Many resources are needed to download a project. Please understand that we have to compensate our server costs. Thank you in advance. Project price only 1 $
You can buy this project and download/modify it how often you want.
package org.rcsb.cif.schema.mm;
import org.rcsb.cif.model.*;
import org.rcsb.cif.schema.*;
import javax.annotation.Generated;
/**
* Data items in the REFLNS_SHELL category record details about
* the reflection data used to determine the ATOM_SITE data items
* broken down into shells of resolution.
*/
@Generated("org.rcsb.cif.schema.generator.SchemaGenerator")
public class ReflnsShell extends DelegatingCategory {
public ReflnsShell(Category delegate) {
super(delegate);
}
@Override
protected Column createDelegate(String columnName, Column column) {
switch (columnName) {
case "d_res_high":
return getDResHigh();
case "d_res_low":
return getDResLow();
case "meanI_over_sigI_all":
return getMeanIOverSigIAll();
case "meanI_over_sigI_obs":
return getMeanIOverSigIObs();
case "number_measured_all":
return getNumberMeasuredAll();
case "number_measured_obs":
return getNumberMeasuredObs();
case "number_possible":
return getNumberPossible();
case "number_unique_all":
return getNumberUniqueAll();
case "number_unique_obs":
return getNumberUniqueObs();
case "percent_possible_obs":
return getPercentPossibleObs();
case "Rmerge_F_all":
return getRmergeFAll();
case "Rmerge_F_obs":
return getRmergeFObs();
case "meanI_over_sigI_gt":
return getMeanIOverSigIGt();
case "meanI_over_uI_all":
return getMeanIOverUIAll();
case "meanI_over_uI_gt":
return getMeanIOverUIGt();
case "number_measured_gt":
return getNumberMeasuredGt();
case "number_unique_gt":
return getNumberUniqueGt();
case "percent_possible_gt":
return getPercentPossibleGt();
case "Rmerge_F_gt":
return getRmergeFGt();
case "Rmerge_I_gt":
return getRmergeIGt();
case "pdbx_redundancy":
return getPdbxRedundancy();
case "pdbx_chi_squared":
return getPdbxChiSquared();
case "pdbx_netI_over_sigmaI_all":
return getPdbxNetIOverSigmaIAll();
case "pdbx_netI_over_sigmaI_obs":
return getPdbxNetIOverSigmaIObs();
case "pdbx_Rrim_I_all":
return getPdbxRrimIAll();
case "pdbx_Rpim_I_all":
return getPdbxRpimIAll();
case "pdbx_rejects":
return getPdbxRejects();
case "pdbx_ordinal":
return getPdbxOrdinal();
case "pdbx_diffrn_id":
return getPdbxDiffrnId();
case "pdbx_CC_half":
return getPdbxCCHalf();
case "pdbx_CC_star":
return getPdbxCCStar();
case "pdbx_R_split":
return getPdbxRSplit();
case "pdbx_redundancy_reflns_obs":
return getPdbxRedundancyReflnsObs();
case "pdbx_number_anomalous":
return getPdbxNumberAnomalous();
case "pdbx_Rrim_I_all_anomalous":
return getPdbxRrimIAllAnomalous();
case "pdbx_Rpim_I_all_anomalous":
return getPdbxRpimIAllAnomalous();
case "pdbx_Rmerge_I_all_anomalous":
return getPdbxRmergeIAllAnomalous();
case "percent_possible_all":
return getPercentPossibleAll();
case "Rmerge_I_all":
return getRmergeIAll();
case "Rmerge_I_obs":
return getRmergeIObs();
case "pdbx_Rsym_value":
return getPdbxRsymValue();
case "pdbx_percent_possible_ellipsoidal":
return getPdbxPercentPossibleEllipsoidal();
case "pdbx_percent_possible_spherical":
return getPdbxPercentPossibleSpherical();
case "pdbx_percent_possible_ellipsoidal_anomalous":
return getPdbxPercentPossibleEllipsoidalAnomalous();
case "pdbx_percent_possible_spherical_anomalous":
return getPdbxPercentPossibleSphericalAnomalous();
case "pdbx_redundancy_anomalous":
return getPdbxRedundancyAnomalous();
case "pdbx_CC_half_anomalous":
return getPdbxCCHalfAnomalous();
case "pdbx_absDiff_over_sigma_anomalous":
return getPdbxAbsDiffOverSigmaAnomalous();
case "pdbx_percent_possible_anomalous":
return getPdbxPercentPossibleAnomalous();
default:
return new DelegatingColumn(column);
}
}
/**
* The smallest value in angstroms for the interplanar spacings
* for the reflections in this shell. This is called the highest
* resolution.
