Question 20. limx→1[(1 + cosπx)/(1 - x)2]
Solution:
We have,
limx→1[(1 + cosπx)/(1 - x)2]
Here, x→1, h→0
= Limh→0[{1 + cosπ(1 + h)}/{1 - (1 + h)}2]
= Limh→0[(1 - cosπh)/h2]
= Limh→0[2sin2(πh/2)/h2]
=
2\lim_{h\to0}[\frac{sin^2(\frac{πh}{2})}{(\frac{2}{π})^2×(\frac{πh}{2})^2}] = 2π2/4
= π2/2
Question 21. limx→1[(1 - x2)/sinπx]
Solution:
We have,
limx→1[(1 - x2)/sinπx]
Here, x→1, h→0
= limh→0[{1 - (1 - h)2}/sinπ(1 - h)]
= limh→0[(2h - h2)/-sinπh]
= -limh→0[{h(2 - h)}/sinπh]
=
\lim_{h\to0}[\frac{(2-h)}{\frac{sinπh}{h}}] =
\lim_{h\to0}[\frac{(2-h)}{(\frac{sinπh}{πh})×π}] = (2 - 0)/π
= 2/π
Question 22. limx→π/4[(1 - sin2x)/(1 + cos4x)]
Solution:
We have,
limx→π/4[(1 - sin2x)/(1 + cos4x)]
Here, x→π/4, h→0
= limh→0[{1 - sin2(π/4 - h)}/{1 + cos4(π/4 - h)}]
= limh→0[{1 - sin(π/2 - 2h)}/{1 + cos(π - 4h)}]
= limh→0[(1 - cos2h)/(1 - cos4h)]
= limh→0[2sin2h/2sin22h]
=
\lim_{h\to0}[\frac{\frac{sin^2h}{h^2}}{\frac{sin^22h}{4h^2}×4}] = (1/4)
Question 23. limx→π[(1 + cosx)/tan2x]
Solution:
We have,
limx→π[(1 + cosx)/tan2x]
Here, x→π, h→0
= limh→0[{1+cos(π + h)}/tan2(π + h)]
= limh→0[(1 - cosh)/tan2h]
= limh→0[{2sin2(h/2)}/tan2h]
=
2×\lim_{h\to0}[\frac{sin^2(\frac{h}{2})}{(\frac{h}{2})^2×(\frac{2}{h})^2}]×\lim_{h\to0}[\frac{1}{\frac{tan^2h}{h^2}×h^2}] = 2/4
= 1/2
Question 24. limn→∞[nsin(π/4n)cos(π/4n)]
Solution:
We have,
limn→∞[nsin(π/4n)cos(π/4n)]
= limn→∞[nsin(π/4n)]Limn→∞[cos(π/4n)]
=
\lim_{n\to∞}[\frac{nsin\frac{π}{4n}}{(\frac{π}{4n})}]×(\frac{π}{4n})×1 =
(\frac{π}{4})\lim_{n\to∞}[\frac{sin\frac{π}{4n}}{(\frac{π}{4n})}] Let, y = (π/4n)
If n→∞, y→0.
