ErrorAmplificationAnalysis#

class ErrorAmplificationAnalysis(name=None)[source]#

Error amplification analysis class based on a fit to a cosine function.

Fit model

This is the curve fitting analysis. The following equation(s) are used to represent curve(s).

Analyse an error amplifying calibration experiment by fitting the data to a cosine function. The user must also specify the intended rotation angle per gate, here labeled, \({\rm apg}\). The parameter of interest in the fit is the deviation from the intended rotation angle per gate labeled \({\rm d}\theta\). The fit function is

\[y = \frac{{\rm amp}}{2}\cos\left(x[{\rm d}\theta + {\rm apg} ] \ -{\rm phase\_offset}\right)+{\rm base}\]

To understand how the error is measured we can transformed the function above into

\[y = \frac{{\rm amp}}{2} \left(\ \cos\right({\rm d}\theta \cdot x\left)\ \cos\right({\rm apg} \cdot x - {\rm phase\_offset}\left) -\ \sin\right({\rm d}\theta \cdot x\left)\ \sin\right({\rm apg} \cdot x - {\rm phase\_offset}\left) \right) + {\rm base}\]

When \({\rm apg} \cdot x - {\rm phase\_offset} = (2n + 1) \pi/2\) is satisfied the fit model above simplifies to

\[y = \mp \frac{{\rm amp}}{2} \sin\left({\rm d}\theta \cdot x\right) + {\rm base}\]

In the limit \({\rm d}\theta \ll 1\), the error can be estimated from the curve data

\[{\rm d}\theta \simeq \mp \frac{2(y - {\rm base})}{x \cdot {\rm amp}}\]

Fit parameters

The following fit parameters are estimated during the analysis.

Descriptions
  • \(\rm amp\): Amplitude of the oscillation.

  • \(\rm base\): Base line.

  • \(d\theta\): The angle offset in the gate that we wish to measure.

Initial Guess
  • \(\rm amp\): The maximum y value less the minimum y value.

  • \(\rm base\): The average of the data.

  • \(d\theta\): Multiple initial guesses are tried ranging from -a to a where a is given by max(abs(angle_per_gate), np.pi / 2). Extra guesses are added based on curve data when either \(\rm amp\) or \(\rm base\) is \(\pi/2\). See fit model for details.

Boundaries
  • \(\rm amp\): [-2, 2] scaled to the maximum signal value.

  • \(\rm base\): [-1, 1] scaled to the maximum signal value.

  • \(d\theta\): [-0.8 pi, 0.8 pi]. The bounds do not include plus and minus pi since these values often correspond to symmetry points of the fit function. Furthermore, this type of analysis is intended for values of \(d\theta\) close to zero.

Analysis options

These are the keyword arguments of the run() method.

Options
  • Defined in the class ErrorAmplificationAnalysis:

    • max_good_angle_error (float)

      Default value: 1.5707963267948966
      The maximum angle error for which the fit is considered as good. Defaults to \(\pi/2\).
  • Defined in the class BaseCurveAnalysis:

    • plotter (BasePlotter)

      Default value: Instance of CurvePlotter
      A curve plotter instance to visualize the analysis result.
    • plot_raw_data (bool)

      Default value: False
      Set True to draw processed data points, dataset without formatting, on canvas. This is False by default.
    • return_fit_parameters (bool)

      Default value: True
      (Deprecated) Set True to return all fit model parameters with details of the fit outcome. Default to False.
    • return_data_points (bool)

      Default value: False
      (Deprecated) Set True to include in the analysis result the formatted data points given to the fitter. Default to False.
    • data_processor (Callable)

      Default value: None
      A callback function to format experiment data. This can be a DataProcessor instance that defines the self.__call__ method.
    • normalization (bool)

      Default value: False
      Set True to normalize y values within range [-1, 1]. Default to False.
    • average_method (Literal[“sample”, “iwv”, “shots_weighted”])

      Default value: "shots_weighted"
      Method to average the y values when the same x values appear multiple times. One of “sample”, “iwv” (i.e. inverse weighted variance), “shots_weighted”. See mean_xy_data() for details. Default to “shots_weighted”.
    • p0 (Dict[str, float])

      Default value: {}
      Initial guesses for the fit parameters. The dictionary is keyed on the fit parameter names.
    • bounds (Dict[str, Tuple[float, float]])

      Default value: {}
      Boundary of fit parameters. The dictionary is keyed on the fit parameter names and values are the tuples of (min, max) of each parameter.
    • fit_method (str)

