2D Wave Equation (2)

• 2维波动方程初边值问题:
  2维波动方程如下,
  egin{equation}
  frac{partial^2u}{partial t^2} = Dleft(frac{partial^2u}{partial x^2} + frac{partial^2 u}{partial y^2} ight), quad (x, y) in Omega = [-L_x. L_x] imes[-L_y, L_y], tin[0, T]
  label{eq_1}
  end{equation}
  初始条件如下,
  egin{equation}
  left{
  egin{split}
  &u(x, y, 0) = u_0(x, y),quad &(x, y) in Omega \
  &u_t(x, y, 0) = 0,quad &(x, y) in Omega
  end{split}
  ight.
  label{eq_2}
  end{equation}
  边界条件如下,
  egin{equation}
  u(x, y, t) = 0, quad (x, y) in partial Omega, t in [0, T]
  label{eq_3}
  end{equation}
• 连续型系统的离散化:
  本文拟降阶时间微分项, 令
  egin{equation}
  frac{partial u}{partial t} = v
  label{eq_4}
  end{equation}
  式$eqref{eq_1}$转化如下,
  egin{equation}
  left{
  egin{split}
  frac{partial u}{partial t} &= v \
  frac{partial v}{partial t} &= Dleft( frac{partial^2 u}{partial x^2} + frac{partial^2 u}{partial y^2} ight) \
  end{split}
  ight .
  label{eq_5}
  end{equation}
  式$eqref{eq_2}$转化如下,
  egin{equation}
  left{
  egin{split}
  u(x, y, 0) &= u_0(x, y) \
  v(x, y, 0) &= 0 \
  end{split}
  ight.
  label{eq_6}
  end{equation}
  本文拟采用中心差分处理空间微分项, 式$eqref{eq_5}$转换如下,
  egin{equation}
  left{
  egin{split}
  frac{partial u_{i, j}}{partial t} &= v_{i, j} \
  frac{partial v_{i, j}}{partial t} &= Dleft( frac{u_{i+1,j} + u_{i-1, j} - 2u_{i,j}}{h_x^2} + frac{u_{i,j+1} + u_{i,j-1} - 2u_{i,j}}{h_y^2} ight)
  end{split}
  ight .
  label{eq_7}
  end{equation}
  令,
  egin{equation*}
  U = egin{bmatrix}
  u_{0,0} & cdots & u_{0,n_x} \
  vdots & ddots & vdots \
  u_{n_y,0} & cdots & u_{n_y,n_x} \
  end{bmatrix}quad
  V = egin{bmatrix}
  v_{0,0} & cdots & v_{0,n_x} \
  vdots & ddots & vdots \
  v_{n_y,0} & cdots & v_{n_y,n_x} \
  end{bmatrix}quad
  A_x = egin{bmatrix}
  -2 & 1 & & & \
  1 & -2 & 1 & & \
  & ddots & ddots & ddots & \
  & & 1 & -2 & 1 \
  & & & 1 & -2 \
  end{bmatrix}quad
  A_y = egin{bmatrix}
  -2 & 1 & & & \
  1 & -2 & 1 & & \
  & ddots & ddots & ddots & \
  & & 1 & -2 & 1 \
  & & & 1 & -2 \
  end{bmatrix}
  end{equation*}
  式$eqref{eq_7}$转换如下,
  egin{equation}
  left{
  egin{split}
  frac{partial U}{partial t} &= V \
  frac{partial V}{partial t} &= Dleft( frac{UA_x}{h_x^2} + frac{A_yU}{h_y^2} ight)
  end{split}
  ight.
  label{eq_8}
  end{equation}
  注意, 上式$eqref{eq_8}$中$U$之边界值需以边界条件式$eqref{eq_3}$填充. 本文拟采用Runge-Kutta方法求解上式$eqref{eq_8}$, 则有,
  egin{equation}
  egin{bmatrix}U \ Vend{bmatrix}^{k+1}
  = egin{bmatrix}U \ Vend{bmatrix}^k + frac{1}{6}left(vec{K}_1 + 2vec{K}_2 + 2vec{K}_3 + vec{K}_4 ight)h_t
  label{eq_9}
  end{equation}
  注意, 上式$eqref{eq_9}$中$U$、$V$之初始值需以初始条件式$eqref{eq_6}$填充. 其中,
  egin{gather*}
  vec{F}(U, V) = egin{bmatrix} V \ Dleft( frac{UA_x}{h_x^2} + frac{A_yU}{h_y^2} ight) end{bmatrix} =
  egin{bmatrix} F_1 \ F_2 end{bmatrix}\
  vec{K}_1 = vec{F}(U, V) \
  vec{K}_2 = vec{F}(U + frac{h_t}{2}F_1^{(1)}, V+frac{h_t}{2}F_2^{(1)}) \
  vec{K}_3 = vec{F}(U + frac{h_t}{2}F_1^{(2)}, V+frac{h_t}{2}F_2^{(2)}) \
  vec{K}_4 = vec{F}(U + h_tF_1^{(3)}, V + h_tF_2^{(3)}) \
  end{gather*}
  其中, 上标$^{(1)}$、$^{(2)}$、$^{(3)}$分别代表相应分量来自于$vec{K}_1$、$vec{K}_2$、$vec{K}_3$. 由此, 根据式$eqref{eq_9}$即可完成式$eqref{eq_1}$2维波动方程的数值求解.
• 代码实现:
  Part Ⅰ:
  现以如下初始条件为例进行算法实施,
  egin{equation*}
  u_0(x,y) = 0.1mathrm{e}^{-((x-x_c)^2 + (y-y_c)^2)/0.0005}
  end{equation*}
  Part Ⅱ:
  利用finite difference求解2D Wave equation, 实现如下,
  

