Code reference¶
modulelevel methods¶

dclab.
new_dataset
(data, identifier=None)[source]¶ Initialize a new RTDC dataset
Parameters:  data –
can be one of the following:
 dict
 .tdms file
 .rtdc file
 subclass of RTDCBase (will create a hierarchy child)
 identifier (str) – A unique identifier for this dataset. If set to None an identifier is generated.
Returns: dataset – A new dataset instance
Return type: subclass of
dclab.rtdc_dataset.RTDCBase
 data –
global definitions¶
These definitionas are used throughout the dclab/ShapeIn/ShapeOut ecosystem.
configuration¶
Valid configuration sections and keys are described in: Analysis metadata and Experiment metadata.

dclab.dfn.
CFG_ANALYSIS
¶ Usereditable configuration for data analysis.

dclab.dfn.
CFG_METADATA
¶ Measurementspecific metadata.

dclab.dfn.
config_funcs
¶ Dictionary of dictionaries containing functions to convert input data to the predefined data type

dclab.dfn.
config_keys
¶ Dictionary with sections as keys and configuration parameter names as values

dclab.dfn.
config_types
¶ Dictionary of dictionaries containing the data type of each configuration parameter
features¶
Features are discussed in more detail in: Features.

dclab.dfn.
FEATURES_SCALAR
¶ Scalar features

dclab.dfn.
FEATURES_NON_SCALAR
¶ Nonscalar features

dclab.dfn.
feature_names
¶ List of valid feature names

dclab.dfn.
feature_labels
¶ List of humanreadable labels for each valid feature

dclab.dfn.
feature_name2label
¶ Dictionary that maps feature names to feature labels

dclab.dfn.
scalar_feature_names
¶ List of valid scalar feature names
RTDC dataset manipulation¶
Base class¶

class
dclab.rtdc_dataset.
RTDCBase
(identifier=None)[source]¶ RTDC measurement base class
Notes
Besides the filter arrays for each data feature, there is a manual boolean filter array
RTDCBase.filter.manual
that can be edited by the user  a boolean value ofFalse
means that the event is excluded from all computations.
get_downsampled_scatter
(xax='area_um', yax='deform', downsample=0, xscale='linear', yscale='linear')[source]¶ Downsampling by removing points at dense locations
Parameters:  xax (str) – Identifier for x axis (e.g. “area_um”, “aspect”, “deform”)
 yax (str) – Identifier for y axis
 downsample (int) –
Number of points to draw in the downsampled plot. This number is either
 >=1: exactly downsample to this number by randomly adding
 or removing points
 0 : do not perform downsampling
 xscale (str) – If set to “log”, take the logarithm of the xvalues before performing downsampling. This is useful when data are are displayed on a logscale. Defaults to “linear”.
 yscale (str) – See xscale.
Returns: xnew, xnew
Return type: filtered x and y

get_kde_contour
(xax='area_um', yax='deform', xacc=None, yacc=None, kde_type='histogram', kde_kwargs={}, xscale='linear', yscale='linear')[source]¶ Evaluate the kernel density estimate for contour plots
Parameters:  xax (str) – Identifier for X axis (e.g. “area_um”, “aspect”, “deform”)
 yax (str) – Identifier for Y axis
 xacc (float) – Contour accuracy in x direction
 yacc (float) – Contour accuracy in y direction
 kde_type (str) – The KDE method to use
 kde_kwargs (dict) – Additional keyword arguments to the KDE method
 xscale (str) – If set to “log”, take the logarithm of the xvalues before computing the KDE. This is useful when data are are displayed on a logscale. Defaults to “linear”.
 yscale (str) – See xscale.
Returns: X, Y, Z – The kernel density Z evaluated on a rectangular grid (X,Y).
Return type: coordinates

get_kde_scatter
(xax='area_um', yax='deform', positions=None, kde_type='histogram', kde_kwargs={}, xscale='linear', yscale='linear')[source]¶ Evaluate the kernel density estimate for scatter plots
Parameters:  xax (str) – Identifier for X axis (e.g. “area_um”, “aspect”, “deform”)
 yax (str) – Identifier for Y axis
 positions (list of two 1d ndarrays or ndarray of shape (2, N)) – The positions where the KDE will be computed. Note that the KDE estimate is computed from the the points that are set in self.filter.all.
 kde_type (str) – The KDE method to use
 kde_kwargs (dict) – Additional keyword arguments to the KDE method
 xscale (str) – If set to “log”, take the logarithm of the xvalues before computing the KDE. This is useful when data are are displayed on a logscale. Defaults to “linear”.
 yscale (str) – See xscale.
Returns: density – The kernel density evaluated for the filtered data points.
Return type: 1d ndarray

