#!/usr/bin/env python3 """ MERRA iLE ========= Compute the iLE field and for atmospheric flow at time of Godzilla dust storm using MERRA-2 data which is vertically averaged over pressure surfaces ranging from 500hPa to 800hPa. """ # Author: ajarvis # Data: MERRA-2 - Global Modeling and Assimilation Office - NASA import numpy as np import matplotlib.pyplot as plt from numbacs.flows import get_interp_arrays_2D, get_callable_2D from numbacs.diagnostics import ile_2D_func # %% # Get flow data # -------------- # Load in atmospheric velocity data, dates, and coordinates. Set domain for # iLE computation, set time, and retrieve jit-callable function for velocity data. # # .. note:: # Pandas is a simpler option for storing and manipulating dates but we use # numpy here as Pandas is not a dependency. # load in atmospheric data dates = np.load("../data/merra_june2020/dates.npy") dt = (dates[1] - dates[0]).astype("timedelta64[h]").astype(int) t = np.arange(0, len(dates) * dt, dt, np.float64) lon = np.load("../data/merra_june2020/lon.npy") lat = np.load("../data/merra_june2020/lat.npy") # NumbaCS uses 'ij' indexing, most geophysical data uses 'xy' # indexing for the spatial coordintes. We need to switch axes and # scale by 3.6 since velocity data is in m/s and we want km/hr. u = np.moveaxis(np.load("../data/merra_june2020/u_500_800hPa.npy"), 1, 2) * 3.6 v = np.moveaxis(np.load("../data/merra_june2020/v_500_800hPa.npy"), 1, 2) * 3.6 nt, nx, ny = u.shape # set domain more refined domain on which iLE will be computed dx = 0.15 dy = 0.15 lonf = np.arange(-35, 25 + dx, dx) latf = np.arange(-5, 40 + dy, dy) # get interpolant arrays of velocity field grid_vel, C_eval_u, C_eval_v = get_interp_arrays_2D(t, lon, lat, u, v) # get jit-callable interpolant of velocity data vel_func = get_callable_2D(grid_vel, C_eval_u, C_eval_v, spherical=1) # set time at which iLE will be computed day = 20 t0_date = np.datetime64(f"2020-06-{day:02d}") t0 = t[np.nonzero(dates == t0_date)[0][0]] # %% # iLE # ---- # Compute iLE field from velocity data directly at time t0. ile = ile_2D_func(vel_func, lonf, latf, t0=t0, h=1e-2) # %% # Plot # ---- # Plot the results. Using the cartopy package for plotting geophysical data is # advised but it is not a dependency so we simply use matplotlib. coastlines = np.load("../data/merra_june2020/coastlines.npy") fig, ax = plt.subplots(dpi=200) ax.scatter(coastlines[:, 0], coastlines[:, 1], 1, "k", marker=".", edgecolors=None, linewidths=0) ax.contourf( lonf, latf, ile.T, levels=np.linspace(0, np.percentile(ile, 99.5), 51), extend="both", zorder=0 ) ax.set_xlim([lonf[0], lonf[-1]]) ax.set_ylim([latf[0], latf[-1]]) ax.set_aspect("equal") plt.show()