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test(e2e): add ECEF→WGS84 and Euler→quaternion helpers
Closed-form Heikkinen method for ECEF conversion (centimetre accuracy, no iteration). ZYX aerospace-convention Euler → quaternion. Both needed by upcoming VPAIRAdapter rewrite; reusable for other datasets shipping ECEF or Euler poses (e.g. some MARS-LVIG releases). Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
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Yuzviak
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"""Coordinate conversion helpers used by dataset adapters.
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- `ecef_to_wgs84`: closed-form Zhu/Heikkinen conversion (no iteration), accurate
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to centimetres for any point above the Earth's surface.
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- `euler_to_quaternion`: aerospace ZYX intrinsic convention (yaw → pitch → roll
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applied to body frame in that order). Inputs in radians.
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"""
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from __future__ import annotations
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import math
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# WGS84 constants
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_A = 6_378_137.0 # semi-major axis, metres
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_F = 1.0 / 298.257223563 # flattening
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_B = _A * (1.0 - _F) # semi-minor axis
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_E2 = 1.0 - (_B * _B) / (_A * _A) # first eccentricity squared
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_EP2 = (_A * _A) / (_B * _B) - 1.0 # second eccentricity squared
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def ecef_to_wgs84(x: float, y: float, z: float) -> tuple[float, float, float]:
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"""ECEF (metres) → WGS84 (lat° N, lon° E, altitude metres above ellipsoid).
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Uses Heikkinen's closed-form method — no iteration, one pass, centimetre
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accuracy for any realistic aerial vehicle altitude.
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"""
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r = math.sqrt(x * x + y * y)
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if r == 0.0:
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# Pole: lon is conventionally 0, lat is ±90 depending on sign of z
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lat = 90.0 if z >= 0 else -90.0
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alt = abs(z) - _B
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return lat, 0.0, alt
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ee = _A * _A - _B * _B
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f = 54.0 * _B * _B * z * z
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g = r * r + (1.0 - _E2) * z * z - _E2 * ee
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c = (_E2 * _E2 * f * r * r) / (g * g * g)
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s = (1.0 + c + math.sqrt(c * c + 2.0 * c)) ** (1.0 / 3.0)
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p = f / (3.0 * (s + 1.0 / s + 1.0) ** 2 * g * g)
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q = math.sqrt(1.0 + 2.0 * _E2 * _E2 * p)
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r0 = -(p * _E2 * r) / (1.0 + q) + math.sqrt(
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0.5 * _A * _A * (1.0 + 1.0 / q)
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- (p * (1.0 - _E2) * z * z) / (q * (1.0 + q))
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- 0.5 * p * r * r
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)
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u = math.sqrt((r - _E2 * r0) ** 2 + z * z)
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v = math.sqrt((r - _E2 * r0) ** 2 + (1.0 - _E2) * z * z)
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z0 = (_B * _B * z) / (_A * v)
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lat = math.degrees(math.atan((z + _EP2 * z0) / r))
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lon = math.degrees(math.atan2(y, x))
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alt = u * (1.0 - (_B * _B) / (_A * v))
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return lat, lon, alt
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def euler_to_quaternion(
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roll: float, pitch: float, yaw: float
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) -> tuple[float, float, float, float]:
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"""Aerospace ZYX intrinsic Euler → (qx, qy, qz, qw).
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Rotation order: yaw (about world z) → pitch (about intermediate y) → roll
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(about body x). All inputs in radians. Output quaternion has unit norm.
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"""
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cr = math.cos(roll * 0.5)
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sr = math.sin(roll * 0.5)
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cp = math.cos(pitch * 0.5)
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sp = math.sin(pitch * 0.5)
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cy = math.cos(yaw * 0.5)
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sy = math.sin(yaw * 0.5)
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qw = cr * cp * cy + sr * sp * sy
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qx = sr * cp * cy - cr * sp * sy
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qy = cr * sp * cy + sr * cp * sy
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qz = cr * cp * sy - sr * sp * cy
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return qx, qy, qz, qw
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"""Coordinate conversion helpers — ECEF↔WGS84 + Euler→quaternion."""
