Reducing interference between multiple structured light depth sensors using motion
We present a method for reducing interference between multiple structured light-based
depth sensors operating in the same spectrum with rigidly attached projectors and cameras.
A small amount of motion is applied to a subset of the sensors so that each unit sees its own
projected pattern sharply, but sees a blurred version of the patterns of other units. If high
spacial frequency patterns are used, each sensor sees its own pattern with higher contrast
than the patterns of other units, resulting in simplified pattern disambiguation. An analysis of …
depth sensors operating in the same spectrum with rigidly attached projectors and cameras.
A small amount of motion is applied to a subset of the sensors so that each unit sees its own
projected pattern sharply, but sees a blurred version of the patterns of other units. If high
spacial frequency patterns are used, each sensor sees its own pattern with higher contrast
than the patterns of other units, resulting in simplified pattern disambiguation. An analysis of …
We present a method for reducing interference between multiple structured light-based depth sensors operating in the same spectrum with rigidly attached projectors and cameras. A small amount of motion is applied to a subset of the sensors so that each unit sees its own projected pattern sharply, but sees a blurred version of the patterns of other units. If high spacial frequency patterns are used, each sensor sees its own pattern with higher contrast than the patterns of other units, resulting in simplified pattern disambiguation. An analysis of this method is presented for a group of commodity Microsoft Kinect color-plus-depth sensors with overlapping views. We demonstrate that applying a small vibration with a simple motor to a subset of the Kinect sensors results in reduced interference, as manifested as holes and noise in the depth maps. Using an array of six Kinects, our system reduced interference-related missing data from from 16.6% to 1.4% of the total pixels. Another experiment with three Kinects showed an 82.2% percent reduction in the measurement error introduced by interference. A side-effect is blurring in the color images of the moving units, which is mitigated with post-processing. We believe our technique will allow inexpensive commodity depth sensors to form the basis of dense large-scale capture systems.
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