Check and fix all constants and units compare to MetPy results

This commit is contained in:
arofarn 2021-06-28 17:55:09 +02:00
parent adaf8b11b9
commit c1f55485ad
2 changed files with 55 additions and 40 deletions

14
tests/metpy_simpletest.py Normal file
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@ -0,0 +1,14 @@
# SPDX-FileCopyrightText: 2017 Scott Shawcroft, written for Adafruit Industries
# SPDX-FileCopyrightText: Copyright (c) 2021 Arofarn
#
# SPDX-License-Identifier: BSD-3-Clause
"""Same as umetpy_simpletest but for original MetPy module, to compare and validate results"""
import metpy.constants as mpconsts
# pylint: disable=eval-used
print("List of all constants:\n")
for cst in dir(mpconsts):
if cst[0] != "_" and cst not in ["exporter", "units"]:
print("{:30s} = {:.12f}".format(cst, eval("{}.{}".format("mpconsts", cst))))

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@ -71,10 +71,9 @@ molecular_weight_ratio :math:`\epsilon` epsilon :math:`\text{None}`
.. [7] [WMO1966]_
.. [8] [Picard2008]_
""" # noqa: E501
# pylint: enable=line-too-long
# pylint: disable=invalid-name
from .package_tools import Exporter
exporter = Exporter(globals())
@ -82,53 +81,55 @@ exporter = Exporter(globals())
# Export all the variables defined in this block
with exporter:
# Earth
earth_gravity = g = 9.80665 # 'm / s^2'
Re = earth_avg_radius = 6371008.7714 # 'm'
G = gravitational_constant = 6.67430e-11 # 'm^3 / kg / s^2'
GM = geocentric_gravitational_constant = 3986005e8 # 'm^3 / s^2'
omega = earth_avg_angular_vel = 7292115e-11 # 'rad / s'
d = earth_sfc_avg_dist_sun = 149597870700.0 # 'm'
S = earth_solar_irradiance = 1360.8 # 'W / m^2'
delta = earth_max_declination = 23.45 # 'degrees'
earth_orbit_eccentricity = 0.0167 # 'dimensionless'
earth_mass = me = geocentric_gravitational_constant / gravitational_constant
earth_gravity = g = 9.80665 # 'm / s^2' x
Re = earth_avg_radius = 6371008.7714 # 'm' x
G = gravitational_constant = 6.67430e-11 # 'm^3 / kg / s^2' x
GM = geocentric_gravitational_constant = 3986005e8 # 'm^3 / s^2' x
omega = earth_avg_angular_vel = 7292115e-11 # 'rad / s' x
d = earth_sfc_avg_dist_sun = 149597870700.0 # 'm' x
S = earth_solar_irradiance = 1360.8 # 'W / m^2' x
delta = earth_max_declination = 23.45 # 'degrees' x
earth_orbit_eccentricity = 0.0167 # 'dimensionless' x
earth_mass = me = 5972169366075843731783680 # 'kg' x
# molar gas constant
R = 8.314462618 # 'J / mol / K'
R = 8.314462618 # 'J / mol / K' x
# Water
Mw = water_molecular_weight = 18.015268 # 'g / mol'
Rv = water_gas_constant = R / Mw
rho_l = density_water = 999.97495 # 'kg / m^3'
wv_specific_heat_ratio = 1.330 # 'dimensionless'
Cp_v = wv_specific_heat_press = (
wv_specific_heat_ratio * Rv / (wv_specific_heat_ratio - 1)
)
Cv_v = wv_specific_heat_vol = Cp_v / wv_specific_heat_ratio
Cp_l = water_specific_heat = 4.2194 # 'kJ / kg / K'
Lv = water_heat_vaporization = 2.50084e6 # 'J / kg'
Lf = water_heat_fusion = 3.337e5 # 'J / kg'
Cp_i = ice_specific_heat = 2090 # 'J / kg / K'
rho_i = density_ice = 917 # 'kg / m^3'
Mw = water_molecular_weight = 18.015268 # 'g / mol' x
Rv = water_gas_constant = 0.461523115726 # 'J / g / K' x
rho_l = density_water = 999.97495 # 'kg / m^3' x
wv_specific_heat_ratio = 1.330 # 'dimensionless' x
# Cp_v = (wv_specific_heat_ratio * Rv / (wv_specific_heat_ratio - 1))
Cp_v = wv_specific_heat_press = 1.860078011866 # 'J / g / K' x
# Cv_v = Cp_v / wv_specific_heat_ratio
Cv_v = wv_specific_heat_vol = 1.398554896140 # 'J / g / K' x
Cp_l = water_specific_heat = 4.2194 # 'kJ / kg / K' x
Lv = water_heat_vaporization = 2500840 # 'J / kg' x
Lf = water_heat_fusion = 333700.0 # 'J / kg' x
Cp_i = ice_specific_heat = 2090 # 'J / kg / K' x
rho_i = density_ice = 917 # 'kg / m^3' x
# Dry air
Md = dry_air_molecular_weight = 28.96546e-3 # 'kg / mol'
Rd = dry_air_gas_constant = R / Md
Md = dry_air_molecular_weight = 0.02896546 # 'kg / mol' x
# Rd = dry_air_gas_constant = R / Md
Rd = dry_air_gas_constant = 287.047490977185 # 'J / K / kg` x
dry_air_spec_heat_ratio = 1.4 # 'dimensionless'
Cp_d = dry_air_spec_heat_press = (
dry_air_spec_heat_ratio * Rd / (dry_air_spec_heat_ratio - 1)
)
Cv_d = dry_air_spec_heat_vol = Cp_d / dry_air_spec_heat_ratio
# TODO : check unit conversion
rho_d = dry_air_density_stp = 1000.0 / (Rd * 273.15) # 'kg / m^3'
# Cp_d = (dry_air_spec_heat_ratio * Rd / (dry_air_spec_heat_ratio - 1))
Cp_d = dry_air_spec_heat_press = 1004.666218420146 # 'J / K / kg` x
# Cv_d = dry_air_spec_heat_vol = Cp_d / dry_air_spec_heat_ratio
Cv_d = dry_air_spec_heat_vol = 717.618727442962 # 'J / K / kg` x
# rho_d = dry_air_density_stp = 1000.0 mbar / (Rd * 273.15 K)
rho_d = dry_air_density_stp = 1.275395968940 # 'kg / m^3' x
# General meteorology constants
P0 = pot_temp_ref_press = 1000.0 # 'mbar'
# TODO : check unit conversion
kappa = poisson_exponent = Rd / Cp_d # 'dimensionless'
gamma_d = dry_adiabatic_lapse_rate = g / Cp_d
# TODO : check unit conversion
epsilon = molecular_weight_ratio = Mw / Md # 'dimensionless'
P0 = pot_temp_ref_press = 1000.0 # 'mbar' x
# kappa = poisson_exponent = Rd / Cp_d
kappa = poisson_exponent = 0.285714285714 # 'dimensionless' x
# gamma_d = dry_adiabatic_lapse_rate = g / Cp_d
gamma_d = dry_adiabatic_lapse_rate = 0.009761102563 # 'K * kg * m / J / s^2' x
# epsilon = molecular_weight_ratio = Mw / Md
epsilon = molecular_weight_ratio = 0.621956910058 # 'dimensionless'
del exporter
del Exporter