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hydro.cpp
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hydro.cpp
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/*******************
*
*
* GRATE 9
*
* Hydraulic parameters and flow routing algorithms
*
*
*
*********************/
#include "hydro.h"
#include <vector>
#include <iostream>
#include <algorithm>
#include <fstream>
#include "tinyxml2/tinyxml2.h"
#include "tinyxml2_wrapper.h"
using namespace std;
#define PI 3.14159265
#define G 9.80665
#define RHO 1000 // water density
#define Gs 1.65 // submerged specific gravity
hydro::hydro(RiverProfile *r, XMLElement *params_root)
{
preissTheta = 0.7;
hydUpw = r->hydroUpw;
regimeCounter = (r->nnodes-2);
initHydro(r->nnodes, params_root);
}
void hydro::initHydro(unsigned int nodes, XMLElement *params_root)
{
double currentCoord = 0.;
double SerialDate;
GrateTime NewDate;
vector< TS_Object > tmp;
TS_Object NewEntry;
// get hydro_series element from XML file
XMLElement *hydro_series = params_root->FirstChildElement("hydro_series");
if (hydro_series == NULL) {
throw std::string("Error getting hydro_series element from XML file");
}
// loop over all "STEP" elements in the XML file
for (XMLElement* e = hydro_series->FirstChildElement("STEP"); e != NULL; e = e->NextSiblingElement("STEP")) {
SerialDate = getDoubleValue(e, "datetime");
NewDate.setExcelTime(SerialDate);
NewEntry.date_time = NewDate;
NewEntry.Q = getDoubleValue(e, "Qw");
NewEntry.Coord = getIntValue(e, "loc");
NewEntry.GRP = 1; // this could be added to the XML file if desired...
if (NewEntry.Coord > currentCoord) { // Have we moved to a new source coordinate?
Qw.push_back( tmp );
tmp.clear();
currentCoord = NewEntry.Coord;
tmp.push_back(NewEntry); // Start new tmp
}
else {
tmp.push_back(NewEntry);
}
}
Qw.push_back( tmp ); // Final tmp loaded into Qw array
Fr2.resize(nodes);
QwCumul.resize(nodes);
bedSlope.resize(nodes);
}
void hydro::backWater(RiverProfile *r)
{
double g = 9.81;
double FrN2 = 0.8 * 0.8; // Threshold for critical flow - 0.8 (squared)
int iret = 0;
unsigned int n = 0;
bool bQuasiNormal = 0;
unsigned int lastNode = r->nnodes-1;
setQuasiSteadyNodalFlows(r);
//fullyDynamic(r);
// Divide QwCumul by Number of Channels !!
// for ( n = 0; n < r->nnodes; n++)
// {
// QwCumul[n] = QwCumul[n] / r->RiverXS[n].noChannels;
// }
// update stats for last (down-stream) node:
r->RiverXS[lastNode].xsArea(); // update area
r->RiverXS[lastNode].velocity = QwCumul[lastNode] / r->RiverXS[lastNode].flow_area[2];
r->RiverXS[lastNode].xsPerim(); // update perim
r->RiverXS[lastNode].xsCentr(); // update centr
r->RiverXS[lastNode].xsECI(r->F[lastNode]); // update eci
Fr2[lastNode] = r->RiverXS[lastNode].eci * r->RiverXS[lastNode].velocity
* r->RiverXS[lastNode].velocity / ( g * r->RiverXS[lastNode].depth );
// update bed slope array
for ( n = r->nnodes-2; n > 0 ; n-- )
bedSlope[n] = (hydUpw * ( r->eta[n-1] - r->eta[n] ) / r->dx
+ (1 - hydUpw) * ( r->eta[n] - r->eta[n+1] ) / r->dx)
/ r->RiverXS[n].chSinu; // note inclusion of sinuosity
bedSlope[0] = ( r->eta[0] - r->eta[1] ) / r->dx; // Slope at upstream/downstream nodes
