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I managed to draw a bezier curve like:

glColor3f(0,1,0);
glBegin(GL_LINE_STRIP);
for (int i = 3; i < nPt; i+=3) {
    glColor3f(0,0,0);
    for (float k = 0; k < NLINESEGMENT+1; k++) {
        float x = pow(1.0-k/NLINESEGMENT,3)*ptList[i-3].x +
            3*(k/NLINESEGMENT)*pow(1.0-k/NLINESEGMENT, 2) * ptList[i-2].x +
            3*(1.0-k/NLINESEGMENT)*pow(k/NLINESEGMENT, 2) * ptList[i-1].x +
            pow(k/NLINESEGMENT, 3)*ptList[i].x;
        float y = pow(1.0-k/NLINESEGMENT,3)*ptList[i-3].y +
            3*(k/NLINESEGMENT)*pow(1.0-k/NLINESEGMENT, 2) * ptList[i-2].y +
            3*(1.0-k/NLINESEGMENT)*pow(k/NLINESEGMENT, 2) * ptList[i-1].y +
            pow(k/NLINESEGMENT, 3)*ptList[i].y;
        glVertex2d(x,y);
    }
}
glEnd();

Now I want to add tangent arrows for each point, how can I do that? I am given a function that draws an arrow. So I believe I need to just rotate the reference frame and draw that arrow. But how do I compute the rotation? I think I need to differenciate the equations, but the question still remains, how do I use that?

UPDATE

enter image description here

As every 4th point is put, a curve is drawn.

I am supposed to achieve something like below

enter image description here

Full Source

UPDATE 2

Ok I made an attempt at drawing the tangents like:

glColor3f(0,1,0);
for (int i = 3; i < nPt; i+=3) {
    for (int n = 0; n < NOBJECTONCURVE; n++) {
        float t = (float)n/NOBJECTONCURVE;
        float x0 = points[i-3].x,
                x1 = points[i-2].x,
                x2 = points[i-1].x, 
                x3 = points[i].x;
        float y0 = points[i-3].y,
                y1 = points[i-2].y,
                y2 = points[i-1].y, 
                y3 = points[i].y;

        float x = pow(1.0-t, 3) * points[i-3].x +
            3 * t * pow(1.0 - t, 2) * points[i-2].x +
            3 * (1.0 - t) * pow(t, 2) * points[i-1].x +
            pow(t, 3)*points[i].x;
        float y = pow(1.0-t, 3) * points[i-3].y +
            3 * t * pow(1.0 - t, 2) * points[i-2].y +
            3 * (1.0 - t) * pow(t, 2) * points[i-1].y +
            pow(t, 3)*points[i].y;

        float dx = -3*(1-t)*x0 + 3*x1*((2*t)*(t-1)+pow((1-t),2)) + 3*x2*(2*t*(1-t)-pow(t,2)) + 3*pow(t,2)*x3;
        float dy = -3*(1-t)*y0 + 3*y1*((2*t)*(t-1)+pow((1-t),2)) + 3*y2*(2*t*(1-t)-pow(t,2)) + 3*pow(t,2)*y3;
        float angle = atan(dy/dx);

        glPushMatrix();
        glTranslatef(x, y, 0);
        glRotatef(angle * 180 / 3.14159265, 0, 0, 1);
        drawRightArrow();
        glPopMatrix();
    }
}

enter image description here

But as you can see the tangents appear to be incorrect especially in the middle of a bezier curve?

share|improve this question
    
IMO in this type of questions a screenshot of what you done, can make the question better. –  M M. Oct 26 '13 at 9:54
    
@MM. added an image. –  Jiew Meng Oct 26 '13 at 10:01
1  
@JiewMeng In x0, y0 tangent angle is ang=arctan(dy/dx). Arrow's coordinates (arrow of length l) then: (x0,y0) - (l * cos(ang), l * sin(ang)). –  Petr Budnik Oct 26 '13 at 10:17
    
@PetrBudnik: Why do you calculate an angle if you convert it to a vector again right afterwards? –  Nico Schertler Oct 26 '13 at 15:45
    
@NicoSchertler Because angle is independent of dx and dy which, generally, vary from point to point. –  Petr Budnik Oct 26 '13 at 16:42

2 Answers 2

up vote 3 down vote accepted

Because we don't want to interrupt the line strip, it is reasonable to make another loop that draws the arrows. In this loop, we can skip some steps, because we probably don't want arrows after each step. The arrows can be drawn as a 'GL_LINES' primitive.

