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Chapter 29 of RD Sharma's Class 12 mathematics textbook delves into the study of planes in three-dimensional space. Exercise 29.3 focuses on advanced problems related to planes, including finding equations of planes under specific conditions, determining distances between planes and points, and analyzing the relationships between multiple planes. This set of solutions (Set 2) continues to build on the concepts introduced in the chapter and previous exercises.
General equation of a plane: Ax + By + Cz + D = 0
Distance formula between a point and a plane: |Ax₀ + By₀ + Cz₀ + D| / √(A² + B² + C²)
Angle between two planes: cos θ = |A₁A₂ + B₁B₂ + C₁C₂| / √((A₁² + B₁² + C₁²)(A₂² + B₂² + C₂²))
Condition for parallel planes: A₁/A₂ = B₁/B₂ = C₁/C₂
Condition for perpendicular planes: A₁A₂ + B₁B₂ + C₁C₂ = 0
Solution:
As we know that the vector equation of a plane passing through a point and normal to is
....(i)
Here,
= Position vector of P - Position of vector of O
=
Now, put, all these values in equation (i), we get,
....(2)
Now put in eq(2), we get
(x)(3) + (y)(1) + (z)(−1) = -4
3x + y − z = -4
So, this is the required equation of plane.
Solution:
As we know that the vector equation of a plane passing through a point and normal to is
.....(i)
Here, = mid-point of AB
So,
= Position vector of A + Position of vector of B/ 2
=
=
And,
= Position vector of B - Position of vector of A
=
=
Now put all these values in eq(1), we get
.....(2)
Now put in eq(2), we get
(x)(2) + (y)(2) + (z)(2) = 18
2x + 2y + 2z = 18
or we can write as
x + y + z = 9
So, this is the required equation of plane.
Solution:
Given equations of planes are
x - y + z - 2 = 0 and 3x + 2y - z + 4 = 0
So first we solve, x - y + z - 2 = 0
.....(i)
Now we solve, 3x + 2y - z =- 4
...(ii)
So, from eq(i) and (ii), we conclude that
is normal to eq(i) and is normal to eq(ii)
So,
=
= (1)(3) + (-1)(2) + (1)(-1)
=3 - 2 - 1
= 3 - 3 = 0
Hence, is perpendicular to
Solution:
Given equations of planes are
and
So first we solve,
.....(1)
Now we solve,
......(2)
So, from eq(i) and (ii), we conclude that
is normal to eq(i) and is normal to eq(ii)
So,
=
= (2)(2) + (-1)(-2) + (3)(-2)
= 4 + 2 - 6
= 6 - 6
= 0
Hence, is perpendicular to
Solution:
Equation of plane = 2x + 2y + 2z = 3
So,
So, the normal to the plane
and the direction ratio of
So, the direction cosine of ....(1)
= √[(2)2 + (2)2 + (2)2]
= √[4 + 4 + 4]
= √12 = 2√3
Now put the value of |\vec{n}| in eq(1), we get
Direction cosine of |\vec{n}| =
=
So, u = 1/√3, v = 1/√3, W = 1/√3
Let us assume that the α, β, γ be the angle that normal \vec{n} makes with the coordinate axes.
So, u = cos α = 1/√3
α = cos-11/√3 ....(2)
v = cos β = 1/√3
β = cos-11/√3 ....(3)
w = cos γ = 1/√3
γ = cos-11/√3 ....(4)
So, from equation (2), (3) and (4), we get
α = β = γ
Hence proved that the normal vector to the plane 2x + 2y + 2z = 3 is equally inclined with the coordinate axes.
