calculating parallel lines in a circle

Question

I am calculating lines (2 sets of coordinates ) ( the purple and green-blue lines ) that are n perpendicular distance from an original line. (original line is pink ) ( distance is the green arrow )

How do I get the coordinates of the four new points?

I have the coordinates of the 2 original points and their angles. ( pink line )

I need it to work if the lines are vertical, or any other orientation.

Right now I am trying to calculate it by: 1. get new point n distance perpendicular to the two old points 2. find where the circle intersects the new line I have defined.

I feel like there is an easier way.

Answer 1

Similarly to @MBo's answer, let's assume that the center is (0,0) and that your initial two points are:

P0 = (x0, y0) and P1 = (x1, y1)

A point on the line P0P1 has the form:

(x, y) = c(x1 - x0, y1 - y0) + (x0, y0)

for some constant c.

Let (u, v) be the normal to the line P0P1:

(u, v) = (y1 - y0, x1 - x0) / sqrt((x1 - x0)^2 + (y1 - y0)^2)

A point on any of the lines parallel to P0P1 has the form:

(x, y) = c(x1 - x0, y1 - y0) + (x0, y0) +/- (u, v)* n         {eq 1}

where n is the perpendicular distance between lines and c is a constant.

What remains here is to find the values of c such that (x,y) is on the circle. But these can be calculated by solving the following two quadratic equations:

(c(x1 - x0) + x0 +/- u*n)^2 + (c(y1 - y0) + y0 +/- v*n)^2 = r^2

where r is the radius. Note that these equations can be written as:

c^2(x1 - x0)^2 + 2c(x1 - x0)*(x0 +/- u*n) + (x0 +/- u*n)^2
 + c^2(y1 - y0)^2 + 2c(y1 - y0)*(y0 +/- v*n) + (y0 +/- v*n)^2 = r^2

or

A*c^2 + B*c + D = 0

where

A = (x1 - x0)^2 + (y1 - y0)^2
B = 2(x1 - x0)*(x0 +/- u*n) + 2(y1 - y0)*(y0 +/- v*n)
D = (x0 +/- u*n)^2 + (y0 +/- v*n)^2 - r^2

which are actually two quadratic equations one for each selection of the +/- signs. The 4 solutions of these two equations will give you the four values of c from which you will get the four points using {eq 1}

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UPDATE

Here are the two quadratic equations (I've reused the letters A, B and C but they are different in each case):

A*c^2 + B*c + D = 0                                           {eq 2}

where

A = (x1 - x0)^2 + (y1 - y0)^2
B = 2(x1 - x0)*(x0 + u*n) + 2(y1 - y0)*(y0 + v*n)
D = (x0 + u*n)^2 + (y0 + v*n)^2 - r^2

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A*c^2 + B*c + D = 0                                           {eq 3}

where

A = (x1 - x0)^2 + (y1 - y0)^2
B = 2(x1 - x0)*(x0 - u*n) + 2(y1 - y0)*(y0 - v*n)
D = (x0 - u*n)^2 + (y0 - v*n)^2 - r^2

Answer 2

Let's circle radius is R, circle center is (0,0) (if not, shift all coordinates to simplify math), first chord end is P0=(x0, y0), second chord end is P1=(x1,y1), unknown new chord end is P=(x,y). Chord length L is

L = Sqrt((x1-x0)^2 + (y1-y0)^2)

Chord ends lie on the circle, so

x^2 + y^2 = R^2   {1}

Doubled area of triangle PP0P1 might be expressed as product of the base and height and through absolute value of cross product of two edge vectors, so

+/- L * n = (x-x0)*(y-y1)-(x-x1)*(y-y0) =   {2}
        x*y - x*y1 - x0*y + x0*y1 - x*y + x*y0 + x1*y - x1*y0 = 
        x * (y0-y1) + y * (x1-x0) + (x0*y1-x1*y0)

Solve system of equation {1} and {2}, find coordinates of new chord ends. (Up to 4 points - two for +L*n case, two for -L*n case)

I cannot claim though that this method is simpler - {2} is essentially an equation of parallel line, and substitution in {1} is intersection with circle.