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How to change x-axis ticks labels in stackedplot?

  h = stackedplot(rand(6,3));   I want to set x-axis ticks according to my own defined set i.e., instead of 1:6, I want to replace x-axisticks [1, 2,3 ,4,5,6] to ['A', 'S','T', 'AAA', 'BBB', 'ZZZ'] , by rotating it to 90 degree that is vertically insted of horizontally?     NOTE:- Matlabsolutions.com  provide latest  MatLab Homework Help, MatLab Assignment Help  ,  Finance Assignment Help  for students, engineers and researchers in Multiple Branches like ECE, EEE, CSE, Mechanical, Civil with 100% output.Matlab Code for B.E, B.Tech,M.E,M.Tech, Ph.D. Scholars with 100% privacy guaranteed. Get MATLAB projects with source code for your learning and research. There does not seem to be an easy way to set the  XTick  or  XTickLabel  of a  StackedLineChart  object (such as what's created by  stackedplot ):   data = rand(6,3); h = stackedplot(1:6,data); % try a couple of things, neither of which work try set(h,'XTick',1:6,'XTic
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Problem with polyfit and polyval

 Hello there, I took some manual measurements of the frequency response of a pre-amplifier and now I want to do a polyfit to get a smoother approximation (as I only measured some key points, the resolution is quite irregular) of the FR, which I do with polyfit. But so far, it returns me ZERO for all the polynomial coefficients! I'm probably doing a really simple mistake.

This is the code (the Amp.mat file is annexed):
 
 
%%Frequency Response Plot

close all; clear all

load('Amp.mat'); % Manual Measurements of the FR

Freq = Amp(:,1);          % Frequency
G = Amp(:,3)./Amp(:,2);   % Gain
Phase = Amp(:,4);         % Phase

GFit = polyfit(Freq,G,length(Freq));
GFitVal = polyval(GFit,Freq); 

PhaseFit = polyfit(Freq,Phase,length(Freq));
PhaseFitVal = polyval(PhaseFit,Freq); 

figure;

subplot(2,1,1)

semilogx(Freq,G, ...
         Freq,GFitVal); 
grid on;
legend('G', ...
       'GFitVal');
xlabel('Frequency (Hz)')
ylabel('Gain')
title('Gain x Frequency of the Pre-amplifier')

subplot(2,1,2)

semilogx(Freq,Phase, ...
         Freq,PhaseFitVal); 
grid on;
legend('Phase', ...
       'PhaseFit');
xlabel('Frequency (Hz)')
ylabel('Phase (degrees)')
title('Phase x Frequency of the Pre-amplifier')

% Impulse Response

x = 0:1e5;

GS = polyval(GFit,x);
PhaseS = polyval(PhaseFit,x);

FilterFreq = [flip(GS(2:end)).*exp(1i*(-flip(PhaseS(2:end)))) ...
              GS.*exp(1i*PhaseS)];

FilterIR = ifft(FilterFreq);

figure;

stem(FilterIR)
grid on;
xlabel('Samples (n)')
ylabel('Level')
title('Impulse Response of the Pre-amplifier')

ANSWER



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It took me a few minutes to come up with this purely signal processing approach, so no curve fitting required. Experiment with the numerator and denominator orders of the transfer function to get the result you want. (Another option would be the firls function, and there are other empirical methods to consider depending on what you want to do. There is also the entire System Identification Toolbox! You are doing system identification here.)
 
It should give you everything you want:

 
D = load('Philippe Amp.mat');
Freq = D.Amp(:,1);                                              % Hz Frequency Vector
Vi = D.Amp(:,3);
Vo = D.Amp(:,4);
H = Vo./Vi;                                                     % Amplitude Transfer Function
Phase = D.Amp(:,4);
W = Freq/max(Freq)*pi;                                          % Radian Frequency Vector

figure(1)                                                       % Look At The Data
subplot(2,1,1)
plot(Freq,Vi,  Freq,Vo)
grid
subplot(2,1,2)
plot(Freq, Phase)
grid

figure(2)

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