All Downloads are FREE. Search and download functionalities are using the official Maven repository.

org.eclipse.dawnsci.nexus.NXcrystal Maven / Gradle / Ivy

/*-
 *******************************************************************************
 * Copyright (c) 2015 Diamond Light Source Ltd.
 * All rights reserved. This program and the accompanying materials
 * are made available under the terms of the Eclipse Public License v1.0
 * which accompanies this distribution, and is available at
 * http://www.eclipse.org/legal/epl-v10.html
 *
 * This file was auto-generated from the NXDL XML definition.
 *******************************************************************************/

package org.eclipse.dawnsci.nexus;

import java.util.Map;

import org.eclipse.dawnsci.analysis.api.tree.DataNode;

import org.eclipse.january.dataset.IDataset;

/**
 * A crystal monochromator or analyzer.
 * Permits double bent
 * monochromator comprised of multiple segments with anisotropic
 * Gaussian mosaic.
 * If curvatures are set to zero or are absent, array
 * is considered to be flat.
 * Scattering vector is perpendicular to surface. Crystal is oriented
 * parallel to beam incident on crystal before rotation, and lies in
 * vertical plane.
 * 

Symbols: * These symbols will be used below to coordinate dimensions with the same lengths.

    *
  • n_comp * number of different unit cells to be described
  • *
  • i * number of wavelengths

* */ public interface NXcrystal extends NXobject { public static final String NX_USAGE = "usage"; public static final String NX_TYPE = "type"; public static final String NX_CHEMICAL_FORMULA = "chemical_formula"; public static final String NX_ORDER_NO = "order_no"; public static final String NX_CUT_ANGLE = "cut_angle"; public static final String NX_SPACE_GROUP = "space_group"; public static final String NX_UNIT_CELL = "unit_cell"; public static final String NX_UNIT_CELL_A = "unit_cell_a"; public static final String NX_UNIT_CELL_B = "unit_cell_b"; public static final String NX_UNIT_CELL_C = "unit_cell_c"; public static final String NX_UNIT_CELL_ALPHA = "unit_cell_alpha"; public static final String NX_UNIT_CELL_BETA = "unit_cell_beta"; public static final String NX_UNIT_CELL_GAMMA = "unit_cell_gamma"; public static final String NX_UNIT_CELL_VOLUME = "unit_cell_volume"; public static final String NX_ORIENTATION_MATRIX = "orientation_matrix"; public static final String NX_WAVELENGTH = "wavelength"; public static final String NX_D_SPACING = "d_spacing"; public static final String NX_SCATTERING_VECTOR = "scattering_vector"; public static final String NX_REFLECTION = "reflection"; public static final String NX_THICKNESS = "thickness"; public static final String NX_DENSITY = "density"; public static final String NX_SEGMENT_WIDTH = "segment_width"; public static final String NX_SEGMENT_HEIGHT = "segment_height"; public static final String NX_SEGMENT_THICKNESS = "segment_thickness"; public static final String NX_SEGMENT_GAP = "segment_gap"; public static final String NX_SEGMENT_COLUMNS = "segment_columns"; public static final String NX_SEGMENT_ROWS = "segment_rows"; public static final String NX_MOSAIC_HORIZONTAL = "mosaic_horizontal"; public static final String NX_MOSAIC_VERTICAL = "mosaic_vertical"; public static final String NX_CURVATURE_HORIZONTAL = "curvature_horizontal"; public static final String NX_CURVATURE_VERTICAL = "curvature_vertical"; public static final String NX_IS_CYLINDRICAL = "is_cylindrical"; public static final String NX_CYLINDRICAL_ORIENTATION_ANGLE = "cylindrical_orientation_angle"; public static final String NX_POLAR_ANGLE = "polar_angle"; public static final String NX_AZIMUTHAL_ANGLE = "azimuthal_angle"; public static final String NX_BRAGG_ANGLE = "bragg_angle"; public static final String NX_TEMPERATURE = "temperature"; public static final String NX_TEMPERATURE_COEFFICIENT = "temperature_coefficient"; /** * Position of crystal * * @return the value. */ public NXgeometry getGeometry(); /** * Position of crystal * * @param geometry the geometry */ public void setGeometry(NXgeometry geometry); /** * Get a NXgeometry node by name: *
    *
  • * Position of crystal
  • *
* * @param name the name of the node. * @return a map from node names to the NXgeometry for that node. */ public NXgeometry getGeometry(String name); /** * Set a NXgeometry node by name: *
    *
  • * Position of crystal
  • *
* * @param name the name of the node * @param geometry the value to set */ public void setGeometry(String name, NXgeometry geometry); /** * Get all NXgeometry nodes: *
    *
  • * Position of crystal
  • *
* * @return a map from node names to the NXgeometry for that node. */ public Map getAllGeometry(); /** * Set multiple child nodes of a particular type. *
    *
  • * Position of crystal
  • *
* * @param geometry the child nodes to add */ public void setAllGeometry(Map geometry); /** * How this crystal is used. Choices are in the list. *

