Code reference¶
Module level aliases¶
For user convenience, the following objects are available at the module level.

class
nanite.
Indentation
¶ alias of
nanite.indent.Indentation

class
nanite.
IndentationGroup
¶ alias of
nanite.group.IndentationGroup

class
nanite.
IndentationRater
¶ alias of
nanite.rate.IndentationRater

class
nanite.
QMap
¶ alias of
nanite.qmap.QMap

nanite.
load_group
()¶ alias of
nanite.group.load_group
Forceindentation data¶

class
nanite.indent.
Indentation
(idnt_data)[source]¶ Forceindentation
Parameters: idnt_data (nanite.read.IndentationData) – Object holding the experimental data 
apply_preprocessing
(preprocessing=None)[source]¶ Perform curve preprocessing steps
Parameters: preprocessing (list) – A list of preprocessing method names that are stored in the IndentationPreprocessor class. If set to None, self.preprocessing will be used.

compute_emodulus_mindelta
(callback=None)[source]¶ Elastic modulus in dependency of maximum indentation
The fitting interval is varied such that the maximum indentation depth ranges from the lowest tip position to the estimated contact point. For each interval, the current model is fitted and the elastic modulus is extracted.
Parameters: callback (callable) – A method that is called with the emoduli and indentations as the computation proceeds every five steps. Returns: emoduli, indentations – The fitted elastic moduli at the corresponding maximal indentation depths. Return type: 1d ndarrays Notes
The information about emodulus and mindelta is also stored in self.fit_properties with the keys “optimal_fit_E_array” and “optimal_fit_delta_array”, if self.fit_model is called with the argument search_optimal_fit set to True.

estimate_contact_point_index
()[source]¶ Estimate the contact point
Contact point (CP) estimation involves a preprocessing step where the force data are transformed into gradient space (to account for a slope in the approach curve) and a subsequent analysis with two different methods to determine when the gradient changes significantly enough to qualify for a CP. Of those two methods, the one which yields the smallest index (measured from the beginning of the approach curve) is returned. If one of the methods fail, then a fit function with a constant and linear part is used to determine the CP.
Preprocessing:
 Compute the rolling average of the force (Otherwise the gradient would be too wild)
 Compute the gradient (Converting to gradient space gets rid of linear contributions in the approach part)
 Compute the rolling average of the gradient (Makes the curve to analyze more smooth so that the methods below don’t hit the alarm too early)
Method 1: baseline deviation
 Obtain the baseline (initial 10% of the gradient curve)
 Compute average and maximum deviation of the baseline
 The CP is the index of the curve where it exceeds twice of the maximum deviation
Method 2: sign of gradient
 Apply a median filter to the approach curve
 Compute the gradient
 Cut off trailing 10 points from the gradient (noise)
 The CP is the index of the gradient curve when the sign changes, measured from the point of maximal indentation.
If one of the methods fail, then a combined constant+linear function (max(constant, linear) is fitted to the gradient to determine the contact point. If that fails as well, then the CP defaults to the center of the entire approach curve.
Changed in version 1.6.0: Add the gradient preprocessing step to circumvent issues with tilted baselines. This feature does not significantly affect fitting results.
Changed in version 1.6.1: Added max(constant, linear) fit when the other methods fail.

estimate_optimal_mindelta
()[source]¶ Estimate the optimal indentation depth
This is a convenience function that wraps around compute_emodulus_mindelta and IndentationFitter.compute_opt_mindelta.

fit_model
(**kwargs)[source]¶ Fit the approachretract data to a model function
Parameters:  model_key (str) – A key referring to a model in nanite.model.models_available
 params_initial (instance of lmfit.Parameters or dict) – Parameters for fitting. If not given, default parameters are used.
 range_x (tuple of 2) – The range for fitting, see range_type below.
 range_type (str) –
One of:
 absolute:
 Set the absolute fitting range in values given by the x_axis.
 relative cp:
 In some cases it is desired to be able to fit a model only up until a certain indentation depth (tip position) measured from the contact point. Since the contact point is a fit parameter as well, this requires a twopass fitting.
 preprocessing (list of str) – Preprocessing
 segment (str) – One of “approach” or “retract”.
 weight_cp (float) – Weight the contact point region which shows artifacts that are difficult to model with e.g. Hertz.
 optimal_fit_edelta (bool) – Search for the optimal fit by varying the maximal indentation depth and determining a plateau in the resulting Young’s modulus (fitting parameter “E”).

