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258 lines
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Markdown
258 lines
17 KiB
Markdown
---
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weight: 4
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title: FAQ
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menu:
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docs:
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identifier: "vmanomaly-faq"
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parent: "anomaly-detection"
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weight: 4
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aliases:
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- /anomaly-detection/FAQ.html
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---
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## What is VictoriaMetrics Anomaly Detection (vmanomaly)?
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VictoriaMetrics Anomaly Detection, also known as `vmanomaly`, is a service for detecting unexpected changes in time series data. Utilizing machine learning models, it computes and pushes back an ["anomaly score"](/anomaly-detection/components/models#vmanomaly-output) for user-specified metrics. This hands-off approach to anomaly detection reduces the need for manual alert setup and can adapt to various metrics, improving your observability experience.
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Please refer to [our QuickStart section](/anomaly-detection/#practical-guides-and-installation) to find out more.
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> **Note: `vmanomaly` is a part of [enterprise package](../enterprise.md). You need to get a [free trial license](https://victoriametrics.com/products/enterprise/trial/) for evaluation.**
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## What is anomaly score?
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Among the metrics produced by `vmanomaly` (as detailed in [vmanomaly output metrics](/anomaly-detection/components/models#vmanomaly-output)), `anomaly_score` is a pivotal one. It is **a continuous score > 0**, calculated in such a way that **scores ranging from 0.0 to 1.0 usually represent normal data**, while **scores exceeding 1.0 are typically classified as anomalous**. However, it's important to note that the threshold for anomaly detection can be customized in the alert configuration settings.
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The decision to set the changepoint at `1.0` is made to ensure consistency across various models and alerting configurations, such that a score above `1.0` consistently signifies an anomaly, thus, alerting rules are maintained more easily.
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> Note: `anomaly_score` is a metric itself, which preserves all labels found in input data and (optionally) appends [custom labels, specified in writer](/anomaly-detection/components/writer#metrics-formatting) - follow the link for detailed output example.
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## How is anomaly score calculated?
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For most of the [univariate models](/anomaly-detection/components/models#univariate-models) that can generate `yhat`, `yhat_lower`, and `yhat_upper` time series in [their output](/anomaly-detection/components/models#vmanomaly-output) (such as [Prophet](/anomaly-detection/components/models#prophet) or [Z-score](/anomaly-detection/components/models#z-score)), the anomaly score is calculated as follows:
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- If `yhat` (expected series behavior) equals `y` (actual value observed), then the anomaly score is 0.
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- If `y` (actual value observed) falls within the `[yhat_lower, yhat_upper]` confidence interval, the anomaly score will gradually approach 1, the closer `y` is to the boundary.
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- If `y` (actual value observed) strictly exceeds the `[yhat_lower, yhat_upper]` interval, the anomaly score will be greater than 1, increasing as the margin between the actual value and the expected range grows.
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Please see example graph illustrating this logic below:
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![anomaly-score-calculation-example](vmanomaly-prophet-example.webp)
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> p.s. please note that additional post-processing logic might be applied to produced anomaly scores, if common arguments like [`min_dev_from_expected`](https://docs.victoriametrics.com/anomaly-detection/components/models/#minimal-deviation-from-expected) or [`detection_direction`](https://docs.victoriametrics.com/anomaly-detection/components/models/#detection-direction) are enabled for a particular model. Follow the links above for the explanations.
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## How does vmanomaly work?
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`vmanomaly` applies built-in (or custom) [anomaly detection algorithms](/anomaly-detection/components/models), specified in a config file.
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- All the models generate a metric called [anomaly_score](#what-is-anomaly-score)
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- All produced anomaly scores are unified in a way that values lower than 1.0 mean “likely normal”, while values over 1.0 mean “likely anomalous”
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- Simple rules for alerting: start with `anomaly_score{“key”=”value”} > 1`
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- Models are retrained continuously, based on `schedulers` section in a config, so that threshold=1.0 remains actual
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- Produced scores are stored back to VictoriaMetrics TSDB and can be used for various observability tasks (alerting, visualization, debugging).
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## What data does vmanomaly operate on?
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`vmanomaly` operates on data fetched from VictoriaMetrics, where you can leverage full power of [MetricsQL](/metricsql) for data selection, sampling, and processing. Users can also [apply global filters](/#prometheus-querying-api-enhancements) for more targeted data analysis, enhancing scope limitation and tenant visibility.