* Type: NX_CHAR *

Enumeration:

    *
  • Bragg * reflection geometry
  • *
  • Laue * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * This is the *Hill* system used by Chemical Abstracts. * See, for example: * http://www.iucr.org/__data/iucr/cif/standard/cifstd15.html, * http://www.cas.org/training/stneasytips/subinforformula1.html, * or * http://www.indiana.edu/~cheminfo/courses/471cnfs.html.

*

* * @return the value. */ public IDataset getUsage(); /** * How this crystal is used. Choices are in the list. *

* Type: NX_CHAR *

Enumeration:

    *
  • Bragg * reflection geometry
  • *
  • Laue * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * This is the *Hill* system used by Chemical Abstracts. * See, for example: * http://www.iucr.org/__data/iucr/cif/standard/cifstd15.html, * http://www.cas.org/training/stneasytips/subinforformula1.html, * or * http://www.indiana.edu/~cheminfo/courses/471cnfs.html.

*

* * @param usage the usage */ public DataNode setUsage(IDataset usage); /** * How this crystal is used. Choices are in the list. *

* Type: NX_CHAR *

Enumeration:

    *
  • Bragg * reflection geometry
  • *
  • Laue * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * This is the *Hill* system used by Chemical Abstracts. * See, for example: * http://www.iucr.org/__data/iucr/cif/standard/cifstd15.html, * http://www.cas.org/training/stneasytips/subinforformula1.html, * or * http://www.indiana.edu/~cheminfo/courses/471cnfs.html.

*

* * @return the value. */ public String getUsageScalar(); /** * How this crystal is used. Choices are in the list. *

* Type: NX_CHAR *

Enumeration:

    *
  • Bragg * reflection geometry
  • *
  • Laue * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * This is the *Hill* system used by Chemical Abstracts. * See, for example: * http://www.iucr.org/__data/iucr/cif/standard/cifstd15.html, * http://www.cas.org/training/stneasytips/subinforformula1.html, * or * http://www.indiana.edu/~cheminfo/courses/471cnfs.html.

