0.0.165_对函数增加了中文备注

API_Reference.py

@@ -50,260 +50,372 @@ sigma_zz = guan.sigma_zz()
 
 # Module 2: Fourier transform
 
+# 通过元胞和跃迁项得到一维的哈密顿量（需要输入k值）
 hamiltonian = guan.one_dimensional_fourier_transform(k, unit_cell, hopping)
 
+# 通过元胞和跃迁项得到二维方格子的哈密顿量（需要输入k值）
 hamiltonian = guan.two_dimensional_fourier_transform_for_square_lattice(k1, k2, unit_cell, hopping_1, hopping_2)
 
+# 通过元胞和跃迁项得到三维立方格子的哈密顿量（需要输入k值）
 hamiltonian = guan.three_dimensional_fourier_transform_for_cubic_lattice(k1, k2, k3, unit_cell, hopping_1, hopping_2, hopping_3)
 
+# 通过元胞和跃迁项得到一维的哈密顿量（返回的哈密顿量为携带k的函数）
 hamiltonian_function = guan.one_dimensional_fourier_transform_with_k(unit_cell, hopping)
 
+# 通过元胞和跃迁项得到二维方格子的哈密顿量（返回的哈密顿量为携带k的函数）
 hamiltonian_function = guan.two_dimensional_fourier_transform_for_square_lattice_with_k1_k2(unit_cell, hopping_1, hopping_2)
 
+# 通过元胞和跃迁项得到三维立方格子的哈密顿量（返回的哈密顿量为携带k的函数）
 hamiltonian_function = guan.three_dimensional_fourier_transform_for_cubic_lattice_with_k1_k2_k3(unit_cell, hopping_1, hopping_2, hopping_3)
 
+# 由实空间格矢得到倒空间格矢（一维）
 b1 = guan.calculate_one_dimensional_reciprocal_lattice_vector(a1)
 
+# 由实空间格矢得到倒空间格矢（二维）
 b1, b2 = guan.calculate_two_dimensional_reciprocal_lattice_vectors(a1, a2)
 
+# 由实空间格矢得到倒空间格矢（三维）
 b1, b2, b3 = guan.calculate_three_dimensional_reciprocal_lattice_vectors(a1, a2, a3)
 
+# 由实空间格矢得到倒空间格矢（一维），这里为符号运算
 b1 = guan.calculate_one_dimensional_reciprocal_lattice_vector_with_sympy(a1)
 
+# 由实空间格矢得到倒空间格矢（二维），这里为符号运算
 b1, b2 = guan.calculate_two_dimensional_reciprocal_lattice_vectors_with_sympy(a1, a2)
 
+# 由实空间格矢得到倒空间格矢（三维），这里为符号运算
 b1, b2, b3 = guan.calculate_three_dimensional_reciprocal_lattice_vectors_with_sympy(a1, a2, a3)
 
 
 
 # Module 3: Hamiltonian of finite size systems
 
+# 构建一维的有限尺寸体系哈密顿量（可设置是否为周期边界条件）
 hamiltonian = guan.hamiltonian_of_finite_size_system_along_one_direction(N, on_site=0, hopping=1, period=0)
 
+# 构建二维的方格子有限尺寸体系哈密顿量（可设置是否为周期边界条件）
 hamiltonian = guan.hamiltonian_of_finite_size_system_along_two_directions_for_square_lattice(N1, N2, on_site=0, hopping_1=1, hopping_2=1, period_1=0, period_2=0)
 
+# 构建三维的立方格子有限尺寸体系哈密顿量（可设置是否为周期边界条件）
 hamiltonian = guan.hamiltonian_of_finite_size_system_along_three_directions_for_cubic_lattice(N1, N2, N3, on_site=0, hopping_1=1, hopping_2=1, hopping_3=1, period_1=0, period_2=0, period_3=0)
 
+# 构建有限尺寸的SSH模型哈密顿量
 hamiltonian = guan.hamiltonian_of_finite_size_ssh_model(N, v=0.6, w=1, onsite_1=0, onsite_2=0, period=1)
 
+# 获取Zigzag边的石墨烯条带的元胞间跃迁
 hopping = guan.get_hopping_term_of_graphene_ribbon_along_zigzag_direction(N, eta=0)
 
+# 构建有限尺寸的石墨烯哈密顿量（可设置是否为周期边界条件）
 hamiltonian = guan.hamiltonian_of_finite_size_system_along_two_directions_for_graphene(N1, N2, period_1=0, period_2=0)
 
