Filter löschen
Filter löschen

Matrix Issue Line 33, 35, 37

1 Ansicht (letzte 30 Tage)
Briana Canet
Briana Canet am 22 Mär. 2022
Kommentiert: Briana Canet am 22 Mär. 2022
Hi. Line 33, 35, and 37 (v_a2, s1_a2, s2_a2) are supposed to create a matrix/array (not sure what the right term is) like Line 27 and Line 29 does.
Note that v_a2 uses K_a1 and Mu_a1 which are both matrix/array and then v_a2 is used for s1_a2 and s2_a2.
I am not sure how to accomplish this. Please help!
% Approach 1
E_m = 70000; % Elastic modulus of matrix, MPa
v_m = .33; % Poisson ratio of matrix
E_i = 250000; % Elastic modulus of inclusion, MPa
v_i = .2; % Poisson ratio of inclusion
% Fiber volume fraction
f_i = 0:0.01:1;
% 0 is 0% fiber and 1 is 100% fiber content
% points to be plotted
K_m = (E_m)/(3*(1-2*v_m));
K_i = (E_i)/(3*(1-2*v_i));
Mu_m = (E_m)/(2*(1+v_m));
Mu_i = (E_i)/(2*(1+v_i));
% Iteration 1
s1_a1 = (1+v_m)/(3*(1-v_m));
s2_a1 = (2*(4-5*v_m))/(15*(1-v_m));
K_a1 = K_m*((1+f_i*(K_m/(K_m-K_i)-s1_a1)^-1)).^-1;
Mu_a1 = Mu_m*((1+f_i*(Mu_m/(Mu_m-Mu_i)-s2_a1)^-1)).^-1;
% Iteration 2
v_a2 = (3*K_a1-2*Mu_a1)/(2*(3*K_a1+Mu_a1));
s1_a2 = (1+v_a2)/(3*(1-v_a2));
s2_a2 = (2*(4-5*v_a2))/(15*(1-v_a2));
K_a2 = K_m*(1+(f_i*((K_i/K_m)-1).*(1+((K_i./K_a1)-1)*s1_a2).^-1));
Mu_a2 = Mu_m*(1+(f_i*((Mu_i/Mu_m)-1).*(1+((Mu_i./Mu_a1)-1)*s2_a2).^-1));
% Plotting
figure(1)
plot(f_i,K_a1, 'Color', 'red', 'LineWidth', 2);
hold on;
plot(f_i,K_a2, 'Color', 'black', 'LineWidth', 2);
hold off;
%plot(f_i,K_a3, 'Color', 'blue', 'LineWidth', 2);
%hold on;
%plot(f_i,K_a4, 'Color', 'cyan', 'LineWidth', 2);
%hold on;
%plot(f_i,K_a5, 'Color', 'yellow', 'LineWidth', 2);
%hold on;
%plot(f_i,K_Reuss, 'Color', 'magenta', 'LineWidth', 2);
%hold on;
%plot(f_i,K_Voigt, 'Color', 'green', 'LineWidth', 2);
%hold off;
grid off;
legend('K_a_1', 'K_a_2','K_a_3', 'K_a_4', 'K_a_5', 'K_R_e_u_s_s',...
'K_V_o_i_g_t')
legend('Location','northwest','FontSize',12)
title('Approach 1: Bulk Modulus vs. Inclusion Volume Fraction')
xlabel('Inclusion Volume Fraction, f_i')
ylabel('Bulk Modulus, K [MPa]')

Melden Sie sich an, um diese Frage zu beantworten.

