$\Rightarrow dx = a{\sec ^2}\theta \,d\theta ,$ then we have
$I = \int_0^{\pi /4} {\frac{{{a^4}{{\tan }^4}\theta .\,a{{\sec }^2}\theta \,d\theta }}{{{a^8}{{\sec }^8}\theta }}} $
==> $\frac{1}{{{a^3}}}\int_0^{\pi /4} {{{\sin }^4}\theta } {\cos ^2}\theta \,d\theta $
$= I = \frac{1}{{{a^3}}}\left[ {\int_0^{\pi /4} {({{\sin }^4}\theta } - {{\sin }^6}\theta } \right]\,d\theta $
$ = \frac{1}{{{a^3}}}\int_0^{\pi /4} {\left[ {\frac{{{{(1 - \cos 2\theta )}^2}}}{4} - \frac{{{{(1 - \cos 2\theta )}^3}}}{8}} \right]\,} d\theta $
$ = \frac{1}{{8{a^3}}}\int_0^{\pi /4} {{\rm{ }}(1 + \cos 2\theta } )(1 + {\cos ^2}2\theta - 2\cos 2\theta )d\theta $
$ = \frac{1}{{8{a^3}}}\int_0^{\pi /4} {(1 - \cos 2\theta - {{\cos }^2}2\theta + {{\cos }^3}2\theta )\,d\theta } $
$ = \frac{1}{{32{a^3}}}\int_0^{\pi /4} {(2 - \cos 2\theta - 2\cos 4\theta + \cos 6\theta )d\theta } $
$ = \frac{1}{{32{a^3}}}\left[ {2\theta - \frac{{\sin 2\theta }}{2} - \frac{{\sin 4\theta }}{2} + \frac{{\sin 6\theta }}{6}} \right]_0^{\pi /4}$
$ = \frac{1}{{16{a^3}}}\left( {\frac{\pi }{4} - \frac{1}{3}} \right)$.
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$\alpha \log _{\mathrm{e}}|1+\tan \mathrm{x}|+\beta \log _{\mathrm{c}}\left|1-\tan \mathrm{x}+\tan ^{2} \mathrm{x}\right|+\gamma \tan ^{-1}\left(\frac{2 \tan \mathrm{x}-1}{\sqrt{3}}\right)+\mathrm{C}$
કે જ્યાં $\mathrm{C}$ એ સંકલન અચળાંક છે તો $18\left(\alpha+\beta+\gamma^{2}\right)$ ની કિમંત મેળવો.