Beginners Guide / Help
======================
.. automodule:: jscatter
    :noindex:


**Analysis of data consists of several steps that can be done with Jscatter** :

* Reading of measured data
* Define a model
* Fit your model (test if it describes data)
* Save results !!!

These are described in the following.

**Some places to start with Python/Numpy/SciPy** :

- `Python-Numpy-Tutorial <http://cs231n.github.io/python-numpy-tutorial/>`_ A **crash course** with contents as :

 - Basic data types, Containers (Lists, Dictionaries, Sets, Tuples), Functions, Classes
 - Numpy, Arrays, indexing, Datatypes, Array math, Broadcasting

- `The Python Tutorial <https://docs.python.org/3/tutorial/>`_
- `Numpy Quickstart tutorial <https://docs.scipy.org/doc/numpy/user/quickstart.html>`_
- `SciPy : high-level scientific computing <https://scipy-lectures.org/intro>`_

.. |binder| image:: https://img.shields.io/badge/launch-jscatter-F5A252.svg?logo=data:image/png;base64,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
            :alt: link to mybinder
            :target: https://mybinder.org/v2/gl/biehl%2Fjscatter/master?filepath=src%2Fjscatter%2Fexamples%2Fnotebooks


**How to use, get help and command expansion**

Jscatter works in a `terminal/shell <http://linuxcommand.org/lc3_learning_the_shell.php>`_ (open it)
as basis without a graphical user interface (GUI).

For convenience we use Ipython (colors highlighting, history, ...), start it typing "ipython" in a terminal.

Optionally Jscatter can also be run in an environment like Jupyter (see :ref:`Jupyter Notebook`).
Give it a try using a live demo in a Jupyter Notebook at |binder| to test Jscatter.


In a shell some simple things help the user.

- The Python docstring of a function can be retrieved by *help(command)*
- The 'TAB' can be used to expand a command or get the list of possible methods/attributes
- Just typing the name of an object returns a short representation e.g. the content of a dataarray.
- js.showDoc() opens the documentation in a web browser.

::

 import jscatter as js
 i5 = js.dL(js.examples.datapath + '/iqt_1hho.dat')

 # try with some data from below
 help(i5.fit)

 # command completion by *TAB*
 i5.a    # write this and press 2x *TAB* to get *append, aslist, attr*

 # show string representation
 i5

 js.showDoc()

What are dataArray/dataList
---------------------------
:ref:`dataArray` is a container for matrix like data like a spreadsheet.
Additional to the entries in the spreadsheet we have attributes describing metadata like
the temperature of the measurement related to the spreadsheet data accessible as ``data.temperature``.

:ref:`dataList` is a container for a list of *dataArrays* with variable size
e.g. for repeated measurements or a temperature rise.

In most cases these data are read from a file, as it was stored from an measurement/instrument.

See :ref:`dataArray` and :ref:`dataList` how to create and use both. In short: ::

 import jscatter as js
 import numpy as np

 x=np.r_[0:10:0.5]                                  # creates a 1dim numpy array
 matrix = np.c_[x, x**2, 1.234*np.sin(3.141*x)].T   # creates a matrix with x in columns
 data0 = js.dA(matrix)                              # creates dataArray from above matrix
 data0.temperature = 273.15                         # adds attribut temperature

 data1 = js.dL()                                    # empty dataList
 for i in [1,2,3,4,5]:                              # add several dataArrays
    # internal a dataarray is created and appended
    data1.append(np.c_[x, x**2+i, 1.234*np.sin(i*3.141*x)].T)

*dataArray/dataList* have additional methods to treat the contained data.
This might be simple mathematical operations like *add* a value to a column or summing,
averaging, adding another array of data as inherited from *numpy arrays*
or methods for fitting and interpolation.




First basic examples
--------------------
This shows the basic reading and fitting of some data as a starting point.

Details of all commands are explained later or in respective chapters.


A parabolic fit
^^^^^^^^^^^^^^^
A simple example without additional stuff as a skeleton. Additional possibilities are shown later. ::

 import jscatter as js
 import numpy as np

 # load data into a dataArray
 data=js.dA(js.examples.datapath+'/exampledata0.dat')

 # Look at some attributes that were stored in the read data
 data.attr            # shows a list of attributes as below
 data.temperature     # contains the temperature found in the file
 data.comment         # contains a comment

 # define model like a mathematical function y = f(q,a,b,c)
 # test this using e.g parabola(data.X,1,2,3)
 def parabola(q,a,b,c):
    # q values as numpy array (a list of values), the model returns an array (the y values)
    y = (q-a)**2+b*q+c
    return y

 # fit the data defining free parameters, fixed parameters and map model names to data names.
 # (map data 'X' values (array) to model 'q' parameter.)
 data.fit( model=parabola ,freepar={'a':2,'b':4}, fixpar={'c':-20}, mapNames={'q':'X'})
 data.showlastErrPlot()

 # map additionally the 'temperature' in the data for parameter 'c'.
 data.fit( model=parabola ,freepar={'a':2,'b':4}, fixpar={}, mapNames={'q':'X','c':'temperature'})

 # make nice plot with data and fit
 p=js.grace(1,1)
 p.plot(data)
 p.plot(data.lastfit,line=1,symbol=0)       # add result in lastfit
 p.title('Noisy parabola')

.. image:: ../../examples/basicExamples0.png
    :align: left
    :width: 300px
    :alt: Basic Example

.. image:: ../../examples/basicExamples0.lastfit.png
    :align: center
    :width: 300px
    :alt: Basic Example

A bit more complex data
^^^^^^^^^^^^^^^^^^^^^^^
Here we introduce more possibilities and concepts how to treat the data and introduce models.

