# Copyright (c) 2009,2017,2018,2019 MetPy Developers.
# Distributed under the terms of the BSD 3-Clause License.
# SPDX-License-Identifier: BSD-3-Clause
"""Contains calculation of kinematic parameters (e.g. divergence or vorticity)."""
import functools
import warnings
import numpy as np
from . import coriolis_parameter
from .tools import first_derivative, gradient
from .. import constants as mpconsts
from ..cbook import iterable
from ..package_tools import Exporter
from ..units import atleast_2d, check_units, concatenate, units
from ..xarray import preprocess_xarray
exporter = Exporter(globals())
def _stack(arrs):
return concatenate([a[np.newaxis] if iterable(a) else a for a in arrs], axis=0)
def _is_x_first_dim(dim_order):
"""Determine whether x is the first dimension based on the value of dim_order."""
if dim_order is None:
dim_order = 'yx'
return dim_order == 'xy'
def _check_and_flip(arr):
"""Transpose array or list of arrays if they are 2D."""
if hasattr(arr, 'ndim'):
if arr.ndim >= 2:
return arr.T
else:
return arr
elif not isinstance(arr, str) and iterable(arr):
return tuple(_check_and_flip(a) for a in arr)
else:
return arr
def ensure_yx_order(func):
"""Wrap a function to ensure all array arguments are y, x ordered, based on kwarg."""
@functools.wraps(func)
def wrapper(*args, dim_order=None, **kwargs):
# Check what order we're given
x_first = _is_x_first_dim(dim_order)
# If x is the first dimension, flip (transpose) every array within the function args.
if x_first:
args = tuple(_check_and_flip(arr) for arr in args)
for k, v in kwargs:
kwargs[k] = _check_and_flip(v)
ret = func(*args, **kwargs)
# If we flipped on the way in, need to flip on the way out so that output array(s)
# match the dimension order of the original input.
if x_first:
return _check_and_flip(ret)
else:
return ret
# Inject a docstring for the dim_order argument into the function's docstring.
dim_order_doc = """
dim_order : str or ``None``, optional
The ordering of dimensions in passed in arrays. Can be one of ``None``, ``'xy'``,
or ``'yx'``. ``'xy'`` indicates that the dimension corresponding to x is the leading
dimension, followed by y. ``'yx'`` indicates that x is the last dimension, preceded
by y. ``None`` indicates that the default ordering should be assumed,
which is 'yx'. Can only be passed as a keyword argument, i.e.
func(..., dim_order='xy')."""
# Find the first blank line after the start of the parameters section
params = wrapper.__doc__.find('Parameters')
blank = wrapper.__doc__.find('\n\n', params)
wrapper.__doc__ = wrapper.__doc__[:blank] + dim_order_doc + wrapper.__doc__[blank:]
return wrapper
[docs]@exporter.export
@preprocess_xarray
@ensure_yx_order
@check_units('[speed]', '[speed]', '[length]', '[length]')
def vorticity(u, v, dx, dy):
r"""Calculate the vertical vorticity of the horizontal wind.
Parameters
----------
u : (M, N) `pint.Quantity`
x component of the wind
v : (M, N) `pint.Quantity`
y component of the wind
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
Returns
-------
(M, N) `pint.Quantity`
vertical vorticity
See Also
--------
divergence
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
"""
dudy = first_derivative(u, delta=dy, axis=-2)
dvdx = first_derivative(v, delta=dx, axis=-1)
return dvdx - dudy
[docs]@exporter.export
@preprocess_xarray
@ensure_yx_order
@check_units(dx='[length]', dy='[length]')
def divergence(u, v, dx, dy):
r"""Calculate the horizontal divergence of a vector.
