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pv_ECEF_to_NED.m
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pv_ECEF_to_NED.m
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function [L_b,lambda_b,h_b,v_eb_n] = pv_ECEF_to_NED(r_eb_e,v_eb_e)
%pv_ECEF_to_NED - Converts Cartesian to curvilinear position and velocity
%resolving axes from ECEF to NED
%
% Software for use with "Principles of GNSS, Inertial, and Multisensor
% Integrated Navigation Systems," Second Edition.
%
% This function created 11/4/2012 by Paul Groves
%
% Inputs:
% r_eb_e Cartesian position of body frame w.r.t. ECEF frame, resolved
% along ECEF-frame axes (m)
% v_eb_e velocity of body frame w.r.t. ECEF frame, resolved along
% ECEF-frame axes (m/s)
%
% Outputs:
% L_b latitude (rad)
% lambda_b longitude (rad)
% h_b height (m)
% v_eb_n velocity of body frame w.r.t. ECEF frame, resolved along
% north, east, and down (m/s)
% Copyright 2012, Paul Groves
% License: BSD; see license.txt for details
% Parameters
R_0 = 6378137; %WGS84 Equatorial radius in meters
e = 0.0818191908425; %WGS84 eccentricity
% Begins
% Convert position using Borkowski closed-form exact solution
% From (2.113)
lambda_b = atan2(r_eb_e(2),r_eb_e(1));
% From (C.29) and (C.30)
k1 = sqrt(1 - e^2) * abs (r_eb_e(3));
k2 = e^2 * R_0;
beta = sqrt(r_eb_e(1)^2 + r_eb_e(2)^2);
E = (k1 - k2) / beta;
F = (k1 + k2) / beta;
% From (C.31)
P = 4/3 * (E*F + 1);
% From (C.32)
Q = 2 * (E^2 - F^2);
% From (C.33)
D = P^3 + Q^2;
% From (C.34)
V = (sqrt(D) - Q)^(1/3) - (sqrt(D) + Q)^(1/3);
% From (C.35)
G = 0.5 * (sqrt(E^2 + V) + E);
% From (C.36)
T = sqrt(G^2 + (F - V * G) / (2 * G - E)) - G;
% From (C.37)
L_b = sign(r_eb_e(3)) * atan((1 - T^2) / (2 * T * sqrt (1 - e^2)));
% From (C.38)
h_b = (beta - R_0 * T) * cos(L_b) +...
(r_eb_e(3) - sign(r_eb_e(3)) * R_0 * sqrt(1 - e^2)) * sin (L_b);
% Calculate ECEF to NED coordinate transformation matrix using (2.150)
cos_lat = cos(L_b);
sin_lat = sin(L_b);
cos_long = cos(lambda_b);
sin_long = sin(lambda_b);
C_e_n = [-sin_lat * cos_long, -sin_lat * sin_long, cos_lat;...
-sin_long, cos_long, 0;...
-cos_lat * cos_long, -cos_lat * sin_long, -sin_lat];
% Transform velocity using (2.73)
v_eb_n = C_e_n * v_eb_e;
% Ends