* @return FloatColumn
*/
public FloatColumn getDResHigh() {
return delegate.getColumn("d_res_high", DelegatingFloatColumn::new);
}
/**
* The highest value in angstroms for the interplanar spacings
* for the reflections in this shell. This is called the lowest
* resolution.
* @return FloatColumn
*/
public FloatColumn getDResLow() {
return delegate.getColumn("d_res_low", DelegatingFloatColumn::new);
}
/**
* The ratio of the mean of the intensities of all reflections
* in this shell to the mean of the standard uncertainties of the
* intensities of all reflections in this shell.
* @return FloatColumn
*/
public FloatColumn getMeanIOverSigIAll() {
return delegate.getColumn("meanI_over_sigI_all", DelegatingFloatColumn::new);
}
/**
* The ratio of the mean of the intensities of the reflections
* classified as 'observed' (see _reflns.observed_criterion) in
* this shell to the mean of the standard uncertainties of the
* intensities of the 'observed' reflections in this
* shell.
* @return FloatColumn
*/
public FloatColumn getMeanIOverSigIObs() {
return delegate.getColumn("meanI_over_sigI_obs", DelegatingFloatColumn::new);
}
/**
* The total number of reflections measured for this
* shell.
* @return IntColumn
*/
public IntColumn getNumberMeasuredAll() {
return delegate.getColumn("number_measured_all", DelegatingIntColumn::new);
}
/**
* The number of reflections classified as 'observed'
* (see _reflns.observed_criterion) for this
* shell.
* @return IntColumn
*/
public IntColumn getNumberMeasuredObs() {
return delegate.getColumn("number_measured_obs", DelegatingIntColumn::new);
}
/**
* The number of unique reflections it is possible to measure in
* this shell.
* @return IntColumn
*/
public IntColumn getNumberPossible() {
return delegate.getColumn("number_possible", DelegatingIntColumn::new);
}
/**
* The total number of measured reflections which are symmetry-
* unique after merging for this shell.
* @return IntColumn
*/
public IntColumn getNumberUniqueAll() {
return delegate.getColumn("number_unique_all", DelegatingIntColumn::new);
}
/**
* The total number of measured reflections classified as 'observed'
* (see _reflns.observed_criterion) which are symmetry-unique
* after merging for this shell.
* @return IntColumn
*/
public IntColumn getNumberUniqueObs() {
return delegate.getColumn("number_unique_obs", DelegatingIntColumn::new);
}
/**
* The percentage of geometrically possible reflections represented
* by reflections classified as 'observed' (see
* _reflns.observed_criterion) for this shell.
* @return FloatColumn
*/
public FloatColumn getPercentPossibleObs() {
return delegate.getColumn("percent_possible_obs", DelegatingFloatColumn::new);
}
/**
* Residual factor Rmerge for all reflections that satisfy the
* resolution limits established by _reflns_shell.d_res_high and
* _reflns_shell.d_res_low.
*
* sum~i~(sum~j~|F~j~ - <F>|)
* Rmerge(F) = --------------------------
* sum~i~(sum~j~<F>)
*
* F~j~ = the amplitude of the jth observation of reflection i
* <F> = the mean of the amplitudes of all observations of
* reflection i
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection
* @return FloatColumn
*/
public FloatColumn getRmergeFAll() {
return delegate.getColumn("Rmerge_F_all", DelegatingFloatColumn::new);
}
/**
* Residual factor Rmerge for reflections that satisfy the
* resolution limits established by _reflns_shell.d_res_high and
* _reflns_shell.d_res_low and the observation criterion
* established by _reflns.observed_criterion.
