subsurface/core/deco.c
Robert C. Helling 5b080bedde Remove option to apply GFlow at maxdepth
This option should have never been there. This is not how
gradient factors are supposed to work. It would only trick
users to use the wrong value..

Signed-off-by: Robert C. Helling <helling@atdotde.de>
2017-09-20 08:54:41 -07:00

656 lines
26 KiB
C

// SPDX-License-Identifier: GPL-2.0
/* calculate deco values
* based on Bühlmann ZHL-16b
* based on an implemention by heinrichs weikamp for the DR5
* the original file was given to Subsurface under the GPLv2
* by Matthias Heinrichs
*
* The implementation below is a fairly complete rewrite since then
* (C) Robert C. Helling 2013 and released under the GPLv2
*
* add_segment() - add <seconds> at the given pressure, breathing gasmix
* deco_allowed_depth() - ceiling based on lead tissue, surface pressure, 3m increments or smooth
* set_gf() - set Buehlmann gradient factors
* set_vpmb_conservatism() - set VPM-B conservatism value
* clear_deco()
* cache_deco_state()
* restore_deco_state()
* dump_tissues()
*/
#include <math.h>
#include <string.h>
#include "dive.h"
#include <assert.h>
#include "core/planner.h"
#include "qthelperfromc.h"
#define cube(x) (x * x * x)
// Subsurface until v4.6.2 appeared to produce marginally less conservative plans than our benchmarks.
// This factor was used to correct this. Since a fix for the saturation and desaturation rates
// was introduced in v4.6.3 this can be set to a value of 1.0 which means no correction.
#define subsurface_conservatism_factor 1.0
extern bool in_planner();
extern int plot_depth;
extern pressure_t first_ceiling_pressure;
//! Option structure for Buehlmann decompression.
struct buehlmann_config {
double satmult; //! safety at inert gas accumulation as percentage of effect (more than 100).
double desatmult; //! safety at inert gas depletion as percentage of effect (less than 100).
int last_deco_stop_in_mtr; //! depth of last_deco_stop.
double gf_high; //! gradient factor high (at surface).
double gf_low; //! gradient factor low (at bottom/start of deco calculation).
double gf_low_position_min; //! gf_low_position below surface_min_shallow.
};
struct buehlmann_config buehlmann_config = {
.satmult = 1.0,
.desatmult = 1.0,
.last_deco_stop_in_mtr = 0,
.gf_high = 0.75,
.gf_low = 0.35,
.gf_low_position_min = 1.0,
};
//! Option structure for VPM-B decompression.
struct vpmb_config {
double crit_radius_N2; //! Critical radius of N2 nucleon (microns).
double crit_radius_He; //! Critical radius of He nucleon (microns).
double crit_volume_lambda; //! Constant corresponding to critical gas volume (bar * min).
double gradient_of_imperm; //! Gradient after which bubbles become impermeable (bar).
double surface_tension_gamma; //! Nucleons surface tension constant (N / bar = m2).
double skin_compression_gammaC; //! Skin compression gammaC (N / bar = m2).
double regeneration_time; //! Time needed for the bubble to regenerate to the start radius (min).
double other_gases_pressure; //! Always present pressure of other gasses in tissues (bar).
