Datasets:

Emreargin
/

BioDCASE2026_Bird_Counting

	---
	license: cc-by-4.0
	task_categories:
	- audio-classification
	language:
	- en
	tags:
	- audio
	- birds
	- bioacoustics
	- biodiversity
	- ecology
	- population-estimation
	- bird-counting
	- zoo
	- aviary
	- passive-acoustic-monitoring
	- biodcase
	- biodcase2026
	pretty_name: "BioDCASE 2026 - Bird Counting (Task 6)"
	size_categories:
	- 100K<n<1M
	---

	# BioDCASE 2026 — Bird Counting (Task 6)

	Development dataset for the Bird Counting task of the [BioDCASE 2026 Challenge](https://biodcase.github.io/challenge2026/).

	## Task overview

	Estimating the number of individual birds from acoustic recordings is a fundamental challenge in biodiversity monitoring. This task addresses bird abundance estimation in zoo aviaries with known ground-truth population counts.

	Participants receive collections of short audio fragments (~3 seconds each) extracted from continuous passive acoustic recordings in multi-species aviaries. Each aviary contains a known number of a target bird species alongside other co-occurring species. The recordings capture birds vocalizing naturally in groups over extended periods, creating realistic acoustic complexity including overlapping vocalizations, environmental noise, and natural behavioral variation.

	The task is to estimate the number of individuals of the target species in each aviary.

	For full task details, timeline, evaluation criteria, and submission instructions, see:
	- Task page: [https://www.ml4biodiversity.org/biodcase26_birdcounts/](https://www.ml4biodiversity.org/biodcase26_birdcounts/)
	- Challenge page: [https://biodcase.github.io/challenge2026/](https://biodcase.github.io/challenge2026/)
	- Baseline code: [https://github.com/ml4biodiversity/biodcase-population-estimation](https://github.com/ml4biodiversity/biodcase-population-estimation)

	## Dataset description

	The development dataset contains 140,899 audio files across 6 aviaries recorded at European zoos using passive acoustic monitoring equipment. Recordings were made during spring and summer 2025. Each aviary was recorded continuously for 7–11 days; this dataset includes a curated subset of 2–3 representative days per aviary selected to minimize distributional distortion of key acoustic features while keeping the dataset manageable.

	### Target species

	Three bird species are designated as estimation targets. Population estimation is evaluated only for these species:

	\| Species \| Scientific name \| Aviaries \| Population range \|
	\|---\|---\|---\|---\|
	\| Greater flamingo \| Phoenicopterus roseus \| dev_aviary_2, dev_aviary_4, dev_aviary_5, dev_aviary_6 \| 52–161 \|
	\| Red-billed quelea \| Quelea quelea \| dev_aviary_1, dev_aviary_3 \| 61–153 \|
	\| Hadada ibis \| Bostrychia hagedash \| dev_aviary_2, dev_aviary_4 \| 4–6 \|

	Each aviary also contains additional non-target bird species (2–12 species per aviary, 28 species in total across all aviaries). The complete species inventory with population counts is provided in `metadata/ground_truth.csv`.

	### Aviary summary

	\| Aviary \| Days \| Audio files \| Target species \| Target population \|
	\|---\|---\|---\|---\|---\|
	\| dev_aviary_1 \| 3 \| 12,627 \| Red-billed quelea \| 153 \|
	\| dev_aviary_2 \| 3 \| 25,569 \| Greater flamingo (107), Hadada ibis (6) \| 113 \|
	\| dev_aviary_3 \| 3 \| 11,879 \| Red-billed quelea \| 61 \|
	\| dev_aviary_4 \| 3 \| 36,340 \| Greater flamingo (161), Hadada ibis (4) \| 165 \|
	\| dev_aviary_5 \| 2 \| 19,363 \| Greater flamingo \| 52 \|
	\| dev_aviary_6 \| 3 \| 35,121 \| Greater flamingo \| 52 \|
	\| Total \| 17 \| 140,899 \| \| \|

	Note: Aviary 5 and aviary 6 are two separate recording sessions from the same physical location with the same bird population, captured on different dates. They are treated as independent data points with different acoustic conditions.

	### Audio format

	All audio files are single-channel (mono) WAV files, 16-bit PCM, sampled at 48 kHz, with a duration of approximately 3 seconds each. The files represent consecutive, non-overlapping segments extracted from continuous recordings.

	## Dataset structure

	```
	BioDCASE2026_Bird_Counting/
	├── dev_aviary_1/
	│ ├── chunk_000/
	│ │ ├── rec_d1_00_00_45.750000.wav
	│ │ ├── rec_d1_00_01_49.wav
	│ │ └── ...
	│ ├── chunk_001/
	│ │ └── ...
	│ └── ...
	├── dev_aviary_2/
	│ └── ...
	├── dev_aviary_3/
	│ └── ...
	├── dev_aviary_4/
	│ └── ...
	├── dev_aviary_5/
	│ └── ...
	├── dev_aviary_6/
	│ └── ...
	└── metadata/
	├── ground_truth.csv
	└── recording_info.csv
	```

	### Filename convention

	Audio filenames follow the pattern:

	```
	rec_{day}_{HH}_{MM}_{SS}[.ffffff].wav
	```

	where `{day}` is a day identifier (`d1`, `d2`, or `d3`) and `{HH}_{MM}_{SS}[.ffffff]` encodes the time of day (hours, minutes, seconds, optional fractional seconds). For example, `rec_d1_19_05_02.500000.wav` is a recording from day 1 at 19:05:02.5.