  # 2D Wave equation之求解 - 有限差分法
  
  import numpy
  from matplotlib import pyplot as plt
  from matplotlib import animation
  
  
  class WaveEq(object):
      
      def __init__(self, nx=300, ny=300, nt=1000, Lx=1, Ly=1, Lt=6):
          self.__nx = nx                        # x轴子区间划分数
          self.__ny = ny                        # y轴子区间划分数
          self.__nt = nt                        # t轴子区间划分数
          self.__Lx = Lx                        # x轴半长
          self.__Ly = Ly                        # y轴半长
          self.__Lt = Lt                        # t轴全长
          self.__D = 0.1
          
          self.__hx = 2 * Lx / nx
          self.__hy = 2 * Ly / ny
          self.__ht = Lt / nt
          
          self.__X, self.__Y = self.__build_gridPoints()
          self.__T = numpy.linspace(0, Lt, nt + 1)
          self.__Ax, self.__Ay = self.__build_2ndOrdMat()
          
          
      def get_solu(self):
          '''
          数值求解
          '''
          UList = list()
          
          U0 = self.__get_initial_U0()
          V0 = self.__get_initial_V0()
          self.__fill_boundary_U(U0)
          UList.append(U0)
          for t in self.__T[:-1]:
              # print(t, numpy.max(U0))
              Uk, Vk = self.__calc_Uk_Vk(t, U0, V0)
              UList.append(Uk)
              U0, V0 = Uk, Vk
          
          return self.__X, self.__Y, self.__T, UList
              
      
      def __calc_Uk_Vk(self, t, U0, V0):
          K1 = self.__calc_F(U0, V0)
          tmpU, tmpV = U0 + self.__ht / 2 * K1[0], V0 + self.__ht / 2 * K1[1]
          self.__fill_boundary_U(tmpU)
          
          K2 = self.__calc_F(tmpU, tmpV)
          tmpU, tmpV = U0 + self.__ht / 2 * K2[0], V0 + self.__ht / 2 * K2[1]
          self.__fill_boundary_U(tmpU)
          
          K3 = self.__calc_F(tmpU, tmpV)
          tmpU, tmpV = U0 + self.__ht * K3[0], V0 + self.__ht * K3[1]
          self.__fill_boundary_U(tmpU)
          