- Use  a model from the libraries or change it to your needs.
- Fit with a condition
- Simulate fit result with changed parameters.
- Use a vectorized quadrature to include the distribution of a parameter.
- Access the fit result

The used data relate to small angle scattering of **spherical particles in solvent**
with a polydispersity in radius. ::

 import jscatter as js
 import numpy as np

 # load data
 data=js.dA(js.examples.datapath+'/exampledata.dat')

 # plot data
 p=js.grace(1,1)
 p.plot(data,le='my data')
 p.yaxis(scale='l',label='I(Q) / cm\S-1',size=1.5)
 p.xaxis(min=0.1,max=4,scale='l',label='Q / nm\S-1',size=1.5)
 p.title('Measurement of spheres')

 # use Guinier model from module formfactor (shortcut ff) as first size estimate in limited range q<1/Rg
 # fit it (with start values) and show result
 data.fit(js.ff.guinier,freepar={'Rg':5,'A':1},
                        fixpar={},
                        mapNames={'q':'X'},
                        condition=lambda a:a.X<1/7.)

 # show fit result (The ErrPlot is reused in next fits)
 data.showlastErrPlot(yscale='log',fitlinecolor=5)

 # compare to full dataset in above plot
 # modelValues recalcs fit result with optional changed parameters (here larger q range)
 p.plot( data.modelValues(q=np.r_[0.1:1:0.02]), line=[1,3,2], symbol=0, legend='fit Guinier')
 p.legend(x=0.8,y=1e6)          # update legend with position

 # define monodisperse sphere model adding amplitude and background
 # jscatter models return dataArray with X, Y and more attributes
 # you may return just an array
 def sphere(q,R,A,bgr):
    result=A*js.ff.sphere(q=q,radius=R).Y+bgr
    return result

 # use sphere model (keywords as *freepar* can be dropped if order of keywords is preserved)
 data.fit(sphere,{'R':5,'A':1,'bgr':50},{},{'q':'X'})

 p.plot(data.modelValues(q=data.X), li=[1,3,3], sy=0, le='fit sphere')
 p.legend()

 # define better sphere model with polydisperse radius
 # here we reuse the returned dataArray (which includes attributes) and add bgr attribute.
 def psphere(q,R,A,bgr,dR):
    # dR is radius width of a Gaussian centered at R (see doc of pDA)
    result=js.formel.pDA(js.ff.sphere,dR,'radius',q=q,radius=R)
    result.Y = A * result.Y + bgr
    result.bgr = bgr
    return result

 # use the polydisperse sphere model
 data.fit(psphere,{'R':5,'A':1,'bgr':50,'dR':1},{},{'q':'X'})

 p.plot(data.modelValues(q=np.r_[0.1:4:0.04]), li=[1,3,4], sy=0, le='fit polydisperse sphere')
 p.legend(x=0.8,y=1e6)
 p.xaxis(min=0.1,max=4)
 # p.save('myevaluation.agr')
 # p.save('myevaluation.png')

 # look at result with parameters with errors
 data.lastfit          # model data
 data.lastfit.R        # fit parameter
 data.lastfit.R_err    # fit parameter 1-sigma error
 data.lastfit.dR
 data.lastfit.dR_err

 # save the fit result including the fit parameters, errors and covariance matrix
 data.lastfit.save('myevaluationfitresult.dat')

.. image:: ../../examples/basicExamples.png
    :align: center
    :height: 300px
    :alt: Basic Example


Reading ASCII files
-------------------
A common problem is how to read ASCII files with data as the format is often not
very intuitive designed. Often there is additional metadata before or after a matrix like block or in the filename.

Jscatter uses a simple concept to classify lines :

* 2 numbers at the beginning of a line are **data** (matrix like data block).
* a name followed by a number (and more) is an **attribute** with name and content.
* everything else is **comment** (but can later be converted to an attribute).
* The filename is **always** stored in attribute ``.name``

 A new dataArray is created if, while reading a file, a data block with an attribute block
 (preceded or appended) is found or a keyword indicates it (see :py:class:`~dataarray.dataList`).

