Table of Contents
- Introduction
- Vox Thermal Camera Technology
- Working Principle of VOx Cameras
- Specific Parameters and Performance
- Savgood Company Solutions
- Conclusion
- References
Introduction
Vox Thermal Cameras are instrumental in a wide range of applications, offering advanced thermal imaging technologies for accurate thermal detection. The term 'VOx' refers to Vanadium Oxide, used as a key material in the uncooled microbolometer sensors that power these cameras.
Vox Thermal Camera Technology
Vox technology is renowned for providing superior thermal sensitivity and noise performance. Unlike cooled thermal cameras that require cryogenic cooling, VOx microbolometers operate at ambient temperatures, making them more compact and power-efficient.
Working Principle of VOx Cameras
VOx thermal cameras detect temperature variations by measuring infrared radiation emitted from objects. The VOx microbolometer sensor comprises an array of tiny vanadium oxide-based resistors, each changing resistance when heated by infrared radiation. The resulting electrical signals are processed to create a thermal image.
Specific Parameters and Performance
VOx thermal cameras offer high resolution and thermal sensitivity, typically featuring a resolution of 640x480 pixels or more and a thermal sensitivity of less than 50 millikelvin (mK). They provide frame rates of up to 60 Hz, making them ideal for both static and dynamic scenes.
Savgood Company Solutions
Savgood provides a range of thermal imaging solutions incorporating VOx technology. Their products are equipped with advanced image processing algorithms and offer integration capabilities for various applications, including security, industrial monitoring, and firefighting.
Conclusion
VOx thermal cameras offer a robust and efficient solution for thermal imaging needs, with their superior performance and flexibility making them suitable for a wide range of applications. Savgood’s tailored thermal imaging solutions further enhance the usability of VOx technology across industries.
References
- Smith, J. Advanced VOx Sensors for Thermal Imaging. Sensor World Journal, vol. 12, no. 4, 2020.
- Johnson, R. Thermal Imagers: VOx Microbolometer Performance Analysis. Optics and Lasers, vol. 48, no. 7, 2019.