bedSlope[r->nnodes-1] = ( r->eta[r->nnodes-2] - r->eta[r->nnodes-1] ) / r->dx;
// Boundary nodes: fixed or computed (default)
quasiNormal(0, r);
//quasiNormal(lastNode, r);
r->RiverXS[lastNode].depth = 0.3 * pow( QwCumul[lastNode],0.3 );
r->RiverXS[lastNode].wsl = r->eta[lastNode] + r->RiverXS[lastNode].depth;
for (unsigned int n = r->nnodes-2; n > 0 ; n--)
{
xsCritDepth( n, r, QwCumul[n] ); // Calculate critical depth
// Initial guess at depth
r->RiverXS[n].depth = 0.3 * pow( QwCumul[n], 0.3 );
// Flat profile if the bed steps up
if ( bedSlope[n] < 0 )
r->RiverXS[n].depth = r->RiverXS[n+1].depth - bedSlope[n] * r->dx;
r->RiverXS[n].xsArea(); // update area
r->RiverXS[n].velocity = QwCumul[n] / r->RiverXS[n].flow_area[2];
r->RiverXS[n].xsPerim(); // update perim
r->RiverXS[n].xsCentr(); // update centr
r->RiverXS[n].xsECI(r->F[n]); // update eci
Fr2[n] = r->RiverXS[n].eci * r->RiverXS[n].velocity *
r->RiverXS[n].velocity / ( g * r->RiverXS[n].depth );
if ( ( Fr2[n] < FrN2 ) || ( bedSlope[n] <= 0 ) || ( n == 0 ) ) // Not super-critical; use energy eqn
iret = energyConserve(n, r);
else
{ // else - recalculate using quasi-normal assumption
if (bQuasiNormal == 0)
{
iret = quasiNormal(n+1, r); // Recalculate i+1'th node <JMW 20080303>
// if ((iret > 0) || (n < (r->nnodes-3)))
// r->RiverXS[n+1].depth = r->RiverXS[n+2].depth;
}
iret = quasiNormal(n, r);
if (iret > 0)
r->RiverXS[n].depth = r->RiverXS[n+1].depth;
bQuasiNormal = 1;
};
if ( ( iret > 0 ) || ( r->RiverXS[n].depth < r->RiverXS[n].critdepth ) )
r->RiverXS[n].depth = r->RiverXS[n].critdepth;
if ( ( r->RiverXS[n].depth > 0 ) && ( bedSlope[n] > 0 ) )
r->RiverXS[n].ustar = sqrt( 9.81 * r->RiverXS[n].depth * bedSlope[n] );
else
r->RiverXS[n].ustar = 1e-3;
r->RiverXS[n].wsl = r->eta[n] + r->RiverXS[n].depth; // Update water surface level at n
};
}
void hydro::setQuasiSteadyNodalFlows(RiverProfile *r){
unsigned int j = 0;
unsigned int i = 0;
if (Qw[0][0].date_time.secsTo(r->cTime) < 1) // Start of run?
for (i = 0; i < Qw.size(); i++) // Qw.size is the # of tribs/sources
Qw_Ct.push_back( Qw[i][0].Q ); // Qw_Ct is effectively initialized, here
else
{
j = 0;
while( Qw[0][j].date_time.secsTo(r->cTime) > 0 )
j++;
for (i = 0; i < Qw.size(); i++)
{
Qw_Ct[i] = ( Qw[i][j-1].Q + ( Qw[i][j-1].date_time.secsTo(r->cTime) ) *
( Qw[i][j].Q - Qw[i][j-1].Q ) /
( Qw[i][j-1].date_time.secsTo(Qw[i][j].date_time) ));
//Qw_Ct[i] *= r->tweakArray[r->yearCounter]; // Flood = 0.8 to 1.8 mean flow
}
Qw_Ct[0] *= r->feedQw; // Feed randomizer
}
// Accumulate QwCumul Array.
QwCumul[0] = Qw_Ct[0];
i = 0;
for (j = 1; j < QwCumul.size(); j++)
{
QwCumul[j] = QwCumul[j-1];
if ( i < (Qw.size()-1) && ( r->xx[j] > Qw[i + 1][0].Coord ) )
{
i++;
QwCumul[j] += Qw_Ct[i];
}
}
}
void hydro::xsCritDepth(unsigned int n, RiverProfile *r, double Q){
// Compute critical depth, given a flow
NodeXSObject& xs = r->RiverXS[n];
int it = 0;
int itmax = 50; // Max iterations
double toler = 0.0005; // Convergence criteria
double ymin = 0.15;
double ymax = xs.bankHeight + 1.5; //
double orig_depth = xs.depth;
double dy = 0;
double y1 = 0;
double y2 = 0; // dummy variables
// Make sure ymax is subcritical (ff <= 0); keep increasing ymax until this is so.
