error in ode45. I have declared the vector to be 3x1 but it only reads it as 2x1.

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Ayush Ranjan on 21 Apr 2023

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https://nl.mathworks.com/matlabcentral/answers/1950808-error-in-ode45-i-have-declared-the-vector-to-be-3x1-but-it-only-reads-it-as-2x1

Edited: Stephen23 on 21 Apr 2023

Accepted Answer: Dyuman Joshi

for kpm=27:1:30

tspan = 0:30;

yo=[0.01 0.05 0.179];

[t,y]=ode45(@newwaykumar2004,tspan,yo);

end

function dydt=newwaykumar2004(t,y)

kp=3;

global kpm;

kmp = 25;

klm = 15;

kl = 1;

theta=1;

w=0.5;

function qz=f(m)

qz=1+tanh((m-theta)/w);

end

dpdt=kp*y(1)*(1-y(1))-kpm*y(1)*y(2);

dmdt=(kmp*y(1)+y(3))*y(2)*(1-y(2))-y(2);

dIdt=klm*f(y(2))-kl*y(3);

dydt=[dpdt;dmdt;dIdt];

end

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Answer 1

Dyuman Joshi on 21 Apr 2023

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https://nl.mathworks.com/matlabcentral/answers/1950808-error-in-ode45-i-have-declared-the-vector-to-be-3x1-but-it-only-reads-it-as-2x1#answer_1220188

Edited: Dyuman Joshi on 21 Apr 2023

Open in MATLAB Online

You get the error because dpdt is empty, and thus dydt is 2x1.

Instead of defining kpm as global, it is better to define it as an input to the ode function. MathWorks recommends to avoid the use of global as well

Note that in your code t and y are being overwritten in each iteration of the loop. I have modified t and y to store the result of each iteration

%Defining constant value variables outside the loop
kpm = 27:1:30;
tspan = 0:30;
yo=[0.01 0.05 0.179];
n = numel(kpm);
nt = numel(tspan);
nyo = numel(yo);
%Pre-allocation
t = zeros(nt,n);
y = zeros(nt,nyo,n);
%Ode Loop
for k = 1:n
[t(:,k),y(:,:,k)]=ode45(@(t,y) newwaykumar2004(t,y,kpm(k)), tspan, yo);
end
%t(:,k) represents a solution corresponding to kpm(k)
t
t = 31×4
   0     0     0
   1     1     1
   2     2     2
   3     3     3
   4     4     4
   5     5     5
   6     6     6
   7     7     7
   8     8     8
   9     9     9
%y(:,:,k) represents a solution corresponding to kpm(k)
y
y = 
y(:,:,1) =

0100    0.0500    0.1790
0561    0.0489    0.4715
0591    0.1776    0.7081
0044    0.2052    1.0206
0005    0.1854    1.0996
0001    0.1686    1.0806
0000    0.1508    1.0303
0000    0.1309    0.9670
0000    0.1094    0.8979
0000    0.0876    0.8284
0000    0.0672    0.7634
0001    0.0494    0.7067
0007    0.0352    0.6604
0062    0.0256    0.6254
0580    0.0305    0.6074
0759    0.2007    0.7492
0023    0.2373    1.1380
0001    0.2241    1.2470
0000    0.2198    1.2647
0000    0.2172    1.2619
   -0.0000    0.2142    1.2526
   -0.0000    0.2103    1.2386
0000    0.2049    1.2194
   -0.0000    0.1976    1.1938
0000    0.1881    1.1602
0000    0.1757    1.1176
0000    0.1603    1.0652
0000    0.1420    1.0041
0000    0.1214    0.9359
0000    0.0995    0.8667
0000    0.0781    0.7985