*
* sum~i~(sum~j~|F~j~ - <F>|)
* Rmerge(F) = --------------------------
* sum~i~(sum~j~<F>)
*
* F~j~ = the amplitude of the jth observation of reflection i
* <F> = the mean of the amplitudes of all observations of
* reflection i
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection
* @return FloatColumn
*/
public FloatColumn getRmergeFObs() {
return delegate.getColumn("Rmerge_F_obs", DelegatingFloatColumn::new);
}
/**
* The ratio of the mean of the intensities of the significantly
* intense reflections (see _reflns.threshold_expression) in
* this shell to the mean of the standard uncertainties of the
* intensities of the significantly intense reflections in this
* shell.
* @return FloatColumn
*/
public FloatColumn getMeanIOverSigIGt() {
return delegate.getColumn("meanI_over_sigI_gt", DelegatingFloatColumn::new);
}
/**
* The ratio of the mean of the intensities of all reflections
* in this shell to the mean of the standard uncertainties of the
* intensities of all reflections in this shell.
* @return FloatColumn
*/
public FloatColumn getMeanIOverUIAll() {
return delegate.getColumn("meanI_over_uI_all", DelegatingFloatColumn::new);
}
/**
* The ratio of the mean of the intensities of the significantly
* intense reflections (see _reflns.threshold_expression) in
* this shell to the mean of the standard uncertainties of the
* intensities of the significantly intense reflections in this
* shell.
* @return FloatColumn
*/
public FloatColumn getMeanIOverUIGt() {
return delegate.getColumn("meanI_over_uI_gt", DelegatingFloatColumn::new);
}
/**
* The number of significantly intense reflections
* (see _reflns.threshold_expression) measured for this
* shell.
* @return IntColumn
*/
public IntColumn getNumberMeasuredGt() {
return delegate.getColumn("number_measured_gt", DelegatingIntColumn::new);
}
/**
* The total number of significantly intense reflections
* (see _reflns.threshold_expression) resulting from merging
* measured symmetry-equivalent reflections for this resolution
* shell.
* @return IntColumn
*/
public IntColumn getNumberUniqueGt() {
return delegate.getColumn("number_unique_gt", DelegatingIntColumn::new);
}
/**
* The percentage of geometrically possible reflections
* represented by significantly intense reflections
* (see _reflns.threshold_expression) measured for this
* shell.
* @return FloatColumn
*/
public FloatColumn getPercentPossibleGt() {
return delegate.getColumn("percent_possible_gt", DelegatingFloatColumn::new);
}
/**
* The value of Rmerge(F) for significantly intense reflections
* (see _reflns.threshold_expression) in a given shell.
*
* sum~i~ ( sum~j~ | F~j~ - <F> | )
* Rmerge(F) = --------------------------------
* sum~i~ ( sum~j~ <F> )
*
* F~j~ = the amplitude of the jth observation of reflection i
* <F> = the mean of the amplitudes of all observations of
* reflection i
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection.
* @return FloatColumn
*/
public FloatColumn getRmergeFGt() {
return delegate.getColumn("Rmerge_F_gt", DelegatingFloatColumn::new);
}
/**
* The value of Rmerge(I) for significantly intense reflections
* (see _reflns.threshold_expression) in a given shell.
*
* sum~i~ ( sum~j~ | I~j~ - <I> | )
* Rmerge(I) = --------------------------------
* sum~i~ ( sum~j~ <I> )
*
* I~j~ = the intensity of the jth observation of reflection i
* <I> = the mean of the intensities of all observations of
* reflection i
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection.
* @return FloatColumn
*/
public FloatColumn getRmergeIGt() {
return delegate.getColumn("Rmerge_I_gt", DelegatingFloatColumn::new);
}
/**
* Redundancy for the current shell.
* @return FloatColumn
*/
public FloatColumn getPdbxRedundancy() {
return delegate.getColumn("pdbx_redundancy", DelegatingFloatColumn::new);
}
/**
* Chi-squared statistic for this resolution shell.
* @return FloatColumn
*/
public FloatColumn getPdbxChiSquared() {
return delegate.getColumn("pdbx_chi_squared", DelegatingFloatColumn::new);
}
/**
* The mean of the ratio of the intensities to their
* standard uncertainties of all reflections in the
* resolution shell.
