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Question
Prove that: `(sec^3 θ)/(sec^2 θ - 1) + ("cosec"^3 θ)/("cosec"^2 θ - 1) = sec θ . "cosec" θ (sec θ + "cosec" θ)`
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Solution
Given to prove:
`(sec^3 θ)/(sec^2 θ - 1) + ("cosec"^3 θ)/("cosec"^2 θ - 1) = sec θ . "cosec" θ (sec θ + "cosec" θ)`
Recall the identities:
sec2θ – 1 = tan2θ
cosec2θ – 1 = cot2θ
Rewrite the left-hand side (LHS) using these:
`(sec^3θ)/(tan^2θ) + ("cosec"^3θ)/(cot^2θ)`
Recall:
`sec θ = 1/cos θ`
`"cosec" θ = 1/sin θ`
`tan θ = sin θ/cos θ`
`cot θ = cos θ/sin θ`
Substitute these into the expression:
`(1/(cos θ))^3/((sin θ)/(cos θ))^2 + (1/(sin θ))^3/((cos θ)/(sin θ))^2`
Simplify each term:
First term:
`(1/(cos^3θ))/((sin^2θ)/(cos^2θ)) = 1/(cos^3θ) xx (cos^2θ)/(sin^2θ)`
= `1/(cos θ sin^2 θ)`
Second term:
`(1/(sin^3θ))/((cos^2θ)/(sin^2θ)) = 1/(sin^3θ) xx (sin^2θ)/(cos^2θ)`
= `1/(sin θ cos^2 θ)`
So the LHS becomes:
`1/(cos θ sin^2 θ) + 1/(sin θ cos^2 θ)`
The common denominator is sin2 θ cos2 θ.
Rewrite each term:
`1/(cos θ sin^2 θ) = cos θ/(cos^2 θ sin^2 θ)`
`1/(sin θ cos^2 θ) = sin θ/(sin^2 θ cos^2 θ)`
Actually, to get common denominator:
Multiply numerator and denominator appropriately:
First term:
`1/(cos θ sin^2 θ) = (cos θ)/(cos^2 θ sin^2 θ)` ...(Multiply numerator and denominator by cos θ)
Second term:
`1/(sin θ cos^2 θ) = (sin θ)/(sin^2 θ cos^2 θ)` ...(Multiply numerator and denominator by sin θ)
Now add:
`(cos θ)/(cos^2θ sin^2θ) + (sin θ)/(sin^2θ cos^2θ) = (cos θ + sin θ)/(sin^2θ cos^2 θ)`
RHS is:
`sec θ . "cosec" θ . (sec θ + "cosec" θ) = 1/(cos θ) xx 1/(sin θ) xx (1/(cos θ) + 1/(sin θ))`
Simplify inside the bracket:
`1/(cos θ) + 1/(sin θ) = (sin θ + cos θ)/(sin θ cos θ)`
So RHS becomes:
`1/(cos θ sin θ) xx (sin θ + cos θ)/(sin θ cos θ) = (sin θ + cos θ)/(sin^2θ cos^2θ)`
Both sides are equal:
`(sin θ + cos θ)/(sin^2 θ cos^2 θ)`
Hence, the identity is proved.
