🚨 Industry Pain Points
In modern navigation, control, and motion sensing applications, traditional IMU systems often suffer from:
- Measurement drift caused by temperature variation
- Errors due to installation misalignment
- Nonlinear sensor output under dynamic conditions
- Poor stability in harsh environments (vibration, shock, temperature extremes)
- Insufficient accuracy for high-precision control systems
These limitations reduce system reliability in UAVs, robotics, automotive, and industrial automation applications.
⚙ Product Advantages
Our MEMS IMU is designed with advanced hardware integration and intelligent compensation algorithms to overcome these challenges:
- ✔ Integrated MEMS gyroscope and accelerometer chips for compact high-performance sensing
- ✔ Built-in temperature sensor with full temperature compensation algorithm
- ✔ Installation misalignment angle compensation for real-world mounting errors
- ✔ Nonlinear compensation algorithm improves measurement accuracy
- ✔ Signal processing circuit ensures stable and clean data output
- ✔ Embedded software optimizes real-time data fusion and correction
- ✔ Reliable performance under static, dynamic, and harsh environmental conditions
🚁 Product Applications
This MEMS IMU is widely used in precision motion and navigation systems, including:
- UAV flight control systems
- Fixed-wing and VTOL drones
- Autonomous robots and AGVs
- Marine navigation and stabilization systems
- Automotive positioning and inertial navigation
- Industrial motion tracking and control systems
⭐ Why Choose Us
- High integration MEMS architecture for compact system design
- Advanced multi-layer error compensation algorithms
- Strong environmental adaptability and long-term stability
- High reliability in both static and dynamic conditions
- Suitable for mission-critical navigation and control applications
- Proven performance in industrial and aerospace-grade systems
We focus on delivering stable, accurate, and robust inertial sensing solutions for demanding applications.
❓ Frequently Asked Questions (FAQ)
Q1: Does the IMU support temperature compensation?
Yes, it includes full temperature compensation for stable performance across wide temperature ranges.
Q2: Can it reduce installation errors?
Yes, it has built-in installation misalignment compensation algorithms.
Q3: Is it suitable for high-vibration environments?
Yes, it is designed to operate reliably under vibration and dynamic conditions.
Q4: What sensors are integrated inside?
It integrates MEMS gyroscope, MEMS accelerometer, temperature sensor, and signal processing circuits.
Q5: Does it provide real-time stable output?
Yes, embedded software and compensation algorithms ensure stable and accurate real-time data output.
| Parameter | unit | fundamental form | |
| gyroscope | Measurement range (customizable) | ° /s | ±480 |
| Zero-level offset | ° /h | 150 | |
| Zero-pitch instability (@ALLAN variance) | ° /h | 3 | |
| Zero offset stability (10-second smoothing, 1σ, room temperature) | ° /h | 8 | |
| Zero bias repeatability | ° /h | 5 | |
| Zero bias error across the entire temperature range | ° /h | 60 | |
| random walk | ° / √ h | 0.25 | |
| Zero-zero acceleration sensitivity | ° /h/g | 20 | |
| resolution ratio | ° /s | 0.01 | |
| Output noise (half-maximum) | ° /s | 0.3 | |
| tape width | Hz | 100 | |
| Nonlinear scaling factor | ppm | 50 | |
| Scale factor repeatability | ppm | 50 | |
| cross coupling | % | 0.1 | |
| Parameter | unit | I mould | |
| accelerometer | Measurement range (customizable) | g | ±16 |
| Zero-pitch instability (@ALLAN variance) | mg | 0.05 | |
| Zero offset stability (10-second smoothing, 1σ, room temperature) | mg | 0.1 | |
| Zero bias repeatability | mg | 0.1 | |
| Zero bias error across the entire temperature range | mg | 2.5 | |
| random walk | m/s/ √ h | 0.03 | |
| resolution ratio | mg | 0.1 | |
| tape width | Hz | 100 | |
| Scale factor repeatability | ppm | 200 | |
| cross coupling | % | 0.1 | |
| Parameter | unit | fundamental form | |
|
other |
Stabilization start time | s | 2 |
| Data update rate | Hz | 400 | |
| voltage | V | 5±0.3 | |
| steady state power consumption | W | 0.25 | |
| ripple wave | mV | 100 | |
| working temperature | ℃ | -45~85 | |
| storage temperature | ℃ | -55~105 | |
| weight | g | 18±1 | |
| size | mm | 24*22.4*9 | |
| Interface | —— | UART | |
