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gsw_C_from_SP.m
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gsw_C_from_SP.m
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function C = gsw_C_from_SP(SP,t,p)
% gsw_C_from_SP conductivity from SP
%==========================================================================
%
% USAGE:
% C = gsw_C_from_SP(SP,t,p)
%
% DESCRIPTION:
% Calculates conductivity, C, from (SP,t,p) using PSS-78 in the range
% 2 < SP < 42. If the input Practical Salinity is less than 2 then a
% modified form of the Hill et al. (1986) fomula is used for Practical
% Salinity. The modification of the Hill et al. (1986) expression is to
% ensure that it is exactly consistent with PSS-78 at SP = 2.
%
% The conductivity ratio returned by this function is consistent with the
% input value of Practical Salinity, SP, to 2x10^-14 psu over the full
% range of input parameters (from pure fresh water up to SP = 42 psu).
% This error of 2x10^-14 psu is machine precision at typical seawater
% salinities. This accuracy is achieved by having four different
% polynomials for the starting value of Rtx (the square root of Rt) in
% four different ranges of SP, and by using one and a half iterations of
% a computationally efficient modified Newton-Raphson technique (McDougall
% and Wotherspoon, 2013) to find the root of the equation.
%
% Note that strictly speaking PSS-78 (Unesco, 1983) defines Practical
% Salinity in terms of the conductivity ratio, R, without actually
% specifying the value of C(35,15,0) (which we currently take to be
% 42.9140 mS/cm).
%
% INPUT:
% SP = Practical Salinity (PSS-78) [ unitless ]
% t = in-situ temperature (ITS-90) [ deg C ]
% p = sea pressure [ dbar ]
% ( i.e. absolute pressure - 10.1325 dbar )
%
% SP & t need to have the same dimensions.
% p may have dimensions 1x1 or Mx1 or 1xN or MxN, where SP & t are MxN.
%
% OUTPUT:
% C = conductivity [ mS/cm ]
%
% AUTHOR:
% Trevor McDougall, Paul Barker and Rich Pawlowicz [ [email protected] ]
%
% VERSION NUMBER: 3.05 (27th January 2015)
%
% REFERENCES:
% Hill, K.D., T.M. Dauphinee and D.J. Woods, 1986: The extension of the
% Practical Salinity Scale 1978 to low salinities. IEEE J. Oceanic Eng.,
% OE-11, 1, 109 - 112.
%
% IOC, SCOR and IAPSO, 2010: The international thermodynamic equation of
% seawater - 2010: Calculation and use of thermodynamic properties.
% Intergovernmental Oceanographic Commission, Manuals and Guides No. 56,
% UNESCO (English), 196 pp. Available from http://www.TEOS-10.org
% See appendix E of this TEOS-10 Manual.
%
% McDougall T. J. and S. J. Wotherspoon, 2013: A simple modification of
% Newton's method to achieve convergence of order 1 + sqrt(2). Applied
% Mathematics Letters, 29, 20-25.
%
% Unesco, 1983: Algorithms for computation of fundamental properties of
% seawater. Unesco Technical Papers in Marine Science, 44, 53 pp.
%
% The software is available from http://www.TEOS-10.org
%
%==========================================================================
%--------------------------------------------------------------------------
% Check variables and resize if necessary
%--------------------------------------------------------------------------
if ~(nargin == 3)
error('gsw_C_from_SP: Must have 3 input arguments')
end %if
% This line ensures that SP is non-negative.
if any(SP < 0)
error('gsw_C_from_SP: SP must be non-negative!')
end
[ms,ns] = size(SP);
[mt,nt] = size(t);
[mp,np] = size(p);
if (mt ~= ms | nt ~= ns)
error('gsw_C_from_SP: SP and t must have same dimensions')
end
if (mp == 1) & (np == 1) % p is a scalar,
p = p*ones(ms,ns); % Fill to size of SP.
elseif (np == ns) & (mp == 1) % p is row vector,
p = p(ones(1,ms),:); % copy down each column.