short conservatism; //! VPM-B conservatism level (0-4)
};
struct vpmb_config vpmb_config = {
.crit_radius_N2 = 0.55,
.crit_radius_He = 0.45,
.crit_volume_lambda = 199.58,
.gradient_of_imperm = 8.30865, // = 8.2 atm
.surface_tension_gamma = 0.18137175, // = 0.0179 N/msw
.skin_compression_gammaC = 2.6040525, // = 0.257 N/msw
.regeneration_time = 20160.0,
.other_gases_pressure = 0.1359888,
.conservatism = 3
};
const double buehlmann_N2_a[] = { 1.1696, 1.0, 0.8618, 0.7562,
0.62, 0.5043, 0.441, 0.4,
0.375, 0.35, 0.3295, 0.3065,
0.2835, 0.261, 0.248, 0.2327 };
const double buehlmann_N2_b[] = { 0.5578, 0.6514, 0.7222, 0.7825,
0.8126, 0.8434, 0.8693, 0.8910,
0.9092, 0.9222, 0.9319, 0.9403,
0.9477, 0.9544, 0.9602, 0.9653 };
const double buehlmann_N2_t_halflife[] = { 5.0, 8.0, 12.5, 18.5,
27.0, 38.3, 54.3, 77.0,
109.0, 146.0, 187.0, 239.0,
305.0, 390.0, 498.0, 635.0 };
// 1 - exp(-1 / (halflife * 60) * ln(2))
const double buehlmann_N2_factor_expositon_one_second[] = {
2.30782347297664E-003, 1.44301447809736E-003, 9.23769302935806E-004, 6.24261986779007E-004,
4.27777107246730E-004, 3.01585140931371E-004, 2.12729727268379E-004, 1.50020603047807E-004,
1.05980191127841E-004, 7.91232600646508E-005, 6.17759153688224E-005, 4.83354552742732E-005,
3.78761777920511E-005, 2.96212356654113E-005, 2.31974277413727E-005, 1.81926738960225E-005
};
const double buehlmann_He_a[] = { 1.6189, 1.383, 1.1919, 1.0458,
0.922, 0.8205, 0.7305, 0.6502,
0.595, 0.5545, 0.5333, 0.5189,
0.5181, 0.5176, 0.5172, 0.5119 };
const double buehlmann_He_b[] = { 0.4770, 0.5747, 0.6527, 0.7223,
0.7582, 0.7957, 0.8279, 0.8553,
0.8757, 0.8903, 0.8997, 0.9073,
0.9122, 0.9171, 0.9217, 0.9267 };
const double buehlmann_He_t_halflife[] = { 1.88, 3.02, 4.72, 6.99,
10.21, 14.48, 20.53, 29.11,
41.20, 55.19, 70.69, 90.34,
115.29, 147.42, 188.24, 240.03 };
const double buehlmann_He_factor_expositon_one_second[] = {
6.12608039419837E-003, 3.81800836683133E-003, 2.44456078654209E-003, 1.65134647076792E-003,
1.13084424730725E-003, 7.97503165599123E-004, 5.62552521860549E-004, 3.96776399429366E-004,
2.80360036664540E-004, 2.09299583354805E-004, 1.63410794820518E-004, 1.27869320250551E-004,
1.00198406028040E-004, 7.83611475491108E-005, 6.13689891868496E-005, 4.81280465299827E-005
};
const double vpmb_conservatism_lvls[] = { 1.0, 1.05, 1.12, 1.22, 1.35 };
/* Inspired gas loading equations depend on the partial pressure of inert gas in the alveolar.
* P_alv = (P_amb - P_H2O + (1 - Rq) / Rq * P_CO2) * f
* where:
* P_alv alveolar partial pressure of inert gas
* P_amb ambient pressure
* P_H2O water vapour partial pressure = ~0.0627 bar
* P_CO2 carbon dioxide partial pressure = ~0.0534 bar
* Rq respiratory quotient (O2 consumption / CO2 production)
* f fraction of inert gas
*
* In our calculations, we simplify this to use an effective water vapour pressure
* WV = P_H20 - (1 - Rq) / Rq * P_CO2
*
* Buhlmann ignored the contribution of CO2 (i.e. Rq = 1.0), whereas Schreiner adopted Rq = 0.8.
* WV_Buhlmann = PP_H2O = 0.0627 bar
* WV_Schreiner = 0.0627 - (1 - 0.8) / Rq * 0.0534 = 0.0493 bar
* Buhlmann calculations use the Buhlmann value, VPM-B calculations use the Schreiner value.
