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Chapter 23 of RD Sharma's Class 11 Mathematics textbook covers the concept of straight lines which is a fundamental topic in coordinate geometry. Understanding straight lines is crucial for solving problems related to their equations, slopes, intercepts, and various geometric properties. Exercise 23.9 focuses on applying these concepts to solve practical problems involving straight lines.
The Straight lines in coordinate geometry are represented by linear equations and can be analyzed using various properties such as the slope, intercepts, and angle with respect to the axes. Key concepts include:
(i) slope-intercept form and find slope and y-intercept
(ii) Intercept form and find intercept on the axes
(iii) The normal form and find p and α.
Solution:
(i) slope-intercept form and find slope and y-intercept
Given equation:√3x + y + 2 = 0
Therefore, y = – √3x – 2
Thus, m = -√3, c = -2
Hence, the slope = – √3 and y-intercept = -2
(ii) Intercept form and find intercept on the axes
Given equation: √3x + y + 2 = 0
√3x + y = -2 [ Divide both sides by -2 ]
√3x/-2 + y/-2 = 1
Therefore, x-intercept = -2/√3 and y-intercept = -2
(iii) The normal form and find p and α
Given equation: √3x + y + 2 = 0
-√3x – y = 2 [ Divide both sides by 2 ]
(-√3/2)x - y/2 = 1
The normal form is represented as x cos α + y sin α = p
Thus,
cos α = -√3/2 = cos 210°
sin α = -1/2 = sin 210°
Therefore, p = 1 and α = 210°
(i) x + √3y – 4 = 0
(ii) x + y + √2 = 0
(iii) x - y + 2√2 = 0
(iv) x - 3 = 0
(v) y - 2 = 0
Solution:
(i) x + √3y – 4 = 0
Given equation: x + √3y – 4 = 0
x + √3y = 4 [ Divide both sides by 2 ]
(1/2)x + (√3/2)y = 2
The normal form is represented as x cos α + y sin α = p
Thus,
cos α = 1/2 = cos 60°
sin α = √3/2 = sin 60°
Therefore, p = 2 and α = 60°
(ii) x + y + √2 = 0
Given equation: x + y + √2 = 0
-x – y = √2 [ Divide both sides by √2 ]
(-1/√2)x - (1/√2)y = 1
The normal form is represented as x cos α + y sin α = p
Thus,
cos α = -1/√2
sin α = -1/√2
Since, both are negative,
Thus α is in III quadrant,
α = π(π/4) = 5π/4 = 225°
Therefore, p = 1 and α = 225°
(iii) x - y + 2√2 = 0
Given equation: x - y + 2√2 = 0
-x + y = 2√2 [ Divide both sides by √2 ]
(-1/√2)x - (-1/√2)y = 2
The normal form is represented as x cos α + y sin α = p
Thus,
cos α = -1/√2
sin α = -1/√2
α is in II quadrant,
α = (π/4) + (π/2) = 3π/4 = 135°
Therefore, p = 2 and α = 135°
(iv) x - 3 = 0
Given equation: x - 3 = 0
x = 3
The normal form is represented as x cos α + y sin α = p
Thus,
cos α = 1 = cos 0°
Therefore, p = 3 and α = 0°
(v) y - 2 = 0
Given equation: y - 2 = 0
y = 2
The normal form is represented as x cos α + y sin α = p
Thus,
sin α = 1 = sin π/2°
Therefore, p = 2 and α = π/2°
Solution:
Given equation: x/a + y/b = 1
Since, the general equation of line is represented as y = mx + c.
Thus,
bx + ay = ab
ay = – bx + ab
y = -bx/a + b
Hence, m = -b/a, c = b
Therefore, the slope = -b/a and y-intercept = b
Solution:
Given equations:
3x − 4y + 4 = 0 ...... (i)
2x + 4y − 5 = 0 ...... (ii)
For equation (i),
-3x + 4y = 4 [ Divide both sides by 5 i.e. √(-3)2 + (4)2 ]
(-3/5)x + (4/5)y = 4/5
Therefore, p = 4/5
Now for equation (ii),
2x + 4y = – 5
-2x – 4y = 5 [ Divide both sides by √20 i.e. √(-2)2 + (-4)2 ]
(-2/√20)x – (4/√20)y = 5/√20
Therefore, p = 5/√20 = 5/4.47
Comparing value of p for equations (i) and (ii) we get,
4/5 < 5/4.47
Therefore, the line 3x − 4y + 4 = 0 is nearest to the origin.
Solution:
Given equations:
4x + 3y + 10 = 0 ...... (i)
5x – 12y + 26 = 0 ...... (ii)
7x + 24y = 50 ...... (iii)
For equation (i),
4x + 3y + 10 = 0
-4x – 3y = 10 [ Divide both sides by 5 i.e. √(-4)2 + (-3)2 ]
(-4/5)x – 3/5)y = 10/5
(-4/5)x – 3/5)y = 2
Therefore, p = 2
For equation (ii),
5x − 12y + 26 = 0
-5x + 12y = 26 [ Divide both sides by 13 i.e. √(-5)2 + (12)2 ]
(-5/13)x + (12/13)y = 26/13
(-5/13)x + (12/13)y = 2
Therefore, p = 2
For equation (iii),
7x + 24y = 50 [ Divide both sides by 25 i.e. √(7)2 + (24)2 ]
(7/25)x + (24/25)y = 50/25
(7/25)x + (24/25)y = 2
Therefore, p = 2
Hence, the origin is equidistant from the given lines.
Solution:
Given equation: √3x + y + 2 = 0
√3x + y = 2
-√3x - y = 2
The normal form is represented as x cos θ + y sin θ = p
Thus,
cos θ = -√3
sin θ = 1
tan θ = 1/√3
θ = π+(π/6) = 180° + 30° = 210°
Therefore, p = 2 and θ = 120°
Solution:
Given equation: 3x - 2y + 6 = 0
-3x + 2y = 6 [ Divide both sides by 6 ]
(-3/6)x + (2/6)y = 6/6
(-1/2)x + (1/3)y = 1
Therefore, x-intercept = -2 and y-intercept = 3
Solution:
Given: Perpendicular distance from the origin to the line is 5 units i.e p = 5
The normal form is represented as x cos α + y sin α = p
x cos α + y sin α = 5
y sin α = -x cos α + 5
y = (-x (cos α/sin α) + 5)
y = -x cot α + 5
Comparing it with the equation y = mx + c,
m = -cot α
-1 = -cot α
cot α = 1
α = π/4
Thus, the equation is,
x cos π/4 + y sin π/4 = 5
x/√2 + y/√2 = 5
x + y = 5√2
Therefore, x + y = 5√2 is the equation of line.
Read More:
Exercise 23.9 in Chapter 23 of RD Sharma's textbook helps reinforce the understanding of the straight lines by the applying theoretical concepts to practical problems. The Mastery of these concepts is essential for the solving more complex problems in coordinate geometry and for the preparing for the higher-level mathematics.
