INQMAD
We present a new incremental anomaly detection method that performs continuous density estimation based on random Fourier features and the mechanism of quantum measurements and density matrices. The method continuously updates the estimation of the density of normal samples, giving more importance to new samples.
Install / Use
/learn @Joaggi/INQMADREADME
InQMAD: Incremental Quantum Measurement Anomaly Detection
This is the official repository for INQMAD. It has been created using Tensorflow and Jax.
InQMAD is now part of PySAD. Check it out!
Abstract:
Streaming anomaly detection refers to the problem of detecting anomalous data samples in streams of data. This problem poses challenges that classical and deep anomaly detection methods are not designed to cope with, such as conceptual drift and continuous learning. State-of-the-art flow anomaly detection methods rely on fixed memory using hash functions or nearest neighbors that may not be able to constrain high frequency values or remove seamless outliers and cannot be trained in an end-to-end deep learning architecture. We present a new incremental anomaly detection method that performs continuous density estimation based on random Fourier features and the mechanism of quantum measurements and density matrices. The method continuously updates the estimation of the density of normal samples, giving more importance to new samples and decreasing the importance of older samples. It can process potentially endless data and its update complexity is constant O(1). A systematic evaluation against 12 state-of-the-art streaming anomaly detection algorithms and using 12 streaming datasets is presented.
Published in:
- 2022 IEEE International Conference on Data Mining Workshops (ICDMW)
Date of Conference:
- 28 November 2022 - 01 December 2022
Date Added to IEEE Xplore:
- 08 February 2023
DOI:
- 10.1109/ICDMW58026.2022.00107
Conference Location:
- Orlando, FL, USA
Dataset
All datasets used in the experiments are publicly available on Zenodo:
🔗 https://zenodo.org/records/18613986
The Zenodo repository contains:
- Raw datasets used in the paper
- Preprocessed versions (when applicable)
- Metadata and experiment-related files
Please download the datasets and place them in the appropriate directory as expected by the experiment configuration files.
Setup
Environment Installation
We recommend using Miniconda to ensure reproducibility.
1️⃣ Install Miniconda
Download and install Miniconda from: https://docs.conda.io/en/latest/miniconda.html
2️⃣ Create the Conda Environment
From the root of the repository, run:
conda env create -f environment.yml
conda activate learning-with-density-matrices
This will create an isolated environment with all required dependencies.
3️⃣ Install the Package
Install the project in editable mode:
pip install -e .
If you plan to contribute or run tests, install development dependencies as well:
pip install -e .[dev]
Editable mode (-e) ensures that changes to the source code are immediately reflected without reinstalling the package.
Git Submodules
This repository depends on external components managed as Git submodules.
After cloning the repository, initialize and update all submodules:
git submodule update --init --recursive
If you already cloned the repository without submodules, you can run the same command to properly fetch them.
Experiment Tracking with MLflow
All experiments are logged using MLflow with a local SQLite backend.
1️⃣ Create the Tracking Directory
mkdir -p mlflow
Experiments will be stored under:
mlflow/tracking.db
2️⃣ Launch the MLflow UI
After running experiments, start the MLflow dashboard with:
mlflow ui --port 8080 --backend-store-uri sqlite:///mlflow/tracking.db
Then open your browser at:
http://localhost:8080
The dashboard allows you to:
- Compare experiment runs
- Track metrics and parameters
- Visualize artifacts
- Reproduce results
Citation
If you use this repository in your research, please cite:
@article{gallego2025inqmad,
title={INQMAD: incremental streaming anomaly detection with density matrices, quantum measurement, and density estimation},
author={Gallego, Joseph and Bustos-Brinez, Oscar A and Gonz{\'a}lez, Fabio A},
journal={Neural Computing and Applications},
volume={37},
number={32},
pages={27475--27503},
year={2025},
publisher={Springer}
}
@dataset{gallego_2026_18613986,
author = {Gallego, Joseph and
Bustos-Briñez, Oscar Alberto and
Gonzalez, Fabio},
title = {InQMAD: Incremental Quantum Measurement Anomaly
Detection Dataset
},
month = feb,
year = 2026,
publisher = {Zenodo},
version = {1.0.0},
doi = {10.5281/zenodo.18613986},
url = {https://doi.org/10.5281/zenodo.18613986},
}
@software{joagg_2022_7183564,
author = {Joagg},
title = {Joaggi/Incremental-Anomaly-Detection-using-
Quantum-Measurements: v1.0.0
},
month = oct,
year = 2022,
publisher = {Zenodo},
version = {v1.0.0},
doi = {10.5281/zenodo.7183564},
url = {https://doi.org/10.5281/zenodo.7183564},
}
We appreciate citations as they help support continued research in density matrix–based machine learning methods.