*/
#define WV_PRESSURE 0.0627 // water vapor pressure in bar, based on respiratory quotient Rq = 1.0 (Buhlmann value)
#define WV_PRESSURE_SCHREINER 0.0493 // water vapor pressure in bar, based on respiratory quotient Rq = 0.8 (Schreiner value)
#define DECO_STOPS_MULTIPLIER_MM 3000.0
#define NITROGEN_FRACTION 0.79
struct deco_state global_deco_state;
struct deco_state *deco_state = &global_deco_state;
#define TISSUE_ARRAY_SZ sizeof(deco_state->tissue_n2_sat)
int sumx, sum1;
long sumxx;
double sumy, sumxy;
double get_crit_radius_He()
{
if (vpmb_config.conservatism <= 4)
return vpmb_config.crit_radius_He * vpmb_conservatism_lvls[vpmb_config.conservatism] * subsurface_conservatism_factor;
return vpmb_config.crit_radius_He;
}
double get_crit_radius_N2()
{
if (vpmb_config.conservatism <= 4)
return vpmb_config.crit_radius_N2 * vpmb_conservatism_lvls[vpmb_config.conservatism] * subsurface_conservatism_factor;
return vpmb_config.crit_radius_N2;
}
// Solve another cubic equation, this time
// x^3 - B x - C == 0
// Use trigonometric formula for negative discriminants (see Wikipedia for details)
double solve_cubic2(double B, double C)
{
double discriminant = 27 * C * C - 4 * cube(B);
if (discriminant < 0.0) {
return 2.0 * sqrt(B / 3.0) * cos(acos(3.0 * C * sqrt(3.0 / B) / (2.0 * B)) / 3.0);
}
double denominator = pow(9 * C + sqrt(3 * discriminant), 1 / 3.0);
return pow(2.0 / 3.0, 1.0 / 3.0) * B / denominator + denominator / pow(18.0, 1.0 / 3.0);
}
// This is a simplified formula avoiding radii. It uses the fact that Boyle's law says
// pV = (G + P_amb) / G^3 is constant to solve for the new gradient G.
double update_gradient(double next_stop_pressure, double first_gradient)
{
double B = cube(first_gradient) / (first_ceiling_pressure.mbar / 1000.0 + first_gradient);
double C = next_stop_pressure * B;
double new_gradient = solve_cubic2(B, C);
if (new_gradient < 0.0)
report_error("Negative gradient encountered!");
return new_gradient;
}
double vpmb_tolerated_ambient_pressure(double reference_pressure, int ci)
{
double n2_gradient, he_gradient, total_gradient;
if (reference_pressure >= first_ceiling_pressure.mbar / 1000.0 || !first_ceiling_pressure.mbar) {
n2_gradient = deco_state->bottom_n2_gradient[ci];
he_gradient = deco_state->bottom_he_gradient[ci];
} else {
n2_gradient = update_gradient(reference_pressure, deco_state->bottom_n2_gradient[ci]);
he_gradient = update_gradient(reference_pressure, deco_state->bottom_he_gradient[ci]);
}
total_gradient = ((n2_gradient * deco_state->tissue_n2_sat[ci]) + (he_gradient * deco_state->tissue_he_sat[ci])) / (deco_state->tissue_n2_sat[ci] + deco_state->tissue_he_sat[ci]);
return deco_state->tissue_n2_sat[ci] + deco_state->tissue_he_sat[ci] + vpmb_config.other_gases_pressure - total_gradient;
}
double tissue_tolerance_calc(const struct dive *dive, double pressure)
{
int ci = -1;
double ret_tolerance_limit_ambient_pressure = 0.0;
double gf_high = buehlmann_config.gf_high;
double gf_low = buehlmann_config.gf_low;
double surface = get_surface_pressure_in_mbar(dive, true) / 1000.0;
double lowest_ceiling = 0.0;
double tissue_lowest_ceiling[16];
for (ci = 0; ci < 16; ci++) {