get_ancillary_parameters
(model_key=None)[source]¶ Compute ancillary parameters for the current model

get_initial_fit_parameters
(model_key=None, common_ancillaries=True, model_ancillaries=True)[source]¶ Return the initial fit parameters
If there are not initial fit parameters set in self.fit_properties, then they are computed.
Parameters: Notes
global_ancillaries and model_ancillaries only have an effect if self.fit_properties[“params_initial”] is set.

rate_quality
(regressor='Extra Trees', training_set='zef18', names=None, lda=None)[source]¶ Compute the quality of the obtained curve
Uses heuristic approaches to rate a curve.
Parameters: Returns: rating – A value between 0 and 10 where 0 is the lowest rating. If no fit has been performed, a rating of 1 is returned.
Return type: Notes
The rating is cached based on the fitting hash (see IndentationFitter._hash).

data
= None¶ All data as afmformats.AFMForceDistance

fit_properties
¶ Fitting results, see
Indentation.fit_model()
)

preprocessing
= None¶ Default preprocessing steps steps, see
Indentation.apply_preprocessing()
.

Groups¶

class
nanite.group.
IndentationGroup
(path=None, callback=None)[source]¶ Group of Indentation
Parameters: 
append
(item)[source]¶ Append an indentation dataset
Parameters: item (nanite.indent.Indentation) – Forceindentation dataset


nanite.group.
load_group
(path, callback=None)[source]¶ Load indentation data from disk
Parameters:  path (pathlike) – Path to experimental data
 callback (callable or None) – Callback function for tracking loading progress
Returns: group – Indentation group with forcedistance data
Return type: nanite.IndetationGroup
Loading data¶

nanite.read.
get_data_paths
(path)[source]¶ Obtain a list of data files
Parameters: path (str or pathlib.Path) – Path to a data file or a directory containing data files. Returns: paths – All supported data files found in path. If path is a file, [pathlib.Path(path)] is returned. If path has an unsupported extion, an empty list is returned. Return type: list of pathlib.Path
Preprocessing¶

class
nanite.preproc.
IndentationPreprocessor
[source]¶ 
static
apply
(apret, preproc_names)[source]¶ Perform forcedistance preprocessing steps
Parameters:  apret (nanite.Indentation) – The afm data to preprocess
 preproc_names (list) – A list of names for static methods in IndentationPreprocessor that will be applied (in the order given).
Notes
This method is usually called from within the Indentation class instance. If you are using this class directly and apply it more than once, you might need to call apret.reset() before preprocessing a second time.

static
compute_tip_position
(apret)[source]¶ Compute the tipsample separation
This computation correctly reproduces the column “Vertical Tip Position” as it is exported by the JPK analysis software with the checked option “Use Unsmoothed Height”.

static
correct_split_approach_retract
(apret)[source]¶ Split the approach and retract curves (farthest point method)
Approach and retract curves are defined by the microscope. When the direction of piezo movement is flipped, the force at the sample tip is still increasing. This can be either due to a time lag in the AFM system or due to a residual force acting on the sample due to the bent cantilever.
To repair this time lag, we append parts of the retract curve to the approach curve, such that the curves are split at the minimum height.

static

nanite.preproc.
available_preprocessors
= ['compute_tip_position', 'correct_force_offset', 'correct_split_approach_retract', 'correct_tip_offset', 'smooth_height']¶ Available preprocessors
Modeling¶
Methods and constants¶

nanite.model.
get_anc_parm_keys
(model_key)[source]¶ Return the key names of a model’s ancillary parameters

nanite.model.
get_anc_parms
(idnt, model_key)[source]¶ Compute ancillary parameters for a forcedistance dataset
Ancillary parameters include parameters that:
 are unrelated to fitting: They may just be important parameters to the user.
 require the entire dataset: They cannot be extracted during fitting, because they require more than just the approach xor retract curve to compute (e.g. hysteresis, jump of retract curve at maximum indentation). They may, additionally, depend on initial fit parameters set by the user.
 require a fit: They are dependent on fitting parameters but are not required during fitting.
Notes
If an ancillary parameter name matches that of a fitting parameter, then it is assumed that it can be used for fitting. Please see
nanite.indent.Indentation.get_initial_fit_parameters()
andnanite.fit.guess_initial_parameters()
.Ancillary parameters are set to np.nan if they cannot be computed.
Parameters:  idnt (nanite.indent.Indentation) – The forcedistance data for which to compute the ancillary parameters
 model_key (str) – Name of the model
Returns: ancillaries – keyvalue dictionary of ancillary parameters
Return type:

nanite.model.
get_model_by_name
(name)[source]¶ Convenience function to obtain a model by name instead of by key

nanite.model.
get_parm_name
(model_key, parm_key)[source]¶ Return parameter label
Parameters: Returns: parm_name – The parameter label (e.g. “Young’s Modulus”)
Return type:

nanite.model.
get_parm_unit
(model_key, parm_key)[source]¶ Return parameter unit
Parameters: Returns: parm_unit – The parameter unit (e.g. “Pa”)
Return type:

nanite.model.
ANCILLARY_COMMON
= {'max_indent': ('Maximum indentation', 'm')}¶ Common ancillary parameters
Models¶
Each model is implemented as a submodule in nanite.model. For instance
nanite.model.model_hertz_parabolic
. Each of these modules implements
the following functions (which are not listed for each model in the
subsections below):

nanite.model.model_submodule.
get_parameter_defaults
()¶ Return the default parameters of the model.

nanite.model.model_submodule.
model
()¶ Wrap the actual model for fitting.

nanite.model.model_submodule.
residual
()¶ Compute the residuals during fitting.
In addition, each submodule contains the following attributes:

nanite.model.model_submodule.
model_doc
¶ The docstring of the model function.

nanite.model.model_submodule.
model_key
¶ The model key used in the command line interface and during scripting.

nanite.model.model_submodule.
model_name
¶ The name of the model.

nanite.model.model_submodule.
parameter_keys
¶ Parameter keywords of the model for higherlevel applications.

nanite.model.model_submodule.
parameter_names
¶ Parameter names of the model for higherlevel applications.

nanite.model.model_submodule.
parameter_units
¶ Parameter units for higherlevel applications.
conical indenter (Hertz)¶
model key  hertz_cone 
model name  conical indenter (Hertz) 
model location  nanite.model.model_conical_indenter 

nanite.model.model_conical_indenter.
hertz_conical
(E, delta, alpha, nu, contact_point=0, baseline=0)[source]¶ Hertz model for a conical indenter
\[F = \frac{2\tan\alpha}{\pi} \frac{E}{1\nu^2} \delta^2\]Parameters:  E (float) – Young’s modulus [N/m²]
 delta (1d ndarray) – Indentation [m]
 alpha (float) – Half cone angle [degrees]
 nu (float) – Poisson’s ratio
 contact_point (float) – Indentation offset [m]
 baseline (float) – Force offset [N]
 negindent (bool) – If True, will assume that the indentation value(s) given by delta are negative and must be mutlitplied by 1.
Returns: F – Force [N]
Return type: Notes
These approximations are made by the Hertz model:
 The sample is isotropic.
 The sample is a linear elastic solid.
 The sample is extended infinitely in one half space.
 The indenter is not deformable.
 There are no additional interactions between sample and indenter.
Additional assumptions:
 infinitely sharp probe
References
Love (1939) [Love1939]
parabolic indenter (Hertz)¶
model key  hertz_para 
model name  parabolic indenter (Hertz) 
model location  nanite.model.model_hertz_paraboloidal 

nanite.model.model_hertz_paraboloidal.
hertz_paraboloidal
(E, delta, R, nu, contact_point=0, baseline=0)[source]¶ Hertz model for a paraboloidal indenter
\[F = \frac{4}{3} \frac{E}{1\nu^2} \sqrt{R} \delta^{3/2}\]Parameters:  E (float) – Young’s modulus [N/m²]
 delta (1d ndarray) – Indentation [m]
 R (float) – Tip radius [m]
 nu (float) – Poisson’s ratio
 contact_point (float) – Indentation offset [m]
 baseline (float) – Force offset [N]
 negindent (bool) – If True, will assume that the indentation value(s) given by delta are negative and must be mutlitplied by 1.
Returns: F – Force [N]
Return type: Notes
The original model reads
\[F = \frac{4}{3} \frac{E}{1\nu^2} \sqrt{2k} \delta^{3/2},\]where \(k\) is defined by the paraboloid equation
\[\rho^2 = 4kz.\]These approximations are made by the Hertz model:
 The sample is isotropic.
 The sample is a linear elastic solid.
 The sample is extended infinitely in one half space.
 The indenter is not deformable.
 There are no additional interactions between sample and indenter.
Additional assumptions:
 radius of spherical cell is larger than the indentation
References
Sneddon (1965) [Sneddon1965]
pyramidal indenter, threesided (Hertz)¶
model key  hertz_pyr3s 
model name  pyramidal indenter, threesided (Hertz) 
model location  nanite.model.model_hertz_three_sided_pyramid 

