--- language: - en license: apache-2.0 library_name: gliner2 tags: - named-entity-recognition - ner - pii - anonymisation - gliner - gliner2 - token-classification - privacy datasets: - synthetic base_model: fastino/gliner2-large-v1 model-index: - name: NERPA results: - task: type: token-classification name: Named Entity Recognition metrics: - type: precision value: 0.93 name: Micro-Precision - type: recall value: 0.90 name: Micro-Recall pipeline_tag: token-classification --- # NERPA - Fine-Tuned GLiNER2 for PII Anonymisation A fine-tuned [GLiNER2 Large](https://huggingface.co/fastino/gliner2-large-v1) (340M params) model trained to detect Personally Identifiable Information (PII) in text. Built as a flexible, self-hosted replacement for AWS Comprehend at [Overmind](https://overmindlab.ai). ## Fine-Tuning Details - **Base model:** [fastino/gliner2-large-v1](https://huggingface.co/fastino/gliner2-large-v1) (DeBERTa v3 Large backbone, 340M params) - **Training data:** 1,210 synthetic snippets generated with Gemini 3 Pro + Python Faker, each containing 2–4 PII entities - **Eval data:** 300 held-out snippets (no template overlap with training) - **Strategy:** Full weight fine-tuning with differential learning rates: - Encoder (DeBERTa v3): `1e-7` - GLiNER-specific layers: `1e-6` - **Batch size:** 64 - **Convergence:** 175 steps ## Why NERPA? NERPA combines two technical advantages that commercial NER services like AWS Comprehend cannot offer: ### 1. Bi-Encoder Architecture for Zero-Shot Entity Detection GLiNER2 is a bi-encoder that takes both text and entity label descriptions as input, rather than treating entity types as fixed output classes. This architectural difference means you can define arbitrary entity types at inference time without retraining: ```python # Standard PII entities entities = detect_entities(model, text, entities={ "PERSON_NAME": "Person name", "DATE_OF_BIRTH": "Date of birth", "EMAIL": "Email address", }) # Add domain-specific entities on the fly entities = detect_entities(model, text, entities={ "PERSON_NAME": "Person name", "MEDICATION": "Drug or medication name", "DIAGNOSIS": "Medical condition or diagnosis", "LAB_VALUE": "Laboratory test result", }) ``` This isn't prompt engineering or few-shot learning. The model's bi-encoder architecture natively supports arbitrary entity schemas. Fine-tuning on PII improves precision on those specific types without degrading the zero-shot capability. **Example:** Context-dependent entity distinction ```python text = """Last weekend, I visited Riverside Farm & Wildlife Park with my family. The kids were excited to see the tigers first—magnificent creatures pacing behind the reinforced glass. My daughter Sarah kept comparing them to our tabby cat at home, saying how similar their stripes looked, though obviously Mittens is much smaller and sleeps on our couch rather than prowling through artificial jungle habitats.""" entities = detect_entities(model, text, entities={ "ZOO": "Animals in a zoo or wildlife park", "PET": "Pet animals owned by someone", }) ``` Output: ``` Last weekend, I visited Riverside Farm & Wildlife Park with my family. The kids were excited to see the [ZOO] first—magnificent creatures pacing behind the reinforced glass. My daughter Sarah kept comparing them to our [PET] at home, saying how similar their stripes looked, though obviously [PET] is much smaller and sleeps on our couch rather than prowling through artificial jungle habitats. ``` The model correctly distinguishes tigers (zoo animals) from the tabby cat and even the cat's name Mittens (pets) based purely on contextual cues. No retraining required. ### 2. Superior Performance on Standard PII Fine-tuning GLiNER2 Large on 1,210 synthetic PII examples produced a model that outperforms AWS Comprehend on standard entity detection: | Model | Micro-Precision | Micro-Recall | | --- | --- | --- | | AWS Comprehend | 0.90 | 0.94 | | GLiNER2 Large (off-the-shelf) | 0.84 | 0.89 | | **NERPA (this model)** | **0.93** | **0.90** | NERPA achieves **3% higher precision** than AWS Comprehend while maintaining comparable recall. The fine-tuning also enables fine-grained date disambiguation (DATE_OF_BIRTH vs DATE_TIME), which AWS Comprehend cannot do without custom model training. ### The Architecture Advantage AWS Comprehend treats entity types as fixed classification targets. Adding a new entity type requires: 1. Annotating thousands of examples 2. Training a custom model 3. Paying for model hosting 4. Managing model versioning NERPA's bi-encoder architecture makes entity types a runtime parameter. Adding new entities is a single line of code. ## Pre-Optimised PII Entity Types NERPA is fine-tuned on these entity types (but you can add more at inference time): | Entity | Description | | --- | --- | | `PERSON_NAME` | Person name | | `DATE_OF_BIRTH` | Date of birth | | `DATE_TIME` | Generic date and time | | `EMAIL` | Email address | | `PHONE` | Phone numbers | | `LOCATION` | Address, city, country, postcode, street | | `AGE` | Age of a person | | `BUSINESS_NAME` | Business name | | `USERNAME` | Username | | `URL` | Any URL | | `BANK_ACCOUNT_DETAILS` | IBAN, SWIFT, routing numbers, etc. | | `CARD_DETAILS` | Card