Even complex ASCII files can be read with a few changes given as options to fit into this concept.
New attributes can be generated from content of the comments if not detected automatically.
This can be done during reading using some simple options in *dataArray/dataList* creation:

- dataArray (js.dA) reads **one** dataset from a file. ::

    # create single dataArray from file
    dat=js.dA('singledatafilename.dat')            # take dataset in file
    dat=js.dA('multidatafilename.dat',index=2)     # take dataset index=3 in file (indices start with 0)


- dataList  (js.dL) reads **all** datasets from one/multiple files (may differ in shape) ::

   # create dataList
   data=js.dL('../data/latest_0001.dat')          # read all dataset in file
   data=js.dL('../data/latest_0001.dat',index=2)  # select only the second dataset in the file
   data.append(dat)                               # append single dataArray read from above

  **Read all, filter later**
  Create dataList from multiple files (uses `glob <https://docs.python.org/2/library/glob.html#module-glob>`_ patterns) ::


   data=js.dL('../data/latest*.dat')              # reads all '.dat' files starting with 'latest' in data folder.
   # filter according to attributes or name
   data2=data.filter(lambda a:a.name.startswith('latest_conc2') & (a.Temp>100))
   data3=data[1:-1:3]                             # drop first and last and use only each 3rd

   # same with glob (using name patterns as ?,*) treating
   import glob
   data=js.dL()  # empty dataList
   for filename in glob.glob('../data/latest*.dat'):
      data.append(filename)                       # you may add options

   # add attributes e.g. from filename or comments
   for dat in data:
      dat.Temp=float(dat.name.split('_')[2])     # extract attribute from name (which is always the filename read from)
      dat.pressure=dat.comment[1].split()[1]     # if second comment line contains 'pressure 1000 mbar'

****

Options to use:

* ``replace={‘old’:’new’,’,’:’.’}``     ==>  replace char and strings
* ``skiplines=lambda words: any(w in words for w in [‘’,’ ‘,’NAN’,’*’])``  ==> skip complete bad lines
* ``takeline='ATOM'``   ==> select specific lines
* ``ignore='#'``       ==> skip lines starting with this character
* ``usecols=[1,2,5]``  ==> select specific columns
* ``lines2parameter=[2,3,4]``  ==> use these data lines as comment and not as data.

See :py:func:`~dataarray.dataArray` for all options and how to use them.

- If there is more information in comments or filename this can be extracted by using the comment lines.
   * ``data.getfromcomment('nameatfirstcolumn')`` ==> extract a list of words in this line
   * ``data.name``  ==> filename, see below examples.
- Set columns for *X,.Y,.Z,.W* and respective errors by ``data.setColumnIndex(ix=2,iy=4,iey=None)`` to pick the columns
  that are for interest. See :ref:`Manipulating dataArray/dataList`

**How to extract information from comment lines** ::

 # lines as 'pressure 1013 14' are used automatically to set an attribute as .pressure
 # if data.name is a string as 'adh_Temp273_conc02.dat' extract Temp and conc like
 temp=data.name.split('_')
 data.Temp=float(temp[1][4:])
 data.conc=float(temp[2][4:6])
 #
 # if same line is in comment use
 temp=data.comment[0].split('_')
 # or use data.getfromComment(...)



**Some examples and how to read them**

filename: data1_273K_10mM.dat (e.g. Instrument JNSE@MLZ, Garching) ::

 this is just a comment or description of the data
 temp     293
 pressure 1013 14
 detectorsetting up
 name     temp1bsa
 0.854979E-01  0.178301E+03  0.383044E+02
 0.882382E-01  0.156139E+03  0.135279E+02
 0.909785E-01  0.150313E+03  0.110681E+02
 0.937188E-01  0.147430E+03  0.954762E+01
 0.964591E-01  0.141615E+03  0.846613E+01
 0.991995E-01  0.141024E+03  0.750891E+01
 0.101940E+00  0.135792E+03  0.685011E+01
 0.104680E+00  0.140996E+03  0.607993E+01

Read by ::

 data=js.dA('data1_273K_10mM.dat')
 data.getfromComment('detectorsetting')           # creates attribute detectorsetting with string value 'up' found in comments
 data.Temp=float(data.name.split('_')[1][:-1])    # extracts the temperature from filename
 data.conc=float(data.name.split('_')[2][:-2])    # same for concentration
 data.pressure[0]                                 # use pressure value 1013 # this was created automatically
 data.Temp                                        # use temperature value   # this was created explicit

NSE measurement from IN15 at ILL Grenoble ::

