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If you are looking for some problems with solutions you can find some by clicking on the "Practice Problems" link above.
If you are looking for some problems with solutions you can find some by clicking on the "Practice Problems" link above.
Section 3.9 : Chain Rule
For problems 1 – 51 differentiate the given function.
- \(g\left( x \right) = {\left( {3 - 8x} \right)^{11}}\)
- \(g\left( z \right) = \sqrt[7]{{9{z^3}}}\)
- \(h\left( t \right) = {\left( {9 + 2t - {t^3}} \right)^6}\)
- \(y = \sqrt {{w^3} + 8{w^2}} \)
- \(R\left( v \right) = {\left( {14{v^2} - 3v} \right)^{ - 2}}\)
- \(\displaystyle H\left( w \right) = \frac{2}{{{{\left( {6 - 5w} \right)}^8}}}\)
- \(f\left( x \right) = \sin \left( {4x + 7{x^4}} \right)\)
- \(T\left( x \right) = \tan \left( {1 - 2{{\bf{e}}^x}} \right)\)
- \(g\left( z \right) = \cos \left( {\sin \left( z \right) + {z^2}} \right)\)
- \(h\left( u \right) = \sec \left( {{u^2} - u} \right)\)
- \(y = \cot \left( {1 + \cot \left( x \right)} \right)\)
- \(f\left( t \right) = {{\bf{e}}^{1 - {t^{\,2}}}}\)
- \(J\left( z \right) = {{\bf{e}}^{12z - {z^{\,6}}}}\)
- \(f\left( z \right) = {{\bf{e}}^{z + \ln \left( z \right)}}\)
- \(B\left( x \right) = {7^{\cos \left( x \right)}}\)
- \(z = {3^{{x^{\,2}} - 9x}}\)
- \(R\left( z \right) = \ln \left( {6z + {{\bf{e}}^z}} \right)\)
- \(h\left( w \right) = \ln \left( {{w^7} - {w^5} + {w^3} - w} \right)\)
- \(g\left( t \right) = \ln \left( {1 - \csc \left( t \right)} \right)\)
- \(f\left( v \right) = {\tan ^{ - 1}}\left( {3 - 2v} \right)\)
- \(h\left( t \right) = {\sin ^{ - 1}}\left( {9t} \right)\)
- \(A\left( t \right) = \cos \left( t \right) - \sqrt[6]{{1 - \sin \left( t \right)}}\)
- \(H\left( z \right) = \ln \left( {6z} \right) - 4\sec \left( z \right)\)
- \(f\left( x \right) = {\tan ^4}\left( x \right) + \tan \left( {{x^4}} \right)\)
- \(f\left( u \right) = {{\bf{e}}^{4u}} - 6{{\bf{e}}^{ - u}} + 7{{\bf{e}}^{{u^{\,2}} - 8u}}\)
- \(g\left( z \right) = {\sec ^8}\left( z \right) + \sec \left( {{z^8}} \right)\)
- \(k\left( w \right) = {\left( {{w^4} - 1} \right)^5} + \sqrt {2 + 9w} \)
- \(h\left( x \right) = \sqrt[3]{{{x^2} - 5x + 1}} + {\left( {9x + 4} \right)^{ - 7}}\)
- \(T\left( x \right) = {\left( {2{x^3} - 1} \right)^5}{\left( {5 - 3x} \right)^4}\)
- \(w = \left( {{z^2} + 4z} \right)\sin \left( {1 - 2z} \right)\)
- \(Y\left( t \right) = {t^8}{\cos ^4}\left( t \right)\)
- \(f\left( x \right) = \sqrt {6 - {x^4}} \,\,\,\ln \left( {10x + 3} \right)\)
- \(A\left( z \right) = \sec \left( {4z} \right)\tan \left( {{z^2}} \right)\)
- \(h\left( v \right) = \sqrt {5v} + \ln \left( {{v^4}} \right){{\bf{e}}^{6 + 9v}}\)
- \(\displaystyle f\left( x \right) = \frac{{{{\bf{e}}^{{x^{\,2}} + 8x}}}}{{\sqrt {{x^4} + 7} }}\)
- \(\displaystyle g\left( x \right) = \frac{{{{\left( {4x + 1} \right)}^3}}}{{{{\left( {{x^2} - x} \right)}^6}}}\)
- \(\displaystyle g\left( t \right) = \frac{{\csc \left( {1 - t} \right)}}{{1 + {{\bf{e}}^{ - t}}}}\)
