C. Direction Cosines of a Line
If α, β, γ are the angles which a given directed line makes with the positive direction of the axes. of x, y and z respectively, then cos a, cos β cos g are called the direction cosines (briefly written as d.c.'s) of the line. These d.c.'s are usually denoted by ℓ, m, n.
Let AB be a given line.Draw a line OP parallel to the line AB and passing through the origin O. Measure angles a, b, g, then cos a, cos β, cos g are the d.c.'s of the line AB. It can be easily seen that l, m, n, are the direction cosines of a line if and only if is a unit vector in the direction of that line.
Clearly, OP'(i.e. the line through O and parallel to BA) makes angle 180o - α, 180o - β, 180o - γ, with OX, OY and OZ respectively.
Hence d.c.'s of the line BA are cos (180o - α), cos (180o - β), cos (180o - γ) i.e., are -cos α, -cos β , - cos γ.
If the length of a line OP through the origin O be r, then the co-ordinates of P are (ℓr, mr, nr) where ℓ, m, n are the d c.'s of OP.
If ℓ, m, n are direction cosines of any line AB, then they will satisfy ℓ 2 + m2 + n2 = 1.
Direction Ratios :
If the direction cosines ℓ, m, n of a given line be proportional to any three numbers a, b, c respectively, then the numbers a, b, c are called direction ratios (briefly written as d.r.'s of the given line.
Relation Between Direction Cosines And Direction Ratios :
Let a, b, c be the direction ratios of a line whose d.c.’s are ℓ, m, n. From the definition of d.r.'s. we have ℓ/a = m/b = n/c = k (say). Then ℓ = ka, m = kb, n = kc. But ℓ2 + m2 + n2 = 1.
Taking the positive value of k, we get
Again taking the negative value of k, we get
Remark. Direction cosines of a line are unique. But the direction ratios of a line are by no means unique. If a, b, c are direction ratios of a line, then ka, kb, kc are also direction ratios of that line where k is any non-zero real number. Moreover if a, b, c are direction ratios of a line, then a ˆi + b ˆj + c kˆ is a vector parallel to that line.
Ex.4 Find the direction cosines ℓ + m + n of the two lines which are connected by the relation ℓ + m + n = 0 and mn - 2nℓ -2ℓm = 0.
Sol.
The given relations are ℓ+ m + n = 0 or ℓ = -m - n ....(1)
and mn - 2nℓ - 2ℓm = 0 ...(2)
Putting the value of ℓ from (1) in the relation (2), we get mn - 2n (-m -n) - 2(-m - n) m = 0 or 2m2 + 5mn + 2n2 = 0 or (2m + n) (m + 2n) = 0.
From (1), we have ...(3)
Now when ,
(3) given
∴
∴ The d.c.’s of one line are
i.e.
∴ The d.c.’s of the one line are
Again when
i.e.
∴ The d.c.’s of the other line are
To find the projection of the line joining two points P(x1, y1, z1) and Q(x2, y2, z2) on the another line whose d.c.’s are ℓ, m, n
Let O be the origin. Then
Now the unit vector along the line whose d.c.’s are ℓ,m,n
∴ projection of PQ on the line whose d.c.’s are ℓ, m, n
The angle q between these two lines is given by
If l1, m1, n1 and l2 , m2, n2 are two sets of real numbers, then
(l12 + m12 + n12) (l22 + m22 + n22) - (l1l2 + m1m2 + n1n2)2 = (m1n2 – m2n1)2 + (n1l2 - n2l1)2 + (l1m2 - l2m1)2
Now, we have
sin2 θ = 1 - cos2 θ = 1 - (l1l2 + m1m2 + n1n2)2 = (l12 + m12 + n12) (l22 + m22 + n22) - (l1l2 + m1m2 + n1n2)2
= (m1n2 – m2n1)2 + (n1l2 - n2l1)2 + (l1m2 - l2m1)2 =
Condition for perpendicularity
Condition for parallelism
Ex.5 Show that the lines whose d.c.’s are given by l + m + n = 0 and 2mn + 3ln - 5lm = 0 are at right angles.