 ftime         	E_SUM       	EERR_SUM    	EQ_0.0596   	EERRQ_0.0596	EQ_0.0662   	EERRQ_0.0662	EQ_0.0728   	EERRQ_0.0728	EQ_0.0793   	EERRQ_0.0793	EQ_0.0859   	EERRQ_0.0859
 Amplitude   	 -1.0000e+00	  0.0000e+00	  3.3149e+00	  1.9984e-03	  3.4203e+00	  2.0375e-03	  3.2560e+00	  1.9803e-03	  2.7188e+00	  1.8161e-03	  1.8634e+00	  1.5032e-03
 Polarisation	 -1.0000e+00	  0.0000e+00	  2.3719e+00	  4.4403e-03	  2.3723e+00	  4.6673e-03	  2.1675e+00	  4.6726e-03	  1.7156e+00	  4.4392e-03	  1.1127e+00	  3.7890e-03
  0.0000e+00	  1.0000e+00	  1.0318e-03	  1.0000e+00	  1.9261e-03	  1.0000e+00	  2.0252e-03	  1.0000e+00	  2.2186e-03	  1.0000e+00	  2.6615e-03	  1.0000e+00	  3.4992e-03
  2.2428e-01	  9.7447e-01	  3.4201e-03	  9.7363e-01	  6.3708e-03	  9.7026e-01	  6.6990e-03	  9.8392e-01	  7.3605e-03	  9.8819e-01	  8.8623e-03	  9.5632e-01	  1.1831e-02
  2.9474e-01	  9.8425e-01	  3.3694e-03	  9.9020e-01	  6.1962e-03	  9.7785e-01	  6.5809e-03	  9.9125e-01	  7.2723e-03	  9.8005e-01	  8.8698e-03	  9.9022e-01	  1.1909e-02
  3.6520e-01	  9.7910e-01	  3.3071e-03	  9.8269e-01	  6.0875e-03	  9.8190e-01	  6.4363e-03	  9.7275e-01	  7.1155e-03	  9.8566e-01	  8.7117e-03	  9.7766e-01	  1.1829e-02
  5.0612e-01	  9.7927e-01	  3.2226e-03	  9.7898e-01	  5.9112e-03	  9.7517e-01	  6.2379e-03	  9.8108e-01	  6.9563e-03	  9.8669e-01	  8.5569e-03	  9.8611e-01	  1.1557e-02
  ...

Read by ::

 # column 1,2 are averages over following columns. First line contains q values
 data=js.dL()   # empty dataList
 temp=js.dA('017112345.txt')         # read all then sort later
 for i in [3,5,7,9]:
    data.append(temp[[0,i,i+1]])
    data[-1].Amplitude=temp.Amplitude[i-1:i+1]
    data[-1].Polarisation=temp.Polarisation[i-1:i+1]
    data[-1].q=float(temp.comment[0].split()[i].split('_')[1])


aspirin.pdb: Atomic coordinates for aspirin (`AIN <http://ligand-expo.rcsb.org/reports/A/AIN/AIN_ideal.pdb>`_ from `Protein Data Bank, PDB <http://www.rcsb.org/ligand/AIN>`_ )::

 Header
 Remarks blabla
 Remarks in pdb files are sometimes more than 100 lines
 ATOM      1  O1  AIN A   1       1.731   0.062  -2.912  1.00 10.00           O
 ATOM      2  C7  AIN A   1       1.411   0.021  -1.604  1.00 10.00           C
 ATOM      3  O2  AIN A   1       2.289   0.006  -0.764  1.00 10.00           O
 ATOM      4  C3  AIN A   1      -0.003  -0.006  -1.191  1.00 10.00           C
 ATOM      5  C4  AIN A   1      -1.016   0.010  -2.153  1.00 10.00           C
 ATOM      6  C5  AIN A   1      -2.337  -0.015  -1.761  1.00 10.00           C
 ATOM      7  C6  AIN A   1      -2.666  -0.063  -0.416  1.00 10.00           C
 ATOM      8  C1  AIN A   1      -1.675  -0.085   0.544  1.00 10.00           C
 ATOM      9  C2  AIN A   1      -0.340  -0.060   0.168  1.00 10.00           C
 ATOM     10  O3  AIN A   1       0.634  -0.083   1.111  1.00 10.00           O
 ATOM     11  C8  AIN A   1       0.314   0.035   2.410  1.00 10.00           C
 ATOM     12  O4  AIN A   1      -0.824   0.277   2.732  1.00 10.00           O
 ATOM     13  C9  AIN A   1       1.376  -0.134   3.466  1.00 10.00           C
 ATOM     14  HO1 AIN A   1       2.659   0.080  -3.183  1.00 10.00           H
 ATOM     15  H4  AIN A   1      -0.765   0.047  -3.203  1.00 10.00           H
 ATOM     16  H5  AIN A   1      -3.119   0.001  -2.505  1.00 10.00           H
 ATOM     17  H6  AIN A   1      -3.704  -0.082  -0.117  1.00 10.00           H
 ATOM     18  H1  AIN A   1      -1.939  -0.123   1.591  1.00 10.00           H
 ATOM     19  H91 AIN A   1       0.931  -0.004   4.453  1.00 10.00           H
 ATOM     20  H92 AIN A   1       1.807  -1.133   3.391  1.00 10.00           H
 ATOM     21  H93 AIN A   1       2.158   0.610   3.318  1.00 10.00           H
 CONECT    1    2   14 may appear at the end
 HETATOM lines may appear at the end
 END

Read by (several methods): ::