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Respective config is defined in a [`reader`](/anomaly-detection/components/reader#vm-reader) section.
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## Handling noisy input data
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`vmanomaly` operates on data fetched from VictoriaMetrics using [MetricsQL](/metricsql) queries, so the initial data quality can be fine-tuned with aggregation, grouping, and filtering to reduce noise and improve anomaly detection accuracy.
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## Output produced by vmanomaly
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`vmanomaly` models generate [metrics](/anomaly-detection/components/models#vmanomaly-output) like `anomaly_score`, `yhat`, `yhat_lower`, `yhat_upper`, and `y`. These metrics provide a comprehensive view of the detected anomalies. The service also produces [health check metrics](/anomaly-detection/components/monitoring#metrics-generated-by-vmanomaly) for monitoring its performance.
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## Choosing the right model for vmanomaly
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Selecting the best model for `vmanomaly` depends on the data's nature and the [types of anomalies](https://victoriametrics.com/blog/victoriametrics-anomaly-detection-handbook-chapter-2/#categories-of-anomalies) to detect. For instance, [Z-score](/anomaly-detection/components/models#z-score) is suitable for data without trends or seasonality, while more complex patterns might require models like [Prophet](/anomaly-detection/components/models#prophet).
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Also, starting from [v1.12.0](/anomaly-detection/changelog/#v1120) it's possible to auto-tune the most important params of selected model class, find [the details here](/anomaly-detection/components/models#autotuned).
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Please refer to [respective blogpost on anomaly types and alerting heuristics](https://victoriametrics.com/blog/victoriametrics-anomaly-detection-handbook-chapter-2/) for more details.
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Still not 100% sure what to use? We are [here to help](/anomaly-detection/#get-in-touch).
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## Alert generation in vmanomaly
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While `vmanomaly` detects anomalies and produces scores, it *does not directly generate alerts*. The anomaly scores are written back to VictoriaMetrics, where an external alerting tool, like [`vmalert`](/vmalert), can be used to create alerts based on these scores for integrating it with your alerting management system.
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## Preventing alert fatigue
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Produced anomaly scores are designed in such a way that values from 0.0 to 1.0 indicate non-anomalous data, while a value greater than 1.0 is generally classified as an anomaly. However, there are no perfect models for anomaly detection, that's why reasonable defaults expressions like `anomaly_score > 1` may not work 100% of the time. However, anomaly scores, produced by `vmanomaly` are written back as metrics to VictoriaMetrics, where tools like [`vmalert`](/vmalert) can use [MetricsQL](/MetricsQL) expressions to fine-tune alerting thresholds and conditions, balancing between avoiding [false negatives](https://victoriametrics.com/blog/victoriametrics-anomaly-detection-handbook-chapter-1/#false-negative) and reducing [false positives](https://victoriametrics.com/blog/victoriametrics-anomaly-detection-handbook-chapter-1/#false-positive).
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## How to backtest particular configuration on historical data?
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Starting from [v1.7.2](/anomaly-detection/changelog#v172) you can produce (and write back to VictoriaMetrics TSDB) anomaly scores for historical (backtesting) period, using `BacktestingScheduler` [component](/anomaly-detection/components/scheduler#backtesting-scheduler) to imitate consecutive "production runs" of `PeriodicScheduler` [component](/anomaly-detection/components/scheduler#periodic-scheduler). Please find an example config below:
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```yaml
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schedulers:
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scheduler_alias:
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class: 'backtesting' # or "scheduler.backtesting.BacktestingScheduler" until v1.13.0
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# define historical period to backtest on
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# should be bigger than at least (fit_window + fit_every) time range
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from_iso: '2024-01-01T00:00:00Z'
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to_iso: '2024-01-15T00:00:00Z'
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# copy these from your PeriodicScheduler args
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fit_window: 'P14D'
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fit_every: 'PT1H'
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# number of parallel jobs to run. Default is 1, each job is a separate OneOffScheduler fit/inference run.
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n_jobs: 1
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models:
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model_alias1:
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# ...
