Class 12 Maths Three Dimensional Geometry – Get here the Notes for Class 12 Maths Three Dimensional Geometry. Candidates who are ambitious to qualify the Class 12 with good score can check this article for Notes. This is possible only when you have the best CBSE Class 12 Maths study material and a smart preparation plan. To assist you with that, we are here with notes. Hope these notes will helps you understand the important topics and remember the key points for exam point of view. Below we provided the Notes of Class 12 Maths for topic Three Dimensional Geometry.

**Class:**12th**Subject:**Maths**Topic:**Three Dimensional Geometry**Resource:**Notes

## CBSE Class 12 Maths Notes: Three Dimensional Geometry

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**Coordinate System**

The three mutually perpendicular lines in a space which divides the space into eight parts and if these perpendicular lines are the coordinate axes, then it is said to be a coordinate system.

**Sign Convention**

**Distance between Two Points**

Let P(x_{1}, y_{1}, z_{1}) and Q(x_{2}, y_{2}, z_{2}) be two given points. The distance between these points is given by

PQ √(x_{2} – x_{1})^{2} + (y_{2} – y_{1})^{2} + (z_{2} – z_{1})^{2}

The distance of a point P(x, y, z) from origin O is

OP = √x^{2} + y^{2} + z^{2}

**Section Formulae**

(i) The coordinates of any point, which divides the join of points P(x_{1}, y_{1}, z_{1}) and Q(x_{2}, y_{2}, z_{2}) in the ratio m : n internally are

(mx_{2} + nx_{1} / m + n, my_{2} + ny_{1} / m + n, mz_{2} + nz_{1} / m + n)

(ii) The coordinates of any point, which divides the join of points P(x_{1}, y_{1}, z_{1}) and Q(x_{2}, y_{2}, z_{2}) in the ratio m : n externally are

(mx_{2} – nx_{1} / m – n, my_{2} – ny_{1} / m – n, mz_{2} – nz_{1} / m – n)

(iii) The coordinates of mid-point of P and Q are

(x_{1} + x_{2} / 2 , y_{1} + y_{2} / 2, z_{1} + z_{2} / 2)

(iv) Coordinates of the centroid of a triangle formed with vertices P(x_{1}, y_{1}, z_{1}) and Q(x_{2}, y_{2}, z_{2}) and R(x_{3}, y_{3}, z_{3}) are

(x_{1} + x_{2} + x_{3} / 3 , y_{1} + y_{2} + y_{3} / 3, z_{1} + z_{2} + z_{3} / 3)

(v) **Centroid of a Tetrahedron**

If (x_{1}, y_{1}, z_{1}), (x_{2}, y_{2}, z_{2}), (x_{3}, y_{3}, z_{3}) and (x_{4}, y_{4}, z_{4}) are the vertices of a tetrahedron, then its centroid G is given by

(x_{1} + x_{2} + x_{3} + x_{4 } / 4 , y_{1} + y_{2} + y_{3} + y_{4} / 4, z_{1} + z_{2} + z_{3} + z_{4} / 4)

**Direction Cosines**

If a directed line segment OP makes angle α, β and γ with OX , OY and OZ respectively, then Cos α, cos β and cos γ are called direction cosines of up and it is represented by l, m, n.

i.e.,

l = cos α

m = cos β

and n = cos γ

If OP = r, then coordinates of OP are (lr, mr , nr)

(i) If 1, m, n are direction cosines of a vector r, then

(a) r = |r| (li + mj + nk) ⇒ r = li + mj + nk

(b) l^{2} + m^{2} + n^{2} = 1

(c) Projections of r on the coordinate axes are

(d) |r| = l|r|, m|r|, n|r| / √sum of the squares of projections of r on the coordinate axes

(ii) If P(x_{1}, y_{1}, z_{1}) and Q(x_{2}, y_{2}, z_{2}) are two points, such that the direction cosines of PQ are l, m, n. Then,

x_{2} – x_{1} = l|PQ|, y_{2} – y_{1} = m|PQ|, z_{2} – z_{1} = n|PQ|

These are projections of PQ on X , Y and Z axes, respectively.