nanite.model.model_hertz_three_sided_pyramid.
hertz_three_sided_pyramid
(E, delta, alpha, nu, contact_point=0, baseline=0)[source]¶ Hertz model for three sided pyramidal indenter
\[F = 0.887 \tan\alpha \cdot \frac{E}{1\nu^2} \delta^2\]Parameters:  E (float) – Young’s modulus [N/m²]
 delta (1d ndarray) – Indentation [m]
 alpha (float) – Inclination angle of the pyramidal face [degrees]
 nu (float) – Poisson’s ratio
 contact_point (float) – Indentation offset [m]
 baseline (float) – Force offset [N]
 negindent (bool) – If True, will assume that the indentation value(s) given by delta are negative and must be mutlitplied by 1.
Returns: F – Force [N]
Return type: Notes
These approximations are made by the Hertz model:
 The sample is isotropic.
 The sample is a linear elastic solid.
 The sample is extended infinitely in one half space.
 The indenter is not deformable.
 There are no additional interactions between sample and indenter.
 The inclination angle of the pyramidal face (in radians) must be close to zero.
References
Bilodeau et al. 1992 [Bilodeau:1992]
spherical indenter (Sneddon)¶
model key  sneddon_spher 
model name  spherical indenter (Sneddon) 
model location  nanite.model.model_sneddon_spherical 

nanite.model.model_sneddon_spherical.
delta_of_a
()¶ Compute indentation from contact area radius (wrapper)

nanite.model.model_sneddon_spherical.
get_a
()¶ Compute the contact area radius (wrapper)

nanite.model.model_sneddon_spherical.
hertz_spherical
()¶ Hertz model for Spherical indenter  modified by Sneddon
\[\begin{split}F &= \frac{E}{1\nu^2} \left( \frac{R^2+a^2}{2} \ln \! \left( \frac{R+a}{Ra}\right) aR \right)\\ \delta &= \frac{a}{2} \ln \! \left(\frac{R+a}{Ra}\right)\end{split}\](\(a\) is the radius of the circular contact area between bead and sample.)
Parameters:  E (float) – Young’s modulus [N/m²]
 delta (1d ndarray) – Indentation [m]
 R (float) – Tip radius [m]
 nu (float) – Poisson’s ratio
 contact_point (float) – Indentation offset [m]
 baseline (float) – Force offset [N]
 negindent (bool) – If True, will assume that the indentation value(s) given by delta are negative and must be multiplied by 1.
Returns: F – Force [N]
Return type: Notes
These approximations are made by the Hertz model:
 The sample is isotropic.
 The sample is a linear elastic solid.
 The sample is extended infinitely in one half space.
 The indenter is not deformable.
 There are no additional interactions between sample and indenter.
Additional assumptions:
 no surface forces
References
Sneddon (1965) [Sneddon1965]
spherical indenter (Sneddon, approximative)¶
model key  sneddon_spher_approx 
model name  spherical indenter (Sneddon, approximative) 
model location  nanite.model.model_sneddon_spherical_approximation 