	Day identifiers are anonymized — the mapping from day identifiers to calendar dates is not provided to participants.

	### Chunk subdirectories

	Within each aviary, audio files are organized into `chunk_NNN/` subdirectories for practical file management. The chunk boundaries have no acoustic significance — they are simply a way to keep directory sizes manageable. All chunks within an aviary should be treated as a single continuous collection.

	## Metadata

	### `metadata/ground_truth.csv`

	Complete species inventory for all 6 aviaries, including both target and non-target species:

	\| Column \| Description \|
	\|---\|---\|
	\| `aviary_id` \| Aviary identifier (`dev_aviary_1` through `dev_aviary_6`) \|
	\| `common_name` \| English common name of the species \|
	\| `scientific_name` \| Binomial scientific name \|
	\| `count` \| Number of individuals present in the aviary \|
	\| `is_target` \| `1` if the species is evaluated for population estimation, `0` otherwise \|

	### `metadata/recording_info.csv`

	Summary statistics per aviary:

	\| Column \| Description \|
	\|---\|---\|
	\| `aviary_id` \| Aviary identifier \|
	\| `n_days` \| Number of recording days included \|
	\| `n_files` \| Total number of audio files \|

	## Baseline system

	A complete baseline system is available at [https://github.com/ml4biodiversity/biodcase-population-estimation](https://github.com/ml4biodiversity/biodcase-population-estimation). It implements a two-stage pipeline:

	1. Species detection — Run a bird species detector on each aviary's audio files. Two detection packages are provided:
	- `pip install aria-inference` (ARIA ensemble detector, recommended)
	- `pip install aria-inference-birdnet` (BirdNET-based detector)

	2. Feature extraction — Extract detection-count statistics, temporal bout structure, and optionally scikit-maad acoustic indices from the detection output.

	3. Population estimation — Fit species-specific regression models using leave-one-out cross-validation.

	The baseline achieves a combined MAE of 11.50 (MAPE 10.6%) across all target species using ARIA detections.

	## Evaluation

	The main leaderboard ranks systems based on population estimation accuracy for the three target species. The primary metric is Mean Absolute Error (MAE) computed across all (aviary, target species) data points. Secondary metrics include RMSE, R², and MAPE.

	Participants may optionally extend their methods to non-target species for a secondary leaderboard, but this does not affect final rankings.

	The evaluation set will be released according to the [challenge timeline](https://biodcase.github.io/challenge2026/).

	## Key challenges

	- Flock-calling species: Greater flamingos vocalize synchronously in large groups, making it difficult to distinguish individual contributions from detection counts alone. Raw detection rates saturate as flock size grows.
	- Sparse calibration data: With only 6 aviaries (and 2–4 data points per target species), models must generalize from very few examples.
	- Multi-species environments: Each aviary contains 2–12 co-occurring species with overlapping frequency ranges and calling times.
	- Population range: Target populations span two orders of magnitude (4 to 161 individuals), requiring methods that work across scales.

	## Usage with 🤗 Datasets

	```python
	from datasets import load_dataset

	# Load the dataset (streams audio on demand)
	ds = load_dataset("Emreargin/BioDCASE2026_Bird_Counting")
	```

	Or download directly and process locally:

	```bash
	# Clone with git-lfs
	git lfs install
	git clone https://huggingface.co/datasets/Emreargin/BioDCASE2026_Bird_Counting

	# Run the baseline
	cd biodcase-population-estimation
	pip install aria-inference
	aria-inference --input ../BioDCASE2026_Bird_Counting/dev_aviary_1/ --output detections/dev_aviary_1_detections.csv
	# ... repeat for dev_aviary_2 through dev_aviary_6
	python feature_builder.py --detections-dir detections/ --audio-root ../BioDCASE2026_Bird_Counting/ --output results/stage2_features.csv
	python estimator.py --features results/stage2_features.csv
	```

	## License

	This dataset is released under the [Creative Commons Attribution 4.0 International (CC BY 4.0)](https://creativecommons.org/licenses/by/4.0/) license.

	## Citation

	If you use this dataset, please cite:

	```bibtex
	@dataset{ml4biodiversity2026dataset,
	author = {Arg{\i}n, Emre and H{\"a}rm{\"a}, Aki and Arslan-Dogan, Aysenur},
	title = {{BioDCASE 2026 Bird Counting: Avian Population Estimation
	from Passive Acoustic Recordings}},
	year = {2026},
	publisher = {Hugging Face},
	url = {https://huggingface.co/datasets/Emreargin/BioDCASE2026_Bird_Counting},
	}
	```

	Please cite this repository if you use the official baseline implementation:

	```bibtex
	@software{ml4biodiversity2026baseline,
	author = {Arg{\i}n, Emre and H{\"a}rm{\"a}, Aki and Arslan-Dogan, Aysenur},
	title = {{BioDCASE 2026 Bird Counting Baseline: Avian Population Estimation
	from Passive Acoustic Recordings}},
	year = {2026},
	publisher = {GitHub},
	url = {https://github.com/ml4biodiversity/biodcase-population-estimation},
	version = {1.0.0},
	}
	```

	## Contact

	For questions about the dataset or the challenge task, please contact:
	- Emre Argın — Maastricht University ([challenge task lead](https://biodcase.github.io/challenge2026/))
	- Aki Härmä — Maastricht University
	- Aysenur Arslan-Dogan — Maastricht University (main contact person)

	Or open a discussion on the [dataset page](https://huggingface.co/datasets/Emreargin/BioDCASE2026_Bird_Counting/discussions).