 # 1.
 # take 'ATOM' lines, but only column 6-8 as x,y,z coordinates.
 js.dA(js.examples.datapath+'/AIN_ideal.pdb',takeline='ATOM',replace={'ATOM':'0'},usecols=[6,7,8])
 # 2.
 # replace 'ATOM' string by number and set XYZ for convenience
 js.dA(js.examples.datapath+'/AIN_ideal.pdb',replace={'ATOM':'0'},usecols=[6,7,8],XYeYeX=[0,1,None,None,2])
 # 3.
 # only the Oxygen atoms
 js.dA(js.examples.datapath+'/AIN_ideal.pdb',takeline=lambda w:(w[0]=='ATOM') & (w[2][0]=='O'),replace={'ATOM':'0'},usecols=[6,7,8])
 # 4.
 # using regular expressions we can decode the atom specifier into a scattering length
 import re
 rHO=re.compile('HO\d') # 14 is HO1
 rH=re.compile('H\d+')  # represents something like 'H11' or 'H1' see regular expressions
 rC=re.compile('C\d+')
 rO=re.compile('O\d+')
 # replace atom specifier by number and use it as last column
 ain=js.dA(js.examples.datapath+'/AIN_ideal.pdb',replace={'ATOM':'0',rC:1,rH:5,rO:2,rHO:5},usecols=[6,7,8,2],XYeYeX=[0,1,None,None,2])
 # 5.
 # read only atoms and use it to retrieve atom data from js.formel.Elements
 atoms=js.dA('AIN_ideal.pdb',replace={'ATOM':'0'},usecols=[2],XYeYeX=[0,1,None,None,2])[0].array
 al=[js.formel.Elements[a[0].lower()] for a in atoms]

data2.txt::

 # this is just a comment or description of the data
 # temp     ;    293
 # pressure ; 1013 14  bar
 # name     ; temp1bsa
 &doit
 0,854979E-01  0,178301E+03  0,383044E+02
 0,882382E-01  0,156139E+03  0,135279E+02
 0,909785E-01  *             0,110681E+02
 0,937188E-01  0,147430E+03  0,954762E+01
 0,964591E-01  0,141615E+03  0,846613E+01
 nan           nan           0

Read by ::

 # ignore is by default '#', so switch it of
 # skip lines with non numbers in data
 # replace some char by others or remove by replacing with empty string ''.
 js.dA('data2.txt',replace={'#':'',';':'',',':'.'},skiplines=[‘*’,'nan'],ignore='' )


pdh format used in some SAXS instruments (first real data point is line 4)::

 SAXS BOX
       2057         0         0         0         0         0         0         0
   0.000000E+00   3.053389E+02   0.000000E+00   1.000000E+00   1.541800E-01
   0.000000E+00   1.332462E+00   0.000000E+00   0.000000E+00   0.000000E+00
 -1.069281E-01   2.277691E+03   1.168599E+00
 -1.037351E-01   2.239132E+03   1.275602E+00
 -1.005422E-01   2.239534E+03   1.068182E+00
 -9.734922E-02   2.219594E+03   1.102175E+00
 ......

Read by::

 # this saves the prepended lines in attribute line_2,...
 empty=js.dA('exampleData/buffer_averaged_corrected_despiked.pdh',usecols=[0,1],lines2parameter=[2,3,4])
 # next just ignores the first lines (and last 50) and uses every second line,
 empty=js.dA('exampleData/buffer_averaged_corrected_despiked.pdh',usecols=[0,1],block=[5,-50,2])

Read csv data by (comma separated list) ::

 js.dA('data2.txt',replace={',':' '})
 # If tabs separate the columns
 js.dA('data2.txt',replace={',':' ','\t':' '})

Get a list of files in a folder with specific names ::

 import glob
 files=glob.glob('latest*.dat')     # files starting with 'latest' and ending '.dat'
 files=glob.glob('latest???.dat')     # files starting with 'latest' and ending '.dat' and 3 char in between



Creating from numpy arrays
--------------------------
This demonstrates how to create dataArrays form calculated data with error::

 #
 x=np.r_[0:10:0.5]                 # a list of values
 D,A,q=0.45,0.99,1.2               # parameters
 data=js.dA(np.vstack([x,  np.exp(-q**2*D*x)+np.random.rand(len(x))*0.05,  x*0+0.05]))
 data.diffusioncoefficient=D
 data.amplitude=A
 data.wavevector=q

 # alternative (diffusion with noise and error )
 data=js.dA(np.c_[x,np.exp(-q**2*D*x)*0.05,x*0+0.05].T)
 f=lambda xx,DD,qq,e:np.exp(-qq**2*DD*xx)+np.random.rand(len(x))*e
 data=js.dA(np.c_[x,f(x,D,q,0.05),np.zeros_like(x)+0.05].T)

Manipulating dataArray/dataList
-------------------------------
Changing values uses the same syntax as in numpy arrays with all available methods and additional .X,.Y...

