I have been unable to find anything close to this with Google, so I'm afraid that my question itself may be flawed... None the less, here goes:

I wish to display a matrix of values (Z) at various fixed dynamic ranges. In this case, fixed at 0dB, 10dB, ..., 40dB.

My current approach is to find Zmag = abs(Z).^2, Zn = normalized(Zmag), Zdb = 10*log10(1+Zn)

In order to view a different dynamic range (say, 10dB) I would include 'Zn(Zn<0.1)=0.1' before finding Zdb. For 20dB I do the same, except the value of interest changes to 0.01.

Then I do a color mesh plot of Zn and view the XY (top, from 3D perspective) plot to see something similar to what imagesc(Zn) would give. The intent is that as I increase the dynamic range, I should see a more detailed plot (with more colors between the maximum and minimum, in this case).

My current method is performing as (I think) it should for 10dB: 10dB dynamic range mesh Compared to 40dB: 40dB dynamic range mesh plot

However, I can't see a difference between my 0,20,30, and 40dB plots. I would expect there to be a gradual increase in values from 0dB to 40dB.

-Dylan

EDIT: Here is some sample code. It is a snippit of the real code, but should still run:

```
%% Constants
fnum = 1;
Fc = 1/16;
taup = 128;
taumin = 1;
taumax = 512;
taux = taumin:taumax;
%% Signal
l = 1:16; %Signal length
s = sin(2*pi*Fc*l); %Original Signal
sig = zeros([1 taup+512]);
sig(taup:taup+size(l,2)-1) = s;
[mfr,fdy] = MatchedFilterResponse(sig,taup,l);
Z = mfr;
slices = true;
%full dynamic range
name = 'Short Tone Ping results with 0dB range';
Zmag = abs(Z).^2;
Zn = normalizeMat(Zmag);
Zdb = 10*log10(1+Zn);
fnum = plotSurfaces(taux,fdy,Zdb,fnum,name,slices);
slices = false;
%40dB dynamic range
name = 'Short Tone Ping results with 40dB range';
Z40mag = Zmag;
Z40n = normalizeMat(Z40mag);
Z40n(Z40n<0.0001) = 0.0001;
Z40db = 10*log10(1+Z40n);
fnum = plotSurfaces(taux,fdy,Z40db,fnum,name,slices);
function [mfr,fdy] = MatchedFilterResponse(sig,taup,l)
Fdmin = -1/16;
Fdmax = 1/16;
Fdinc = (0.125)/(255);
fdy = linspace(Fdmin,Fdmax,256);
i = 0;
for tau = 1:512
i = i+1;
j = 0;
for Fd = Fdmin:Fdinc:Fdmax
j = j+1;
a = sig(l+taup-1);
b = sig(l+tau).*exp(1i*2*pi*Fd*l);
mfr(j,i) = sum(a.*b);
end
end
return
end
function [fnum] = plotSurfaces(taux,fdy,z,fnum,name,slices)
fid = figure(fnum);
axes1 = axes('Parent',fid);
grid(axes1,'on');
hold(axes1,'all');
msh = mesh(taux,fdy,z,'Parent',axes1);
xlabel ('Delay - seconds');
ylabel ('Frequency offset from center frequency - Cycles/sample');
zlabel ('Ambiguity function (Normalized Magnitude-Squared)','Visible','off');
fname = strcat(name,' (Ambiguity Function z(\tau;F_d))');
title(fname);
ax = axis;
axis([50 200 ax(3) ax(4)])
cb = colorbar('peer',axes1);
set(get(cb,'ylabel'),'String','Magnitude-Squared (dB)');
hold off;
fnum = fnum + 1;
return
end
```