(iii) If 1, m, n are direction cosines of a vector r and a b, c are three numbers, such that l / a = m / b = n / c.

Then, we say that the direction ratio of r are proportional to a, b, c.

Also, we have

l = a / √a^{2} + b^{2} + c^{2}, m = b / √a^{2} + b^{2} + c^{2}, n = c / √a^{2} + b^{2} + c^{2}

(iv) If θ is the angle between two lines having direction cosines l_{1}, m_{1}, n_{1} and 1_{2}, m_{2}, n_{2}, then

cos θ = l_{1}1_{2} + m_{1}m_{2} + n_{1}n_{2}

(a) Lines are parallel, if l_{1} / 1_{2} = m_{1} / m_{2} = n_{1} / n_{2}

(b) Lines are perpendicular, if l_{1}1_{2} + m_{1}m_{2} + n_{1}n_{2}

(v) If θ is the angle between two lines whose direction ratios are proportional to a_{1}, b_{1}, c_{1} and a_{2}, b_{2}, c_{2} respectively, then the angle θ between them is given by

cos θ = a_{1}a_{2} + b_{1}b_{2} + c_{1}c_{2} / √a^{2}_{1} + b^{2}_{1} + c^{2}_{1} √a^{2}_{2} + b^{2}_{2} + c^{2}_{2}

Lines are parallel, if a_{1} / a_{2} = b_{1} / b_{2} = c_{1} / c_{2}

Lines are perpendicular, if a_{1}a_{2} + b_{1}b_{2} + c_{1}c_{2} = 0.

(vi) The projection of the line segment joining points P(x_{1}, y_{1}, z_{1}) and Q(x_{2}, y_{2}, z_{2}) to the line having direction cosines 1, m, n is

|(x_{2} – x_{1})l + (y_{2} – y_{1})m + (z_{2} – z_{1})n|.

(vii) The direction ratio of the line passing through points P(x_{1}, y_{1}, z_{1}) and Q(x_{2}, y_{2}, z_{2}) are proportional to x_{2} – x_{1}, y_{2} – y_{1} – z_{2} – z_{1} Then, direction cosines of PQ are

x_{2} – x_{1} / |PQ|, y_{2} – y_{1} / |PQ|, z_{2} – z_{1} / |PQ|

**Area of Triangle**

If the vertices of a triangle be A(x_{1}, y_{1}, z_{1}) and B(x_{2}, y_{2}, z_{2}) and C(x_{3}, y_{3}, z_{3}), then

**Angle Between Two Intersecting Lines**

If l(x_{1}, m_{1}, n_{1}) and l(x_{2}, m_{2}, n_{2}) be the direction cosines of two given lines, then the angle θ between them is given by

cos θ = l_{1}1_{2} + m_{1}m_{2} + n_{1}n_{2}

(i) The angle between any two diagonals of a cube is cos^{-1} (1 / 3).

(ii) The angle between a diagonal of a cube and the diagonal of a face (of the cube is cos^{-1} (√2 / 3)

**Straight Line in Space**

The two equations of the line ax + by + cz + d = 0 and a’ x + b’ y + c’ z + d’ = 0 together represents a straight line.

1. Equation of a straight line passing through a fixed point A(x_{1}, y_{1}, z_{1}) and having direction ratios a, b, c is given by

x – x_{1} / a = y – y_{1} / b = z – z_{1} / c, it is also called the symmetrically form of a line.

Any point P on this line may be taken as (x_{1} + λa, y_{1} + λb, z_{1} + λc), where λ ∈ R is parameter. If a, b, c are replaced by direction cosines 1, m, n, then λ, represents distance of the point P from the fixed point A.