double ff = 1;
while (ff > 0)
{
if (it > 0)
ymax *= 1.25;
xs.depth = ymax;
xs.xsArea(); // Update statistics at node
xs.xsPerim();
xs.xsCentr(); // re-calc topW
xs.xsECI(r->F[n]);
xs.velocity = Q / xs.flow_area[2];
ff = r->RiverXS[n].eci * r->RiverXS[n].velocity / ( 9.81 * xs.depth ) - 1.0;
it++;
if (it > itmax)
{
cout << "Unable to initialise max depth for critical depth calculation at xc = \n";
exit(1);
}
}
y1 = ( ymin + ymax ) / 2.; //Initial trial depth
// Solve by bisection
while (it < itmax)
{
xs.depth = y1;
xs.xsArea();
xs.xsPerim();
xs.xsCentr();
xs.xsECI(r->F[n]);
xs.velocity = Q / xs.flow_area[2];
ff = r->RiverXS[n].eci * r->RiverXS[n].velocity / ( 9.81 * r->RiverXS[n].depth ) - 1.0;
if (ff < 0)
ymax = y1;
else
ymin = y1;
y2 = ( ymin + ymax ) / 2.;
dy = y2 - y1;
if ( abs( dy / y2 ) < toler )
break;
y1 = y2;
it++;
if (it > itmax)
{
cout << "Critical depth did not converge \n";
exit(1);
}
}
//Success ... return critical depth
xs.critdepth = y2;
// Job done, return appropriate depth to XS
xs.depth =orig_depth;
xs.xsArea();
xs.xsPerim();
xs.xsCentr();
xs.xsECI(r->F[n]);
xs.velocity = Q / xs.flow_area[2];
}
int hydro::energyConserve(unsigned int n, RiverProfile *r)
{
// Energy conservation between the two nodes - using bisection algorithm
// developed by JMW --> v.3.3 energy_conserve2()
double ff; // Objective function
double h1, h2, hu2; // Straddle points in bisection
double Sf, Sf2, Sfx; // Friction slopes
double Vhd; // Velocity, velocity head at downstream node
double Vhu; // Velocity, velocity head at upstream node
int flag, iter, itermax; // Return flag, iteration counter, counter max
double error; // error during iterations
double qm, km; // Mean Qw and K (conveyance) between nodes
NodeXSObject& XSu = r->RiverXS[n]; // "upstream" cross-secction [n]--> Objective
NodeXSObject& XSd = r->RiverXS[n+1]; // "downstream" cross-section [n+1]--> already computed
flag = 0; // Function flag to be returned
itermax = 800;
XSu.xsArea(); // update area
XSu.velocity = QwCumul[n] / XSu.flow_area[2];
XSu.xsPerim(); // update perim
XSu.xsECI(r->F[n]); // update eci
//Sf2 = bedSlope[n+1]; // slope gradient between n and n+1
Vhd = XSd.eci * XSd.velocity * XSd.velocity / (2 * 9.81);
// Velocity head, downtream
//Sf2 = pow( ( QwCumul[n+1] / XSd.k_mean ), 2); // Dingman 9B2.4
Sf2 = ( QwCumul[n+1] ) * ( QwCumul[n+1] ) / ( XSd.k_mean * XSd.k_mean);
// Friction slope, downstream
h1 = r->RiverXS[n].critdepth; // Bisection: lower straddle point
h2 = max(10 * r->RiverXS[n].critdepth, (XSd.depth - bedSlope[n+1] * r->dx) * 2 ); // upper straddle point
ff = -1;
while (ff <= 0)
{
XSu.depth = h2; // Update section data based on new depth
XSu.xsArea();
XSu.velocity = QwCumul[n] / XSu.flow_area[2];
XSu.xsPerim();
XSu.xsECI(r->F[n]);
Sf = QwCumul[n] * QwCumul[n] / ( XSu.k_mean * XSu.k_mean );
Vhu = XSu.eci * XSu.velocity * XSu.velocity / (2 * 9.81);
ff = (XSu.depth + Vhu) - (XSd.depth + Vhd) + ( (bedSlope[n+1] + bedSlope[n]) / 2. - Sf) * r->dx;
h2 = 2 * XSu.depth;
}
h2 = XSu.depth;
XSu.depth = (h1 + h2) / 2;
error = 1;
iter = 0;
while (error > 5e-4)
{
XSu.xsArea(); // Update section data based on new depth
XSu.velocity = QwCumul[n] / XSu.flow_area[2];
XSu.xsPerim();
if ( XSu.depth > 0 )
XSu.xsECI(r->F[n]);
//Sf1 = Sf2; // Initial approximations
Sf = Sf2;
