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package org.rcsb.cif.schema.mm;
import org.rcsb.cif.model.*;
import org.rcsb.cif.schema.*;
import javax.annotation.Generated;
/**
* Data items in the DIFFRN_RADIATION category describe
* the radiation used in measuring the diffraction intensities,
* its collimation and monochromatization before the sample.
*
* Post-sample treatment of the beam is described by data
* items in the DIFFRN_DETECTOR category.
*/
@Generated("org.rcsb.cif.schema.generator.SchemaGenerator")
public class DiffrnRadiation extends DelegatingCategory {
public DiffrnRadiation(Category delegate) {
super(delegate);
}
@Override
protected Column createDelegate(String columnName, Column column) {
switch (columnName) {
case "collimation":
return getCollimation();
case "diffrn_id":
return getDiffrnId();
case "filter_edge":
return getFilterEdge();
case "inhomogeneity":
return getInhomogeneity();
case "monochromator":
return getMonochromator();
case "polarisn_norm":
return getPolarisnNorm();
case "polarisn_ratio":
return getPolarisnRatio();
case "probe":
return getProbe();
case "type":
return getType();
case "xray_symbol":
return getXraySymbol();
case "wavelength_id":
return getWavelengthId();
case "pdbx_monochromatic_or_laue_m_l":
return getPdbxMonochromaticOrLaueML();
case "pdbx_wavelength_list":
return getPdbxWavelengthList();
case "pdbx_wavelength":
return getPdbxWavelength();
case "pdbx_diffrn_protocol":
return getPdbxDiffrnProtocol();
case "pdbx_analyzer":
return getPdbxAnalyzer();
case "pdbx_scattering_type":
return getPdbxScatteringType();
default:
return new DelegatingColumn(column);
}
}
/**
* The collimation or focusing applied to the radiation.
* @return StrColumn
*/
public StrColumn getCollimation() {
return delegate.getColumn("collimation", DelegatingStrColumn::new);
}
/**
* This data item is a pointer to _diffrn.id in the DIFFRN
* category.
* @return StrColumn
*/
public StrColumn getDiffrnId() {
return delegate.getColumn("diffrn_id", DelegatingStrColumn::new);
}
/**
* Absorption edge in angstroms of the radiation filter used.
* @return FloatColumn
*/
public FloatColumn getFilterEdge() {
return delegate.getColumn("filter_edge", DelegatingFloatColumn::new);
}
/**
* Half-width in millimetres of the incident beam in the
* direction perpendicular to the diffraction plane.
* @return FloatColumn
*/
public FloatColumn getInhomogeneity() {
return delegate.getColumn("inhomogeneity", DelegatingFloatColumn::new);
}
/**
* The method used to obtain monochromatic radiation. If a mono-
* chromator crystal is used, the material and the indices of the
* Bragg reflection are specified.
* @return StrColumn
*/
public StrColumn getMonochromator() {
return delegate.getColumn("monochromator", DelegatingStrColumn::new);
}
/**
* The angle in degrees, as viewed from the specimen, between the
* perpendicular component of the polarization and the diffraction
* plane. See _diffrn_radiation.polarisn_ratio.
* @return FloatColumn
*/
public FloatColumn getPolarisnNorm() {
return delegate.getColumn("polarisn_norm", DelegatingFloatColumn::new);
}
/**
* Polarization ratio of the diffraction beam incident on the
* crystal. This is the ratio of the perpendicularly polarized
* to the parallel-polarized component of the radiation. The
* perpendicular component forms an angle of
* _diffrn_radiation.polarisn_norm to the normal to the
* diffraction plane of the sample (i.e. the plane containing
* the incident and reflected beams).
* @return FloatColumn
*/
public FloatColumn getPolarisnRatio() {
return delegate.getColumn("polarisn_ratio", DelegatingFloatColumn::new);
}
/**
* The nature of the radiation used (i.e. the name of the
* subatomic particle or the region of the electromagnetic
* spectrum). It is strongly recommended that this information
* is given, so that the probe radiation can be simply determined.
* @return StrColumn
*/
public StrColumn getProbe() {
return delegate.getColumn("probe", DelegatingStrColumn::new);
}
/**
* The nature of the radiation. This is typically a description
* of the X-ray wavelength in Siegbahn notation.
* @return StrColumn
*/
public StrColumn getType() {
return delegate.getColumn("type", DelegatingStrColumn::new);
}
/**
* The IUPAC symbol for the X-ray wavelength for the probe
* radiation.
* @return StrColumn
*/
public StrColumn getXraySymbol() {
return delegate.getColumn("xray_symbol", DelegatingStrColumn::new);
}
/**
* This data item is a pointer to _diffrn_radiation_wavelength.id
* in the DIFFRN_RADIATION_WAVELENGTH category.
* @return StrColumn
*/
public StrColumn getWavelengthId() {
return delegate.getColumn("wavelength_id", DelegatingStrColumn::new);
}
/**
* Monochromatic or Laue.
* @return StrColumn
*/
public StrColumn getPdbxMonochromaticOrLaueML() {
return delegate.getColumn("pdbx_monochromatic_or_laue_m_l", DelegatingStrColumn::new);
}
/**
* Comma separated list of wavelengths or wavelength range.
* @return StrColumn
*/
public StrColumn getPdbxWavelengthList() {
return delegate.getColumn("pdbx_wavelength_list", DelegatingStrColumn::new);
}
/**
* Wavelength of radiation.
* @return StrColumn
*/
public StrColumn getPdbxWavelength() {
return delegate.getColumn("pdbx_wavelength", DelegatingStrColumn::new);
}
/**
* SINGLE WAVELENGTH, LAUE, or MAD.
* @return StrColumn
*/
public StrColumn getPdbxDiffrnProtocol() {
return delegate.getColumn("pdbx_diffrn_protocol", DelegatingStrColumn::new);
}
/**
* Indicates the method used to obtain monochromatic radiation.
* _diffrn_radiation.monochromator describes the primary beam
* monochromator (pre-specimen monochromation).
* _diffrn_radiation.pdbx_analyzer specifies the
* post-diffraction analyser (post-specimen) monochromation.
* Note that monochromators may have either 'parallel' or
* 'antiparallel' orientation. It is assumed that the
* geometry is parallel unless specified otherwise.
* In a parallel geometry, the position of the monochromator
* allows the incident beam and the final post-specimen
* and post-monochromator beam to be as close to parallel
* as possible. In a parallel geometry, the diffracting
* planes in the specimen and monochromator will be parallel
* when 2*theta(monochromator) is equal to 2*theta (specimen).
* For further discussion see R. Jenkins and R. Snyder,
* Introduction to X-ray Powder Diffraction, Wiley (1996),
* pp. 164-5.
* @return StrColumn
*/
public StrColumn getPdbxAnalyzer() {
return delegate.getColumn("pdbx_analyzer", DelegatingStrColumn::new);
}
/**
* The radiation scattering type for this diffraction data set.
* @return StrColumn
*/
public StrColumn getPdbxScatteringType() {
return delegate.getColumn("pdbx_scattering_type", DelegatingStrColumn::new);
}
}