File:Capri sights.png

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Summary

DescriptionCapri sights.png	English: Map of Capri. Uses terrain data from SRTM3 (http://dds.cr.usgs.gov/srtm/version2_1/SRTM3/Eurasia/N40E014.hgt.zip). Bitmap version of File:Capri_sights_terrain.svg. Note: An offical map of Capri (with roads, etc.) can be found at http://www.capritourism.com/imgg/download/capri_map_en.pdf
Date	5 July 2006
Source	Own work
Author	Morn the Gorn compass rose from Maps_template-fr.svg: Eric Gaba (Sting - fr:Sting) Road and rail data from OpenStreetMap
Other versions	Older SVG file without terrain SVG file with terrain. Rsvg does not align the terrain correctly, so do not use this SVG directly in Wikipedia at this point!

Code

Terrain shading layer was generated with the following Python script (requires Python Imaging Library and NumPy):

# Read SRTM3 file and create shaded relief

# 2010-04-05

from struct import unpack,calcsize

from numpy import *
import numpy as np
from PIL import Image

row_length = 1201	# row_length is 1201 for SRTM3 or 3601 for SRTM1
file_name  = "N40E014.hgt"	# from http://dds.cr.usgs.gov/srtm/version2_1/SRTM3/Eurasia/
hlim       = 800	# height limit for map [m]

ref_lat    = 40.55	# reference latitude
earth_eq   = 6371. * 1000. * 2. * pi
x_scale    = 1./360.*earth_eq*cos(ref_lat/180.*pi)/row_length
y_scale    = 1./360.*earth_eq/row_length

print "1 pixel = %u * %u m" % (x_scale, y_scale)
print "factor", y_scale/x_scale

h = zeros((row_length, row_length))
f = open(file_name, 'r')
li = []

for j in range(row_length):
	for i in range(row_length):
		d = f.read(2)
		(height,) = unpack('>h', d)
	        h[i,j] = height
		if height < -1000:
			li.append((i,j))

hmax = h.max()
h3 = zeros_like(h)
h3[:,:] = h[:,:]
print len(li), "missing data points"

def get_nei(z):
	h2 = h[z[0]-1:z[0]+2,z[1]-1:z[1]+2]
	nn = sum(where(h2 < -1000, 0, 1))
	av = sum(where(h2 > -1000, h2, 0)) / float(nn)
	return nn, av

# fill missing points with a nearest-neighbor averaging method:
loop = len(li)
lim = 7
while loop > 0:
	sd = False
	for q in range(len(li)):
		if h[li[q]] > -1000.: continue
		n, a = get_nei(li[q])
		if n >= lim:
			print li[q],loop, n, a, lim
			h3[li[q]] = a
			loop -= 1
			sd = True
	if not sd: lim -= 1
	h[:,:] = h3[:,:]
print "missing points done"	

def hext(a):
	"Hex color to triplet."
	r,g,b = a[0:2], a[2:4], a[4:6]
	return int(r, 16), int(g, 16), int(b, 16)

# from http://en.wikipedia.org/wiki/Wikipedia:WikiProject_Maps/Conventions/Topographic_maps:
col_sea = hext("0978ab")
cols = """
{{Mapcolor|r=245|v=244|b=242|hex=#F5F4F2|col=black}}
{{Mapcolor|r=224|v=222|b=216|hex=#E0DED8|col=black}}
{{Mapcolor|r=202|v=195|b=184|hex=#CAC3B8|col=black}}
{{Mapcolor|r=186|v=174|b=154|hex=#BAAE9A|col=black}}
{{Mapcolor|r=172|v=154|b=124|hex=#AC9A7C|col=black}}
{{Mapcolor|r=170|v=135|b=83|hex=#AA8753|col=black}}
{{Mapcolor|r=185|v=152|b=90|hex=#B9985A|col=black}}
{{Mapcolor|r=195|v=167|b=107|hex=#C3A76B|col=black}}
{{Mapcolor|r=202|v=185|b=130|hex=#CAB982|col=black}}
{{Mapcolor|r=211|v=202|b=157|hex=#D3CA9D|col=black}}
{{Mapcolor|r=222|v=214|b=163|hex=#DED6A3|col=black}}
{{Mapcolor|r=232|v=225|b=182|hex=#E8E1B6|col=black}}
{{Mapcolor|r=239|v=235|b=192|hex=#EFEBC0|col=black}}
{{Mapcolor|r=225|v=228|b=181|hex=#E1E4B5|col=black}}
{{Mapcolor|r=209|v=215|b=171|hex=#D1D7AB|col=black}}
{{Mapcolor|r=189|v=204|b=150|hex=#BDCC96|col=black}}
{{Mapcolor|r=168|v=198|b=143|hex=#A8C68F|col=black}}
{{Mapcolor|r=148|v=191|b=139|hex=#94BF8B|col=black}}
{{Mapcolor|r=172|v=208|b=165|hex=#ACD0A5|col=black}}
"""
col = []

