Metadata-Version: 1.1
Name: iraclis
Version: 1.4.0
Summary: Analysis pipeline for HST/WFC3 spectroscopic observations of exoplanet transits and eclipses
Home-page: https://github.com/ucl-exoplanets/Iraclis
Author: Angelos Tsiaras
Author-email: aggelostsiaras@gmail.com
License: Creative Commons Attribution 4.0 International License
Description: # Iraclis
        
        <img src="https://github.com/ucl-exoplanets/Iraclis/blob/master/logo.jpg" width="20%">
        
        Analysis pipeline for **HST/WFC3** spectroscopic observations of exoplanet transits and eclipses
        
        A complete package to analyse single-object spatially scanned spectroscopic observations of extrasolar planets 
        obtained with the near-infrared grisms (G102, G141) of the **Wide Field Camera 3** on-board the 
        **Hubble Space Telescope**. 
        
        Includes:
        * Reduction of the raw frames.
        * Calibration of the position of the total spectrum and the different spectral elements.
        * Extraction of the total flux and the flux per spectral element.
        * Fitting of the white and the spectral light-curves.
        
        Currently, fitting can be applied only on single-visit light-curves but in the next version it will
        be updated to fit also multiple visits of the same target simultaneously.
        
        
        ## References
        
        * Tsiaras et al. 2016a, [A New Approach to Analyzing HST Spatial Scans: The Transmission Spectrum of HD 209458 b](http://iopscience.iop.org/article/10.3847/0004-637X/832/2/202), ApJ, 832, 202. 
        * Tsiaras et al. 2016b, [Detection of an Atmosphere Around the Super-Earth 55 Cancri e](http://iopscience.iop.org/article/10.3847/0004-637X/820/2/99), ApJ, 820, 99.
        * Tsiaras et al. 2018, [A Population Study of Gaseous Exoplanets](http://iopscience.iop.org/article/10.3847/1538-3881/aaaf75), AJ, 155, 156.
        
        
        ## License
        
        This work is licensed under the Creative Commons Attribution 4.0 International License.
        
        Copyright (c) 2018 Angelos Tsiaras
        
        Please pay attention to Section 3 of the license and do:
        - retain identification of the creators by including the above listed references in future work and publications,
        - indicate if You modified the Licensed Material and retain an indication of any previous modifications.
        
        To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/ 
        or send a letter to Creative Commons, PO Box 1866, Mountain View, CA 94042, USA.
        
        
        ## Installation
        
        Open a terminal and type: `pip install iraclis`  
        
        
        ## Usage
        
        #### Getting HST/WFC3 data
        
        Each transit or eclipse dataset, obtained with WFC3, includes many spectroscopic images (using one of the two 
        spectroscopic grisms: G102 or G141) and also, at least, one direct (undispersed) image (using one of the 15 WFC3 imaging 
        filters: F098W, F132N, F140W, F126N, F153M, F167N, F139M, F164N, F127M, F160W, F128N, F125W, F130N, F110W, F105W).
        
        To use Iraclis, download all the spectroscopic data in the RAW format and the imaging data in the FLT format
        from the [MAST archive](https://archive.stsci.edu/hst/search.php). Keep all your files together in one directory.
        
        #### Analysing HST/WFC3 data
        
        Within a bash terminal:
        - you can process a dataset using a parameters file by typing: `iraclis -p path_to_parameters_fle`
        - or using default values for the parameters by typing: `iraclis -d path_to_data_directory`
        
        Within a python terminal, first import the package: `import iraclis`
        - you can process a dataset using a parameters file by typing: `iraclis.process_visit(parameters_file='path_to_parameters_fle')`
        - or using default values for the parameters by typing: `iraclis.process_visit(data_directory='path_to_data_directory')`
        
        #### Setting up a parameters file
        
        A parameters file is a simple txt file that contains all the important paramets controlling the data anlaysis process 
        of a WFC3 dataset. Below, you can find the description of such a file (this file is included in the examples).
        
        `data_directory` **`iraclis_test_dataset_hatp26b_raw_data`**  
        (diectory path) The path of the directory where the dataset is stored.
        