+# 获取石墨烯有效模型沿着x方向的在位能和跃迁项（其中，动量qy为参数）
 h00, h01 = guan.get_onsite_and_hopping_terms_of_2d_effective_graphene_along_one_direction(qy, t=1, staggered_potential=0, eta=0, valley_index=0)
 
+# 获取BHZ模型的在位能和跃迁项
 H0, H1, H2 = guan.get_onsite_and_hopping_terms_of_bhz_model(A=0.3645/5, B=-0.686/25, C=0, D=-0.512/25, M=-0.01, a=1)
 
+# 获取半个BHZ模型的在位能和跃迁项（自旋向上）
 H0, H1, H2 = guan.get_onsite_and_hopping_terms_of_half_bhz_model_for_spin_up(A=0.3645/5, B=-0.686/25, C=0, D=-0.512/25, M=-0.01, a=1)
 
+# 获取半个BHZ模型的在位能和跃迁项（自旋向下）
 H0, H1, H2 = guan.get_onsite_and_hopping_terms_of_half_bhz_model_for_spin_down(A=0.3645/5, B=-0.686/25, C=0, D=-0.512/25, M=-0.01, a=1)
 
 
 
 # Module 4: Hamiltonian of models in the reciprocal space
 
+# 一维链的哈密顿量
 hamiltonian = guan.hamiltonian_of_simple_chain(k)
 
+# 二维方格子的哈密顿量
 hamiltonian = guan.hamiltonian_of_square_lattice(k1, k2)
 
+# 准一维方格子条带的哈密顿量
 hamiltonian = guan.hamiltonian_of_square_lattice_in_quasi_one_dimension(k, N=10, period=0)
 
+# 三维立方格子的哈密顿量
 hamiltonian = guan.hamiltonian_of_cubic_lattice(k1, k2, k3)
 
+# SSH模型的哈密顿量
 hamiltonian = guan.hamiltonian_of_ssh_model(k, v=0.6, w=1)
 
+# 石墨烯的哈密顿量
 hamiltonian = guan.hamiltonian_of_graphene(k1, k2, staggered_potential=0, t=1, a=1/math.sqrt(3))
 
+# 石墨烯有效模型的哈密顿量
 hamiltonian = guan.effective_hamiltonian_of_graphene(qx, qy, t=1, staggered_potential=0, valley_index=0)
 
+# 石墨烯有效模型离散化后的哈密顿量
 hamiltonian = guan.effective_hamiltonian_of_graphene_after_discretization(qx, qy, t=1, staggered_potential=0, valley_index=0)
 
+# 准一维Zigzag边石墨烯条带的哈密顿量
 hamiltonian = guan.hamiltonian_of_graphene_with_zigzag_in_quasi_one_dimension(k, N=10, M=0, t=1, period=0)
 
+# Haldane模型的哈密顿量
 hamiltonian = guan.hamiltonian_of_haldane_model(k1, k2, M=2/3, t1=1, t2=1/3, phi=math.pi/4, a=1/math.sqrt(3))
 
+# 准一维Haldane模型条带的哈密顿量
 hamiltonian = guan.hamiltonian_of_haldane_model_in_quasi_one_dimension(k, N=10, M=2/3, t1=1, t2=1/3, phi=math.pi/4, period=0)
 
+# 一个量子反常霍尔效应的哈密顿量
 hamiltonian = guan.hamiltonian_of_one_QAH_model(k1, k2, t1=1, t2=1, t3=0.5, m=-1)
 
+# BHZ模型的哈密顿量
 hamiltonian = guan.hamiltonian_of_bhz_model(kx, ky, A=0.3645/5, B=-0.686/25, C=0, D=-0.512/25, M=-0.01)
 
+# 半BHZ模型的哈密顿量（自旋向上）
 hamiltonian = guan.hamiltonian_of_half_bhz_model_for_spin_up(kx, ky, A=0.3645/5, B=-0.686/25, C=0, D=-0.512/25, M=-0.01)
 
+# 半BHZ模型的哈密顿量（自旋向下）
 hamiltonian = guan.hamiltonian_of_half_bhz_model_for_spin_down(kx, ky, A=0.3645/5, B=-0.686/25, C=0, D=-0.512/25, M=-0.01)
 
+# BBH模型的哈密顿量
 hamiltonian = guan.hamiltonian_of_bbh_model(kx, ky, gamma_x=0.5, gamma_y=0.5, lambda_x=1, lambda_y=1)
 
