You x-data is from 40 to 140.....how you can limit from 0?
How to adjust plot?
4 views (last 30 days)
Show older comments
How can I adjust my x axis to start from 0 in the figures. When I set xlim then the figures become totally changed. Please help me to adjust the code.
clear all; close all; clc;
Vrest = 0; % mV− change this to −65 ifdesired
dt = 0.01; % ms
totalTime = 150; % ms
C = 20; % uF/cm^2
V_Ca = 120; %mV %Reversal potential for Ca2+ current
V_K = -84; %mV %Reversal potential for K+ current
V_Leak = -60; %mV %Reversal potential for leak current
g_Ca = 4.4; % mS/cm^2 % Maximal conductance associated with Ca2+ current
g_K = 8; % mS/cm^2 % Maximal conductance associated with K+ current
g_Leak = 2; % mS/cm^2 % Conductance associated with leak current
V_1 = -1.2; % mV
V_2 = 18; % mV
% Vector oftimesteps
t = [0:dt:totalTime];
% samples = length(t);
V = zeros(size(t));
% Current input −− change this to see how different inputs affect the neuron
I_current = ones(1,length(t))*0.0;
I_current(45/dt:end) = 90; % Input of 0 microA/cm2 beginning at 50 ms and steady until end of time period.
% initializing values
V(1) = Vrest; % membrane potential is starting at its resting state
% separate functions to get the alpha and beta values
[alphaW, betaW] = w_equations(V(1));
% initializing gating variables to the asymptotic values when membrane potential
% is set to the membrane resting value based on equation 13
w(1) = (alphaW / (alphaW + betaW));
% repeat for time determined in totalTime , by each dt
for i = 1:length(t)
% calculate new alpha and beta based on last known membrane potenatial
[alphaW, betaW] = w_equations(V(i));
minf = 1/2*(1 + tanh((V-V_1)/V_2));
% conductance variables − computed separately to show how this
% changes with membrane potential in one ofthe graphs
conductance_Ca(i) = g_Ca*(minf(i));
conductance_K(i)=g_K*(w(i));
% retrieving ionic currents
I_Ca(i) = conductance_Ca(i)*(V(i)-V_Ca);
I_K(i) = conductance_K(i)*(V(i)-V_K);
I_Leak(i) = g_Leak*(V(i)-V_Leak);
% Calculating the input
Input = I_current(i) - (I_Ca(i) + I_K(i) + I_Leak(i));
% Calculating the new membrane potential
V(i+1) = V(i) + Input* dt*(1/C);
% getting new values for the gating variables
w(i+1) = w(i) + (alphaW *(1-w(i)) - betaW * w(i))*dt;
end
%%
%figure('Name', 'Membrane Potential vs input')
%subplot(2,1,1)
%plot(t(45/dt:end),V(45/dt:end-1), 'LineWidth', 2)
%xlabel('Time (ms)')
%ylabel('Voltage (mV)')
%title('Action Potential')
%subplot(2,1,2)
%plot(t(45/dt:end),I_current(45/dt:end), 'r', 'LineWidth', 2)
%xlabel('Time (ms)')
%ylabel('Voltage (mV)')
%title('Input')
figure('Name', 'Membrane Potential vs input')
plot(t(45/dt:end),V(45/dt:end-1), 'LineWidth', 2)
xlabel('Time (ms)')
ylabel('Voltage (mV)')
