11. 设函数$f(x)=({{\text{e}}^{x}}-1)({{\text{e}}^{2x}}-2)\cdots ({{\text{e}}^{nx}}-n)$,其中$n$为正整数,则${f}'(0)=$( )。 A: ${{(-1)}^{n-1}}(n-1)!$ B: ${{(-1)}^{n}}(n-1)!$ C: ${{(-1)}^{n-1}}n!$ D: ${{(-1)}^{n}}n!$
11. 设函数$f(x)=({{\text{e}}^{x}}-1)({{\text{e}}^{2x}}-2)\cdots ({{\text{e}}^{nx}}-n)$,其中$n$为正整数,则${f}'(0)=$( )。 A: ${{(-1)}^{n-1}}(n-1)!$ B: ${{(-1)}^{n}}(n-1)!$ C: ${{(-1)}^{n-1}}n!$ D: ${{(-1)}^{n}}n!$
<;?php$text = 'This is a test'; $n=strlen($text); // $n=14echo substr_count($text, 'is');?>;以上程序的输出结果是( )。 A: 1 B: is is a test C: true D: 2
<;?php$text = 'This is a test'; $n=strlen($text); // $n=14echo substr_count($text, 'is');?>;以上程序的输出结果是( )。 A: 1 B: is is a test C: true D: 2
下列数列中,无界但不是无穷大的是 A: $\frac{n}{\ln n}$ B: ${{(-1)}^{n}}{{n}^{2}}+n$ C: $n\sin \frac{n\text{ }\!\!\pi\!\!\text{ }}{2}$ D: $\frac{{{\text{e}}^{n}}}{n!}$
下列数列中,无界但不是无穷大的是 A: $\frac{n}{\ln n}$ B: ${{(-1)}^{n}}{{n}^{2}}+n$ C: $n\sin \frac{n\text{ }\!\!\pi\!\!\text{ }}{2}$ D: $\frac{{{\text{e}}^{n}}}{n!}$
1. 函数$y=\arctan x$在$x=0$处的$3$阶导数值为______ 。2. Legendre多项式${{L}_{n}}(x)=\frac{{{\text{d}}^{n}}[{{({{x}^{2}}-1)}^{n}}]}{\text{d}{{x}^{n}}},\ n=1,2,...$,则${{L}_{2}}(1)=$______ 。
1. 函数$y=\arctan x$在$x=0$处的$3$阶导数值为______ 。2. Legendre多项式${{L}_{n}}(x)=\frac{{{\text{d}}^{n}}[{{({{x}^{2}}-1)}^{n}}]}{\text{d}{{x}^{n}}},\ n=1,2,...$,则${{L}_{2}}(1)=$______ 。
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$\int_{0}^{\frac{\text{ }\!\!\pi\!\!\text{ }}{4}}{[\cos (2t)\mathbf{i}+\sin (2t)\mathbf{j}+t\sin t\mathbf{k}]}\operatorname{dt}=$( ) A: $(\frac{1}{2},\frac{1}{2},\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$ B: $(1,\frac{1}{2},\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$ C: $(\frac{1}{2},1,\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$ D: $(1,1,\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$
$\int_{0}^{\frac{\text{ }\!\!\pi\!\!\text{ }}{4}}{[\cos (2t)\mathbf{i}+\sin (2t)\mathbf{j}+t\sin t\mathbf{k}]}\operatorname{dt}=$( ) A: $(\frac{1}{2},\frac{1}{2},\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$ B: $(1,\frac{1}{2},\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$ C: $(\frac{1}{2},1,\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$ D: $(1,1,\frac{4-\text{ }\!\!\pi\!\!\text{ }}{4\sqrt{2}})$
函数TEXT("2018/1/1","mm")返回值为1。
函数TEXT("2018/1/1","mm")返回值为1。
函数TEXT('2018/1/1','mm')返回值为1。
函数TEXT('2018/1/1','mm')返回值为1。
已知齐次方程$(x-1){{y}^{''}}-x{{y}^{'}}+y=0$的通解为$Y={{C}_{1}}x+{{C}_{2}}{{e}^{x}}$,则方程$(x-1){{y}^{''}}-x{{y}^{'}}+y={{(x-1)}^{2}}$的通解是( ) A: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-({{x}^{2}}+1)$ B: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-({{x}^{3}}+1)$ C: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-{{x}^{2}}$ D: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-{{x}^{2}}+1$
已知齐次方程$(x-1){{y}^{''}}-x{{y}^{'}}+y=0$的通解为$Y={{C}_{1}}x+{{C}_{2}}{{e}^{x}}$,则方程$(x-1){{y}^{''}}-x{{y}^{'}}+y={{(x-1)}^{2}}$的通解是( ) A: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-({{x}^{2}}+1)$ B: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-({{x}^{3}}+1)$ C: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-{{x}^{2}}$ D: ${{\text{C}}_{1}}x+{{\text{C}}_{2}}{{e}^{x}}-{{x}^{2}}+1$
已知()y()=()ln()x(),则()y()(()n())()=()。A.()(()−()1())()n()n()!()x()−()n()"()role="presentation">()(()−()1())()n()n()!()x()−()n();()B.()(()−()1())()n()(()n()−()1())()!()x()−()2()n()"()role="presentation">()(()−()1())()n()(()n()−()1())()!()x()−()2()n();()C.()(()−()1())()n()−()1()(()n()−()1())()!()x()n()"()role="presentation">()(()−()1())()n()−()1()(()n()−()1())()!()x()-n();()D.()(()−()1())()n()−()1()n()!()x()−()n()+()1()"()role="presentation">()(()−()1())()n()−()1()n()!()x()−()n()+()1().
已知()y()=()ln()x(),则()y()(()n())()=()。A.()(()−()1())()n()n()!()x()−()n()"()role="presentation">()(()−()1())()n()n()!()x()−()n();()B.()(()−()1())()n()(()n()−()1())()!()x()−()2()n()"()role="presentation">()(()−()1())()n()(()n()−()1())()!()x()−()2()n();()C.()(()−()1())()n()−()1()(()n()−()1())()!()x()n()"()role="presentation">()(()−()1())()n()−()1()(()n()−()1())()!()x()-n();()D.()(()−()1())()n()−()1()n()!()x()−()n()+()1()"()role="presentation">()(()−()1())()n()−()1()n()!()x()−()n()+()1().