+# Kagome模型的哈密顿量
 hamiltonian = guan.hamiltonian_of_kagome_lattice(kx, ky, t=1)
 
 
 
 # Module 5: band structures and wave functions
 
+# 计算哈密顿量的本征值
 eigenvalue = guan.calculate_eigenvalue(hamiltonian)
 
+# 输入哈密顿量函数（带一组参数），计算一组参数下的本征值，返回本征值向量组
 eigenvalue_array = guan.calculate_eigenvalue_with_one_parameter(x_array, hamiltonian_function, print_show=0)
 
+# 输入哈密顿量函数（带两组参数），计算两组参数下的本征值，返回本征值向量组
 eigenvalue_array = guan.calculate_eigenvalue_with_two_parameters(x_array, y_array, hamiltonian_function, print_show=0, print_show_more=0)
 
+# 计算哈密顿量的本征矢
 eigenvector = guan.calculate_eigenvector(hamiltonian)
 
+# 通过二分查找的方法获取和相邻波函数一样规范的波函数
 vector_target = guan.find_vector_with_the_same_gauge_with_binary_search(vector_target, vector_ref, show_error=1, show_times=0, show_phase=0, n_test=1000, precision=1e-6)
 
+# 通过使得波函数的一个非零分量为实数，得到固定规范的波函数
 vector = guan.find_vector_with_fixed_gauge_by_making_one_component_real(vector, precision=0.005, index=None)
 
+# 通过使得波函数的一个非零分量为实数，得到固定规范的波函数（在一组波函数中选取最大的那个分量）
 vector_array = guan.find_vector_array_with_fixed_gauge_by_making_one_component_real(vector_array, precision=0.005)
 
+# 旋转两个简并的波函数（说明：参数比较多，效率不高）
 vector1, vector2 = guan.rotation_of_degenerate_vectors(vector1, vector2, index1=None, index2=None, precision=0.01, criterion=0.01, show_theta=0)
 
+# 旋转两个简并的波函数向量组（说明：参数比较多，效率不高）
 vector1_array, vector2_array = guan.rotation_of_degenerate_vectors_array(vector1_array, vector2_array, precision=0.01, criterion=0.01, show_theta=0)
 
 
 
 # Module 6: Green functions
 
+# 输入哈密顿量，得到格林函数
 green = guan.green_function(fermi_energy, hamiltonian, broadening, self_energy=0)
 
+# 在Dyson方程中的一个中间格林函数G_{nn}^{n}
 green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n_minus, broadening, self_energy=0)
 
+# 在Dyson方程中的一个中间格林函数G_{in}^{n}
 green_in_n = guan.green_function_in_n(green_in_n_minus, h01, green_nn_n)
 
+# 在Dyson方程中的一个中间格林函数G_{ni}^{n}
 green_ni_n = guan.green_function_ni_n(green_nn_n, h01, green_ni_n_minus)
 
+# 在Dyson方程中的一个中间格林函数G_{ii}^{n}
 green_ii_n = guan.green_function_ii_n(green_ii_n_minus, green_in_n_minus, h01, green_nn_n, green_ni_n_minus)
 
+# 计算转移矩阵（该矩阵可以用来计算表面格林函数）
 transfer = guan.transfer_matrix(fermi_energy, h00, h01)
 
+# 计算电极的表面格林函数
 right_lead_surface, left_lead_surface = guan.surface_green_function_of_lead(fermi_energy, h00, h01)
 
+# 计算电极的自能（基于Dyson方程的小矩阵形式）
 right_self_energy, left_self_energy, gamma_right, gamma_left = guan.self_energy_of_lead(fermi_energy, h00, h01)
 
+# 计算电极的自能（基于中心区整体的大矩阵形式）
 right_self_energy, left_self_energy, gamma_right, gamma_left = guan.self_energy_of_lead_with_h_LC_and_h_CR(fermi_energy, h00, h01, h_LC, h_CR)
 
+# 计算电极的自能（基于中心区整体的大矩阵形式，可适用于多端电导的计算）
 self_energy, gamma = guan.self_energy_of_lead_with_h_lead_to_center(fermi_energy, h00, h01, h_lead_to_center)
 
+# 计算考虑电极自能后的中心区的格林函数
 green, gamma_right, gamma_left = guan.green_function_with_leads(fermi_energy, h00, h01, h_LC, h_CR, center_hamiltonian)
 