polygon_filter_add
(filt)[source]¶ Associate a Polygon Filter with this instance
Parameters: filt (int or instance of PolygonFilter) – The polygon filter to add

polygon_filter_rm
(filt)[source]¶ Remove a polygon filter from this instance
Parameters: filt (int or instance of PolygonFilter) – The polygon filter to remove

config
= None¶ Configuration of the measurement

export
= None¶ Export functionalities; instance of
dclab.rtdc_dataset.export.Export
.

features
¶ All available features

filter
= None¶ Filtering functionalities; instance of
dclab.rtdc_dataset.filter.Filter
.

format
= None¶ Dataset format (derived from class name)

hash
¶ Reproducible dataset hash (defined by derived classes)

identifier
¶ Unique (unreproducible) identifier

title
= None¶ Title of the measurement

Dictionary format¶

class
dclab.rtdc_dataset.
RTDC_Dict
(ddict, *args, **kwargs)[source]¶ Dictionarybased RTDC dataset
Parameters:  ddict (dict) – Dictionary with keys from dclab.definitions.feature_names (e.g. “area_cvx”, “deform”, “image”) with which the class will be instantiated. The configuration is set to the default configuration of dclab.
 *args – Arguments for RTDCBase
 **kwargs – Keyword arguments for RTDCBase
HDF5 (.rtdc) format¶

class
dclab.rtdc_dataset.
RTDC_HDF5
(h5path, *args, **kwargs)[source]¶ HDF5 file format for RTDC measurements
Parameters:  h5path (str or pathlib.Path) – Path to a ‘.tdms’ measurement file.
 *args – Arguments for RTDCBase
 **kwargs – Keyword arguments for RTDCBase

path
¶ Path to the experimental HDF5 (.rtdc) file
Type: pathlib.Path

dclab.rtdc_dataset.fmt_hdf5.
MIN_DCLAB_EXPORT_VERSION
= '0.3.3.dev2'¶ rtdc files exported with dclab prior to this version are not supported
Hierarchy format¶

class
dclab.rtdc_dataset.
RTDC_Hierarchy
(hparent, *args, **kwargs)[source]¶ Hierarchy dataset (filtered from RTDCBase)
A few words on hierarchies: The idea is that a subclass of RTDCBase can use the filtered data of another subclass of RTDCBase and interpret these data as unfiltered events. This comes in handy e.g. when the percentage of different subpopulations need to be distinguished without the noise in the original data.
Children in hierarchies always update their data according to the filtered event data from their parent when apply_filter is called. This makes it easier to save and load hierarchy children with e.g. ShapeOut and it makes the handling of hierarchies more intuitive (when the parent changes, the child changes as well).
Parameters:  hparent (instance of RTDCBase) – The hierarchy parent.
 *args – Arguments for RTDCBase
 **kwargs – Keyword arguments for RTDCBase
TDMS format¶

class
dclab.rtdc_dataset.
RTDC_TDMS
(tdms_path, *args, **kwargs)[source]¶ TDMS file format for RTDC measurements
Parameters:  tdms_path (str or pathlib.Path) – Path to a ‘.tdms’ measurement file.
 *args – Arguments for RTDCBase
 **kwargs – Keyword arguments for RTDCBase

path
¶ Path to the experimental dataset (main .tdms file)
Type: pathlib.Path

dclab.rtdc_dataset.fmt_tdms.
get_project_name_from_path
(path, append_mx=False)[source]¶ Get the project name from a path.
For a path “/home/peter/hans/HLC12398/online/M1_13.tdms” or For a path “/home/peter/hans/HLC12398/online/data/M1_13.tdms” or without the “.tdms” file, this will return always “HLC12398”.
Parameters:
config¶

class
dclab.rtdc_dataset.config.
Configuration
(files=[], cfg={})[source]¶ Configuration class for RTDC datasets
This class has a dictionarylike interface to access and set configuration values, e.g.
cfg = load_from_file("/path/to/config.txt") # access the channel width cfg["setup"]["channel width"] # modify the channel width cfg["setup"]["channel width"] = 30
Parameters:  files (list of files) – The config files with which to initialize the configuration
 cfg (dictlike) – The dictionary with which to initialize the configuration
export¶