Parameters
----------
u : (M, N) `pint.Quantity`
x component of the vector
v : (M, N) `pint.Quantity`
y component of the vector
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
Returns
-------
(M, N) `pint.Quantity`
The horizontal divergence
See Also
--------
vorticity
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
"""
dudx = first_derivative(u, delta=dx, axis=-1)
dvdy = first_derivative(v, delta=dy, axis=-2)
return dudx + dvdy
[docs]@exporter.export
@preprocess_xarray
@ensure_yx_order
def advection(scalar, wind, deltas):
r"""Calculate the advection of a scalar field by the wind.
The order of the dimensions of the arrays must match the order in which
the wind components are given. For example, if the winds are given [u, v],
then the scalar and wind arrays must be indexed as x,y (which puts x as the
rows, not columns).
Parameters
----------
scalar : N-dimensional array
Array (with N-dimensions) with the quantity to be advected.
wind : sequence of arrays
Length M sequence of N-dimensional arrays. Represents the flow,
with a component of the wind in each dimension. For example, for
horizontal advection, this could be a list: [u, v], where u and v
are each a 2-dimensional array.
deltas : sequence of float or ndarray
A (length M) sequence containing the grid spacing(s) in each dimension. If using
arrays, in each array there should be one item less than the size of `scalar` along the
applicable axis.
Returns
-------
N-dimensional array
An N-dimensional array containing the advection at all grid points.
"""
# This allows passing in a list of wind components or an array.
wind = _stack(wind)
# If we have more than one component, we need to reverse the order along the first
# dimension so that the wind components line up with the
# order of the gradients from the ..., y, x ordered array.
if wind.ndim > scalar.ndim:
wind = wind[::-1]
# Gradient returns a list of derivatives along each dimension. We convert
# this to an array with dimension as the first index. Reverse the deltas to line up
# with the order of the dimensions.
grad = _stack(gradient(scalar, deltas=deltas[::-1]))
# Make them be at least 2D (handling the 1D case) so that we can do the
# multiply and sum below
grad, wind = atleast_2d(grad, wind)
return (-grad * wind).sum(axis=0)
[docs]@exporter.export
@preprocess_xarray
@ensure_yx_order
@check_units('[temperature]', '[speed]', '[speed]', '[length]', '[length]')
def frontogenesis(thta, u, v, dx, dy, dim_order='yx'):
r"""Calculate the 2D kinematic frontogenesis of a temperature field.
The implementation is a form of the Petterssen Frontogenesis and uses the formula
outlined in [Bluestein1993]_ pg.248-253.
.. math:: F=\frac{1}{2}\left|\nabla \theta\right|[D cos(2\beta)-\delta]
* :math:`F` is 2D kinematic frontogenesis
* :math:`\theta` is potential temperature
* :math:`D` is the total deformation
* :math:`\beta` is the angle between the axis of dilitation and the isentropes
* :math:`\delta` is the divergence
Parameters
----------
thta : (M, N) `pint.Quantity`
Potential temperature
u : (M, N) `pint.Quantity`
x component of the wind
v : (M, N) `pint.Quantity`
y component of the wind
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
Returns
-------
(M, N) `pint.Quantity`
2D Frontogenesis in [temperature units]/m/s
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
Conversion factor to go from [temperature units]/m/s to [temperature units/100km/3h]
:math:`1.08e4*1.e5`
"""
# Get gradients of potential temperature in both x and y
ddy_thta = first_derivative(thta, delta=dy, axis=-2)
ddx_thta = first_derivative(thta, delta=dx, axis=-1)
# Compute the magnitude of the potential temperature gradient
mag_thta = np.sqrt(ddx_thta**2 + ddy_thta**2)
# Get the shearing, stretching, and total deformation of the wind field
shrd = shearing_deformation(u, v, dx, dy, dim_order=dim_order)
strd = stretching_deformation(u, v, dx, dy, dim_order=dim_order)
tdef = total_deformation(u, v, dx, dy, dim_order=dim_order)
# Get the divergence of the wind field
div = divergence(u, v, dx, dy, dim_order=dim_order)
# Compute the angle (beta) between the wind field and the gradient of potential temperature
psi = 0.5 * np.arctan2(shrd, strd)
beta = np.arcsin((-ddx_thta * np.cos(psi) - ddy_thta * np.sin(psi)) / mag_thta)
return 0.5 * mag_thta * (tdef * np.cos(2 * beta) - div)
[docs]@exporter.export
@preprocess_xarray
@ensure_yx_order
@check_units(f='[frequency]', dx='[length]', dy='[length]')
def geostrophic_wind(heights, f, dx, dy):
r"""Calculate the geostrophic wind given from the heights or geopotential.