*

* * @param usage the usage */ public DataNode setUsageScalar(String usage); /** * Type or material of monochromating substance. * Chemical formula can be specified separately. * Use the "reflection" field to indicate the (hkl) orientation. * Use the "d_spacing" field to record the lattice plane spacing. * This field was changed (2010-11-17) from an enumeration to * a string since common usage showed a wider variety of use * than a simple list. These are the items in the list at * the time of the change: PG (Highly Oriented Pyrolytic Graphite) | * Ge | Si | Cu | Fe3Si | CoFe | Cu2MnAl (Heusler) | Multilayer | * Diamond. * * @return the value. */ public IDataset getType(); /** * Type or material of monochromating substance. * Chemical formula can be specified separately. * Use the "reflection" field to indicate the (hkl) orientation. * Use the "d_spacing" field to record the lattice plane spacing. * This field was changed (2010-11-17) from an enumeration to * a string since common usage showed a wider variety of use * than a simple list. These are the items in the list at * the time of the change: PG (Highly Oriented Pyrolytic Graphite) | * Ge | Si | Cu | Fe3Si | CoFe | Cu2MnAl (Heusler) | Multilayer | * Diamond. * * @param type the type */ public DataNode setType(IDataset type); /** * Type or material of monochromating substance. * Chemical formula can be specified separately. * Use the "reflection" field to indicate the (hkl) orientation. * Use the "d_spacing" field to record the lattice plane spacing. * This field was changed (2010-11-17) from an enumeration to * a string since common usage showed a wider variety of use * than a simple list. These are the items in the list at * the time of the change: PG (Highly Oriented Pyrolytic Graphite) | * Ge | Si | Cu | Fe3Si | CoFe | Cu2MnAl (Heusler) | Multilayer | * Diamond. * * @return the value. */ public String getTypeScalar(); /** * Type or material of monochromating substance. * Chemical formula can be specified separately. * Use the "reflection" field to indicate the (hkl) orientation. * Use the "d_spacing" field to record the lattice plane spacing. * This field was changed (2010-11-17) from an enumeration to * a string since common usage showed a wider variety of use * than a simple list. These are the items in the list at * the time of the change: PG (Highly Oriented Pyrolytic Graphite) | * Ge | Si | Cu | Fe3Si | CoFe | Cu2MnAl (Heusler) | Multilayer | * Diamond. * * @param type the type */ public DataNode setTypeScalar(String type); /** * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * * This is the *Hill* system used by Chemical Abstracts. * * @return the value. */ public IDataset getChemical_formula(); /** * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * * This is the *Hill* system used by Chemical Abstracts. * * @param chemical_formula the chemical_formula */ public DataNode setChemical_formula(IDataset chemical_formula); /** * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * * This is the *Hill* system used by Chemical Abstracts. * * @return the value. */ public String getChemical_formulaScalar(); /** * The chemical formula specified using CIF conventions. * Abbreviated version of CIF standard: * * Only recognized element symbols may be used. * * Each element symbol is followed by a 'count' number. A count of '1' may be omitted. * * A space or parenthesis must separate each cluster of (element symbol + count). * * Where a group of elements is enclosed in parentheses, the multiplier for the * group must follow the closing parentheses. That is, all element and group * multipliers are assumed to be printed as subscripted numbers. * * Unless the elements are ordered in a manner that corresponds to their chemical * structure, the order of the elements within any group or moiety depends on * whether or not carbon is present. * * If carbon is present, the order should be: * C, then H, then the other elements in alphabetical order of their symbol. * If carbon is not present, the elements are listed purely in alphabetic * order of their symbol. * * This is the *Hill* system used by Chemical Abstracts. * * @param chemical_formula the chemical_formula */ public DataNode setChemical_formulaScalar(String chemical_formula); /** * A number which describes if this is the first, second,.. * :math:`n^{th}` crystal in a multi crystal monochromator *

* Type: NX_INT *

* * @return the value. */ public IDataset getOrder_no(); /** * A number which describes if this is the first, second,.. * :math:`n^{th}` crystal in a multi crystal monochromator *

* Type: NX_INT *

* * @param order_no the order_no */ public DataNode setOrder_no(IDataset order_no); /** * A number which describes if this is the first, second,.. * :math:`n^{th}` crystal in a multi crystal monochromator *

* Type: NX_INT *

* * @return the value. */ public Long getOrder_noScalar(); /** * A number which describes if this is the first, second,.. * :math:`n^{th}` crystal in a multi crystal monochromator *

* Type: NX_INT *

* * @param order_no the order_no */ public DataNode setOrder_noScalar(Long order_no); /** * Cut angle of reflecting Bragg plane and plane of crystal surface *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getCut_angle(); /** * Cut angle of reflecting Bragg plane and plane of crystal surface *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param cut_angle the cut_angle */ public DataNode setCut_angle(IDataset cut_angle); /** * Cut angle of reflecting Bragg plane and plane of crystal surface *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getCut_angleScalar(); /** * Cut angle of reflecting Bragg plane and plane of crystal surface *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param cut_angle the cut_angle */ public DataNode setCut_angleScalar(Double cut_angle); /** * Space group of crystal structure * * @return the value. */ public IDataset getSpace_group(); /** * Space group of crystal structure * * @param space_group the space_group */ public DataNode setSpace_group(IDataset space_group); /** * Space group of crystal structure * * @return the value. */ public String getSpace_groupScalar(); /** * Space group of crystal structure * * @param space_group the space_group */ public DataNode setSpace_groupScalar(String space_group); /** * Unit cell parameters (lengths and angles) *

