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orrery.py
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orrery.py
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import numpy as np
import matplotlib.pyplot as plt
from glob import glob
import os
import datetime as dt
from diverging_map import diverge_map
import matplotlib.font_manager as fm
# what KOI file to use
cd = os.path.abspath(os.path.dirname(__file__))
koilist = os.path.join(cd, 'KOI_List.txt')
#koilist = os.path.join(cd, 'KOI_List_old.txt')
# are we loading in system locations from a previous file (None if not)
lcenfile = os.path.join(cd, 'orrery_centers.txt')
#lcenfile = os.path.join(cd, 'orrery_centers_old.txt')
#lcenfile = None
# if we're not loading a centers file,
# where do we want to save the one generated (None if don't save)
#scenfile = os.path.join(cd, 'orrery_centers.txt')
scenfile = None
# add in the solar system to the plots
addsolar = True
# put it at a fixed location? otherwise use posinlist to place it
fixedpos = True
# fixed x and y positions (in AU) to place the Solar System
# if addsolar and fixedpos are True
ssx = 3.
ssy = 0.
# fraction of the way through the planet list to treat the solar system
# if fixedpos is False.
# 0 puts it first and near the center, 1 puts it last on the outside
posinlist = 0.2
# making rstart smaller or maxtry bigger takes longer but tightens the
# circle
# Radius of the circle (AU) to initially try placing a system
# when generating locations
rstart = 4.
# number of tries to randomly place a system at a given radius
# before expanding the circle
maxtry = 50
# minimum spacing between systems (AU)
spacing = 0.3
# which font to use for the text
fontfile = os.path.join(cd, 'Avenir-Black.otf')
fontfam = 'normal'
fontcol = 'white'
# font sizes at various resolutions
fszs1 = {480: 12, 720: 14, 1080: 22}
fszs2 = {480: 15, 720: 17, 1080: 27}
# background color
bkcol = 'black'
# color and alpha for the circular orbit paths
orbitcol = '#424242'
orbitalpha = 1.
# add a background to the legend to distinguish it?
legback = True
# if so, use this color and alpha
legbackcol = bkcol
legalpha = 0.7
# are we making the png files for a movie or gif
makemovie = True
# resolution of the images. Currently support 480, 720 or 1080.
reso = 1080
# output directory for the images in the movie
# (will be created if it doesn't yet exist)
#outdir = os.path.join(cd, 'orrery-40s/')
outdir = os.path.join(cd, 'movie/')
# number of frames to produce
# using ffmpeg with the palette at (sec * frames/sec)
# nframes = 40 * 20
nframes = 60 * 30
# times to evaluate the planets at
# Kepler observed from 120.5 to 1591
times = np.arange(1591 - nframes / 2., 1591, 0.5)
# setup for the custom zoom levels
inds = np.arange(len(times))
nmax = inds[-1]
zooms = np.zeros_like(times) - 1.
x0s = np.zeros_like(times) + np.nan
y0s = np.zeros_like(times) + np.nan
startx, starty = 4, 0
endx, endy = -4, 0
# what zoom level each frame is at (1. means default with everything)
"""
# zoom out once
zooms[inds < 0.25 * nmax] = 0.35
zooms[inds > 0.7 * nmax] = 1.
zooms[zooms < 0.] = np.interp(inds[zooms < 0.], inds[zooms > 0.],
zooms[zooms > 0.])