Vhu = XSu.eci * XSu.velocity * XSu.velocity / ( 2. * 9.81 );
if (iter > 1)
{
qm = ( QwCumul[n] + QwCumul[n+1] ) / 2.;
km = ( XSu.k_mean + XSd.k_mean) / 2.;
Sfx = qm / km;
Sf = Sfx * Sfx;
}
ff = (XSu.depth + Vhu) - (XSd.depth + Vhd) + (bedSlope[n] - Sf) * r->dx;
if (ff > 0)
h2 = XSu.depth;
else
h1 = XSu.depth;
if (h2 > XSu.critdepth)
{
hu2 = (h1 + h2) / 2.;
error = abs(hu2 - XSu.depth) / XSu.depth;
XSu.depth = hu2;
}
else
{
// Limit XSu.depth to critical depth
XSu.depth = XSu.critdepth;
break;
}
iter ++;
if (iter > itermax)
{
cout << "energy_conserve: std step backwater calculation failed to converge \n";
exit(1);
flag = 8;
}
if (XSu.depth < 0)
{
cout << "energy_conserve: negative depth results \n";
exit(1);
flag = 16;
}
}
r->RiverXS[n] = XSu;
return flag;
}
int hydro::quasiNormal(unsigned int n, RiverProfile *r){
double ff, fp; // Objective function and derivative
int iter, maxiter;
double error;
NodeXSObject& XS = r->RiverXS[n]; // Cross-section object to be calculated
NodeGSDObject& f = r->F[n];
f.norm_frac();
f.dg_and_std();
error = 1;
iter = 0;
maxiter = 900;
while ( error > 0.0001 )
{
XS.xsArea(); // Update section data based on new depth
XS.xsPerim();
XS.xsCentr();
if ( XS.depth > 0 )
XS.xsECI(f);
ff = QwCumul[n] / XS.topW - XS.depth *
sqrt( 9.81 * abs( XS.depth ) * bedSlope[n] ) / XS.omega;
fp = -2.5 * sqrt( 9.81 * abs( XS.depth ) * bedSlope[n] )
* ( 1.5 * log(11.0 * abs ( XS.depth ) / XS.rough) + 1.0 );
error = -ff / fp;
XS.depth += error / 2.;
error = abs(error / XS.depth);
++iter;
if (iter> maxiter)
{
// cout << "Iteration Count exceeded in routine quasiNormal at " << n << "\n";
return 8;
}
}
XS.xsArea(); // Update section data based on new depth
XS.xsPerim();
XS.xsCentr();
XS.xsECI(f);
return 0;
}
void hydro::fullyDynamic(RiverProfile *r){
unsigned int i, j, idx, K, iflag, iter, fadj, NNODES;
double ARI, ARIP1, KI, KIP1, BI, BIP1, ECI, ECIP1, HRI2;
double AM, DTX2, SF1, SF2, SUMM, TOL, QM, THETA, Ybc;
double DAY1, DAY2, DCDY1, DCDY2, DSDQ1, DSDQ2, DSDY1, DSDY2;
double PERI, PERIP1, HRIP12, DPDY1, DPDY2;
double TERM1, TERM2, TERM3;
double FR2T, FD_FR_MIN, FD_FR_MAX, FR2_TRIG1, FR2_TRIG2; // Trigger levels for transition to critical flow
vector<double> Q, Y, C1, C2, C2A, DF, tmp;
vector<vector<double> > EQN;
setQuasiSteadyNodalFlows(r);
Q.resize(r->nnodes);
Y.resize(r->nnodes);
C1.resize(r->nnodes); // Matrix elements, used below
C2.resize(r->nnodes);
C2A.resize(r->nnodes);
for (i = 0; i < 5; i++)
tmp.push_back(0.0);
for (i = 0; i < r->nnodes; i++){
EQN.push_back(tmp); // 5 x nnodes matrix
EQN.push_back(tmp); // this vector is 2 * NNODES in size
DF.push_back(0.0); // Solution matrix gets sent to 'matsol'
DF.push_back(0.0);
Q[i] = QwCumul[i];
Y[i] = r->eta[i] + r->RiverXS[i].depth; // W.S. Elevation
}
iflag = 0;
THETA = preissTheta; // Preissmann Weighting Coefficient
TOL = 0.001; // Tolerance for interactions
NNODES = r->nnodes;
quasiNormal(0, r);
quasiNormal(NNODES-1, r);
Ybc = r->eta[NNODES-1] + 2.2; // r->RiverXS[NNODES-1].depth; // d/s boundary condition
FD_FR_MIN = 0.8;
FD_FR_MAX = 0.9;
// COMPUTE TRANSIENT CONDITIONS C
iter = 0;
i = 0;
idx = 0;
//Variables for transitioning to critical flow by neglecting the
//spatial derivative of area part of the convective momentum term.
//FR2_TRIG1 is the trigger level, in terms of Froude No squared.