* Type: NX_FLOAT * Units: NX_LENGTH * Dimensions: 1: n_comp; 2: 6; *

* * @return the value. */ public IDataset getUnit_cell(); /** * Unit cell parameters (lengths and angles) *

* Type: NX_FLOAT * Units: NX_LENGTH * Dimensions: 1: n_comp; 2: 6; *

* * @param unit_cell the unit_cell */ public DataNode setUnit_cell(IDataset unit_cell); /** * Unit cell parameters (lengths and angles) *

* Type: NX_FLOAT * Units: NX_LENGTH * Dimensions: 1: n_comp; 2: 6; *

* * @return the value. */ public Double getUnit_cellScalar(); /** * Unit cell parameters (lengths and angles) *

* Type: NX_FLOAT * Units: NX_LENGTH * Dimensions: 1: n_comp; 2: 6; *

* * @param unit_cell the unit_cell */ public DataNode setUnit_cellScalar(Double unit_cell); /** * Unit cell lattice parameter: length of side a *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getUnit_cell_a(); /** * Unit cell lattice parameter: length of side a *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param unit_cell_a the unit_cell_a */ public DataNode setUnit_cell_a(IDataset unit_cell_a); /** * Unit cell lattice parameter: length of side a *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getUnit_cell_aScalar(); /** * Unit cell lattice parameter: length of side a *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param unit_cell_a the unit_cell_a */ public DataNode setUnit_cell_aScalar(Double unit_cell_a); /** * Unit cell lattice parameter: length of side b *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getUnit_cell_b(); /** * Unit cell lattice parameter: length of side b *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param unit_cell_b the unit_cell_b */ public DataNode setUnit_cell_b(IDataset unit_cell_b); /** * Unit cell lattice parameter: length of side b *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getUnit_cell_bScalar(); /** * Unit cell lattice parameter: length of side b *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param unit_cell_b the unit_cell_b */ public DataNode setUnit_cell_bScalar(Double unit_cell_b); /** * Unit cell lattice parameter: length of side c *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getUnit_cell_c(); /** * Unit cell lattice parameter: length of side c *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param unit_cell_c the unit_cell_c */ public DataNode setUnit_cell_c(IDataset unit_cell_c); /** * Unit cell lattice parameter: length of side c *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getUnit_cell_cScalar(); /** * Unit cell lattice parameter: length of side c *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param unit_cell_c the unit_cell_c */ public DataNode setUnit_cell_cScalar(Double unit_cell_c); /** * Unit cell lattice parameter: angle alpha *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getUnit_cell_alpha(); /** * Unit cell lattice parameter: angle alpha *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param unit_cell_alpha the unit_cell_alpha */ public DataNode setUnit_cell_alpha(IDataset unit_cell_alpha); /** * Unit cell lattice parameter: angle alpha *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getUnit_cell_alphaScalar(); /** * Unit cell lattice parameter: angle alpha *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param unit_cell_alpha the unit_cell_alpha */ public DataNode setUnit_cell_alphaScalar(Double unit_cell_alpha); /** * Unit cell lattice parameter: angle beta *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getUnit_cell_beta(); /** * Unit cell lattice parameter: angle beta *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param unit_cell_beta the unit_cell_beta */ public DataNode setUnit_cell_beta(IDataset unit_cell_beta); /** * Unit cell lattice parameter: angle beta *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getUnit_cell_betaScalar(); /** * Unit cell lattice parameter: angle beta *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param unit_cell_beta the unit_cell_beta */ public DataNode setUnit_cell_betaScalar(Double unit_cell_beta); /** * Unit cell lattice parameter: angle gamma *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getUnit_cell_gamma(); /** * Unit cell lattice parameter: angle gamma *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param unit_cell_gamma the unit_cell_gamma */ public DataNode setUnit_cell_gamma(IDataset unit_cell_gamma); /** * Unit cell lattice parameter: angle gamma *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getUnit_cell_gammaScalar(); /** * Unit cell lattice parameter: angle gamma *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param unit_cell_gamma the unit_cell_gamma */ public DataNode setUnit_cell_gammaScalar(Double unit_cell_gamma); /** * Volume of the unit cell *