Parameters
----------
heights : (M, N) `pint.Quantity`
The height field, with either leading dimensions of (x, y) or trailing dimensions
of (y, x), depending on the value of ``dim_order``.
f : array_like
The coriolis parameter. This can be a scalar to be applied
everywhere or an array of values.
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `heights` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `heights` along the applicable axis.
Returns
-------
A 2-item tuple of arrays, `pint.Quantity`
A tuple of the u-component and v-component of the geostrophic wind.
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
"""
if heights.dimensionality['[length]'] == 2.0:
norm_factor = 1. / f
else:
norm_factor = mpconsts.g / f
dhdy = first_derivative(heights, delta=dy, axis=-2)
dhdx = first_derivative(heights, delta=dx, axis=-1)
return -norm_factor * dhdy, norm_factor * dhdx
[docs]@exporter.export
@check_units(f='[frequency]', dx='[length]', dy='[length]', u='[speed]', v='[speed]')
def ageostrophic_wind(heights, f, dx, dy, u, v, dim_order='yx'):
r"""Calculate the ageostrophic wind given from the heights or geopotential.
Parameters
----------
heights : (M, N) ndarray
The height or geopotential field.
f : array_like
The coriolis parameter. This can be a scalar to be applied
everywhere or an array of values.
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `heights` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `heights` along the applicable axis.
u : (M, N) `pint.Quantity`
The u wind field.
v : (M, N) `pint.Quantity`
The u wind field.
Returns
-------
A 2-item tuple of arrays, `pint.Quantity`
A tuple of the u-component and v-component of the ageostrophic wind.
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
The order of the inputs will be changed in 1.0 to be (heights, u, v, f, dx, dy).
To updated to the new format, use `from metpy.future import ageostrophic_wind`.
"""
warnings.warn('Input variables will be reordered in 1.0 to be (heights, u, v, f, dx, dy).'
'To update to new input format before 1.0 is released, use'
'`from metpy.future import ageostrophic_wind`.', FutureWarning)
from ..future import ageostrophic_wind as _ageostrophic_wind
return _ageostrophic_wind(heights, u, v, f, dx, dy, dim_order=dim_order)
[docs]@exporter.export
@preprocess_xarray
@check_units('[length]', '[temperature]')
def montgomery_streamfunction(height, temperature):
r"""Compute the Montgomery Streamfunction on isentropic surfaces.
The Montgomery Streamfunction is the streamfunction of the geostrophic wind on an
isentropic surface. This quantity is proportional to the geostrophic wind in isentropic
coordinates, and its gradient can be interpreted similarly to the pressure gradient in
isobaric coordinates.
Parameters
----------
height : `pint.Quantity`
Array of geopotential height of isentropic surfaces
temperature : `pint.Quantity`
Array of temperature on isentropic surfaces
Returns
-------
stream_func : `pint.Quantity`
Notes
-----
The formula used is that from [Lackmann2011]_ p. 69.
.. math:: \Psi = gZ + C_pT
* :math:`\Psi` is Montgomery Streamfunction
* :math:`g` is avg. gravitational acceleration on Earth
* :math:`Z` is geopotential height of the isentropic surface
* :math:`C_p` is specific heat at constant pressure for dry air
* :math:`T` is temperature of the isentropic surface
See Also
--------
get_isentropic_pressure
"""
return (mpconsts.g * height) + (mpconsts.Cp_d * temperature)
[docs]@exporter.export
@preprocess_xarray
@check_units('[speed]', '[speed]', '[length]', '[length]', '[length]',
'[speed]', '[speed]')
def storm_relative_helicity(u, v, heights, depth, bottom=0 * units.m,
storm_u=0 * units('m/s'), storm_v=0 * units('m/s')):
# Partially adapted from similar SharpPy code
r"""Calculate storm relative helicity.
