计算[img=127x40]1803177bfc8c3e2.png[/img]的程序表达为 A: sqrt(sin alpha ^ 2 + cos beta ^ 2) B: sqrt(sin^2(alpha) + cos^2(beta)) C: sqrt(pow(sin(alpha), 2) + pow(cos(beta), 2)) D: sqrt pow(sin(alpha), 2) + pow(cos(beta), 2)
计算[img=127x40]1803177bfc8c3e2.png[/img]的程序表达为 A: sqrt(sin alpha ^ 2 + cos beta ^ 2) B: sqrt(sin^2(alpha) + cos^2(beta)) C: sqrt(pow(sin(alpha), 2) + pow(cos(beta), 2)) D: sqrt pow(sin(alpha), 2) + pow(cos(beta), 2)
\((\cos\alpha \cos\beta, \cos\alpha \sin\beta, \sin\alpha),(1,1,0),(1,2,1)\)张成六面体体积最大为___. A: \(\sqrt{3}\) B: \(2\sqrt{3}\) C: \(\sqrt{6}\)
\((\cos\alpha \cos\beta, \cos\alpha \sin\beta, \sin\alpha),(1,1,0),(1,2,1)\)张成六面体体积最大为___. A: \(\sqrt{3}\) B: \(2\sqrt{3}\) C: \(\sqrt{6}\)
(4)$A$矢量的方向余弦(与三个坐标轴的夹角余弦)的大小是: A: $cos\alpha=3/\sqrt{14},cos\beta=-1/\sqrt{14},cos\gamma=3/\sqrt{14}$ B: $cos\alpha=4/\sqrt{14},cos\beta=-1/\sqrt{14},cos\gamma=3/\sqrt{14}$ C: $cos\alpha=2/\sqrt{14},cos\beta=-1/\sqrt{14},cos\gamma=3/\sqrt{14}$ D: $cos\alpha=3/\sqrt{14},cos\beta=9/\sqrt{14},cos\gamma=3/\sqrt{14}$
(4)$A$矢量的方向余弦(与三个坐标轴的夹角余弦)的大小是: A: $cos\alpha=3/\sqrt{14},cos\beta=-1/\sqrt{14},cos\gamma=3/\sqrt{14}$ B: $cos\alpha=4/\sqrt{14},cos\beta=-1/\sqrt{14},cos\gamma=3/\sqrt{14}$ C: $cos\alpha=2/\sqrt{14},cos\beta=-1/\sqrt{14},cos\gamma=3/\sqrt{14}$ D: $cos\alpha=3/\sqrt{14},cos\beta=9/\sqrt{14},cos\gamma=3/\sqrt{14}$
实验命令“fsurf(@(u,v)2*u*sin(v),@(u,v)3*u*cos(v),@(u,v)u^2,[0,5,0,2*pi]), hold on, fsurf(@(u,v)0,3*u*cos(v),@(u,v)u^2,[0,5,0,2*pi])”的结果是【 】
实验命令“fsurf(@(u,v)2*u*sin(v),@(u,v)3*u*cos(v),@(u,v)u^2,[0,5,0,2*pi]), hold on, fsurf(@(u,v)0,3*u*cos(v),@(u,v)u^2,[0,5,0,2*pi])”的结果是【 】
以\( (2,2,1) \)为起点,以\( (1,3,0) \)为终点的向量的方向余弦为( ). A: \( \cos \alpha = { { - 1} \over {\sqrt 3 }},\cos \beta = {1 \over {\sqrt 3 }},\cos \gamma = { { - 1} \over {\sqrt 3 }} \) B: \( \cos \alpha = {1 \over {\sqrt 3 }},\cos \beta = { { - 1} \over {\sqrt 3 }},\cos \gamma = { { - 1} \over {\sqrt 3 }} \) C: \( \cos \alpha = { { - 1} \over {\sqrt 3 }},\cos \beta = { { - 1} \over {\sqrt 3 }},\cos \gamma = { { - 1} \over {\sqrt 3 }} \) D: \( \cos \alpha = { { - 1} \over {\sqrt 3 }},\cos \beta = { { - 1} \over {\sqrt 3 }},\cos \gamma = {1 \over {\sqrt 3 }} \)
