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Question: Evaluate the limit \(\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \cos x\cdot \log \left(...

Evaluate the limit limxπ2(cosxlog(tanx))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \cos x\cdot \log \left( \tan x \right) \right).

Explanation

Solution

Hint: We will use the method of substitution of the value that is in the limit. Also we will use L’Hopital’s Rule.

Complete step-by-step solution -
Now, we will consider the limit as limxπ2(cosxlog(tanx))....(i)\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \cos x\cdot \log \left( \tan x \right) \right)....(i).
Now, we will substitute the value of the limit that is, we will put x=π2x=\dfrac{\pi }{2} in expression (i). Therefore, we have limxπ2(cosxlog(tanx))=(cos(π2)log(tan(π2)))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \cos x\cdot \log \left( \tan x \right) \right)=\left( \cos \left( \dfrac{\pi }{2} \right)\cdot \log \left( \tan \left( \dfrac{\pi }{2} \right) \right) \right). As we know that value of cos(π2)=0\cos \left( \dfrac{\pi }{2} \right)=0 and the value of tan(π2)=\tan \left( \dfrac{\pi }{2} \right)=\infty . Therefore, we have (cos(π2)log(tan(π2)))=(0log())\left( \cos \left( \dfrac{\pi }{2} \right)\cdot \log \left( \tan \left( \dfrac{\pi }{2} \right) \right) \right)=\left( 0\cdot \log \left( \infty \right) \right). Since, the value of log()=\log \left( \infty \right)=\infty . So, we have that (0log())=0\left( 0\cdot \log \left( \infty \right) \right)=0\cdot \infty . Thus, it is a 00\cdot \infty case. So, we can apply L’Hopital’s Rule here. But before that we will convert the trigonometric term cos(x)=1sec(x)\cos \left( x \right)=\dfrac{1}{\sec \left( x \right)} and apply this as a substitution to equation (i). Therefore, we have
limxπ2(cosxlog(tanx))=limxπ2(1sec(x)log(tanx)) limxπ2(1sec(x)log(tanx))=limxπ2(log(tanx)sec(x)) \begin{aligned} & \underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \cos x\cdot \log \left( \tan x \right) \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{1}{\sec \left( x \right)}\cdot \log \left( \tan x \right) \right) \\\ & \Rightarrow \underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{1}{\sec \left( x \right)}\cdot \log \left( \tan x \right) \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\log \left( \tan x \right)}{\sec \left( x \right)} \right) \\\ \end{aligned}
Now we will apply L’Hopital’s rule and differentiate numerator and denominator individually. As we know that the differentiation is log(tanx)=1tan(x)×sec2(x)\log \left( \tan x \right)=\dfrac{1}{\tan \left( x \right)}\times {{\sec }^{2}}\left( x \right) and the differentiation of sec(x)=sec(x)tan(x)\sec \left( x \right)=\sec \left( x \right)\tan \left( x \right). Thus, we have that limxπ2(log(tanx)sec(x))=limxπ2(sec2(x)tan(x)sec(x)tan(x)1)\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\log \left( \tan x \right)}{\sec \left( x \right)} \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\dfrac{{{\sec }^{2}}\left( x \right)}{\tan \left( x \right)}}{\dfrac{\sec \left( x \right)\tan \left( x \right)}{1}} \right). Now, we will apply the formula abcd=ab×dc\dfrac{\dfrac{a}{b}}{\dfrac{c}{d}}=\dfrac{a}{b}\times \dfrac{d}{c} here at this step. Thus, we have that limxπ2(sec2(x)tan(x)sec(x)tan(x)1)=limxπ2(sec2(x)tan(x)×1sec(x)tan(x))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\dfrac{{{\sec }^{2}}\left( x \right)}{\tan \left( x \right)}}{\dfrac{\sec \left( x \right)\tan \left( x \right)}{1}} \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{{{\sec }^{2}}\left( x \right)}{\tan \left( x \right)}\times \dfrac{1}{\sec \left( x \right)\tan \left( x \right)} \right) after cancelling the common terms we have,
