Vector Equations of Straight Lines in 2D and 3D Geometry
160 likes | 183 Vues
Learn about vector equations of straight lines, position vectors, parallel vectors, and conversions to Cartesian form with clear examples.
Vector Equations of Straight Lines in 2D and 3D Geometry
E N D
Presentation Transcript
Vectors (6) Vector Equation of a Line
Revise: Position Vectors a = xi + yj + zk z A In 2D and 3D, all points have position vectors a y e.g. The position vector of point A o x
-20 i + 30 j -10 i + 15 j 2 a a -2 i + 3 j 1/5a Revise: Parallel Vectors Vectors with a scaler applied are parallel i.e. with a different magnitude but same direction
Vector Equation of a line (2D) A a Any parallel vector (to line) (any point it passes through) y o x A line can be identified by a linear combination of a position vector and a free vector
Vector Equation of a line (2D) y Any parallel vector to line A a (any point it passes through) o x A line can be identified by a linear combination of a position vector and a free vector
Vector Equation of a line (2D) t is a scaler - it can be any number, since we only need a parallel vector a = xi+ yj b = pi+ qj A line can be identified by a linear combination of a position vector and a free vector y A parallel vector to line x o E.g. a + tb = (xi+ yj) + t(pi+ qj)
[ ] [ ] [ ] 2 2 2 2 2 2 [ ] [ ] [ ] 1 3 1 3 1 3 [ ] x y Scaler (any number) Vector Equation of a y = mx + c (1) 1. Position vector to any point on line y = x + 2 2. A free vector parallel to the line 3.linear combination of a position vector and a free vector = + t Equation
[ ] [ ] [ ] -3 -3 -3 -3 -3 -3 [ ] [ ] [ ] 4 6 4 6 4 6 = + t [ ] x y Scaler (any number) Vector Equation of a y = mx + c (2) 1. Position vector to any point on line y = x + 2 2. A free vector parallel to the line 3.linear combination of a position vector and a free vector Equation
[ ] [ ] [ ] 4 2 4 2 4 2 [ ] [ ] [ ] 2 4 2 4 2 4 [ ] x y Scaler (any number) Vector Equation of a y = mx + c (3) 1. Position vector to any point on line y = 1/2 x + 3 2. A free vector parallel to the line 3.linear combination of a position vector and a free vector = + t Equation
[ ] [ ] [ ] [ ] [ ] 1 2 1 2 1 2 When t=0 1 3 1 3 = x=1, y=2 When t=1 [ ] 2 5 = [ ] [ ] [ ] x y x y x y x=2, y=5 Sketch this line and find its equation y = 3x - 1 = + t
[ ] [ ] [ ] [ ] 1 2 1 2 1 3 1 3 = + t r = + t [ ] x y Equations of straight lines y = 3x - 1 ….. is a Cartesian Equation of a straight line ….. is a Vector Equation of a straight line Often written ……. r is the position vector of any point R on the line Any point Direction
[ ] [ ] [ ] [ ] [ ] 2 5 2 5 r 7 3 7 3 7 3 = + t the direction vector = + t Increase in y Gradient = Increase in x [ ] [ ] = x y x y Convert this Vector Equation into Cartesian form Gradient (m) = 5 / 2 = 2.5 Equations of form y= mx+c y= 2.5x + c When t = 0 3 = 2.5 x 7 + cc = -14.5 x = 7 y = 3 y= 2.5x – 14.5
[ ] [ ] [ ] [ ] 2 5 2 5 r 7 3 7 3 = + t = + t [ ] x y Convert this Vector Equation into Cartesian form (2) x = 7 + 2t y = 3 + 5t Convert to Parametric equations 5x = 35 + 10t 2y = 6 + 10t Eliminate ‘t’ 5x – 2y = 29 subtract
[ ] [ ] a b 1 m r = + t [ ] Any point 0 3 the direction vector = 4 1 Increase in y Gradient = [ ] Increase in x [ ] [ ] 1 4 0 3 1 4 r = + t Convert this Cartesian equation into a Vector equation Want something like this ………. y = 4x + 3 When x=0, y = 4 x 0 + 3 = 3 = Any point Gradient (m) = 4 represents the direction
Can replace with a parallel vector [ ] [ ] [ ] 0 3 x y 1/4 1 = + t [ ] [ ] 0 3 1 4 r = + t Convert this Cartesian equation into a Vector equation Easier Method y = 4x + 3 y - 3 = 4x = t Write: x = 1/4 t t = 4x t = y - 3 y = 3 + t
[ ] [ ] a b 1 m r = + t Any point the direction vector Summary A line can be identified by a linear combination of a position vector and a free [direction] vector Equations of form y-b=m(x-a) Line goes through (a,b) with gradient m