        `output_directory_copy` **`False`**  
        (diectory name/False) If you wish to copy your results in a new directory, give here its name. The default results are 
        stored in the “results” directory. This is useful if you wish to analyse the same dataset multiple times with different 
        fitting parameters.
        
        `reduction` **`True`**  
        (True/False) Whether to reduce the data or not. You can set it to False if you wish to re-run the analysis starting 
        from a later stage.
        
        `splitting` **`True`**  
        (True/False) Whether to split the data or not. In this case the reduced data will be splitted into the differential 
        frames N - N-1, rather than final-initial.
        
        `extraction` **`False`**  
        (True/False) Whether to extract the light-curves or not. You can set it to False if you wish to re-run the analysis 
        starting from a later stage.
        
        `splitting_extraction` **`True`**  
        (True/False) Whether to extract the light-curves from the splitted data or not. You can set it to False if you wish to 
        re-run the analysis starting from a later stage. Note: set only one of the extraction or splitting_extraction to true. 
        If you wish to have both, re-run the analysis with different values for these parameters.
        
        `fitting_white` **`True`**  
        (True/False) Whether to fit the white light-curve or not. You can set it to False if you wish to re-run the analysis 
        starting from a later stage.
        
        `fitting_spectrum` **`True`**  
        (True/False) Whether to fit the spectral light-curves or not. 
        
        `target_x_offset` **`0`**  
        `target_y_offset` **`0`**  
        (number) In the rare case that in the field of view there is a star brighter that your target, give here the difference 
        in their positions. This is important because the code automatically identifies the brightest star as the target 
        (in 99% of the observations, this is the case).
        
        `aperture_lower_extend` **`-20`**  
        (number) Vertical starting position of the extraction box. Use negative value. -20 means that the extraction box will 
        start 20 pixels below the spectrum.
        
        `aperture_upper_extend` **`20`**  
        (number) Vertical final position of the extraction box. Use positive value. 20 means that the extraction box will stop 
        20 pixels above the spectrum.
        
        `extraction_method` **`gauss`**  
        (gauss/integral) There are two available extraction methods: gauss (where the flux extracted is the convolution of the 
        spectrum with a gaussian) or integral (where the flux extracted is calculated as the integral of the spectrum inside the 
        extraction aperture)
        
        `extraction_gauss_sigma` **`47`**  
        (number) Useful only in the case of gauss extraction. This is the sigma of the gaussian used, in Angstrom. The default number of 
        47 is approximately equal to one pixel.
        
        `method` **`claret`**  
        (claret/linear/quad/sqrt) Limb-darkening method to be used. Choose between: claret, linear, quad, sqrt.
        
        `white_lower_wavelength` **`10880`**  
        `white_upper_wavelength` **`16800`**  
        (number/default) Right and left edges of the extracted white light curve, in Angstroms.
        
        `white_ldc1` **`0.850033`**  
        (number/default) First limb-darkening coefficients for the white light-curve.
        
        `white_ldc2` **`-0.728096`**  
        (number/default) Second limb-darkening coefficients for the white light-curve. Will not be used if the linear method is 
        chosen.
        
        `white_ldc3` **`0.908153`**  
        (number/default) Third limb-darkening coefficients for the white light-curve. Will not be used if the linear, the quad 
        or the sqrt method is chosen.
        
        `white_ldc4` **`-0.397691`**  
        (number/default) Forth limb-darkening coefficients for the white light-curve. Will not be used if the linear, the quad 
        or the sqrt method is chosen.
        
        **Comment**: You can set the above six parameters to default, if you want to use the pre-calculated limb-darkening 
        coefficients. In this case, the claret limb-darkening method will be used. These coefficients have been calculated for 
        a wavelength range between 10880.0 and 16800.0 Angstroms.
        
        `bins_file` **`iraclis_test_dataset_hatp26b_bins.txt`**  
        (file path/default_high/default_low/default_vlow) Path to the bins file.
        
        **Comment**: You can set the above parameter to default_high, default_low or default_vlow. In this case, the claret 
        limb-darkening method will be used. Be careful to avoid conflicts, as the limb-darkening method used between spectral 
        and white light curves should be the same.
        