*
* _reflns_shell.pdbx_netI_over_sigmaI_all = <I/sigma(I)>
* @return FloatColumn
*/
public FloatColumn getPdbxNetIOverSigmaIAll() {
return delegate.getColumn("pdbx_netI_over_sigmaI_all", DelegatingFloatColumn::new);
}
/**
* The mean of the ratio of the intensities to their
* standard uncertainties of observed reflections
* (see _reflns.observed_criterion) in the resolution shell.
*
* _reflns_shell.pdbx_netI_over_sigmaI_obs = <I/sigma(I)>
* @return FloatColumn
*/
public FloatColumn getPdbxNetIOverSigmaIObs() {
return delegate.getColumn("pdbx_netI_over_sigmaI_obs", DelegatingFloatColumn::new);
}
/**
* The redundancy-independent merging R factor value Rrim,
* also denoted Rmeas, for merging all intensities in a
* given shell.
*
* sum~i~ [N~i~ /( N~i~ - 1)]1/2^ sum~j~ | I~j~ - <I~i~> |
* Rrim = --------------------------------------------------------
* sum~i~ ( sum~j~ I~j~ )
*
* I~j~ = the intensity of the jth observation of reflection i
* <I~i~> = the mean of the intensities of all observations of
* reflection i
* N~i~ = the redundancy (the number of times reflection i
* has been measured).
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection.
*
* Ref: Diederichs, K. & Karplus, P. A. (1997). Nature Struct.
* Biol. 4, 269-275.
* Weiss, M. S. & Hilgenfeld, R. (1997). J. Appl. Cryst.
* 30, 203-205.
* Weiss, M. S. (2001). J. Appl. Cryst. 34, 130-135.
* @return FloatColumn
*/
public FloatColumn getPdbxRrimIAll() {
return delegate.getColumn("pdbx_Rrim_I_all", DelegatingFloatColumn::new);
}
/**
* The precision-indicating merging R factor value Rpim,
* for merging all intensities in a given shell.
*
* sum~i~ [1/(N~i~ - 1)]1/2^ sum~j~ | I~j~ - <I~i~> |
* Rpim = --------------------------------------------------
* sum~i~ ( sum~j~ I~j~ )
*
* I~j~ = the intensity of the jth observation of reflection i
* <I~i~> = the mean of the intensities of all observations of
* reflection i
* N~i~ = the redundancy (the number of times reflection i
* has been measured).
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection.
*
* Ref: Diederichs, K. & Karplus, P. A. (1997). Nature Struct.
* Biol. 4, 269-275.
* Weiss, M. S. & Hilgenfeld, R. (1997). J. Appl. Cryst.
* 30, 203-205.
* Weiss, M. S. (2001). J. Appl. Cryst. 34, 130-135.
* @return FloatColumn
*/
public FloatColumn getPdbxRpimIAll() {
return delegate.getColumn("pdbx_Rpim_I_all", DelegatingFloatColumn::new);
}
/**
* The number of rejected reflections in the resolution
* shell. Reflections may be rejected from scaling
* by setting the observation criterion,
* _reflns.observed_criterion.
* @return IntColumn
*/
public IntColumn getPdbxRejects() {
return delegate.getColumn("pdbx_rejects", DelegatingIntColumn::new);
}
/**
* An ordinal identifier for this resolution shell.
* @return IntColumn
*/
public IntColumn getPdbxOrdinal() {
return delegate.getColumn("pdbx_ordinal", DelegatingIntColumn::new);
}
/**
* An identifier for the diffraction data set corresponding to this resolution shell.
*
* Multiple diffraction data sets specified as a comma separated list.
* @return StrColumn
*/
public StrColumn getPdbxDiffrnId() {
return delegate.getColumn("pdbx_diffrn_id", DelegatingStrColumn::new);
}
/**
* The Pearson's correlation coefficient expressed as a decimal value
* between the average intensities from randomly selected
* half-datasets within the resolution shell.
*
* Ref: Karplus & Diederichs (2012), Science 336, 1030-33
* @return FloatColumn
*/
public FloatColumn getPdbxCCHalf() {
return delegate.getColumn("pdbx_CC_half", DelegatingFloatColumn::new);
}
/**
* Estimates the value of CC_true, the true correlation coefficient
* between the average intensities from randomly selected half-datasets
* within the resolution shell.