2. Equation of a straight line joining two fixed points A(x_{1}, y_{1}, z_{1}) and B(x_{2}, y_{2}, z_{2}) is given by

x – x_{1} / x_{2} – x_{1} = y – y_{1} / y_{2} – y_{1} = z – z_{1} / z_{2} – z_{1}

3. Vector equation of a line passing through a point with position vector a and parallel to vector b is r = a + λ b, where A, is a parameter.

4. Vector equation of a line passing through two given points having position vectors a and b is r = a + λ (b – a) , where λ is a parameter.

5. (a) The length of the perpendicular from a point on the line r – a + λ b is given by

(b) The length of the perpendicular from a point P(x_{1}, y_{1}, z_{1}) on the line

where, 1, m, n are direction cosines of the line.

6. **Skew Lines** Two straight lines in space are said to be skew lines, if they are neither parallel nor intersecting.

7. **Shortest Distance** If l_{1} and l_{2} are two skew lines, then a line perpendicular to each of lines 4 and 12 is known as the line of shortest distance.

If the line of shortest distance intersects the lines l_{1} and l_{2} at P and Q respectively, then the distance PQ between points P and Q is known as the shortest distance between l_{1} and l_{2}.

8. The shortest distance between the lines

9. The shortest distance between lines r = a_{1} + λb_{1} and r = a_{2} + μb_{2} is given by

10. The shortest distance parallel lines r = a_{1} + λb_{1} and r = a_{2} + μb_{2} is given by

11. Lines r = a_{1} + λb_{1} and r = a_{2} + μb_{2} are intersecting lines, if (b_{1} * b_{2}) * (a_{2} – a_{1}) = 0.

12. The image or reflection (x, y, z) of a point (x_{1}, y_{1}, z_{1}) in a plane ax + by + cz + d = 0 is given by

x – x_{1} / a = y – y_{1} / b = z – z_{1} / c = – 2 (ax_{1} + by_{1} + cz_{1} + d) / a^{2} + b^{2} + c^{2}

13. The foot (x, y, z) of a point (x_{1}, y_{1}, z_{1}) in a plane ax + by + cz + d = 0 is given by

x – x_{1} / a = y – y_{1} / b = z – z_{1} / c = – (ax_{1} + by_{1} + cz_{1} + d) / a^{2} + b^{2} + c^{2}

14. Since, x, y and z-axes pass through the origin and have direction cosines (1, 0, 0), (0, 1, 0) and (0, 0, 1), respectively. Therefore, their equations are

x – axis : x – 0 / 1 = y – 0 / 0 = z – 0 / 0

y – axis : x – 0 / 0 = y – 0 / 1 = z – 0 / 0

z – axis : x – 0 / 0 = y – 0 / 0 = z – 0 / 1

**Plane**

A plane is a surface such that, if two points are taken on it, a straight line joining them lies wholly in the surface.

**General Equation of the Plane**

The general equation of the first degree in x, y, z always represents a plane. Hence, the general equation of the plane is ax + by + cz + d = 0. The coefficient of x, y and z in the cartesian equation of a plane are the direction ratios of normal to the plane.

**Equation of the Plane Passing Through a Fixed Point**

The equation of a plane passing through a given point (x_{1}, y_{1}, z_{1}) is given by a(x – x_{1}) + b (y — y_{1}) + c (z — z_{1}) = 0.

**Normal Form of the Equation of Plane**

(i) The equation of a plane, which is at a distance p from origin and the direction cosines of the normal from the origin to the plane are l, m, n is given by lx + my + nz = p.

(ii) The coordinates of foot of perpendicular N from the origin on the plane are (1p, mp, np).

**Intercept Form**

The intercept form of equation of plane represented in the form of

x / a + y / b + z / c = 1

where, a, b and c are intercepts on X, Y and Z-axes, respectively.

**For x intercept** Put y = 0, z = 0 in the equation of the plane and obtain the value of x. Similarly, we can determine for other intercepts.

