How to create 3D model from 2D image

Question

If I take a picture with a camera, so I know the distance from the camera to the object, such as a scale model of a house, I would like to turn this into a 3D model that I can maneuver around so I can comment on different parts of the house.

If I sit down and think about taking more than one picture, labeling direction, and distance, I should be able to figure out how to do this, but, I thought I would ask if someone has some paper that may help explain more.

What language you explain in doesn't matter, as I am looking for the best approach.

Right now I am considering showing the house, then the user can put in some assistance for height, such as distance from the camera to the top of that part of the model, and given enough of this it would be possible to start calculating heights for the rest, especially if there is a top-down image, then pictures from angles on the four sides, to calculate relative heights.

Then parts will need to differ in color to help separate out the various parts of the model I expect also.

Answer 1

As mentioned, the problem is very hard and is often also referred to as multi-view object reconstruction. It is usually approached by solving the stereo-view reconstruction problem for each pair of consecutive images.

Performing stereo reconstruction requires that pairs of images are taken that have a good amount of visible overlap of physical points. If you have:

• the intrinsic camera parameters (requiring camera calibration),
• the camera's position and rotation (it's extrinsic parameters), and
• 8 or more physical points with matching known positions in two photos (when using the eight-point algorithm)

then the stereo reconstruction problem can be solved for all these matching points using only matrix theory. However, this requires a lot of theory about co-ordinate projections with homogeneous co-ordinates and also knowledge of the pinhole camera model and camera matrix. More specifically, you would need to calculate the fundamental and essential matrices and then use triangulation to find the 3D co-ordinates of the points.

This whole stereo reconstruction would then be repeated for each pair of consecutive images (implying that you need an order to the images or at least knowledge of which images have many overlapping points). For each pair you can consider the matching positions of any 8 points.

In your case you probably want a method that works without needing the camera parameters so that it works for unknown camera set-ups. For this you should probably look into methods for uncalibrated stereo reconstruction. My knowledge is actually quite thin on most of the theory, so the best I can do is to further provide you with some references that are hopefully useful (in order of relevance):

• I found a PDF chapter on Multiple View Geometry that contains most of the critical theory. In fact the textbook Multiple View Geometry in Computer Vision should also be quite useful (sample chapters available here).
• Here's a page describing a project on uncalibrated stereo reconstruction that seems to include some source code that could be useful. They find matching points in an automated manner using one of many feature detection techniques. If you want this part of the process to be automated as well, then SIFT feature detection is commonly considered to be an excellent non-real-time technique (since it's quite slow).
• A paper about Scene Reconstruction from Multiple Uncalibrated Views.
• A slideshow on Methods for 3D Reconstruction from Multiple Images (it has some more references below it's slides towards the end).
• A paper comparing different multi-view stereo reconstruction algorithms can be found here. It limits itself to algorithms that "reconstruct dense object models from calibrated views".
• Here's a paper that goes into lots of detail for the case that you have stereo cameras that take multiple images: Towards robust metric reconstruction via a dynamic uncalibrated stereo head. They then find methods to self-calibrate the cameras.
• I don't know if it's within the constraints of what you want to do, but the easiest method of capturing 3D models is to use other range imaging techniques like using the XBox's Kinect sensor for directly capturing depth data.

I'm not sure how helpful all of this is, but hopefully it includes enough useful terminology and references to find further resources. As you can see, this is far from a solved problem and is still actively researched. The less you want to do in an automated manner the more well-defined the problem becomes, but even in these cases quite a bit of theory is required to get started.

Answer 2

This problem is known as Photogrammetry.

Google will supply you with endless references, just be aware that if you want to roll your own, it's a very hard problem.

Answer 3

Check out The Deadalus Project, althought that website does not contain a gallery with illustrative information about the solution, it post several papers and info about the working method.

I watched a lecture from one of the main researchers of the project (Roger Hubbold), and the image results are quite amazing! Althought is a complex and long problem. It has a lot of tricky details to take into account to get an approximation of the 3d data, take for example the 3d information from wall surfaces, for which the heuristic to work is as follows: Take a photo with normal illumination of the scene, and then retake the picture in same position with full flash active, then substract both images and divide the result by a pre-taken flash calibration image, apply a box filter to this new result and then post-process to estimate depth values, the whole process is explained in detail in this paper (which is also posted/referenced in the project website)

Answer 4

Google Sketchup (free) has a photo matching tool that allows you to take a photograph and match its perspective for easy modeling.

EDIT: It appears that you're interested in developing your own solution. I thought you were trying to obtain a 3D model of an image in a single instance. If this answer isn't helpful, I apologize.