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import numpy as np
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import pytest
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from gps_denied.testing.coord import ecef_to_wgs84, euler_to_quaternion
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# --- ECEF → WGS84 ---
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def test_ecef_origin_is_on_equator_prime_meridian():
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# Point on equator at lon=0, alt=0 is at x=6378137, y=0, z=0 (WGS84 semi-major)
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lat, lon, alt = ecef_to_wgs84(6378137.0, 0.0, 0.0)
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assert lat == pytest.approx(0.0, abs=1e-6)
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assert lon == pytest.approx(0.0, abs=1e-6)
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assert alt == pytest.approx(0.0, abs=1e-3)
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def test_ecef_north_pole():
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# Semi-minor axis b ≈ 6356752.314 — north pole, lat=90, lon undefined but typically 0
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lat, lon, alt = ecef_to_wgs84(0.0, 0.0, 6356752.314245)
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assert lat == pytest.approx(90.0, abs=1e-4)
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assert alt == pytest.approx(0.0, abs=1e-2)
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def test_ecef_known_point_munich():
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# Munich, Germany: lat≈48.1351, lon≈11.5820, alt≈520 m
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# ECEF from standard converter:
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# X ≈ 4177789.3, Y ≈ 855098.1, Z ≈ 4727807.9
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lat, lon, alt = ecef_to_wgs84(4177789.3, 855098.1, 4727807.9)
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assert lat == pytest.approx(48.1351, abs=1e-3)
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assert lon == pytest.approx(11.5820, abs=1e-3)
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assert alt == pytest.approx(520.0, abs=2.0)
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def test_ecef_vpair_sample_point():
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# From VPAIR sample poses_query.txt first row:
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# 4023518.0, 510303.75, 4906569.65 — should be in Bonn/Eifel region, Germany
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# (VPAIR was recorded near Bonn). Expected lat ~50.7°, lon ~7.2°, alt ~(200-400) m.
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lat, lon, alt = ecef_to_wgs84(4023518.0, 510303.75, 4906569.65)
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assert 50.0 < lat < 51.5, f"lat={lat}"
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assert 6.5 < lon < 8.0, f"lon={lon}"
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# Bonn-Eifel area ground elevation 100-500 m
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assert 100.0 < alt < 700.0, f"alt={alt}"
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# --- Euler → quaternion ---
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def test_euler_zero_is_identity_quaternion():
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qx, qy, qz, qw = euler_to_quaternion(0.0, 0.0, 0.0)
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assert qx == pytest.approx(0.0, abs=1e-12)
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assert qy == pytest.approx(0.0, abs=1e-12)
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assert qz == pytest.approx(0.0, abs=1e-12)
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assert qw == pytest.approx(1.0, abs=1e-12)
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def test_euler_yaw_90_deg_about_z():
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# Yaw = π/2 around world z, roll=pitch=0
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# Expected quaternion: (0, 0, sin(π/4), cos(π/4)) ≈ (0, 0, 0.7071, 0.7071)
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qx, qy, qz, qw = euler_to_quaternion(0.0, 0.0, np.pi / 2)
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assert qx == pytest.approx(0.0, abs=1e-10)
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assert qy == pytest.approx(0.0, abs=1e-10)
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assert qz == pytest.approx(np.sin(np.pi / 4), abs=1e-10)
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assert qw == pytest.approx(np.cos(np.pi / 4), abs=1e-10)
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def test_euler_roll_90_deg_about_x():
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# Roll = π/2 around body x, pitch=yaw=0
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qx, qy, qz, qw = euler_to_quaternion(np.pi / 2, 0.0, 0.0)
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assert qx == pytest.approx(np.sin(np.pi / 4), abs=1e-10)
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assert qy == pytest.approx(0.0, abs=1e-10)
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assert qz == pytest.approx(0.0, abs=1e-10)
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assert qw == pytest.approx(np.cos(np.pi / 4), abs=1e-10)
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def test_euler_unit_norm():
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# Arbitrary angles — the returned quaternion must be unit norm
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qx, qy, qz, qw = euler_to_quaternion(0.3, -0.7, 1.2)
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norm = (qx * qx + qy * qy + qz * qz + qw * qw) ** 0.5
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assert norm == pytest.approx(1.0, abs=1e-12)
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