METHOD AND DEVICE FOR HIGH-RESOLUTION IMAGING WHICH OBTAINS CAMERA POSE USING DEFOCUSING

US 20140022350A1
Filed: 07/15/2013
Published: 01/23/2014
Est. Priority Date: 08/27/2008
Status: Active Grant

First Claim

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1. A method for determining a change in pose of a moving sensor using a defocusing technique comprising acts of:

capturing, at an initial time, an initial plurality of defocused images of an object substantially simultaneously with a sensor, from an initial sensor pose;

extracting three-dimensional (3-D) locations of three or more object features from the relative locations of the object features in the initial plurality of defocused images on the sensor;

capturing, at a subsequent time, a subsequent plurality of defocused images of the object substantially simultaneously, from a subsequent sensor pose;

extracting 3-D locations of three or more object features from the relative locations of the object features in the subsequent plurality of defocused images on the sensor;

matching the object features from the initial plurality of defocused images with corresponding object features from the subsequent plurality of defocused images using a technique selected from the group consisting of;

a feature matching algorithm; and

an error minimization method; and

calculating a change in pose of the sensor between the initial and subsequent times using the 3-D locations extracted from the initial and subsequent pluralities of defocused images,whereby the change in pose of the moving sensor is determined.

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Abstract

A method and device for high-resolution three-dimensional (3-D) Imaging which obtains camera pose using defocusing is disclosed. The device comprises a lens obstructed by a mask having two sets of apertures. The first set of apertures produces a plurality of defocused images of the object which are used to obtain camera pose. The second set of optical filters produces a plurality of defocused images of a projected pattern of markers on the object. The images produced by the second set of apertures are differentiable from the images used to determine pose, and are used to construct a detailed 3-D image of the object. Using the known change in camera pose between captured images, the 3-D images produced can be overlaid to produce a high-resolution 3-D image of the object.

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16 Claims

1. A method for determining a change in pose of a moving sensor using a defocusing technique comprising acts of:
- capturing, at an initial time, an initial plurality of defocused images of an object substantially simultaneously with a sensor, from an initial sensor pose;
  
  extracting three-dimensional (3-D) locations of three or more object features from the relative locations of the object features in the initial plurality of defocused images on the sensor;
  
  capturing, at a subsequent time, a subsequent plurality of defocused images of the object substantially simultaneously, from a subsequent sensor pose;
  
  extracting 3-D locations of three or more object features from the relative locations of the object features in the subsequent plurality of defocused images on the sensor;
  
  matching the object features from the initial plurality of defocused images with corresponding object features from the subsequent plurality of defocused images using a technique selected from the group consisting of;
  
  a feature matching algorithm; and
  
  an error minimization method; and
  
  calculating a change in pose of the sensor between the initial and subsequent times using the 3-D locations extracted from the initial and subsequent pluralities of defocused images,whereby the change in pose of the moving sensor is determined.
- View Dependent Claims (2, 3, 4, 5)
- - 2. The method of claim 1, further comprising an act of constructing a high-resolution 3-D image of the object by:
    - projecting a pattern of markers on the object;
      
      capturing, at the initial time, and from the initial sensor pose, an initial plurality of defocused images of the projected pattern of markers with the sensor, the defocused images being differentiable from the initial pluralities of defocused images of the object used for determining sensor pose;
      
      constructing a 3-D image of the object based on relative positions of the initial plurality of defocused images of the projected pattern of markers on the sensor;
      
      capturing, at the subsequent time, and from the subsequent sensor pose, a subsequent plurality of defocused images of the projected pattern of markers with the sensor, the defocused images being differentiable from the subsequent pluralities of defocused images of the object used for determining sensor pose;
      
      constructing a 3-D image of the object based on relative positions of the subsequent plurality of defocused images of the projected pattern of markers on the sensor; and
      
      overlaying the 3-D images constructed from the initial and subsequent pluralities of defocused images of the projected pattern of markers using the known change in sensor pose between the initial and subsequent times to produce a high-resolution 3-D image of the object.
  - 3. The method of claim 2, further comprising an act of resolving the detailed 3-D image of the object to a desired resolution by:
    - capturing, at a second subsequent time, a second subsequent plurality of defocused images of the object substantially simultaneously, from a second subsequent sensor pose;
      
      extracting 3-D locations of three or more object features from the relative locations of the object features in the second subsequent plurality of defocused images on the sensor;
      
      matching the object features from the subsequent plurality of defocused images with corresponding object features from the second subsequent plurality of defocused images using a technique selected from the group consisting of;
      