= (π/4).Limy→0[siny/y]
= (π/4)
Question 25. limn→∞[2n-1sin(a/2n)]
Solution:
We have,
limn→∞[2n-1sin(a/2n)]
=
\lim_{n\to∞}[\frac{2^n}{2}×sin(\frac{a}{2^n})] =
\lim_{n\to∞}[\frac{2^n}{2}×\frac{sin(\frac{a}{2^n})}{\frac{a}{2^n}}×\frac{a}{2^n}] =
(\frac{a}{2})\lim_{n\to∞}[\frac{sin\frac{a}{2^n}}{(\frac{a}{2^n})}] Let, y = (a/2n)
If n→∞, y→0
= (a/2).Limy→0[siny/y]
= (a/2)
Question 26. limn→∞[sin(a/2n)/sin(b/2n)]
Solution:
We have,
limn→∞[sin(a/2n)/sin(b/2n)]
=
\lim_{n\to∞}[\frac{sin(\frac{a}{2^n})}{(\frac{a}{2^n})}×(\frac{a}{2^n})]\lim_{n\to∞}[\frac{}{\frac{sin(\frac{b}{2^n})}{(\frac{b}{2^n})}×(\frac{b}{2^n})}] Let, y = (a/2n) and z = (b/2n)
If n→∞, y→0 and z→0
=
\frac{y}{z}\lim_{y\to0}[\frac{siny}{y}]\lim_{z\to0}[\frac{y}{siny}] =
\frac{\frac{a}{2^n}}{\frac{b}{2^n}} = (a/b)
Question 27. limx→-1[(x2 - x - 2)/{(x2 + x) + sin(x + 1)}]
Solution:
We have,
limx→-1[(x2 - x - 2)/{(x2 + x) + sin(x + 1)}]
= limx→-1[(x2 - x - 2)/{x(x + 1) + sin(x + 1)}]
= limx→-1[(x - 2)(x + 1)/{x(x + 1) + sin(x + 1)}]
Let, y = x + 1
If x→-1, then y→0
= limy→0[y(y - 3)/{y(y - 1) + siny}]
=
\lim_{y\to0}[\frac{(y-3)}{(y-1)+\frac{siny}{y}}] = (0 - 3)/{(0 - 1) + 1}
= -3/0
= ∞
Question 28. limx→2[(x2 - x - 2)/{(x2 - 2x) + sin(x - 2)}]
Solution:
We have,
limx→2[(x2 - x - 2)/{(x2 - 2x) + sin(x - 2)}]
= limx→2[{(x - 2)(x + 1)}/{x(x + 1) + sin(x + 1)}]
Let, y = x - 2
If x→2, then y→0
= limy→0[y(y + 3)/{y(y + 2) + siny}]
=
\lim_{y\to0}[\frac{(y+3)}{(y+2)+\frac{siny}{y}}] = (0 + 3)/{(0 + 1) + 1}
= 3/3
= 1
Question 29. limx→1[(1 - x)tan(πx/2)]
Solution:
We have,
limx→1[(1 - x)tan(πx/2)]
Here, x→1, h→0
= limh→0[{1 - (1 - h)}tan{π/2(1 - h)}]
= limh→0[htan{π/2-πh/2)}
= limh→0[hcot(πh/2)]
=
\lim_{h\to0}[\frac{h}{tan(\frac{πh}{2})}] =
\lim_{h\to0}[\frac{1}{\frac{tan(\frac{πh}{2})}{\frac{πh}{2}}×\frac{π}{2}}] =
\frac{1}{\frac{π}{2}} = (2/π)
Question 30. limx→π/4[(1 - tanx)/(1 - √2sinx)]
Solution:
We have,
limx→π/4[(1 - tanx)/(1 - √2sinx)]
On rationalizing the denominator.
= limx→π/4[{(1 - tanx)(1 - √2sinx)}/(1 - 2sin2x)]
=
\lim_{x\to \frac{π}{4}}[\frac{(1-\frac{sinx}{cosx})(1+\sqrt2sinx)}{cos2x}] =
\lim_{x\to \frac{π}{4}}[\frac{(cosx-sinx)(1+\sqrt2sinx)}{cosx.cos2x}] =
\lim_{x\to \frac{π}{4}}[\frac{(cosx-sinx)(1+\sqrt2sinx)}{cosx.(cos^2x-sin^2x)}] =