Akzeptierte Antwort

Voss
Voss am 22 Mär. 2022
Ran in:
Use element-wise division (./) in the calculations on those lines, and use element-wise multiplication (.*) in the subsequent calculations of K_a2 and Mu_a2, since they are using vectors now.
% Approach 1
E_m = 70000; % Elastic modulus of matrix, MPa
v_m = .33; % Poisson ratio of matrix
E_i = 250000; % Elastic modulus of inclusion, MPa
v_i = .2; % Poisson ratio of inclusion
% Fiber volume fraction
f_i = 0:0.01:1;
% 0 is 0% fiber and 1 is 100% fiber content
% points to be plotted
K_m = (E_m)/(3*(1-2*v_m));
K_i = (E_i)/(3*(1-2*v_i));
Mu_m = (E_m)/(2*(1+v_m));
Mu_i = (E_i)/(2*(1+v_i));
% Iteration 1
s1_a1 = (1+v_m)/(3*(1-v_m));
s2_a1 = (2*(4-5*v_m))/(15*(1-v_m));
K_a1 = K_m*((1+f_i*(K_m/(K_m-K_i)-s1_a1)^-1)).^-1;
Mu_a1 = Mu_m*((1+f_i*(Mu_m/(Mu_m-Mu_i)-s2_a1)^-1)).^-1;
% Iteration 2
% v_a2 = (3*K_a1-2*Mu_a1)/(2*(3*K_a1+Mu_a1));
% s1_a2 = (1+v_a2)/(3*(1-v_a2));
% s2_a2 = (2*(4-5*v_a2))/(15*(1-v_a2));
v_a2 = (3*K_a1-2*Mu_a1)./(2*(3*K_a1+Mu_a1))
v_a2 = 1×101
0.3300 0.3290 0.3281 0.3270 0.3260 0.3250 0.3239 0.3228 0.3216 0.3204 0.3192 0.3180 0.3167 0.3154 0.3141 0.3127 0.3113 0.3098 0.3083 0.3068 0.3052 0.3035 0.3018 0.3001 0.2983 0.2964 0.2945 0.2925 0.2904 0.2883
s1_a2 = (1+v_a2)./(3*(1-v_a2))
s1_a2 = 1×101
0.6617 0.6603 0.6588 0.6573 0.6558 0.6542 0.6527 0.6510 0.6494 0.6477 0.6460 0.6442 0.6424 0.6405 0.6386 0.6366 0.6347 0.6326 0.6305 0.6283 0.6261 0.6239 0.6215 0.6192 0.6167 0.6142 0.6116 0.6089 0.6062 0.6034
s2_a2 = (2*(4-5*v_a2))./(15*(1-v_a2))
s2_a2 = 1×101
0.4677 0.4679 0.4682 0.4685 0.4688 0.4692 0.4695 0.4698 0.4701 0.4705 0.4708 0.4712 0.4715 0.4719 0.4723 0.4727 0.4731 0.4735 0.4739 0.4743 0.4748 0.4752 0.4757 0.4762 0.4767 0.4772 0.4777 0.4782 0.4788 0.4793
% K_a2 = K_m*(1+(f_i*((K_i/K_m)-1).*(1+((K_i./K_a1)-1)*s1_a2).^-1));
% Mu_a2 = Mu_m*(1+(f_i*((Mu_i/Mu_m)-1).*(1+((Mu_i./Mu_a1)-1)*s2_a2).^-1));
K_a2 = K_m*(1+(f_i.*((K_i/K_m)-1).*(1+((K_i./K_a1)-1).*s1_a2).^-1))
K_a2 = 1×101
1.0e+05 * 0.6863 0.6905 0.6947 0.6991 0.7034 0.7078 0.7123 0.7168 0.7214 0.7260 0.7307 0.7354 0.7402 0.7451 0.7500 0.7550 0.7600 0.7651 0.7703 0.7755 0.7808 0.7862 0.7916 0.7971 0.8027 0.8083 0.8140 0.8198 0.8257 0.8317
Mu_a2 = Mu_m*(1+(f_i.*((Mu_i/Mu_m)-1).*(1+((Mu_i./Mu_a1)-1).*s2_a2).^-1))
Mu_a2 = 1×101
1.0e+07 * 0.0026 0.0027 0.0027 0.0027 0.0028 0.0028 0.0028 0.0029 0.0029 0.0030 0.0030 0.0030 0.0031 0.0031 0.0032 0.0032 0.0032 0.0033 0.0033 0.0034 0.0034 0.0035 0.0035 0.0036 0.0036 0.0037 0.0038 0.0038 0.0039 0.0039
% Plotting
figure(1)
plot(f_i,K_a1, 'Color', 'red', 'LineWidth', 2);
hold on;
plot(f_i,K_a2, 'Color', 'black', 'LineWidth', 2);
hold off;
%plot(f_i,K_a3, 'Color', 'blue', 'LineWidth', 2);
%hold on;
%plot(f_i,K_a4, 'Color', 'cyan', 'LineWidth', 2);
%hold on;
%plot(f_i,K_a5, 'Color', 'yellow', 'LineWidth', 2);
%hold on;
%plot(f_i,K_Reuss, 'Color', 'magenta', 'LineWidth', 2);
%hold on;
%plot(f_i,K_Voigt, 'Color', 'green', 'LineWidth', 2);
%hold off;
grid off;
legend('K_a_1', 'K_a_2','K_a_3', 'K_a_4', 'K_a_5', 'K_R_e_u_s_s',...
'K_V_o_i_g_t')
Warning: Ignoring extra legend entries.
legend('Location','northwest','FontSize',12)
title('Approach 1: Bulk Modulus vs. Inclusion Volume Fraction')
xlabel('Inclusion Volume Fraction, f_i')
ylabel('Bulk Modulus, K [MPa]')

Weitere Antworten (2)

