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Jungfraujoch/image_analysis/bragg_integration/BraggIntegrationEngine.cpp
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v1.0.0-rc.156 (#66)
This is an UNSTABLE release. It includes many experimental features, as well as many AI generated fixes. We recommend using rc.152 for production use.

* jfjoch_process: Major rotation (rot3d) data processing overhaul - robust profile-fit integration, Cauchy-loss scaling with optional absorption surface, de-novo indexing and space-group/centering determination fixes, and merging statistics + ISa in the mmCIF output.
* jfjoch_process: Add EXPERIMENTAL ice-ring detection (--detect-ice-rings) that excludes ice reflections from scaling.
* Compression: Add BSHUF_ZSTD_RLE_HUFF, make compression size-aware (drop frames that don't fit rather than aborting), and add the jfjoch_recompress tool.
* jfjoch_viewer: Report "Multiple lattices detected" and grey out "Analyze dataset" on a live connection.
* jfjoch_broker: Write smargon chi/phi goniometer positions to NXmx; read sensor thickness/material from HDF5 metadata.
* CI: Build Windows (CUDA and non-CUDA) installers.Reviewed-on: #66

Co-authored-by: Filip Leonarski <filip.leonarski@psi.ch>
2026-07-03 19:18:56 +02:00

101 lines
4.3 KiB
C++

// SPDX-FileCopyrightText: 2026 Filip Leonarski, Paul Scherrer Institute <filip.leonarski@psi.ch>
// SPDX-License-Identifier: GPL-3.0-only
#include "BraggIntegrationEngine.h"
#include <algorithm>
#include <string>
namespace {
// Radial parallax broadening as the coefficient of tan^2(2theta), i.e. Var(z)/pixel^2 [px^2].
// Copied verbatim from ProfileIntegrate2D: a photon converts at a random depth z (exponential,
// attenuation length L, truncated at the sensor thickness), shifting the recorded spot radially by
// z*tan(2theta). L is photoelectric-dominated (~lambda^3), so a per-material reference (13 keV) is
// scaled by lambda^3; Si and CdTe are the sensors in use.
double parallax_var_px2(const std::string &material, double thickness_um, double lambda_A, double pixel_um) {
if (!(thickness_um > 0.0) || !(pixel_um > 0.0) || !(lambda_A > 0.0))
return 0.0;
const double L_ref = material == "CdTe" ? 42.6 : 273.0; // attenuation length [um] at 0.953 A
const double s = lambda_A / 0.953;
const double L = L_ref / (s * s * s);
const double a = thickness_um / L, e = std::exp(-a);
if (1.0 - e <= 0.0)
return 0.0;
const double mean = L * (1.0 - (1.0 + a) * e) / (1.0 - e);
const double ez2 = L * L * (2.0 - (a * a + 2.0 * a + 2.0) * e) / (1.0 - e);
const double var = std::max(0.0, ez2 - mean * mean); // um^2
return var / (pixel_um * pixel_um);
}
} // namespace
BraggIntegrationEngine::BraggIntegrationEngine(const DiffractionExperiment &experiment)
: geom(experiment.GetDiffractionGeometry()) {
const auto settings = experiment.GetBraggIntegrationSettings();
const auto &det = experiment.GetDetectorSetup();
mode = settings.GetIntegrator();
empirical = mode == IntegratorMode::ProfileEmpirical;
// Same frame as the reflections' predicted_x/predicted_y and the ImagePreprocessorBuffer that
// feeds this engine (MXAnalysisWithoutFPGA sizes that buffer to GetPixelsNum()).
xpixel = experiment.GetXPixelsNum();
ypixel = experiment.GetYPixelsNum();
npixel = experiment.GetPixelsNum();
r1_sq = settings.GetR1() * settings.GetR1();
r2 = settings.GetR2();
r2_sq = r2 * r2;
r3 = settings.GetR3();
r3_sq = r3 * r3;
min_sigma_ratio = settings.GetMinimumSigmaInRegardsToI();
R = static_cast<int>(std::ceil(r2));
G = 2 * R + 1;
GG = G * G;
// A set bandwidth (broadband / stills) vs monochromatic (rotation) splits the treatment: the
// background sigma-clip and radial-elongation terms are path-dependent (see ProfileIntegrate2D).
bw_sigma = experiment.GetBandwidthFWHM().value_or(0.0f) / 2.3548f;
broadband = bw_sigma > 0.0;
apply_bkg_clip = broadband;
const double c_par = parallax_var_px2(det.GetSensorMaterial(), det.GetSensorThickness_um(),
geom.GetWavelength_A(), geom.GetPixelSize_mm() * 1000.0);
c_radial = c_par + (broadband ? 0.0 : bragg_engine::C_CAPTURE);
F_px = geom.GetDetectorDistance_mm() / std::max(1e-6f, geom.GetPixelSize_mm());
beam_x = geom.GetBeamX_pxl();
beam_y = geom.GetBeamY_pxl();
use_ellipse = !empirical && (bw_sigma > 0.0 || c_radial > 0.0);
polarization = experiment.GetPolarizationFactor();
}
std::vector<Reflection> BraggIntegrationEngine::Finalize(const std::vector<Reflection> &predicted,
size_t npredicted,
const std::vector<BraggFitResult> &results,
int64_t image_number) const {
std::vector<Reflection> out;
out.reserve(npredicted);
for (size_t i = 0; i < npredicted; ++i) {
const auto &fr = results[i];
if (!fr.ok)
continue;
Reflection refl = predicted[i];
refl.I = fr.I;
refl.sigma = fr.sigma;
refl.bkg = fr.bkg;
if (fr.has_observed) {
refl.observed_x = fr.observed_x;
refl.observed_y = fr.observed_y;
}
refl.observed = true;
if (polarization)
refl.rlp /= geom.CalcAzIntPolarizationCorr(refl.predicted_x, refl.predicted_y, polarization.value());
refl.image_scale_corr = refl.rlp / refl.partiality;
refl.image_number = static_cast<float>(image_number);
out.push_back(refl);
}
return out;
}