+# 计算用于计算局域电流的格林函数G_n
 G_n = guan.electron_correlation_function_green_n_for_local_current(fermi_energy, h00, h01, h_LC, h_CR, center_hamiltonian)
 
 
 
 # Module 7: density of states
 
+# 计算体系的总态密度
 total_dos = guan.total_density_of_states(fermi_energy, hamiltonian, broadening=0.01)
 
+# 对于不同费米能，计算体系的总态密度
 total_dos_array = guan.total_density_of_states_with_fermi_energy_array(fermi_energy_array, hamiltonian, broadening=0.01, print_show=0)
 
+# 计算方格子的局域态密度（其中，哈密顿量的维度为：dim_hamiltonian = N1*N2*internal_degree）
 local_dos = guan.local_density_of_states_for_square_lattice(fermi_energy, hamiltonian, N1, N2, internal_degree=1, broadening=0.01)
 
+# 计算立方格子的局域态密度（其中，哈密顿量的维度为：dim_hamiltonian = N1*N2*N3*internal_degree）
 local_dos = guan.local_density_of_states_for_cubic_lattice(fermi_energy, hamiltonian, N1, N2, N3, internal_degree=1, broadening=0.01)
 
+# 利用Dyson方程，计算方格子的局域态密度（其中，h00的维度为：dim_h00 = N2*internal_degree）
 local_dos = guan.local_density_of_states_for_square_lattice_using_dyson_equation(fermi_energy, h00, h01, N2, N1, internal_degree=1, broadening=0.01)
 
+# 利用Dyson方程，计算立方格子的局域态密度（其中，h00的维度为：dim_h00 = N2*N3*internal_degree）
 local_dos = guan.local_density_of_states_for_cubic_lattice_using_dyson_equation(fermi_energy, h00, h01, N3, N2, N1, internal_degree=1, broadening=0.01)
 
+# 利用Dyson方程，计算方格子条带（考虑了电极自能）的局域态密度（其中，h00的维度为：dim_h00 = N2*internal_degree）
 local_dos = guan.local_density_of_states_for_square_lattice_with_self_energy_using_dyson_equation(fermi_energy, h00, h01, N2, N1, right_self_energy, left_self_energy, internal_degree=1, broadening=0.01)
 
 
 
 # Module 8: quantum transport
 
+# 计算电导
 conductance = guan.calculate_conductance(fermi_energy, h00, h01, length=100)
 
+# 计算不同费米能下的电导
 conductance_array = guan.calculate_conductance_with_fermi_energy_array(fermi_energy_array, h00, h01, length=100, print_show=0)
 
+# 计算在势垒散射下的电导
 conductance = guan.calculate_conductance_with_barrier(fermi_energy, h00, h01, length=100, barrier_length=20, barrier_potential=1)
 
+# 计算在无序散射下的电导
 conductance = guan.calculate_conductance_with_disorder(fermi_energy, h00, h01, disorder_intensity=2.0, disorder_concentration=1.0, length=100, calculation_times=1)
 
+# 计算在无序垂直切片的散射下的电导
 conductance = guan.calculate_conductance_with_slice_disorder(fermi_energy, h00, h01, disorder_intensity=2.0, disorder_concentration=1.0, length=100)
 
+# 计算在无序水平切片的散射下的电导
 conductance = guan.calculate_conductance_with_disorder_inside_unit_cell_which_keeps_translational_symmetry(fermi_energy, h00, h01, disorder_intensity=2.0, disorder_concentration=1.0, length=100)
 
+# 计算在随机空位的散射下的电导
 conductance = guan.calculate_conductance_with_random_vacancy(fermi_energy, h00, h01, vacancy_concentration=0.5, vacancy_potential=1e9, length=100)
 
+# 计算在不同无序散射强度下的电导
 conductance_array = guan.calculate_conductance_with_disorder_intensity_array(fermi_energy, h00, h01, disorder_intensity_array, disorder_concentration=1.0, length=100, calculation_times=1, print_show=0)
 
+# 计算在不同无序浓度下的电导
 conductance_array = guan.calculate_conductance_with_disorder_concentration_array(fermi_energy, h00, h01, disorder_concentration_array, disorder_intensity=2.0, length=100, calculation_times=1, print_show=0)
 
+# 计算在不同无序散射长度下的电导
 conductance_array = guan.calculate_conductance_with_scattering_length_array(fermi_energy, h00, h01, length_array, disorder_intensity=2.0, disorder_concentration=1.0, calculation_times=1, print_show=0)
 