"""
# zoom out then back in
zooms[inds < 0.25 * nmax] = 0.45
x0s[inds < 0.25 * nmax] = startx
y0s[inds < 0.25 * nmax] = starty
zooms[(inds > 0.5 * nmax) & (inds < 0.6 * nmax)] = 1.
zooms[inds > 0.85 * nmax] = 0.45
x0s[inds > 0.85 * nmax] = endx
y0s[inds > 0.85 * nmax] = endy
zooms[zooms < 0.] = np.interp(inds[zooms < 0.], inds[zooms > 0.],
zooms[zooms > 0.])
x0s[~np.isfinite(x0s)] = np.interp(inds[~np.isfinite(x0s)], inds[np.isfinite(x0s)],
x0s[np.isfinite(x0s)])
y0s[~np.isfinite(y0s)] = np.interp(inds[~np.isfinite(y0s)], inds[np.isfinite(y0s)],
y0s[np.isfinite(y0s)])
# ===================================== #
# reference time for the Kepler data
time0 = dt.datetime(2009, 1, 1, 12)
# the KIC number given to the solar system
kicsolar = -5
# load in the data from the KOI list
kics, pds, it0s, radius, iteqs, semi = np.genfromtxt(
koilist, unpack=True, usecols=(1, 5, 8, 20, 26, 23), delimiter=',')
# grab the KICs with known parameters
good = (np.isfinite(semi) & np.isfinite(pds) &
np.isfinite(radius) & np.isfinite(iteqs))
kics = kics[good]
pds = pds[good]
it0s = it0s[good]
semi = semi[good]
radius = radius[good]
iteqs = iteqs[good]
# if we've already decided where to put each system, load it up
if lcenfile is not None:
multikics, xcens, ycens, maxsemis = np.loadtxt(lcenfile, unpack=True)
nplan = len(multikics)
# otherwise figure out how to fit all the planets into a nice distribution
else:
# we only want to plot multi-planet systems
multikics, nct = np.unique(kics, return_counts=True)
multikics = multikics[nct > 1]
maxsemis = multikics * 0.
nplan = len(multikics)
# the maximum size needed for each system
for ii in np.arange(len(multikics)):
maxsemis[ii] = np.max(semi[np.where(kics == multikics[ii])[0]])
# place the smallest ones first, but add noise
# so they aren't perfectly in order
inds = np.argsort(maxsemis + np.random.randn(len(maxsemis)) * 0.5)[::-1]
# place the smallest ones first, but add uniform noise
# so they aren't perfectly in order
#inds = np.argsort(maxsemis + np.random.uniform(low=-2, high=2, size=len(maxsemis)))[::-1]
# purely random order
#np.random.shuffle(inds)
# biggest ones first, small ones fill in
#bigs = np.where(maxsemis > 1.)[0]
#smalls = np.where(maxsemis <= 1.)[0]
#np.random.shuffle(smalls)
#inds = np.concatenate((bigs, smalls))
# reorder to place them
maxsemis = maxsemis[inds]
multikics = multikics[inds]
# add in the solar system if desired
if addsolar:
nplan += 1
# we know where we want the solar system to be placed, place it first
if fixedpos:
insind = 0
# otherwise treat it as any other system
# and place it at this point through the list
else:
insind = int(posinlist * len(maxsemis))
maxsemis = np.insert(maxsemis, insind, 1.524)
multikics = np.insert(multikics, insind, kicsolar)
# ratio = x extent / y extent
# what is the maximum and minimum aspect ratio of the final placement
maxratio = 16.5 / 9
minratio = 14.3 / 9
xcens = np.array([])
ycens = np.array([])
# place all the planets without overlapping or violating aspect ratio
for ii in np.arange(nplan):
# reset the counters
repeat = True
r0 = rstart * 1.
ct = 0
ratio = 1.
# progress bar
if (ii % 20) == 0:
print('Placing {0} of {1} planets'.format(ii, nplan))
# put the solar system at its fixed position if desired
if multikics[ii] == kicsolar and fixedpos:
xcens = np.concatenate((xcens, [ssx]))
ycens = np.concatenate((ycens, [ssy]))
repeat = False
else:
xcens = np.concatenate((xcens, [0.]))
ycens = np.concatenate((ycens, [0.]))