        `planet` **`HAT-P_26 b`**  
        (name/auto) Planet name, useful if the system has multiple planets.
        
        `star_teff` **`-0.04`**  
        (number/auto) Stellar temperature, used if the limb-darkening coefficients are set to auto.
        
        `star_logg` **`5079`**  
        (number/auto) Stellar log(g), used if the limb-darkening coefficients are set to auto.
        
        `star_meta` **`4.56`**  
        (number/auto) Stellar metallicity, used if the limb-darkening coefficients are set to auto.
        
        `rp_over_rs` **`0.0715`**  
        (number/auto) Initial value for the planet-to-star radius ratio. This parameters is always fitted both for the white 
        and the spectral light-curves in cases of transits.
        
        `fp_over_fs` **`0.0001`**  
        (number/auto) Initial value for the planet-to-star flux ratio. This parameters is always fitted both for the white and 
        the spectral light-curves in cases of eclipses.
        
        `period` **`4.234515`**  
        (number/auto) Period of the planetary orbit in days. Always fixed.
        
        `sma_over_rs` **`13.44`**  
        (number/auto) Initial value for the semi-major axis of the planetary orbit.
        
        `eccentricity` **`0.0`**  
        (number/auto) Eccentricity of the planetary orbit. Always fixed.
        
        `inclination` **`88.6`**  
        (number/auto) Initial value for the inclination of the planetary orbit, in degrees.
        
        `periastron` **`0.0`**  
        (number/auto) Periastron of the planetary orbit in degrees. Always fixed.
        
        `mid_time` **`2455304.65118`**  
        (number/auto) Initial value for the mid-transit-time of the planetary orbit, in HJD.
        
        **Comment**: You can set any of the above 12 parameters to auto, to use the data from the Open Exoplanet Catalogue.
        
        `apply_up_down_stream_correction` **`False`**  
        (True/False) Whether to correct for the up-stream/down-stream effect or not. Useful only in cases of fast scans that 
        cross the line between the upper two and lower two quadrants of the detector.
        
        `exclude_initial_orbits` **`1`**  
        (number) Number of HST orbits to be removed from the begging of the visit. Usually set to 1.
        
        `exclude_final_orbits` **`0`**  
        (number) Number of HST orbits to be removed from the end of the visit. Usually set to 0.
        
        `exclude_initial_orbit_points` **`0`**  
        (number) Number of HST exposures to be removed from the begging of each HST-orbit.
        
        `mcmc_iterations` **`500000`**  
        (number) Number of emcee iterations for the white light-curve fitting
        
        `mcmc_walkers` **`200`**  
        (number) Number of emcee wakers for the white light-curve fitting
        
        `mcmc_burned_iterations` **`200000`**  
        (number) Number of emcee burned iterations for the white light-curve fitting
        
        `spectral_mcmc_iterations` **`50000`**  
        (number) Number of emcee iterations for the spectral light-curve fitting
        
        `spectral_mcmc_walkers` **`100`**  
        (number) Number of emcee walkers for the spectral light-curve fitting
        
        `spectral_mcmc_burned_iterations` **`20000`**  
        (number) Number of emcee burned iterations for the spectral light-curve fitting
        
        `first_orbit_ramp` **`True`**  
        (True/False) Whether to fit for different ramp coefficients for the first HST orbit in the analysis (after excluding 
        exclude_initial_orbits orbits) or not.
        
        `second_order_ramp` **`False`**  
        (True/False) Whether to fit for a quadratic visit-long ramp or not.
        
        `mid_orbit_ramps` **`True`**  
        (True/False) Whether to fit for mid-orbit ramps caused by buffer-dumps or not.
        
        `fit_ldc1` **`False`**  
        (True/False) Whether to fit for the first limb-darkening coefficient or not. The same will be applied both for the 
        white and the spectral light-curves.
        
        `fit_ldc2` **`False`**  
        (True/False) Whether to fit for the second limb-darkening coefficient or not. The same will be applied both for 
        the white and the spectral light-curves. Will not be used if the linear method is chosen.
        
        `fit_ldc3` **`False`**  
        (True/False) Whether to fit for the third limb-darkening coefficient or not. The same will be applied both for 
        the white and the spectral light-curves. Will not be used if the linear, the quad or the sqrt method is chosen.
        