+# 计算得到Gamma矩阵和格林函数，用于计算六端口的量子输运
 gamma_array, green = guan.get_gamma_array_and_green_for_six_terminal_transmission(fermi_energy, h00_for_lead_4, h01_for_lead_4, h00_for_lead_2, h01_for_lead_2, center_hamiltonian, width=10, length=50, internal_degree=1, moving_step_of_leads=10)
 
+# 计算六端口的透射矩阵
 transmission_matrix = guan.calculate_six_terminal_transmission_matrix(fermi_energy, h00_for_lead_4, h01_for_lead_4, h00_for_lead_2, h01_for_lead_2, center_hamiltonian, width=10, length=50, internal_degree=1, moving_step_of_leads=10)
 
+# 计算从电极1出发的透射系数
 transmission_12, transmission_13, transmission_14, transmission_15, transmission_16 = guan.calculate_six_terminal_transmissions_from_lead_1(fermi_energy, h00_for_lead_4, h01_for_lead_4, h00_for_lead_2, h01_for_lead_2, center_hamiltonian, width=10, length=50, internal_degree=1, moving_step_of_leads=10)
 
+# 通过动量k的虚部，判断通道为传播通道还是衰减通道
 if_active = guan.if_active_channel(k_of_channel)
 
+# 获取通道的动量和速度，用于计算散射矩阵
 k_of_channel, velocity_of_channel, eigenvalue, eigenvector = guan.get_k_and_velocity_of_channel(fermi_energy, h00, h01)
 
+# 获取分类后的动量和速度，以及U和F，用于计算散射矩阵
 k_right, k_left, velocity_right, velocity_left, f_right, f_left, u_right, u_left, ind_right_active = guan.get_classified_k_velocity_u_and_f(fermi_energy, h00, h01)
 
+# 计算散射矩阵
 transmission_matrix, reflection_matrix, k_right, k_left, velocity_right, velocity_left, ind_right_active = guan.calculate_scattering_matrix(fermi_energy, h00, h01, length=100)
 
+# 从散射矩阵中，获取散射矩阵的信息
 number_of_active_channels, number_of_evanescent_channels, k_of_right_moving_active_channels, k_of_left_moving_active_channels, velocity_of_right_moving_active_channels, velocity_of_left_moving_active_channels, transmission_matrix_for_active_channels, reflection_matrix_for_active_channels, total_transmission_of_channels, total_conductance, total_reflection_of_channels, sum_of_transmission_and_reflection_of_channels = guan.information_of_scattering_matrix(transmission_matrix, reflection_matrix, k_right, k_left, velocity_right, velocity_left, ind_right_active)
 
+# 已知h00和h01，计算散射矩阵并获得散射矩阵的信息
 number_of_active_channels, number_of_evanescent_channels, k_of_right_moving_active_channels, k_of_left_moving_active_channels, velocity_of_right_moving_active_channels, velocity_of_left_moving_active_channels, transmission_matrix_for_active_channels, reflection_matrix_for_active_channels, total_transmission_of_channels, total_conductance, total_reflection_of_channels, sum_of_transmission_and_reflection_of_channels = guan.calculate_scattering_matrix_and_get_information(fermi_energy, h00, h01, length=100)
 
+# 从散射矩阵中，打印出散射矩阵的信息
 guan.print_or_write_scattering_matrix_with_information_of_scattering_matrix(number_of_active_channels, number_of_evanescent_channels, k_of_right_moving_active_channels, k_of_left_moving_active_channels, velocity_of_right_moving_active_channels, velocity_of_left_moving_active_channels, transmission_matrix_for_active_channels, reflection_matrix_for_active_channels, total_transmission_of_channels, total_conductance, total_reflection_of_channels, sum_of_transmission_and_reflection_of_channels, print_show=1, write_file=0, filename='a', file_format='.txt')
 
+# 已知h00和h01，计算散射矩阵并打印出散射矩阵的信息
 guan.print_or_write_scattering_matrix(fermi_energy, h00, h01, length=100, print_show=1, write_file=0, filename='a', file_format='.txt')
 
+# 在无序下，计算散射矩阵
 transmission_matrix, reflection_matrix, k_right, k_left, velocity_right, velocity_left, ind_right_active = guan.calculate_scattering_matrix_with_disorder(fermi_energy, h00, h01, length=100, disorder_intensity=2.0, disorder_concentration=1.0)
 