# repeat until we find an open location for this system
while repeat:
# pick a random radius (up to our limit) and angle
r = np.random.rand() * r0
theta = np.random.rand() * 2. * np.pi
xcens[ii] = r * np.cos(theta)
ycens[ii] = r * np.sin(theta)
# check what the aspect ratio would be if we place it here
xex = (xcens + maxsemis[:ii + 1]).max() - \
(xcens - maxsemis[:ii + 1]).min()
yex = (ycens + maxsemis[:ii + 1]).max() - \
(ycens - maxsemis[:ii + 1]).min()
ratio = xex / yex
# how far apart are all systems
dists = np.sqrt((xcens - xcens[ii]) ** 2. +
(ycens - ycens[ii]) ** 2.)
rsum = maxsemis + maxsemis[ii]
# systems that overlap
bad = np.where(dists < rsum[:ii + 1] + spacing)
# either the systems overlap or we've placed a lot and
# the aspect ratio isn't good enough so try again
if len(bad[0]) == 1 and (
(minratio <= ratio <= maxratio) or ii < 50):
repeat = False
# if we've been trying to place this system but can't get it
# at this radius, expand the search zone
if ct > maxtry:
ct = 0
# add equal area every time
r0 = np.sqrt(rstart ** 2. + r0 ** 2.)
ct += 1
# save this placement distribution if desired
if scenfile is not None:
np.savetxt(scenfile,
np.column_stack((multikics, xcens, ycens, maxsemis)),
fmt=['%d', '%f', '%f', '%f'])
plt.close('all')
# make a diagnostic plot showing the distribution of systems
fig = plt.figure()
plt.xlim((xcens - maxsemis).min(), (xcens + maxsemis).max())
plt.ylim((ycens - maxsemis).min(), (ycens + maxsemis).max())
plt.gca().set_aspect('equal', adjustable='box')
plt.xlabel('AU')
plt.ylabel('AU')
for ii in np.arange(nplan):
c = plt.Circle((xcens[ii], ycens[ii]), maxsemis[ii], clip_on=False,
alpha=0.3)
fig.gca().add_artist(c)
# all of the parameters we need for the plot
t0s = np.array([])
periods = np.array([])
semis = np.array([])
radii = np.array([])
teqs = np.array([])
usedkics = np.array([])
fullxcens = np.array([])
fullycens = np.array([])
for ii in np.arange(nplan):
# known solar system parameters
if addsolar and multikics[ii] == kicsolar:
usedkics = np.concatenate((usedkics, np.ones(8) * kicsolar))
# always start the outer solar system in the same places
# for optimial visibility
t0s = np.concatenate((t0s, [85., 192., 266., 180.,
times[0] - 3. * 4332.8 / 4,
times[0] - 22. / 360 * 10755.7,
times[0] - 30687 * 145. / 360,
times[0] - 60190 * 202. / 360]))
periods = np.concatenate((periods, [87.97, 224.70, 365.26, 686.98,
4332.8, 10755.7, 30687, 60190]))
semis = np.concatenate((semis, [0.387, 0.723, 1.0, 1.524, 5.203,
9.537, 19.19, 30.07]))
radii = np.concatenate((radii, [0.383, 0.95, 1.0, 0.53, 10.86, 9.00,
3.97, 3.86]))
teqs = np.concatenate((teqs, [409, 299, 255, 206, 200,
200, 200, 200]))
fullxcens = np.concatenate((fullxcens, np.zeros(8) + xcens[ii]))
fullycens = np.concatenate((fullycens, np.zeros(8) + ycens[ii]))
