Display Results as nicely formatted table

Question

buxZED 2011 年 2 月 23 日

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https://jp.mathworks.com/matlabcentral/answers/1892-display-results-as-nicely-formatted-table

回答済み: Abhay 2022 年 10 月 14 日

in this codes, how do I get the resalts as a nice table showing step by step iterations clarifying more collums would be

itteration, lower, upper, f(lower), f(upper), f(xc), f(c), xupper-xlower

function y = f(x) y = x.^3 - 2;

exists. Then:
>> format long
>> eps_abs = 1e-5;
>> eps_step = 1e-5;
>> a = 0.0;
>> b = 2.0;
>> while (b - a >= eps_step || ( abs( f(a) ) >= eps_abs && abs( f(b) )  >= eps_abs ) )
    c = (a + b)/2;
    if ( f(c) == 0 )
       break;
    elseif ( f(a)*f(c) < 0 )
       b = c;
    else
       a = c;
    end
end
>> [a b]
ans = 1.259918212890625  1.259925842285156
>> abs(f(a))
ans =    0.0000135103601622
>> abs(f(b))
ans =    0.0000228224229404

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Tadashi 2018 年 9 月 1 日

If your MATLAB version is R2013b or newer, you can use table command.

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Answer 1

Paulo Silva 2011 年 2 月 23 日

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https://jp.mathworks.com/matlabcentral/answers/1892-display-results-as-nicely-formatted-table#answer_2830

MATLAB Online で開く

I have no idea what f(xc) is so I didn't included it, don't use the following code to benchmark your function because it's slower (datasave isn't preallocated), use it only to get a nice table of values and have another function that doesn't make the table for benchmarks (tic toc or profiler).

Using the format short:

clc
fprintf('  itteration   lower    upper    f(lower)  f(upper)    f(c)  xupper-xlower\n')
clear
f=@(x) x.^3 - 2;
format short
eps_abs = 1e-5;
eps_step = 1e-5;
a = 0;
b = 2.0;
iter=0;
datasave=[];
while (b - a >= eps_step || ( abs( f(a) ) >= eps_abs && abs( f(b) )  >= eps_abs ) )
    iter=iter+1;
    c = (a + b)/2;
    datasave=[datasave; iter a b f(a) f(b) f(c) b-a];
    if ( f(c) == 0 )
       break;
    elseif ( f(a)*f(c) < 0 )
       b = c;
    else
       a = c;
    end
end
disp(datasave)

The output looks like this:

   itteration   lower    upper    f(lower)  f(upper)    f(c)  xupper-xlower
0000         0    2.0000   -2.0000    6.0000       NaN    2.0000
0000    1.0000    2.0000   -1.0000    6.0000   -1.0000    1.0000
0000    1.0000    1.5000   -1.0000    1.3750    1.3750    0.5000
0000    1.2500    1.5000   -0.0469    1.3750   -0.0469    0.2500
0000    1.2500    1.3750   -0.0469    0.5996    0.5996    0.1250
0000    1.2500    1.3125   -0.0469    0.2610    0.2610    0.0625
0000    1.2500    1.2813   -0.0469    0.1033    0.1033    0.0313
0000    1.2500    1.2656   -0.0469    0.0273    0.0273    0.0156
0000    1.2578    1.2656   -0.0100    0.0273   -0.0100    0.0078
0000    1.2578    1.2617   -0.0100    0.0086    0.0086    0.0039
0000    1.2598    1.2617   -0.0007    0.0086   -0.0007    0.0020
0000    1.2598    1.2607   -0.0007    0.0039    0.0039    0.0010
0000    1.2598    1.2603   -0.0007    0.0016    0.0016    0.0005
0000    1.2598    1.2600   -0.0007    0.0004    0.0004    0.0002
0000    1.2599    1.2600   -0.0002    0.0004   -0.0002    0.0001
0000    1.2599    1.2599   -0.0002    0.0001    0.0001    0.0001
0000    1.2599    1.2599   -0.0000    0.0001   -0.0000    0.0000
0000    1.2599    1.2599   -0.0000    0.0001    0.0001    0.0000
0000    1.2599    1.2599   -0.0000    0.0000    0.0000    0.0000

Using the format long:

clc
fprintf('       itteration              lower             upper             f(lower)            f(upper)               f(c)           xupper-xlower\n')
clear
f=@(x) x.^3 - 2;
format long
eps_abs = 1e-5;
eps_step = 1e-5;
a = 0;
b = 2.0;
iter=0;
datasave=[];
while (b - a >= eps_step || ( abs( f(a) ) >= eps_abs && abs( f(b) )  >= eps_abs ) )
    iter=iter+1;
    c = (a + b)/2;
    datasave=[datasave; iter a b f(a) f(b) f(c) b-a];
    if ( f(c) == 0 )
       break;
    elseif ( f(a)*f(c) < 0 )
       b = c;
    else
       a = c;
    end
end
disp(datasave)