nanite.model.model_sneddon_spherical_approximation.
hertz_sneddon_spherical_approx
(E, delta, R, nu, contact_point=0, baseline=0)[source]¶ Hertz model for Spherical indenter  approximation
\[F = \frac{4}{3} \frac{E}{1\nu^2} \sqrt{R} \delta^{3/2} \left(1  \frac{1}{10} \frac{\delta}{R}  \frac{1}{840} \left(\frac{\delta}{R}\right)^2 + \frac{11}{15120} \left(\frac{\delta}{R}\right)^3 + \frac{1357}{6652800} \left(\frac{\delta}{R}\right)^4 \right)\]Parameters:  E (float) – Young’s modulus [N/m²]
 delta (1d ndarray) – Indentation [m]
 R (float) – Tip radius [m]
 nu (float) – Poisson’s ratio
 contact_point (float) – Indentation offset [m]
 baseline (float) – Force offset [N]
 negindent (bool) – If True, will assume that the indentation value(s) given by delta are negative and must be mutlitplied by 1.
Returns: F – Force [N]
Return type: Notes
These approximations are made by the Hertz model:
 The sample is isotropic.
 The sample is a linear elastic solid.
 The sample is extended infinitely in one half space.
 The indenter is not deformable.
 There are no additional interactions between sample and indenter.
Additional assumptions:
 no surface forces
References
Sneddon (1965) [Sneddon1965], Dobler (personal communication, 2018) [Dobler]
Fitting¶

class
nanite.fit.
FitProperties
[source]¶ Fit property manager class
Provide convenient access to fit properties as a dictionary and dynamically manage resets due to new initial parameters.
Dynamic properties include:
 set “params_initial” to None if the “model_key” changes
 remove all keys except those in FP_DEFAULT if a key that is in FP_DEFAULT changes (All other keys are considered to be obsolete fitting results).
Additional attributes:
 “segment_bool”: bool
 False for “approach” and True for “retract”

class
nanite.fit.
IndentationFitter
(idnt, **kwargs)[source]¶ Fit forcedistance curves
Parameters:  idnt (nanite.indent.Indentation) – The dataset to fit
 model_key (str) – A key referring to a model in nanite.model.models_available
 params_initial (instance of lmfit.Parameters) – Parameters for fitting. If not given, default parameters are used.
 range_x (tuple of 2) – The range for fitting, see range_type below.
 range_type (str) –
One of:
 absolute:
 Set the absolute fitting range in values given by the x_axis.
 relative cp:
 In some cases it is desired to be able to fit a model only up until a certain indentation depth (tip position) measured from the contact point. Since the contact point is a fit parameter as well, this requires a twopass fitting.
 preprocessing (list of str) – Preprocessing
 segment (str) – One of “approach” or “retract”.
 weight_cp (float) – Weight the contact point region which shows artifacts that are difficult to model with e.g. Hertz.
 optimal_fit_edelta (bool) – Search for the optimal fit by varying the maximal indentation depth and determining a plateau in the resulting Young’s modulus (fitting parameter “E”).
 optimal_fit_num_samples (int) – Number of samples to use for searching the optimal fit

compute_emodulus_vs_mindelta
(callback=None)[source]¶ Compute elastic modulus vs. minimal indentation curve

static
compute_opt_mindelta
(emoduli, indentations)[source]¶ Determine the plateau of an emodulusindentation curve
The following procedure is performed:
 Smooth the emodulus data with a Butterworth filter
 Label sequences that have similar values by binning into ten regions between the min and max.
 Ignore sequences with emodulus that is smaller than the binning size.
 Determine the longest sequence.

nanite.fit.
guess_initial_parameters
(idnt=None, model_key='hertz_para', common_ancillaries=True, model_ancillaries=True)[source]¶ Guess initial fitting parameters
Parameters:  idnt (nanite.indent.Indentation) – The dataset to use for guessing initial fitting parameters using ancillary parameters
 model_key (str) – The model key
 common_ancillaries (bool) – Guess global ancillary parameters (such as contact point)
 model_ancillaries (bool) – Use modelrelated ancillary parameters
Rating¶
Features¶

class
nanite.rate.features.
IndentationFeatures
(dataset=None)[source]¶ 
static
compute_features
(idnt, which_type='all', names=None, ret_names=False)[source]¶ Compute the features for a data set
Parameters:  idnt (nanite.Indentation) – A dataset to rate
 names (list of str) – The names of the rating methods to use, e.g. [“rate_apr_bumps”, “rate_apr_mon_incr”]. If None (default), all available rating methods are used.
Notes
names may include features that are excluded by which_type. E.g. if a “bool” feature is in names but which_type is “float”, then the “bool” feature will be silently ignored.