deco_state->buehlmann_inertgas_a[ci] = ((buehlmann_N2_a[ci] * deco_state->tissue_n2_sat[ci]) + (buehlmann_He_a[ci] * deco_state->tissue_he_sat[ci])) / deco_state->tissue_inertgas_saturation[ci];
deco_state->buehlmann_inertgas_b[ci] = ((buehlmann_N2_b[ci] * deco_state->tissue_n2_sat[ci]) + (buehlmann_He_b[ci] * deco_state->tissue_he_sat[ci])) / deco_state->tissue_inertgas_saturation[ci];
}
if (decoMode() != VPMB) {
for (ci = 0; ci < 16; ci++) {
/* tolerated = (tissue_inertgas_saturation - buehlmann_inertgas_a) * buehlmann_inertgas_b; */
tissue_lowest_ceiling[ci] = (deco_state->buehlmann_inertgas_b[ci] * deco_state->tissue_inertgas_saturation[ci] - gf_low * deco_state->buehlmann_inertgas_a[ci] * deco_state->buehlmann_inertgas_b[ci]) /
((1.0 - deco_state->buehlmann_inertgas_b[ci]) * gf_low + deco_state->buehlmann_inertgas_b[ci]);
if (tissue_lowest_ceiling[ci] > lowest_ceiling)
lowest_ceiling = tissue_lowest_ceiling[ci];
if (lowest_ceiling > deco_state->gf_low_pressure_this_dive)
deco_state->gf_low_pressure_this_dive = lowest_ceiling;
}
for (ci = 0; ci < 16; ci++) {
double tolerated;
if ((surface / deco_state->buehlmann_inertgas_b[ci] + deco_state->buehlmann_inertgas_a[ci] - surface) * gf_high + surface <
(deco_state->gf_low_pressure_this_dive / deco_state->buehlmann_inertgas_b[ci] + deco_state->buehlmann_inertgas_a[ci] - deco_state->gf_low_pressure_this_dive) * gf_low + deco_state->gf_low_pressure_this_dive)
tolerated = (-deco_state->buehlmann_inertgas_a[ci] * deco_state->buehlmann_inertgas_b[ci] * (gf_high * deco_state->gf_low_pressure_this_dive - gf_low * surface) -
(1.0 - deco_state->buehlmann_inertgas_b[ci]) * (gf_high - gf_low) * deco_state->gf_low_pressure_this_dive * surface +
deco_state->buehlmann_inertgas_b[ci] * (deco_state->gf_low_pressure_this_dive - surface) * deco_state->tissue_inertgas_saturation[ci]) /
(-deco_state->buehlmann_inertgas_a[ci] * deco_state->buehlmann_inertgas_b[ci] * (gf_high - gf_low) +
(1.0 - deco_state->buehlmann_inertgas_b[ci]) * (gf_low * deco_state->gf_low_pressure_this_dive - gf_high * surface) +
deco_state->buehlmann_inertgas_b[ci] * (deco_state->gf_low_pressure_this_dive - surface));
else
tolerated = ret_tolerance_limit_ambient_pressure;
deco_state->tolerated_by_tissue[ci] = tolerated;
if (tolerated >= ret_tolerance_limit_ambient_pressure) {
deco_state->ci_pointing_to_guiding_tissue = ci;
ret_tolerance_limit_ambient_pressure = tolerated;
}
}
} else {
// VPM-B ceiling
double reference_pressure;
ret_tolerance_limit_ambient_pressure = pressure;
// The Boyle compensated gradient depends on ambient pressure. For the ceiling, this should set the ambient pressure.
do {
reference_pressure = ret_tolerance_limit_ambient_pressure;
ret_tolerance_limit_ambient_pressure = 0.0;
for (ci = 0; ci < 16; ci++) {
double tolerated = vpmb_tolerated_ambient_pressure(reference_pressure, ci);
if (tolerated >= ret_tolerance_limit_ambient_pressure) {
deco_state->ci_pointing_to_guiding_tissue = ci;
ret_tolerance_limit_ambient_pressure = tolerated;
}
deco_state->tolerated_by_tissue[ci] = tolerated;
}
// We are doing ok if the gradient was computed within ten centimeters of the ceiling.