elseif (mp == ms) & (np == 1) % p is column vector,
p = p(:,ones(1,ns)); % copy across each row.
elseif (np == ms) & (np == 1) % p is a transposed row vector,
p = p.'; % transposed then
p = p(ones(1,ms), :); % copy down each column.
elseif (mp == ms) & (np == ns)
% ok
else
error('gsw_C_from_SP: p has wrong dimensions')
end %if
if ms == 1
SP = SP.';
t = t.';
p = p.';
transposed = 1;
else
transposed = 0;
end
%--------------------------------------------------------------------------
% Setting up the constants
%--------------------------------------------------------------------------
a0 = 0.0080;
a1 = -0.1692;
a2 = 25.3851;
a3 = 14.0941;
a4 = -7.0261;
a5 = 2.7081;
b0 = 0.0005;
b1 = -0.0056;
b2 = -0.0066;
b3 = -0.0375;
b4 = 0.0636;
b5 = -0.0144;
c0 = 0.6766097;
c1 = 2.00564e-2;
c2 = 1.104259e-4;
c3 = -6.9698e-7;
c4 = 1.0031e-9;
d1 = 3.426e-2;
d2 = 4.464e-4;
d3 = 4.215e-1;
d4 = -3.107e-3;
e1 = 2.070e-5;
e2 = -6.370e-10;
e3 = 3.989e-15;
p0 = 4.577801212923119e-3;
p1 = 1.924049429136640e-1;
p2 = 2.183871685127932e-5;
p3 = -7.292156330457999e-3;
p4 = 1.568129536470258e-4;
p5 = -1.478995271680869e-6;
p6 = 9.086442524716395e-4;
p7 = -1.949560839540487e-5;
p8 = -3.223058111118377e-6;
p9 = 1.175871639741131e-7;
p10 = -7.522895856600089e-5;
p11 = -2.254458513439107e-6;
p12 = 6.179992190192848e-7;
p13 = 1.005054226996868e-8;
p14 = -1.923745566122602e-9;
p15 = 2.259550611212616e-6;
p16 = 1.631749165091437e-7;
p17 = -5.931857989915256e-9;
p18 = -4.693392029005252e-9;
p19 = 2.571854839274148e-10;
p20 = 4.198786822861038e-12;
q0 = 5.540896868127855e-5;
q1 = 2.015419291097848e-1;
q2 = -1.445310045430192e-5;
q3 = -1.567047628411722e-2;
q4 = 2.464756294660119e-4;
q5 = -2.575458304732166e-7;
q6 = 5.071449842454419e-3;
q7 = -9.081985795339206e-5;
q8 = -3.635420818812898e-6;
q9 = 2.249490528450555e-8;
q10 = -1.143810377431888e-3;
q11 = 2.066112484281530e-5;
q12 = 7.482907137737503e-7;
q13 = 4.019321577844724e-8;
q14 = -5.755568141370501e-10;
q15 = 1.120748754429459e-4;
q16 = -2.420274029674485e-6;
q17 = -4.774829347564670e-8;
q18 = -4.279037686797859e-9;
q19 = -2.045829202713288e-10;
q20 = 5.025109163112005e-12;
r0 = 3.432285006604888e-3;
r1 = 1.672940491817403e-1;
r2 = 2.640304401023995e-5;
r3 = 1.082267090441036e-1;
r4 = -6.296778883666940e-5;
r5 = -4.542775152303671e-7;
r6 = -1.859711038699727e-1;
r7 = 7.659006320303959e-4;
r8 = -4.794661268817618e-7;
r9 = 8.093368602891911e-9;
r10 = 1.001140606840692e-1;
r11 = -1.038712945546608e-3;
r12 = -6.227915160991074e-6;