* Type: NX_FLOAT * Units: NX_VOLUME *

* * @return the value. */ public IDataset getUnit_cell_volume(); /** * Volume of the unit cell *

* Type: NX_FLOAT * Units: NX_VOLUME *

* * @param unit_cell_volume the unit_cell_volume */ public DataNode setUnit_cell_volume(IDataset unit_cell_volume); /** * Volume of the unit cell *

* Type: NX_FLOAT * Units: NX_VOLUME *

* * @return the value. */ public Double getUnit_cell_volumeScalar(); /** * Volume of the unit cell *

* Type: NX_FLOAT * Units: NX_VOLUME *

* * @param unit_cell_volume the unit_cell_volume */ public DataNode setUnit_cell_volumeScalar(Double unit_cell_volume); /** * Orientation matrix of single crystal sample using Busing-Levy convention: * W. R. Busing and H. A. Levy (1967). Acta Cryst. 22, 457-464 *

* Type: NX_FLOAT * Dimensions: 1: 3; 2: 3; *

* * @return the value. */ public IDataset getOrientation_matrix(); /** * Orientation matrix of single crystal sample using Busing-Levy convention: * W. R. Busing and H. A. Levy (1967). Acta Cryst. 22, 457-464 *

* Type: NX_FLOAT * Dimensions: 1: 3; 2: 3; *

* * @param orientation_matrix the orientation_matrix */ public DataNode setOrientation_matrix(IDataset orientation_matrix); /** * Orientation matrix of single crystal sample using Busing-Levy convention: * W. R. Busing and H. A. Levy (1967). Acta Cryst. 22, 457-464 *

* Type: NX_FLOAT * Dimensions: 1: 3; 2: 3; *

* * @return the value. */ public Double getOrientation_matrixScalar(); /** * Orientation matrix of single crystal sample using Busing-Levy convention: * W. R. Busing and H. A. Levy (1967). Acta Cryst. 22, 457-464 *

* Type: NX_FLOAT * Dimensions: 1: 3; 2: 3; *

* * @param orientation_matrix the orientation_matrix */ public DataNode setOrientation_matrixScalar(Double orientation_matrix); /** * Optimum diffracted wavelength *

* Type: NX_FLOAT * Units: NX_WAVELENGTH * Dimensions: 1: i; *

* * @return the value. */ public IDataset getWavelength(); /** * Optimum diffracted wavelength *

* Type: NX_FLOAT * Units: NX_WAVELENGTH * Dimensions: 1: i; *

* * @param wavelength the wavelength */ public DataNode setWavelength(IDataset wavelength); /** * Optimum diffracted wavelength *

* Type: NX_FLOAT * Units: NX_WAVELENGTH * Dimensions: 1: i; *

* * @return the value. */ public Double getWavelengthScalar(); /** * Optimum diffracted wavelength *

* Type: NX_FLOAT * Units: NX_WAVELENGTH * Dimensions: 1: i; *

* * @param wavelength the wavelength */ public DataNode setWavelengthScalar(Double wavelength); /** * spacing between crystal planes of the reflection *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getD_spacing(); /** * spacing between crystal planes of the reflection *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param d_spacing the d_spacing */ public DataNode setD_spacing(IDataset d_spacing); /** * spacing between crystal planes of the reflection *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getD_spacingScalar(); /** * spacing between crystal planes of the reflection *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param d_spacing the d_spacing */ public DataNode setD_spacingScalar(Double d_spacing); /** * Scattering vector, Q, of nominal reflection *

* Type: NX_FLOAT * Units: NX_WAVENUMBER *

* * @return the value. */ public IDataset getScattering_vector(); /** * Scattering vector, Q, of nominal reflection *

* Type: NX_FLOAT * Units: NX_WAVENUMBER *

* * @param scattering_vector the scattering_vector */ public DataNode setScattering_vector(IDataset scattering_vector); /** * Scattering vector, Q, of nominal reflection *

* Type: NX_FLOAT * Units: NX_WAVENUMBER *

* * @return the value. */ public Double getScattering_vectorScalar(); /** * Scattering vector, Q, of nominal reflection *