Mathieu NOE
Mathieu NOE am 22 Mär. 2022
hello
I put the dots so that the multiplication and division are performed element by element between arrays , but the result looks strange to me (a modulus that drop until it gets negative seems wrong)
Dot product - MATLAB dot - MathWorks France
also , but this is my preference , instead of writing A .* (B.^-1) I prefer the simpler A./B
It's late now for me so I'll have a look again tomorrow
i'm surprised for example so see this equation that mix a modulus and poisson ratio as physically equivalent terms ... like adding tomatoes with oranges ??
v_a2 = (3*K_a1-2*Mu_a1)./(2*(3*K_a1+Mu_a1));
code
clc
clearvars
% Approach 1
E_m = 70000; % Elastic modulus of matrix, MPa
v_m = .33; % Poisson ratio of matrix
E_i = 250000; % Elastic modulus of inclusion, MPa
v_i = .2; % Poisson ratio of inclusion
% Fiber volume fraction
f_i = 0:0.01:1;
% 0 is 0% fiber and 1 is 100% fiber content
% points to be plotted
K_m = (E_m)/(3*(1-2*v_m));
K_i = (E_i)/(3*(1-2*v_i));
Mu_m = (E_m)/(2*(1+v_m));
Mu_i = (E_i)/(2*(1+v_i));
% Iteration 1
s1_a1 = (1+v_m)/(3*(1-v_m));
s2_a1 = (2*(4-5*v_m))/(15*(1-v_m));
% K_a1 = K_m*((1+f_i*(K_m/(K_m-K_i)-s1_a1)^-1)).^-1;
K_a1 = K_m./((1+f_i*(K_m/(K_m-K_i)-s1_a1)^-1));
% Mu_a1 = Mu_m*((1+f_i*(Mu_m/(Mu_m-Mu_i)-s2_a1)^-1)).^-1;
Mu_a1 = Mu_m./((1+f_i*(Mu_m/(Mu_m-Mu_i)-s2_a1)^-1));
% Iteration 2
v_a2 = (3*K_a1-2*Mu_a1)./(2*(3*K_a1+Mu_a1));
s1_a2 = (1+v_a2)./(3*(1-v_a2));
s2_a2 = (2*(4-5*v_a2))./(15*(1-v_a2));
% K_a2 = K_m*(1+(f_i*((K_i/K_m)-1).*(1+((K_i./K_a1)-1).*s1_a2).^-1));
K_a2 = K_m*(1+(f_i*((K_i/K_m)-1)./(1+((K_i./K_a1)-1).*s1_a2)));
% Mu_a2 = Mu_m*(1+(f_i*((Mu_i/Mu_m)-1).*(1+((Mu_i./Mu_a1)-1).*s2_a2).^-1));
Mu_a2 = Mu_m*(1+(f_i*((Mu_i/Mu_m)-1)./(1+((Mu_i./Mu_a1)-1).*s2_a2)));
% Plotting
figure(1)
plot(f_i,K_a1, 'Color', 'red', 'LineWidth', 2);
hold on;
plot(f_i,K_a2, 'Color', 'black', 'LineWidth', 2);
% plot(f_i,K_a3, 'Color', 'blue', 'LineWidth', 2);
% plot(f_i,K_a4, 'Color', 'cyan', 'LineWidth', 2);
% plot(f_i,K_a5, 'Color', 'yellow', 'LineWidth', 2);
% plot(f_i,K_Reuss, 'Color', 'magenta', 'LineWidth', 2);
% plot(f_i,K_Voigt, 'Color', 'green', 'LineWidth', 2);
hold off;
grid off;
legend('K_a_1', 'K_a_2','K_a_3', 'K_a_4', 'K_a_5', 'K_R_e_u_s_s',...
'K_V_o_i_g_t')
legend('Location','northwest','FontSize',12)
title('Approach 1: Bulk Modulus vs. Inclusion Volume Fraction')
xlabel('Inclusion Volume Fraction, f_i')
ylabel('Bulk Modulus, K [MPa]')
  2 Kommentare
Briana Canet
Briana Canet am 22 Mär. 2022
Yes these results look strange to me as well. Please look into it! Appreciate it.
Briana Canet
Briana Canet am 22 Mär. 2022
The equations were provided by my instructor.

Melden Sie sich an, um zu kommentieren.

Briana Canet
Briana Canet am 22 Mär. 2022
K_a2 = K_m*(1+(f_i.*((K_i/K_m)-1).*(1+((K_i./K_a1)-1).*s1_a2).^-1))
Why is there a dot after :((K_i/K_m)-1)
K_i and K_m are constants non-arrays.
Why is there a dot immediately after K_i
Also constant
  1 Kommentar
Briana Canet
Briana Canet am 22 Mär. 2022
Hi! There was something wrong my logic! I fixed it but thank you the dot operator tip helped.

Melden Sie sich an, um zu kommentieren.

Kategorien

Mehr zu Scripts finden Sie in Help Center und File Exchange

Tags

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by