Calculate surface normals from depth image using neighboring pixels cross product
As the title says I want to calculate the surface normals of a given depth image by using the cross product of neighboring pixels. I would like to use Opencv for that and avoid using PCL however, I do not really understand the procedure, since my knowledge is quite limited in the subject. Therefore, I would be grateful is someone could provide some hints. To mention here that I do not have any other information except the depth image and the corresponding rgb image, so no K camera matrix information.
Thus, lets say that we have the following depth image:
and I want to find the normal vector at a corresponding point with a corresponding depth value like in the following image:
How can I do that using the cross product of the neighbouring pixels? I do not mind if the normals are not highly accurate.
Thanks.
Update:
Ok, I was trying to follow @timday's answer and port his code to Opencv. With the following code:
Mat depth = <my_depth_image> of type CV_32FC1
Mat normals(depth.size(), CV_32FC3);
for(int x = 0; x < depth.rows; ++x)
{
for(int y = 0; y < depth.cols; ++y)
{
float dzdx = (depth.at<float>(x+1, y) - depth.at<float>(x-1, y)) / 2.0;
float dzdy = (depth.at<float>(x, y+1) - depth.at<float>(x, y-1)) / 2.0;
Vec3f d(-dzdx, -dzdy, 1.0f);
Vec3f n = normalize(d);
normals.at<Vec3f>(x, y) = n;
}
}
imshow("depth", depth / 255);
imshow("normals", normals);
I am getting the correct following result (I had to replace double with float and Vecd to Vecf, I do not know why that would make any difference though):
You don't really need to use the cross product for this, but see below.
Consider your range image is a function z(x,y).
The normal to the surface is in the direction (-dz/dx,-dz/dy,1). (Where by dz/dx I mean the differential: the rate of change of z with x). And then normals are conventionally normalized to unit length.
Incidentally, if you're wondering where that (-dz/dx,-dz/dy,1) comes from... if you take the 2 orthogonal tangent vectors in the plane parellel to the x and y axes, those are (1,0,dzdx) and (0,1,dzdy). The normal is perpendicular to the tangents, so should be (1,0,dzdx)X(0,1,dzdy) - where 'X' is cross-product - which is (-dzdx,-dzdy,1). So there's your cross product derived normal, but there's little need to compute it so explicitly in code when you can just use the resulting expression for the normal directly.
Pseudocode to compute a unit-length normal at (x,y) would be something like
dzdx=(z(x+1,y)-z(x-1,y))/2.0;
dzdy=(z(x,y+1)-z(x,y-1))/2.0;
direction=(-dzdx,-dzdy,1.0)
magnitude=sqrt(direction.x**2 + direction.y**2 + direction.z**2)
normal=direction/magnitude
Depending on what you're trying to do, it might make more sense to replace the NaN values with just some large number.
Using that approach, from your range image, I can get this:
(I'm then using the normal directions calculated to do some simple shading; note the "steppy" appearance due to the range image's quantization; ideally you'd have higher precision than 8-bit for the real range data).
Sorry, not OpenCV or C++ code, but just for completeness: the complete code which produced that image (GLSL embedded in a Qt QML file; can be run with Qt5's qmlscene) is below. The pseudocode above can be found in the fragment shader's main() function:
import QtQuick 2.2
Image {
source: 'range.png' // The provided image
ShaderEffect {
anchors.fill: parent
blending: false
property real dx: 1.0/parent.width
property real dy: 1.0/parent.height
property variant src: parent
vertexShader: "
uniform highp mat4 qt_Matrix;
attribute highp vec4 qt_Vertex;
attribute highp vec2 qt_MultiTexCoord0;
varying highp vec2 coord;
void main() {
coord=qt_MultiTexCoord0;
gl_Position=qt_Matrix*qt_Vertex;
}"
fragmentShader: "
uniform highp float dx;
uniform highp float dy;
varying highp vec2 coord;
uniform sampler2D src;
void main() {
highp float dzdx=( texture2D(src,coord+vec2(dx,0.0)).x - texture2D(src,coord+vec2(-dx,0.0)).x )/(2.0*dx);
highp float dzdy=( texture2D(src,coord+vec2(0.0,dy)).x - texture2D(src,coord+vec2(0.0,-dy)).x )/(2.0*dy);
highp vec3 d=vec3(-dzdx,-dzdy,1.0);
highp vec3 n=normalize(d);
highp vec3 lightDirection=vec3(1.0,-2.0,3.0);
highp float shading=0.5+0.5*dot(n,normalize(lightDirection));
gl_FragColor=vec4(shading,shading,shading,1.0);
}"
}
}
- How portable is code with #pragma optimize?
- Make warn_unused_result applied to all function with GCC
- Multiple threads and CPU cache
- Linking error vs. compilation error
- how to compile multiple instances of a source file linking to it different files.o
- Background compile in VS2010 and C/C++
- What Turing complete macro languages are available for C/C++
- How to use Cython to compile Python 3 into C
- Are forward declarations needed when the typedef declaration is done?
- How to assign real and imaginary parts of complex variables in C
- Strict aliasing between Complex numbers and real numbers in C
- How to CORRECTLY install gsl library in Linux?
- Using = operator on atomic variable?
- Unknown conversion types in this program I'm meant to compile
- Iterator in C language
- Treating __func__ as a string literal instead of a predefined identifier
- c - strcpy with struct string returning error
- Segmentation fault when executing a Python script in a C program?
- Questions about C Function Prototypes and Compilation
- What is the purpose of "-Wa,option" in GCC?
- Do we have c99 subflags
- netcat gcc compile option so that IDA pro can show function name
- What is the correct way to free output buffer after call to openssl::i2d_X509?
- How can I link C++ files to a C program?
- Why doesn't this program in C compile? Error: undefined reference to `i2c_smbus_read_byte_data'
- integer promotion isn't taken into account
- Why do I get a SEGFAULT when I try to sort an array of integers using K & R code examples?
- Are C preprocessor statements a part of the C language?
- FFMPEG Api conversion from YUV420P to RGB produces strange output
- Why is the tree constructed this way incorrect?