continue
fd = np.where(kics == multikics[ii])[0]
# get the values for this system
usedkics = np.concatenate((usedkics, kics[fd]))
t0s = np.concatenate((t0s, it0s[fd]))
periods = np.concatenate((periods, pds[fd]))
semis = np.concatenate((semis, semi[fd]))
radii = np.concatenate((radii, radius[fd]))
teqs = np.concatenate((teqs, iteqs[fd]))
fullxcens = np.concatenate((fullxcens, np.zeros(len(fd)) + xcens[ii]))
fullycens = np.concatenate((fullycens, np.zeros(len(fd)) + ycens[ii]))
# sort by radius so that the large planets are on the bottom and
# don't cover smaller planets
rs = np.argsort(radii)[::-1]
usedkics = usedkics[rs]
t0s = t0s[rs]
periods = periods[rs]
semis = semis[rs]
radii = radii[rs]
teqs = teqs[rs]
fullxcens = fullxcens[rs]
fullycens = fullycens[rs]
if makemovie:
plt.ioff()
else:
plt.ion()
# create the figure at the right size (this assumes a default pix/inch of 100)
figsizes = {480: (8.54, 4.8), 720: (8.54, 4.8), 1080: (19.2, 10.8)}
fig = plt.figure(figsize=figsizes[reso])
# make the plot cover the entire figure with the right background colors
ax = fig.add_axes([0.0, 0, 1, 1])
ax.axis('off')
fig.patch.set_facecolor(bkcol)
ax.patch.set_facecolor(bkcol)
# don't count the orbits of the outer solar system in finding figure limits
ns = np.where(usedkics != kicsolar)[0]
# this section manually makes the aspect ratio equal
# but completely fills the figure
# need this much buffer zone so that planets don't get cut off
buffsx = (fullxcens[ns].max() - fullxcens[ns].min()) * 0.007
buffsy = (fullycens[ns].max() - fullycens[ns].min()) * 0.007
# current limits of the figure
xmax = (fullxcens[ns] + semis[ns]).max() + buffsx
xmin = (fullxcens[ns] - semis[ns]).min() - buffsx
ymax = (fullycens[ns] + semis[ns]).max() + buffsy
ymin = (fullycens[ns] - semis[ns]).min() - buffsy
# figure aspect ratio
sr = 16. / 9.
# make the aspect ratio exactly right
if (xmax - xmin) / (ymax - ymin) > sr:
plt.xlim(xmin, xmax)
plt.ylim((ymax + ymin) / 2. - (xmax - xmin) / (2. * sr),
(ymax + ymin) / 2. + (xmax - xmin) / (2. * sr))
else:
plt.ylim(ymin, ymax)
plt.xlim((xmax + xmin) / 2. - (ymax - ymin) * sr / 2.,
(xmax + xmin) / 2. + (ymax - ymin) * sr / 2.)
lws = {480: 1, 720: 1, 1080: 2}
sslws = {480: 2, 720: 2, 1080: 4}
# plot the orbital circles for every planet
for ii in np.arange(len(t0s)):
# solid, thinner lines for normal planets
ls = 'solid'
zo = 0
lw = lws[reso]
# dashed, thicker ones for the solar system
if usedkics[ii] == kicsolar:
ls = 'dashed'
zo = -3
lw = sslws[reso]
c = plt.Circle((fullxcens[ii], fullycens[ii]), semis[ii], clip_on=False,
alpha=orbitalpha, fill=False,
color=orbitcol, zorder=zo, ls=ls, lw=lw)
fig.gca().add_artist(c)
# set up the planet size scale
sscales = {480: 12., 720: 30., 1080: 50.}
sscale = sscales[reso]
rearth = 1.