feat_con_apr_flatness
()[source]¶ flatness of APR residuals
fraction of the positivegradient residuals in the approach part

feat_con_apr_size
()[source]¶ relative APR size
length of the approach part relative to the indentation part

feat_con_bln_slope
()[source]¶ slope of BLN
slope obtained from a linear leastsquares fit to the baseline

feat_con_bln_variation
()[source]¶ variation in BLN
comparison of the forces at the beginning and at the end of the baseline

feat_con_cp_curvature
()[source]¶ curvature at CP
curvature of the forcedistance data at the contact point

feat_con_cp_magnitude
()[source]¶ residuals at CP
mean value of the residuals around the contact point

feat_con_idt_maxima_75perc
()[source]¶ maxima in IDT residuals
sum of the indentation residuals’ maxima in three intervals inbetween 25% and 100% relative to the maximum indentation

feat_con_idt_spike_area
()[source]¶ area of IDT spikes
area of spikes appearing in the indentation part

feat_con_idt_sum_75perc
()[source]¶ residuals in 75% IDT
sum of the residuals in the indentation part inbetween 25% and 100% relative to the maximum indentation

classmethod
get_feature_funcs
(which_type='all', names=None)[source]¶ Return functions that compute features from a dataset
Parameters:  names (list of str) – The names of the rating methods to use, e.g. [“rate_apr_bumps”, “rate_apr_mon_incr”]. If None (default), all available rating methods are returned.
 which_type (str) – Which features to return: [“all”, “bool”, “float”].
Returns: raters – Each item in the list consists contains the name of the rating method and the corresponding rating method.
Return type: list of tuples (name, callable)

classmethod
get_feature_names
(which_type='all', names=None, ret_indices=False)[source]¶ Get features names
Parameters: Returns: name_list – List of feature names (callables of this class)
Return type: list of str

contact_point
¶

datafit_apr
¶

datares_apr
¶

dataset
= None¶ current dataset from which features are computed

datax_apr
¶

datay_apr
¶

has_contact_point
¶

is_fitted
¶

is_valid
¶

meta
¶

static

nanite.rate.features.
VALID_FEATURE_TYPES
= ['all', 'binary', 'continuous']¶ Valid keyword arguments for feature types
Rater¶

class
nanite.rate.rater.
IndentationRater
(regressor=None, scale=None, lda=None, training_set=None, names=None, weight=True, sample_weight=None, *args, **kwargs)[source]¶ Rate quality
Parameters:  regressor (scikilearn RegressorMixin) – The regressor used for rating
 scale (bool) – If True, apply a Standard Scaler. If a regressor based on decision trees is used, the Standard Scaler is not used by default, otherwise it is.
 lda (bool) – If True, apply a Linear Discriminant Analysis (LDA). If a regressor based on a decision tree is used, LDA is not used by default, otherwise it is.
 training_set (tuple of (X, y)) – The training set (samples, response)
 names (list of str) – Feature names to use
 weight (bool) – Weight the input samples by the number of occurrences or with sample_weight. For treebased classifiers, set this to True to avoid bias.
 sample_weight (listlike) – The sample weights. If set to None sample weights are computed from the training set.
 *args (list) – Positional arguments for
IndentationFeatures
 **kwargs – Keyword arguments for
IndentationFeatures
See also
sklearn.preprocessing.StandardScaler
 Standard scaler
sklearn.discriminant_analysis.LinearDiscriminantAnalysis
 Linear discriminant analysis
nanite.rate.regressors.reg_trees
 List of regressors that are identified as treebased

static
get_training_set_path
(label='zef18')[source]¶ Return the path to a training set shipped with nanite
Training sets are stored in the nanite.rate module path with
ts_
prepended to label.

classmethod
load_training_set
(path=None, names=None, which_type=['continuous'], remove_nan=True, ret_names=False)[source]¶ Load a training set from a directory
By default, only the “continuous” features are imported. The “binary” features are not needed for training; they are used to sort out new forcedistance data.