For readability I'd recommend to define the parameter t in the inner loop as

float t = (float)k/NLINESEGMENT;

Now we need to calculate the derivative of the curve with respect to t at this point. This derivative can be calculated for each coordinate independently. It looks like this question is a homework, so I'll leave that to you

float dx = ... //derivative of x-component with respect to t
float dy = ... //derivative of y-component with respect to t

We will also need the curve point. Ideally you have saved it in the previous loop in an array or similar structure.

So we can draw the arrow's base line (where s is a custom scale factor):

glVertex2d(x, y);
glVertex2d(x + s * dx, y + s * dy);

We will also need the actual arrow. An orthogonal vector to the arrow direction is (-dy, dx). So we can just combine the direction and the orthogonal direction to get the arrow:

glVertex2d(x + s * dx, y + s * dy);
glVertex2d(x + 0.9 * s * dx - 0.1 * dy, y + 0.9 * s * dy + 0.1 * dx);
glVertex2d(x + s * dx, y + s * dy);
glVertex2d(x + 0.9 * s * dx + 0.1 * dy, y + 0.9 * s * dy - 0.1 * dx);

This will result in a 90° arrow. You can change the angle by adjusting the coefficients (0.9 and 0.1).

Update

Your derivative is closer to the actual solution, but still contains some mistakes: Bezier derivative

Furthermore, when calculating the angle, use the atan2 function. This allows you to get angles greater than PI/2:

float angle = atan2(dy,dx);
share|improve this answer
    
dx and dy, generally, vary from point to point. In this case your arrows will have different lengths. Unless you normalize on sqrt(dx * dx + dy * dy). –  Petr Budnik Oct 26 '13 at 16:43
    
It was my intention to make the arrows' lengths proportional to the derivative's length. But that depends on the task, of course. –  Nico Schertler Oct 26 '13 at 17:15
    
This will not make them proportional to the "derivative length". Derivative is dy/dx (it's actually lim dy/dx with dx->0). Its value is the same for, say, dx = 1, dy = 0.5 and dx = 10000, dy = 5000, and is equal to 0.5. But your arrows' lengths in this case will differ 10000 times. That's why you have to work with the angle one way or another (you can use dy/dx = tan(ang) if you like). –  Petr Budnik Oct 26 '13 at 17:39
    
I'm talking about the derivatives of x and y with respect to t (dx/dt and dy/dt). The derivative of y with respect to x is somewhat harder to calculate and may contain discontinuities (for vertical line parts). Therefore, it is not a good idea to use it for displaying the tangent vector. Furthermore, y can usually not be described as a function of x. There may be more than 1 y-value for a given x. –  Nico Schertler Oct 26 '13 at 17:52
    
IMHO, you do not need t. You have an array of discrete 2D points representing a function. You need to find derivative dy/dx in each point numerically to get the tangent line. Again, the function is not differentiable analytically - it's a set of discrete points... For dx = 0 we have infinite derivative, so we just draw a vertical line... Furthermore, the fact that a function has more than one y for a given x does not make it non-differentiable. Think of the equation of a circle. Derivative exits everywhere except, ironically, for two points with a single y value. –  Petr Budnik Oct 26 '13 at 22:17

My two cents, hope it helps.

If I understood correctly, essentially, you have an array of 2D points with (x, y) coordinates representing some function y = f(x). You want to find tangent vector in each of these points (and plot it, eventually, together with the function itself).

In this light, the function itself is not important, really. So, I used y^2 = R^2 - x^2 - equation of a circle with center in origin to fill in function's array (you can substitute your own function, obviously). The code below finds derivative in each point (except for the end points) using a very simple method: derivative in i-th point is y'_i = f'(x[i]) = (f(x[i+1]) - f(x[i-1])) / (x_[i+1] - x_[i-1]), where _i denotes subscript. The code then finds the coordinates of the end of the tangent vector of the constant length with respect to the given function's point. It takes into account the direction in we which we walk along the function's array. In the end the code outputs coordinates of the tangent vector with respect to the origin of the coordinate system (something you'll use to plot it; you'll have to add actual arrow on the end yourself). It also outputs tangent vector's length, derivative value and the corresponding angle, just for fun ;). Note, the angle's value is in the range [-PI/2, PI/2] - the way std::atan() returns it. I didn't bother to convert it to [0, 2*PI] range to represent the actual rotation of the tangent vector from positive x-axis since we don't really need this value.