Calculates storm relatively helicity following [Markowski2010]_ 230-231.
.. math:: \int\limits_0^d (\bar v - c) \cdot \bar\omega_{h} \,dz
This is applied to the data from a hodograph with the following summation:
.. math:: \sum_{n = 1}^{N-1} [(u_{n+1} - c_{x})(v_{n} - c_{y}) -
(u_{n} - c_{x})(v_{n+1} - c_{y})]
Parameters
----------
u : array-like
u component winds
v : array-like
v component winds
heights : array-like
atmospheric heights, will be converted to AGL
depth : number
depth of the layer
bottom : number
height of layer bottom AGL (default is surface)
storm_u : number
u component of storm motion (default is 0 m/s)
storm_v : number
v component of storm motion (default is 0 m/s)
Returns
-------
`pint.Quantity`
positive storm-relative helicity
`pint.Quantity`
negative storm-relative helicity
`pint.Quantity`
total storm-relative helicity
"""
warnings.warn('Input variables will be reordered in 1.0 to be (heights, u, v, depth, '
'bottom, storm_u, storm_v). To update to new input format before 1.0 is '
'released, use `from metpy.future import storm_relative_helicity`.',
FutureWarning)
from ..future import storm_relative_helicity as _storm_relative_helicity
return _storm_relative_helicity(heights, u, v, depth,
bottom=bottom, storm_u=storm_u, storm_v=storm_v)
[docs]@exporter.export
@preprocess_xarray
@check_units('[speed]', '[speed]', '[length]', '[length]')
def absolute_vorticity(u, v, dx, dy, lats, dim_order='yx'):
"""Calculate the absolute vorticity of the horizontal wind.
Parameters
----------
u : (M, N) `pint.Quantity`
x component of the wind
v : (M, N) `pint.Quantity`
y component of the wind
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
lats : (M, N) ndarray
latitudes of the wind data in radians or with appropriate unit information attached
Returns
-------
(M, N) `pint.Quantity`
absolute vorticity
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
"""
f = coriolis_parameter(lats)
relative_vorticity = vorticity(u, v, dx, dy, dim_order=dim_order)
return relative_vorticity + f
[docs]@exporter.export
@preprocess_xarray
@check_units('[temperature]', '[pressure]', '[speed]', '[speed]',
'[length]', '[length]', '[dimensionless]')
def potential_vorticity_baroclinic(potential_temperature, pressure, u, v, dx, dy, lats):
r"""Calculate the baroclinic potential vorticity.
.. math:: PV = -g \left(\frac{\partial u}{\partial p}\frac{\partial \theta}{\partial y}
- \frac{\partial v}{\partial p}\frac{\partial \theta}{\partial x}
+ \frac{\partial \theta}{\partial p}(\zeta + f) \right)
This formula is based on equation 4.5.93 [Bluestein1993]_.
Parameters
----------
potential_temperature : (P, M, N) `pint.Quantity`
potential temperature
pressure : (P, M, N) `pint.Quantity`
vertical pressures
u : (P, M, N) `pint.Quantity`
x component of the wind
v : (P, M, N) `pint.Quantity`
y component of the wind
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
lats : (M, N) ndarray
latitudes of the wind data in radians or with appropriate unit information attached
Returns
-------
(P, M, N) `pint.Quantity`
baroclinic potential vorticity
Notes
-----
This function will only work with data that is in (P, Y, X) format. If your data
is in a different order you will need to re-order your data in order to get correct
results from this function.