for l in cols.splitlines():
	if len(l) < 10: continue
	i = l.find('#')
	if i > -1:
		col.append(hext(l[i+1:i+7]))

col.reverse()	# -> bottom to top

o = Image.new('RGB', h.shape)

def interp(c, f):
	"Interpolate into color table."
	r = int((1.-f) * col[c][0] + f * col[c+1][0])
	g = int((1.-f) * col[c][1] + f * col[c+1][1])
	b = int((1.-f) * col[c][2] + f * col[c+1][2])
	return r,g,b

for j in range(row_length):
	for i in range(row_length):
		c, f = divmod(h[j,i] / hmax * (len(col)-1), 1)
		if 0 < h[j,i] < hmax:
			o.putpixel((j,i), interp(int(c), f))
		elif h[i,j] == hmax:
			o.putpixel((j,i), col[-1])
		else: o.putpixel((j,i), col_sea)

o.save("map_height.png")	# save height map
o2 = o.crop((0,0,942,603))
o2.save("map_height_cropped.png")

# taken from hillshade.py:
#def illumination(idata,azdeg=315.0,altdeg=45.):
def illumination(idata,azdeg=225.0,altdeg=45.):
    # convert alt, az to radians
    az = azdeg*np.pi/180.0
    alt = altdeg*np.pi/180.0
    # gradient in x and y directions
    dx, dy = np.gradient(idata)
    slope = 0.5*np.pi - np.arctan(np.hypot(dx, dy))
    aspect = np.arctan2(dx, dy)
    odata = np.sin(alt)*np.sin(slope) + np.cos(alt)*np.cos(slope)*np.cos(-az -\
             aspect - 0.5*np.pi)
    # rescale to interval -1,1
    # 1 means maximum sun exposure and 0 means complete shade.
    odata = (odata - odata.min())/(odata.max() - odata.min())
    return odata

il = 255 * illumination(h)

o4 = Image.new('RGBA', il.shape)
for j in range(row_length-1):
	for i in range(row_length-1):
		v = int(il[j,i])
		if 0 <= v < 128:
			alpha = (255 - 2*v)
			o4.putpixel((j,i), (0,0,0,alpha))
		elif v == 128:
			o4.putpixel((j,i), (0,0,0,0))
		elif 128 < v < 256:
			alpha = 2*(v-128)
			o4.putpixel((j,i), (255,255,255,alpha))
		else:
			o4.putpixel((j,i), (255,255,255,0))
o4.save("il_NW_alpha.png")	# NW-illuminated (alpha transparency for use with Inkscape)

Licensing

I, the copyright holder of this work, hereby publish it under the following licenses:

This file is licensed under the Creative Commons Attribution-Share Alike 3.0 Unported license.

You are free:

to share – to copy, distribute and transmit the work
to remix – to adapt the work

Under the following conditions:

attribution – You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use.
share alike – If you remix, transform, or build upon the material, you must distribute your contributions under the same or compatible license as the original.

Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A copy of the license is included in the section entitled GNU Free Documentation License.

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File history

Click on a date/time to view the file as it appeared at that time.

	Date/Time	Dimensions	User	Comment
current	22:15, 30 September 2010	2,000 × 1,100 (1.05 MB)	Morn	added OpenStreetMap layer
	22:55, 7 April 2010	2,000 × 1,100 (951 KB)	Morn	added scale in feet
	18:44, 7 April 2010	2,049 × 1,154 (956 KB)	Morn	more mountains
	13:47, 7 April 2010	2,000 × 1,100 (935 KB)	Morn	mountain heights
	21:48, 6 April 2010	2,000 × 1,100 (914 KB)	Morn	Philosophical Park as area
	18:58, 5 April 2010	2,000 × 1,100 (909 KB)	Morn	improved terrain
	18:59, 4 April 2010	2,000 × 1,100 (857 KB)	Morn	compass rose
	15:45, 4 April 2010	2,000 × 1,100 (818 KB)	Morn	hypsometric colors
	00:32, 4 April 2010	2,000 × 1,127 (670 KB)	Morn	slightly stronger colors
	19:44, 3 April 2010	2,000 × 1,100 (655 KB)	Morn	terrain shading from SRTM 3 data