Sol. From the first relation, we have l = -m - n. ..(i)
Putting this value of l in the second relation, we have
2mn + 3 (–m –n) n – 5 (–m –n) m = 0 or 5m2 + 4mn – 3n2 = 0 or 5(m/n)2 + 4(m/n) – 3 = 0 ....(2)
Let l1, m1, n1 and l2, m2, n2 be the d,c's of the two lines. Then the roots of (2) are m1/n1 and m2/n2.
product of the roots ...(3)
Again from (1), n = – l - m and putting this value of n in the second given relation, we have
2m (–l - m) + 3l(-l - m) - 5lm = 0
or 3(l/m)2 + 10 (l/m) + 2 = 0.
From (3) and (4) we have
l1l2 + m1m2 + n1n2 = (2 + 3 - 5) k = 0 . k = 0. ⇒ The lines are at right angles.
Remarks :
(a) Any three numbers a, b, c proportional to the directi on cosi nes are called the direction ratios
same sign either +ve or –ve should be taken throughout.
(b) If θ is the angle between the two lines whose d.c's are l 1 , m1, n1 and l 2 , m2, n2
cos θ = l1l2 + m1m2 + n1n2
Hence if lines are perpendicular then l1l2 + m1m2 + n1n2 = 0.
if lines are parallel then
Note that if three lines are coplanar then
(c) Projection of the join of two points on a line with d.c’s l, m, n are l (x2 – x1) + m(y2 – y1) + n(z2 – z1)
(d) If l1, m1, n1 and l2, m2, n2 are the d.c.s of two concurrent lines, show that the d.c.s of two lines bisecting the angles between them are proportional to l1 ± l2, m1 ± m2, n1 ± n2.
D. Area Of A Triangle
Show that the area of a triangle whose vertices are the origin and the points A(x1, y1, z1) and B( x2, y2, z2) is
The direction ratios of OA are x1, y1, z1 and those of OB are x2, y2, z2.
Also OA =
and OB =
∴ the d.c.' s of OA are
and the d.c.’s of OB are
Hence if q is the angle between the line OA and OB, then
Hence the area of ΔOAB
Ex.6 Find the area of the triangle whose vertices are A(1, 2, 3), B(2, –1, 1)and C(1, 2, –4).
Sol. Let Δx, Δy, Δz be the areas of the projecti ons of the area Δ of triangle ABC on the yz, zx and xy-planes respectively. We have
∴ the required area
Ex.7 A plane is passing through a point P(a, –2a, 2a), a ≠ 0, at right angle to OP, where O is the origin to meet the axes in A, B and C. Find the area of the triangle ABC.
Sol.
Equation of plane passing through P(a, –2a, 2a) is A(x – a) + B(y + 2a) + C(z – 2a) = 0.
∵ the direction cosines of the normal OP to the plane ABC are proportional to a – 0, –2a – 0, 2a – 0 i.e. a, –2a, 2a.
⇒ equation of plane ABC is a(x – a) – 2a(y + 2a) + 2a(z – 2a) = 0 or ax – 2ay + 2az = 9a2 ....(1)
Now projection of area of triangle ABC on ZX, XY and YZ
planes are the triangles AOC, AOB and BOC respectively.
∴ (Area ΔABC)2 = (Area ΔAOC)2 + (Area ΔAOB)2 + (Area ΔBOC)2
E. PLANE
(i) General equation of degree one in x, y, z i.e. ax + by + cz + d = 0 represents a plane.
(ii) Equation of a plane passing through (x1, y1, z1) is a(x – x1) + b (y – y1) + c(z – z1) = 0
where a, b, c are the direction ratios of the normal to the plane.
(iii) Equation of a plane if its intercepts on the co-ordinate axes are
(iv) Equation of a plane if the length of the perpendicular from the origin on the plane is ‘p’ and d.c’s of the perpendiculars as ℓ , m, n is lx + my + nz = p
(v) Parallel and perpendicular planes : Two planes a1 x + b1 y + c1z + d1 = 0 and a2 x + b2 y + c2 z + d2 = 0 are
Perpendicular if a1a2 + b1b2 + c1c2 = 0, parallel if
and Coincident if
(vi) Angle between a plane and a line is the complement of the angle between the normal to the plane and the line. If
where θ is the angle between the line and normal to the plane.