          K4 = self.__calc_F(tmpU, tmpV)
          
          Uk = U0 + (K1[0] + 2 * K2[0] + 2 * K3[0] + K4[0]) / 6 * self.__ht
          Vk = V0 + (K1[1] + 2 * K2[1] + 2 * K3[1] + K4[1]) / 6 * self.__ht
          self.__fill_boundary_U(Uk)
          return Uk, Vk
          
          
      def __calc_F(self, U0, V0):
          F1 = V0
          term0 = numpy.matmul(U0, self.__Ax) / self.__hx ** 2
          term1 = numpy.matmul(self.__Ay, U0) / self.__hy ** 2
          F2 = self.__D * (term0 + term1)
          return F1, F2
      
          
      def __fill_boundary_U(self, U):
          '''
          填充边界条件
          '''
          U[0, :] = 0
          U[-1, :] = 0
          U[:, 0] = 0
          U[:, -1] = 0
          
          
      def __get_initial_V0(self):
          '''
          获取V之初始条件
          '''
          V0 = numpy.zeros(self.__X.shape)
          return V0
          
          
      def __get_initial_U0(self):
          '''
          获取U之初始条件
          '''
          xc = 0
          yc = 0
          U0 = 0.1 * numpy.exp(-((self.__X - xc) ** 2 + (self.__Y - yc) ** 2) / 0.0005)
          return U0
          
          
      def __build_2ndOrdMat(self):
          '''
          构造2阶微分算子的矩阵形式
          '''
          Ax = self.__build_AMat(self.__nx + 1)
          Ay = self.__build_AMat(self.__ny + 1)
          return Ax, Ay
          
          
      def __build_AMat(self, n):
          term0 = numpy.identity(n) * -2
          term1 = numpy.eye(n, n, 1)
          term2 = numpy.eye(n, n, -1)
          AMat = term0 + term1 + term2
          return AMat
          
          
      def __build_gridPoints(self):
          '''
          构造网格节点
          '''
          X = numpy.linspace(-self.__Lx, self.__Lx, self.__nx + 1)
          Y = numpy.linspace(-self.__Ly, self.__Ly, self.__ny + 1)
          X, Y = numpy.meshgrid(X, Y)
          return X, Y
          
          
  class WavePlot(object):
      
      fig = None
      ax1 = None
      line = None
      X, Y, T, Z = None, None, None, None
      
      @classmethod
      def plot_ani(cls, waveObj):
          cls.X, cls.Y, cls.T, cls.Z = waveObj.get_solu()
          
          cls.fig = plt.figure(figsize=(10, 10), dpi=40)
          cls.ax1 = plt.subplot()
          cls.line = cls.ax1.pcolormesh(cls.X, cls.Y, cls.Z[0][:-1, :-1], cmap="jet")
          
          ani = animation.FuncAnimation(cls.fig, cls.update, frames=range(1, len(cls.T), 25), blit=True, interval=5, repeat=True)
          
          ani.save("plot_ani.gif", writer="PillowWriter", fps=200)
          plt.close()
          
      
      @classmethod
      def update(cls, frame):
          cls.line.set_array(cls.Z[frame][:-1, :-1])
          cls.line.set_norm(norm=None)
          return cls.line,
          
          
  if __name__ == "__main__":
      nx = 300
      ny = 300
      nt = 4000
      
      Lx = 0.5
      Ly = 0.5
      Lt = 10
      waveObj = WaveEq(nx, ny, nt, Lx, Ly, Lt)
      # waveObj.get_solu()
      
      WavePlot.plot_ani(waveObj)

• 结果展示:
  注意, 以上为幅值分布情况, 为加强比对, 每一帧之色彩分布均是相对的.
• 使用建议:
  ①. 利用变数变换降阶处理高阶PDE, 转换为低阶PDE系统便利离散化.
• 参考文档:
  吴一东. 数值方法7:偏微分方程5:双曲型微分方程. bilibili, 2020.