subsurface/core/gas-model.c

// SPDX-License-Identifier: GPL-2.0
/* gas-model.c */
/* gas compressibility model */
#include <stdio.h>
#include <stdlib.h>
#include "dive.h"

/* "Virial minus one" - the virial cubic form without the initial 1.0 */
#define virial_m1(C, x1, x2, x3) (C[0]*x1+C[1]*x2+C[2]*x3)

/*
 * Z = pV/nRT
 *
 * Cubic virial least-square coefficients for O2/N2/He based on data from
 *
 *    PERRY’S CHEMICAL ENGINEERS’ HANDBOOK SEVENTH EDITION
 *
 * with the lookup and curve fitting by Lubomir.
 *
 * The "virial" form of the compression factor polynomial is
 *
 *      Z = 1.0 + C[0]*P + C[1]*P^2 + C[2]*P^3 ...
 *
 * and these tables do not contain the initial 1.0 term.
 *
 * NOTE! Helium coefficients are a linear mix operation between the
 * 323K and one for 273K isotherms, to make everything be at 300K.
 */
double gas_compressibility_factor(struct gasmix *gas, double bar)
{
	static const double o2_coefficients[3] = {
		-7.18092073703e-04,
		+2.81852572808e-06,
		-1.50290620492e-09
	};
	static const double n2_coefficients[3] = {
		-2.19260353292e-04,
		+2.92844845532e-06,
		-2.07613482075e-09
	};
	static const double he_coefficients[3] = {
		+4.87320026468e-04,
		-8.83632921053e-08,
		+5.33304543646e-11
	};
	int o2, he;
	double x1, x2, x3;
	double Z;

	o2 = get_o2(gas);
	he = get_he(gas);

	x1 = bar; x2 = x1*x1; x3 = x2*x1;

	Z = virial_m1(o2_coefficients, x1, x2, x3) * o2 +
	    virial_m1(he_coefficients, x1, x2, x3) * he +
	    virial_m1(n2_coefficients, x1, x2, x3) * (1000 - o2 - he);

	/*
	 * We add the 1.0 at the very end - the linear mixing of the
	 * three 1.0 terms is still 1.0 regardless of the gas mix.
	 *
	 * The * 0.001 is because we did the linear mixing using the
	 * raw permille gas values.
	 */
	return Z * 0.001 + 1.0;
}

/* Compute the new pressure when compressing (expanding) volome v1 at pressure p1 bar to volume v2
 * taking into account the compressebility (to first order) */

double isothermal_pressure(struct gasmix *gas, double p1, int volume1, int volume2)
{
	double p_ideal = p1 * volume1 / volume2 / gas_compressibility_factor(gas, p1);

	return p_ideal * gas_compressibility_factor(gas, p_ideal);
}

inline double gas_density(struct gasmix *gas, int pressure) {
	int density =  gas->he.permille * HE_DENSITY + gas->o2.permille * O2_DENSITY + (1000 - gas->he.permille - gas->o2.permille) * N2_DENSITY;

	return density * (double) pressure / gas_compressibility_factor(gas, pressure / 1000.0) / SURFACE_PRESSURE / 1000000.0;
}
-												Add SPDX header to remaining core files

Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2017-04-27 18:24:53 +00:00
+								// SPDX-License-Identifier: GPL-2.0
-												gas model: split up gas compressibility into a file of its own

The gas compressibility is such a specialized thing that I really prefer
having it separate.

This keeps Robert's Redlich-Kwong equation as-is, but let's experiment
with other models soon...

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-02 21:49:59 +00:00
+								/* gas-model.c */
 								/* gas compressibility model */
 								#include <stdio.h>
 								#include <stdlib.h>
 								#include "dive.h"
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+								/* "Virial minus one" - the virial cubic form without the initial 1.0 */
 								#define virial_m1(C, x1, x2, x3) (C[0]*x1+C[1]*x2+C[2]*x3)
-												gas model: add polynomials for Z factors of oxygen/nitrogen/helium

.. and use a linear mix of them for arbitrary gas mixes.

For the special case of air, we continue to use the air-specific
polynomial.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-03 00:30:24 +00:00
 								/*
-												Compute and display gas density

This appears to be critical for work of breathing so it might be
worthwhile to compute. So far only in infobox.