class
dclab.rtdc_dataset.export.
Export
(rtdc_ds)[source]¶ Export functionalities for RTDC datasets

avi
(path, filtered=True, override=False)[source]¶ Exports filtered event images to an avi file
Parameters: Notes
Raises OSError if current dataset does not contain image data

fcs
(path, features, filtered=True, override=False)[source]¶ Export the data of an RTDC dataset to an .fcs file
Parameters:  mm (instance of dclab.RTDCBase) – The dataset that will be exported.
 path (str) – Path to a .tsv file. The ending .tsv is added automatically.
 features (list of str) – The features in the resulting .tsv file. These are strings that are defined in dclab.definitions.scalar_feature_names, e.g. “area_cvx”, “deform”, “frame”, “fl1_max”, “aspect”.
 filtered (bool) – If set to True, only the filtered data (index in ds._filter) are used.
 override (bool) – If set to True, an existing file
path
will be overridden. If set to False, raises OSError ifpath
exists.
Notes
Due to incompatibility with the .fcs file format, all events with NaNvalued features are not exported.

hdf5
(path, features, filtered=True, override=False, compression='gzip')[source]¶ Export the data of the current instance to an HDF5 file
Parameters:  path (str) – Path to an .rtdc file. The ending .rtdc is added automatically.
 features (list of str) – The features in the resulting .tsv file. These are strings that are defined in dclab.definitions.feature_names, e.g. “area_cvx”, “deform”, “frame”, “fl1_max”, “image”.
 filtered (bool) – If set to True, only the filtered data (index in ds._filter) are used.
 override (bool) – If set to True, an existing file
path
will be overridden. If set to False, raises OSError ifpath
exists.  compression (str or None) – Compression method for “contour”, “image”, and “trace” data as well as logs; one of [None, “lzf”, “gzip”, “szip”].

tsv
(path, features, filtered=True, override=False)[source]¶ Export the data of the current instance to a .tsv file
Parameters:  path (str) – Path to a .tsv file. The ending .tsv is added automatically.
 features (list of str) – The features in the resulting .tsv file. These are strings that are defined in dclab.definitions.scalar_feature_names, e.g. “area_cvx”, “deform”, “frame”, “fl1_max”, “aspect”.
 filtered (bool) – If set to True, only the filtered data (index in ds._filter) are used.
 override (bool) – If set to True, an existing file
path
will be overridden. If set to False, raises OSError ifpath
exists.

filter¶

class
dclab.rtdc_dataset.filter.
Filter
(rtdc_ds)[source]¶ Boolean filter arrays for RTDC measurements
Parameters: rtdc_ds (instance of RTDCBase) – The RTDC dataset the filter applies to 
update
(force=[])[source]¶ Update the filters according to self.rtdc_ds.config[“filtering”]
Parameters: force (list) – A list of feature names that must be refiltered with min/max values.

all
= None¶ All filters combined (see
Filter.update()
)

invalid
= None¶ Invalid (nan/inf) events

manual
= None¶ Reserved for manual filtering

polygon
= None¶ Polygon filters

rtdc_ds
= None¶ Instance of RTDCBase the filter applies to

lowlevel functionalities¶
downsampling¶
Contentbased downsampling of ndarrays

dclab.downsampling.
downsample_rand
(a, samples, remove_invalid=False, ret_idx=False)[source]¶ Downsampling by randomly removing points
Parameters: Returns:  dsa (1d ndarray of size samples) – The pseudorandomly downsampled array a
 idx (1d boolean array with same shape as a) – Only returned if ret_idx is True. A boolean array such that a[idx] == dsa
features¶

dclab.features.contour.
get_contour
(mask)[source]¶ Compute the image contour from a mask
The contour is computed in a very inefficient way using scikitimage and a conversion of float coordinates to pixel coordinates.
Parameters: mask (binary ndarray of shape (M,N) or (K,M,N)) – The mask outlining the pixel positions of the event. If a 3d array is given, then K indexes the individual contours. Returns: cont – A 2D array that holds the contour of an event (in pixels) e.g. obtained using mm.contour where mm is an instance of RTDCBase. The first and second columns of cont correspond to the x and ycoordinates of the contour. Return type: ndarray or list of K ndarrays of shape (J,2)