*
* CC_star = sqrt(2*CC_half/(1+CC_half))
*
* Ref: Karplus & Diederichs (2012), Science 336, 1030-33
* @return FloatColumn
*/
public FloatColumn getPdbxCCStar() {
return delegate.getColumn("pdbx_CC_star", DelegatingFloatColumn::new);
}
/**
* R split measures the agreement between the sets of intensities created by merging
* odd- and even-numbered images from the data within the resolution shell.
*
* Ref: T. A. White, R. A. Kirian, A. V. Martin, A. Aquila, K. Nass,
* A. Barty and H. N. Chapman (2012), J. Appl. Cryst. 45, 335-341
* @return FloatColumn
*/
public FloatColumn getPdbxRSplit() {
return delegate.getColumn("pdbx_R_split", DelegatingFloatColumn::new);
}
/**
* For this shell, the redundancy in the observed reflections.
* @return FloatColumn
*/
public FloatColumn getPdbxRedundancyReflnsObs() {
return delegate.getColumn("pdbx_redundancy_reflns_obs", DelegatingFloatColumn::new);
}
/**
* This item is a duplicate of _reflns_shell.number_unique_all,
* but only for the observed Friedel pairs.
* @return IntColumn
*/
public IntColumn getPdbxNumberAnomalous() {
return delegate.getColumn("pdbx_number_anomalous", DelegatingIntColumn::new);
}
/**
* This item is the duplicate of _reflns_shell.pdbx_Rrim_I_all, but
* is limited to observed Friedel pairs.
* @return FloatColumn
*/
public FloatColumn getPdbxRrimIAllAnomalous() {
return delegate.getColumn("pdbx_Rrim_I_all_anomalous", DelegatingFloatColumn::new);
}
/**
* This item serves the same purpose as
* _reflns_shell.pdbx_Rpim_I_all, but applies to observed Friedel pairs
* only.
* @return FloatColumn
*/
public FloatColumn getPdbxRpimIAllAnomalous() {
return delegate.getColumn("pdbx_Rpim_I_all_anomalous", DelegatingFloatColumn::new);
}
/**
* This item is the same as _reflns_shell.pdbx_Rmerge_I_all, but
* applies to observed Friedel pairs only.
* @return FloatColumn
*/
public FloatColumn getPdbxRmergeIAllAnomalous() {
return delegate.getColumn("pdbx_Rmerge_I_all_anomalous", DelegatingFloatColumn::new);
}
/**
* The percentage of geometrically possible reflections represented
* by all reflections measured for this shell.
* @return FloatColumn
*/
public FloatColumn getPercentPossibleAll() {
return delegate.getColumn("percent_possible_all", DelegatingFloatColumn::new);
}
/**
* The value of Rmerge(I) for all reflections in a given shell.
*
* sum~i~(sum~j~|I~j~ - <I>|)
* Rmerge(I) = --------------------------
* sum~i~(sum~j~<I>)
*
* I~j~ = the intensity of the jth observation of reflection i
* <I> = the mean of the intensities of all observations of
* reflection i
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection
* @return FloatColumn
*/
public FloatColumn getRmergeIAll() {
return delegate.getColumn("Rmerge_I_all", DelegatingFloatColumn::new);
}
/**
* The value of Rmerge(I) for reflections classified as 'observed'
* (see _reflns.observed_criterion) in a given shell.
*
* sum~i~(sum~j~|I~j~ - <I>|)
* Rmerge(I) = --------------------------
* sum~i~(sum~j~<I>)
*
* I~j~ = the intensity of the jth observation of reflection i
* <I> = the mean of the intensities of all observations of
* reflection i
*
* sum~i~ is taken over all reflections
* sum~j~ is taken over all observations of each reflection
* @return FloatColumn
*/
public FloatColumn getRmergeIObs() {
return delegate.getColumn("Rmerge_I_obs", DelegatingFloatColumn::new);
}
/**
* R sym value in percent.