        `fit_ldc4` **`False`**  
        (True/False) Whether to fit for the forth limb-darkening coefficient or not. The same will be applied both for 
        the white and the spectral light-curves. Will not be used if the linear, the quad or the sqrt method is chosen.
        
        `fit_sma_over_rs` **`False`**  
        (True/False) Whether to fit for the semi-major axis of the planetary orbit or not. This is fitted only on the white 
        light-curve.
        
        `fit_inclination` **`False`**  
        (True/False) Whether to fit for the inclination of the planetary orbit or not. This is fitted only on the white 
        light-curve.
        
        `fit_mid_time` **`True`**  
        (True/False) Whether to fit for the mid-transit-time of the planetary orbit or not. This is fitted only on the white 
        light-curve.
        
        #### Setting up a bins file
        
        A bins file is a simple txt file that contains three to six columns, indicating for each spectral light curve: 
        a-b. Right and left edges of the extracted spectral light curve, in Angstroms, c-f. limb-darkening coefficients for 
        the spectral light-curve. Below, you can find the description of such a file (this file is included in the examples).
        
        `11108 11416 0.985047 -1.385670 1.781030 -0.7267230`  
        `11416 11709 0.949097 -1.266470 1.640630 -0.6754740`  
        `11709 11988 0.928715 -1.195690 1.553730 -0.6452910`  
        `11988 12257 0.903069 -1.109910 1.456180 -0.6107730`  
        `12257 12522 0.878225 -1.023230 1.361070 -0.5780620`  
        `12522 12791 0.859841 -0.950740 1.274760 -0.5481460`  
        `12791 13058 0.849884 -0.896126 1.203900 -0.5267150`  
        `13058 13321 0.832077 -0.833290 1.125660 -0.4941230`  
        `13321 13586 0.809188 -0.726211 0.991314 -0.4438480`  
        `13586 13860 0.795028 -0.641081 0.872551 -0.3971340`  
        `13860 14140 0.788556 -0.586294 0.802106 -0.3739860`  
        `14140 14425 0.784454 -0.561833 0.775730 -0.3685690`  
        `14425 14719 0.772069 -0.460859 0.627183 -0.3091360`  
        `14719 15027 0.772703 -0.404730 0.517165 -0.2597780`  
        `15027 15345 0.772846 -0.296638 0.327104 -0.1754390`  
        `15345 15682 0.798113 -0.256525 0.198611 -0.1108030`  
        `15682 16042 0.848830 -0.376905 0.274511 -0.1251750`  
        `16042 16432 0.894871 -0.410984 0.233093 -0.0939863`
        
        #### Testing the code
        
        In the examples you will find a short python script that downloads a test dataset from the MAST 
        archive. There, you can also find the parameters file and the bins file described above. The test dataset is a transit 
        of HATP-26 b from the observing proposal 14260 (PI: Deming Drake). 
        
        
        ## Products
        
        The final product is a pickle file named "fitting_results.pickle" and can be found in the "results" directory 
        (or the output_directory_copy that you have set in the parameters file. To open the pickle file you will need python 
        installed in your computer and the packages pickle and numpy.
        
        The command to load a pickle file is: `database = pickle.load(open(‘database_file.pickle’))`
        
        This dictionary contains the three main dictionaries that include all the results for a particular dataset. These are:
        
        `database['lightcurves']` extracted light-curves and transit fitting data  
        `database['spectrum']` planetary spectrum  
        
        The `database['lightcurves']` dictionary contains all the information on the extracted white and spectral 
        light-curves and their fitting, and has the following content:
        
        `database['lightcurves']['white']` white light curve and fitting  
        `database['lightcurves']['bin_01']` first wavelength channel  
        `database['lightcurves']['bin_02']` second wavelength channel  
        etc... 
        