title('Action Potential')
figure('Name', 'Gating Parameters')
plot(t(45/dt:end),w(45/dt:end-1), 'g','LineWidth', 2)
hold on
plot(t(45/dt:end),minf(45/dt:end), 'm','LineWidth', 2)
legend('w','minf')
xlabel('Time (ms)')
ylabel('')
title('Gating Parameters')
figure('Name', 'Conductance')
plot(t(45/dt:end),V(45/dt:end-1), 'r', t(45/dt:end), conductance_Ca(45/dt:end), 'b', t(45/dt:end), conductance_K(45/dt:end), 'g', 'LineWidth', 2)
legend('Action Potential', 'Ca+ Conductance', 'K+ Conductance')
xlabel('Time (ms)')
ylabel('Voltage (mV)')
title('Conduction of K+ and Ca+')
figure('Name', 'Currents')
plot(t(45/dt:end),I_Ca(45/dt:end), 'r',t(45/dt:end),I_K(45/dt:end), 'b', 'LineWidth', 2)
legend('ICa+', 'IK+')
xlabel('Time (ms)')
ylabel('Current')
title ('Currents')
% Special graph to show ionic current movement
Vrest = 0;
voltage = [-100:0.01:100];
for i = 1:length(voltage)
[alphaW, betaW] = w_equations(voltage(i));
tauw(i) = 1/(alphaW+betaW);
xw(i) = alphaW/(alphaW+betaW);
aW(i) = alphaW;
bW(i) = betaW;
end
%figure('Name', 'Equilibrium Function');
%plot(voltage, xw,'LineWidth', 2);
%legend('w');
%title('Equilibrium Function');
%xlabel('mV')
%ylabel('x(u)');
%xlabel('Time (ms)')
%%%%%%%% functions section - always after main code %%%%%%%%%%%%%%%
%calculate alpha w and beta w
function [alpha_w, beta_w] = w_equations(V)
V_3 = 2; % mV
V_4 = 30; % mV
phi = 0.04; %1/ms %Rate scaling parameter
alpha_w = 1/2*phi* cosh((V-V_3)/(2*V_4))*(1 + tanh((V-V_3)/V_4));
beta_w = 1/2*phi* cosh((V-V_3)/(2*V_4))*(1 - tanh((V-V_3)/V_4));
end
%%%%%%%% functions section - always after main code %%%%%%%%%%%%%%%
%function [minf] = m_inf(V)
%V_1 = -1.2; % mV
%V_2 = 18; % mV
%V_3 = 2; % mV
%V_4 = 30; % mV
%minf = 1/2*(1 + tanh((V-V_1)/V_2));
%end
Accepted Answer
KSSV
on 27 Jun 2022
Edited: KSSV
on 27 Jun 2022
Don't use:
plot(t(45/dt:end),V(45/dt:end-1), 'LineWidth', 2)
instead use:
plot(t,V, 'LineWidth', 2)
Like this:
clear all; close all; clc;
Vrest = 0; % mV− change this to −65 ifdesired
dt = 0.01; % ms
totalTime = 150; % ms
C = 20; % uF/cm^2
V_Ca = 120; %mV %Reversal potential for Ca2+ current
V_K = -84; %mV %Reversal potential for K+ current
V_Leak = -60; %mV %Reversal potential for leak current
g_Ca = 4.4; % mS/cm^2 % Maximal conductance associated with Ca2+ current
g_K = 8; % mS/cm^2 % Maximal conductance associated with K+ current
g_Leak = 2; % mS/cm^2 % Conductance associated with leak current
V_1 = -1.2; % mV
V_2 = 18; % mV
% Vector oftimesteps
t = [0:dt:totalTime];
% samples = length(t);
% Current input −− change this to see how different inputs affect the neuron
I_current = ones(1,length(t))*0.0;
I_current(45/dt:end) = 90; % Input of 0 microA/cm2 beginning at 50 ms and steady until end of time period.