rnep = 3.856
rjup = 10.864
rmerc = 0.383
# for the planet size legend
solarsys = np.array([rmerc, rearth, rnep, rjup])
pnames = ['Mercury', 'Earth', 'Neptune', 'Jupiter']
csolar = np.array([409, 255, 46, 112])
# keep the smallest planets visible and the largest from being too huge
solarsys = np.clip(solarsys, 0.8, 1.3 * rjup)
solarscale = sscale * solarsys
radii = np.clip(radii, 0.8, 1.3 * rjup)
pscale = sscale * radii
# color bar temperature tick values and labels
ticks = np.array([250, 500, 750, 1000, 1250])
labs = ['250', '500', '750', '1000', '1250']
# blue and red colors for the color bar
RGB1 = np.array([1, 185, 252])
RGB2 = np.array([220, 55, 19])
# create the diverging map with a white in the center
mycmap = diverge_map(RGB1=RGB1, RGB2=RGB2, numColors=15)
# just plot the planets at time 0. for this default plot
phase = 2. * np.pi * (0. - t0s) / periods
tmp = plt.scatter(fullxcens + semis * np.cos(phase),
fullycens + semis * np.sin(phase), marker='o',
edgecolors='none', lw=0, s=pscale, c=teqs, vmin=ticks.min(),
vmax=ticks.max(), zorder=3, cmap=mycmap, clip_on=False)
fsz1 = fszs1[reso]
fsz2 = fszs2[reso]
prop = fm.FontProperties(fname=fontfile)
# create the 'Solar System' text identification
if addsolar:
loc = np.where(usedkics == kicsolar)[0][0]
plt.text(fullxcens[loc], fullycens[loc], 'Solar\nSystem', zorder=-2,
color=fontcol, family=fontfam, fontproperties=prop, fontsize=fsz1,
horizontalalignment='center', verticalalignment='center')
# if we're putting in a translucent background behind the text
# to make it easier to read
if legback:
box1starts = {480: (0., 0.445), 720: (0., 0.46), 1080: (0., 0.47)}
box1widths = {480: 0.19, 720: 0.147, 1080: 0.153}
box1heights = {480: 0.555, 720: 0.54, 1080: 0.53}
box2starts = {480: (0.79, 0.8), 720: (0.83, 0.84), 1080: (0.83, 0.84)}
box2widths = {480: 0.21, 720: 0.17, 1080: 0.17}
box2heights = {480: 0.2, 720: 0.16, 1080: 0.16}
# create the rectangles at the right heights and widths
# based on the resolution
c = plt.Rectangle(box1starts[reso], box1widths[reso], box1heights[reso],
alpha=legalpha, fc=legbackcol, ec='none', zorder=4,
transform=ax.transAxes)
d = plt.Rectangle(box2starts[reso], box2widths[reso], box2heights[reso],
alpha=legalpha, fc=legbackcol, ec='none', zorder=4,
transform=ax.transAxes)
ax.add_artist(c)
ax.add_artist(d)
# appropriate spacing from the left edge for the color bar
cbxoffs = {480: 0.09, 720: 0.07, 1080: 0.074}
cbxoff = cbxoffs[reso]
# plot the solar system planet scale
ax.scatter(np.zeros(len(solarscale)) + cbxoff,
1. - 0.13 + 0.03 * np.arange(len(solarscale)), s=solarscale,
c=csolar, zorder=5, marker='o',
edgecolors='none', lw=0, cmap=mycmap, vmin=ticks.min(),
vmax=ticks.max(), clip_on=False, transform=ax.transAxes)
# put in the text labels for the solar system planet scale
for ii in np.arange(len(solarscale)):
ax.text(cbxoff + 0.01, 1. - 0.14 + 0.03 * ii,
pnames[ii], color=fontcol, family=fontfam,
fontproperties=prop, fontsize=fsz1, zorder=5,
transform=ax.transAxes)
# colorbar axis on the left centered with the planet scale
ax2 = fig.add_axes([cbxoff - 0.005, 0.54, 0.01, 0.3])
ax2.set_zorder(2)
cbar = plt.colorbar(tmp, cax=ax2, extend='both', ticks=ticks)
# remove the white/black outline around the color bar
cbar.outline.set_linewidth(0)
# allow two different tick scales
cbar.ax.minorticks_on()