dclab.features.bright.
get_bright
(mask, image, ret_data='avg, sd')[source]¶ Compute avg and/or std of the event brightness
The event brightness is defined by the grayscale values of the image data within the event mask area.
Parameters:  mask (ndarray or list of ndarrays of shape (M,N) and dtype bool) – The mask values, True where the event is located in image.
 image (ndarray or list of ndarrays of shape (M,N)) – A 2D array that holds the image in form of grayscale values of an event.
 ret_data (str) – A commaseparated list of metrices to compute  “avg”: compute the average  “sd”: compute the standard deviation Selected metrics are returned in alphabetical order.
Returns:  bright_avg (float or ndarray of size N) – Average image data within the contour
 bright_std (float or ndarray of size N) – Standard deviation of image data within the contour

dclab.features.emodulus.
get_emodulus
(area_um, deform, medium='CellCarrier', channel_width=20.0, flow_rate=0.16, px_um=0.34, temperature=23.0, copy=True)[source]¶ Compute apparent Young’s modulus using a lookup table
Parameters:  area_um (float or ndarray) – Apparent (2D image) area [µm²] of the event(s)
 deform (float or ndarray) – The deformation (1circularity) of the event(s)
 medium (str or float) – The medium to compute the viscosity for. If a string in [“CellCarrier”, “CellCarrier B”] is given, the viscosity will be computed. If a float is given, this value will be used as the viscosity in mPa*s.
 channel_width (float) – The channel width [µm]
 flow_rate (float) – Flow rate [µl/s]
 px_um (float) – The detector pixel size [µm] used for pixelation correction. Set to zero to disable.
 temperature (float or ndarray) – Temperature [°C] of the event(s)
 copy (bool) – Copy input arrays. If set to false, input arrays are overridden.
Returns: elasticity – Apparent Young’s modulus in kPa
Return type: float or ndarray
Notes
 The lookup table used was computed with finite elements methods according to [MMM+17].
 The computation of the Young’s modulus takes into account corrections for the viscosity (medium, channel width, flow rate, and temperature) [MOG+15] and corrections for pixelation of the area and the deformation which are computed from a (pixelated) image [Her17].
See also
dclab.features.emodulus_viscosity.get_viscosity()
 compute viscosity for known media

dclab.features.emodulus_viscosity.
get_viscosity
(medium='CellCarrier', channel_width=20.0, flow_rate=0.16, temperature=23.0)[source]¶ Returns the viscosity for RTDCspecific media
Parameters: Returns: viscosity – Viscosity in mPa*s
Return type: float or ndarray
Notes
 CellCarrier and CellCarrier B media are optimized for RTDC measurements.
 Values for the viscosity of water are computed using equation (15) from [KSW78].

dclab.features.fl_crosstalk.
correct_crosstalk
(fl1, fl2, fl3, fl_channel, ct21=0, ct31=0, ct12=0, ct32=0, ct13=0, ct23=0)[source]¶ Perform crosstalk correction
Parameters:  fli (int, float, or np.ndarray) – Measured fluorescence signals
 fl_channel (int (1, 2, or 3)) – The channel number for which the crosstalkcorrected signal should be computed
 cij (float) – Spill (crosstalk or bleedthrough) from channel i to channel j This spill is computed from the fluorescence signal of e.g. singlestained positive control cells; It is defined by the ratio of the fluorescence signals of the two channels, i.e cij = flj / fli.
See also
get_compensation_matrix()
 compute the inverse crosstalk matrix
Notes
If there are only two channels (e.g. fl1 and fl2), then the crosstalk to and from the other channel (ct31, ct32, ct13, ct23) should be set to zero.