以\( (2,2,1) \)为起点,以\( (1,3,0) \)为终点的向量的方向余弦为( ). A: \( \cos \alpha = { { - 1} \over {\sqrt 3 }},\cos \beta = {1 \over {\sqrt 3 }},\cos \gamma = { { - 1} \over {\sqrt 3 }} \) B: \( \cos \alpha = {1 \over {\sqrt 3 }},\cos \beta = { { - 1} \over {\sqrt 3 }},\cos \gamma = { { - 1} \over {\sqrt 3 }} \) C: \( \cos \alpha = { { - 1} \over {\sqrt 3 }},\cos \beta = { { - 1} \over {\sqrt 3 }},\cos \gamma = { { - 1} \over {\sqrt 3 }} \) D: \( \cos \alpha = { { - 1} \over {\sqrt 3 }},\cos \beta = { { - 1} \over {\sqrt 3 }},\cos \gamma = {1 \over {\sqrt 3 }} \)
已知u(t)=2 cos (2t-90°)V,i(t)= cos (2t+150°)mA,则( )。
已知u(t)=2 cos (2t-90°)V,i(t)= cos (2t+150°)mA,则( )。
画出下列扇形区域。[img=541x528]18030733b119884.png[/img] A: ParametricPlot[{v Cos[u],v Sin[u]},{u,0,3Pi/2},{v,1/2,1}] B: ParametricPlot[{v Cos[u],v Sin[u]},{v,1/2,1},{u,0,3Pi/2}] C: ParametricPlot[{v Cos[u],v Sin[u]},{u,-Pi/2,0},{v,1/2,1}] D: ParametricPlot[{v Cos[u],v Sin[u]},{v,1/2,1},{u,-Pi/2,0}]
画出下列扇形区域。[img=541x528]18030733b119884.png[/img] A: ParametricPlot[{v Cos[u],v Sin[u]},{u,0,3Pi/2},{v,1/2,1}] B: ParametricPlot[{v Cos[u],v Sin[u]},{v,1/2,1},{u,0,3Pi/2}] C: ParametricPlot[{v Cos[u],v Sin[u]},{u,-Pi/2,0},{v,1/2,1}] D: ParametricPlot[{v Cos[u],v Sin[u]},{v,1/2,1},{u,-Pi/2,0}]
一平面简谐波以速度\(u\)沿\(x\)轴正方向传播,在\(t=t'\)时波形曲线如图所示.则坐标原点\(O\)的振动方程为 A: \(y=a\)cos[\(\frac{u}{b}\)\((t-t')\)\(+\frac{\pi}{2}\)] B: \(y=a\)cos[2\(\pi\)\(\frac{u}{b}\)\((t-t')\)\(-\frac{\pi}{2}\)] C: \(y=a\)cos[\(\pi\)\(\frac{u}{b}\)\((t+t')\)\(+\frac{\pi}{2}\)] D: \(y=a\)cos[\(\pi\)\(\frac{u}{b}\)\((t-t')\)\(-\frac{\pi}{2}\)]
一平面简谐波以速度\(u\)沿\(x\)轴正方向传播,在\(t=t'\)时波形曲线如图所示.则坐标原点\(O\)的振动方程为 A: \(y=a\)cos[\(\frac{u}{b}\)\((t-t')\)\(+\frac{\pi}{2}\)] B: \(y=a\)cos[2\(\pi\)\(\frac{u}{b}\)\((t-t')\)\(-\frac{\pi}{2}\)] C: \(y=a\)cos[\(\pi\)\(\frac{u}{b}\)\((t+t')\)\(+\frac{\pi}{2}\)] D: \(y=a\)cos[\(\pi\)\(\frac{u}{b}\)\((t-t')\)\(-\frac{\pi}{2}\)]
3.将正弦电压 u = 10 cos ( 314t+30( ) V 施加于感抗 XL = 5 ( 的电感元件上,则通过该元件的 电流i = ( )。 A: A、2 cos( 314t-60() A B: 2 cos( 314t+60() A C: 2 cos( 314t+30() A D: 2 cos( 314t-30() A
3.将正弦电压 u = 10 cos ( 314t+30( ) V 施加于感抗 XL = 5 ( 的电感元件上,则通过该元件的 电流i = ( )。 A: A、2 cos( 314t-60() A B: 2 cos( 314t+60() A C: 2 cos( 314t+30() A D: 2 cos( 314t-30() A
实验命令“surf(@(u,v)2*u.*sin(v),@(u,v)3*u.*cos(v),@(u,v)u.^2,[0,5,0,2*pi])”表示【 】
实验命令“surf(@(u,v)2*u.*sin(v),@(u,v)3*u.*cos(v),@(u,v)u.^2,[0,5,0,2*pi])”表示【 】