Changeset 0794ce3 in sasview for src/sas/sasgui/perspectives


Ignore:
Timestamp:
Sep 11, 2017 6:10:58 AM (7 years ago)
Author:
lewis
Branches:
master, ESS_GUI, ESS_GUI_Docs, ESS_GUI_batch_fitting, ESS_GUI_bumps_abstraction, ESS_GUI_iss1116, ESS_GUI_iss879, ESS_GUI_iss959, ESS_GUI_opencl, ESS_GUI_ordering, ESS_GUI_sync_sascalc, magnetic_scatt, release-4.2.2, ticket-1009, ticket-1094-headless, ticket-1242-2d-resolution, ticket-1243, ticket-1249, ticket885, unittest-saveload
Children:
fca1f50, d07f863
Parents:
ccf58fb (diff), e2b2473 (diff)
Note: this is a merge changeset, the changes displayed below correspond to the merge itself.
Use the (diff) links above to see all the changes relative to each parent.
Message:

Merge branch 'master' into corfunc3d

Location:
src/sas/sasgui/perspectives/corfunc
Files:
5 edited

Legend:

Unmodified
Added
Removed
  • src/sas/sasgui/perspectives/corfunc/corfunc.py

    r463e7ffc r9b90bf8  
    189189            # Show the transformation as a curve instead of points 
    190190            new_plot.symbol = GUIFRAME_ID.CURVE_SYMBOL_NUM 
     191        elif label == IDF_LABEL: 
     192            new_plot.xaxis("{x}", 'A') 
     193            new_plot.yaxis("{g_1}", '') 
     194            # Linear scale 
     195            new_plot.xtransform = 'x' 
     196            new_plot.ytransform = 'y' 
     197            group_id = GROUP_ID_IDF 
     198            # Show IDF as a curve instead of points 
     199            new_plot.symbol = GUIFRAME_ID.CURVE_SYMBOL_NUM 
    191200        new_plot.id = label 
    192201        new_plot.name = label 
  • src/sas/sasgui/perspectives/corfunc/corfunc_panel.py

    r7432acb r9b90bf8  
    5555        self._data = data # The data to be analysed (corrected fr background) 
    5656        self._extrapolated_data = None # The extrapolated data set 
     57        # Callable object of class CorfuncCalculator._Interpolator representing 
     58        # the extrapolated and interpolated data 
     59        self._extrapolated_fn = None 
    5760        self._transformed_data = None # Fourier trans. of the extrapolated data 
    5861        self._calculator = CorfuncCalculator() 
     
    218221 
    219222        try: 
    220             params, self._extrapolated_data = self._calculator.compute_extrapolation() 
     223            params, self._extrapolated_data, self._extrapolated_fn = \ 
     224                self._calculator.compute_extrapolation() 
    221225        except Exception as e: 
    222226            msg = "Error extrapolating data:\n" 
     
    257261            StatusEvent(status=msg)) 
    258262 
    259     def transform_complete(self, transform=None): 
     263    def transform_complete(self, transforms=None): 
    260264        """ 
    261265        Called from FourierThread when calculation has completed 
    262266        """ 
    263267        self._transform_btn.SetLabel("Transform") 
    264         if transform is None: 
     268        if transforms is None: 
    265269            msg = "Error calculating Transform." 
    266270            if self.transform_type == 'hilbert': 
     
    270274            self._extract_btn.Disable() 
    271275            return 
    272         self._transformed_data = transform 
    273         import numpy as np 
    274         plot_x = transform.x[np.where(transform.x <= 200)] 
    275         plot_y = transform.y[np.where(transform.x <= 200)] 
     276 
     277        self._transformed_data = transforms 
     278        (transform1, transform3, idf) = transforms 
     279        plot_x = transform1.x[transform1.x <= 200] 
     280        plot_y = transform1.y[transform1.x <= 200] 
    276281        self._manager.show_data(Data1D(plot_x, plot_y), TRANSFORM_LABEL1) 
     282        # No need to shorten gamma3 as it's only calculated up to x=200 
     283        self._manager.show_data(transform3, TRANSFORM_LABEL3) 
     284 
     285        plot_x = idf.x[idf.x <= 200] 
     286        plot_y = idf.y[idf.x <= 200] 
     287        self._manager.show_data(Data1D(plot_x, plot_y), IDF_LABEL) 
     288 
    277289        # Only enable extract params button if a fourier trans. has been done 
    278290        if self.transform_type == 'fourier': 
     