* Type: NX_FLOAT * Units: NX_WAVENUMBER *

* * @param scattering_vector the scattering_vector */ public DataNode setScattering_vectorScalar(Double scattering_vector); /** * Miller indices (hkl) values of nominal reflection *

* Type: NX_INT * Units: NX_UNITLESS * Dimensions: 1: 3; *

* * @return the value. */ public IDataset getReflection(); /** * Miller indices (hkl) values of nominal reflection *

* Type: NX_INT * Units: NX_UNITLESS * Dimensions: 1: 3; *

* * @param reflection the reflection */ public DataNode setReflection(IDataset reflection); /** * Miller indices (hkl) values of nominal reflection *

* Type: NX_INT * Units: NX_UNITLESS * Dimensions: 1: 3; *

* * @return the value. */ public Long getReflectionScalar(); /** * Miller indices (hkl) values of nominal reflection *

* Type: NX_INT * Units: NX_UNITLESS * Dimensions: 1: 3; *

* * @param reflection the reflection */ public DataNode setReflectionScalar(Long reflection); /** * Thickness of the crystal. (Required for Laue orientations - see "usage" field) *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getThickness(); /** * Thickness of the crystal. (Required for Laue orientations - see "usage" field) *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param thickness the thickness */ public DataNode setThickness(IDataset thickness); /** * Thickness of the crystal. (Required for Laue orientations - see "usage" field) *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getThicknessScalar(); /** * Thickness of the crystal. (Required for Laue orientations - see "usage" field) *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param thickness the thickness */ public DataNode setThicknessScalar(Double thickness); /** * mass density of the crystal *

* Type: NX_NUMBER * Units: NX_MASS_DENSITY *

* * @return the value. */ public IDataset getDensity(); /** * mass density of the crystal *

* Type: NX_NUMBER * Units: NX_MASS_DENSITY *

* * @param density the density */ public DataNode setDensity(IDataset density); /** * mass density of the crystal *

* Type: NX_NUMBER * Units: NX_MASS_DENSITY *

* * @return the value. */ public Number getDensityScalar(); /** * mass density of the crystal *

* Type: NX_NUMBER * Units: NX_MASS_DENSITY *

* * @param density the density */ public DataNode setDensityScalar(Number density); /** * Horizontal width of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getSegment_width(); /** * Horizontal width of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_width the segment_width */ public DataNode setSegment_width(IDataset segment_width); /** * Horizontal width of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getSegment_widthScalar(); /** * Horizontal width of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_width the segment_width */ public DataNode setSegment_widthScalar(Double segment_width); /** * Vertical height of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getSegment_height(); /** * Vertical height of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_height the segment_height */ public DataNode setSegment_height(IDataset segment_height); /** * Vertical height of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getSegment_heightScalar(); /** * Vertical height of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_height the segment_height */ public DataNode setSegment_heightScalar(Double segment_height); /** * Thickness of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getSegment_thickness(); /** * Thickness of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_thickness the segment_thickness */ public DataNode setSegment_thickness(IDataset segment_thickness); /** * Thickness of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getSegment_thicknessScalar(); /** * Thickness of individual segment *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_thickness the segment_thickness */ public DataNode setSegment_thicknessScalar(Double segment_thickness); /** * Typical gap between adjacent segments *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getSegment_gap(); /** * Typical gap between adjacent segments *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_gap the segment_gap */ public DataNode setSegment_gap(IDataset segment_gap); /** * Typical gap between adjacent segments *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getSegment_gapScalar(); /** * Typical gap between adjacent segments *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_gap the segment_gap */ public DataNode setSegment_gapScalar(Double segment_gap); /** * number of segment columns in horizontal direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getSegment_columns(); /** * number of segment columns in horizontal direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_columns the segment_columns */ public DataNode setSegment_columns(IDataset segment_columns); /** * number of segment columns in horizontal direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getSegment_columnsScalar(); /** * number of segment columns in horizontal direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_columns the segment_columns */ public DataNode setSegment_columnsScalar(Double segment_columns); /** * number of segment rows in vertical direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public IDataset getSegment_rows(); /** * number of segment rows in vertical direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_rows the segment_rows */ public DataNode setSegment_rows(IDataset segment_rows); /** * number of segment rows in vertical direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @return the value. */ public Double getSegment_rowsScalar(); /** * number of segment rows in vertical direction *