      Default value: "least_squares"
      Fit method that LMFIT minimizer uses. Default to least_squares method which implements the Trust Region Reflective algorithm to solve the minimization problem. See LMFIT documentation for available options.
    • lmfit_options (Dict[str, Any])

      Default value: {}
      Options that are passed to the LMFIT minimizer. Acceptable options depend on fit_method.
    • x_key (str)

      Default value: "xval"
      Circuit metadata key representing a scanned value.
    • fit_category (str)

      Default value: "formatted"
      Name of dataset in the scatter table to fit.
    • result_parameters (List[Union[str, ParameterRepr])

      Default value: ["d_theta"]
      Parameters reported in the database as a dedicated entry. This is a list of parameter representation which is either string or ParameterRepr object. If you provide more information other than name, you can specify [ParameterRepr("alpha", "α", "a.u.")] for example. The parameter name should be defined in the series definition. Representation should be printable in standard output, i.e. no latex syntax.
    • extra (Dict[str, Any])

      Default value: {}
      A dictionary that is appended to all database entries as extra information.
    • fixed_parameters (Dict[str, Any])

      Default value: {}
      Fitting model parameters that are fixed during the curve fitting. This should be provided with default value keyed on one of the parameter names in the series definition.
    • filter_data (Dict[str, Any])

      Default value: {}
      Dictionary of experiment data metadata to filter. Experiment outcomes with metadata that matches with this dictionary are used in the analysis. If not specified, all experiment data are input to the curve fitter. By default, no filtering condition is set.
    • data_subfit_map (Dict[str, Dict[str, Any]])

      Default value: {}
      The mapping of experiment result data to sub-fit models. This dictionary is keyed on the LMFIT model name, and the value is a sorting key-value pair that filters the experiment results, and the filtering is done based on the circuit metadata.
  • Defined in the class BaseAnalysis:

    • figure_names (str or List[str])

      Default value: None
      Identifier of figures that appear in the experiment data to sort figures by name.

See also

Initialization

Initialize data fields that are privately accessed by methods.

Parameters:
  • models – List of LMFIT Model class to define fitting functions and parameters. If multiple models are provided, the analysis performs multi-objective optimization where the parameters with the same name are shared among provided models. When multiple models are provided, user must specify the data_subfit_map value in the analysis options to allocate experimental results to a particular fit model.

  • name (str | None) – Optional. Name of this analysis.

Attributes

drawer#

A short-cut for curve drawer instance, if set. None otherwise.

Deprecated since version 0.5: The method qiskit_experiments.curve_analysis.base_curve_analysis.BaseCurveAnalysis.drawer() is deprecated as of qiskit-experiments 0.5. It will be removed after 0.6. Use plotter from the new visualization module.

models#

Return fit models.

name#

Return name of this analysis.

options#

Return the analysis options for run() method.

parameters#

Return parameters of this curve analysis.

plotter#

A short-cut to the curve plotter instance.

Methods

config()#

Return the config dataclass for this analysis

Return type:

AnalysisConfig

copy()#

Return a copy of the analysis

Return type:

BaseAnalysis

classmethod from_config(config)#

Initialize an analysis class from analysis config

Return type:

BaseAnalysis

model_names()#

Return model names.

Return type:

List[str]

run(experiment_data, replace_results=False, **options)#

Run analysis and update ExperimentData with analysis result.

Parameters:
  • experiment_data (ExperimentData) – the experiment data to analyze.

  • replace_results (bool) – If True clear any existing analysis results, figures, and artifacts in the experiment data and replace with new results. See note for additional information.

  • options – additional analysis options. See class documentation for supported options.

Returns:

An experiment data object containing analysis results, figures, and artifacts.

Raises:

QiskitError – If experiment_data container is not valid for analysis.

Return type:

ExperimentData

Note

Updating Results

If analysis is run with replace_results=True then any analysis results, figures, and artifacts in the experiment data will be cleared and replaced with the new analysis results. Saving this experiment data will replace any previously saved data in a database service using the same experiment ID.

If analysis is run with replace_results=False and the experiment data being analyzed has already been saved to a database service, or already contains analysis results or figures, a copy with a unique experiment ID will be returned containing only the new analysis results and figures. This data can then be saved as its own experiment to a database service.

set_options(**fields)#

Set the analysis options for run() method.

Parameters:

fields – The fields to update the options