y(:,:,2) =

0100    0.0500    0.1790
0540    0.0481    0.4711
0586    0.1675    0.6959
0048    0.1943    0.9850
0006    0.1727    1.0543
0001    0.1533    1.0280
0000    0.1331    0.9714
0000    0.1116    0.9043
0000    0.0898    0.8350
0001    0.0692    0.7696
0003    0.0512    0.7121
0016    0.0370    0.6651
0131    0.0291    0.6308
0879    0.0538    0.6258
0291    0.2158    0.8615
0013    0.2077    1.1050
0001    0.1911    1.1424
0000    0.1772    1.1161
0000    0.1616    1.0681
0000    0.1434    1.0083
0000    0.1228    0.9411
0000    0.1010    0.8711
0000    0.0795    0.8027
0000    0.0600    0.7402
0000    0.0434    0.6877
0000    0.0303    0.6451
0004    0.0206    0.6127
0048    0.0143    0.5895
0617    0.0163    0.5771
0989    0.2203    0.7202
0012    0.2602    1.2164


y(:,:,3) =

0100    0.0500    0.1790
0521    0.0474    0.4707
0589    0.1581    0.6842
0053    0.1853    0.9552
0007    0.1627    1.0185
0002    0.1416    0.9882
0001    0.1202    0.9288
0001    0.0983    0.8610
0001    0.0770    0.7941
0003    0.0580    0.7335
0013    0.0424    0.6825
0092    0.0325    0.6439
0625    0.0441    0.6286
0493    0.1828    0.7753
0029    0.1959    1.0286
0003    0.1750    1.0753
0000    0.1566    1.0430
0000    0.1370    0.9854
0000    0.1158    0.9181
0000    0.0939    0.8483
0000    0.0729    0.7816
0000    0.0542    0.7222
0002    0.0388    0.6726
0014    0.0272    0.6338
0144    0.0210    0.6064
1126    0.0487    0.6057
0208    0.2327    0.8997
0006    0.2146    1.1448
0000    0.2005    1.1806
0000    0.1896    1.1607
0000    0.1773    1.1218


y(:,:,4) =

0100    0.0500    0.1790
0502    0.0467    0.4704
0591    0.1494    0.6738
0057    0.1771    0.9284
0008    0.1537    0.9870
0002    0.1316    0.9542
0001    0.1096    0.8938
0001    0.0878    0.8271
0002    0.0675    0.7633
0008    0.0501    0.7074
0046    0.0373    0.6627
0312    0.0359    0.6347
0848    0.1121    0.6774
0094    0.1901    0.9267
0008    0.1688    1.0242
0001    0.1477    1.0048
0000    0.1266    0.9487
0000    0.1047    0.8816
0000    0.0831    0.8134
0001    0.0631    0.7502
0003    0.0461    0.6958
0020    0.0331    0.6522
0163    0.0266    0.6213
0999    0.0596    0.6232
0202    0.2071    0.8726
0010    0.1896    1.0614
0001    0.1696    1.0720
0000    0.1511    1.0285
0000    0.1311    0.9668
0000    0.1095    0.8980
0000    0.0877    0.8286
function dydt=newwaykumar2004(t,y,kpm)
kp=3;
kmp = 25;
klm = 15;
kl = 1;
theta=1;
w=0.5;
%function handle
f = @(m) 1+tanh((m-theta)/w);
dpdt=kp*y(1)*(1-y(1))-kpm*y(1)*y(2);
dmdt=(kmp*y(1)+y(3))*y(2)*(1-y(2))-y(2);
dIdt=klm*f(y(2))-kl*y(3);
dydt=[dpdt;dmdt;dIdt];
end

1 Comment
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Stephen23 on 21 Apr 2023

Edited: Stephen23 on 21 Apr 2023

Ayush Ranjan: you should follow Dyuman Joshi's excellent advice to make KPM an input argument (and avoid GLOBAL variables). Note that the ODE45 documentation includes an example showing how to pass extra parameters to the ODE function:

https://www.mathworks.com/help/matlab/ref/ode45.html#bu3uhuk

which links in turn to this page:

https://www.mathworks.com/help/matlab/math/parameterizing-functions.html

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