(vii) Length of the ⊥ar from a point (x1, y1, z1) to a plane ax + by + cz + d = 0 is p =
(viii) Distance between two parallel planes ax + by + cz + d1 = 0 and ax + by + cz + d2 = 0 is
(ix) Planes bisecting the angle between two planes a1x + b1y + c1z + d1 = 0 and a2 x + b2y + c2 z + d2 = 0 is given by
of these two bisecting planes, one bisects the acute and the other obtuse angle between the given planes.
(x) Equation of a plane through the intersection of two planes P1 and P2 is given by P1 + λP2 = 0
Ex.8 Reduce the equation of the plane x + 2y – 2z – 9 = 0 to the normal form and hence find the length of the perpendicular drawn form the origin to the given plane.
Sol. The equation of the given plane is x + 2y – 2z – 9 = 0
Bringing the constant term to the R.H.S., the equation becomes x + 2y – 2z = 9 ...(1)
[Note that in the equation (1) the constant term 9 is positive. If it were negative, we would have changed the sign throughout to make it positive.]
Now the square root of the sum of the squares of the coefficients of x, y, z in (1)
Dividing both sides of (1) by 3, we have
....(2)
The equation (2) of the plane is in the normal form ℓx + my + nz = p.
Hence the d.c.’s ℓ, m, n of the normal to the plane are 1/2,2/3,-2/3 and the length p of the perpendicular from the origin to the plane is 3.
Ex.9 Find the equation to the plane through the three points (0, –1, –1), (4, 5, 1) and (3, 9, 4).
Sol. The equation of any plane passing through the point (0, –1, –1) is given by a(x – 0) + b{y – (–1)} + c{z – (–1)} = 0 or ax + b(y + 1) + c (z + 1) = 0 ....(1)
If the plane (1) passes through the point (4, 5, 1), we have 4a + 6b + 2c = 0 ....(2)
If the plane (1) passes through the point (3, 9, 4), we have 3a + 10b + 5c = 0....(3)
Now solving the equations (2) and (3), we have
∴ a = 10λ, b = -14λ, c = 22λ.
Putting these value of a, b, c in (1), the equation of the required plane is given by
λ[10x - 14(y + 1) + 22(z + 1)] = 0 or 10x - 14(y + 1) + 22(z + 1) = 0 or 5x - 7y + 11z + 4 = 0.
F. STRAIGHT LINE
(i) Equation of a line through A(x1, y1, z1) and having direction cosines ℓ , m , n are and the lines through (x1, y1, z1) and (x2, y2, z2)
(ii) Intersection of two planes a1x + b1y + c1z + d1 = 0 and a2x + b2y + c2z + d2 = 0 together represent the un symmetrical form of the straight line.
(iii) General equation of the plane containing the line is A(x – x1) + B(y – y1) + c(z – z1) = 0 where A ℓ + bm + cn = 0.
(iv) Line of Greatest Slope AB is the line of intersection of G-plane and H is the h orizontal plane. Line of greatest slope on a given plane, drawn through a given point on the plane, is the line through the point 'P'perpendicular to the line of intersection of the given plane with any horizontal plane.
Ex.15 Show that the di stance of the point of inter section of the line and the plane x – y + z = 5 from the point (–1, –5, –10) is 13.
Sol. The equation of the given line are
= r (say) ....(1)
The co-ordinates of any point on the line (1) are (3r + 2, 4r - 1, 12 r + 2).
If this point lies on the plane x – y + z = 5, we have 3r + 2 – (4r – 1) + 12r + 2 = 5, or 11r = 0, or r = 0.
Putting this value of r, the co-ordinates of the point of intersection of the line (1) and the given plane are (2, –1, 2).
∴ The required distance = distance between the points (2, –1, 2) and (–1, –5, –10)
=
Ex.16 Find the co-ordinates of the foot of the perpendicular drawn from the origin to the plane 3x + 4y – 6z + 1 = 0. Find also the co-ordinates of the point on the line which is at the same distance from the foot of the perpendicular as the origin is.