For background, see

https://www.youtube.com/watch?v=QBajM3xmOtc

Signed-off-by: Robert C. Helling <helling@atdotde.de>

											
										
										
											2017-05-12 13:36:24 +00:00
+								 * Z = pV/nRT
 								 *
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+								 * Cubic virial least-square coefficients for O2/N2/He based on data from
-												gas model: replace Redlich-Kwong with least-square quintic

This goes back to just doing air compressibility, but using the
least-squares quintic polynomial equation that Lubomir generated based
on the Wikipedia table for air at 300K in the 1-500 bar range.

We might be able to do similar things for mixed gases..

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-02 22:11:53 +00:00
+								 *
-												gas model: simplify and improve our Z factor calculations

Lubomir found better compressibility data for the pure gases that we
need for scuba, making the air table superfluous: we get good values
from just regular linear mixing of the Oxygen, Nitrogen and Helium
calculations.

Also, rather than using a quintic polynomial, a cubic one does
sufficiently well, making for smaller code and fewer coefficients.

And judging by the reactions from people on G+ (as well as just looking
at how good the fit is with the air data), this is all the right way to
do this, and this thus removes the Redlich-Kwong equation.

All-credit-goes-to: Lubomir I. Ivanov <neolit123@gmail.com>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-03 21:57:54 +00:00
+								 *    PERRY’S CHEMICAL ENGINEERS’ HANDBOOK SEVENTH EDITION
-												gas model: add polynomials for Z factors of oxygen/nitrogen/helium

.. and use a linear mix of them for arbitrary gas mixes.

For the special case of air, we continue to use the air-specific
polynomial.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-03 00:30:24 +00:00
+								 *
-												gas model: simplify and improve our Z factor calculations

Lubomir found better compressibility data for the pure gases that we
need for scuba, making the air table superfluous: we get good values
from just regular linear mixing of the Oxygen, Nitrogen and Helium
calculations.

Also, rather than using a quintic polynomial, a cubic one does
sufficiently well, making for smaller code and fewer coefficients.

And judging by the reactions from people on G+ (as well as just looking
at how good the fit is with the air data), this is all the right way to
do this, and this thus removes the Redlich-Kwong equation.

All-credit-goes-to: Lubomir I. Ivanov <neolit123@gmail.com>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-03 21:57:54 +00:00
+								 * with the lookup and curve fitting by Lubomir.
-												gas model: add polynomials for Z factors of oxygen/nitrogen/helium

.. and use a linear mix of them for arbitrary gas mixes.

For the special case of air, we continue to use the air-specific
polynomial.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-03 00:30:24 +00:00
+								 *
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+								 * The "virial" form of the compression factor polynomial is
 								 *
 								 *      Z = 1.0 + C[0]*P + C[1]*P^2 + C[2]*P^3 ...
 								 *
 								 * and these tables do not contain the initial 1.0 term.
 								 *
-												gas model: simplify and improve our Z factor calculations

Lubomir found better compressibility data for the pure gases that we
need for scuba, making the air table superfluous: we get good values
from just regular linear mixing of the Oxygen, Nitrogen and Helium
calculations.

Also, rather than using a quintic polynomial, a cubic one does
sufficiently well, making for smaller code and fewer coefficients.

And judging by the reactions from people on G+ (as well as just looking
at how good the fit is with the air data), this is all the right way to
do this, and this thus removes the Redlich-Kwong equation.

All-credit-goes-to: Lubomir I. Ivanov <neolit123@gmail.com>
Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-03 21:57:54 +00:00
+								 * NOTE! Helium coefficients are a linear mix operation between the
 								 * 323K and one for 273K isotherms, to make everything be at 300K.
-												gas model: add polynomials for Z factors of oxygen/nitrogen/helium

.. and use a linear mix of them for arbitrary gas mixes.

For the special case of air, we continue to use the air-specific
polynomial.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-03 00:30:24 +00:00
+								 */
-												gas model: replace Redlich-Kwong with least-square quintic

This goes back to just doing air compressibility, but using the
least-squares quintic polynomial equation that Lubomir generated based
on the Wikipedia table for air at 300K in the 1-500 bar range.

We might be able to do similar things for mixed gases..

