DJI Zenmuse H30T - Advanced Thermal Imaging Solution
The DJI Zenmuse H30T is a cutting-edge infrared thermal camera designed for integration with the DJI Matrice 350 and 300 series. This high-performance device combines multiple functionalities to deliver precise and reliable thermal imaging and measurement across various environments and scenarios, making it ideal for security operations, emergency response, and natural resource management.Key Specifications
- Focal Length: 52mm
- Diagonal Field of View (DFOV): 45.2°
- Sensor: Uncooled VOx Microbolometer
- Photo Resolution: 1280×1024
- Video Resolution: 1280×1024@30fps
- Temperature Measurement Range: -20° to 1600° CHigh-Resolution Thermal Imaging
With a resolution of 1280×1024, the H30T provides four times the detail compared to previous models, allowing for comprehensive thermal imaging over expansive areas. This enhanced clarity is essential for effective monitoring and analysis in various applications.Advanced Zoom Capabilities
The camera features a digital zoom of up to 32×, enabling users to focus on specific areas for in-depth analysis. This capability is crucial for identifying and assessing thermal anomalies with precision.Multiple Thermal Enhancement Modes
The H30T includes several infrared enhancement modes, such as High Gain for accurate temperature measurements, Low Gain for a broader temperature range, and a new High-Resolution Mode for observing objects with minimal temperature differences, ensuring versatility in various scenarios.Linked Zoom Functionality
This innovative feature allows for synchronized scaling of visible light and thermal images, facilitating easier comparisons and object identification. This integration enhances the overall effectiveness of thermal assessments.Wide Temperature Measurement Range
The H30T offers an extensive temperature measurement range from -20° to 1600° C, making it suitable for applications in firefighting and inspections of high-temperature areas. This broad range ensures that users can effectively monitor and respond to diverse thermal conditions.