+# 在无序下，计算散射矩阵，并获取散射矩阵多次计算的平均信息
 transmission_matrix_for_active_channels_averaged, reflection_matrix_for_active_channels_averaged = guan.calculate_scattering_matrix_with_disorder_and_get_averaged_information(fermi_energy, h00, h01, length=100, disorder_intensity=2.0, disorder_concentration=1.0, calculation_times=1)
 
 
 
 # Module 9: topological invariant
 
+# 通过高效法计算方格子的陈数
 chern_number = guan.calculate_chern_number_for_square_lattice_with_efficient_method(hamiltonian_function, precision=100, print_show=0)
 
+# 通过高效法计算方格子的陈数（可计算简并的情况）
 chern_number = guan.calculate_chern_number_for_square_lattice_with_efficient_method_for_degenerate_case(hamiltonian_function, index_of_bands=[0, 1], precision=100, print_show=0)
 
+# 通过Wilson loop方法计算方格子的陈数
 chern_number = guan.calculate_chern_number_for_square_lattice_with_wilson_loop(hamiltonian_function, precision_of_plaquettes=20, precision_of_wilson_loop=5, print_show=0)
 
+# 通过Wilson loop方法计算方格子的陈数（可计算简并的情况）
 chern_number = guan.calculate_chern_number_for_square_lattice_with_wilson_loop_for_degenerate_case(hamiltonian_function, index_of_bands=[0, 1], precision_of_plaquettes=20, precision_of_wilson_loop=5, print_show=0)
 
+# 通过高效法计算贝利曲率
 k_array, berry_curvature_array = guan.calculate_berry_curvature_with_efficient_method(hamiltonian_function, k_min=-math.pi, k_max=math.pi, precision=100, print_show=0)
 
+# 通过高效法计算贝利曲率（可计算简并的情况）
 k_array, berry_curvature_array = guan.calculate_berry_curvature_with_efficient_method_for_degenerate_case(hamiltonian_function, index_of_bands=[0, 1], k_min=-math.pi, k_max=math.pi, precision=100, print_show=0)
 
+# 通过Wilson loop方法计算贝里曲率
 k_array, berry_curvature_array = guan.calculate_berry_curvature_with_wilson_loop(hamiltonian_function, k_min=-math.pi, k_max=math.pi, precision_of_plaquettes=20, precision_of_wilson_loop=5, print_show=0)
 
+# 通过Wilson loop方法计算贝里曲率（可计算简并的情况）
 k_array, berry_curvature_array = guan.calculate_berry_curvature_with_wilson_loop_for_degenerate_case(hamiltonian_function, index_of_bands=[0, 1], k_min=-math.pi, k_max=math.pi, precision_of_plaquettes=20, precision_of_wilson_loop=5, print_show=0)
 
+# 计算蜂窝格子的陈数（高效法）
 chern_number = guan.calculate_chern_number_for_honeycomb_lattice(hamiltonian_function, a=1, precision=300, print_show=0)
 
+# 计算Wilson loop
 wilson_loop_array = guan.calculate_wilson_loop(hamiltonian_function, k_min=-math.pi, k_max=math.pi, precision=100, print_show=0)
 
 
 
 # Module 10: read and write
 
+# 读取文件中的一维数据（每一行一组x和y）
 x_array, y_array = guan.read_one_dimensional_data(filename='a', file_format='.txt')
 
+# 读取文件中的一维数据（每一行一组x和y）（支持复数形式）
 x_array, y_array = guan.read_one_dimensional_complex_data(filename='a', file_format='txt')
 
+# 读取文件中的二维数据（第一行和列分别为横纵坐标）
 x_array, y_array, matrix = guan.read_two_dimensional_data(filename='a', file_format='.txt')
 
+# 读取文件中的二维数据（第一行和列分别为横纵坐标）（支持复数形式）
 x_array, y_array, matrix = guan.read_two_dimensional_complex_data(filename='a', file_format='.txt')
 
+# 打开文件用于新增内容
 f = guan.open_file(filename='a', file_format='.txt')
 
+# 在文件中写入一维数据（每一行一组x和y）
 guan.write_one_dimensional_data(x_array, y_array, filename='a', file_format='.txt')
 
+# 在文件中写入一维数据（每一行一组x和y）（需要输入文件）
 guan.write_one_dimensional_data_without_opening_file(x_array, y_array, f)
 
