diff --git a/doc/js_tutorials/js_video/js_lucas_kanade/js_lucas_kanade.markdown b/doc/js_tutorials/js_video/js_lucas_kanade/js_lucas_kanade.markdown index a86bf11223baa6c77665241197d80e05cc00068c..f4e4f231b078b18ca45890d52cdb0a7c8436b15d 100644 --- a/doc/js_tutorials/js_video/js_lucas_kanade/js_lucas_kanade.markdown +++ b/doc/js_tutorials/js_video/js_lucas_kanade/js_lucas_kanade.markdown @@ -133,9 +133,9 @@ Dense Optical Flow in OpenCV.js Lucas-Kanade method computes optical flow for a sparse feature set (in our example, corners detected using Shi-Tomasi algorithm). OpenCV.js provides another algorithm to find the dense optical flow. It -computes the optical flow for all the points in the frame. It is based on Gunner Farneback's +computes the optical flow for all the points in the frame. It is based on Gunnar Farneback's algorithm which is explained in "Two-Frame Motion Estimation Based on Polynomial Expansion" by -Gunner Farneback in 2003. +Gunnar Farneback in 2003. We use the function: **cv.calcOpticalFlowFarneback (prev, next, flow, pyrScale, levels, winsize, iterations, polyN, polySigma, flags)** diff --git a/doc/tutorials/video/optical_flow/optical_flow.markdown b/doc/tutorials/video/optical_flow/optical_flow.markdown index 45bbfa46ce0ad110cedf884980ed23f4b4534b90..a9faf9be13c46c87ae37801d2b2af0c61d5394e7 100644 --- a/doc/tutorials/video/optical_flow/optical_flow.markdown +++ b/doc/tutorials/video/optical_flow/optical_flow.markdown @@ -136,9 +136,9 @@ Dense Optical Flow in OpenCV Lucas-Kanade method computes optical flow for a sparse feature set (in our example, corners detected using Shi-Tomasi algorithm). OpenCV provides another algorithm to find the dense optical flow. It -computes the optical flow for all the points in the frame. It is based on Gunner Farneback's +computes the optical flow for all the points in the frame. It is based on Gunnar Farneback's algorithm which is explained in "Two-Frame Motion Estimation Based on Polynomial Expansion" by -Gunner Farneback in 2003. +Gunnar Farneback in 2003. Below sample shows how to find the dense optical flow using above algorithm. We get a 2-channel array with optical flow vectors, \f$(u,v)\f$. We find their magnitude and direction. We color code the