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vasrap/android_distance_port.rb

Created April 27, 2013 17:12
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Calculates distance in meters between 2 GPS coordinates (Android port)
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android_distance_port.rb
# Calculates distance in meters between 2 GPS coordinates
# Ported to Ruby from the Android SDK source
# Original paper explaning the process: http://www.ngs.noaa.gov/PUBS_LIB/inverse.pdf
# Arguments p1, p2 are instances of the class Point below:
# class Point
# attr_accessor :lat, :lon
# end
def android_distance_port(p1, p2)
lat1 = p1.lat
lon1 = p1.lon
lat2 = p2.lat
lon2 = p2.lon
max_iterations = 20
lat1 *= Math::PI / 180.0
lat2 *= Math::PI / 180.0
lon1 *= Math::PI / 180.0
lon2 *= Math::PI / 180.0
a = 6378137.0
b = 6356752.3142
f = (a - b) / a
a_sq_minus_b_sq_over_b_sq = (a * a - b * b) / (b * b)
cap_l = lon2 - lon1
cap_a = 0.0
cap_u1 = Math.atan((1.0 - f) * Math.tan(lat1))
cap_u2 = Math.atan((1.0 - f) * Math.tan(lat2))
coscap_u1 = Math.cos(cap_u1)
coscap_u2 = Math.cos(cap_u2)
sincap_u1 = Math.sin(cap_u1)
sincap_u2 = Math.sin(cap_u2)
coscap_u1coscap_u2 = coscap_u1 * coscap_u2
sincap_u1sincap_u2 = sincap_u1 * sincap_u2
sigma = 0.0
delta_sigma = 0.0
cos_sqcap_alpha = 0.0
cos_2_s_m = 0.0
cos_sigma = 0.0
sin_sigma = 0.0
coscap_lambda = 0.0
sincap_lambda = 0.0
lambda = cap_l
(0..max_iterations).each do |iter|
lambda_orig = lambda
coscap_lambda = Math.cos(lambda)
sincap_lambda = Math.sin(lambda)
t1 = coscap_u2 * sincap_lambda
t2 = coscap_u1 * sincap_u2 - sincap_u1 * coscap_u2 * coscap_lambda
sin_sq_sigma = t1 * t1 + t2 * t2
sin_sigma = Math.sqrt(sin_sq_sigma)
cos_sigma = sincap_u1sincap_u2 + coscap_u1coscap_u2 * coscap_lambda
sigma = Math.atan2(sin_sigma, cos_sigma)
sincap_alpha = 0.0
unless sin_sigma == 0
sincap_alpha = coscap_u1coscap_u2 * sincap_lambda / sin_sigma
end
cos_sqcap_alpha = 1.0 - sincap_alpha * sincap_alpha
cos_2_s_m = 0.0
unless cos_sqcap_alpha == 0
cos_2_s_m = cos_sigma - 2.0 * sincap_u1sincap_u2 / cos_sqcap_alpha
end
u_squared = cos_sqcap_alpha * a_sq_minus_b_sq_over_b_sq
cap_a = 1 + (u_squared / 16384.0) *
(4096.0 + u_squared *
(-768 + u_squared * (320.0 - 175.0 * u_squared)))
cap_b = (u_squared / 1024.0) *
(256.0 + u_squared *
(-128.0 + u_squared * (74.0 - 47.0 * u_squared)))
cap_c = (f / 16.0) *
cos_sqcap_alpha *
(4.0 + f * (4.0 - 3.0 * cos_sqcap_alpha))
cos_2_s_m_sq = cos_2_s_m * cos_2_s_m
delta_sigma = cap_b * sin_sigma *
(cos_2_s_m + (cap_b / 4.0) *
(cos_sigma * (-1.0 + 2.0 * cos_2_s_m_sq) -
(cap_b / 6.0) * cos_2_s_m *
(-3.0 + 4.0 * sin_sigma * sin_sigma) *
(-3.0 + 4.0 * cos_2_s_m_sq)))
lambda = cap_l +
(1.0 - cap_c) * f * sincap_alpha *
(sigma + cap_c * sin_sigma *
(cos_2_s_m + cap_c * cos_sigma *
(-1.0 + 2.0 * cos_2_s_m * cos_2_s_m)))
delta = (lambda - lambda_orig) / lambda
if (delta).abs < 1.0e-12
break
end
end
(b * cap_a * (sigma - delta_sigma)).to_f
end
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