The same function can be used for isobaric and isentropic PV analysis. Provide winds
for vorticity calculations on the desired isobaric or isentropic surface. At least three
layers of pressure/potential temperature are required in order to calculate the vertical
derivative (one above and below the desired surface). The first two terms will be zero if
isentropic level data is used due to the gradient of theta in both the x and y-directions
will be zero since you are on an isentropic surface.
This function expects pressure/isentropic level to increase with increasing array element
(e.g., from higher in the atmosphere to closer to the surface. If the pressure array is
one-dimensional p[:, None, None] can be used to make it appear multi-dimensional.)
"""
if ((np.shape(potential_temperature)[-3] < 3) or (np.shape(pressure)[-3] < 3)
or (np.shape(potential_temperature)[-3] != (np.shape(pressure)[-3]))):
raise ValueError('Length of potential temperature along the pressure axis '
'{} must be at least 3.'.format(-3))
avor = absolute_vorticity(u, v, dx, dy, lats, dim_order='yx')
dthtadp = first_derivative(potential_temperature, x=pressure, axis=-3)
if ((np.shape(potential_temperature)[-2] == 1)
and (np.shape(potential_temperature)[-1] == 1)):
dthtady = 0 * units.K / units.m # axis=-2 only has one dimension
dthtadx = 0 * units.K / units.m # axis=-1 only has one dimension
else:
dthtady = first_derivative(potential_temperature, delta=dy, axis=-2)
dthtadx = first_derivative(potential_temperature, delta=dx, axis=-1)
dudp = first_derivative(u, x=pressure, axis=-3)
dvdp = first_derivative(v, x=pressure, axis=-3)
return (-mpconsts.g * (dudp * dthtady - dvdp * dthtadx
+ avor * dthtadp)).to(units.kelvin * units.meter**2
/ (units.second * units.kilogram))
[docs]@exporter.export
@preprocess_xarray
@check_units('[length]', '[speed]', '[speed]', '[length]', '[length]', '[dimensionless]')
def potential_vorticity_barotropic(heights, u, v, dx, dy, lats, dim_order='yx'):
r"""Calculate the barotropic (Rossby) potential vorticity.
.. math:: PV = \frac{f + \zeta}{H}
This formula is based on equation 7.27 [Hobbs2006]_.
Parameters
----------
heights : (M, N) `pint.Quantity`
atmospheric heights
u : (M, N) `pint.Quantity`
x component of the wind
v : (M, N) `pint.Quantity`
y component of the wind
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
lats : (M, N) ndarray
latitudes of the wind data in radians or with appropriate unit information attached
Returns
-------
(M, N) `pint.Quantity`
barotropic potential vorticity
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
"""
avor = absolute_vorticity(u, v, dx, dy, lats, dim_order=dim_order)
return (avor / heights).to('meter**-1 * second**-1')
[docs]@exporter.export
@preprocess_xarray
@check_units('[speed]', '[speed]', '[speed]', '[speed]', '[length]', '[length]',
'[dimensionless]')
def inertial_advective_wind(u, v, u_geostrophic, v_geostrophic, dx, dy, lats):
r"""Calculate the inertial advective wind.
.. math:: \frac{\hat k}{f} \times (\vec V \cdot \nabla)\hat V_g
.. math:: \frac{\hat k}{f} \times \left[ \left( u \frac{\partial u_g}{\partial x} + v
\frac{\partial u_g}{\partial y} \right) \hat i + \left( u \frac{\partial v_g}
{\partial x} + v \frac{\partial v_g}{\partial y} \right) \hat j \right]
.. math:: \left[ -\frac{1}{f}\left(u \frac{\partial v_g}{\partial x} + v
\frac{\partial v_g}{\partial y} \right) \right] \hat i + \left[ \frac{1}{f}
\left( u \frac{\partial u_g}{\partial x} + v \frac{\partial u_g}{\partial y}
\right) \right] \hat j
This formula is based on equation 27 of [Rochette2006]_.