# turn off tick lines and put the physical temperature scale on the left
cbar.ax.tick_params(axis='y', which='major', color=fontcol, width=2,
left=False, right=False, length=5, labelleft=True,
labelright=False, zorder=5)
# turn off tick lines and put the physical temperature approximations
# on the right
cbar.ax.tick_params(axis='y', which='minor', color=fontcol, width=2,
left=False, right=False, length=5, labelleft=False,
labelright=True, zorder=5)
# say where to put the physical temperature approximations and give them labels
cbar.ax.yaxis.set_ticks([255, 409, 730, 1200], minor=True)
cbar.ax.set_yticklabels(labs, color=fontcol, family=fontfam,
fontproperties=prop, fontsize=fsz1, zorder=5)
cbar.ax.set_yticklabels(['Earth', 'Mercury', 'Surface\nof Venus', 'Lava'],
minor=True, color=fontcol, family=fontfam,
fontproperties=prop, fontsize=fsz1)
clab = 'Planet Equilibrium\nTemperature (K)'
# add the overall label at the bottom of the color bar
cbar.ax.set_xlabel(clab, color=fontcol, family=fontfam, fontproperties=prop,
size=fsz1, zorder=5)
# switch back to the main plot
plt.sca(ax)
# upper right credit and labels text offsets
txtxoffs = {480: 0.2, 720: 0.16, 1080: 0.16}
txtyoffs1 = {480: 0.10, 720: 0.08, 1080: 0.08}
txtyoffs2 = {480: 0.18, 720: 0.144, 1080: 0.144}
txtxoff = txtxoffs[reso]
txtyoff1 = txtyoffs1[reso]
txtyoff2 = txtyoffs2[reso]
# put in the credits in the top right
text = plt.text(1. - txtxoff, 1. - txtyoff1,
time0.strftime('Kepler Orrery V\n%d %b %Y'), color=fontcol,
family=fontfam, fontproperties=prop,
fontsize=fsz2, zorder=5, transform=ax.transAxes)
plt.text(1. - txtxoff, 1. - txtyoff2, 'By Ethan Kruse\n@ethan_kruse',
color=fontcol, family=fontfam,
fontproperties=prop, fontsize=fsz1,
zorder=5, transform=ax.transAxes)
# the center of the figure
x0 = np.mean(plt.xlim())
y0 = np.mean(plt.ylim())
# width of the figure
xdiff = np.diff(plt.xlim()) / 2.
ydiff = np.diff(plt.ylim()) / 2.
# create the output directory if necessary
if makemovie and not os.path.exists(outdir):
os.mkdir(outdir)
if makemovie:
# get rid of all old png files so they don't get included in a new movie
oldfiles = glob(os.path.join(outdir, '*png'))
for delfile in oldfiles:
os.remove(delfile)
# go through all the times and make the planets move
for ii, time in enumerate(times):
# remove old planet locations and dates
tmp.remove()
text.remove()
# re-zoom to appropriate level
plt.xlim([x0s[ii] - xdiff * zooms[ii], x0s[ii] + xdiff * zooms[ii]])
plt.ylim([y0s[ii] - ydiff * zooms[ii], y0s[ii] + ydiff * zooms[ii]])
newt = time0 + dt.timedelta(time)
# put in the credits in the top right
text = plt.text(1. - txtxoff, 1. - txtyoff1,
newt.strftime('Kepler Orrery V\n%d %b %Y'),
color=fontcol, family=fontfam,
fontproperties=prop,
fontsize=fsz2, zorder=5, transform=ax.transAxes)
# put the planets in the correct location
phase = 2. * np.pi * (time - t0s) / periods
tmp = plt.scatter(fullxcens + semis * np.cos(phase),
fullycens + semis * np.sin(phase),
marker='o', edgecolors='none', lw=0, s=pscale, c=teqs,
vmin=ticks.min(), vmax=ticks.max(),
zorder=3, cmap=mycmap, clip_on=False)
fig.savefig(os.path.join(outdir, 'fig{0:04d}.png'.format(ii)),
facecolor=fig.get_facecolor(), edgecolor='none')
if not (ii % 10):
print('{0} of {1} frames'.format(ii, len(times)))