        The `database['spectra']` dictionary contains the final extracted planetary spectrum, and has the following structure:
        
        `database['spectrum']['wavelength']` mean wavelength of the different channels (μm)  
        `database['spectrum']['width']` wavelength width of the different channels (μm)  
        `database['spectrum']['depth']` transit depth in each wavelength channel  
        `database['spectrum']['error']` uncertainty in the transit depth in each wavelength channel  
        
        #### White light curve and fitting
        
        The `database['lightcurves']['white']` dictionary has the following structure:
        
        `database['lightcurves']['white']['limb_darkening']['method']` limb darkening method used  
        `database['lightcurves']['white']['wavelength']['lambda1']` lower wavelength limit of the band in Angstroms  
        `database['lightcurves']['white']['wavelength']['lambda2']` upper wavelength limit of the band in Angstroms  
        `database['lightcurves']['white']['wavelength']['lambda_mean']` mean wavelength of the band in Angstroms  
        `database['lightcurves']['white']['wavelength']['lambda_width']` width of the band in Angstroms  
        `database['lightcurves']['white']['exposure']['exp_time']` exposure time for each data point in seconds  
        `database['lightcurves']['white']['exposure']['model_resolution']` sub-exposure time used to model each data point in seconds  
        `database['lightcurves']['white']['input_time_series']['x_shift']` horizontal shifts during the observation  
        `database['lightcurves']['white']['input_time_series']['x_shift_error']` uncertainty in the horizontal shifts during the observation  
        `database['lightcurves']['white']['input_time_series']['y_shift']` vertical shifts during the observation  
        `database['lightcurves']['white']['input_time_series']['y_shift_error']` uncertainty in the horizontal shifts during the observation  
        `database['lightcurves']['white']['input_time_series']['sky']` sky background level during the observation  
        `database['lightcurves']['white']['input_time_series']['scan']` scan direction (1 for forward scans, -1 for reverse scans)  
        `database['lightcurves']['white']['input_time_series']['hjd']` heliocentric Julian date during the observation  
        `database['lightcurves']['white']['input_time_series']['raw_lc']` raw white light-curve  
        `database['lightcurves']['white']['input_time_series']['raw_lc_error']` uncertainty in the raw white light-curve  
        `database['lightcurves']['white']['output_time_series']['phase']` orbital phase  
        `database['lightcurves']['white']['output_time_series']['systematics']` best-fit model for the systematics  
        `database['lightcurves']['white']['output_time_series']['detrended_lc']` de-trended white light-curve  
        `database['lightcurves']['white']['output_time_series']['transit']` best-fit model for the transit  
        `database['lightcurves']['white']['output_time_series']['residuals']` fitting residuals  
        `database['lightcurves']['white']['statistics']['res_std']` standard deviation of the residuals  
        `database['lightcurves']['white']['statistics']['res_autocorr']` autocorrelation function of the residuals  
        `database['lightcurves']['white']['statistics']['corr_variables']` fitted variables  
        `database['lightcurves']['white']['statistics']['corr_matrix']` correlation matric of the fitted variables  
        `database['lightcurves']['white']['parameters']['ldc_1']` first limb-darkening coefficient  
        `database['lightcurves']['white']['parameters']['ldc_2']` second limb-darkening coefficient  
        `database['lightcurves']['white']['parameters']['ldc_3']` third limb-darkening coefficient  
        `database['lightcurves']['white']['parameters']['ldc_4']` forth limb-darkening coefficient  
        `database['lightcurves']['white']['parameters']['rp']` planetary radius relative to the stellar radius  
        `database['lightcurves']['white']['parameters']['fp']` planetary flux relative to the stellar flux (useful only for eclipses)  
        `database['lightcurves']['white']['parameters']['P']` orbital period in days  
        `database['lightcurves']['white']['parameters']['a']` orbital semi-major axis relative to the stellar radius  
        `database['lightcurves']['white']['parameters']['e']` orbital eccentricity  
        `database['lightcurves']['white']['parameters']['i']` orbital inclination in degrees  
        `database['lightcurves']['white']['parameters']['omega']` orbital argument of periastron in degrees  
        `database['lightcurves']['white']['parameters']['t_0']` mit-transit time in HJD  
        `database['lightcurves']['white']['parameters']['n_w_for']` normalization factor for the forward scans  
        `database['lightcurves']['white']['parameters']['n_w_rev']` normalization factor for the reverse scans  
        `database['lightcurves']['white']['parameters']['r_a1']` linear term of the long-term ramp  
        `database['lightcurves']['white']['parameters']['r_a2']` quadratic term of the long-term ramp  
        `database['lightcurves']['white']['parameters']['r_b1']` amplitude of the exponential short-term ramp  
        `database['lightcurves']['white']['parameters']['r_b2']` decay of the exponential short-term ramp  
        `database['lightcurves']['white']['parameters']['for_b1']` amplitude of the exponential short-term ramp for the first orbit  
        `database['lightcurves']['white']['parameters']['for_b2']` amplitude of the exponential short-term ramp for the first orbit  
        `database['lightcurves']['white']['parameters']['mor_b1']` amplitude of the exponential short-term ramp after a buffer dump  
        `database['lightcurves']['white']['parameters']['mor_b2']` amplitude of the exponential short-term ramp after a buffer dump  
        