**Equation of Planes with Given Conditions**

(i) Equation of a plane passing through the point A(x_{1}, y_{1}, z_{1}) and parallel to two given lines with direction ratios

(ii) Equation of a plane through two points A(x_{1}, y_{1}, z_{1}) and B(x_{2}, y_{2}, z_{2}) and parallel to a line with direction ratios a, b, c is

(iii) The Equation of a plane passing through three points A(x_{1}, y_{1}, z_{1}), B(x_{2}, y_{2}, z_{2}) and C(x_{3}, y_{3}, z_{3}) is

(iv) Four points A(x_{1}, y_{1}, z_{1}), B(x_{2}, y_{2}, z_{2}), C(x_{3}, y_{3}, z_{3}) and D(x_{4}, y_{4}, z_{4}) are coplanar if and only if

(v) Equation of the plane containing two coplanar lines

**Angle between Two Planes**

The angle between two planes is defined as the angle between the normal to them from any point.

Thus, the angle between the two planes

a_{1}x + b_{1}y + c_{1}z + d_{1} = 0

and a_{2}x + b_{2}y + c_{2}z + d_{2} = 0

is equal to the angle between the normals with direction cosines

± a_{1} / √Σ a^{2}_{1}, ± b_{1} / √Σ a^{2}_{1}, ± c_{1} / √Σ a^{2}_{1}

and ± a_{2} / √Σ a^{2}_{2}, ± b_{2} / √Σ a^{2}_{2}, ± c_{2} / √Σ a^{2}_{2}

If θ is the angle between the normals, then

cos θ = ± a_{1}a_{2} + b_{1}b_{2} + c_{1}c_{2} / √a^{2}_{1} + b^{2}_{1} + c^{2}_{1} √a^{2}_{2} + b^{2}_{2} + c^{2}_{2}

**Parallelism and Perpendicularity of Two Planes**

Two planes are parallel or perpendicular according as the normals to them are parallel or perpendicular.

Hence, the planes a_{1}x + b_{1}y + c_{1}z + d_{1} = 0 and a_{2}x + b_{2}y + c_{2}z + d_{2} = 0

are parallel, if a_{1} / a_{2} = b_{1} / b_{2} = c_{1} / c_{2} and perpendicular, if a_{1}a_{2} + b_{1}b_{2} + c_{1}c_{2} = 0.

Note The equation of plane parallel to a given plane ax + by + cz + d = 0 is given by ax + by + cz + k = 0, where k may be determined from given conditions.

**Angle between a Line and a Plane**

**In Vector Form** The angle between a line r = a + λ b and plane r *• n = d, is defined as the complement of the angle between the line and normal to the plane:

sin θ = n * b / |n||b|

**In Cartesian Form** The angle between a line x – x_{1} / a_{1} = y – y_{1} / b_{1} = z – z_{1} / c_{1}

and plane a_{2}x + b_{2}y + c_{2}z + d_{2} = 0 is sin θ = a_{1}a_{2} + b_{1}b_{2} + c_{1}c_{2} / √a^{2}_{1} + b^{2}_{1} + c^{2}_{1} √a^{2}_{2} + b^{2}_{2} + c^{2}_{2}

**Distance of a Point from a Plane**

Let the plane in the general form be ax + by + cz + d = 0. The distance of the point P(x_{1}, y_{1}, z_{1}) from the plane is equal to

If the plane is given in, normal form lx + my + nz = p. Then, the distance of the point P(x_{1}, y_{1}, z_{1}) from the plane is |lx_{1} + my_{1} + nz_{1} – p|.

**Distance between Two Parallel Planes**

If ax + by + cz + d_{1} = 0 and ax + by + cz + d_{2} = 0 be equation of two parallel planes. Then, the distance between them is

**Bisectors of Angles between Two Planes**

The bisector planes of the angles between the planes

a_{1}x + b_{1}y + c_{1}z + d_{1} = 0, a_{2}x + b_{2}y + c_{2}z + d_{2} = 0 is

a_{1}x + b_{1}y + c_{1}z + d_{1} / √Σa^{2}_{1} = ± a_{2}x + b_{2}y + c_{2}z + d_{2} / √Σa^{2}_{2}

One of these planes will bisect the acute angle and the other obtuse angle between the given plane.