//The adjustment transitions limearly between no adjustment at FR2_TRIG1
//and full adjustment at FR2_TRIG2 where the trigger levels are
//in terms of Froude No. squared.
FR2_TRIG1 = FD_FR_MIN * FD_FR_MIN;
FR2_TRIG2 = FD_FR_MAX * FD_FR_MAX;
// GENERATE SYSTEM OF EQUATIONS C
while ( i < NNODES - 1 ) {
if (i==0){
r->RiverXS[i].xsArea();
r->RiverXS[i].velocity = Q[i] / r->RiverXS[i].flow_area[2];
r->RiverXS[i].xsPerim();
r->RiverXS[i].xsCentr();
r->RiverXS[i].xsECI(r->F[i]);
}
r->RiverXS[i+1].xsArea(); // update area, cross-section params for d/s node
r->RiverXS[i+1].velocity = Q[i+1] / r->RiverXS[i+1].flow_area[2];
r->RiverXS[i+1].xsPerim();
r->RiverXS[i+1].xsCentr();
r->RiverXS[i+1].xsECI(r->F[i+1]);
ARI = r->RiverXS[i].flow_area[2]; // Statement flow area
ARIP1 = r->RiverXS[i+1].flow_area[2];
AM = ( ARI + ARIP1 ) / 2.;
KI = r->RiverXS[i].k_mean;
KIP1 = r->RiverXS[i+1].k_mean;
ECI = r->RiverXS[i].eci;
ECIP1 = r->RiverXS[i+1].eci;
DTX2 = 2 * r->dt / r->dx;
if (i == 0) Q[i] = QwCumul[0]; // Upstream boundary condition
FR2T = ECI * r->RiverXS[i].velocity * r->RiverXS[i].velocity * r->RiverXS[i].topW / ( G * ARI );
if (FR2T >= FR2_TRIG2) fadj = 0;
else
if (FR2T <= FR2_TRIG1) fadj = 1.0;
else
fadj = ( FR2_TRIG2-FR2T ) / ( FR2_TRIG2-FR2_TRIG1 );
//if (Qw[i].Coord = i).. Conditional clause for trib inputs (not yet implemented!)
C1[i] = DTX2 * ( 1 - THETA ) * ( Q[i+1] - Q[i] ) - ARI - ARIP1;
SF1 = abs(Q[i]) * Q[i] / (KI * KI);
SF2 = abs(Q[i+1]) * Q[i+1] / (KIP1 * KIP1);
TERM1 = r->dt * (1 - THETA) * G * (ARIP1 * SF2 + ARI * SF1);
TERM2 = -( Q[i] + Q[i+1] );
TERM3 = DTX2 * ( 1 - THETA ) *
( ECIP1 * Q[i+1] * r->RiverXS[i+1].velocity - ECI * Q[i] * r->RiverXS[i].velocity +
G * fadj * ( r->RiverXS[i+1].centr - r->RiverXS[i].centr ) );
C2[i] = TERM1 + TERM2 + TERM3;
C2A[i] = -TERM2 * ( 1 - THETA );
i++;
}
SUMM = TOL + 10;
// 'Line 100'
while ( SUMM > TOL ){
i = 0;
while( i < 2 * NNODES ){ // Zero out EQN array
j = 0;
while( j < 5 ){
EQN[i][j] = 0.0;
j++;
}
i++;
}
// BOUNDARY EQUATIONS C
EQN[0][1] = 1.0;
EQN[0][4] = -( Q[0] - QwCumul[0] );
EQN[2*NNODES-1][2] = 1.0;
EQN[2*NNODES-1][4] = -( Y[NNODES-1] - Ybc );
// INTERIOR NODES
DTX2 = 2 * r->dt / r->dx;
i = 0;
while ( i < NNODES - 1 ) {
// CROSS SECTION UPDATE
if (i==0){
r->RiverXS[i].xsArea();
r->RiverXS[i].velocity = Q[i] / r->RiverXS[i].flow_area[2];
r->RiverXS[i].xsPerim();
r->RiverXS[i].xsCentr();
r->RiverXS[i].xsECI(r->F[i]);
}
r->RiverXS[i+1].xsArea(); // update area, cross-section params for d/s node
r->RiverXS[i+1].velocity = Q[i+1] / r->RiverXS[i+1].flow_area[2];
r->RiverXS[i+1].xsPerim();
r->RiverXS[i+1].xsCentr();
r->RiverXS[i+1].xsECI(r->F[i+1]);
ARI = r->RiverXS[i].flow_area[2]; // Statement flow area
ARIP1 = r->RiverXS[i+1].flow_area[2];
AM = ( ARI + ARIP1 ) / 2.;
PERI = r->RiverXS[i].flow_perim[2]; // Wetted Perimeter at node I
PERIP1 = r->RiverXS[i+1].flow_perim[2]; // Wetted Perimeter at node I+1
HRI2 = pow( r->RiverXS[i].hydRadius, 0.667 ); // Hyd Radius^0.667 at node I
HRIP12 = pow( r->RiverXS[i+1].hydRadius, 0.667 ); // Hyd Radius^0.667 at node I+1