+# 在文件中写入二维数据（第一行和列分别为横纵坐标）
 guan.write_two_dimensional_data(x_array, y_array, matrix, filename='a', file_format='.txt')
 
+# 在文件中写入二维数据（第一行和列分别为横纵坐标）（需要输入文件）
 guan.write_two_dimensional_data_without_opening_file(x_array, y_array, matrix, f)
 
+# 在文件中写入二维数据（不包括x和y）
 guan.write_two_dimensional_data_without_xy_array(matrix, filename='a', file_format='.txt')
 
+# 在文件中写入二维数据（不包括x和y）（需要输入文件）
 guan.write_two_dimensional_data_without_xy_array_and_without_opening_file(matrix, f)
 
+# 以显示编号的样式，打印数组
 guan.print_array_with_index(array, show_index=1, index_type=0)
 
 
@@ -311,90 +423,128 @@ guan.print_array_with_index(array, show_index=1, index_type=0)
 
 # Module 11: plot figures
 
+# 导入plt, fig, ax
 plt, fig, ax = guan.import_plt_and_start_fig_ax(adjust_bottom=0.2, adjust_left=0.2, labelsize=20)
 
+# 基于plt, fig, ax开始画图
 guan.plot_without_starting_fig(plt, fig, ax, x_array, y_array, xlabel='x', ylabel='y', title='', fontsize=20, style='', y_min=None, y_max=None, linewidth=None, markersize=None, color=None)
 
+# 画图
 guan.plot(x_array, y_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style='', y_min=None, y_max=None, linewidth=None, markersize=None, adjust_bottom=0.2, adjust_left=0.2)
 
+# 一组横坐标数据，两组纵坐标数据画图
 guan.plot_two_array(x_array, y1_array, y2_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, markersize_1=None, markersize_2=None, adjust_bottom=0.2, adjust_left=0.2)
 
+# 两组横坐标数据，两组纵坐标数据画图
 guan.plot_two_array_with_two_horizontal_array(x1_array, x2_array, y1_array, y2_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, markersize_1=None, markersize_2=None, adjust_bottom=0.2, adjust_left=0.2)
 
+# 一组横坐标数据，三组纵坐标数据画图
 guan.plot_three_array(x_array, y1_array, y2_array, y3_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', style_3='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, linewidth_3=None,markersize_1=None, markersize_2=None, markersize_3=None, adjust_bottom=0.2, adjust_left=0.2)
 
+# 三组横坐标数据，三组纵坐标数据画图
 guan.plot_three_array_with_three_horizontal_array(x1_array, x2_array, x3_array, y1_array, y2_array, y3_array, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=20, show=1, save=0, filename='a', file_format='.jpg', dpi=300, style_1='', style_2='', style_3='', y_min=None, y_max=None, linewidth_1=None, linewidth_2=None, linewidth_3=None, markersize_1=None, markersize_2=None, markersize_3=None, adjust_bottom=0.2, adjust_left=0.2)
 
+# 画三维图
 guan.plot_3d_surface(x_array, y_array, matrix, xlabel='x', ylabel='y', zlabel='z', title='', fontsize=20, labelsize=15, show=1, save=0, filename='a', file_format='.jpg', dpi=300, z_min=None, z_max=None, rcount=100, ccount=100)
 
+# 画Contour图
 guan.plot_contour(x_array, y_array, matrix, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=15, cmap='jet', levels=None, show=1, save=0, filename='a', file_format='.jpg', dpi=300)
 
+# 画棋盘图/伪彩色图
 guan.plot_pcolor(x_array, y_array, matrix, xlabel='x', ylabel='y', title='', fontsize=20, labelsize=15, cmap='jet', levels=None, show=1, save=0, filename='a', file_format='.jpg', dpi=300)
 
+# 通过坐标画点和线
 guan.draw_dots_and_lines(coordinate_array, draw_dots=1, draw_lines=1, max_distance=1.1, line_style='-k', linewidth=1, dot_style='ro', markersize=3, show=1, save=0, filename='a', file_format='.eps', dpi=300)
 
+# 合并两个图片
 guan.combine_two_images(image_path_array, figsize=(16,8), show=0, save=1, filename='a', file_format='.jpg', dpi=300)
 
+# 合并三个图片
 guan.combine_three_images(image_path_array, figsize=(16,5), show=0, save=1, filename='a', file_format='.jpg', dpi=300)
 
+# 合并四个图片
 guan.combine_four_images(image_path_array, figsize=(16,16), show=0, save=1, filename='a', file_format='.jpg', dpi=300)
 