\lim_{x\to \frac{π}{4}}[\frac{(cosx-sinx)(1+\sqrt2sinx)}{cosx.(cosx-sinx)(cosx+sinx)}] =
\frac{1+\sqrt2×\frac{1}{\sqrt2}}{(\frac{1}{\sqrt2})(\frac{1}{\sqrt2}+\frac{1}{\sqrt2})} = 2/1
= 2
Question 31. limx→π[{√(2 + cosx) - 1}/(π - x)2]
Solution:
We have,
limx→π[{√(2 + cosx) - 1}/(π - x)2]
Let, y = [π - x]
Here, x→π, y→0
=
\lim_{y\to0}[\frac{\sqrt{2+cos(π-y)}-1}{y^2}] = limy→0[{√(2 - cosy) - 1}/y2]
On rationalizing the numerator, we get
=
\lim_{y\to0}[\frac{2-cosy-1}{y^2(\sqrt{2-cosy}-1)}] = limy→0[{1 - cosy}/y2{√(2 - cosy) - 1}]
=
\lim_{y\to0}[\frac{2sin^2\frac{y}{2}}{y^2(\sqrt{2-cosx}+1)}] =
\lim_{y\to0}[\frac{2sin^2\frac{y}{2}}{(\frac{y}{2})^2(\sqrt{2-cosx}+1)×4}] = 2 × (1/4) × {1/(1 + 1)}
= (1/4)
Question 32. limx→π/4[(√cosx - √sinx)/(x - π/4)]
Solution:
We have,
limx→π/4[(√cosx - √sinx)/(x - π/4)]
On rationalizing the numerator, we get
= limx→π/4[(cosx - sinx)/{(√cosx + √sinx)(x - π/4)}]
=
\lim_{h\to0}[\frac{cos(\frac{π}{4}+h)-sin(\frac{π}{4}+h)}{(\frac{π}{4}+h-\frac{π}{4})(\sqrt{cos(\frac{π}{4}+h)}+\sqrt{sin(\frac{π}{4}+h)}}] =
\lim_{h\to0}[\frac{-2×\frac{1}{\sqrt2}×sinh}{h(\sqrt{cos(\frac{π}{4}+h)}+\sqrt{sin(\frac{π}{4}+h)})}] =
\lim_{h\to0}[\frac{-\sqrt2×sinh}{h(\sqrt{cos(\frac{π}{4}+h)}+\sqrt{sin(\frac{π}{4}+h)})}] =
-\sqrt2[\frac{1}{(\frac{1}{\sqrt2})^{\frac{1}{2}}+(\frac{1}{\sqrt2})^{\frac{1}{2}}}]
Question 33. limx→1[(1 - 1/x)/sinπ(x - 1)]
Solution:
We have,
limx→1[(1 - 1/x)/sinπ(x - 1)]
= limx→1[(x - 1)/x{sinπ(x - 1)}]
Let, y = x - 1
If x→1, then y→0
= limy→0[y/{(y + 1)sin(πy)}]
=
\lim_{y\to0}[\frac{1}{\frac{(y+1).sin(πy)}{y}}] =
\lim_{y\to0}[\frac{1}{\frac{(y+1).sin(πy)}{πy}×π}] = 1/{(1 + 0) × 1 × π}
= 1/π
Question 34. limx→π/6[(cot2x - 3)/(cosecx - 2)]
Solution:
We have,
limx→π/6[(cot2x - 3)/(cosecx - 2)]
= limx→π/6[(cosec2x - 1 - 3)/(cosecx - 2)]
= limx→π/6[(cosec2x - 22)/(cosecx - 2)]
= limx→π/6[{(cosecx + 2)(cosecx - 2)}/(cosecx - 2)]
= limx→π/6[(cosecx + 2)]
= cosec(π/6) + 2
= 2 + 2
= 4
Question 35. limx→π/4[(√2 - cosx - sinx)/(4x - π)2]
Solution:
We have,
limx→π/4[(√2 - cosx - sinx)/(4x - π)2]
= limx→π/4[(√2 - cosx - sinx)/{42(π/4 - x)2}]
=
\lim_{x\to \frac{π}{2}}\frac{\sqrt2[1-(\frac{1}{\sqrt2}.cosx+\frac{1}{\sqrt2}.sinx)]}{4^2(\frac{π}{4}-x)^2} =