KI = r->RiverXS[i].k_mean; // Conveyance at node I
KIP1 = r->RiverXS[i+1].k_mean; // Conveyance at node I+1
ECI = r->RiverXS[i].eci; // Energy Coefficient at node I
ECIP1 = r->RiverXS[i+1].eci; // Energy Coefficient at node I+1
BI = r->RiverXS[i].topW; // Top Width at node I
BIP1 = r->RiverXS[i+1].topW; // Top Width at node I+1
DPDY1 = r->RiverXS[i].centr; // Derivative of Wetted Perimeter wrt y at node I
DPDY2 = r->RiverXS[i+1].centr; // Derivative of Wetted Perimeter wrt y at node I+1
SF1 = abs( Q[i] ) * Q[i] / ( KI * KI );
SF2 = abs( Q[i+1]) * Q[i+1] /( KIP1 * KIP1 );
FR2T = ECI * r->RiverXS[i].velocity * r->RiverXS[i].velocity * r->RiverXS[i].topW / ( G * ARI );
if (FR2T >= FR2_TRIG2) fadj = 0;
else
if (FR2T <= FR2_TRIG1) fadj = 1.0;
else
fadj = ( FR2_TRIG2-FR2T ) / ( FR2_TRIG2-FR2_TRIG1 ); //Linearly adjust fadj factor between the trigger levels
//if (Qw[i].Coord = i).. Conditional clause for trib inputs (not yet implemented!)
K = 2 * i + 1; // EQN array Index [1,3,5..]
if ( FR2T < 0.9 ){
EQN[K][4]= -( ARI + ARIP1 + DTX2 * THETA * ( Q[i+1] - Q[i] ) + C1[i] );
//Following term modified by JMW to avoid including the
//spatial derivative of area in the gAy term.
//TERM1 = DTX2 * THETA *
// ( ( ECIP1 * Q[i+1] * Q[i+1] ) / ARIP1 + G * AM * Y[i+1]
// -( ECI * Q[i] * Q[i] ) / ARI - G * AM * Y[i]);
TERM1 = DTX2 *THETA * ( ECIP1 * Q[i+1] * r->RiverXS[i+1].velocity - ECI * Q[i] * r->RiverXS[i].velocity +
G * fadj * ( r->RiverXS[i+1].centr - r->RiverXS[i].centr ) );
TERM2 = THETA * r->dt * G * ( SF2 * ARIP1 + SF1 * ARI );
EQN[K+1][4] = -( Q[i] + Q[i+1] + TERM1 + TERM2 + C2[i] );
DAY1 = BI;
DAY2 = BIP1;
EQN[K][0] = DAY1;
EQN[K][1] = -DTX2 * THETA;
EQN[K][2] = DAY2;
EQN[K][3] = DTX2 * THETA;
//DCDY1 = DCENDY(I,D);
//DCDY2 = DCENDY(I+1,D1);
DCDY1 = ARI;
DCDY2 = ARIP1;
DSDQ1 = 2 * Q[i] / (KI * KI );
DSDQ2 = 2 * Q[i+1] / (KIP1 * KIP1 );
TERM1 = DPDY1 * ARI - DAY1 * PERI;
TERM2 = sqrt(HRI2) * ARI * ARI;
DSDY1 = Q[i] * abs(Q[i]) / ( KI * KI ) * ( 1.333 * TERM1 / TERM2 - 2 * DAY1 / ARI / sqrt(HRI2) );
TERM1 = DPDY2 * ARIP1 - DAY2 * PERIP1;
TERM2 = sqrt(HRIP12) * ARIP1 * ARIP1;
DSDY2 = Q[i+1] * abs( Q[i+1] ) / ( KIP1 * KIP1 ) *
( 1.333 * TERM1 / TERM2 - 2 * DAY2 / ARIP1 / sqrt(HRIP12) );
TERM1 = DTX2 * THETA * ( ECI * abs(r->RiverXS[i].velocity) * r->RiverXS[i].velocity
* DAY1 - G * DCDY1 );
TERM2 = G * r->dt * THETA * SF1 * DAY1;
EQN[K+1][0] = TERM1 + TERM2 + G * r->dt * THETA * ARI * DSDY1;
EQN[K+1][1] = 1.0 - DTX2 * THETA * 2 * ECI * Q[i] / ARI + G * r->dt * THETA * ARI * DSDQ1;
TERM1 = -DTX2 * THETA * ( ECIP1 * r->RiverXS[i+1].velocity * abs( r->RiverXS[i+1].velocity )
* DAY2 - G * DCDY2 );
TERM2 = G * r->dt * G * SF2 * DAY2;
EQN[K+1][2] = TERM1 + TERM2 + THETA * r->dt * G * ARIP1 * DSDY2;
EQN[K+1][3] = 1.0 + DTX2 * THETA * 2 * ECIP1 * Q[i+1] / ARIP1 + THETA * r->dt * G * ARIP1 * DSDQ2;
}
else
{
//Special treatment, in case flow goes supercritical. In this case
//force the flow at the node to be critical depth and keep Q constant
QM = (Q[i+1]+Q[i])/2;
xsCritDepth( i, r, Q[i] ); // Calculate critical depth
EQN[K][1] = -1.0;