Parameters
----------
u : (M, N) `pint.Quantity`
x component of the advecting wind
v : (M, N) `pint.Quantity`
y component of the advecting wind
u_geostrophic : (M, N) `pint.Quantity`
x component of the geostrophic (advected) wind
v_geostrophic : (M, N) `pint.Quantity`
y component of the geostrophic (advected) wind
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
lats : (M, N) ndarray
latitudes of the wind data in radians or with appropriate unit information attached
Returns
-------
(M, N) `pint.Quantity`
x component of inertial advective wind
(M, N) `pint.Quantity`
y component of inertial advective wind
Notes
-----
Many forms of the inertial advective wind assume the advecting and advected
wind to both be the geostrophic wind. To do so, pass the x and y components
of the geostrophic with for u and u_geostrophic/v and v_geostrophic.
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
"""
f = coriolis_parameter(lats)
dugdy, dugdx = gradient(u_geostrophic, deltas=(dy, dx), axes=(-2, -1))
dvgdy, dvgdx = gradient(v_geostrophic, deltas=(dy, dx), axes=(-2, -1))
u_component = -(u * dvgdx + v * dvgdy) / f
v_component = (u * dugdx + v * dugdy) / f
return u_component, v_component
[docs]@exporter.export
@preprocess_xarray
@check_units('[speed]', '[speed]', '[temperature]', '[pressure]', '[length]', '[length]')
def q_vector(u, v, temperature, pressure, dx, dy, static_stability=1):
r"""Calculate Q-vector at a given pressure level using the u, v winds and temperature.
.. math:: \vec{Q} = (Q_1, Q_2)
= - \frac{R}{\sigma p}\left(
\frac{\partial \vec{v}_g}{\partial x} \cdot \nabla_p T,
\frac{\partial \vec{v}_g}{\partial y} \cdot \nabla_p T
\right)
This formula follows equation 5.7.55 from [Bluestein1992]_, and can be used with the
the below form of the quasigeostrophic omega equation to assess vertical motion
([Bluestein1992]_ equation 5.7.54):
.. math:: \left( \nabla_p^2 + \frac{f_0^2}{\sigma} \frac{\partial^2}{\partial p^2}
\right) \omega =
- 2 \nabla_p \cdot \vec{Q} -
\frac{R}{\sigma p} \beta \frac{\partial T}{\partial x}.
Parameters
----------
u : (M, N) `pint.Quantity`
x component of the wind (geostrophic in QG-theory)
v : (M, N) `pint.Quantity`
y component of the wind (geostrophic in QG-theory)
temperature : (M, N) `pint.Quantity`
Array of temperature at pressure level
pressure : `pint.Quantity`
Pressure at level
dx : `pint.Quantity`
The grid spacing(s) in the x-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
dy : `pint.Quantity`
The grid spacing(s) in the y-direction. If an array, there should be one item less than
the size of `u` along the applicable axis.
static_stability : `pint.Quantity`, optional
The static stability at the pressure level. Defaults to 1 if not given to calculate
the Q-vector without factoring in static stability.
Returns
-------
tuple of (M, N) `pint.Quantity`
The components of the Q-vector in the u- and v-directions respectively
See Also
--------
static_stability
Notes
-----
If inputs have more than two dimensions, they are assumed to have either leading dimensions
of (x, y) or trailing dimensions of (y, x), depending on the value of ``dim_order``.
"""
dudy, dudx = gradient(u, deltas=(dy, dx), axes=(-2, -1))
dvdy, dvdx = gradient(v, deltas=(dy, dx), axes=(-2, -1))
dtempdy, dtempdx = gradient(temperature, deltas=(dy, dx), axes=(-2, -1))
q1 = -mpconsts.Rd / (pressure * static_stability) * (dudx * dtempdx + dvdx * dtempdy)
q2 = -mpconsts.Rd / (pressure * static_stability) * (dudy * dtempdx + dvdy * dtempdy)
return q1.to_base_units(), q2.to_base_units()