V = zeros(size(t)) ;
w = zeros(size(t)) ;
conductance_Ca = zeros(size(t)) ;
conductance_K = zeros(size(t));
I_Ca = zeros(size(t)) ;
I_K = zeros(size(t)) ;
I_Leak = zeros(size(t)) ;
% initializing values
V(1) = Vrest; % membrane potential is starting at its resting state
% separate functions to get the alpha and beta values
[alphaW, betaW] = w_equations(V(1));
% initializing gating variables to the asymptotic values when membrane potential
% is set to the membrane resting value based on equation 13
w(1) = (alphaW / (alphaW + betaW));
% repeat for time determined in totalTime , by each dt
for i = 1:length(t)-1
% calculate new alpha and beta based on last known membrane potenatial
[alphaW, betaW] = w_equations(V(i));
minf = 1/2*(1 + tanh((V-V_1)/V_2));
% conductance variables − computed separately to show how this
% changes with membrane potential in one ofthe graphs
conductance_Ca(i) = g_Ca*(minf(i));
conductance_K(i)=g_K*(w(i));
% retrieving ionic currents
I_Ca(i) = conductance_Ca(i)*(V(i)-V_Ca);
I_K(i) = conductance_K(i)*(V(i)-V_K);
I_Leak(i) = g_Leak*(V(i)-V_Leak);
% Calculating the input
Input = I_current(i) - (I_Ca(i) + I_K(i) + I_Leak(i));
% Calculating the new membrane potential
V(i+1) = V(i) + Input* dt*(1/C);
% getting new values for the gating variables
w(i+1) = w(i) + (alphaW *(1-w(i)) - betaW * w(i))*dt;
end
%%
%figure('Name', 'Membrane Potential vs input')
%subplot(2,1,1)
%plot(t,V, 'LineWidth', 2)
%xlabel('Time (ms)')
%ylabel('Voltage (mV)')
%title('Action Potential')
%subplot(2,1,2)
%plot(t,I_current, 'r', 'LineWidth', 2)
%xlabel('Time (ms)')
%ylabel('Voltage (mV)')
%title('Input')
figure('Name', 'Membrane Potential vs input')
plot(t,V, 'LineWidth', 2)
xlabel('Time (ms)')
ylabel('Voltage (mV)')
title('Action Potential')
figure('Name', 'Gating Parameters')
plot(t,w, 'g','LineWidth', 2)
hold on
plot(t,minf, 'm','LineWidth', 2)
legend('w','minf')
xlabel('Time (ms)')
ylabel('')
title('Gating Parameters')
figure('Name', 'Conductance')
plot(t,V, 'r', t, conductance_Ca, 'b', t, conductance_K, 'g', 'LineWidth', 2)
legend('Action Potential', 'Ca+ Conductance', 'K+ Conductance')
xlabel('Time (ms)')
ylabel('Voltage (mV)')
title('Conduction of K+ and Ca+')
figure('Name', 'Currents')
plot(t,I_Ca, 'r',t,I_K, 'b', 'LineWidth', 2)
legend('ICa+', 'IK+')
xlabel('Time (ms)')
ylabel('Current')
title ('Currents')
% Special graph to show ionic current movement
Vrest = 0;
voltage = [-100:0.01:100];
for i = 1:length(voltage)
[alphaW, betaW] = w_equations(voltage(i));
tauw(i) = 1/(alphaW+betaW);
xw(i) = alphaW/(alphaW+betaW);
aW(i) = alphaW;
bW(i) = betaW;
end
%figure('Name', 'Equilibrium Function');
%plot(voltage, xw,'LineWidth', 2);
%legend('w');
%title('Equilibrium Function');
%xlabel('mV')
%ylabel('x(u)');
%xlabel('Time (ms)')
%%%%%%%% functions section - always after main code %%%%%%%%%%%%%%%
%calculate alpha w and beta w
function [alpha_w, beta_w] = w_equations(V)
V_3 = 2; % mV
V_4 = 30; % mV
phi = 0.04; %1/ms %Rate scaling parameter
alpha_w = 1/2*phi* cosh((V-V_3)/(2*V_4))*(1 + tanh((V-V_3)/V_4));
beta_w = 1/2*phi* cosh((V-V_3)/(2*V_4))*(1 - tanh((V-V_3)/V_4));
end
%%%%%%%% functions section - always after main code %%%%%%%%%%%%%%%
%function [minf] = m_inf(V)
%V_1 = -1.2; % mV
%V_2 = 18; % mV
%V_3 = 2; % mV
%V_4 = 30; % mV
%minf = 1/2*(1 + tanh((V-V_1)/V_2));
%end
More Answers (0)
See Also
Categories
Find more on Loops and Conditional Statements in Help Center and File Exchange
Community Treasure Hunt
Find the treasures in MATLAB Central and discover how the community can help you!
Start Hunting!
You can also select a web site from the following list
Americas
- América Latina (Español)
- Canada (English)
- United States (English)
Europe
- Belgium (English)
- Denmark (English)
- Deutschland (Deutsch)
- España (Español)
- Finland (English)
- France (Français)
- Ireland (English)
- Italia (Italiano)
- Luxembourg (English)
- Netherlands (English)
- Norway (English)
- Österreich (Deutsch)
- Portugal (English)
- Sweden (English)
- Switzerland
- United Kingdom (English)
Asia Pacific
- Australia (English)
- India (English)
- New Zealand (English)
- 中国
- 日本Japanese (日本語)
- 한국Korean (한국어)