dclab.features.fl_crosstalk.
get_compensation_matrix
(ct21, ct31, ct12, ct32, ct13, ct23)[source]¶ Compute crosstalk inversion matrix
The spillover matrix is
 c11 c12 c13  c21 c22 c23  c31 c32 c33 The diagonal elements are set to 1, i.e.
ct11 = c22 = c33 = 1
Parameters: cij (float) – Spill from channel i to channel j Returns: inv – Compensation matrix (inverted spillover matrix) Return type: np.ndarray

dclab.features.inert_ratio.
get_inert_ratio_cvx
(cont)[source]¶ Compute the inertia ratio of the convex hull of a contour
The inertia ratio is computed from the central second order of moments along x (mu20) and y (mu02) via sqrt(mu20/mu02).
Parameters: cont (ndarray or list of ndarrays of shape (N,2)) – A 2D array that holds the contour of an event (in pixels) e.g. obtained using mm.contour where mm is an instance of RTDCBase. The first and second columns of cont correspond to the x and ycoordinates of the contour. Returns: inert_ratio_cvx – The inertia ratio of the contour’s convex hull Return type: float or ndarray of size N Notes
The contour moments mu20 and mu02 are computed the same way they are computed in OpenCV’s moments.cpp.
See also
get_inert_ratio_raw()
 Compute inertia ratio of a raw contour
References

dclab.features.inert_ratio.
get_inert_ratio_raw
(cont)[source]¶ Compute the inertia ratio of a contour
The inertia ratio is computed from the central second order of moments along x (mu20) and y (mu02) via sqrt(mu20/mu02).
Parameters: cont (ndarray or list of ndarrays of shape (N,2)) – A 2D array that holds the contour of an event (in pixels) e.g. obtained using mm.contour where mm is an instance of RTDCBase. The first and second columns of cont correspond to the x and ycoordinates of the contour. Returns: inert_ratio_raw – The inertia ratio of the contour Return type: float or ndarray of size N Notes
The contour moments mu20 and mu02 are computed the same way they are computed in OpenCV’s moments.cpp.
See also
get_inert_ratio_cvx()
 Compute inertia ratio of the convex hull of a contour
References

dclab.features.volume.
get_volume
(cont, pos_x, pos_y, pix)[source]¶ Calculate the volume of a polygon revolved around an axis
The volume estimation assumes rotational symmetry. Green`s theorem and the Gaussian divergence theorem allow to formulate the volume as a line integral.
Parameters:  cont (ndarray or list of ndarrays of shape (N,2)) – A 2D array that holds the contour of an event [px] e.g. obtained using mm.contour where mm is an instance of RTDCBase. The first and second columns of cont correspond to the x and ycoordinates of the contour.
 pos_x (float or ndarray of length N) – The x coordinate(s) of the centroid of the event(s) [µm] e.g. obtained using mm.pos_x
 pos_y (float or ndarray of length N) – The y coordinate(s) of the centroid of the event(s) [µm] e.g. obtained using mm.pos_y
 px_um (float) – The detector pixel size in µm. e.g. obtained using: mm.config[“image”][“pix size”]
Returns: volume – volume in um^3
Return type: float or ndarray
Notes
The computation of the volume is based on a full rotation of the upper and the lower halves of the contour from which the average is then used.
The volume is computed radially from the the center position given by (pos_x, pos_y). For sufficiently smooth contours, such as densely sampled ellipses, the center position does not play an important role. For contours that are given on a coarse grid, as is the case for RTDC, the center position must be given.
References
 Halpern et al. [HWT02], chapter 5, Section 5.4
 This is a translation from a Matlab script by Geoff Olynyk.
isoelastics¶
Isoelastics management

class
dclab.isoelastics.
Isoelastics
(paths=[])[source]¶ 
add
(isoel, col1, col2, channel_width, flow_rate, viscosity, method)[source]¶ Add isoelastics
Parameters:  isoel (list of ndarrays) – Each list item resembles one isoelastic line stored as an array of shape (N,3). The last column contains the emodulus data.
 col1 (str) – Name of the first feature of all isoelastics (e.g. isoel[0][:,0])
 col2 (str) – Name of the second feature of all isoelastics (e.g. isoel[0][:,1])
 channel_width (float) – Channel width in µm
 flow_rate (float) – Flow rate through the channel in µl/s
 viscosity (float) – Viscosity of the medium in mPa*s
 method (str) – The method used to compute the isoelastics (must be one of VALID_METHODS).
Notes
The following isoelastics are automatically added for user convenience:  isoelastics with col1 and col2 interchanged  isoelastics for circularity if deformation was given