        Each `database['lightcurves']['white']['parameters']['xx']` element includes also the following keys:
        
        `database['lightcurves']['white']['parameters']['xx']['name']` name  
        `database['lightcurves']['white']['parameters']['xx']['initial']` initial value (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['min_allowed']` minimum of the prior (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['max_allowed']` maximum of the prior (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['trace']` mcmc trace (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['trace_bins']` mcmc trace bins (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['trace_counts']` mcmc trace distribution (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['value']` final value  
        `database['lightcurves']['white']['parameters']['xx']['m_error']` final -error (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['p_error']` final +error (None if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['print_name']` name shown in plots  
        `database['lightcurves']['white']['parameters']['xx']['print_value']` value shown in plots  
        `database['lightcurves']['white']['parameters']['xx']['print_m_error']` -error shown in plots (- if not fitted)  
        `database['lightcurves']['white']['parameters']['xx']['print_p_error']` +error shown in plots (- if not fitted)  
        
        #### Spectral light curves and fitting
        
        Each `database['light_curves']['bin_yy']` dictionary has the following structure:
        
        `database['lightcurves']['bin_yy']['limb_darkening']['method']` limb darkening method used  
        `database['lightcurves']['bin_yy']['wavelength']['lambda1']` lower wavelength limit of the band in Angstroms  
        `database['lightcurves']['bin_yy']['wavelength']['lambda2']` upper wavelength limit of the band in Angstroms  
        `database['lightcurves']['bin_yy']['wavelength']['lambda_mean']` mean wavelength of the band in Angstroms  
        `database['lightcurves']['bin_yy']['wavelength']['lambda_width']` width of the band in Angstroms  
        `database['lightcurves']['bin_yy']['exposure']['exp_time']` exposure time for each data point in seconds  
        `database['lightcurves']['bin_yy']['exposure']['model_resolution']` sub-exposure time used to model each data point in seconds  
        `database['lightcurves']['bin_yy']['input_time_series']['x_shift']` horizontal shifts during the observation  
        `database['lightcurves']['bin_yy']['input_time_series']['x_shift_error']` uncertainty in the horizontal shifts during the observation  
        `database['lightcurves']['bin_yy']['input_time_series']['y_shift']` vertical shifts during the observation  
        `database['lightcurves']['bin_yy']['input_time_series']['y_shift_error']` uncertainty in the horizontal shifts during the observation  
        `database['lightcurves']['bin_yy']['input_time_series']['sky']` sky background level during the observation  
        `database['lightcurves']['bin_yy']['input_time_series']['scan']` scan direction (1 for forward scans, -1 for reverse scans)  
        `database['lightcurves']['bin_yy']['input_time_series']['hjd']` heliocentric Julian date during the observation  
        `database['lightcurves']['bin_yy']['input_time_series']['raw_lc']` raw spectral light-curve  
        `database['lightcurves']['bin_yy']['input_time_series']['white_raw_lc']` raw white light-curve  
        `database['lightcurves']['bin_yy']['input_time_series']['relative_lc']` relative spectral light-curve (raw relative spectral light-curve divided by the raw white light-curve)
        `database['lightcurves']['bin_yy']['input_time_series']['relative_lc_error']` uncertainty in the relative spectral light-curve
        `database['lightcurves']['bin_yy']['input_time_series']['white_model']` transit model for the white light-curve  
        `database['lightcurves']['bin_yy']['output_time_series']['phase']` orbital phase  
        `database['lightcurves']['bin_yy']['output_time_series']['systematics']` best-fit model for the systematics  
        `database['lightcurves']['bin_yy']['output_time_series']['detrended_lc']` de-trended white light-curve  
