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calculateGRDMetrics.py
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calculateGRDMetrics.py
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import time
from datetime import datetime
import model2roms
import IOstation
import clim2bry
import decimateGrid
import grd
import numpy as np
import atmosForcing
__author__ = 'Trond Kristiansen'
__email__ = '[email protected]'
__created__ = datetime(2015, 7, 7)
__modified__ = datetime(2015, 7, 7)
__version__ = "1.0"
__status__ = "Development"
doc = """ dist = greatCircle(lon1,lat1,lon2,lat2]
greatCircle: Coumputes great circle distance between to points
This function computes great circle distance between two longitude and latitude points.
The Earth is assumed to be a sphere. This approximation is valid for short distances.
On Input: Longitude is positive to the east and negative to the
west. Latitude is positive to the north and negative
to the south.
lon1 longitude point 1 [decimal degrees]
lat1 latitude point 1 [decimal degrees]
lon2 longitude point 2 [decimal degrees]
lat2 latitude point 2 [decimal degrees]
On Output:
dist great circle distance between point 1 and point 2
[meters]
Adapted from routine written by Pat J. Haley [Harvard University].
"""
def greatCircle(lon1,lat1,lon2,lat2):
#----------------------------------------------------------------------------
# Set often used parameters.
#----------------------------------------------------------------------------
radius = 6371.315
deg2rad = np.pi/180.0
rad2deg = 180.0/np.pi
#----------------------------------------------------------------------------
# Convert to radians.
#----------------------------------------------------------------------------
slon = np.multiply(lon1,deg2rad)
slat = np.multiply(lat1,deg2rad)
elon = np.multiply(lon2,deg2rad)
elat = np.multiply(lat2,deg2rad)
#----------------------------------------------------------------------------
# Compute distance along great circle [kilometers].
#----------------------------------------------------------------------------
alpha = np.multiply(np.sin(slat),np.sin(elat)) + np.cos(slat)*np.cos(elat)*np.cos(elon-slon)
alpha=np.arccos(alpha)
#km2meter=1000.
dist=np.multiply(radius,alpha)#*km2meter
return dist
def calculateGridMetrics(G, GreatCircle, decimate, startindex, endindex):
doc2 = """function [pm, pn, dndx, dmde] = grid_metrics[G, GreatCircle]
GRID_METRICS: Compute ROMS Grid horizontal metrics
[pm, pn, dndx, dmde] = grid_metrics[G, GreatCircle]
decimate is used for createing a smaller grid basedon the input data.
The new grid uses every 'decimate' point to calculate the metrics.
This function computes horizontal grid spacing metrics from
Grid NetCDF file or Grid structure G.
On Input:
G A ROMS grid structure as defined in grd.py
GreatCircle Switch indicating how to compute the grid distance:
GreatCircle = true Great-circle distance
GreatCircle = false Cartesian distance
On Output:
pm Curvilinear coordinate metric in the XI-direction
[1/meters dx = 1/pm]
pm Curvilinear coordinate metric in the ETA-direction
[1/meters dy = 1/pn]
dndx XI-derivative of inverse metric factor pn [meters],
d[pn]/d[XI]
dmde ETA-derivative of inverse metric factor pm [meters],
d[pm]/d[ETA]
If G is a Grid structure and GreatCircle=true, the following values are
needed to compute the great circle distances [G.spherical must be 1]:
G.spherical Grid spherical flag [0 | 1]
G.lon_rho RHO-points longitude [decimal degrees]
G.lat_rho RHO-points latitude [decimal degrees]
G.lon_u U-points longitude [decimal degrees]
G.lat_u U-points latitude [decimal degrees]
G.lon_v V-points longitude [decimal degrees]
G.lat_v V-points latitude [decimal degrees]
longitude: positive East, negative West
latitude: positive North, negative South
Otherwise, if G is a grid structure and GreatCircle=false, the following
values are needed to compute Cartesian distances regardless the value of
G.spherical:
G.spherical Grid spherical flag [0 | 1]
G.x_rho RHO-points X-location [meters]
G.y_rho RHO-points Y-location [meters]
G.x_u U-points X-location [meters]
G.x_u U-points Y-location [meters]
G.x_v V-points X-location [meters]
G.x_v V-points Y-location [meters]
=========================================================================%
Copyright [c] 2002-2014 The ROMS/TOMS Group %
Licensed under a MIT/X style license %
See License_ROMS.txt Hernan G. Arango %
=========================================================================%
"""
