1f2557a0e4
Demonstrates the new CameraModel/CameraModelTolerance API, two independent beam pointing angles, and per-plane z refinement with a deliberately offset nominal camera pose and z values. Co-Authored-By: Claude Sonnet 5 <noreply@anthropic.com>
181 lines
7.4 KiB
Python
181 lines
7.4 KiB
Python
"""End-to-end demonstration of the he11lib reconstruction pipeline.
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Simulates a gyrotron beam that is mostly the LG_00 fundamental mode with a
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small admixture of LG_01, viewed by a thermal camera at four distances from
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the output window through a tilted, off-axis pinhole `CameraModel`. The
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camera has an unknown transverse offset/pointing (two independent tilt
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angles) and adds sensor noise; the target also has some thermal-diffusion
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blur that we correct for. The nominal camera pose and each plane's nominal
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`z` are deliberately offset from the (unknown-to-the-reconstructor) ground
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truth, simulating realistic calibration/measurement error, and are jointly
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refined by the fit within their tolerances. We then reconstruct the mode
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purity, beam center/pointing, camera pose, and per-plane z, and plot the
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diagnostics.
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Run with:
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python examples/full_pipeline_example.py
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"""
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from __future__ import annotations
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import matplotlib.pyplot as plt
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from he11lib import (
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BeamReconstructor,
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CameraModel,
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CameraModelTolerance,
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DiffusionDeconvolver,
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GeometryCalibration,
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LGBasis,
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SyntheticBeamGenerator,
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plot_center_trace,
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plot_mode_purity,
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plot_residuals,
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)
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# --- Known reference beam parameters (from the gyrotron/mode-converter design) ---
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W0 = 5e-3 # reference waist radius, meters
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Z0 = 0.5 # reference waist location, meters from the output window
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WAVELENGTH = 1.76e-3 # radiation wavelength, meters (e.g. a 170 GHz gyrotron)
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# --- Ground truth for the synthetic beam (unknown to the reconstructor) ---
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TRUE_COEFFICIENTS = {(0, 0): 0.95 + 0j, (0, 1): 0.25 + 0.05j}
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TRUE_CENTER = (0.4e-3, -0.3e-3) # beam offset from the optical axis
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TRUE_POINTING_HORIZONTAL_DEG = 0.15 # beam pointing (horizontal tilt)
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TRUE_POINTING_VERTICAL_DEG = -0.08 # beam pointing (vertical tilt)
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IMAGE_SHAPE = (81, 81)
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# A camera positioned well upstream of the target planes and mildly tilted,
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# so true perspective projection (keystoning) is in play but the frame
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# still comfortably contains the beam at every z below. Calibration only
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# gives us a nominal estimate of this pose -- it's refined jointly with
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# everything else, within CAMERA_TOLERANCE, because of mechanical vibration
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# between calibration and measurement.
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PIXEL_SCALE = 4e-4 # meters/pixel, used only to size FOCAL_LENGTH_PX below
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CAMERA_DISTANCE = 5.0 # meters upstream of the output window
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FOCAL_LENGTH_PX = (CAMERA_DISTANCE + Z0) / PIXEL_SCALE
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# NOTE on the small magnitudes below: at CAMERA_DISTANCE + Z0 ~= 5.5 m with
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# an 81x81 frame at PIXEL_SCALE, the imaged footprint is only ~3.2 cm wide.
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# A pinhole camera's boresight sweeps laterally by
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# (CAMERA_DISTANCE + Z0) * tan(angle) at the target plane, so even a
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# fraction of a degree of yaw/pitch error translates to centimeters of
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# parallax there -- degrees-scale tilt (as in a naive "mildly tilted"
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# choice) would sweep the boresight tens of centimeters away from the beam,
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# off the edge of the frame entirely. Small angles here (~0.01-0.03 deg)
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# still exercise true keystoning/off-axis projection while keeping the beam
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# comfortably inside the frame at every z. Similarly, CAMERA_TOLERANCE's
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# yaw/pitch bounds are kept tight: yaw/pitch changes are nearly degenerate
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# with the beam's own two pointing angles (both produce an z-dependent
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# transverse drift), so a loose (e.g. several-degree) bound lets the
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# optimizer trade pointing off against yaw/pitch and converge to a very
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# wrong split of the two; roll doesn't share that degeneracy and is given
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# more room.
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TRUE_CAMERA = CameraModel(
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focal_length_px=FOCAL_LENGTH_PX,
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position=(0.002, -0.003, -CAMERA_DISTANCE),
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orientation_deg=(0.03, -0.02, 0.01),
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)
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# Nominal (calibrated) camera pose, deliberately offset from TRUE_CAMERA
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# within CAMERA_TOLERANCE, standing in for real calibration error.