**Sphere**

A sphere is the locus of a point which moves in a space in such a way that its distance from a fixed point always remains constant.

**General Equation of the Sphere**

**In Cartesian Form** The equation of the sphere with centre (a, b, c) and radius r is

(x – a)^{2} + (y – b)^{2} + (z – c)^{2} = r^{2} …….(i)

In generally, we can write

x^{2} + y^{2} + z^{2} + 2ux + 2vy + 2wz + d = 0

Here, its centre is (-u, v, w) and radius = √u^{2} + v^{2} + w^{2} – d

**In Vector Form** The vector equation of a sphere of radius a and Centre having position vector c is |r – c| = a

**Important Points to be Remembered**

(i) The general equation of second degree in x, y, z is ax^{2} + by^{2} + cz^{2} + 2hxy + 2kyz + 2lzx + 2ux + 2vy + 2wz + d = 0

represents a sphere, if

(a) a = b = c (≠ 0)

(b) h = k = 1 = 0

The equation becomes

ax^{2} + ay^{2} + az^{2} + 2ux + 2vy + 2wz + d – 0 …(A)

To find its centre and radius first we make the coefficients of x^{2}, y^{2} and z^{2} each unity by dividing throughout by a.

Thus, we have

x^{2}+y^{2}+z^{2} + (2u / a) x + (2v / a) y + (2w / a) z + d / a = 0 …..(B)

∴ Centre is (- u / a, – v / a, – w / a)

and radius = √u^{2} / a^{2} + v^{2} / a^{2} + w^{2} / a^{2} – d / a

= √u^{2} + v^{2} + w^{2} – ad / |a| .

(ii) Any sphere concentric with the sphere

x^{2} + y^{2} + z^{2} + 2ux + 2vy + 2wz + d = 0

is x^{2} + y^{2} + z^{2} + 2ux + 2vy + 2wz + k = 0

(iii) Since, r^{2} = u^{2} + v^{2} + w^{2} — d, therefore, the Eq. (B) represents a real sphere, if u^{2} +v^{2} + w^{2} — d > 0

(iv) The equation of a sphere on the line joining two points (x_{1}, y_{1}, z_{1}) and (x_{2}, y_{2}, z_{2}) as a diameter is

(x – x_{1}) (x – x_{1}) + (y – y_{1}) (y – y_{2}) + (z – z_{1}) (z – z_{2}) = 0.

(v) The equation of a sphere passing through four non-coplanar points (x_{1}, y_{1}, z_{1}), (x_{2}, y_{2}, z_{2}), (x_{3}, y_{3}, z_{3}) and (x_{4}, y_{4}, z_{4}) is

**Tangency of a Plane to a Sphere**

The plane lx + my + nz = p will touch the sphere x^{2} + y^{2} + z^{2} + 2ux + 2vy + 2 wz + d = 0, if length of the perpendicular from the centre ( – u, – v,— w)= radius,

i.e., |lu – mv – nw – p| / √l^{2} + m^{2} + n^{2} = √u^{2} + v^{2} + w^{2} – d

(lu – mv – nw – p)^{2} = (u^{2} + v^{2} + w^{2} – d) (l^{2} + m^{2} + n^{2})

**Plane Section of a Sphere**

Consider a sphere intersected by a plane. The set of points common to both sphere and plane is called a plane section of a sphere.

In ΔCNP, NP^{2} = CP^{2} – CN^{2} = r^{2} – p^{2}

∴ NP = √r^{2} – p^{2}

Hence, the locus of P is a circle whose centre is at the point N, the foot of the perpendicular from the centre of the sphere to the plane.

The section of sphere by a plane through its centre is called a great circle. The centre and radius of a great circle are the same as those of the sphere.

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