} while (fabs(ret_tolerance_limit_ambient_pressure - reference_pressure) > 0.01);
if (plot_depth) {
++sum1;
sumx += plot_depth;
sumxx += plot_depth * plot_depth;
double n2_gradient, he_gradient, total_gradient;
n2_gradient = update_gradient(depth_to_bar(plot_depth, &displayed_dive), deco_state->bottom_n2_gradient[deco_state->ci_pointing_to_guiding_tissue]);
he_gradient = update_gradient(depth_to_bar(plot_depth, &displayed_dive), deco_state->bottom_he_gradient[deco_state->ci_pointing_to_guiding_tissue]);
total_gradient = ((n2_gradient * deco_state->tissue_n2_sat[deco_state->ci_pointing_to_guiding_tissue]) + (he_gradient * deco_state->tissue_he_sat[deco_state->ci_pointing_to_guiding_tissue]))
/ (deco_state->tissue_n2_sat[deco_state->ci_pointing_to_guiding_tissue] + deco_state->tissue_he_sat[deco_state->ci_pointing_to_guiding_tissue]);
double buehlmann_gradient = (1.0 / deco_state->buehlmann_inertgas_b[deco_state->ci_pointing_to_guiding_tissue] - 1.0) * depth_to_bar(plot_depth, &displayed_dive) + deco_state->buehlmann_inertgas_a[deco_state->ci_pointing_to_guiding_tissue];
double gf = (total_gradient - vpmb_config.other_gases_pressure) / buehlmann_gradient;
sumxy += gf * plot_depth;
sumy += gf;
plot_depth = 0;
}
}
return ret_tolerance_limit_ambient_pressure;
}
/*
* Return buelman factor for a particular period and tissue index.
*
* We cache the factor, since we commonly call this with the
* same values... We have a special "fixed cache" for the one second
* case, although I wonder if that's even worth it considering the
* more general-purpose cache.
*/
double factor(int period_in_seconds, int ci, enum inertgas gas)
{
double factor;
if (period_in_seconds == 1) {
if (gas == N2)
return buehlmann_N2_factor_expositon_one_second[ci];
else
return buehlmann_He_factor_expositon_one_second[ci];
}
factor = cache_value(ci, period_in_seconds, gas);
if (!factor) {
// ln(2)/60 = 1.155245301e-02
if (gas == N2)
factor = 1 - exp(-period_in_seconds * 1.155245301e-02 / buehlmann_N2_t_halflife[ci]);
else
factor = 1 - exp(-period_in_seconds * 1.155245301e-02 / buehlmann_He_t_halflife[ci]);
cache_insert(ci, period_in_seconds, gas, factor);
}
return factor;
}
double calc_surface_phase(double surface_pressure, double he_pressure, double n2_pressure, double he_time_constant, double n2_time_constant)
{
double inspired_n2 = (surface_pressure - ((in_planner() && (decoMode() == VPMB)) ? WV_PRESSURE_SCHREINER : WV_PRESSURE)) * NITROGEN_FRACTION;
if (n2_pressure > inspired_n2)
return (he_pressure / he_time_constant + (n2_pressure - inspired_n2) / n2_time_constant) / (he_pressure + n2_pressure - inspired_n2);
if (he_pressure + n2_pressure >= inspired_n2){
double gradient_decay_time = 1.0 / (n2_time_constant - he_time_constant) * log ((inspired_n2 - n2_pressure) / he_pressure);
double gradients_integral = he_pressure / he_time_constant * (1.0 - exp(-he_time_constant * gradient_decay_time)) + (n2_pressure - inspired_n2) / n2_time_constant * (1.0 - exp(-n2_time_constant * gradient_decay_time));
return gradients_integral / (he_pressure + n2_pressure - inspired_n2);
}
return 0;
}
void vpmb_start_gradient()
{
int ci;
for (ci = 0; ci < 16; ++ci) {
deco_state->initial_n2_gradient[ci] = deco_state->bottom_n2_gradient[ci] = 2.0 * (vpmb_config.surface_tension_gamma / vpmb_config.skin_compression_gammaC) * ((vpmb_config.skin_compression_gammaC - vpmb_config.surface_tension_gamma) / deco_state->n2_regen_radius[ci]);