r13 = 2.798564479737090e-8;
r14 = -1.343623657549961e-10;
r15 = 1.024345179842964e-2;
r16 = 4.981135430579384e-4;
r17 = 4.466087528793912e-6;
r18 = 1.960872795577774e-8;
r19 = -2.723159418888634e-10;
r20 = 1.122200786423241e-12;
u0 = 5.180529787390576e-3;
u1 = 1.052097167201052e-3;
u2 = 3.666193708310848e-5;
u3 = 7.112223828976632;
u4 = -3.631366777096209e-4;
u5 = -7.336295318742821e-7;
u6 = -1.576886793288888e+2;
u7 = -1.840239113483083e-3;
u8 = 8.624279120240952e-6;
u9 = 1.233529799729501e-8;
u10 = 1.826482800939545e+3;
u11 = 1.633903983457674e-1;
u12 = -9.201096427222349e-5;
u13 = -9.187900959754842e-8;
u14 = -1.442010369809705e-10;
u15 = -8.542357182595853e+3;
u16 = -1.408635241899082;
u17 = 1.660164829963661e-4;
u18 = 6.797409608973845e-7;
u19 = 3.345074990451475e-10;
u20 = 8.285687652694768e-13;
k = 0.0162;
t68 = t.*1.00024;
ft68 = (t68 - 15)./(1 + k.*(t68 - 15));
x = sqrt(SP);
Rtx = nan(size(SP));
%--------------------------------------------------------------------------
% Finding the starting value of Rtx, the square root of Rt, using four
% different polynomials of SP and t68.
%--------------------------------------------------------------------------
if any(SP >= 9)
[I] = find(SP >= 9);
Rtx(I) = p0 + x(I).*(p1 + p4*t68(I) + x(I).*(p3 + p7*t68(I) + x(I).*(p6 ...
+ p11*t68(I) + x(I).*(p10 + p16*t68(I)+ x(I).*p15))))...
+ t68(I).*(p2+ t68(I).*(p5 + x(I).*x(I).*(p12 + x(I).*p17) + p8*x(I) ...
+ t68(I).*(p9 + x(I).*(p13 + x(I).*p18)+ t68(I).*(p14 + p19*x(I) + p20*t68(I)))));
end
if any(SP >= 0.25 & SP < 9)
[I] = find(SP >= 0.25 & SP < 9);
Rtx(I) = q0 + x(I).*(q1 + q4*t68(I) + x(I).*(q3 + q7*t68(I) + x(I).*(q6 ...
+ q11*t68(I) + x(I).*(q10 + q16*t68(I)+ x(I).*q15))))...
+ t68(I).*(q2+ t68(I).*(q5 + x(I).*x(I).*(q12 + x(I).*q17) + q8*x(I) ...
+ t68(I).*(q9 + x(I).*(q13 + x(I).*q18)+ t68(I).*(q14 + q19*x(I) + q20*t68(I)))));
end
if any(SP >= 0.003 & SP < 0.25)
[I] = find(SP >= 0.003 & SP < 0.25);
Rtx(I) = r0 + x(I).*(r1 + r4*t68(I) + x(I).*(r3 + r7*t68(I) + x(I).*(r6 ...
+ r11*t68(I) + x(I).*(r10 + r16*t68(I)+ x(I).*r15))))...
+ t68(I).*(r2+ t68(I).*(r5 + x(I).*x(I).*(r12 + x(I).*r17) + r8*x(I) ...
+ t68(I).*(r9 + x(I).*(r13 + x(I).*r18)+ t68(I).*(r14 + r19*x(I) + r20*t68(I)))));
end
if any(SP < 0.003)
[I] = find(SP < 0.003);
Rtx(I) = u0 + x(I).*(u1 + u4*t68(I) + x(I).*(u3 + u7*t68(I) + x(I).*(u6 ...
+ u11*t68(I) + x(I).*(u10 + u16*t68(I)+ x(I).*u15))))...
+ t68(I).*(u2+ t68(I).*(u5 + x(I).*x(I).*(u12 + x(I).*u17) + u8*x(I) ...