- The columns used for .X,.Y,.Z,.W and respective errors can be changed by *.setColumnIndex(ix=2,iy=4,iey=None)* .
  Later .Y is used during fits as dependent variable.
- Default ix,iy,iey = 0,1,2 as one expects this
- When writing data the attribute line ``XYeYeX 0 1 2 - - - - -`` is used to save the column indices in sequence as given in
  :py:func:`~.dataarray.protectedNames` -> *X, Y, eY, eX, Z, eZ, W, eW*.
  When reading the file this attribut information is used to recover the column indices.
  If the line is missing the default ``0 1 2`` is used.

dataList elements should be changed individually as dataArray (this can be done in loops) ::

 i7=js.dL(js.examples.datapath+'/polymer.dat')
 for ii in i7:
    ii.X/=10          # change scale
    ii.Y/=ii.conc     # normalising by concentration
    ii.Y=-np.log(ii.Y)*2
 i1=js.dA(js.examples.datapath+'/a0_336.dat')
 # all the same to multiply .X by 2
 i1.X*=2
 i1[0]*=2
 i1[0]=i1[0]*2        # most clear writing
 # multiply each second Y value by 2 (using advanced numpy indexing)
 i1[1,::2]=i1[1,::2]*2
 # now more strange: each second gets the value from following *2+1
 # unlimited possibilities to manipulate data :-)
 i1[1,::2]=i1[1,1::2]*2+1 + i1[2,1::2]

 # making a Kratky plot
 p=js.grace()
 i1k=i1.copy()
 i1k.Y=i1k.Y*i1k.X**2
 p.plot(i1k)
 # or
 p.plot(i1.X*10,i1.Y*i1.X**2)

Indexing dataArray/dataList and reducing
----------------------------------------
Basic **Slicing** and **Indexing/Advanced Indexing/Slicing** works as described at
`numpy indexing <https://docs.scipy.org/doc/numpy/reference/arrays.indexing.html>`_ .

This means accessing parts of the dataArray/dataList by indexing with integers, boolean masks or arrays
to extract/manipulate a subset of the data.

[A,B,C] in the following describes A dataList, B dataArray columns and C values in columns.

The start:end:step notation is used. With missing value start equals 0, end the last and step 1.

::

 i5=js.dL(js.examples.datapath+'/iqt_1hho.dat')
 # remove first 2 and last 2 datapoints in all dataArrays
 i6=i5[:,:,:2:-2]
 # remove first column and use 1,2,3 columns in all dataArrays
 i6=i5[:,1:4,:]
 # use each second element in dataList and remove last 2 datapoints in all dataArrays
 i6=i5[::2,:,:-2]
 # You can loop over the dataArrays
 for dat in i5:
    dat.X=dat.X*10
 # select a subset by explicit list
 i7=i5[[2,3,5,6,]]


**Reducing data** to a lower number of values can be done by above fancy indexing (loosing data)
or using ``data.prune`` (see :py:class:`~.dataList` )

prune reduces e.g by 2000 points by averaging in intervals to get 100 points.

::

 i7=js.dL(js.examples.datapath+'/a0_336.dat')
 # mean values in interval [0.1,4] with 100 points distributed on logscale
 i7_2=i7.prune(lower=0.1,upper=4,number=100,kind='log') #type='mean' is default

dataList can be **filtered** to use a subset e.g. with restricted attribute values as  .q>1 or temp>300 .

::

 i5=js.dL(js.examples.datapath+'/iqt_1hho.dat')
 i6=i5.filter(lambda a:a.q<2)
 i6=i5.filter(lambda a:a.q in [1,2,3,4,5])
 i6=i5.filter(temp=300)         # automatically sorted for these attributes

This demonstrates how to filter data values according to some rule. ::

 x=np.r_[0:10:0.5]
 D,A,q=0.45,0.99,1.2               # parameters
 rand=np.random.randn(len(x))      # the noise on the signal
 data=js.dA(np.vstack([x,np.exp(-q**2*D*x)+rand*0.05,x*0+0.05,rand])) # generate data with noise
 # select like this
 newdata=data[:,data[3]>0]         # take only positive noise in column 3
 newdata=data[:,data.X>2]          # X>2
 newdata=data[:,data.Y<0.9]        # Y<0.9

Fitting experimental data
-------------------------
We need:

- **Data** need to be read and prepared.

 - Data may be a single dataset (usually in a *dataArray*) or several of these (in a *dataList*) like
   multiple measurements with same or changing parameters (e.g. wavevectors).
   Coordinates are in *.X* and values in *.Y*
 - 2D data (e.g. a detector image with 2 dimensions) need to be transformed to coordinates
   *.X*, *.Z* with values in *.Y*. This also gives pixels coordinates in an image a physical
   interpretation as e.g. wavevectors.
   See examples :ref:`2D fitting` and :ref:`Fitting the 2D scattering of a lattice`
 - Attributes need to be extracted from read data (from comments or filename or from a list).
   In the below example the temperature is stored in the data as attribute.

- A **model**, which can be defined in different ways.
  See below or in :ref:`How to build simple models` for different ways.

  Avoid using lists as parameters as list are used to discriminate
  between common parameters (a single float) and individual fit parameters
  (a list of float for each) in dataList.