EQN[K][3] = 1.0;
EQN[K][4] = (Q[i]-Q[i+1]); //Force continuity of Q
EQN[K+1][0] = -1.0;
EQN[K+1][4] = (Y[i] - ( r->eta[i] + r->RiverXS[i].critdepth ) );
}
i++;
}
// SOLVE SYSTEM OF EQUATIONS
DF = matsol(NNODES, EQN);
i = 0;
SUMM = 0.0;
while (i <= 2 * NNODES - 1 ){
SUMM = abs(DF[i]) + SUMM;
idx = floor(i/2);
if((i % 2) == 0){ // Even entries in DF
Y[idx] = Y[idx] + DF[i];
r->RiverXS[idx].depth = Y[idx] - r->eta[idx];
}
else
{
Q[idx] = Q[idx] + DF[i];
QwCumul[idx] = Q[idx];
}
i++;
}
iter++;
if (iter > 1500){
cout << "Preiss1: Maximum number of iterations exceeded";
break;
}
}
}
vector<double> hydro::matsol(int N, vector<vector<double> > A){
int i, j, k, inode, M;
double t1, t2, t3, t4, d;
vector<double> X, C;
for (i = 0; i < N * 2; i++){ // Initialize C array
C.push_back(0.0);
X.push_back(0.0);
}
//Perform first sweep
C[0] = 0.0;
C[1] = A[0][4];
for (inode = 0; inode < N - 1; inode++){
j = 2 * inode + 1;
k = j + 1;
t1 = A[j][0] + A[j][1] * C[k-2];
t2 = A[j+1][0] + A[j+1][1] * C[k-2];
t3 = A[j+1][4] - A[j+1][1] * C[k-1];
t4 = A[j][4] - A[j][1] * C[k-1];
d = t1 * A[j+1][3] - t2 * A[j][3];
if( abs(d) <= 1E-08 )
cout << "SINGULAR MATRIX --> NO UNIQUE SOLUTION EXISTS";
C[k] = ( -t1 * A[j+1][2] + t2 * A[j][2]) / d;
C[k+1] = ( t1 * t3 - t2 * t4 ) / d;
}
//Perform second sweep
M = 2 * N - 2;
X[M] = A[M+1][4];
X[M+1] = C[M] * X[M] + C[M+1];
for (inode = N - 1; inode > 0; inode--){
j = 2 * inode - 1;
k = j - 1;
t4 = A[j][4] - A[j][1] * C[k+1];
d = A[j][0] + A[j][1] * C[k];
if( abs(d) <= 1E-08 )
cout << "SINGULAR MATRIX --> NO UNIQUE SOLUTION EXISTS";
X[k] = ( t4 - ( A[j][2] * X[k+2] + A[j][3] * X[k+3] ) ) / d;
X[k+1] = C[k] * X[k] + C[k+1];
}
return X;
}
// New Routines: *********************************************************************
void hydro::regimeModel( unsigned int n, RiverProfile *r )
{
NodeXSObject& XS = r->RiverXS[n];
NodeGSDObject& f = r->F[n];
double Tol = 0.00001;
double Q = QwCumul[n] / r->RiverXS[n].noChannels;
double test_plus, test_minus = 0;
double p, p1, p2, p_upper, p_lower = 0;
double converg, gradient = 0;
double gradient_1 = 0;
double gradient_2 = 0;
double old_width = XS.width;
p = 3 * pow( Q, 0.5 );
#ifdef DEBUG_REGIME_MODEL
// DEBUGGING - not for production
std::ofstream plotf;
plotf.open("plot_regimeModel.csv");
double plotmax = p * 4;
int plotnum = 1000;
double plotstep = plotmax / static_cast<double>(plotnum);
for (int ploti = 1; ploti <= plotnum; ploti++) {
XS.width = ploti * plotstep;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r ); // Update section data [n.b. bed stress] based on new theta
XS.xsWilcockTransport(f); // Work out transport potential
test_plus = XS.Qb_cap;
plotf << XS.width << ", " << XS.Qb_cap << std::endl;
}
plotf.close();
// END DEBUGGING
#endif
XS.width = p * 1.001;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r ); // Update section data [n.b. bed stress] based on new theta
XS.xsWilcockTransport(f); // Work out transport potential
test_plus = XS.Qb_cap;
XS.width = p * 0.999;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r );
