I want to measure distance to an object using a 3d stereoscopic camera phone with opencv. I am looking for a formula which will measure the accuracy of the distance measurement, depending on the focal length, the distance between the 2 cameras, the image resolution, and the size of the measured object. Googling a little, I found this formula:

d = Z^2 * p / (f*b)

Z - distance to object, p - disparity accuracy, f - focal length, b - baseline (distance between cameras).

I know the baseline and the focal length, but I don't know the disparity accuracy. Is this formula what I need? If so, how do I find the disparity accuracy?



If you look at the paragraph after formula 8 in the document you link you can see that they have a disparity accuracy 0.18*10^-6m. Reading a bit further, I conclude that the disparity accuracy they use is the distance in m between two pixels on the CCD of the cameras used. For a 1/4" CCD (which measures 3.2mm by 2.4mm) with resolution 640X480 (a very old VGA camera) this would be 5*10^-6. I don't know what the sensor size for the LG Optimus 3D is, but assuming 1/4" CCD's and 2592 pixel horizontal resolution, the baseline for the disparity accuracy would be: 1.23*10^-6, giving a depth accuracy at 10m of about 0.85m. Which looks reasonable to me. If the CCD is smaller it will improve (i.e. the accuracy value lowers).

This is the lowest possible value that assumes perfect matching of features between the two stereo images. This value just represents the physical limitations of your stereo pair.

  • Thanks. I am trying to get a rough estimate of this value to see if my project is feasible. The phone I am currently targeting is LG optimus 3d. Its focal length is 6 mm and its baseline is 24 mm. I want to calculate the distance measurement error at 10 meters. Even if I assume that the disparity error is only 1 pixel, this doesn't make sense (or does it?) d = 10000^2 * 1 / (24 * 6) =~ 694 meters... What am I doing wrong? – barisdad Aug 18 '11 at 10:52
  • OK, My first mistake is that this isn't in meters. But I still don't understand what it means. – barisdad Aug 18 '11 at 11:03
  • ... and my second mistake is that this value is clearly below 1 (it's a ratio and not a pixel value). What could be an estimate of the disparity value of a car at 10 meters? – barisdad Aug 18 '11 at 11:28
  • Where did you find the formula? – jilles de wit Aug 18 '11 at 11:38

I realize this is a year late, but just in case someone finds this.

The formula is this:

dD = dd * D^2 / fB


  • dd = disparity error
  • dD = depth error
  • D = depth
  • f = focal length
  • B = baseline

if f = 6mm = 0.006m, B = 24mm = 0.024m, D = 10m, dd is 1 pixel [let's call it P for now, but it's usually about 1.4um].

Plugging all the numbers in gives:

dD = P * 10^2 / (0.006 * 0.024) ~ 694444 P

For P=1.4um, dD = 0.97 m (which is about 9.7%).

Now this is assuming that your correspondence gives single pixel error. You can do sub pixel search and depending on the noise level and texture in the image, you can get sub pixel accurate correspondence. In which case, your accuracy would be a little better.

NOTE that this formula is for error. The map between disparity and depth is as follows:

d = fB / D


  • d = disparity
  • D = depth
  • f = focal length
  • B = baseline

Similarly, plugging the numbers in gives:

d = (0.006 * 0.024 / 10) m = 0.0000144 m = 0.0144 mm = 14.4 um.

if you assume that your pixel size is about 1.4um, then 14.4um is about 10 pixels. This is consistent with the error above -- meaning that a 1 pixel error represents roughly 10%.

A car that is 10 meters away is shifted 10 pixels between the left and right sensors.

I hope that helps.

  • Hi @thang, my question is about the disparity error. Is it used as a typical value or calculated from given knowledge of the sensor parameters? – M Mahdi Chamseddine Dec 6 '16 at 9:49

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.