- **Fit algorithm**
  We use methods from the `scipy.optimize
  <https://docs.scipy.org/doc/scipy/reference/generated/scipy.optimize.minimize.html#scipy.optimize.minimize>`_
  module that are incorporated in the *.fit*  method of *dataArray/dataList*.
  *.fit* supports different fit algorithms (see dataList.fit Examples how to choose and about speed differences):

 - method='leastsq' (default) is what you usually expect by "fitting" including error bars
   (and a covariance matrix for experts....).
   It is a wrapper around MINPACK’s lmdif and lmder, which is a modification of the
   `Levenberg-Marquardt <https://en.wikipedia.org/wiki/Levenberg-Marquardt_algorithm>`_ algorithm.
   Errors are *1-sigma* errors as they are calculated from the covariance matrix and not directly depend
   on the errors of the *.eY*. Still the relative weight of values according to *.eY* is relevant.
   Here a numerical approximation for the gradient is used to determine the next step.
 - method='Nelder-Mead' `Nelder-Mead <https://en.wikipedia.org/wiki/Nelder-Mead_method>`_ (downhill simplex method)
   algorithm is a direct search method based on function comparison  and
   sometimes converges when gradient methods fail (or stuck in local minima).
   However, the Nelder–Mead technique is a heuristic search method that can converge to non-stationary point.
   It returns no error and is slower than 'leastsquare'.
   Nelder-Mead is able to fit data with integer parameters where a gradient method fails.
 - method='BFGS' `Broyden–Fletcher–Goldfarb–Shanno (BFGS)
   <https://en.wikipedia.org/wiki/Broyden%E2%80%93Fletcher%E2%80%93Goldfarb%E2%80%93Shanno_algorithm>`_ algorithm.
   Not as fast as 'leastsq' but gives also error bars.
 - method='`differential_evolution <https://en.wikipedia.org/wiki/Differential_evolution>`_'
   is a global optimization method using iterative improving candidate solutions.
   In general it needs a large number of function calls but may find a global minimum.
 - method='CG', ..... other `optimization methods
   <https://docs.scipy.org/doc/scipy/reference/generated/scipy.optimize.minimize.html#scipy.optimize.minimize>`_.
   These are slower converging than 'leastsq' and most give no error bars.
   Some require an explicit gradient function ore more.
   They are more for advanced users if someone really knows why using it in special cases.

.. Warning:: **Save results !!!**

             The resulting parameters with errors are in *.lastfit*. **Save the fit result !!!**
             I regularly have to ask PhD students "What are the errors ?" and they
             repeat all their work again.

             Fit results without errors are meaningless.


**If the fit finishes it tells if there was success or if it failed.
For error messages the final parameters are no valid fit results!!! Please always check this.**

A typical example of several datasets from a SAXS measurement (polymer in solution)
::

 import jscatter as js
 import numpy as np

 # read data
 data=js.dL(js.examples.datapath+'/polymer.dat')
 # merge equal Temperatures each measured with two detector distances
 data.mergeAttribut('Temp',limit=0.01,isort='X')

 # define model
 # q will get the X values from your data as numpy ndarray.
 def gCpower(q,I0,Rg,A,beta,bgr):
     """Model Gaussian chain  + power law and background"""
     gc=js.ff.gaussianChain(q=q,Rg=Rg)
     # add power law and background
     gc.Y=I0*gc.Y+A*q**beta+bgr
     # add attributes for later documentation, these are additional content of lastfit (see below)
     gc.A=A
     gc.I0=I0
     gc.bgr=bgr
     gc.beta=beta
     gc.comment=['gaussianChain with power law and bgr','a second comment']
     return gc

 data.makeErrPlot(yscale='l',xscale='l')    # additional errorplot with intermediate output
 data.setlimit(bgr=[0,1])                   # upper and lower soft limit

 # here we use individual parameter ([]) for all except a common beta ( no [] )
 # please try removing the [] and play with it :-)
 # mapNames tells that q is *.X* (maps model names to data names )
 # condition limits the range to fit (may also contain something like (a.Y>0))
 data.fit(model=gCpower,
          freepar={'I0':[0.1],'Rg':[3],'A':[1],'bgr':[0.01],'beta':-3},
          fixpar={},
          mapNames={'q':'X'},
          condition =lambda a:(a.X>0.05) & (a.X<4))

 # to fix a parameter move it to fixpar dict (bgr is automatically extended)
 data.fit(model=gCpower,
          freepar={'I0':[0.1],'Rg':[3],'A':[1]},
          fixpar={'bgr':[0.001, 0.0008, 0.0009],'beta':-4},
          mapNames={'q':'X'},
          condition =lambda a:(a.X>0.05) & (a.X<4))

 # result parameter and error (example)
 data.lastfit.Rg
 data.lastfit.Rg_err
 # as result dataArray
 result=js.dA(np.c_[data.Tempmean,data.lastfit.Rg,data.lastfit.Rg_err].T)
 # plot it
 p=js.grace()
 p.plot(result)

 # save the fit result including parameters, errors and covariance matrix
 # and your model description
 data.lastfit.save('polymer_fitDebye.dat')

You may want to fit dataArray in a dataList individually.
Do it in a loop. ::

 # from the above
 for dat in data:
    dat.fit(model=gCpower,
         freepar={'I0':0.1,'Rg':3,'A':1,},
         fixpar={'bgr':0.001,'beta':-3},
         mapNames={'q':'X'},
         condition =lambda a:(a.X>0.05) & (a.X<4))

 # each dataArray has its own .lastfit, .errPlot and so on
 data[0].showlastErrPlot()
 # for saving with individual names
 for dat in data:
    dat.lastfit.save('fitresult_Temp%2g.dat' %(dat.Tempmean))

**Simulate using the fit result**

To simulate how a certain parameter influences the result we may simulate changes in the best fit parameters
to observe how model values are changing.

