Provides metrics on the accuracy of the models that were trained by the CreatePredictor operation. Use metrics to see how well the model performed and to decide whether to use the predictor to generate a forecast. For more information, see metrics .
This operation generates metrics for each backtest window that was evaluated. The number of backtest windows (NumberOfBacktestWindows
) is specified using the EvaluationParameters object, which is optionally included in the CreatePredictor
request. If NumberOfBacktestWindows
isn’t specified, the number defaults to one.
The parameters of the filling
method determine which items contribute to the metrics. If you want all items to contribute, specify zero
. If you want only those items that have complete data in the range being evaluated to contribute, specify nan
. For more information, see FeaturizationMethod .
Note
Before you can get accuracy metrics, the Status
of the predictor must be ACTIVE
, signifying that training has completed. To get the status, use the DescribePredictor operation.
See also: AWS API Documentation
See ‘aws help’ for descriptions of global parameters.
get-accuracy-metrics
--predictor-arn <value>
[--cli-input-json | --cli-input-yaml]
[--generate-cli-skeleton <value>]
[--cli-auto-prompt <value>]
--predictor-arn
(string)
The Amazon Resource Name (ARN) of the predictor to get metrics for.
--cli-input-json
| --cli-input-yaml
(string)
Reads arguments from the JSON string provided. The JSON string follows the format provided by --generate-cli-skeleton
. If other arguments are provided on the command line, those values will override the JSON-provided values. It is not possible to pass arbitrary binary values using a JSON-provided value as the string will be taken literally. This may not be specified along with --cli-input-yaml
.
--generate-cli-skeleton
(string)
Prints a JSON skeleton to standard output without sending an API request. If provided with no value or the value input
, prints a sample input JSON that can be used as an argument for --cli-input-json
. Similarly, if provided yaml-input
it will print a sample input YAML that can be used with --cli-input-yaml
. If provided with the value output
, it validates the command inputs and returns a sample output JSON for that command.
--cli-auto-prompt
(boolean)
Automatically prompt for CLI input parameters.
See ‘aws help’ for descriptions of global parameters.
PredictorEvaluationResults -> (list)
An array of results from evaluating the predictor.
(structure)
The results of evaluating an algorithm. Returned as part of the GetAccuracyMetrics response.
AlgorithmArn -> (string)
The Amazon Resource Name (ARN) of the algorithm that was evaluated.
TestWindows -> (list)
The array of test windows used for evaluating the algorithm. The
NumberOfBacktestWindows
from the EvaluationParameters object determines the number of windows in the array.(structure)
The metrics for a time range within the evaluation portion of a dataset. This object is part of the EvaluationResult object.
The
TestWindowStart
andTestWindowEnd
parameters are determined by theBackTestWindowOffset
parameter of the EvaluationParameters object.TestWindowStart -> (timestamp)
The timestamp that defines the start of the window.
TestWindowEnd -> (timestamp)
The timestamp that defines the end of the window.
ItemCount -> (integer)
The number of data points within the window.
EvaluationType -> (string)
The type of evaluation.
SUMMARY
- The average metrics across all windows.
COMPUTED
- The metrics for the specified window.Metrics -> (structure)
Provides metrics used to evaluate the performance of a predictor.
RMSE -> (double)
The root mean square error (RMSE).
WeightedQuantileLosses -> (list)
An array of weighted quantile losses. Quantiles divide a probability distribution into regions of equal probability. The distribution in this case is the loss function.
(structure)
The weighted loss value for a quantile. This object is part of the Metrics object.
Quantile -> (double)
The quantile. Quantiles divide a probability distribution into regions of equal probability. For example, if the distribution was divided into 5 regions of equal probability, the quantiles would be 0.2, 0.4, 0.6, and 0.8.
LossValue -> (double)
The difference between the predicted value and the actual value over the quantile, weighted (normalized) by dividing by the sum over all quantiles.