Sol. The equation of the plane is 3x + 4y – 6z + 1 = 0. ....(1)
The direction ratios of the normal to the plane (1) are 3, 4, –6.
Hence the line normal to the plane (1) has d.r.’s 3, 4, –6, so that the equations of the line through (0, 0, 0) and perpendicular to the plane (1) are x/3 = y/4 = z/–6 = r (say) ....(2)
The co-ordinates of any point P on (2) are (3r, 4r, – 6r) ....(3) If this point lies on the plane (1), then 3(3r) + r(4r) – 6(–6r) + 1 = 0, or r = –1/61.
Putting the value of r in (3), the co-ordinates of the foot of the perpendicular P are (–3/61, –4/61, 6/61).
Now let Q be the point on the line which is at the same distance from the foot of the perpendicular as the origin. Let (x1, y1, z1) be the co-ordinates of the point Q. Clearly P is the middle point of OQ.
Hence we have
or x1 = 6/61, y1 = –8/61, z1 = 12/61.
∴ The co-ordinates of Q are (–6/61, –8/61, 12/61).
Ex.17 Find in symmetrical form the equations of the line 3x + 2y – z – 4 = 0 & 4x + y – 2z + 3 = 0 and find its direction cosines.
Sol. The equations of the given line in general form are 3x + 2y – z – 4 = 0 & 4x + y – 2z + 3 = 0 ..(1) Let l, m, n be the d.c.s of the line. Since the line is common to both the planes, it is perpendicular to the normals to both the planes. Hence we have 3l + 2m – n = 0, 4l + m – 2n = 0.
Solving these, we get
or
∴ the d.c.’s of the line are
Now to find the co-ordinates of a point on the line given by (1), let us find the point where it meets the plane z = 0.
Putting z = 0 i the equations given by (1), we have 3x + 2y – 4 = 0, 4x + y + 3 = 0.
Solving these, we get , or x = –2, y = 5.
Therefore the equation of the given line in symmetrical form is
Ex.18 Find the equation of the plane through the line 3x – 4y + 5z = 10, 2x + 2y – 3z = 4 and parallel to the line x = 2y = 3z.
Sol. The equation of the given line are 3x – 4y + 5z = 10, 2x + 2y – 3z = 4 ...(1)
The equation of any plane through the line (1) is (3x – 4y + 5z – 10) + l (2x + 2y - 3z - 4) = 0
or (3 + 2λ)x + (-4 +2λ) y + (5 - 3λ) z - 10 - 4λ = 0. ...(2)
The plane (1) will be parallel to the line x = 2y = 3z
(3 + 2λ) . 6 + (-4 + 2λ). 3 + (5 - 3λ).2 = 0 or λ(12 + 6 - 6) + 18 - 12 + 10 = 0 or λ =-4/3
Putting this value of l in (2), the required equation of the plane is given by
or x – 20y + 27z = 14.
Ex.19 Find the equation of a plane passing through the line and making an angle of 30° with the plane x + y + z = 5.
Sol. The equation of the required plane is (x – y + 1) + λ (2y + z - 6) = 0 Þ x + (2l - 1) y + λz + 1 - 6l = 0
Since it makes an angle of 30° with x +y + z = 5
are two required planes.
Ex.20 Prove that the lines 3x + 2y + z – 5 = 0 = x + y – 2z – 3 and 2x – y – z = 0 = 7x + 10y – 8z – 15 are perpendicular.
Sol. Let l1, m1, n1 be the d.c.s of the first line. Then 3l1 + 2m1 + n1 = 0, l1 + m1 - 2n1 = 0. Solving, we get
Again let l2, m2,n2 be the d.c.s of the second line, then 2l2 - m2 - n2 = 0, 7l2 + 10m2 - 8n2 = 0.
Hence the d.c.’s of the two given lines are proportional to –5, 7, 1 and 2, 1, 3.
We have –5.2 + 7.1 + 1.3 = 0
Therefore, the given lines are perpendicular.
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1. What are direction cosines of a line? |
2. How are direction cosines calculated? |
3. What is the significance of direction cosines? |
4. How can direction cosines be used to find the angle between two lines? |
5. Are direction cosines unique for a line? |
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