--- language: ru license: apache-2.0 library_name: transformers tags: - russian - morpheme-segmentation - token-classification - morphbert - bert - ru - russ pipeline_tag: token-classification new_version: CrabInHoney/morphbert-tiny-v2-morpheme-segmentation-ru --- # MorphBERT-Large: Russian Morpheme Segmentation This repository contains the `CrabInHoney/morphbert-large-morpheme-segmentation-ru` model, a большая transformer-based system fine-tuned for morpheme segmentation of Russian words. The model classifies each character of a given word into one of 25 morpheme categories: ['END', 'END1', 'HYPH', 'HYPH1', 'LINK', 'LINK1', 'LINK2', 'LINK3', 'POSTFIX', 'PREF', 'PREF1', 'PREF2', 'ROOT', 'ROOT1', 'ROOT2', 'ROOT3', 'ROOT4', 'ROOT5', 'SUFF', 'SUFF1', 'SUFF2', 'SUFF3', 'SUFF4', 'SUFF5', 'SUFF6'] ## Model Description `morphbert-large-morpheme-segmentation-ru` uses the powerful transformer architecture, aimed at more accurate prediction of morphological analysis at the character level. Due to its large size, the model demonstrates greater accuracy in determining the constituent morphemes in Russian words compared to the small version (CrabInHoney/morphbert-tiny-morpheme-segmentation-ru). The model was obtained by learning from scratch, the architecture is comparable in complexity to bert-base. **Key Features:** * **Task:** Morpheme Segmentation (Token Classification at Character Level) * **Language:** Russian (ru) * **Architecture:** Transformer (BERT base -like) * **Labels:** ['END', 'END1', 'HYPH', 'HYPH1', 'LINK', 'LINK1', 'LINK2', 'LINK3', 'POSTFIX', 'PREF', 'PREF1', 'PREF2', 'ROOT', 'ROOT1', 'ROOT2', 'ROOT3', 'ROOT4', 'ROOT5', 'SUFF', 'SUFF1', 'SUFF2', 'SUFF3', 'SUFF4', 'SUFF5', 'SUFF6'] **Model Size & Specifications:** * **Parameters:** ~85.5 Million * **Tensor Type:** F32 * **Disk Footprint:** ~342 MB ## Usage The model can be easily used with the Hugging Face `transformers` library. It processes words character by character. ```python from transformers import AutoTokenizer, AutoModelForTokenClassification import torch model_name = "CrabInHoney/morphbert-large-morpheme-segmentation-ru" tokenizer = AutoTokenizer.from_pretrained(model_name) model = AutoModelForTokenClassification.from_pretrained(model_name) model.eval() def analyze(word): tokens = list(word) encoded = tokenizer(tokens, is_split_into_words=True, return_tensors="pt", truncation=True, max_length=34) with torch.no_grad(): logits = model(**encoded).logits predictions = logits.argmax(dim=-1)[0] word_ids = encoded.word_ids() output = [] current_label = None current_chunk = [] for i, word_idx in enumerate(word_ids): if word_idx is not None and word_idx < len(tokens): label_id = predictions[i].item() label = model.config.id2label[label_id] token = tokens[word_idx] if label == current_label: current_chunk.append(token) else: if current_chunk: chunk_str = "".join(current_chunk) output.append(f"{chunk_str}:{current_label}") current_chunk = [token] current_label = label if current_chunk: chunk_str = "".join(current_chunk) output.append(f"{chunk_str}:{current_label}") return " / ".join(output) # Примеры for word in ["масляный", "предчувствий", "тарковский", "кот", "подгон", "сине-белый", "шторы", "абажур", "дедлайн", "веб-сайт", "адаптированная", "формообразующий"]: print(f"{word} → {analyze(word)}") ``` ## Example Predictions ``` масляный → масл:ROOT / ян:SUFF / ый:END предчувствий → пред:PREF / чу:ROOT / в:SUFF / ств:SUFF1 / ий:END тарковский → тарк:ROOT / ов:SUFF / ск:SUFF1 / ий:END кот → кот:ROOT подгон → под:PREF / гон:ROOT сине-белый → син:ROOT / е:LINK / -:HYPH / бел:ROOT1 / ый:END шторы → штор:ROOT / ы:END абажур → абажур:ROOT дедлайн → дедлайн:ROOT веб-сайт → веб:ROOT / -:HYPH / сайт:ROOT1 адаптированная → адапт:ROOT / ир:SUFF / ова:SUFF1 / нн:SUFF2 / ая:END формообразующий → форм:ROOT / о:LINK / образу:ROOT1 / ющ:SUFF / ий:END ``` ## Performance The model achieves an approximate character-level accuracy of **0.99** on its evaluation dataset. ## Limitations * Performance may vary on out-of-vocabulary words, neologisms, or highly complex morphological structures not sufficiently represented in the training data. * The model operates strictly at the character level; it does not incorporate broader lexical or syntactic context. * Ambiguous cases in morpheme boundaries might be resolved based on patterns learned during training, which may not always align with linguistic conventions in edge cases.