      a feature matching algorithm; and
      
      an error minimization method; and
      
      calculating a change hi pose of the sensor between the subsequent aid second subsequent times using the 3-D locations extracted, from the subsequent and second subsequent pluralities of defocused images;
      
      projecting a pattern of markers on the object;
      
      capturing, at the second subsequent time, and from the second subsequent sensor pose, a second subsequent plurality of defocused images of the projected pattern of markers with the sensor, the defocused images being differentiable from the second subsequent pluralities of defocused images of the object used for determining sensor pose;
      
      constructing a 3-D image of the object based on relative positions of the second subsequent plurality of defocused images of the projected pattern of markers on the sensor;
      
      overlaying the 3-D images constructed from the initial, subsequent, and second subsequent pluralities of defocused images of the projected pattern of markers using the known change in sensor pose between the initial and second subsequent times to produce a high-resolution 3-D image of the object; and
      
      repeating these acts at further subsequent times and at further subsequent camera poses until a desired resolution is reached.
  - 4. The method of claim 3, further comprising an act of calculating an absolute pose of the sensor with respect to an environment by:
    - capturing a plurality of defocused images of three or more fixed features of known position in the environment with the sensor; and
      
      extracting 3-D locations of the three or more fixed features in the environment from the relative locations of the fixed features in the plurality of defocused images on the sensor; and
      
      calculating the absolute pose of the sensor using the 3-D locations extracted from the plurality of defocused images.
  - 5. The method of claim 1, further comprising an act of calculating an absolute pose of the sensor with respect to an environment by:
    - capturing a plurality of defocused images of three or more fixed features of known position in the environment with the sensor; and
      
      extracting 3-D locations of the three or more fixed features in the environment from the relative locations of the fixed features in the plurality of defocused images on the sensor; and
      
      calculating the absolute pose of the sensor using the 3-D locations extracted from the plurality of defocused images.

6. An imaging device for producing a high-resolution three-dimensional (3-D) image of an object, comprising:
- a lens obstructed by a mask having at least one set of off-axis apertures for producing a plurality of defocused images of an object substantially simultaneously;
  
  a sensor configured to capture the plurality of defocused images produced; and
  
  a data processing system having one or more processors configured to;
  
  capture, at an initial time, an initial plurality of defocused images of an object substantially simultaneously with a sensor, from an initial sensor pose;
  
  extract three-dimensional (3-D) locations of one or more object features from the relative locations of the object features in the initial plurality of defocused images on the sensor;
  
  capture, at a subsequent time, a subsequent plurality of defocused images of the object substantially simultaneously, from a subsequent sensor pose;
  
  match the object features from the initial plurality of defocused images with corresponding object features from the subsequent plurality of defocused images using a technique selected from the group consisting of;
  
  a feature matching algorithm; and
  
  an error minimization method; and
  
  calculate a change in pose of the sensor between the initial and subsequent times using the 3-D locations extracted from the initial plurality of defocused images,whereby the change in pose of the moving sensor is determined.
- View Dependent Claims (7, 8, 9)
- - 7. The imaging device of claim 6, further comprising projector for projecting a pattern of markers on the surface of the object, the projected pattern of markers being differentiable from the object features on the object, and wherein the data processing system is further configured to:
    - project a pattern of markers on the object;
      
      capture a plurality of defocused images of the projected pattern of markers with the sensor, the defocused images being differentiable from the initial and subsequent pluralities of defocused images of the object features used for determining sensor pose; and
      
      construct a 3-D image of a surface of the object based on relative positions of the plurality of defocused images of the projected pattern of markers on the sensor.
  - 8. The imaging device of claim 7, wherein the data processing system is further configured to calculate an absolute pose of the sensor relative to an environment by:
    - capturing a plurality of defocused images of three or more fixed features of known position in the environment with the sensor;
      
      extracting 3-D locations of the three or more fixed features in the environment from the relative locations of the fixed features in the plurality of defocused images on the sensor; and
      
      calculating the absolute pose of the sensor using the 3-D locations extracted from the plurality of defocused images.
  - 9. The imaging device of claim 6, wherein the data processing system is further configured to calculate an absolute pose of the sensor relative to an environment by:
    - capturing a plurality of defocused images of three or more fixed features of known position in the environment with the sensor;
      
      extracting 3-D locations of the three or more fixed features in the environment from the relative locations of the fixed features in the plurality of defocused images on the sensor; and
      
      calculating the absolute pose of the sensor using the 3-D locations extracted from the plurality of defocused images.