* Type: NX_FLOAT * Units: NX_LENGTH *

* * @param segment_rows the segment_rows */ public DataNode setSegment_rowsScalar(Double segment_rows); /** * horizontal mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getMosaic_horizontal(); /** * horizontal mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param mosaic_horizontal the mosaic_horizontal */ public DataNode setMosaic_horizontal(IDataset mosaic_horizontal); /** * horizontal mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getMosaic_horizontalScalar(); /** * horizontal mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param mosaic_horizontal the mosaic_horizontal */ public DataNode setMosaic_horizontalScalar(Double mosaic_horizontal); /** * vertical mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getMosaic_vertical(); /** * vertical mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param mosaic_vertical the mosaic_vertical */ public DataNode setMosaic_vertical(IDataset mosaic_vertical); /** * vertical mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getMosaic_verticalScalar(); /** * vertical mosaic Full Width Half Maximum *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param mosaic_vertical the mosaic_vertical */ public DataNode setMosaic_verticalScalar(Double mosaic_vertical); /** * Horizontal curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getCurvature_horizontal(); /** * Horizontal curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param curvature_horizontal the curvature_horizontal */ public DataNode setCurvature_horizontal(IDataset curvature_horizontal); /** * Horizontal curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getCurvature_horizontalScalar(); /** * Horizontal curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param curvature_horizontal the curvature_horizontal */ public DataNode setCurvature_horizontalScalar(Double curvature_horizontal); /** * Vertical curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public IDataset getCurvature_vertical(); /** * Vertical curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param curvature_vertical the curvature_vertical */ public DataNode setCurvature_vertical(IDataset curvature_vertical); /** * Vertical curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @return the value. */ public Double getCurvature_verticalScalar(); /** * Vertical curvature of focusing crystal *

* Type: NX_FLOAT * Units: NX_ANGLE *

* * @param curvature_vertical the curvature_vertical */ public DataNode setCurvature_verticalScalar(Double curvature_vertical); /** * Is this crystal bent cylindrically? *

* Type: NX_BOOLEAN *

* * @return the value. */ public IDataset getIs_cylindrical(); /** * Is this crystal bent cylindrically? *

* Type: NX_BOOLEAN *

* * @param is_cylindrical the is_cylindrical */ public DataNode setIs_cylindrical(IDataset is_cylindrical); /** * Is this crystal bent cylindrically? *

* Type: NX_BOOLEAN *

* * @return the value. */ public Boolean getIs_cylindricalScalar(); /** * Is this crystal bent cylindrically? *

* Type: NX_BOOLEAN *

* * @param is_cylindrical the is_cylindrical */ public DataNode setIs_cylindricalScalar(Boolean is_cylindrical); /** * If cylindrical: cylinder orientation angle *

* Type: NX_NUMBER * Units: NX_ANGLE *

* * @return the value. */ public IDataset getCylindrical_orientation_angle(); /** * If cylindrical: cylinder orientation angle *

* Type: NX_NUMBER * Units: NX_ANGLE *

* * @param cylindrical_orientation_angle the cylindrical_orientation_angle */ public DataNode setCylindrical_orientation_angle(IDataset cylindrical_orientation_angle); /** * If cylindrical: cylinder orientation angle *

* Type: NX_NUMBER * Units: NX_ANGLE *

* * @return the value. */ public Number getCylindrical_orientation_angleScalar(); /** * If cylindrical: cylinder orientation angle *