static
add_px_err
(isoel, col1, col2, px_um, inplace=False)[source]¶ Undo pixelation correction
Isoelasticity lines are already corrected for pixelation effects as described in
Mapping of Deformation to Apparent Young’s Modulus in RealTime Deformability Cytometry Christoph Herold, arXiv:1704.00572 [condmat.soft] (2017) https://arxiv.org/abs/1704.00572.
If the isoealsticity lines are displayed with deformation data that are not corrected, then the lines must be “un”corrected, i.e. the pixelation error must be added to the lines to match the experimental data.
Parameters:  isoel (list of 2d ndarrays of shape (N, 3)) – Each item in the list corresponds to one isoelasticity line. The first column is defined by col1, the second by col2, and the third column is the emodulus.
 col2 (col1,) – Define the fist to columns of each isoelasticity line. One of [“area_um”, “circ”, “deform”]
 px_um (float) – Pixel size [µm]

static
convert
(isoel, col1, col2, channel_width_in, channel_width_out, flow_rate_in, flow_rate_out, viscosity_in, viscosity_out, inplace=False)[source]¶ Convert isoelastics in area_umdeform space
Parameters:  isoel (list of 2d ndarrays of shape (N, 3)) – Each item in the list corresponds to one isoelasticity line. The first column is defined by col1, the second by col2, and the third column is the emodulus.
 col2 (col1,) – Define the fist to columns of each isoelasticity line. One of [“area_um”, “circ”, “deform”]
 channel_width_in (float) – Original channel width [µm]
 channel_width_out (float) – Target channel width [µm]
 flow_rate_in (float) – Original flow rate [µl/s]
 flow_rate_in – Target flow rate [µl/s]
 viscosity_in (float) – Original viscosity [mPa*s]
 viscosity_out (float) – Target viscosity [mPa*s]
Notes
If only the positions of the isoelastics are of interest and not the value of the elastic modulus, then it is sufficient to supply values for the channel width and set the values for flow rate and viscosity to a constant (e.g. 1).
See also
dclab.features.emodulus.convert()
 conversion method used

get
(col1, col2, method, channel_width, flow_rate=None, viscosity=None, add_px_err=False, px_um=None)[source]¶ Get isoelastics
Parameters:  col1 (str) – Name of the first feature of all isoelastics (e.g. isoel[0][:,0])
 col2 (str) – Name of the second feature of all isoelastics (e.g. isoel[0][:,1])
 method (str) – The method used to compute the isoelastics (must be one of VALID_METHODS).
 channel_width (float) – Channel width in µm
 flow_rate (float or None) – Flow rate through the channel in µl/s. If set to None, the flow rate of the imported data will be used (only do this if you do not need the correct values for elastic moduli).
 viscosity (float or None) – Viscosity of the medium in mPa*s. If set to None, the flow rate of the imported data will be used (only do this if you do not need the correct values for elastic moduli).
 add_px_err (bool) – If True, add pixelation errors according to C. Herold (2017), https://arxiv.org/abs/1704.00572
 px_um (float) – Pixel size [µm], used for pixelation error computation
See also
dclab.features.emodulus.convert()
 conversion inbetween channel sizes and viscosities
dclab.features.emodulus.corrpix_deform_delta()
 pixelation error that is applied to the deformation data

get_with_rtdcbase
(col1, col2, method, dataset, viscosity=None, add_px_err=False)[source]¶ Convenience method that extracts the metadata from RTDCBase
Parameters:  col1 (str) – Name of the first feature of all isoelastics (e.g. isoel[0][:,0])
 col2 (str) – Name of the second feature of all isoelastics (e.g. isoel[0][:,1])
 method (str) – The method used to compute the isoelastics (must be one of VALID_METHODS).
 dataset (dclab.rtdc_dataset.RTDCBase) – The dataset from which to obtain the metadata.
 viscosity (float or None) – Viscosity of the medium in mPa*s. If set to None, the flow rate of the imported data will be used (only do this if you do not need the correct values for elastic moduli).
 add_px_err (bool) – If True, add pixelation errors according to C. Herold (2017), https://arxiv.org/abs/1704.00572

load_data
(path)[source]¶ Load isoelastics from a text file
The text file is loaded with numpy.loadtxt and must have three columns, representing the two data columns and the elastic modulus with units defined in definitions.py. The file header must have a section defining meta data of the content like so:
# […] # #  column 1: area_um #  column 2: deform #  column 3: emodulus #  channel width [um]: 20 #  flow rate [ul/s]: 0.04 #  viscosity [mPa*s]: 15 #  method: analytical # # […]Parameters: path (str) – Path to a isoelastics text file

