Hardware and software corrections of the spatial distortions of position-sensitive detectors

Leclerc, Grégoire; Ozenne, J.B.; Corbeil, Jean-Simon; Sanche, Léon

doi:10.1063/1.1142145

Cited by 6 publications

(1 citation statement)

References 9 publications

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“…Previous efforts to measure strains accurately using a 2D area detector showed that good calibration of the experimental geometry and distortion are essential [10]. The conventional methods [11][12][13][14][15] for calibration of earlier CCD detectors generally fitted smooth functions (splines or polynomials) to images of grid-like targets. The production of an accurate calibration artifact is problematic because machining tolerances are difficult to reduce below about 10 µm for a >150-mm-sized object.…”

Section: Introductionmentioning

confidence: 99%

Using Powder Diffraction Patterns to Calibrate the Module Geometry of a Pixel Detector

2022

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The precision and accuracy of diffraction measurements with 2D area detectors depends on how well the experimental geometry is known. A method is described to measure the module geometry in order to obtain accurate strain data using a new Eiger2 4M CdTe detector. Smooth Debye–Scherrer powder diffraction rings with excellent signal to noise were collected by using a fine-grained sample of CeO2. From these powder patterns, the different components of the module alignment errors could be observed when the overall detector position was moved. A least squares fitting method was used to refine the detector module and scattering geometry for a series of powder patterns with different beam centers. A precision that is around 1/350 pixel for the module positions was obtained from the fit. This calibration was checked by free refinement of the unit cell of a silicon crystal that gave a maximum residual strain value of 2.1 × 10−5 as the deviation from cubic symmetry.

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Section: Introductionmentioning

confidence: 99%

Using Powder Diffraction Patterns to Calibrate the Module Geometry of a Pixel Detector

2022

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Neutral—Atom Imaging Techniques

Müller¹,

Helm²

2003

Many-Particle Quantum Dynamics in Atomic and Molecular Fragmentation

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An (e,2e) study of double excitation-autoionization mechanisms in helium

McDonald¹,

Crowe²

1993

J. Phys. B: At. Mol. Opt. Phys.

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Measurements are reported of the triple differential cross sections for autoionization of the (2p2)1D and (2s2p)1P states of helium, following double excitation by 200 eV electrons and for a 12 degrees scattered electron angle. The direct ionization cross section for 34.7 eV ejected electrons has also been measured. The use of a multiparameter spectrometer has enabled reliable high resolution, 80 meV, data to be obtained. The resonant ionization cross sections of the autoionizing states obtained from the coincidence ejected electron spectra are analysed using the Shore parametrization and compared with other recent experimental data. Possible theoretical models of the double excitation-autoionization process are discussed and the relative importance of electron correlation and double hit mechanisms assessed in view of the available data.

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Hardware and software corrections of the spatial distortions of position-sensitive detectors

Cited by 6 publications

References 9 publications

Using Powder Diffraction Patterns to Calibrate the Module Geometry of a Pixel Detector

Using Powder Diffraction Patterns to Calibrate the Module Geometry of a Pixel Detector

Neutral—Atom Imaging Techniques

An (e,2e) study of double excitation-autoionization mechanisms in helium

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