The MIC IP fusion 9000i camera is an advanced PTZ surveillance platform designed to provide early detection in mission-critical applications. With its dual visible/thermal imaging capabilities, the MIC IP fusion 9000i camera is the perfect choice when a robust and high-quality imaging solution is needed. The MIC camera's distinctive, ruggedized design is well suited for applications having extreme weather conditions of hot/cold temperatures, high winds, rain, fog, ice, and installations associated with shock and vibrations events such as bridges and towers. Precision engineered using Bosch's domain expertise in material and mechanical engineering, this camera offers the most advanced imaging and positioning system solution available on the market.
Functions
Exceptional imaging performance
The MIC IP fusion 9000i camera incorporates a highperformance thermal imaging core and a 1080p starlight-quality day/night visible camera integrated in the same housing. This allows the camera to deliver simultaneous thermal and visible video streams, maximizing the ability to detect and react to longrange threats.
Thermal imager
The thermal imager incorporates the latest un-cooled vanadium oxide microbolometer technology. This high sensitivity thermal imager is equipped with a fixed focal length Athermal lens that balances the field-ofview with maximizing the detection distance. MIC's thermal core seamlessly and automatically optimizes the image through the use of edge enhancement, dynamic contrast thresholding and adaptive rescaling processes. In addition, its integrated flat field correction feature provides a uniform reference so that scene components are correctly represented.
The combination of these embedded features assure the highest quality image will always be delivered. Depending on model mix, QVGA resolution (320 pixels) and VGA resolution (640 pixels) versions are available, with choice of low (<9Hz) or high (30/60Hz) frame rates. In addition, a wide variety of userselectable thermal color modes are available allowing further optimization of the thermal image.