADIS16505 and ADIS16507?
Yes, it is designed as a direct drop-in replacement for both models.
Q2: Does it support harsh environment operation?
Yes, it maintains stable output under vibration, temperature variation, and dynamic conditions.
Q3: Does it require calibration after installation?
It includes built-in compensation algorithms, reducing the need for manual calibration.
Q4: What industries can use this IMU?
It is widely used in UAVs, robotics, marine systems, and industrial control.
Q5: Does it support real-time motion data output?
Yes, it provides continuous real-time inertial data output with compensated accuracy.
| Parameter | unit | fundamental form | |
| gyroscope | Measurement range (customizable) | ° /s | ±500 |
| Zero-level offset | ° /h | 180 | |
| Zero-pitch instability (@ALLAN variance) | ° /h | 2.5 | |
| Zero offset stability (10-second smoothing, 1σ, room temperature) | ° /h | 10 | |
| Zero bias repeatability | ° /h | 30 | |
| Zero bias error across the entire temperature range | ° /h | 72 | |
| random walk | ° / √ h | 0.15 | |
| Zero-zero acceleration sensitivity | ° /h/g | 2 | |
| resolution ratio | ° /s | 0.01 | |
| Output noise (half-maximum) | ° /s | 0.3 | |
| tape width | Hz | 345 | |
| Nonlinear scaling factor | ppm | 100 | |
| Scale factor repeatability | ppm | 300 | |
| cross coupling | % | 0.1 | |
| Parameter | unit | MOPS6505 | MOPS6507 | |
| accelerometer | Measurement range (customizable) | g | ±8 | ±40 |
| Zero-pitch instability (@ALLAN variance) | mg | 0.02 | 0.01 | |
| Zero offset stability (10-second smoothing, 1σ, room temperature) | mg | 0.05 | 0.1 | |
| Zero bias repeatability | mg | 0.3 | 0.1 | |
| Zero bias error across the entire temperature range | mg | 3 | X、Y:0.5;Z:2 | |
| random walk | m/s/ √ h | 0.1 | 0.03 | |
| resolution ratio | mg | 0.1 | 0.1 | |
| tape width | Hz | 393 | 1000 | |
| Scale factor repeatability | ppm | 500 | 300 | |
| cross coupling | % | 0.1 | 0.1 | |
| Parameter | unit | fundamental form | |
|
other |
Stabilization start time | s | 1 |
| Data update rate | Hz | 2000 | |
| voltage | V | 3.3±0.3 | |
| steady state power consumption | W | 0.1 | |
| ripple wave | mV | 100 | |
| working temperature | ℃ | -45~85 | |
| storage temperature | ℃ | -55~85 | |
| weight | g | 1.7±0.2 | |
| size | mm | 15×15×5.7 | |
| Interface | —— | SPI | |