    286298        """ 
    287299        try: 
    288             params = self._calculator.extract_parameters(self._transformed_data) 
     300            params = self._calculator.extract_parameters(self._transformed_data[0]) 
    289301        except: 
    290302            params = None 
  • src/sas/sasgui/perspectives/corfunc/corfunc_state.py

    r7432acb r457f735  
    5959        self.q = None 
    6060        self.iq = None 
    61         # TODO: Add extrapolated data and transformed data (when implemented) 
    6261 
    6362    def __str__(self): 
  • src/sas/sasgui/perspectives/corfunc/media/corfunc_help.rst

    r1404cce rd78b5cb  
    1010 
    1111This performs a correlation function analysis of one-dimensional 
    12 SAXS/SANS data, or generates a model-independent volume fraction  
     12SAXS/SANS data, or generates a model-independent volume fraction 
    1313profile from the SANS from an adsorbed polymer/surfactant layer. 
    1414 
    15 A correlation function may be interpreted in terms of an imaginary rod moving  
    16 through the structure of the material. Γ\ :sub:`1D`\ (R) is the probability that  
    17 a rod of length R moving through the material has equal electron/neutron scattering  
    18 length density at either end. Hence a frequently occurring spacing within a structure  
     15A correlation function may be interpreted in terms of an imaginary rod moving 
     16through the structure of the material. Γ\ :sub:`1D`\ (R) is the probability that 
     17a rod of length R moving through the material has equal electron/neutron scattering 
     18length density at either end. Hence a frequently occurring spacing within a structure 
    1919manifests itself as a peak. 
    2020 
     
    3030*  Fourier / Hilbert Transform of the smoothed data to give the correlation 
    3131   function / volume fraction profile, respectively 
    32 *  (Optional) Interpretation of the 1D correlation function based on an ideal  
     32*  (Optional) Interpretation of the 1D correlation function based on an ideal 
    3333   lamellar morphology 
    3434 
     
    7474   :align: center 
    7575 
    76     
     76 
    7777Smoothing 
    7878--------- 
    7979 
    80 The extrapolated data set consists of the Guinier back-extrapolation from Q~0  
     80The extrapolated data set consists of the Guinier back-extrapolation from Q~0 
    8181up to the lowest Q value in the original data, then the original scattering data, and the Porod tail-fit beyond this. The joins between the original data and the Guinier/Porod fits are smoothed using the algorithm below to avoid the formation of ripples in the transformed data. 
    8282 
     
    9393    h_i = \frac{1}{1 + \frac{(x_i-b)^2}{(x_i-a)^2}} 
    9494 
    95          
     95 
    9696Transform 
    9797--------- 
     
    102102If "Fourier" is selected for the transform type, the analysis will perform a 
    103103discrete cosine transform on the extrapolated data in order to calculate the 
    104 correlation function 
     1041D correlation function: 
    105105 
    106106.. math:: 
     
    115115    \left(n + \frac{1}{2} \right) k \right] } \text{ for } k = 0, 1, \ldots, 
    116116    N-1, N 
     117 
     118The 3D correlation function is also calculated: 
     119 
     120.. math:: 
     121    \Gamma _{3D}(R) = \frac{1}{Q^{*}} \int_{0}^{\infty}I(q) q^{2} 
     122    \frac{sin(qR)}{qR} dq 
    117123 
    118124Hilbert 
     
    165171.. figure:: profile1.png 
    166172   :align: center 
    167   
     173 
    168174.. figure:: profile2.png 
    169175   :align: center 
    170     
     176 
    171177 
    172178References 
     
    191197----- 
    192198Upon sending data for correlation function analysis, it will be plotted (minus 
    193 the background value), along with a *red* bar indicating the *upper end of the  
     199the background value), along with a *red* bar indicating the *upper end of the 
    194200low-Q range* (used for back-extrapolation), and 2 *purple* bars indicating the range to be used for forward-extrapolation. These bars may be moved my clicking and 
    195201dragging, or by entering appropriate values in the Q range input boxes. 
     
    221227    :align: center 
    222228 
    223          
     229 
    224230.. note:: 
    225231    This help document was last changed by Steve King, 08Oct2016 
  • src/sas/sasgui/perspectives/corfunc/plot_labels.py

    r1dc8ec9 r7dda833  
    44 
    55GROUP_ID_TRANSFORM = r"$\Gamma(x)$" 
    6 TRANSFORM_LABEL1 = r"$\Gamma1(x)$" 
    7 TRANSFORM_LABEL3 = r"$\Gamma3(x)$" 
     6TRANSFORM_LABEL1 = r"$\Gamma_1(x)$" 
     7TRANSFORM_LABEL3 = r"$\Gamma_3(x)$" 
     8 
     9GROUP_ID_IDF = r"$g_1(x)$" 
     10IDF_LABEL = r"$g_1(x)$" 
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