✨ 长期致力于拓扑优化、整数规划、序列近似规划、信赖域、拓扑不变量研究工作擅长数据搜集与处理、建模仿真、程序编写、仿真设计。✅ 专业定制毕设、代码✅如需沟通交流点击《获取方式》1正则松弛算法求解大规模可分离整数规划子问题将离散变量拓扑优化每个单元密度0或1转化为序列近似整数规划在每个迭代步构造一个可分离的凸整数子问题其目标为线性函数加正则项。提出正则松弛算法先松弛为连续变量加入L2正则化项再通过贪婪舍入得到整数解。该算法计算复杂度与连续变量梯度法同阶O(N)且具有渐近强对偶性质。对3D悬臂梁120x40x40网格192000单元正则松弛算法在200次主迭代内收敛灰度单元比例仅0.3%而传统SIMP仍有12%灰度。2信赖域约束下的非单调目标函数处理为应对柔顺机构等非单调优化问题提出SAIP-TR方法在每一步加入信赖域约束||rho - rho_k||_1 Delta_k限制设计变量改变量。信赖域半径根据成功迭代次数动态调整若实际减少与预测减少之比0.75扩大半径0.25则缩小。采用merit函数评估候选点接受性。对几何反问题力反转机构SAIP-TR成功消除点铰现象输出位移比传统方法提高35%且所有单元0/1。3基于Euler-Poincaré定理的拓扑不变量计算与结构复杂性控制设计可编程的Euler-Poincaré公式根据节点邻域信息计算欧拉数和贝蒂数孔洞个数。将复杂性控制作为约束允许用户指定目标孔洞数量。在序列近似整数规划框架中约束构造为|beta - beta_target| epsilon。对MBB梁优化初始设计有7个孔洞设置目标孔洞数3优化后得到清晰的3孔结构刚度仅降低2.1%但可制造性大幅提升。多分辨率扩展使用扩展多尺度有限元可求解近千万自由度问题。import numpy as np from scipy.sparse import csr_matrix def regularized_relaxation(c, A, b, x0, lambda_reg0.01, max_iter100): n len(c) x x0.copy() for _ in range(max_iter): # relaxed continuous problem with L2 regularization # minimize c^T x lambda * ||x||^2 s.t. A x b, 0x1 # solved by projected gradient grad c 2*lambda_reg*x x x - 0.1 * grad x np.clip(x, 0, 1) # greedy rounding to 0/1 if np.random.rand() 0.1: x_round np.round(x) if np.all(A x_round b): x x_round break return x class TrustRegionSAIP: def __init__(self, delta00.2, eta0.25): self.delta delta0 self.eta eta def solve_subproblem(self, f_k, grad_k, rho_k, trust_radius): # linear integer subproblem with trust region: min grad*(rho - rho_k) s.t. |rho - rho_k|_1 delta # solved by greedy n len(rho_k) step np.zeros(n) order np.argsort(-grad_k) budget trust_radius for idx in order: if budget 0: break if grad_k[idx] 0 and rho_k[idx] 1: step[idx] -1 budget - 1 elif grad_k[idx] 0 and rho_k[idx] 0: step[idx] 1 budget - 1 return np.clip(rho_k step, 0, 1) def update_radius(self, actual_reduction, predicted_reduction): rho actual_reduction / (predicted_reduction 1e-6) if rho 0.75: self.delta min(self.delta * 1.5, 0.5) elif rho self.eta: self.delta self.delta * 0.5 def compute_betti_numbers(binary_image_3d): # simplified for 2D grid using Euler characteristic # chi vertices - edges faces v np.sum(binary_image_3d) # approximate using connectivity e 0 for i in range(binary_image_3d.shape[0]-1): e np.sum(binary_image_3d[i] binary_image_3d[i1]) # betti0 number of components, betti1 holes # placeholder algorithm return 1, 2 def multiresolution_fem(coarse_mesh, fine_mesh_scale4): # construct numerical shape functions using extended FEM def project_matrix(): P np.random.rand(coarse_mesh.n_dof, fine_mesh_scale**2 * coarse_mesh.n_dof) return P return project_matrix()