kde_contours¶

dclab.kde_contours.
find_contours_level
(density, x, y, level, closed=False)[source]¶ Find isovalued density contours for a given level value
Parameters:  density (2d ndarray of shape (M, N)) – Kernel density estimate for which to compute the contours
 x (2d ndarray of shape (M, N) or 1d ndarray of size M) – Xvalues corresponding to kde
 y (2d ndarray of shape (M, N) or 1d ndarray of size M) – Yvalues corresponding to kde
 level (float between 0 and 1) – Value along which to find contours in kde relative to its maximum kde
Returns: contours – Contours found for the given level value
Return type: list of ndarrays of shape (P, 2)
See also
skimage.measure.find_contours()
 Contour finding algorithm used

dclab.kde_contours.
get_quantile_levels
(density, x, y, xp, yp, q, normalize=True)[source]¶ Compute density levels for given quantiles by interpolation
For a given 2D density, compute the density levels at which the resulting contours contain the fraction 1q of all data points. E.g. for a measurement of 1000 events, all contours at the level corresponding to a quantile of q=0.95 (95th percentile) contain 50 events (5%).
Parameters:  density (2d ndarray of shape (M, N)) – Kernel density estimate for which to compute the contours
 x (2d ndarray of shape (M, N) or 1d ndarray of size M) – Xvalues corresponding to kde
 y (2d ndarray of shape (M, N) or 1d ndarray of size M) – Yvalues corresponding to kde
 xp (1d ndarray of size D) – Event xdata from which to compute the quantile
 yp (1d ndarray of size D) – Event ydata from which to compute the quantile
 q (array_like or float between 0 and 1) – Quantile along which to find contours in kde relative to its maximum
 normalize (bool) – Whether output levels should be normalized to the maximum of density
Returns: level – Contours level corresponding to the given quantile
Return type: Notes
NaNvalues events in xp and yp are ignored.
kde_methods¶
Kernel Density Estimation methods

dclab.kde_methods.
bin_width_doane
(a)[source]¶ Compute accuracy (bin width) based on Doane’s formula
References

dclab.kde_methods.
ignore_nan_inf
(kde_method)[source]¶ Ignores nans and infs from the input data
Invalid positions in the resulting density are set to nan.

dclab.kde_methods.
kde_gauss
(events_x, events_y, xout=None, yout=None, *args, **kwargs)[source]¶ Gaussian Kernel Density Estimation
Parameters:  events_y (events_x,) – The input points for kernel density estimation. Input is flattened automatically.
 yout (xout,) – The coordinates at which the KDE should be computed. If set to none, input coordinates are used.
Returns: density – The KDE for the points in (xout, yout)
Return type: ndarray, same shape as xout
See also
scipy.stats.gaussian_kde
Notes
This is a wrapped version that ignores nan and inf values.

dclab.kde_methods.
kde_histogram
(events_x, events_y, xout=None, yout=None, *args, **kwargs)[source]¶ Histogrambased Kernel Density Estimation
Parameters:  events_y (events_x,) – The input points for kernel density estimation. Input is flattened automatically.
 yout (xout,) – The coordinates at which the KDE should be computed. If set to none, input coordinates are used.
 bins (tuple (binsx, binsy)) – The number of bins to use for the histogram.
Returns: density – The KDE for the points in (xout, yout)
Return type: ndarray, same shape as xout
See also
numpy.histogram2d scipy.interpolate.RectBivariateSpline
Notes
This is a wrapped version that ignores nan and inf values.

dclab.kde_methods.
kde_multivariate
(events_x, events_y, xout=None, yout=None, *args, **kwargs)[source]¶ Multivariate Kernel Density Estimation
Parameters: Returns: density – The KDE for the points in (xout, yout)
Return type: ndarray, same shape as xout
See also
statsmodels.nonparametric.kernel_density.KDEMultivariate
Notes
This is a wrapped version that ignores nan and inf values.