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schedulers: ['scheduler_alias'] # if omitted, all the defined schedulers will be attached
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queries: ['query_alias1'] # if omitted, all the defined queries will be attached
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# https://docs.victoriametrics.com/anomaly-detection/components/models/#provide-series
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provide_series: ['anomaly_score']
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# ... other models
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reader:
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datasource_url: 'some_url_to_read_data_from'
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queries:
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query_alias1: 'some_metricsql_query'
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sampling_frequency: '1m' # change to whatever you need in data granularity
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# other params if needed
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# https://docs.victoriametrics.com/anomaly-detection/components/reader/#vm-reader
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writer:
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datasource_url: 'some_url_to_write_produced_data_to'
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# other params if needed
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# https://docs.victoriametrics.com/anomaly-detection/components/writer/#vm-writer
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# optional monitoring section if needed
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# https://docs.victoriametrics.com/anomaly-detection/components/monitoring/
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```
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Configuration above will produce N intervals of full length (`fit_window`=14d + `fit_every`=1h) until `to_iso` timestamp is reached to run N consecutive `fit` calls to train models; Then these models will be used to produce `M = [fit_every / sampling_frequency]` infer datapoints for `fit_every` range at the end of each such interval, imitating M consecutive calls of `infer_every` in `PeriodicScheduler` [config](/anomaly-detection/components/scheduler#periodic-scheduler). These datapoints then will be written back to VictoriaMetrics TSDB, defined in `writer` [section](/anomaly-detection/components/writer#vm-writer) for further visualization (i.e. in VMUI or Grafana)
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## Resource consumption of vmanomaly
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`vmanomaly` itself is a lightweight service, resource usage is primarily dependent on [scheduling](/anomaly-detection/components/scheduler) (how often and on what data to fit/infer your models), [# and size of timeseries returned by your queries](./components/reader.md#vm-reader), and the complexity of the employed [models](/anomaly-detection/components/models). Its resource usage is directly related to these factors, making it adaptable to various operational scales.
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> **Note**: Starting from [v1.13.0](/anomaly-detection/changelog#v1130), there is a mode to save anomaly detection models on host filesystem after `fit` stage (instead of keeping them in-memory by default). **Resource-intensive setups** (many models, many metrics, bigger [`fit_window` arg](/anomaly-detection/components/scheduler#periodic-scheduler-config-example)) and/or 3rd-party models that store fit data (like [ProphetModel](/anomaly-detection/components/models#prophet) or [HoltWinters](/anomaly-detection/components/models#holt-winters)) will have RAM consumption greatly reduced at a cost of slightly slower `infer` stage. To enable it, you need to set environment variable `VMANOMALY_MODEL_DUMPS_DIR` to desired location. [Helm charts](https://github.com/VictoriaMetrics/helm-charts/blob/master/charts/victoria-metrics-anomaly/README.md) are being updated accordingly ([`StatefulSet`](https://kubernetes.io/docs/concepts/workloads/controllers/statefulset/) for persistent storage starting from chart version `1.3.0`).
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Here's an example of how to set it up in docker-compose using volumes:
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```yaml
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services:
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# ...
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vmanomaly:
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container_name: vmanomaly
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image: victoriametrics/vmanomaly:latest
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# ...
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ports:
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- "8490:8490"
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restart: always
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volumes:
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- ./vmanomaly_config.yml:/config.yaml
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- ./vmanomaly_license:/license
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# map the host directory to the container directory
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- vmanomaly_model_dump_dir:/vmanomaly/tmp/models
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environment:
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# set the environment variable for the model dump directory
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- VMANOMALY_MODEL_DUMPS_DIR=/vmanomaly/tmp/models/
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platform: "linux/amd64"
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command:
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- "/config.yaml"
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- "--license-file=/license"
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volumes:
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# ...
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vmanomaly_model_dump_dir: {}
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```
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> **Note**: Starting from [v1.15.0](https://docs.victoriametrics.com/anomaly-detection/changelog#v1150) with the introduction of [online models](https://docs.victoriametrics.com/anomaly-detection/components/models/#online-models), you can additionally reduce resource consumption (e.g., flatten `fit` stage peaks by querying less data from VictoriaMetrics at once).
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**Additional Benefits of Switching to Online Models**:
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- **Reduced Latency**: Online models update incrementally, which can lead to faster response times for anomaly detection since the model continuously adapts to new data without waiting for a batch `fit`.