\lim_{x\to \frac{π}{2}}\frac{\sqrt{2}[1-cos(\frac{π}{4}-x)]}{4^2(\frac{π}{4}-x)^2} =
\lim_{x\to \frac{π}{2}}\frac{[2\sqrt{2}sin^2\frac{(\frac{π}{4}-x)}{2}]}{4^2(\frac{π}{4}-x)^2} =
2\sqrt{2}\lim_{x\to \frac{π}{2}}\frac{[sin^2\frac{(\frac{π}{4}-x)}{2}]}{4^2×\frac{(\frac{π}{4}-x)}{4}^2×4} = 2√2/43
= (2√2 × √2)/(43√2)
= 4/(43√2)
= 1/(16√2)
Question 36. limx→π/2[{(π/2 - x)sinx - 2cosx}/{(π/2 - x) + cotx}]
Solution:
We have,
limx→π/2[{(π/2 - x)sinx - 2cosx}/{(π/2 - x) + cotx}]
=
\lim_{h\to0}\frac{[\frac{π}{2}-(\frac{π}{2}-h)]sin(\frac{π}{2}-h)-2cos(\frac{π}{2}-h)}{[\frac{π}{2}-(\frac{π}{2}-h)]+cot(\frac{π}{2}-h)} = limh→0[(hcosh-2sinh)/(h+tanh)]
=
\lim_{h\to0}[\frac{cosh-2\frac{sinh}{h}}{1+\frac{tanh}{h}}] (On dividing the numerator and denominator by h)= (1 - 2)/(1 + 1)
= -1/2
Question 37. limx→π/4[(cosx - sinx)/{(π/4 - x)(cosx + sinx)}]
Solution:
We have,
limx→π/4[(cosx - sinx)/{(π/4 - x)(cosx + sinx)}]
On dividing the numerator and denominator by √2, we get
=
\lim_{x\to \frac{π}{4}}[\frac{\frac{cosx}{\sqrt2}-\frac{sinx}{\sqrt2}}{(\frac{π}{4}-x)(\frac{cosx+sinx}{\sqrt2})}] =
\lim_{x\to \frac{π}{4}}[\frac{{\sqrt2}(sin\frac{π}{4}.cosx-cos\frac{π}{4}.sinx)}{(\frac{π}{4}-x)(cosx+sinx)}] =
\lim_{x\to \frac{π}{4}}[\frac{{\sqrt2}[sin(\frac{π}{4}-x)]}{(\frac{π}{4}-x)(cosx+sinx)}] =
\sqrt2\lim_{x\to \frac{π}{4}}[\frac{[sin(\frac{π}{4}-x)]}{(\frac{π}{4}-x)}]\lim_{x\to \frac{π}{4}}[\frac{1}{(cosx+sinx)}] =
\frac{\sqrt2}{\frac{1}{\sqrt2}+\frac{1}{\sqrt2}} = (√2 × √2)/2
= 1
Question 38. limx→π[{1 - sin(x/2)}/{cos(x/2)(cosx/4 - sinx/4}]
Solution:
We have,
limx→π[{1 - sin(x/2)}/{cos(x/2)(cosx/4 - sinx/4}]
Let, x = π + h
If x→π, then h→0
=
\lim_{h\to0}[\frac{1-sin(\frac{π+h}{2})}{cos(\frac{π+h}{2})[cos(\frac{π+h}{4})-sin(\frac{π+h}{4})]}] =
\lim_{h\to0}[\frac{1-sin(\frac{π}{2}+\frac{h}{2})}{cos(\frac{π}{4}+\frac{h}{2})[cos(\frac{π}{4}+\frac{h}{4})-sin(\frac{π}{4}+\frac{h}{4})]}] =
\lim_{h\to0}[\frac{1-cos(\frac{h}{2})}{-sin(\frac{h}{2})[-\sqrt{2}sin(\frac{h}{2})]}] =
\lim_{h\to0}[\frac{2sin^2(\frac{h}{4})}{-sin(\frac{h}{2})[-\sqrt{2}sin(\frac{h}{4})]}] =
\lim_{h\to0}[\frac{2sin^2(\frac{h}{4})}{2sin(\frac{h}{4})cos(\frac{h}{4})[\sqrt{2}sin(\frac{h}{4})]}] =
(\frac{1}{\sqrt2})\lim_{h\to0}\frac{1}{cos(\frac{h}{4})} = 1/√2