To simulate we may use *.modelValues* to get an explicit result or use *.showlastErrPlot*
to observe the changes in an errPlot.
We just add the new parameter when using these functions. Without parameters we get the original values. ::

 # after a fit we may use it like this
 data.modelValues(Rg=4)
 data.showlastErrPlot(Rg=4,A=2)


Why Fits may fail
-----------------

If your fit fails it is most not an error of the fit algorithm.
Read the message at the end of the fit it gives a hint what happened.

- If your fit results in a not converging solution or maximum steps reached then its not a valid fit result.
  Decrease tolerance, increase maxstep or reduce number of parameter to get a valid result.
  Try more reasonable start parameters.
- Your model may have dependent parameters. Then the gradient cannot be evaluated.
  Think of it as a valley with a flat ground. Then you have a line as minimum but you ask for a point.
- Your starting parameters are way of and within the first try the algorithm finds no improvement.
  This may happen if you have a dominating function of high power and bad starting parameters.
  Choose better ones.
- You may run into a local minimum which also depends on the noise in your data.
  Try different start parameter or a global optimization method.
- Play with the starting parameters and get an idea how parameters influence your function.
  This helps to get an idea what goes wrong.

And finally :

- You have chosen the wrong model ( not correlated to your measurement),
  units are wrong by orders of magnitude, missing contributions, .....
  So read the docs of the models and maybe choose a better one.


Plot experimental data and fit result
-------------------------------------
::

 # plot data
 p=js.grace()
 p.plot(data,legend='measured data')
 p.xaxis(min=0.07,max=4,scale='l',label='Q / nm\S-1')
 p.yaxis(scale='l',label='I(Q) / a.u.')
 # plot the result of the fit
 p.plot(data.lastfit,symbol=0,line=[1,1,4],legend='fit Rg=$radiusOfGyration I0=$I0')
 p.legend()

 p1=js.grace()
 # Tempmean because of previous mergeAttribut; otherwise data.Temp
 p1.plot(data.Tempmean,data.lastfit.Rg,data.lastfit.Rg_err)
 p1.xaxis(label='Temperature / C')
 p1.yaxis(label='Rg / nm')

Save data and fit results
-------------------------
Jscatter saves files in a ASCII format including attributes that can be
reread including the attributes (See first example above and dataArray help).
In this way no information is lost. ::

 data.save('filename.dat')
 # later read them again
 data=js.dA('filename.dat')  # retrieves all attributes

If needed, the raw numpy array can be saved (see numpy.savetxt).
All attribute information is lost. ::

 np.savetxt('test.dat',data.array.T)

Save fit results by saving the .lastfit attribute (it is in general NOT automatically saved with the above) ::

 data.lastfit.save('fitresult.filename.dat')



Additional stuff
----------------

**Creating grids** as list of points in 3D [Nx3]
e.g. for 2D scattering images or for integration ::

 # inspect the later grids by
 js.mpl.scatter3d(qxyz)

 N=10  # number of points
 d=0.1 # distance between grid points

 # traditional numpy way
 # create 2D lattice and append 3rd dimension (2N+1 points in each direction)
 qxy=np.mgrid[-d:d:N*1j, -d:d:N*1j].reshape(2,-1).T
 qxyz=np.c_[qxy,np.zeros(qxy.shape[0])]

 # 2D using 3D lattice
 qxyz=js.sf.sqLattice(d,[N,N]).XYZ     # 2D lattice from square lattice
 qxyz=js.sf.scLattice(d,[N,N,0]).XYZ   # 3D lattice Z collapsed
 qxyz=js.sf.hexLattice(d,[N,N,0]).XYZ  # 3D lattice hexagonal Z collapsed

 # quasi 2D, collapsed dimension but multiple atoms in unit cell
 # cube grid with second point in unit cell (2.5D if second point has Z dimension)
 qxyz=js.sf.rhombicLattice([[1,0,0],[0,1,0],[0,0,1]],[3,3,0],[[-0.1,-0.1,0],[0.1,0.1,0]],[1,2]).XYZ

 # 3D grid
 qxyz=js.sf.scLattice(d,[N,N,N]).XYZ

 # grid of pseudorandom points
 qxyz=js.formel.randomPointsInCube(100, dim=3)  # 3D
 qxyz=np.c_[js.formel.randomPointsInCube(N**2,dim=2),np.zeros(N**2)]  # 2D plane in 3D
 points=js.parallel.randomPointsOnSphere(1500)
 qxyz=js.formel.rphitheta2xyz(points[points[:,1]>0])  # select half sphere

 # rotate if needed
 rotaxis=[0,0,1]       # rotation around y axis
 R=js.formel.rotationMatrix(rotaxis,np.deg2rad(120))    # 120° rotation matrix
 Rqxyz=np.einsum('ij,kj->ki',R,qxyz)