        `database['lightcurves']['bin_yy']['output_time_series']['transit']` best-fit model for the transit  
        `database['lightcurves']['bin_yy']['output_time_series']['residuals']` fitting residuals  
        `database['lightcurves']['bin_yy']['statistics']['res_std']` standard deviation of the residuals  
        `database['lightcurves']['bin_yy']['statistics']['res_autocorr']` autocorrelation function of the residuals  
        `database['lightcurves']['bin_yy']['statistics']['corr_variables']` fitted variables  
        `database['lightcurves']['bin_yy']['statistics']['corr_matrix']` correlation matric of the fitted variables  
        `database['lightcurves']['bin_yy']['parameters']['ldc_1']` first limb-darkening coefficient  
        `database['lightcurves']['bin_yy']['parameters']['ldc_2']` second limb-darkening coefficient  
        `database['lightcurves']['bin_yy']['parameters']['ldc_3']` third limb-darkening coefficient  
        `database['lightcurves']['bin_yy']['parameters']['ldc_4']` forth limb-darkening coefficient  
        `database['lightcurves']['bin_yy']['parameters']['rp']` planetary radius relative to the stellar radius  
        `database['lightcurves']['bin_yy']['parameters']['fp']` planetary flux relative to the stellar flux (useful only for eclipses)  
        `database['lightcurves']['bin_yy']['parameters']['P']` orbital period in days  
        `database['lightcurves']['bin_yy']['parameters']['a']` orbital semi-major axis relative to the stellar radius  
        `database['lightcurves']['bin_yy']['parameters']['e']` orbital eccentricity  
        `database['lightcurves']['bin_yy']['parameters']['i']` orbital inclination in degrees  
        `database['lightcurves']['bin_yy']['parameters']['omega']` orbital argument of periastron in degrees  
        `database['lightcurves']['bin_yy']['parameters']['t_0']` mit-transit time in HJD  
        `database['lightcurves']['bin_yy']['parameters']['n_l_for']` normalization factor for the forward scans  
        `database['lightcurves']['bin_yy']['parameters']['n_l_rev']` normalization factor for the reverse scans  
        `database['lightcurves']['bin_yy']['parameters']['r_a1']` linear term of the long-term ramp   
        
        Each `database['lightcurves']['bin_yy']['parameters']['zz']` element includes also the following keys:
        
        `database['lightcurves']['bin_yy']['parameters']['zz']['name']` name  
        `database['lightcurves']['bin_yy']['parameters']['zz']['initial']` initial value (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['min_allowed']` minimum of the prior (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['max_allowed']` maximum of the prior (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['trace']` mcmc trace (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['trace_bins']` mcmc trace bins (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['trace_counts']` mcmc trace distribution (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['value']` final value  
        `database['lightcurves']['bin_yy']['parameters']['zz']['m_error']` final -error (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['p_error']` final +error (None if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['print_name']` name shown in plots  
        `database['lightcurves']['bin_yy']['parameters']['zz']['print_value']` value shown in plots  
        `database['lightcurves']['bin_yy']['parameters']['zz']['print_m_error']` -error shown in plots (- if not fitted)  
        `database['lightcurves']['bin_yy']['parameters']['zz']['print_p_error']` +error shown in plots (- if not fitted)  
        
        
        ## BUGS!!!
        
        For any issues and bugs please send an E-mail at [atsiaras@star.ucl.ac.uk](atsiaras@star.ucl.ac.uk).
        
Platform: UNKNOWN
Classifier: Development Status :: 4 - Beta
Classifier: Environment :: Console
Classifier: Intended Audience :: Science/Research
Classifier: Topic :: Scientific/Engineering :: Astronomy
Classifier: License :: OSI Approved :: GNU General Public License v3 (GPLv3)
Classifier: Operating System :: MacOS :: MacOS X
Classifier: Programming Language :: Python :: 3.7