deco_state->initial_he_gradient[ci] = deco_state->bottom_he_gradient[ci] = 2.0 * (vpmb_config.surface_tension_gamma / vpmb_config.skin_compression_gammaC) * ((vpmb_config.skin_compression_gammaC - vpmb_config.surface_tension_gamma) / deco_state->he_regen_radius[ci]);
}
}
void vpmb_next_gradient(double deco_time, double surface_pressure)
{
int ci;
double n2_b, n2_c;
double he_b, he_c;
double desat_time;
deco_time /= 60.0;
for (ci = 0; ci < 16; ++ci) {
desat_time = deco_time + calc_surface_phase(surface_pressure, deco_state->tissue_he_sat[ci], deco_state->tissue_n2_sat[ci], log(2.0) / buehlmann_He_t_halflife[ci], log(2.0) / buehlmann_N2_t_halflife[ci]);
n2_b = deco_state->initial_n2_gradient[ci] + (vpmb_config.crit_volume_lambda * vpmb_config.surface_tension_gamma) / (vpmb_config.skin_compression_gammaC * desat_time);
he_b = deco_state->initial_he_gradient[ci] + (vpmb_config.crit_volume_lambda * vpmb_config.surface_tension_gamma) / (vpmb_config.skin_compression_gammaC * desat_time);
n2_c = vpmb_config.surface_tension_gamma * vpmb_config.surface_tension_gamma * vpmb_config.crit_volume_lambda * deco_state->max_n2_crushing_pressure[ci];
n2_c = n2_c / (vpmb_config.skin_compression_gammaC * vpmb_config.skin_compression_gammaC * desat_time);
he_c = vpmb_config.surface_tension_gamma * vpmb_config.surface_tension_gamma * vpmb_config.crit_volume_lambda * deco_state->max_he_crushing_pressure[ci];
he_c = he_c / (vpmb_config.skin_compression_gammaC * vpmb_config.skin_compression_gammaC * desat_time);
deco_state->bottom_n2_gradient[ci] = 0.5 * ( n2_b + sqrt(n2_b * n2_b - 4.0 * n2_c));
deco_state->bottom_he_gradient[ci] = 0.5 * ( he_b + sqrt(he_b * he_b - 4.0 * he_c));
}
}
// A*r^3 - B*r^2 - C == 0
// Solved with the help of mathematica
double solve_cubic(double A, double B, double C)
{
double BA = B/A;
double CA = C/A;
double discriminant = CA * (4 * cube(BA) + 27 * CA);
// Let's make sure we have a real solution:
if (discriminant < 0.0) {
// This should better not happen
report_error("Complex solution for inner pressure encountered!\n A=%f\tB=%f\tC=%f\n", A, B, C);
return 0.0;
}
double denominator = pow(cube(BA) + 1.5 * (9 * CA + sqrt(3.0) * sqrt(discriminant)), 1/3.0);
return (BA + BA * BA / denominator + denominator) / 3.0;
}
void nuclear_regeneration(double time)
{
time /= 60.0;
int ci;
double crushing_radius_N2, crushing_radius_He;
for (ci = 0; ci < 16; ++ci) {
//rm
crushing_radius_N2 = 1.0 / (deco_state->max_n2_crushing_pressure[ci] / (2.0 * (vpmb_config.skin_compression_gammaC - vpmb_config.surface_tension_gamma)) + 1.0 / get_crit_radius_N2());
crushing_radius_He = 1.0 / (deco_state->max_he_crushing_pressure[ci] / (2.0 * (vpmb_config.skin_compression_gammaC - vpmb_config.surface_tension_gamma)) + 1.0 / get_crit_radius_He());
//rs
deco_state->n2_regen_radius[ci] = crushing_radius_N2 + (get_crit_radius_N2() - crushing_radius_N2) * (1.0 - exp (-time / vpmb_config.regeneration_time));
deco_state->he_regen_radius[ci] = crushing_radius_He + (get_crit_radius_He() - crushing_radius_He) * (1.0 - exp (-time / vpmb_config.regeneration_time));
}
}
// Calculates the nucleons inner pressure during the impermeable period
double calc_inner_pressure(double crit_radius, double onset_tension, double current_ambient_pressure)
{
double onset_radius = 1.0 / (vpmb_config.gradient_of_imperm / (2.0 * (vpmb_config.skin_compression_gammaC - vpmb_config.surface_tension_gamma)) + 1.0 / crit_radius);