* @return FloatColumn
*/
public FloatColumn getPdbxRsymValue() {
return delegate.getColumn("pdbx_Rsym_value", DelegatingFloatColumn::new);
}
/**
* Completeness (as a percentage) of symmetry-unique data
* within the intersection of (1) a spherical shell
* (defined by its diffraction limits,
* _reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low) and (2) the ellipsoid
* (described by __reflns.pdbx_aniso_diffraction_limit_*
* items), relative to all possible symmetry-unique
* reflections within that intersection.
* @return FloatColumn
*/
public FloatColumn getPdbxPercentPossibleEllipsoidal() {
return delegate.getColumn("pdbx_percent_possible_ellipsoidal", DelegatingFloatColumn::new);
}
/**
* Completeness (as a percentage) of symmetry-unique data
* within the spherical shell defined by its diffraction
* limits (_reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low) relative to all
* possible symmetry-unique reflections within that shell.
*
* In the absence of an anisotropy description this is
* identical to _reflns_shell.percent_possible_all.
* @return FloatColumn
*/
public FloatColumn getPdbxPercentPossibleSpherical() {
return delegate.getColumn("pdbx_percent_possible_spherical", DelegatingFloatColumn::new);
}
/**
* Completeness (as a percentage) of symmetry-unique
* anomalous difference data within the intersection of
* (1) a spherical shell (defined by its diffraction
* limits, _reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low) and (2) the ellipsoid
* (described by __reflns.pdbx_aniso_diffraction_limit_*
* items), relative to all possible symmetry-unique
* anomalous difference data within that intersection.
* @return FloatColumn
*/
public FloatColumn getPdbxPercentPossibleEllipsoidalAnomalous() {
return delegate.getColumn("pdbx_percent_possible_ellipsoidal_anomalous", DelegatingFloatColumn::new);
}
/**
* Completeness (as a percentage) of symmetry-unique
* anomalous difference data within the spherical shell
* defined by its diffraction limits
* (_reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low) relative to all
* possible symmetry-unique anomalous difference data
* within that shell.
*
* In the absence of an anisotropy description this is
* identical to _reflns.pdbx_percent_possible_anomalous.
* @return FloatColumn
*/
public FloatColumn getPdbxPercentPossibleSphericalAnomalous() {
return delegate.getColumn("pdbx_percent_possible_spherical_anomalous", DelegatingFloatColumn::new);
}
/**
* The redundancy of anomalous difference data within the
* spherical shell (defined by its diffraction limits
* _reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low), i.e. data for which
* intensities for both instances of a Friedel pair are
* available for an acentric reflection.
* @return FloatColumn
*/
public FloatColumn getPdbxRedundancyAnomalous() {
return delegate.getColumn("pdbx_redundancy_anomalous", DelegatingFloatColumn::new);
}
/**
* The correlation coefficient within the spherical shell
* (defined by its diffraction limits
* _reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low) between two randomly
* chosen half-sets of anomalous intensity differences,
* I(+)-I(-) for anomalous data, i.e. data for which
* intensities for both instances of a Friedel pair are
* available for an acentric reflection.
* @return FloatColumn
*/
public FloatColumn getPdbxCCHalfAnomalous() {
return delegate.getColumn("pdbx_CC_half_anomalous", DelegatingFloatColumn::new);
}
/**
* The mean ratio of absolute anomalous intensity
* differences to their standard deviation within the
* spherical shell (defined by its diffraction limits
* _reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low).
*
* |Dano|
* -------------
* sigma(Dano)
*
* with
*
* Dano = I(+) - I(-)
* sigma(Dano) = sqrt( sigma(I(+))^2 + sigma(I(-))^2 )
* @return FloatColumn
*/
public FloatColumn getPdbxAbsDiffOverSigmaAnomalous() {
return delegate.getColumn("pdbx_absDiff_over_sigma_anomalous", DelegatingFloatColumn::new);
}
/**
* Completeness (as a percentage) of symmetry-unique
* anomalous difference data within the spherical shell
* defined by its diffraction limits
* (_reflns_shell.d_resolution_high and
* _reflns_shell.d_resolution_low) relative to all
* possible symmetry-unique anomalous difference data
* within that shell.
* @return FloatColumn
*/
public FloatColumn getPdbxPercentPossibleAnomalous() {
return delegate.getColumn("pdbx_percent_possible_anomalous", DelegatingFloatColumn::new);
}
}