tmd_ellipse gives tidal ellipse parameters at specified location(s).
[umajor,uminor,uphase,uincl] = tmd_ellipse(filename,constituent,lati,loni)[umajor,uminor,uphase,uincl] = tmd_ellipse(filename,constituent,lati,loni) gives the major and minor axes of tidal current velocities.
Inputs:
filenameTMD3.0 compatible tide model ending in .nc.constituentstring constituent (e.g., 'm2')lati,lonigeographic coordinates (can be any size, but must be equal size)
Outputs:
umajorMajor axis, the largest current for the constituent (m/s). Always positive.uminorMinor axis, the smallest current (m/s). Negative uminor indicates clockwise flow.uphaseReference point on the ellipse (degrees)uinclInclination (degrees)
Get the tidal ellipse parameters for the o1 constituent:
fn = 'CATS2008_v2023.nc';
lat = -71.9102;
lon = 172.6590;
% Get ellipse parameters:
[umaj,umin,uphase,uincl] = tmd_ellipse(fn,'o1',lat,lon);
% Print the numbers:
[umaj umin uphase uincl]
ans =
0.2060 -0.0886 36.9514 56.3513The numbers above describe a clockwise flow (negative umin) with a maximum tidal velocity of 20.6 cm/s.
What exactly do the major and minor axes mean? Let's dig in to what the o1 constituent looks like at this location. For this, we will plot one complete cycle of tidal currents for the o1 constituent. How long does it take to complete one o1 cycle?
% Get the o1 constituent angular frequency (rad/s):
[~,~,~,omega] = tmd_constit('o1');
% Convert omega to period in days:
T = (2*pi/omega)/(24*60*60)
T =
1.0758The o1 constituent has a period of about 1.08 days, so we'll start by making an hourly time array that spans 1.08 days. Then we'll solve tidal currents u and v at times t for the location defined above.
% Hourly time array spanning one o1 period:
t = datenum(2022,1,1):1/24:(datenum(2022,1,1)+T);
% Predict hourly tides, considering only the o1 constituent:
u = tmd_predict(fn,lat,lon,t,'u','constituent','o1');
v = tmd_predict(fn,lat,lon,t,'v','constituent','o1');
% Define an array of colors:
col = flipud(parula(length(t)));
figure
hold on
for k=1:length(t)
plot([0 u(k)],[0 v(k)],'color',col(k,:));
text(u(k),v(k),num2str(k-1),'color',col(k,:))
end
grid on
axis equal
xlabel 'eastward velocity (m/s)'
ylabel 'northward velocity (m/s)' 
Above, we see that at hour 0, o1 current velocity was to the northeast. The negative value of umin already told us it's a clockwise ellipse, and as expected, the current sweeps through an elliptical path over the course of the day, ending up back at the starting place just under 26 hours later.
Here is an ellipse plotted directly from the tidal ellipse parameters:
% Equation of an unrotated ellipse:
foo = linspace(0,2*pi,500);
x = umaj*cos(foo);
y = umin*sin(foo);
% Rotate the ellipse:
[theta,r] = cart2pol(x,y);
[xr,yr] = pol2cart(theta+uincl*pi/180,r);
% Plot the rotated ellipse:
plot(xr,yr,'r')
Here's a question I do not know the answer to: Why doesn't the red ellipse line up perfectly with the predicted hourly currents? The umaj and umin parameters are slightly smaller than necessary to meet the hourly predictions. Have I plotted the red ellipse incorrectly, is there a mistake in the tmd_ellipse code, or is there some fundamental concept I'm misunderstanding here? If you know the answer and this section of the doc is still on GitHub, please reach out and explain it to me.
Foreman, M. G. G., & Henry, R. F. (1989). The harmonic analysis of tidal model time series. Advances in water resources, 12(3), 109-120. https://doi.org/10.1016/0309-1708(89)90017-1
The tmd_ellipse function and its documentation were written by Chad A. Greene & Laurie Padman, June 2022.