Here is the code (same code on ideone.com):

#include <vector>
#include <iostream>
#include <cmath>
#include <limits>
#include <iomanip>

namespace so
{
using _data_ = float;

namespace cnst
{
constexpr static std::size_t size_point {360};
constexpr static _data_ radius {100};
constexpr static _data_ length_arrow {5};

constexpr _data_ get_pi()
{
 return (std::atan(1) * 4);
}
} //namespace so::cnst

struct _point_
{
  _data_ x;
  _data_ y;
};
} // namespace so

int main()
{
 std::cout.setf(std::ios_base::fixed); // setting floating point output precision

 std::vector<so::_point_> function_(so::cnst::size_point); // 'y = f(x)' function's value and argument
 // Filling in function's value and argument. Using 'y^2 = R^2 - x^2' function (a circle with center in origin with radius 'R').
 for (std::size_t i_ = 0; i_ < function_.size(); ++i_)
 {
  function_[i_].x = so::cnst::radius * std::cos(2 * so::cnst::get_pi() / so::cnst::size_point * i_);
  function_[i_].y = so::cnst::radius * std::sin(2 * so::cnst::get_pi() / so::cnst::size_point * i_);
 }

 // In simple model, cannot calculate value of derivative in end points (no arrow too, therefore). So these arrays have
 // 'function_.size() - 2 )' elements corresponding to 'function_[1] ... function_[function_.size() - 2]' points.
 std::vector<so::_data_> derivative_(function_.size() - 2); // derivative's value
 std::vector<so::_point_> arrow_(function_.size() - 2); // arrow's end with respect to function's point
 // Simple way to calculate derivative. Calculate arrow's end as well.
 for (std::size_t i_ = 1; i_ < function_.size() - 1; ++i_)
 {
  if ((function_[i_ + 1].x - function_[i_ - 1].x) != 0) // derivative is finite
  {
   derivative_[i_ - 1] = (function_[i_ + 1].y - function_[i_ - 1].y) / (function_[i_ + 1].x - function_[i_ - 1].x);
   arrow_[i_ - 1].x = std::copysign(so::cnst::length_arrow * std::cos(std::atan(derivative_[i_ - 1])),
                                    (function_[i_ + 1].x - function_[i_ - 1].x));
   arrow_[i_ - 1].y = std::copysign(so::cnst::length_arrow * std::sin(std::atan(derivative_[i_ - 1])),
                                    (function_[i_ + 1].y - function_[i_ - 1].y));
  }
  else // derivative is infinite; arrow's end 'x = 0', 'y' depends on the sign of the infinite derivative
  {
   derivative_[i_ - 1] = std::copysign(std::numeric_limits<so::_data_>::infinity(), function_[i_ + 1].y - function_[i_ - 1].y);
   arrow_[i_ - 1].x = 0;
   arrow_[i_ - 1].y = std::copysign(so::cnst::length_arrow, (function_[i_ + 1].y - function_[i_ - 1].y));
  }
 }

 // Output point's number, arrow's coordinates, arrow's length, derivative and the corresponding angle.
 // Format: 'number : (x0, y0) - (x1, y1) : length : derivative : angle'
 for (std::size_t i_ = 1; i_ < function_.size() - 1; ++i_)
 {
  std::cout << std::setw(4) << i_ << " | (" << function_[i_].x << ", " << function_[i_].y << ") - ("
            << (function_[i_].x + arrow_[i_ - 1].x) << ", " << (function_[i_].y + arrow_[i_ - 1].y) << ") | "
            << std::sqrt((arrow_[i_ - 1].x * arrow_[i_ - 1].x) + (arrow_[i_ - 1].y * arrow_[i_ - 1].y)) << " | "
            << derivative_[i_ - 1] << " | " << std::atan(derivative_[i_ - 1]) / so::cnst::get_pi() * so::cnst::size_point / 2
            << "\n";
 }

 return (0);
}
share|improve this answer
    
Your assumption is incorrect from the start - a Bezier isn't a direct correlation between X and Y, it's x=f(t), y=g(t) for t=0→1. –  Mark Ransom Oct 26 '13 at 23:08
    
@MarkRansom I was talking about actual array of 2D points to plot. In this respect, it does not matter how it is filled. –  Petr Budnik Oct 26 '13 at 23:57

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