dclab.kde_methods.
kde_none
(events_x, events_y, xout=None, yout=None)[source]¶ No Kernel Density Estimation
Parameters:  events_y (events_x,) – The input points for kernel density estimation. Input is flattened automatically.
 yout (xout,) – The coordinates at which the KDE should be computed. If set to none, input coordinates are used.
Returns: density – The KDE for the points in (xout, yout)
Return type: ndarray, same shape as xout
Notes
This method is a convenience method that always returns ones in the shape that the other methods in this module produce.
polygon_filter¶

class
dclab.polygon_filter.
PolygonFilter
(axes=None, points=None, inverted=False, name=None, filename=None, fileid=0, unique_id=None)[source]¶ An object for filtering RTDC data based on a polygonial area
Parameters:  axes (tuple of str) – The axes/features on which the polygon is defined. The first axis is the xaxis. Example: (“area_um”, “deform”).
 points (arraylike object of shape (N,2)) – The N coordinates (x,y) of the polygon. The exact order is important.
 inverted (bool) – Invert the polygon filter. This parameter is overridden if filename is given.
 name (str) – A name for the polygon (optional).
 filename (str) – A path to a .poly file as create by this classes’ save method. If filename is given, all other parameters are ignored.
 fileid (int) – Which filter to import from the file (starting at 0).
 unique_id (int) – An integer defining the unique id of the new instance.
Notes
The minimal arguments to this class are either filename OR (axes, points). If filename is set, all parameters are taken from the given .poly file.

copy
(invert=False)[source]¶ Return a copy of the current instance
Parameters: invert (bool) – The copy will be inverted w.r.t. the original

static
get_instance_from_id
(unique_id)[source]¶ Get an instance of the PolygonFilter using a unique id

static
import_all
(path)[source]¶ Import all polygons from a .poly file.
Returns a list of the imported polygon filters

static
point_in_poly
(p, poly)[source]¶ Determine whether a point is within a polygon area
Uses the ray casting algorithm.
Parameters:  p (float) – Coordinates of the point
 poly (array_like of shape (N, 2)) – Polygon (PolygonFilter.points)
Returns: inside – True, if point is inside.
Return type: Notes
If p lies on a side of the polygon, it is defined as
 “inside” if it is on the top or right
 “outside” if it is on the lower or left

save
(polyfile, ret_fobj=False)[source]¶ Save all data to a text file (appends data if file exists).
Polyfile can be either a path to a file or a file object that was opened with the write “w” parameter. By using the file object, multiple instances of this class can write their data.
If ret_fobj is True, then the file object will not be closed and returned.

instances
= [<dclab.polygon_filter.PolygonFilter object>]¶
statistics¶
Statistics computation for RTDC dataset instances

class
dclab.statistics.
Statistics
(name, method, req_feature=False)[source]¶ A helper class for computing statistics
All statistical methods are registered in the dictionary Statistics.available_methods.

get_feature
(ds, feat)[source]¶ Return filtered feature data
The features are filtered according to the userdefined filters, using the information in ds._filter. In addition, all nan and inf values are purged.
Parameters:  ds (dclab.rtdc_dataset.RTDCBase) – The dataset containing the feature
 feat (str) – The name of the feature; must be a scalar feature

available_methods
= {'%gated': <dclab.statistics.Statistics object>, 'Events': <dclab.statistics.Statistics object>, 'Flow rate': <dclab.statistics.Statistics object>, 'Mean': <dclab.statistics.Statistics object>, 'Median': <dclab.statistics.Statistics object>, 'Mode': <dclab.statistics.Statistics object>, 'SD': <dclab.statistics.Statistics object>}¶


dclab.statistics.
get_statistics
(ds, methods=None, features=None)[source]¶ Compute statistics for an RTDC dataset
Parameters:  ds (dclab.rtdc_dataset.RTDCBase) – The dataset for which to compute the statistics.
 methods (list of str or None) – The methods wih which to compute the statistics. The list of available methods is given with dclab.statistics.Statistics.available_methods.keys() If set to None, statistics for all methods are computed.
 features (list of str) – Feature name identifiers are defined in dclab.definitions.scalar_feature_names. If set to None, statistics for all axes are computed.
Returns:  header (list of str) – The header (feature + method names) of the computed statistics.
 values (list of float) – The computed statistics.

dclab.statistics.
mode
(data)[source]¶ Compute an intelligent value for the mode
The most common value in experimental is not very useful if there are a lot of digits after the comma. This method approaches this issue by rounding to bin size that is determined by the Freedman–Diaconis rule.
Parameters: data (1d ndarray) – The data for which the mode should be computed. Returns: mode – The mode computed with the FreedmanDiaconis rule. Return type: float