+ t68(I).*(u9 + x(I).*(u13 + x(I).*u18)+ t68(I).*(u14 + u19*x(I) + u20*t68(I)))));
end
%--------------------------------------------------------------------------
% Finding the starting value of dSP_dRtx, the derivative of SP with respect
% to Rtx.
%--------------------------------------------------------------------------
dSP_dRtx = a1 + (2*a2 + (3*a3 + (4*a4 + 5*a5.*Rtx).*Rtx).*Rtx).*Rtx ...
+ ft68.*(b1 + (2*b2 + (3*b3 + (4*b4 + 5*b5.*Rtx).*Rtx).*Rtx).*Rtx);
if any(SP < 2)
[I2] = find(SP < 2);
x = 400.*(Rtx(I2).*Rtx(I2));
sqrty = 10.*Rtx(I2);
part1 = 1 + x.*(1.5 + x) ;
part2 = 1 + sqrty.*(1 + sqrty.*(1 + sqrty));
Hill_ratio = gsw_Hill_ratio_at_SP2(t(I2));
dSP_dRtx(I2) = dSP_dRtx(I2)...
+ a0.*800.*Rtx(I2).*(1.5 + 2*x)./(part1.*part1)...
+ b0.*ft68(I2).*(10 + sqrty.*(20 + 30.*sqrty))./(part2.*part2);
dSP_dRtx(I2) = Hill_ratio.*dSP_dRtx(I2);
end
%--------------------------------------------------------------------------
% One iteration through the modified Newton-Raphson method (McDougall and
% Wotherspoon, 2012) achieves an error in Practical Salinity of about
% 10^-12 for all combinations of the inputs. One and a half iterations of
% the modified Newton-Raphson method achevies a maximum error in terms of
% Practical Salinity of better than 2x10^-14 everywhere.
%
% We recommend one and a half iterations of the modified Newton-Raphson
% method.
%
% Begin the modified Newton-Raphson method.
%--------------------------------------------------------------------------
SP_est = a0 + (a1 + (a2 + (a3 + (a4 + a5.*Rtx).*Rtx).*Rtx).*Rtx).*Rtx ...
+ ft68.*(b0 + (b1 + (b2+ (b3 + (b4 + b5.*Rtx).*Rtx).*Rtx).*Rtx).*Rtx);
if any(SP_est < 2)
[I2] = find(SP_est < 2);
x = 400.*(Rtx(I2).*Rtx(I2));
sqrty = 10.*Rtx(I2);
part1 = 1 + x.*(1.5 + x) ;
part2 = 1 + sqrty.*(1 + sqrty.*(1 + sqrty));
SP_Hill_raw = SP_est(I2) - a0./part1 - b0.*ft68(I2)./part2;
Hill_ratio = gsw_Hill_ratio_at_SP2(t(I2));
SP_est(I2) = Hill_ratio.*SP_Hill_raw;
end
Rtx_old = Rtx;
Rtx = Rtx_old - (SP_est - SP)./dSP_dRtx;
Rtxm = 0.5*(Rtx + Rtx_old); % This mean value of Rtx, Rtxm, is the
% value of Rtx at which the derivative dSP_dRtx is evaluated.
dSP_dRtx = a1 + (2*a2 + (3*a3 + (4*a4 + 5*a5.*Rtxm).*Rtxm).*Rtxm).*Rtxm ...
+ ft68.*(b1 + (2*b2 + (3*b3 + (4*b4 + 5*b5.*Rtxm).*Rtxm).*Rtxm).*Rtxm);
if any(SP_est < 2)
[I2] = find(SP_est < 2);
x = 400.*(Rtxm(I2).*Rtxm(I2));
sqrty = 10.*Rtxm(I2);
part1 = 1 + x.*(1.5 + x) ;
part2 = 1 + sqrty.*(1 + sqrty.*(1 + sqrty));
dSP_dRtx(I2) = dSP_dRtx(I2)...
+ a0.*800.*Rtxm(I2).*(1.5 + 2*x)./(part1.*part1)...
