Resolve normal depth from Manning's equation

1 Aug 2020
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Answer Accepted
Updated 1 Aug 2020
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Hello,
I aim to obtain the normal depth of a channel using Mannig's equation. Somehow I don't manage to resolve its value. Here it's the pieco of code that I'm using:
riverSlope=0.0114; % [m/m] - inletSlope, outletSlope or riverSlope
bottom_width=33.5937; % [m] - inlet or outlet bottom width
slope_Rbank=1.1336; % [m/m] - slope_Rbank_in or slope_Rbank_out
slope_Lbank=0.3334; % [m/m] - slope_Lbank_in or slope_Lbank_out
q=10; % [m3/s] - Flow discharge
n=0.04; % [-] - Manning's roughness coefficient
syms y
area=(bottom_width+(y/(2*slope_Rbank))+(y/(2*slope_Lbank)))*y;
wetted_perimeter=bottom_width+y*(sqrt(1+(1/slope_Rbank)^2)+sqrt(1+(1/slope_Lbank)^2));
manning_eqn=@(y)(1/n)*((area/wetted_perimeter)^(2/3))*(riverSlope^(1/2))*area==q;
soly=solve(manning_eqn,y)
I would really appreciate if someone can help to fix it in order to obtain the desired values and avoid the coding of an iteration loop for the manual calculation. Thanks in advance!!
Álvaro

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 Accepted Answer

Alan Stevens
Alan Stevens on 1 Aug 2020
Edited: Alan Stevens on 1 Aug 2020

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This shoud do it:
depth0 = 1; % Initial guess
depth = fzero(@manningfn, depth0);
function manning = manningfn(y)
riverSlope=0.0114; % [m/m] - inletSlope, outletSlope or riverSlope
bottom_width=33.5937; % [m] - inlet or outlet bottom width
slope_Rbank=1.1336; % [m/m] - slope_Rbank_in or slope_Rbank_out
slope_Lbank=0.3334; % [m/m] - slope_Lbank_in or slope_Lbank_out
q=10; % [m3/s] - Flow discharge
n=0.04; % [-] - Manning's roughness coefficient
area=(bottom_width+(y/(2*slope_Rbank))+(y/(2*slope_Lbank)))*y;
wetted_perimeter=bottom_width+y*(sqrt(1+(1/slope_Rbank)^2)+sqrt(1+(1/slope_Lbank)^2));
manning = (1/n)*((area/wetted_perimeter)^(2/3))*(riverSlope^(1/2))*area-q;
end

3 Comments
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Álvaro Pardo
Álvaro Pardo on 1 Aug 2020
Is there any way I can define the parameters out of the function? That would be nice because I aim to use them for other applications. Many thanks!!
Alan Stevens
Alan Stevens on 1 Aug 2020
Yes, you could do this:
riverSlope=0.0114; % [m/m] - inletSlope, outletSlope or riverSlope
bottom_width=33.5937; % [m] - inlet or outlet bottom width
slope_Rbank=1.1336; % [m/m] - slope_Rbank_in or slope_Rbank_out
slope_Lbank=0.3334; % [m/m] - slope_Lbank_in or slope_Lbank_out
q=10; % [m3/s] - Flow discharge
n=0.04; % [-] - Manning's roughness coefficient
data =[riverSlope; bottom_width; slope_Rbank; slope_Lbank; q; n];
depth0 = 1; % Initial guess
depth = fzero(@manningfn, depth0,[],data);
function manning = manningfn(y, data)
riverSlope=data(1);
bottom_width=data(2);
slope_Rbank=data(3);
slope_Lbank=data(4);
q=data(5);
n=data(6);
area=(bottom_width+(y/(2*slope_Rbank))+(y/(2*slope_Lbank)))*y;
wetted_perimeter=bottom_width+y*(sqrt(1+(1/slope_Rbank)^2)+sqrt(1+(1/slope_Lbank)^2));
manning = (1/n)*((area/wetted_perimeter)^(2/3))*(riverSlope^(1/2))*area-q;
end

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