+# 制作GIF动画
 guan.make_gif(image_path_array, filename='a', duration=0.1)
 
 
 
 # Module 12: data processing
 
+# 并行计算前的预处理，把参数分成多份
 parameter_array = guan.preprocess_for_parallel_calculations(parameter_array_all, cpus=1, task_index=0)
 
+# 在一组数据中找到数值相近的数
 new_array = guan.find_close_values_in_one_array(array, precision=1e-2)
 
+# 寻找能带的简并点
 degenerate_k_array, degenerate_eigenvalue_array = guan.find_degenerate_points(k_array, eigenvalue_array, precision=1e-2)
 
+# 对于某个目录中的txt文件，批量读取和画图
 guan.batch_reading_and_plotting(directory, xlabel='x', ylabel='y')
 
+# 将RGB转成HEX
 hex = guan.rgb_to_hex(rgb, pound=1)
 
+# 将HEX转成RGB
 rgb = guan.hex_to_rgb(hex)
 
 
 
 # # Module 13: file processing
 
+# 将文件目录结构写入Markdown文件
 guan.write_file_list_in_markdown(directory='./', filename='a', reverse_positive_or_negative=1, starting_from_h1=None, banned_file_format=[], hide_file_format=None, divided_line=None, show_second_number=None, show_third_number=None)
 
+# 查找文件名相同的文件
 repeated_file = guan.find_repeated_file_with_same_filename(directory='./', ignored_directory_with_words=[], ignored_file_with_words=[], num=1000):
 
+# 统计各个子文件夹中的文件数量
 guan.count_file_in_sub_directory(directory='./', smaller_than_num=None)
 
+# 产生必要的文件，例如readme.md
 guan.creat_necessary_file(directory, filename='readme', file_format='.md', content='', overwrite=None, ignored_directory_with_words=[])
 
+# 删除特定文件名的文件
 guan.delete_file_with_specific_name(directory, filename='readme', file_format='.md')
 
+# 所有文件移到根目录（慎用）
 guan.move_all_files_to_root_directory(directory)
 
+# 改变当前的目录位置
 guan.change_directory_by_replacement(current_key_word='code', new_key_word='data')
 
 
 
 # Module 14: others
 
+# 通过Sci-Hub网站下载文献
 guan.download_with_scihub(address=None, num=1)
 
+# 获取PDF文献中的链接。例如: link_starting_form='https://doi.org'
 links = guan.get_links_from_pdf(pdf_path, link_starting_form='')
 
+# 将PDF文件转成文本
 content = guan.pdf_to_text(pdf_path)
 
+# 将文本转成音频
 guan.str_to_audio(str='hello world', filename='str', rate=125, voice=1, read=1, save=0, compress=0, bitrate='16k', print_text=0)
 
+# 将txt文件转成音频
 guan.txt_to_audio(txt_path, rate=125, voice=1, read=1, save=0, compress=0, bitrate='16k', print_text=0)
 
+# 将PDF文件转成音频
 guan.pdf_to_audio(pdf_path, rate=125, voice=1, read=1, save=0, compress=0, bitrate='16k', print_text=0)
 
+# 将wav音频文件压缩成MP3音频文件
 guan.compress_wav_to_mp3(wav_path, output_filename='a.mp3', bitrate='16k')
 
+# 播放学术单词
 guan.play_academic_words(reverse=0, random_on=0, bre_or_ame='ame', show_translation=1, show_link=1, translation_time=2, rest_time=1)
 
+# 播放挑选过后的学术单词
 guan.play_selected_academic_words(reverse=0, random_on=0, bre_or_ame='ame', show_link=1, rest_time=3)
 
+# 播放元素周期表上的单词
 guan.play_element_words(random_on=0, show_translation=1, show_link=1, translation_time=2, rest_time=1)

PyPI/setup.cfg

@@ -1,7 +1,7 @@
 [metadata]
 # replace with your username:
 name = guan
-version = 0.0.163
+version = 0.0.165
 author = guanjihuan
 author_email = guanjihuan@163.com
 description = An open source python package

PyPI/src/guan.egg-info/PKG-INFO

@@ -1,6 +1,6 @@
 Metadata-Version: 2.1
 Name: guan
-Version: 0.0.163
+Version: 0.0.165
 Summary: An open source python package
 Home-page: https://py.guanjihuan.com
 Author: guanjihuan