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- **Scalability**: Handling smaller data chunks at a time reduces memory and computational overhead, making it easier to scale the anomaly detection system.
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- **Improved Resource Utilization**: By spreading the computational load over time and reducing peak demands, online models make more efficient use of system resources, potentially lowering operational costs.
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Here's an example of how we can switch from (offline) [Z-score model](https://docs.victoriametrics.com/anomaly-detection/components/models/#z-score) to [Online Z-score model](https://docs.victoriametrics.com/anomaly-detection/components/models/#online-z-score):
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```yaml
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schedulers:
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periodic:
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class: 'periodic'
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fit_every: '1h'
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fit_window: '2d'
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infer_every: '1m'
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# other schedulers ...
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models:
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zscore_example:
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class: 'zscore'
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schedulers: ['periodic']
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# other model params ...
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# other config sections ...
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```
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to something like
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```yaml
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schedulers:
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periodic:
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class: 'periodic'
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fit_every: '180d' # we need only initial fit to start
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fit_window: '4h' # reduced window, especially if the data doesn't have strong seasonality
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infer_every: '1m' # the model will be updated during each infer call
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# other schedulers ...
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models:
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zscore_example:
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class: 'zscore_online'
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min_n_samples_seen: 120 # i.e. minimal relevant seasonality or (initial) fit_window / sampling_frequency
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schedulers: ['periodic']
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# other model params ...
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# other config sections ...
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```
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As a result, switching from the offline Z-score model to the Online Z-score model results in significant data volume reduction, i.e. over one week:
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**Old Configuration**:
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- `fit_window`: 2 days
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- `fit_every`: 1 hour
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**New Configuration**:
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- `fit_window`: 4 hours
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- `fit_every`: 180 days ( >1 week)
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The old configuration would perform 168 (hours in a week) `fit` calls, each using 2 days (48 hours) of data, totaling 168 * 48 = 8064 hours of data for each timeseries returned.
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The new configuration performs only 1 `fit` call in 180 days, using 4 hours of data initially, totaling 4 hours of data, which is **magnitutes smaller**.
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P.s. `infer` data volume will remain the same for both models, so it does not affect the overall calculations.
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**Data Volume Reduction**:
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- Old: 8064 hours/week (fit) + 168 hours/week (infer)
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- New: 4 hours/week (fit) + 168 hours/week (infer)
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## Scaling vmanomaly
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> **Note:** As of latest release we do not support cluster or auto-scaled version yet (though, it's in our roadmap for - better backends, more parallelization, etc.), so proposed workarounds should be addressed *manually*.
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`vmanomaly` can be scaled horizontally by launching multiple independent instances, each with its own [MetricsQL](/MetricsQL) queries and [configurations](/anomaly-detection/components/):
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- By splitting **queries**, [defined in reader section](/anomaly-detection/components/reader#vm-reader) and spawn separate service around it. Also in case you have *only 1 query returning huge amount of timeseries*, you can further split it by applying MetricsQL filters, i.e. using "extra_filters" [param in reader](/anomaly-detection/components/reader?highlight=extra_filters#vm-reader). See the example below.
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- or **models** (in case you decide to run several models for each timeseries received i.e. for averaging anomaly scores in your alerting rules of `vmalert` or using a vote approach to reduce false positives) - see `queries` arg in [model config](/anomaly-detection/components/models#queries)
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- or **schedulers** (in case you want the same models to be trained under several schedules) - see `schedulers` arg [model section](/anomaly-detection/components/models#schedulers) and `scheduler` [component itself](/anomaly-detection/components/scheduler)
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Here's an example of how to split on `extra_filters`, based on `extra_filters` reader's arg:
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```yaml
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# config file #1, for 1st vmanomaly instance
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# ...
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reader:
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# ...
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queries:
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extra_big_query: metricsql_expression_returning_too_many_timeseries
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extra_filters:
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# suppose you have a label `region` with values to deterministically define such subsets
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- '{region="region_name_1"}'
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# ...
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```
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```yaml
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# config file #2, for 2nd vmanomaly instance
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# ...
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reader:
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# ...
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queries:
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extra_big_query: metricsql_expression_returning_too_many_timeseries
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extra_filters:
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# suppose you have a label `region` with values to deterministically define such subsets
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- '{region="region_name_2"}'
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# ...
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```
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