计算\(\int_{\;L} {ydx + xdy} \),其中 \(L\)为圆周 \(x = R\cos t\), \(y = R\sin t\)上对应 \(t = 0\)到 \(t = {\pi \over 2}\)的一段弧。
A: -1
B: 1
C: 0
D: 2
A: -1
B: 1
C: 0
D: 2
举一反三
- 已知\(L\)为圆周 \(x = a\cos t,y = a\sin t(0 \le t \le 2\pi )\),则\({\oint_L {({x^2} + {y^2})} ^n}ds{\rm{ = }}\) ( ). A: \(2\pi {a^{2n + 1}}\) B: \(2\pi {a^{2n - 1}}\) C: \(\pi {a^{2n + 1}}\) D: \(\pi {a^{2n - 1}}\)
- 计算曲线积分\({\oint_L {({x^2} + {y^2})} ^3}ds\),其中\(L\)为圆周\(x = a\cos t,y = a\sin t(0 \le t \le 2\pi )\)。 A: \(2\pi {a^7}\) B: \(2\pi {a^6}\) C: \(2\pi {a^5}\) D: \(2\pi {a^8}\)
- 计算\({\oint_L {({x^2} + {y^2})} ^n}ds\),其中\(L\)为圆周\(x = a\cos t\),\(y=asint\)\((0 \le t \le 2\pi )\)。 A: \(2\pi {a^{n + 1}}\) B: \(2\pi {a^{2n + 1}}\) C: \(\pi {a^{n + 1}}\) D: \(2\pi {a^{n + 1}}\)
- 已知“syms x y z t r; x=r*cos(t); y=r*sin(t); f=x+y+z; r1=0; r2=1; z1=r^2; z2=1; t1=0; t2=2*pi; f1=int(f*r,z,z1,z2); f2=int(f1,r,r1,r2); A=int(f2,t,t1,t2)”,则下列说法正确的是【】
- 曲线$\left\{ \matrix{ {x^2} + {y^2} + {z^2} = 9 \cr y = x \cr} \right.$的参数方程为( ). A: $$\left\{ \matrix{ x = \sqrt 3 \cos t \cr y = \sqrt 3 \cos t \cr z = \sqrt 3 \sin t \cr} \right.(0 \le t \le 2\pi )$$ B: $$\left\{ \matrix{ x = {3 \over {\sqrt 2 }}\cos t\cr y = {3 \over {\sqrt 2 }}\cos t \cr z = 3\sin t \cr} \right.(0 \le t \le 2\pi )$$ C: $$\left\{ \matrix{ x = \cos t\cr y = \cos t\cr z = \sin t \cr} \right.(0 \le t \le 2\pi )$$ D: $$\left\{ \matrix{ x = {{\sqrt 3 } \over 3}\cos t\cr y = {{\sqrt 3 } \over 3}\cos t \cr z = {{\sqrt 3 } \over 3}\sin t\cr} \right.(0 \le t \le 2\pi )$$