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NOMINAL_CAMERA = CameraModel(
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focal_length_px=FOCAL_LENGTH_PX * 1.01,
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position=(0.0015, -0.0025, -CAMERA_DISTANCE),
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orientation_deg=(0.028, -0.018, 0.005),
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)
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CAMERA_TOLERANCE = CameraModelTolerance(
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focal_length_px=FOCAL_LENGTH_PX * 0.05,
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position=(0.005, 0.005, 0.02),
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orientation_deg=(0.01, 0.01, 0.02),
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)
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# Measurement plane distances, meters. Kept within roughly +/-2 Rayleigh
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# ranges of z0 so the (widening) beam stays well within the camera frame --
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# planes much farther out would be clipped by the finite frame, which
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# degrades the fit.
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Z_LIST = [0.4, 0.45, 0.55, 0.6]
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# Each plane's z is only known to a nominal precision (e.g. a translation
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# stage's readout); offset the nominal value from the true z used to
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# render the plane, and let the fit recover the true z within Z_TOLERANCE.
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NOMINAL_Z_OFFSETS = {0.4: 0.003, 0.45: -0.002, 0.55: 0.004, 0.6: -0.003}
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Z_TOLERANCE = 0.01
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# --- Target thermal-diffusion blur (known target material properties) ---
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THERMAL_DIFFUSIVITY = 1e-6 # m^2/s
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DWELL_TIME = 0.2 # s
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def main() -> None:
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basis = LGBasis(w0=W0, z0=Z0, wavelength=WAVELENGTH)
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generator = SyntheticBeamGenerator(basis=basis, camera=TRUE_CAMERA)
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planes = generator.generate(
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coefficients=TRUE_COEFFICIENTS,
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z_list=Z_LIST,
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image_shape=IMAGE_SHAPE,
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center=TRUE_CENTER,
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pointing_angle_horizontal_deg=TRUE_POINTING_HORIZONTAL_DEG,
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pointing_angle_vertical_deg=TRUE_POINTING_VERTICAL_DEG,
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z_tolerance=Z_TOLERANCE,
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nominal_z_offsets=NOMINAL_Z_OFFSETS,
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noise_std=2e-4,
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seed=42,
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)
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# Apply the same thermal-diffusion blur a real target would exhibit,
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# using the nominal (not true) camera to compute the pixel scale --
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# exactly what BeamReconstructor itself does internally.
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blur_deconvolver = DiffusionDeconvolver(
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thermal_diffusivity=THERMAL_DIFFUSIVITY, dwell_time=DWELL_TIME
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)
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nominal_calibration = GeometryCalibration(NOMINAL_CAMERA)
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for plane in planes:
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pixel_scale = nominal_calibration.effective_pixel_scale(plane.flux.shape, plane.z)
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plane.flux = blur_deconvolver.blur(plane.flux, pixel_scale)
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# The ground truth only has order-0 and order-1 content, so a max_order
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# of 1 is enough for automatic mode-set growth to find it; growing much
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# further would start fitting deconvolution/noise artifacts as spurious
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# higher-order modes.
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reconstructor = BeamReconstructor(
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w0=W0,
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z0=Z0,
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wavelength=WAVELENGTH,
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camera=NOMINAL_CAMERA,
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camera_tolerance=CAMERA_TOLERANCE,
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max_order=1,
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deconvolver=blur_deconvolver,
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)
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result = reconstructor.reconstruct(planes)
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print("Mode purity table (power fraction, phase [rad]):")
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for mode, (fraction, phase) in sorted(
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result.purity.items(), key=lambda item: -item[1][0]
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):
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print(f" LG_{mode[0]},{mode[1]}: {fraction:6.3%} (phase {phase:+.3f} rad)")
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print(
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"\nFitted pointing angles: "
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f"horizontal={result.pointing_angle_horizontal_deg:.4f} deg, "
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f"vertical={result.pointing_angle_vertical_deg:.4f} deg"
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)
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print("Fitted beam center per plane (m):")
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for plane, (cx, cy) in zip(planes, result.centers):
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print(f" z={plane.z:.2f} m -> ({cx:.3e}, {cy:.3e})")
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print("\nFitted camera geometry:")
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for key, value in result.geometry.items():
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print(f" {key}: {value:.6g}")
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print(f"\nUsed phase-retrieval fallback: {result.used_phase_retrieval}")
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plot_mode_purity(result)
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plot_center_trace(planes, result)
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plot_residuals(planes, result)
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plt.show()
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if __name__ == "__main__":
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main()
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