double A = current_ambient_pressure - vpmb_config.gradient_of_imperm + (2.0 * (vpmb_config.skin_compression_gammaC - vpmb_config.surface_tension_gamma)) / onset_radius;
double B = 2.0 * (vpmb_config.skin_compression_gammaC - vpmb_config.surface_tension_gamma);
double C = onset_tension * pow(onset_radius, 3);
double current_radius = solve_cubic(A, B, C);
return onset_tension * onset_radius * onset_radius * onset_radius / (current_radius * current_radius * current_radius);
}
// Calculates the crushing pressure in the given moment. Updates crushing_onset_tension and critical radius if needed
void calc_crushing_pressure(double pressure)
{
int ci;
double gradient;
double gas_tension;
double n2_crushing_pressure, he_crushing_pressure;
double n2_inner_pressure, he_inner_pressure;
for (ci = 0; ci < 16; ++ci) {
gas_tension = deco_state->tissue_n2_sat[ci] + deco_state->tissue_he_sat[ci] + vpmb_config.other_gases_pressure;
gradient = pressure - gas_tension;
if (gradient <= vpmb_config.gradient_of_imperm) { // permeable situation
n2_crushing_pressure = he_crushing_pressure = gradient;
deco_state->crushing_onset_tension[ci] = gas_tension;
}
else { // impermeable
if (deco_state->max_ambient_pressure >= pressure)
return;
n2_inner_pressure = calc_inner_pressure(get_crit_radius_N2(), deco_state->crushing_onset_tension[ci], pressure);
he_inner_pressure = calc_inner_pressure(get_crit_radius_He(), deco_state->crushing_onset_tension[ci], pressure);
n2_crushing_pressure = pressure - n2_inner_pressure;
he_crushing_pressure = pressure - he_inner_pressure;
}
deco_state->max_n2_crushing_pressure[ci] = MAX(deco_state->max_n2_crushing_pressure[ci], n2_crushing_pressure);
deco_state->max_he_crushing_pressure[ci] = MAX(deco_state->max_he_crushing_pressure[ci], he_crushing_pressure);
}
deco_state->max_ambient_pressure = MAX(pressure, deco_state->max_ambient_pressure);
}
/* add period_in_seconds at the given pressure and gas to the deco calculation */
void add_segment(double pressure, const struct gasmix *gasmix, int period_in_seconds, int ccpo2, const struct dive *dive, int sac)
{
(void) sac;
int ci;
struct gas_pressures pressures;
fill_pressures(&pressures, pressure - ((in_planner() && (decoMode() == VPMB)) ? WV_PRESSURE_SCHREINER : WV_PRESSURE),
gasmix, (double) ccpo2 / 1000.0, dive->dc.divemode);
for (ci = 0; ci < 16; ci++) {
double pn2_oversat = pressures.n2 - deco_state->tissue_n2_sat[ci];
double phe_oversat = pressures.he - deco_state->tissue_he_sat[ci];
double n2_f = factor(period_in_seconds, ci, N2);
double he_f = factor(period_in_seconds, ci, HE);
double n2_satmult = pn2_oversat > 0 ? buehlmann_config.satmult : buehlmann_config.desatmult;
double he_satmult = phe_oversat > 0 ? buehlmann_config.satmult : buehlmann_config.desatmult;
deco_state->tissue_n2_sat[ci] += n2_satmult * pn2_oversat * n2_f;
deco_state->tissue_he_sat[ci] += he_satmult * phe_oversat * he_f;
deco_state->tissue_inertgas_saturation[ci] = deco_state->tissue_n2_sat[ci] + deco_state->tissue_he_sat[ci];
}
if(decoMode() == VPMB)
calc_crushing_pressure(pressure);
return;
}
void dump_tissues()
{
int ci;
printf("N2 tissues:");
for (ci = 0; ci < 16; ci++)
printf(" %6.3e", deco_state->tissue_n2_sat[ci]);
printf("\nHe tissues:");
for (ci = 0; ci < 16; ci++)
printf(" %6.3e", deco_state->tissue_he_sat[ci]);
printf("\n");