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-02 22:11:53 +00:00
+								double gas_compressibility_factor(struct gasmix *gas, double bar)
 								{
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+									static const double o2_coefficients[3] = {
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+										-7.18092073703e-04,
 										+2.81852572808e-06,
 										-1.50290620492e-09
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+									};
 									static const double n2_coefficients[3] = {
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+										-2.19260353292e-04,
 										+2.92844845532e-06,
 										-2.07613482075e-09
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+									};
 									static const double he_coefficients[3] = {
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+										+4.87320026468e-04,
 										-8.83632921053e-08,
 										+5.33304543646e-11
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+									};
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+									int o2, he;
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+									double x1, x2, x3;
 									double Z;
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+									o2 = get_o2(gas);
 									he = get_he(gas);
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
 									x1 = bar; x2 = x1*x1; x3 = x2*x1;
 									Z = virial_m1(o2_coefficients, x1, x2, x3) * o2 +
 									    virial_m1(he_coefficients, x1, x2, x3) * he +
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+									    virial_m1(n2_coefficients, x1, x2, x3) * (1000 - o2 - he);
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
 									/*
 									 * We add the 1.0 at the very end - the linear mixing of the
 									 * three 1.0 terms is still 1.0 regardless of the gas mix.
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+									 *
 									 * The * 0.001 is because we did the linear mixing using the
 									 * raw permille gas values.
-												gas model: use virial cubic polynomial form

The "virial" form of the Z compression factor is of the form

   Z = 1.0 + A*p + B*p^2 + C*p^3 + ..

and it's considered the "right" polynomial form to use.  It happens to
also make for one constant less per gas (since the 1.0 can be added
later), and can be used to simplify the expression and avoid a few
floating point operations.

However, in order for that kind of expression simplification to make
sense, we need to make sure that we don't calculate the powers of the
pressure multiple times either, and that means we have to inline all the
actual calculations.

Our compiler options still mean that the generated code isn't optimal,
but that's a separate issue. And it is a lot better than it used to be.

Being clever about this does potentially make the code a tiny bit less
legible, but maybe that's not too bad for something that we'd expect to
not ever touch once we get it right.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-04 05:30:28 +00:00
+									 */
-												gas model: update to new coefficients, and simplify expressions

This updates the gas model to use the new virial coefficients from the R
script, and simplifies the expression a tiny bit by avoiding the
division by 1000 for the gas fractions, and replacing it with a multiply
by 0.001 at the end.

The virial coefficients for Oxygen and Nitrogen changed in the last
digits due to the use of a different tool for the least-square fitting.
That also accounts for the change in format (the coefficients are not
using scientific notation).

The coefficients for Helium changed noticeably more, since they are now
based on the new least-squares fit from the raw data.

But the actual end result does not change appreciably, the main
advantage is that now the numbers are easily reproducible.

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-13 19:23:16 +00:00
+									return Z * 0.001 + 1.0;
-												gas model: replace Redlich-Kwong with least-square quintic

This goes back to just doing air compressibility, but using the
least-squares quintic polynomial equation that Lubomir generated based
on the Wikipedia table for air at 300K in the 1-500 bar range.

We might be able to do similar things for mixed gases..

Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>

											
										
										
											2016-03-02 22:11:53 +00:00
+								}
-												Use real gas compressibility in planner

Modify formluas for gas use to take into account the
compressibility correction for real gases. This introduces
also the inverse formula to compute the pressure for a given
amount of gas.

Signed-off-by: Robert C. Helling <helling@atdotde.de>

											
										
										
											2017-01-12 20:19:40 +00:00
 								/* Compute the new pressure when compressing (expanding) volome v1 at pressure p1 bar to volume v2
 								 * taking into account the compressebility (to first order) */
 								double isothermal_pressure(struct gasmix *gas, double p1, int volume1, int volume2)
 								{
 									double p_ideal = p1 * volume1 / volume2 / gas_compressibility_factor(gas, p1);
 									return p_ideal * gas_compressibility_factor(gas, p_ideal);
 								}
-												Compute and display gas density

This appears to be critical for work of breathing so it might be
worthwhile to compute. So far only in infobox.

For background, see

https://www.youtube.com/watch?v=QBajM3xmOtc

Signed-off-by: Robert C. Helling <helling@atdotde.de>

											
										
										
											2017-05-12 13:36:24 +00:00
 								inline double gas_density(struct gasmix *gas, int pressure) {
 									int density =  gas->he.permille * HE_DENSITY + gas->o2.permille * O2_DENSITY + (1000 - gas->he.permille - gas->o2.permille) * N2_DENSITY;
 									return density * (double) pressure / gas_compressibility_factor(gas, pressure / 1000.0) / SURFACE_PRESSURE / 1000000.0;
 								}