Wide Dynamic Range (WDR) technology improves a camera's image quality under high-contrast lighting conditions where both dimly and brightly lit areas are present in the field of view. It enables the camera to capture details clearly in both the poorly and strongly illuminated areas of the video.
Embeded with industry leading wide dynamic range (WDR) technology, vivid picutures are achieved even in the most intense contrast lighting conditions. For applications with both bright and low lighting conditions that change quickly, True WDR (120dB) optimizes both the bright and dark areas of a scene at the same time to provide usable video.
What WDR Does
Dynamic range refers to the ratio between the largest and smallest measurable quantities of something. In the case of video surveillance, dynamic range measures the ratio between the lightest and darkest elements of the image. WDR technology is great for high contrast scenes, balancing the brightness and shaded areas simultaneously so an image neither appears blown out or too dark.
Decibels (dB) are the value with which dynamic range is measured. IHS defines WDR at 60 dB or greater, though it’s not uncommon to see WDR cameras with capabilities of 120 dB or more. However, keep in mind that each manufacturer has their own method of determining a camera’s dB. Therefore, when comparing product datasheets it is possible that a camera with a lower ratio outperforms a competitor with a higher dB ratio.
How WDR Works
Security cameras with WDR technology are using either Digital WDR (DWDR) or True WDR. True WDR uses image sensors and a digital signal processor (DSP) to provide even illumination to all areas of an image. A True WDR-enabled video surveillance camera has two sensors that takes two scans of each video frame. The first, at low speed (to capture more light), shows the image in normal light conditions. The second scan is taken at high speed to capture less light overall and get an image with strong light in the background. The DSP combines the two scans to form a single, balanced, well-illuminated image.
DWDR uses algorithms instead of sensors to digitally brighten too-dark areas and dim too-bright areas. DWDR relies on the DSP chip instead of the image sensor to provide WDR. It adjusts each individual pixel of the image and calculates exposure accordingly. This technique has some limitations; the intense manipulation of pixels leads to the overall image being more grainy. On the other hand, DWDR doesn’t need costly image sensors, so DWDR can be a more economical option when WDR is a necessity.
When You Don’t Have WDR
There are two options for improving the exposure of an image without using WDR. In a high-contrast scene with heavy, broad, backlighting, the camera will adjust to the average illumination, which will darken the image. If no WDR is available, Backlight Compensation (BLC) brightens the image so you can see darker details better. BLC is a legacy technique that uses DSPs to increase the level of exposure for the entire image. Rather than balancing brightness on overexposed and underexposed areas of an image like WDR does, it brightens the entire image. This is a good solution to prevent washing out images that are already overly lit.
Highlight compensation (HLC) is a technology where image sensors detect strong light within the image and reduce exposure on those areas to enhance the overall image quality. In a dimly-lit scene with bright lighting caused by hot spots (e.g. headlights, street lights), the overall image may become too dark. If no WDR is available, use HLC. The camera automatically suppresses bright light sources, allowing proper exposure of adjacent areas.
Conclusion
Regardless of dB value specified, image results will vary depending on the complexity and amount of movement in a scene. To determine the best camera for an application, it is always best to test that it meets the needs and expectations of the customer.