Use surfc instead of surf, and then make appropriate changes to 'ZLocation' and 'FaceColor' in the contour part of the plot.
Try this —
% clc
% clear
% close all
f=13.56e6; % Fundamental Frequency
T=1/f; % Fundamental Period
omega=2*180*f;
t=0:T*.0001:T;
%************************Triple Fequency Case****************%
k=3; % Number of consecutive Harmonics
Total_Applied_Voltage=300;
V0=(2*Total_Applied_Voltage)/(k+1);
V=nan(1,k);
Omega=nan(1,k);
V_rf=0;
for n=1:1:k
V(n)=V0*(k-n+1)/(k);
Omega(n)=n*omega;
end
discharge_symmetry=1;
theta1=0:5:360;
theta2=0:5:360;
Dc_Self_Bias = nan(length(theta1), length(theta2));
for x=1:1:length(theta1)
for y=1:1:length(theta2)
Vrf=V(1)*cosd(Omega(1)*t+theta1(x))+V(2)*cosd(Omega(2)*t+theta2(y))+V(3)*cosd(Omega(3)*t);
Dc_Self_Bias(x,y)=-(((max(Vrf)+(discharge_symmetry*min(Vrf)))/(1+discharge_symmetry))/Total_Applied_Voltage)*100;
end
end
figure
hsc = surfc(theta1, theta2, Dc_Self_Bias);
% hsc(1).EdgeColor = [1 1 1]*0.8;
hsc(1).EdgeColor = 'interp'; % Surface Plot
hsc(2).ZLocation = 'zmin'; % Contour Plot
hsc(2).FaceColor = 'flat';
% colormap("hsv");
colormap(turbo)
colorbar
xlabel(['\theta_1 ',char(176),''])
ylabel(['\theta_2 ',char(176),''])
zlabel('Dc Self Bias %')
title('Discharge Characteristics')
xlim([min(theta1), max(theta1)])
ylim([min(theta2), max(theta2)])
zlim([min(min(Dc_Self_Bias)), 70])
xticks(min(theta1):30:max(theta1))
yticks(min(theta2):30:max(theta2))
pbaspect([1 1 1])
grid on
grid minor
The ability to change the level of the contour plot was introduced recently. I believe it is available in R2023b. You can set it anywhere you want, within the limits of the z-axis.
.