The output looks like this:

     itteration              lower             upper             f(lower)            f(upper)               f(c)           xupper-xlower
000000000000000                   0   2.000000000000000  -2.000000000000000   6.000000000000000                 NaN   2.000000000000000
000000000000000   1.000000000000000   2.000000000000000  -1.000000000000000   6.000000000000000  -1.000000000000000   1.000000000000000
000000000000000   1.000000000000000   1.500000000000000  -1.000000000000000   1.375000000000000   1.375000000000000   0.500000000000000
000000000000000   1.250000000000000   1.500000000000000  -0.046875000000000   1.375000000000000  -0.046875000000000   0.250000000000000
000000000000000   1.250000000000000   1.375000000000000  -0.046875000000000   0.599609375000000   0.599609375000000   0.125000000000000
000000000000000   1.250000000000000   1.312500000000000  -0.046875000000000   0.260986328125000   0.260986328125000   0.062500000000000
000000000000000   1.250000000000000   1.281250000000000  -0.046875000000000   0.103302001953125   0.103302001953125   0.031250000000000
000000000000000   1.250000000000000   1.265625000000000  -0.046875000000000   0.027286529541016   0.027286529541016   0.015625000000000
000000000000000   1.257812500000000   1.265625000000000  -0.010024547576904   0.027286529541016  -0.010024547576904   0.007812500000000
000000000000000   1.257812500000000   1.261718750000000  -0.010024547576904   0.008573234081268   0.008573234081268   0.003906250000000
000000000000000   1.259765625000000   1.261718750000000  -0.000740073621273   0.008573234081268  -0.000740073621273   0.001953125000000
000000000000000   1.259765625000000   1.260742187500000  -0.000740073621273   0.003912973217666   0.003912973217666   0.000976562500000
000000000000000   1.259765625000000   1.260253906250000  -0.000740073621273   0.001585548394360   0.001585548394360   0.000488281250000
000000000000000   1.259765625000000   1.260009765625000  -0.000740073621273   0.000422512079240   0.000422512079240   0.000244140625000
000000000000000   1.259887695312500   1.260009765625000  -0.000158837092386   0.000422512079240  -0.000158837092386   0.000122070312500
000000000000000   1.259887695312500   1.259948730468750  -0.000158837092386   0.000131823412403   0.000131823412403   0.000061035156250
000000000000000   1.259918212890625   1.259948730468750  -0.000013510360162   0.000131823412403  -0.000013510360162   0.000030517578125
000000000000000   1.259918212890625   1.259933471679688  -0.000013510360162   0.000059155646067   0.000059155646067   0.000015258789063
000000000000000   1.259918212890625   1.259925842285156  -0.000013510360162   0.000022822422940   0.000022822422940   0.000007629394531

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Paulo Silva 2011 年 2 月 23 日

I fixed the code, now the f(c) column is correct.

buxZED 2011 年 2 月 23 日

clc

fprintf(' Iteration XL XR f(XL) f(XR) f(XC) |XR-XL|\n')

clear

stu_id=0.2529;

f=@(x) (2.8*x.^3)-(3.5*x.^2)+(1.5*x)-(0.15+(0.1*stu_id));

format long

eps_abs = 1e-5;

eps_step = 1e-5;

XL = 0;

XR = 1.0;

XC=(XL+XR)/2;

iter=0;

datasave=[];

while (XR - XL >= eps_step || ( abs( f(XL) ) >= eps_abs && abs( f(XR) ) >= eps_abs ) )

iter=iter+1;

datasave=[datasave; iter XL XR f(XL) f(XR) f(XC) XR-XL];

XC = (XL + XR)/2;

if ( f(XC) == 0 )

break;

elseif ( f(XL)*f(XC) < 0 )

XR = XC;

else

XL = XC;

end

disp(datasave)

how do I add "c" to the table

have i done anything wrong?

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Answer 2

Omar Alsaidi 2019 年 7 月 18 日

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この回答への直接リンク

https://jp.mathworks.com/matlabcentral/answers/1892-display-results-as-nicely-formatted-table#answer_383723

fprintf('Celsius equivalent of a Fahrenheit temperature:\t\t Fahrenheit equivalent of a Celsius temperature:\n\n \t Celsius\tFahrenheit \t\t \t\tFahrenheit\tCelsius\n')

c=[0:2:100];

f=[32:2:212];

function [C] = Celsius(f)

C=(f-32) *5/9;

end

function [F]=Fahrenheit(c)

F =9/5*c+32;

end