10. An imaging device for producing a high-resolution three-dimensional (3-D) image of an object, comprising;
- a lens obstructed by a mask having a first set and a second set of off-axis apertures where;
  
  the first set of off-axis apertures comprises a plurality of apertures fitted with filter separators for capturing a plurality of defocused images of an object substantially simultaneously; and
  
  the second set of off-axis apertures comprises a plurality of apertures fitted with filter separators differentiable from those of the first set of off-axis apertures for capturing a plurality of defocused images,a projector for projecting a pattern of markers on the surface of the object, the projected pattern of markers being of a wavelength corresponding to the filter separators of the second set of off-axis apertures; and
  
  a sensor configured to capture the defocused images produced,whereby the images captured on the sensor through the first set of off-axis apertures can be used to determine camera pose, and the images captured on the sensor through the second set of off-axis apertures can be used to construct a high-resolution three-dimensional image of the object.
- View Dependent Claims (11, 12, 13, 14, 15, 16)
- - 11. The device of claim 10, wherein the device further comprises a data processing system, the data processing system having one or more processors configured to:
    - capture, at an initial time, an initial plurality of defocused images of an object substantially simultaneously with a sensor, from an initial sensor pose;
      
      extract three-dimensional (3-D) locations of three or more object features from the relative locations of the object features in the initial plurality of defocused images on the sensor;
      
      capture, at a subsequent time, a subsequent plurality of defocused images of the object substantially simultaneously, from a subsequent sensor pose;
      
      extract three-dimensional (3-D) locations of three or more object features from the relative locations of the object features in the subsequent plurality of defocused images on the sensor;
      
      match the object features from the initial plurality of defocused images with corresponding object features from the subsequent plurality of defocused images using a technique selected from the group consisting of;
      
      a feature matching algorithm; and
      
      an error minimization method; and
      
      calculate a change in pose of the sensor between the initial and subsequent times using the 3-D locations extracted from the initial and subsequent pluralities of defocused images,whereby the change in pose of the moving sensor is determined.
  - 12. The device of claim 11, wherein the data processing system is further configured to:
    - project a pattern of markers on the abject;
      
      capture a plurality of defocused images of the projected pattern of markers with the sensor, the defocused images being differentiable from the initial and subsequent pluralities of defocused images of the object used for determining sensor pose; and
      
      construct a 3-D image of a surface of the object based on relative positions of the plurality of defocused images of the projected pattern of markers on the sensor.
  - 13. The device of claim 12, wherein the data processing system is further configured to calculate an absolute pose of the sensor relative to an environment by:
    - capturing a plurality of defocused images of three or more fixed features of known position in the environment with the sensor;
      
      extracting 3-D locations of the three or more fixed features in the environment from the relative locations of the fixed features in the plurality of defocused images on the sensor; and
      
      calculating the absolute pose of the sensor using the 3-D locations extracted from the plurality of defocused images.
  - 14. The device of claim 13, wherein each of the plurality of apertures comprising the first set of off-axis apertures is fitted with a different type of filter separator, such that the defocused images produced through said apertures are differentiable from one another.
  - 15. The device of claim 11, wherein the data processing system is further configured to calculate an absolute pose of the sensor relative to an environment by:
    - capturing a plurality of defocused images of three or more fixed features of known position in the environment with the sensor;
      
      extracting 3-D locations of the three or more fixed features in the environment from the relative locations of the fixed features in the plurality of defocused images on the sensor; and
      
      calculating the absolute pose of the sensor rising the 3-D locations extracted from the plurality of defocused images.
  - 16. The device of claim 10, wherein each of the plurality of apertures comprising the first set of off-axis apertures is fitted with a different type of filter separator, such that the defocused images produced through said apertures are differentiable from one another.

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Current Assignee
California Institute of Technology
Original Assignee
California Institute of Technology
Inventors
Gharib, Morteza, Lu, Jian, Hsieh, Scott, Harvard, Alexei

Granted Patent

US 9,247,235 B2
Time in Patent Office

Days
Field of Search
US Class Current

348/46
CPC Class Codes

G01B 11/002   for measuring two or more c...

G06T 7/571   from focus

H04N 13/221   using the relative movement...

H04N 13/236   using varifocal lenses or m...

H04N 13/254   in combination with electro...

METHOD AND DEVICE FOR HIGH-RESOLUTION IMAGING WHICH OBTAINS CAMERA POSE USING DEFOCUSING

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METHOD AND DEVICE FOR HIGH-RESOLUTION IMAGING WHICH OBTAINS CAMERA POSE USING DEFOCUSING

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