Human visual understanding of luminescence and brightness encounters the value of pupil diameter along with retinal rod receptors and neuro-pulsation efficiency of brain. Otherwise, the clinician may be dealing with some extent of cataract that makes it hard to understand their luminous and brightness understanding. In digital imaging though, sensors quantum efficiency and optical elements including the adjustment lens and aperture play crucial roles in image brightness. However as long as Falcon Ray digital systems considers clinicians only tool to adjust the brightness to be their light source intensity tool, real time imaging algorithms are applied to image capture, in order to synchronize the digitized amplitude of data and dynamic range to cover all possible observations as an average human vision.

Any digital camera has an entity called the Dynamic Range, which is referred to the distance between the whitest white and the blackest black. This gray level is likewise applied to colors. When a camera sensor provides its image data to the Image Signal Processor of the camera, it is crucial for image processing algorithms to drive the sensor in a way that splits the dynamic range across the area in, where the required clinical data is present. Therefore it is crucial for microscope upgrades to capture the exact surgeon’s observation of colors by adjusting the right point for the true white in real time.

Once capturing the image or a frameset, the camera sensor could be driven in a way to enhance vision for what human eye is naked to. This could be imaging within the NIR frequency band as well as special image manipulations to reveal or project specific defects for surgeons to be extracted from the camera raw data. This gives the operation user a wider choice to illustrate any surgical action than the time a captured image or framset is processed. Sensor raw data is very much wider to navigate through than images with headers that could be only available for post processing options.