number, CVV, expiration | | `DIGITAL_KEYS` | Passwords, PINs, API keys | | `PERSONAL_ID_NUMBERS` | Passport, driving licence, tax IDs | | `TECHNICAL_ID_NUMBERS` | IP/MAC addresses, serial numbers | | `VEHICLE_ID_NUMBERS` | License plates, VINs | ## Quick Start ### Install dependencies ```bash pip install gliner2 torch ``` ### Anonymise text (CLI) ```bash # Inline text python anonymise.py "Dear John Smith, born 15/03/1990. Contact: john@acme.com" # From file python anonymise.py --file input.txt --output anonymised.txt # Show detected entities python anonymise.py --show-entities "Call me at 020-7946-0958, my IBAN is GB29NWBK60161331926819." ``` ### Use in Python ```python from anonymise import load_model, detect_entities, anonymise model = load_model(".") # path to this repo text = ( "Dear John Smith, your appointment is on 2025-03-15. " "Your date of birth (15/03/1990) has been verified. " "Please contact support at help@acme.com or call 020-7946-0958. " ) entities = detect_entities(model, text) print(anonymise(text, entities)) ``` Output: ``` Dear [PERSON_NAME], your appointment is on [DATE_TIME]. Your date of birth ([DATE_OF_BIRTH]) has been verified. Please contact support at [EMAIL] or call [PHONE]. ``` ### Entity detection only If you just need the raw entity offsets (e.g. for your own replacement logic): ```python entities = detect_entities(model, text) for e in entities: print(f'{e["type"]:25s} [{e["start"]}:{e["end"]}] score={e["score"]:.2f} "{text[e["start"]:e["end"]]}"') ``` ``` PERSON_NAME [5:15] score=1.00 "John Smith" DATE_TIME [40:50] score=1.00 "2025-03-15" DATE_OF_BIRTH [72:82] score=1.00 "15/03/1990" EMAIL [129:142] score=1.00 "help@acme.com" PHONE [151:164] score=1.00 "020-7946-0958" BANK_ACCOUNT_DETAILS [187:209] score=1.00 "GB29NWBK60161331926819" ``` ### Detect a subset of entities ```python entities = detect_entities(model, text, entities={ "PERSON_NAME": "Person name", "EMAIL": "Email", }) ``` ### Custom entities You can detect additional entity types beyond the built-in PII set. The model's zero-shot capability means any label + description pair will work — your custom entities are detected and anonymised alongside the fine-tuned ones. **CLI** — use `--extra-entities` / `-e`: ```bash python anonymise.py -e PRODUCT="Product name" -e SKILL="Professional skill" \ "John Smith is a senior Python developer who bought a MacBook Pro." ``` Output: ``` [PERSON_NAME] is a senior [SKILL] developer who bought a [PRODUCT]. ``` **Python:** ```python from anonymise import load_model, detect_entities, anonymise, PII_ENTITIES model = load_model(".") custom_entities = { **PII_ENTITIES, "PRODUCT": "Product name", "SKILL": "Professional skill", } text = "John Smith is a senior Python developer who bought a MacBook Pro." entities = detect_entities(model, text, entities=custom_entities) print(anonymise(text, entities)) ``` ## How It Works The inference pipeline in `anonymise.py`: 1. **Chunking** — Long texts are split into 3000-character chunks with 100-char overlap to stay within the model's context window. Specific chunk size can be varied since DeBERTa-v3 (underlying encoder) uses relative position encoding. We found that this size works as well as smaller ones. 2. **Batch prediction** — Chunks are fed through `GLiNER2.batch_extract_entities()` with `include_spans=True` to get character-level offsets. 3. **Date disambiguation** — Both `DATE_TIME` and `DATE_OF_BIRTH` are always detected together so the model can choose the best label per span. 4. **De-duplication** — Overlapping detections from chunk boundaries are merged, keeping the highest-confidence label for each position. 5. **Replacement** — Detected spans are replaced right-to-left with `[ENTITY_TYPE]` placeholders. ## Notes - **Confidence threshold:** Default is `0.25`. The model sometimes tends to be conservative, so a lower threshold works well for high recall. - **GLiNER2 version:** Requires `gliner2>=1.2.4`. Earlier versions had a bug where entity character offsets mapped to token positions instead of character positions; this is fixed in 1.2.4+. - **Device:** Automatically uses CUDA > MPS > CPU. ## Acknowledgements This model is a fine-tuned version of [GLiNER2 Large](https://huggingface.co/fastino/gliner2-large-v1) by [Fastino AI](https://fastino.ai). We thank the GLiNER2 authors for making their model and library openly available. ## Citation If you use NERPA, please cite both this model and the original GLiNER2 paper: ```bibtex @misc{nerpa2025, title={NERPA: Fine-Tuned GLiNER2 for PII Anonymisation}, author={Akhat Rakishev}, year={2025}, url={https://huggingface.co/OvermindLab/nerpa}, } @misc{zaratiana2025gliner2efficientmultitaskinformation, title={GLiNER2: An Efficient Multi-Task Information Extraction System with Schema-Driven Interface}, author={Urchade Zaratiana and Gil Pasternak and Oliver Boyd and George Hurn-Maloney and Ash Lewis}, year={2025}, eprint={2507.18546}, archivePrefix={arXiv}, primaryClass={cs.CL}, url={https://arxiv.org/abs/2507.18546}, } ``` Built by [Akhat Rakishev](https://github.com/akhatre) at [Overmind](https://overmindlab.ai). Overmind is infrastructure for end-to-end agent optimisation. Learn more at [overmindlab.ai](https://overmindlab.ai).