# Get Grid coordinates.
spherical = G.spherical
if (GreatCircle is True and spherical=="T"):
Xr = G.lon_rho[startindex:endindex:decimate,startindex:endindex:decimate]
Yr = G.lat_rho[startindex:endindex:decimate,startindex:endindex:decimate]
Xu = G.lon_u[startindex:endindex:decimate,startindex:endindex:decimate]
Yu = G.lat_u[startindex:endindex:decimate,startindex:endindex:decimate]
Xv = G.lon_v[startindex:endindex:decimate,startindex:endindex:decimate]
Yv = G.lat_v[startindex:endindex:decimate,startindex:endindex:decimate]
else:
Xr = G.x_rho[startindex:endindex:decimate,startindex:endindex:decimate]
Yr = G.y_rho[startindex:endindex:decimate,startindex:endindex:decimate]
Xu = G.x_u[startindex:endindex:decimate,startindex:endindex:decimate]
Yu = G.y_u[startindex:endindex:decimate,startindex:endindex:decimate]
Xv = G.x_v[startindex:endindex:decimate,startindex:endindex:decimate]
Yv = G.y_v[startindex:endindex:decimate,startindex:endindex:decimate]
#----------------------------------------------------------------------------
# Compute grid spacing [meters].
#----------------------------------------------------------------------------
Mp=len(Xr[:,0])
Lp=len(Xr[0,:])
L = Lp; Lm = L-1
M = Mp; Mm = M-1
dx = np.zeros((Mp,Lp))
dy = np.zeros((Mp,Lp))
# Compute grid spacing.
if (GreatCircle and spherical):
dx[1:M,0:Lp] = greatCircle(Xr[0:Mm,0:Lp], Yr[0:Mm,0:Lp],
Xr[1:M ,0:Lp], Yr[1:M ,0:Lp])
dx[0 ,0:Lp] = greatCircle(Xr[0 ,0:Lp], Yr[0 ,0:Lp],
Xr[1 ,0:Lp], Yr[1 ,0:Lp])
dx[-1 ,0:Lp] = greatCircle(Xr[-2 ,0:Lp], Yr[-2 ,0:Lp],
Xr[-1 ,0:Lp], Yr[-1 ,0:Lp])
dy[0:Mp,1:Lp] = greatCircle(Xr[0:Mp,0:Lm], Yr[0:Mp,0:Lm],
Xr[0:Mp,1:Lp ], Yr[0:Mp,1:Lp ])
dy[0:Mp,0 ] = greatCircle(Xr[0:Mp,0 ], Yr[0:Mp,0 ],
Xr[0:Mp,1 ], Yr[0:Mp,1 ])
dy[0:Mp,-1] = greatCircle(Xr[0:Mp,-2 ], Yr[0:Mp,-2 ],
Xr[0:Mp, -1 ], Yr[0:Mp,-1 ])
dx = dx * 1000. #great circle function computes
dy = dy * 1000. #distances in meters
# Compute inverse grid spacing metrics.
pm = 1.0/dx
pn = 1.0/dy
#----------------------------------------------------------------------------
# Compute inverse metric derivatives.
#----------------------------------------------------------------------------
dndx = np.zeros(np.shape(Xr))
dmde = np.zeros(np.shape(Xr))
dndx[1:Mp-1,1:Lp-1] = 0.5*(1.0/pn[2:Mp,1:Lp-1] - 1.0/pn[0:Mp-2,1:Lp-1])
dmde[1:Mp-1,1:Lp-1] = 0.5*(1.0/pm[1:Mp-1,2:Lp] - 1.0/pm[1:Mp-1,1:Lp-1])
return dndx,dmde,pm,pn