rate
(samples=None, datasets=None)[source]¶ Perform rating step
Parameters:  samples (1d or 2d ndarray (cast to 2d ndarray) or None) – Measured samples, if set to None, dataset must be given.
 dataset (list of nanite.Indentation) – Full, fitted measurement
Returns: ratings – Resulting ratings
Return type:

names
= None¶ feature names used by the regressor pipeline

pipeline
= None¶ sklearn pipeline with transforms (and regressor if given)

nanite.rate.rater.
get_rater
(regressor, training_set='zef18', names=None, lda=None, **reg_kwargs)[source]¶ Convenience method to get a rater
Parameters:  regressor (str or RegressorMixin) – If a string, must be in reg_names.
 training_set (str or pathlib.Path or tuple (X, y)) – A string label representing a training set shipped with nanite, the path to a training set, or a tuple representing the training set (samples, response) for use with sklearn.
Returns: irater – The rating instance.
Return type:
Regressors¶
scikitlearn regressors and their keyword arguments

nanite.rate.regressors.
reg_names
= ['AdaBoost', 'Decision Tree', 'Extra Trees', 'Gradient Tree Boosting', 'Random Forest', 'SVR (RBF kernel)', 'SVR (linear kernel)']¶ List of available default regressor names

nanite.rate.regressors.
reg_trees
= ['AdaBoostRegressor', 'DecisionTreeRegressor', 'ExtraTreesRegressor', 'GradientBoostingRegressor', 'RandomForestRegressor']¶ List of treebased regressor class names (used for keyword defaults in
IndentationRater
)
Manager¶
Save and load userrated datasets

class
nanite.rate.io.
RateManager
(path, verbose=0)[source]¶ Manage userdefined rates

get_cross_validation_score
(regressor, training_set=None, n_splits=20, random_state=42)[source]¶ Regressor crossvalidation scoring
Crossvalidation is used to identify regressors that overfit the train set by splitting the train set into multiple learn/test sets and quantifying the regressor performance for each split.
Parameters:  regressor (str or RegressorMixin) – If a string, must be in reg_names.
 training_set (X, y) – If given, do not use self.samples
Notes
A
skimage.model_selection.KFold
cross validator is used in combination with the mean squared error score.Crossvalidation score is computed from samples that are filtered with the binary features and only from samples that do not contain any nan values.

get_rates
(which='user', training_set='zef18')[source]¶  which: str
 Which rating to return: “user” or a regressor name

get_training_set
(which_type='all', prefilter_binary=False, remove_nans=False, transform=False)[source]¶ Return (X, y) training set

datasets
¶

path
= None¶ Path to the manual ratings (directory or .h5 file)

ratings
¶

samples
¶ The individual sample ratings computed by afmlib

verbose
= None¶ verbosity level


nanite.rate.io.
hdf5_rated
(h5path, indent)[source]¶ Test whether an indentation has already been rated
Returns: Return type: is_rated, rating, comment

nanite.rate.io.
load
(path, meta_only=False, verbose=0)[source]¶ Notes
The .fit_properties attribute of each Indentation instance is overridden by a simple dictionary, so its functionalities are not available anymore.

nanite.rate.io.
save_hdf5
(h5path, indent, user_rate, user_name, user_comment, h5mode='a')[source]¶ Store all relevant data of a user rating into an hdf5 file
Parameters:  h5path (str) – Path to HDF5 rating container where data will be stored
 indent (nanite.Indentation) – The experimental data processed and fitted with nanite
 user_rate (float) – Rating given by the user
 user_name (str) – Name of the rating user
Quantitative maps¶

class
nanite.qmap.
QMap
(path_or_dataset, callback=None)[source]¶ Quantitative force spectroscopy map handling
Parameters:  path_or_dataset (str or nanite.IndentationGroup) – The path to the data file. The data format is determined using the extension of the file and the data is loaded with the correct method.
 callback (callable or None) – A method that accepts a float between 0 and 1 to externally track the process of loading the data.

get_qmap
(feature, qmap_only=False)[source]¶ Return the quantitative map for a feature
Parameters:  feature (str) – Feature to compute map for (see
QMap.features
)  qmap_only – Only return the quantitative map data, not the coordinates
Returns:  x, y (1d ndarray) – Only returned if qmap_only is False; Pixel grid coordinates along x and y
 qmap (2d ndarray) – Quantitative map
 feature (str) – Feature to compute map for (see

extent
¶ extent (x1, x2, y1, y2) [µm]

features
= None¶ Available features (see
nanite.qmap.available_features
)

get_coords
[source]¶ Get the qmap coordinates for each curve in QMap.ds
Parameters: which (str) – “px” for pixels or “um” for microns.

group
= None¶ Indentation data (instance of
nanite.IndentationGroup
)

shape
¶ shape of the map [px]

nanite.qmap.
available_features
= ['data min height', 'fit contact point', "fit young's modulus", 'meta rating', 'meta scan order']¶ Available features for quantitative maps