- \(\displaystyle V\left( z \right) = \frac{{{{\sin }^2}\left( z \right)}}{{1 + \cos \left( {{z^2}} \right)}}\)
- \(U\left( w \right) = \ln \left( {{{\bf{e}}^w}\cos \left( w \right)} \right)\)
- \(h\left( t \right) = \tan \left( {\left( {5 - {t^2}} \right)\ln \left( t \right)} \right)\)
- \(\displaystyle z = \ln \left( {\frac{{3 + x}}{{2 - {x^2}}}} \right)\)
- \(\displaystyle g\left( v \right) = \sqrt {\frac{{{{\bf{e}}^v}}}{{7 + 2v}}} \)
- \(f\left( x \right) = \sqrt {{x^2} + \sqrt {1 + 4x} } \)
- \(u = {\left( {6 + \cos \left( {8w} \right)} \right)^5}\)
- \(h\left( z \right) = {\left( {7z - {z^2} + {{\bf{e}}^{5{z^{\,2}} + z}}} \right)^{ - 4}}\)
- \(A\left( y \right) = \ln \left( {7{y^3} + {{\sin }^2}\left( y \right)} \right)\)
- \(g\left( x \right) = {\csc ^6}\left( {8x} \right)\)
- \(V\left( w \right) = \sqrt[4]{{\cos \left( {9 - {w^2}} \right) + \ln \left( {6w + 5} \right)}}\)
- \(h\left( t \right) = \sin \left( {{t^3}{{\bf{e}}^{ - 6t}}} \right)\)
- \(B\left( r \right) = {\left( {{{\bf{e}}^{\sin \left( r \right)}} - \sin \left( {{{\bf{e}}^r}} \right)} \right)^8}\)
- \(f\left( z \right) = {\cos ^2}\left( {1 + {{\cos }^2}\left( z \right)} \right)\)
- Find the tangent line to \(f\left( x \right) = {\left( {2 - 4{x^2}} \right)^5}\) at \(x = 1\).
- Find the tangent line to \(f\left( x \right) = {{\bf{e}}^{2x + 4}} - 8\ln \left( {{x^2} - 3} \right)\) at \(x = - 2\).
- Determine where \(A\left( t \right) = {t^3}{\left( {9 - t} \right)^4}\) is increasing and decreasing.
- Is \(h\left( x \right) = {\left( {2x + 1} \right)^4}{\left( {2 - x} \right)^5}\) increasing or decreasing more in the interval \(\left[ { - 2,3} \right]\)?
- Determine where \(\displaystyle U\left( w \right) = 3\cos \left( {\frac{w}{2}} \right) + w - 3\) is increasing and decreasing in the interval \(\left[ { - 10,10} \right]\).
- If the position of an object is given by \(s\left( t \right) = 4\sin \left( {3t} \right) - 10t + 7\). Determine where, if anywhere, the object is not moving in the interval \(\left[ {0,4} \right]\).
- Determine where \(f\left( x \right) = 6\sin \left( {2x} \right) - 7\cos \left( {2x} \right) - 3\) is increasing and decreasing in the interval \(\left[ { - 3,2} \right]\).
- Determine where \(H\left( w \right) = \left( {{w^2} - 1} \right){{\bf{e}}^{2 - {w^{\,2}}}}\) is increasing and decreasing.
- What percentage of \(\left[ { - 3,5} \right]\) is the function \(g\left( z \right) = {{\bf{e}}^{{z^2} - 8}} + 3{{\bf{e}}^{1 - 2{z^2}}}\) decreasing?
- The position of an object is given by \(s\left( t \right) = \ln \left( {2{t^3} - 21{t^2} + 36t + 200} \right)\). During the first 10 hours of motion (assuming the motion starts at \(t = 0\)) what percentage of the time is the object moving to the right?
- For the function \(\displaystyle f\left( x \right) = 1 - \frac{x}{2} - \ln \left( {2 + 9x - {x^2}} \right)\) determine each of the following.
- The interval on which the function is defined.
- Where the function is increasing and decreasing.