Abstract: A device and method for obtaining distance information from views is provided. The method generating epipolar images from a light field captured by a light field acquisition device; an edge detection step for detecting, in the epipolar images, edges of objects in the scene captured by the light field acquisition device; in each epipolar image, detecting valid epipolar lines formed by a set of edges; determining the slopes of the valid epipolar lines. The edge detection step may calculate a second spatial derivative for each pixel of the epipolar images and detect the zero-crossings of the second spatial derivatives, to detect object edges with subpixel precision. The method may be performed by low cost mobile devices to calculate real-time depth-maps from depth-camera recordings.

Abstract: A method for obtaining depth information from a scene is disclosed wherein the method has the steps of: a) acquiring a plurality of images of the scene by means of at least one camera during a time of shot wherein the plurality of images offer at least two different views of the scene; b) for each of the images of step a), simultaneously acquiring data about the position of the images referred to a six-axis reference system; c) selecting from the images of step b) at least two images; d) rectifying the images selected on step c) thereby generating a set of rectified images; and e) generating a depth map from the rectified images. Additionally devices for carrying out the method are disclosed.

Abstract: A microlens array that corrects the problems caused by aberrations and non-paraxiality of microlenses is provided. The microlens array has a plurality of microlenses tilted a tilting degree (?, ?) depending on the position of the microlens in the microlens array. Simultaneously, or alternatively, the distances Pul(i) between optical centres (Pi, Pi?1) of adjacent microlenses depend on their positions in the microlens array. Both these distances Pul(i) and the tilting degrees (?, ?) are dependent normally increasing upon the distance to the center of the microlens array. The size of the microlenses may also increase with the distance to the center of the microlens array. An opaque layer may also be applied covering the edges of adjacent microlenses.

Abstract: A device and method for obtaining depth information from a light field is provided. The method generating a plurality of epipolar images from a light field captured by a light field acquisition device; an edge detection step for detecting, in the epipolar images, edges of objects in the scene captured by the light field acquisition device; for each epipolar image, detecting valid epipolar lines formed by a set of edges; and determining the slopes of the valid epipolar lines. In a preferred embodiment, the method extend the epipolar images with additional information of images captured by additional image acquisition devices and obtain extended epipolar lines. The edge detection step calculates a second spatial derivative for each pixel of the epipolar images and detects the zero-crossings of the second spatial derivatives.

Abstract: A method for obtaining depth information from a scene is disclosed wherein the method has the steps of: a) acquiring a plurality of images of the scene by means of at least one camera during a time of shot wherein the plurality of images offer at least two different views of the scene; b) for each of the images of step a), simultaneously acquiring data about the position of the images referred to a six-axis reference system; c) selecting from the images of step b) at least two images; d) rectifying the images selected on step c) thereby generating a set of rectified images; and e) generating a depth map from the rectified images. Additionally devices for carrying out the method are disclosed.

Abstract: A microlens array that corrects the problems caused by aberrations and non-paraxiality of microlenses is provided. The microlens array has a plurality of microlenses tilted a tilting degree (?,?) depending on the position of the microlens in the microlens array. Simultaneously, or alternatively, the distances Pul(i) between optical centres (Pi,Pi?1) of adjacent microlenses depend on their positions in the microlens array. Both these distances Pul(i) and the tilting degrees (?,?) are dependent normally increasing upon the distance to the center of the microlens array. The size of the microlenses may also increase with the distance to the center of the microlens array. An opaque layer may also be applied covering the edges of adjacent microlenses.

Abstract: A device and method for obtaining distance information from views is provided. The method generating epipolar images from a light field captured by a light field acquisition device; an edge detection step for detecting, in the epipolar images, edges of objects in the scene captured by the light field acquisition device; in each epipolar image, detecting valid epipolar lines formed by a set of edges; determining the slopes of the valid epipolar lines. The edge detection step may calculate a second spatial derivative for each pixel of the epipolar images and detect the zero-crossings of the second spatial derivatives, to detect object edges with subpixel precision. The method may be performed by low cost mobile devices to calculate real-time depth-maps from depth-camera recordings.

Abstract: A device and method for obtaining depth information from a light field is provided. The method generating a plurality of epipolar images from a light field captured by a light field acquisition device; an edge detection step for detecting, in the epipolar images, edges of objects in the scene captured by the light field acquisition device; for each epipolar image, detecting valid epipolar lines formed by a set of edges; and determining the slopes of the valid epipolar lines. In a preferred embodiment, the method extend the epipolar images with additional information of images captured by additional image acquisition devices and obtain extended epipolar lines. The edge detection step calculates a second spatial derivative for each pixel of the epipolar images and detects the zero-crossings of the second spatial derivatives.