+ b0.*ft68(I2).*(10 + sqrty.*(20 + 30.*sqrty))./(part2.*part2);
Hill_ratio = gsw_Hill_ratio_at_SP2(t(I2));
dSP_dRtx(I2) = Hill_ratio.*dSP_dRtx(I2);
end
%--------------------------------------------------------------------------
% The line below is where Rtx is updated at the end of the one full
% iteration of the modified Newton-Raphson technique.
%--------------------------------------------------------------------------
Rtx = Rtx_old - (SP_est - SP)./dSP_dRtx;
%--------------------------------------------------------------------------
% Now we do another half iteration of the modified Newton-Raphson
% technique, making a total of one and a half modified N-R iterations.
%--------------------------------------------------------------------------
SP_est = a0 + (a1 + (a2 + (a3 + (a4 + a5.*Rtx).*Rtx).*Rtx).*Rtx).*Rtx ...
+ ft68.*(b0 + (b1 + (b2+ (b3 + (b4 + b5.*Rtx).*Rtx).*Rtx).*Rtx).*Rtx);
if any(SP_est < 2)
[I2] = find(SP_est < 2);
x = 400.*(Rtx(I2).*Rtx(I2));
sqrty = 10.*Rtx(I2);
part1 = 1 + x.*(1.5 + x) ;
part2 = 1 + sqrty.*(1 + sqrty.*(1 + sqrty));
SP_Hill_raw = SP_est(I2) - a0./part1 - b0.*ft68(I2)./part2;
Hill_ratio = gsw_Hill_ratio_at_SP2(t(I2));
SP_est(I2) = Hill_ratio.*SP_Hill_raw;
end
Rtx = Rtx - (SP_est - SP)./dSP_dRtx;
%--------------------------------------------------------------------------
% The following lines of code are commented out, but when activated, return
% the error, SP_error, in Rtx (in terms of psu).
%
% SP_est = a0 + (a1 + (a2 + (a3 + (a4 + a5.*Rtx).*Rtx).*Rtx).*Rtx).*Rtx ...
% + ft68.*(b0 + (b1 + (b2+ (b3 + (b4 + b5.*Rtx).*Rtx).*Rtx).*Rtx).*Rtx);
% if any(SP_est < 2)
% [I2] = find(SP_est < 2);
% x = 400.*(Rtx(I2).*Rtx(I2));
% sqrty = 10.*Rtx(I2);
% part1 = 1 + x.*(1.5 + x) ;
% part2 = 1 + sqrty.*(1 + sqrty.*(1 + sqrty));
% SP_Hill_raw = SP_est(I2) - a0./part1 - b0.*ft68(I2)./part2;
% Hill_ratio = gsw_Hill_ratio_at_SP2(t(I2));
% SP_est(I2) = Hill_ratio.*SP_Hill_raw;
% end
%
% SP_error = abs(SP - SP_est);
%
%--------------This is the end of the error testing------------------------
%--------------------------------------------------------------------------
% Now go from Rtx to Rt and then to the conductivity ratio R at pressure p.
%--------------------------------------------------------------------------
Rt = Rtx.*Rtx;
A = d3 + d4.*t68;
B = 1 + d1.*t68 + d2.*t68.^2;
C = p.*(e1 + e2.*p + e3.*p.^2);
% rt_lc (i.e. rt_lower_case) corresponds to rt as defined in
% the UNESCO 44 (1983) routines.
rt_lc = c0 + (c1 + (c2 + (c3 + c4.*t68).*t68).*t68).*t68;
D = B - A.*rt_lc.*Rt;
E = rt_lc.*Rt.*A.*(B + C);
Ra = sqrt(D.^2 + 4*E) - D;
R = 0.5*Ra./A;
% The dimensionless conductivity ratio, R, is the conductivity input, C,
% divided by the present estimate of C(SP=35, t_68=15, p=0) which is
% 42.9140 mS/cm (=4.29140 S/m^).
C = 42.9140.*R;
if transposed
C = C.';
end
end