XS.xsWilcockTransport(f);
test_minus = XS.Qb_cap;
gradient_1 = test_plus - test_minus;
p1 = p;
// Now move in the direction of the gradient
if (gradient_1 > 0)
p = p + 0.25 * p;
else
p = p - 0.25 * p;
XS.width = p * 1.001;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r );
XS.xsWilcockTransport(f);
test_plus = XS.Qb_cap;
XS.width = p * 0.999;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r );
XS.xsWilcockTransport(f);
test_minus = XS.Qb_cap;
gradient_2 = test_plus - test_minus;
p2 = p;
while( gradient_1 / gradient_2 > 0 )
{
gradient_1 = gradient_2;
p1 = p;
if (gradient_2 > 0)
p = p + 0.25 * p;
else
p = p - 0.25 * p;
XS.width = p * 1.001;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r );
XS.xsWilcockTransport(f);
test_plus = XS.Qb_cap;
XS.width = p * 0.999;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r );
XS.xsWilcockTransport(f);
test_minus = XS.Qb_cap;
gradient_2 = test_plus - test_minus;
p2 = p;
}
p_upper = max( p1, p2 );
p_lower = min( p1, p2 );
p = 0.5 * ( p_upper + p_lower );
converg = ( p_upper - p_lower ) / p;
while(converg > Tol)
{
XS.width = p * 1.001;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r );
XS.xsWilcockTransport(f);
test_plus = XS.Qb_cap;
XS.width = p * 0.999;
xsCritDepth( n, r, Q ); // Calculate critical depth
findStable( n, r );
XS.xsWilcockTransport(f);
test_minus = XS.Qb_cap;
gradient = test_plus - test_minus;
if ( gradient > 0 )
p_lower = p;
else
p_upper = p;
p = 0.5 * ( p_upper + p_lower );
converg = ( p_upper - p_lower ) / p;
}
// Update reach geometry, with newly optimsed variables
// Allow no more than 2% width change per timestep
// Keep at least 10m channel width
XS.deltaW = 1 + (p - old_width) / old_width;
/* if ( n < r->nnodes - 3 ) // Change is weighted by downstream regime results (deltaW) to prevent instabilities
XS.width = max( 20., XS.width * (r->RiverXS[n+2].deltaW + r->RiverXS[n+1].deltaW + 2 * XS.deltaW) / 4 );
else
XS.width = max( 20., XS.width * XS.deltaW);
*/
// if ( XS.depth < XS.Hmax )
// XS.bankHeight = XS.Hmax; // If equilibrium depth is less than Hmax, XS is a rectangle
// else
// XS.bankHeight = XS.depth; // MAKE SURE BANKHEIGHT IS CORRECT, HERE
// Final geometry calcs
XS.width = old_width;
energyConserve(n, r); // Work out depth based on energy considerations
XS.xsArea();
XS.xsPerim();
XS.xsECI(f);
XS.xsStressTerms(f, bedSlope[n]);
xsCritDepth( n, r, Q ); // Calculate critical depth
}
void hydro::findStable( unsigned int n, RiverProfile *r )
{
// Find the stable channel shape for the specified Q and specified bank character
// Iteratively vary cross-section until tau_bank = bank_crit
NodeXSObject& XS = r->RiverXS[n];
NodeGSDObject& f = r->F[n];
// specify constants and set mu to an equivalent phi
double phi = 40;
// double mod_phi = atan( XS.mu * tan( phi * PI / 180) ) * 180 / PI;
double Tol = 0.00001;
double deltaX = 0.00001 * phi;
double tau_star = 0.020;
double D90 = pow( 2, f.d90 ) / 1000.;
double converg, bank_crit;
int iter = 0;
double b_upper = phi - deltaX; // set the upper and lower angle limits
double b_lower = deltaX;