limxπ2(sec2(x)tan(x)×1sec(x)tan(x))=limxπ2(sec(x)tan(x)×1tan(x))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{{{\sec }^{2}}\left( x \right)}{\tan \left( x \right)}\times \dfrac{1}{\sec \left( x \right)\tan \left( x \right)} \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\sec \left( x \right)}{\tan \left( x \right)}\times \dfrac{1}{\tan \left( x \right)} \right)
Now, we will convert this expression in terms of sin(x)\sin \left( x \right) and cos(x)\cos \left( x \right). As we know that the value of sec(x)=1cos(x)\sec \left( x \right)=\dfrac{1}{\cos \left( x \right)} and the value of tan(x)=sin(x)cos(x)\tan \left( x \right)=\dfrac{\sin \left( x \right)}{\cos \left( x \right)}. Therefore, we have
limxπ2(sec(x)tan(x)×1tan(x))=limxπ2(1cos(x)sin(x)cos(x)×1sin(x)cos(x))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\sec \left( x \right)}{\tan \left( x \right)}\times \dfrac{1}{\tan \left( x \right)} \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\dfrac{1}{\cos \left( x \right)}}{\dfrac{\sin \left( x \right)}{\cos \left( x \right)}}\times \dfrac{1}{\dfrac{\sin \left( x \right)}{\cos \left( x \right)}} \right). Again by using the formula abcd=ab×dc\dfrac{\dfrac{a}{b}}{\dfrac{c}{d}}=\dfrac{a}{b}\times \dfrac{d}{c} we have
limxπ2(1cos(x)sin(x)cos(x)×1sin(x)cos(x))=limxπ2(1cos(x)×cos(x)sin(x)×cos(x)sin(x))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\dfrac{1}{\cos \left( x \right)}}{\dfrac{\sin \left( x \right)}{\cos \left( x \right)}}\times \dfrac{1}{\dfrac{\sin \left( x \right)}{\cos \left( x \right)}} \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{1}{\cos \left( x \right)}\times \dfrac{\cos \left( x \right)}{\sin \left( x \right)}\times \dfrac{\cos \left( x \right)}{\sin \left( x \right)} \right)
After cancelling the common terms we have limxπ2(1cos(x)×cos(x)sin(x)×cos(x)sin(x))=limxπ2(1cos(x)×cos2(x)sin2(x))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{1}{\cos \left( x \right)}\times \dfrac{\cos \left( x \right)}{\sin \left( x \right)}\times \dfrac{\cos \left( x \right)}{\sin \left( x \right)} \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{1}{\cos \left( x \right)}\times \dfrac{{{\cos }^{2}}\left( x \right)}{{{\sin }^{2}}\left( x \right)} \right)
Thus, we have
limxπ2(1cos(x)×cos2(x)sin2(x))=limxπ2(cos(x)sin2(x))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{1}{\cos \left( x \right)}\times \dfrac{{{\cos }^{2}}\left( x \right)}{{{\sin }^{2}}\left( x \right)} \right)=\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\cos \left( x \right)}{{{\sin }^{2}}\left( x \right)} \right). Now, we will substitute the value of cos(π2)=0\cos \left( \dfrac{\pi }{2} \right)=0 and sin(π2)=1\sin \left( \dfrac{\pi }{2} \right)=1 therefore, we have limxπ2(cos(x)sin2(x))=(cos(π2)sin2(π2))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \dfrac{\cos \left( x \right)}{{{\sin }^{2}}\left( x \right)} \right)=\left( \dfrac{\cos \left( \dfrac{\pi }{2} \right)}{{{\sin }^{2}}\left( \dfrac{\pi }{2} \right)} \right). After substituting the values we have (cos(π2)sin2(π2))=01\left( \dfrac{\cos \left( \dfrac{\pi }{2} \right)}{{{\sin }^{2}}\left( \dfrac{\pi }{2} \right)} \right)=\dfrac{0}{1}. This means that the value of the expression is equal to 0 after applying the limit.
Hence the value of limxπ2(cosxlog(tanx))\underset{x\to \dfrac{\pi }{2}}{\mathop{\lim }}\,\left( \cos x\cdot \log \left( \tan x \right) \right)is 0.

Note: While using L’Hopital’s rule one should notice that after first substitution of the limit we are getting the L’hopital’s signs or not. Here 00\cdot \infty is one of the signs by which we come to know that L’hopital’s rule is valid. One more thing should be noticed here and that is whenever we will differentiate any expression after L’hospital’s rule we should have a simpler term. That is, it should be in a fraction form and different functions should be on each other’s denominator and numerator. For example, we have converted cosxlog(tanx)\cos x\cdot \log \left( \tan x \right) into log(tanx)sec(x)\dfrac{\log \left( \tan x \right)}{\sec \left( x \right)} and then differentiated.