Theorems and Laws [8]
Prove the following:
3 sin−1 x = sin−1 (3x − 4x3), `x ∈ [-1/2, 1/2]`
Let x = sin θ.
Then, sin−1 x = θ.
We have,
R.H.S = sin−1 (3x – 4x3) = sin−1 (3 sin θ – 4 sin3θ)
= sin−1 (sin 3θ) = sin−1 (3 sin θ – 4 sin3θ)
= 3θ = sin−1 (3 sin θ – 4 sin3θ)
= 3 sin−1 x = sin−1 (3 sin θ – 4 sin3θ)
R.H.S = L.H.S
Prove the following:
3cos–1x = cos–1 (4x3 – 3x), `x ∈ [1/2, 1]`
Let x = cos θ.
Then, cos–1x = θ.
We have,
R.H.S. = cos–1(4x3 – 3x)
= cos–1(4 cos3 θ – 3 cos θ)
= cos–1(cos 3θ)
= 3θ
= 3cos–1x
= L.H.S.
Prove that `sin^(-1) 8/17 + sin^(-1) 3/5 = tan^(-1) 77/36`.
Let `sin^-1 8/17 = x`.
Then, `sin x = 8/17`
⇒ `cos x = sqrt(1 - (8/17)^2`
= `sqrt((225)/(289)`
= `15/17`
∴ `tan x= 8/15` ⇒ `x = tan^-1 8/15`
∴ `sin^-1 8/17 = tan^-1 8/15` ...(1)
Now, let `sin^-1 3/5 = y`.
Then, `sin y = 3/5`
⇒ `cos y = sqrt(1 - (3/5)^2`
= `sqrt(16/25)`
= `4/5`
∴ `tan y = 3/5` ⇒ `y = tan^-1 3/4`
∴ `sin^-1 3/5 = tan^-1 3/4` ...(2)
Now, we ahve:
L.H.S. = `sin^-1 8/17 + sin^-1 3/5`
= `tan^-1 8/15 + tan^-1 3/4` ...[Using (1) and (2)]
= `tan^-1 (8/15 + 3/4)/(1 - 8/15 xx 3/4)`
= `tan^-1 ((32 + 45)/(60 - 24))` ...`[tan^-1x + tan^-1y = tan^-1 (x + y)/(1 - xy)]`
= `tan^-1 77/36` = R.H.S.
Prove that `cos^(-1) 4/5 + cos^(-1) 12/13 = cos^(-1) 33/65`.
Let `cos^(-1) 4/5 = x`.
Then, `cos x = 4/5`
⇒ `sin x = sqrt (1 - (4/5)^2)`
⇒ `sin x = sqrt(1 - 16/25)`
⇒ `sin x = sqrt(9/25)`
⇒ `sin x = 3/5`
∴ `tan x = 3/4` ⇒ `x = tan^(-1) 3/4`
∴ `cos^(-1) 4/5 = tan^(-1) 3/4` ...(1)
Now, let `cos^(-1) 12/13 = y`.
Then, `cos y = 12/13`
⇒ `sin y = 5/13`
∴ `tan y = 5/12` ⇒ `y = tan^(-1) 5/12`
∴ `cos^(-1) 12/13 = tan^(-1) 5/12` ...(2)
Let `cos^(-1) 33/65 = z`.
Then, `cos z = 33/65`
⇒ `sin z = 56/65`
∴ `tan z = 56/33` ⇒ `z = tan^(-1) 56/33`
∴ `cos^(-1) 33/65 = tan^(-1) 56/33` ...(3)
Now, we will prove that:
L.H.S = `cos^(-1) 4/5 + cos^(-1) 12/13`
= `tan^(-1) 3/4 + tan^(-1) 5/12` ...[Using (1) and (2)]
= `tan^(-1) (3/4 + 5/12)/(1 - 3/4 * 5/12)` ...`[tan^(-1) x + tan^(-1) y = tan^(-1) (x + y)/(1 - xy)]`
= `tan^(-1) (36+20)/(48-15)`
= `tan^(-1) 56/33`
= `tan^(-1) 56/33` ...[By (3)]
= R.H.S.
Prove that `cos^(-1) 12/13 + sin^(-1) 3/5 = sin^(-1) 56/65`.
Let `sin^-1 3/5 = x`.
Then, `sin x = 3/5`
⇒ `cos x = sqrt(1 - (3/5)^2`
= `sqrt(16/25)`
= `4/5`
∴ `tan x = 3/4` ⇒ `x = tan^-1 3/4`
∴ `sin^-1 3/5 = tan^-1 3/4` ...(1)
Now, let `cos^-1 12/13 = y`.
Then, `cos y = 12/13` ⇒ `sin y = 5/13`.
∴ `tan y = 5/12` ⇒ `y = tan^-1 5/12`
∴ `cos^-1 12/13 = tan^-1 5/12` ...(2)
Let `sin^-1 56/65 = z`.
Then, `sin z = 56/65` ⇒ `cos z = 33/65`.
∴ `tan z = 56/33` ⇒ `z = tan^-1 56/33`
∴ `sin^-1 56/65 = tan^-1 56/33` ...(3)
Now, we have:
L.H.S. = `cos^-1 12/13 + sin^-1 3/5`
= `tan^-1 5/12 + tan^-1 3/4` ...[Using (1) and (2)]
= `tan^-1 (5/12 + 3/4)/(1 - 5/12 * 3/4)` ...`[tan^-1x + tan^-1y = tan^-1 (x + y)/(1 - xy)]`
= `tan^-1 (20 + 36)/(48 - 15)`
= `tan^-1 56/33`
= `sin^-1 56/65` = R.H.S. ...[Using (3)]
Prove that `tan^(-1) 63/16 = sin^(-1) 5/13 + cos^(-1) 3/5`.