Solution:
Given that,
The equation of plane is = 12x - 3y + 4y = 1
and the magnitude = 26 units
So,
The normal to the plane is
= √[(12)2 + (-3)2 + (4)2]
= √[144 + 9 + 16]
= √169 = 13
Hence, the unit vector =
Now we find a vector normal to the plane with magnitude
So,
26 = 26
= 26
=
So, this is the required vector
Solution:
As we know that the vector equation of a plane passing through a point and normal to is
.....(i)
Here, = position vector of B
So,
and
= Position vector of B - Position of vector of A
=
=
Now put all these values in eq(1), we get
.....(2)
Now put in eq(2), we get
(x)(-14) + (y)(6) + (z)(2) = 178
-14x + 6y + 3z = 178
Or we can write as
7x - 2y - z = -89
So, this is the required equation of plane.
Solution:
Let assume that point (-1, 2, 3) is A point and point (3, -5, 6) is B point and C be the line mid-point of line segment AB
As we know that the vector equation of a plane passing through a point and normal to is
...(i)
Here, = Position vector of C
So, [Because c is the mid point of line AB]
Now,
= Position vector of B- Position vector of A
=
=
=
Now put all these values in eq(1), we get
= 28 ....(2)
Now put in eq(2), we get
(x)(4) + (y)(-7) + (z)(3) = 28
4x - 7y + 3z = 28
So, this is the required equation of plane.
Solution:
According to the given question
As we know that the vector equation of a plane passing through a point and normal to is
So,
....(1)
For cartesian equation:
Put in eq(1), we get
(x)(2) + (y)(3) + (z)(-1) = 20
2x + 3y -z = 20
So, this is the required equation of plane.
Solution:
According to the question, a normal pass through point O(0, 0, 0) and P (1, 2, -3)
So,
and
As we know that the vector equation of a plane passing through a point and normal to is
So,
For cartesian equation:
Put in eq(1), we get
(x)(1) + (y)(2) + (z)(-3) = 14
x + 2y - 3z = 14
So, this is the required equation of plane.
Solution:
According to the question it is given that, O is the origin and the coordinates of A are (a, b, c)
So,
Since, the direction ratios of OA are proportional to a, b, c
So, the direction cosines are:
So the equation of the line is,
ax + by + cz = a2 + b2 + c2
Question 1. Find the equation of the plane passing through the points (1, 2, 3), (2, 3, 1), and (3, 1, 2).
Question 2. Determine the equation of the plane passing through the point (2, -1, 3) and perpendicular to the vector <1, 2, -1>.
Question 3. Find the equation of the plane passing through the point (1, -1, 2) and parallel to the plane 2x - y + 3z = 4.
Question 4. Write the equation of the plane passing through the point (0, 1, -1) and containing the line x = 2t, y = 3t - 1, z = t + 2.
Question 5. Find the equation of the plane passing through the point (1, 2, 3) and perpendicular to the planes x + 2y + 3z = 4 and 2x - y + z = 5.
Question 6. Determine the equation of the plane passing through the points (1, 0, 0), (0, 1, 0), and (0, 0, 1).
Question 7. Find the equation of the plane passing through the point (2, 3, -1) and parallel to the vectors <1, -1, 2> and <2, 1, 1>.
Question 8. Write the equation of the plane that is perpendicular to the line x = 1 + 2t, y = 2 - t, z = 3 + t and passes through the point (1, 2, 3).
Question 9. Find the equation of the plane passing through the point (1, -1, 2) and containing the line of intersection of the planes x + y + z = 1 and x - y + z = 3.
Question 10. Determine the equation of the plane passing through the point (3, -2, 1) and making equal intercepts on the coordinate axes.
Also Read,
Exercise 29.3 | Set 2 of RD Sharma's Class 12 Chapter 29 presents a series of advanced problems that test students' understanding of planes in three-dimensional space. These solutions demonstrate various techniques for working with planes, including finding equations of planes under specific conditions, determining the foot of perpendiculars, and solving problems involving multiple planes. By mastering these concepts, students develop a strong foundation in analytical geometry, which is crucial for further studies in mathematics and related fields. The problems in this set emphasize the importance of spatial reasoning and the application of vector algebra in solving complex geometric scenarios.
