两柱面\( {x^2} + {y^2} = {R^2} \) ,\( {x^2} + {z^2} = {R^2} \) 所围立体体积为( ) A: \( 8{R^2} \) B: \( 10{R^2} \) C: \( 12{R^2} \) D: \( 16{R^2} \)
两柱面\( {x^2} + {y^2} = {R^2} \) ,\( {x^2} + {z^2} = {R^2} \) 所围立体体积为( ) A: \( 8{R^2} \) B: \( 10{R^2} \) C: \( 12{R^2} \) D: \( 16{R^2} \)
设方程\({x^2} + {y^2} + {z^2} = 2Rx\)确定函数\(z=z(x,y)\),则\( { { \partial z} \over {\partial x}}=\) A: \( { { \partial z} \over {\partial x}} = { { R +x} \over z}\) B: \( { { \partial z} \over {\partial x}} =- { { R +x} \over z}\) C: \( { { \partial z} \over {\partial x}} = { { R - x} \over z}\) D: \( { { \partial z} \over {\partial x}} =- { { R - x} \over z}\)
设方程\({x^2} + {y^2} + {z^2} = 2Rx\)确定函数\(z=z(x,y)\),则\( { { \partial z} \over {\partial x}}=\) A: \( { { \partial z} \over {\partial x}} = { { R +x} \over z}\) B: \( { { \partial z} \over {\partial x}} =- { { R +x} \over z}\) C: \( { { \partial z} \over {\partial x}} = { { R - x} \over z}\) D: \( { { \partial z} \over {\partial x}} =- { { R - x} \over z}\)
设A=,且A的特征值为1,2,3,则有() A: x=2,y=4,z=8 B: x=-1,y=4,z∈R C: x=-2,y=2,z∈R D: x=-1,y=4,z=3
设A=,且A的特征值为1,2,3,则有() A: x=2,y=4,z=8 B: x=-1,y=4,z∈R C: x=-2,y=2,z∈R D: x=-1,y=4,z=3
底圆半径相等的两个直交圆柱面\({x^2} + {y^2} = {R^2}\) 及\({x^2} + {z^2} = {R^2}\) 所围成的立体的表面积为( ) A: \(16{R^2}\) B: \(16{R^3}\) C: \(16{R}\) D: \(16{R^4}\)
底圆半径相等的两个直交圆柱面\({x^2} + {y^2} = {R^2}\) 及\({x^2} + {z^2} = {R^2}\) 所围成的立体的表面积为( ) A: \(16{R^2}\) B: \(16{R^3}\) C: \(16{R}\) D: \(16{R^4}\)
()为声压反射率的公式。 A: r<sub>p</sub>=(Z<sub>2</sub>-Z<sub>1</sub>)/Z<sub>1</sub>+Z<sub>2</sub> B: t<sub>p</sub>=1+r<sub>p</sub> C: R=r<sub>p</sub><sup>2</sup> D: D=1-r<sub>p</sub><sup>2</sup>
()为声压反射率的公式。 A: r<sub>p</sub>=(Z<sub>2</sub>-Z<sub>1</sub>)/Z<sub>1</sub>+Z<sub>2</sub> B: t<sub>p</sub>=1+r<sub>p</sub> C: R=r<sub>p</sub><sup>2</sup> D: D=1-r<sub>p</sub><sup>2</sup>
设方程\(z^2+y^2+z^2 = 4z\)确定函数\(z=z(x,y)\),则\( { { {\partial ^2}z} \over {\partial {x^2}}} =\) A: \( { { { { (2 - z)}^2} + {x^2}} \over { { {(2+ z)}^3}}}\) B: \( { { { { (2 - z)}^2} + {x^2}} \over { { {(2 - z)}^3}}}\) C: \( { { { { (2 - z)}^2} -{x^2}} \over { { {(2 - z)}^3}}}\) D: \( { { { { (2 + z)}^2} + {x^2}} \over { { {(2 - z)}^3}}}\)
设方程\(z^2+y^2+z^2 = 4z\)确定函数\(z=z(x,y)\),则\( { { {\partial ^2}z} \over {\partial {x^2}}} =\) A: \( { { { { (2 - z)}^2} + {x^2}} \over { { {(2+ z)}^3}}}\) B: \( { { { { (2 - z)}^2} + {x^2}} \over { { {(2 - z)}^3}}}\) C: \( { { { { (2 - z)}^2} -{x^2}} \over { { {(2 - z)}^3}}}\) D: \( { { { { (2 + z)}^2} + {x^2}} \over { { {(2 - z)}^3}}}\)
设复数z=2+bi(b∈R)且|z|=2,则复数z的虚部为( )
设复数z=2+bi(b∈R)且|z|=2,则复数z的虚部为( )
若复数z=(3+bi)(1+i)-2是纯虚数(b∈R),则|z|=( )A.1B.2C.3D.4
若复数z=(3+bi)(1+i)-2是纯虚数(b∈R),则|z|=( )A.1B.2C.3D.4
9. 已知函数$z=z(x,y)$由${{z}^{3}}-3xyz={{a}^{3}}$确定,则$\frac{{{\partial }^{2}}z}{\partial x\partial y}=$( ) A: $\frac{z({{z}^{4}}-2xy{{z}^{2}}-{{x}^{2}}{{y}^{2}})}{{{({{z}^{2}}-xy)}^{3}}}$ B: $\frac{z({{z}^{4}}-2xy{{z}^{2}}-xy)}{{{({{z}^{2}}-xy)}^{2}}}$ C: $\frac{z({{z}^{3}}-2xyz-{{x}^{2}}{{y}^{2}})}{{{({{z}^{2}}-xy)}^{3}}}$ D: $\frac{z({{z}^{3}}-2xy{{z}^{2}}-{{x}^{2}}y)}{{{({{z}^{2}}-xy)}^{3}}}$
9. 已知函数$z=z(x,y)$由${{z}^{3}}-3xyz={{a}^{3}}$确定,则$\frac{{{\partial }^{2}}z}{\partial x\partial y}=$( ) A: $\frac{z({{z}^{4}}-2xy{{z}^{2}}-{{x}^{2}}{{y}^{2}})}{{{({{z}^{2}}-xy)}^{3}}}$ B: $\frac{z({{z}^{4}}-2xy{{z}^{2}}-xy)}{{{({{z}^{2}}-xy)}^{2}}}$ C: $\frac{z({{z}^{3}}-2xyz-{{x}^{2}}{{y}^{2}})}{{{({{z}^{2}}-xy)}^{3}}}$ D: $\frac{z({{z}^{3}}-2xy{{z}^{2}}-{{x}^{2}}y)}{{{({{z}^{2}}-xy)}^{3}}}$
若f(z)在圆|z|<R内解析,f(0)=0,|f(z)|≤M<+∞,则(1)|f(z)|≤;(2)若在圆内有一点z(0<|z|<R)使
若f(z)在圆|z|<R内解析,f(0)=0,|f(z)|≤M<+∞,则(1)|f(z)|≤;(2)若在圆内有一点z(0<|z|<R)使