Let `sin^(-1) 5/13 = x`.
Then, `sin x = 5/13` ⇒ `cos x = 12/13`.
∴ `tan x = 5/12` ⇒ `x = tan^-1 5/12`
∴ `sin^-1 5/13 = tan^-1 5/12` ...(1)
Let `cos^-1 3/5 = y`.
Then, `cos y = 3/5` ⇒ `sin y = 4/5`.
∴ `tan y = 4/3` ⇒ `y = tan^-1 4/3`
∴ `cos^-1 3/5 = tan^-1 4/3` ...(2)
Using (1) and (2), we have
R.H.S. = `sin^-1 5/13 + cos^-1 3/5`
= `tan^-1 5/12 + tan^-1 4/3`
= `tan^-1 ((5/12 + 4/3)/(1 - 5/12 xx 4/3))` ...`[tan^-1x + tan^-1y = tan^-1 (x + y)/(1 - xy)]`
= `tan^-1 ((15 + 48)/(36 - 20))`
= `tan^-1 63/16`
= L.H.S.
Prove that `tan^(-1) sqrt(x) = 1/2 cos^(-1) (1 - x)/(1 + x), x ∈ [0, 1]`.
Let x = tan2 θ.
Then, `sqrt(x) = tan θ`
⇒ `θ = tan^(-1) sqrtx`
∴ `(1 - x)/(1 + x) = (1 - tan^2θ)/(1 + tan^2θ)`
= cos 2θ
Now, we have:
R.H.S = `1/2 cos^(-1) ((1 - x)/(1 + x))`
= `1/2 cos^(-1) (cos 2θ)`
= `1/2 xx 2θ`
= θ
= `tan^(-1) sqrt(x)`
= L.H.S.
Prove that `cot^(-1) ((sqrt(1 + sin x) + sqrt(1 - sinx))/(sqrt(1 + sin x) - sqrt(1 - sinx))) = x/2, x ∈ (0, pi/4)`.
Consider `(sqrt(1 + sinx) + sqrt(1 - sin x))/(sqrt(1 + sinx) - sqrt(1 - sinx))`
= `((sqrt(1 + sinx) + sqrt(1 - sinx))^2)/((sqrt(1 + sin x))^2 - (sqrt(1 - sin x))^2)` ...(By rationalizing)
= `((1 + sinx) + (1 - sinx) + 2sqrt((1 + sinx)(1 - sinx)))/(1 + sinx - 1 + sinx)`
= `(2(1 + sqrt(1 - sin^2x)))/(2sinx)`
= `(1 + cosx)/(sin x)`
= `(2 cos^2 x/2)/(2sin x/2 cos x/2)`
= `cot x/2`
∴ L.H.S = `cot^(-1) ((sqrt(1 + sin x) + sqrt(1 - sinx))/(sqrt(1 + sin x) - sqrt(1 - sinx)))`
= `cot^(-1) (cot x/2)`
= `x/2` = R.H.S.
Key Points
i. \[\sin^{-1}\frac{1}{x}=\mathrm{cosec}^{-1}\] if x ≥ 1 or x ≤ −1
\[\cos^{-1}\frac{1}{x}=\sec^{-1}x\] if x ≥ 1 or x ≤ −1
\[\tan^{-1}\frac{1}{x}=\cot^{-1}x\] if x > 0
ii. sin⁻¹(−x) = −sin⁻¹x, for x ∈ [−1, 1]
tan⁻¹(−x) = −tan⁻¹x, for x ∈ R
cosec⁻¹(−x) = −cosec⁻¹x, for x ≥ 1
cos⁻¹(−x) = π − cos⁻¹x, for x ∈ [−1, 1]
sec⁻¹(−x) = π − sec⁻¹x, for x ≥ 1
cot⁻¹(−x) = π − cot⁻¹x, for x ∈ R
\[\sin^{-1}x+\cos^{-1}x=\frac{\pi}{2},\] for x ∈ [−1, 1]
\[\tan^{-1}x+\cot^{-1}x=\frac{\pi}{2},\] for x ∈ R
\[\sec^{-1}x+\cos\sec^{-1}x=\frac{\pi}{2},\] for |x| ≥ 1
\[\tan^{-1}x+\tan^{-1}y=\tan^{-1}\left(\frac{x+y}{1-xy}\right),\] for x > 0, y > 0 and xy < 1
\[\tan^{-1}x+\tan^{-1}y=\pi+\tan^{-1}\left(\frac{x+y}{1-xy}\right),\] for x, y > 0 and xy > 1
\[\tan^{-1}x-\tan^{-1}y=\tan^{-1}\left(\frac{x-y}{1+xy}\right),\] for x, y > 0
\[2\tan^{-1}x=\sin^{-1}\left(\frac{2x}{1+x^{2}}\right),\] if −1 ≤ x ≤ 1
\[2\tan^{-1}x=\cos^{-1}\left(\frac{1-x^{2}}{1+x^{2}}\right),\] if x > 0
\[2\tan^{-1}x=\tan^{-1}\left(\frac{2x}{1-x^{2}}\right),\] if −1 < x < 1