* Type: NX_NUMBER * Units: NX_ANGLE *

* * @param cylindrical_orientation_angle the cylindrical_orientation_angle */ public DataNode setCylindrical_orientation_angleScalar(Number cylindrical_orientation_angle); /** * Polar (scattering) angle at which crystal assembly is positioned. * Note: some instrument geometries call this term 2theta. *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @return the value. */ public IDataset getPolar_angle(); /** * Polar (scattering) angle at which crystal assembly is positioned. * Note: some instrument geometries call this term 2theta. *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @param polar_angle the polar_angle */ public DataNode setPolar_angle(IDataset polar_angle); /** * Polar (scattering) angle at which crystal assembly is positioned. * Note: some instrument geometries call this term 2theta. *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @return the value. */ public Double getPolar_angleScalar(); /** * Polar (scattering) angle at which crystal assembly is positioned. * Note: some instrument geometries call this term 2theta. *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @param polar_angle the polar_angle */ public DataNode setPolar_angleScalar(Double polar_angle); /** * Azimuthal angle at which crystal assembly is positioned *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @return the value. */ public IDataset getAzimuthal_angle(); /** * Azimuthal angle at which crystal assembly is positioned *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @param azimuthal_angle the azimuthal_angle */ public DataNode setAzimuthal_angle(IDataset azimuthal_angle); /** * Azimuthal angle at which crystal assembly is positioned *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @return the value. */ public Double getAzimuthal_angleScalar(); /** * Azimuthal angle at which crystal assembly is positioned *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @param azimuthal_angle the azimuthal_angle */ public DataNode setAzimuthal_angleScalar(Double azimuthal_angle); /** * Bragg angle of nominal reflection *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @return the value. */ public IDataset getBragg_angle(); /** * Bragg angle of nominal reflection *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @param bragg_angle the bragg_angle */ public DataNode setBragg_angle(IDataset bragg_angle); /** * Bragg angle of nominal reflection *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @return the value. */ public Double getBragg_angleScalar(); /** * Bragg angle of nominal reflection *

* Type: NX_FLOAT * Units: NX_ANGLE * Dimensions: 1: i; *

* * @param bragg_angle the bragg_angle */ public DataNode setBragg_angleScalar(Double bragg_angle); /** * average/nominal crystal temperature *

* Type: NX_FLOAT * Units: NX_TEMPERATURE *

* * @return the value. */ public IDataset getTemperature(); /** * average/nominal crystal temperature *

* Type: NX_FLOAT * Units: NX_TEMPERATURE *

* * @param temperature the temperature */ public DataNode setTemperature(IDataset temperature); /** * average/nominal crystal temperature *

* Type: NX_FLOAT * Units: NX_TEMPERATURE *

* * @return the value. */ public Double getTemperatureScalar(); /** * average/nominal crystal temperature *

* Type: NX_FLOAT * Units: NX_TEMPERATURE *

* * @param temperature the temperature */ public DataNode setTemperatureScalar(Double temperature); /** * how lattice parameter changes with temperature *

* Type: NX_FLOAT * Units: NX_ANY *

* * @return the value. */ public IDataset getTemperature_coefficient(); /** * how lattice parameter changes with temperature *

* Type: NX_FLOAT * Units: NX_ANY *

* * @param temperature_coefficient the temperature_coefficient */ public DataNode setTemperature_coefficient(IDataset temperature_coefficient); /** * how lattice parameter changes with temperature *

* Type: NX_FLOAT * Units: NX_ANY *

* * @return the value. */ public Double getTemperature_coefficientScalar(); /** * how lattice parameter changes with temperature *

* Type: NX_FLOAT * Units: NX_ANY *

* * @param temperature_coefficient the temperature_coefficient */ public DataNode setTemperature_coefficientScalar(Double temperature_coefficient); /** * log file of crystal temperature * * @return the value. */ public NXlog getTemperature_log(); /** * log file of crystal temperature * * @param temperature_log the temperature_log */ public void setTemperature_log(NXlog temperature_log); /** * crystal reflectivity versus wavelength * * @return the value. */ public NXdata getReflectivity(); /** * crystal reflectivity versus wavelength * * @param reflectivity the reflectivity */ public void setReflectivity(NXdata reflectivity); /** * crystal transmission versus wavelength * * @return the value. */ public NXdata getTransmission(); /** * crystal transmission versus wavelength * * @param transmission the transmission */ public void setTransmission(NXdata transmission); /** * A NXshape group describing the shape of the crystal arrangement * * @return the value. */ public NXshape getShape(); /** * A NXshape group describing the shape of the crystal arrangement * * @param shape the shape */ public void setShape(NXshape shape); }




© 2015 - 2024 Weber Informatics LLC | Privacy Policy