}
void clear_vpmb_state() {
int ci;
for (ci = 0; ci < 16; ci++) {
deco_state->max_n2_crushing_pressure[ci] = 0.0;
deco_state->max_he_crushing_pressure[ci] = 0.0;
}
deco_state->max_ambient_pressure = 0;
}
void clear_deco(double surface_pressure)
{
int ci;
clear_vpmb_state();
for (ci = 0; ci < 16; ci++) {
deco_state->tissue_n2_sat[ci] = (surface_pressure - ((in_planner() && (decoMode() == VPMB)) ? WV_PRESSURE_SCHREINER : WV_PRESSURE)) * N2_IN_AIR / 1000;
deco_state->tissue_he_sat[ci] = 0.0;
deco_state->max_n2_crushing_pressure[ci] = 0.0;
deco_state->max_he_crushing_pressure[ci] = 0.0;
deco_state->n2_regen_radius[ci] = get_crit_radius_N2();
deco_state->he_regen_radius[ci] = get_crit_radius_He();
}
deco_state->gf_low_pressure_this_dive = surface_pressure;
deco_state->gf_low_pressure_this_dive += buehlmann_config.gf_low_position_min;
deco_state->max_ambient_pressure = 0.0;
}
void cache_deco_state(struct deco_state **cached_datap)
{
struct deco_state *data = *cached_datap;
if (!data) {
data = malloc(sizeof(struct deco_state));
*cached_datap = data;
}
*data = *deco_state;
}
void restore_deco_state(struct deco_state *data, bool keep_vpmb_state)
{
if (keep_vpmb_state) {
int ci;
for (ci = 0; ci < 16; ci++) {
data->bottom_n2_gradient[ci] = deco_state->bottom_n2_gradient[ci];
data->bottom_he_gradient[ci] = deco_state->bottom_he_gradient[ci];
data->initial_n2_gradient[ci] = deco_state->initial_n2_gradient[ci];
data->initial_he_gradient[ci] = deco_state->initial_he_gradient[ci];
}
}
*deco_state = *data;
}
int deco_allowed_depth(double tissues_tolerance, double surface_pressure, struct dive *dive, bool smooth)
{
int depth;
double pressure_delta;
/* Avoid negative depths */
pressure_delta = tissues_tolerance > surface_pressure ? tissues_tolerance - surface_pressure : 0.0;
depth = rel_mbar_to_depth(lrint(pressure_delta * 1000), dive);
if (!smooth)
depth = lrint(ceil(depth / DECO_STOPS_MULTIPLIER_MM) * DECO_STOPS_MULTIPLIER_MM);
if (depth > 0 && depth < buehlmann_config.last_deco_stop_in_mtr * 1000)
depth = buehlmann_config.last_deco_stop_in_mtr * 1000;
return depth;
}
void set_gf(short gflow, short gfhigh)
{
if (gflow != -1)
buehlmann_config.gf_low = (double)gflow / 100.0;
if (gfhigh != -1)
buehlmann_config.gf_high = (double)gfhigh / 100.0;
}
void set_vpmb_conservatism(short conservatism)
{
if (conservatism < 0)
vpmb_config.conservatism = 0;
else if (conservatism > 4)
vpmb_config.conservatism = 4;
else
vpmb_config.conservatism = conservatism;
}
double get_gf(double ambpressure_bar, const struct dive *dive)
{
double surface_pressure_bar = get_surface_pressure_in_mbar(dive, true) / 1000.0;
double gf_low = buehlmann_config.gf_low;
double gf_high = buehlmann_config.gf_high;
double gf;
if (deco_state->gf_low_pressure_this_dive > surface_pressure_bar)
gf = MAX((double)gf_low, (ambpressure_bar - surface_pressure_bar) /
(deco_state->gf_low_pressure_this_dive - surface_pressure_bar) * (gf_low - gf_high) + gf_high);
else
gf = gf_low;
return gf;
}
double regressiona()
{
if (sum1 > 1) {
double avxy = sumxy / sum1;
double avx = (double)sumx / sum1;
double avy = sumy / sum1;
double avxx = (double) sumxx / sum1;
return (avxy - avx * avy) / (avxx - avx*avx);
}
else
return 0.0;
}
double regressionb()
{
if (sum1)
return sumy / sum1 - sumx * regressiona() / sum1;
else
return 0.0;
}
void reset_regression()
{
sumx = sum1 = 0;
sumxx = 0L;
sumy = sumxy = 0.0;
}