ベクトル解析

直交座標系において, , , 軸方向の単位ベクトルをそれぞれ , , とする.ベクトル場

とする.次の面 および に対する面積分を計算せよ.

  1. を円筒面 とする (上面と底面の無い円筒の表面) .円筒外向き法線ベクトルを用いよ.
  2. を円筒面の一部 と長方形面 からなる半円筒面とする (上面と底面の無い半円筒の表面) .半円筒外向き法線ベクトルを用いよ.
  3. を円筒面 と, 平面 で囲まれた領域の境界とする.外向き法線ベクトルを用いよ.

Vector Analysis

The unit vectors on , , and axes of Cartesian coordinates are denoted by , , and , respectively. Let the vector field be:

Find the integral of over the following areas , , and :

  1. is the part of the cylindrical surface , i.e., the surface of the cylinder without top and bottom disks. Use the normal vector pointing outside the cylinder.
  2. is the surface consisting of the part of the cylindrical surface and the rectangular surface , i.e., the surface of the half-cylinder without top and bottom planes. Use the normal vector pointing outside the half-cylinder.
  3. is the boundary of the region enclosed by the cylindrical surface , the planes , , and . Use the outward pointing normal vector.

DeepSeekV3

We are given the vector field:

and need to compute the flux integrals over the surfaces , , and .

1. Flux over

is the lateral surface of the cylinder for , with the outward-pointing normal vector.

  • Parametrization: , where and .
  • Outward normal vector: .
  • Dot product: .
  • Integral over :

2. Flux over

consists of the lateral surface of the half-cylinder for and , and the rectangular surface at for and .

  • For the half-cylinder part (similar to , but with ):
  • For the rectangular surface at , the normal vector is , and: so the flux through this part is zero.
  • Total flux over :

3. Flux over

is the boundary of the region enclosed by the cylindrical surface , the planes , , and , with the outward-pointing normal vector.

  • Using the divergence theorem:
  • Volume integral:
  • The volume is bounded by , , giving:
  • Therefore, the flux through is:

Final Answers:

  1. Flux over : .
  2. Flux over : .
  3. Flux over : .

To solve the problem of integrating the vector field over the specified surfaces, we proceed as follows:

1. Surface : Cylindrical Surface for

  • Parameterization:

    • Use cylindrical coordinates with , so , , and .
    • Position vector: .
  • Differential Area Vector:

    • Compute partial derivatives: and .
    • Cross product: .
    • This gives the outward-pointing normal vector.
  • Dot Product:

    • .
  • Integral:

    • Integrate over :
    • Integrate over :
    • Result for : .

2. Surface : Half-Cylinder with for and , plus the rectangle

  • Cylindrical Part ():

    • Similar to , but for (since ).
    • Integral over :
  • Rectangular Part ():

    • The rectangle is at , , .
    • Normal vector points downward: .
    • (since ).
    • Integral over :
  • Result for : .

3. Surface : Boundary of the Region Enclosed by , , , and

  • Divergence Theorem:

    • Since is a closed surface, use the Divergence Theorem:
    • Compute divergence:
    • Volume is a cylinder with radius 1, height from to , cut by the plane .
    • The volume can be found by integrating over the cylindrical coordinates, considering the bounds imposed by .
  • Volume Integral:

    • Convert to cylindrical coordinates: , .
    • The plane gives .
    • The limits for are .
    • Integrate:
    • Result for : .

Final Answers:

  1. For : .
  2. For : .
  3. For : .

GPT-4o

要计算面积分 ,需要明确如何表达面积微元法向量 并将其与向量场 进行点乘。以下是分步说明:

1. 面积微元法向量 的定义

对于给定的曲面 ,面积微元法向量是:

其中:

  • 是曲面 在每一点的单位法向量。
  • 是该点处的小面积元。

因此, 可以表示为:

我们需要将 表达为参数形式。

2. 分步骤计算的流程

(a) 选择适当的参数化

每个曲面 可以用参数化的方法表示其点 和面积微元 。参数化的选择依赖于曲面的定义。

(b) 计算法向量

通过参数化 ,我们可以用两个参数 表示曲面上任意一点。参数化函数为 ,则法向量 可由叉积计算:

对该向量进行归一化后得到单位法向量。

(c) 求点积并积分

将参数化后的 表达为参数形式,计算点积并在参数范围内求积分:

3. 应用到具体问题

问题 1:柱面部分

  • 参数化:柱面 可用参数 表示:
  • 法向量 的叉积为:
  • 积分表达式

问题 2:半柱面部分

同理,将半柱面 与矩形面 分别参数化,重复上述过程。

问题 3:封闭区域

利用柱面 和各个平面参数化,求出相应的法向量并积分。如果封闭区域完整,可以用高斯散度定理将问题转化为体积分。

4. 核心计算

将上述结果代入积分表达式,即可逐步计算得到结果。重要的是将 准确写成参数形式,然后依次积分。