albert-xlarge-v1 / README.md

Large -> Xlarge

a74dd20 almost 4 years ago

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	---
	language: en
	license: apache-2.0
	datasets:
	- bookcorpus
	- wikipedia
	---

	# ALBERT XLarge v1

	Pretrained model on English language using a masked language modeling (MLM) objective. It was introduced in
	[this paper](https://arxiv.org/abs/1909.11942) and first released in
	[this repository](https://github.com/google-research/albert). This model, as all ALBERT models, is uncased: it does not make a difference
	between english and English.

	Disclaimer: The team releasing ALBERT did not write a model card for this model so this model card has been written by
	the Hugging Face team.

	## Model description

	ALBERT is a transformers model pretrained on a large corpus of English data in a self-supervised fashion. This means it
	was pretrained on the raw texts only, with no humans labelling them in any way (which is why it can use lots of
	publicly available data) with an automatic process to generate inputs and labels from those texts. More precisely, it
	was pretrained with two objectives:

	- Masked language modeling (MLM): taking a sentence, the model randomly masks 15% of the words in the input then run
	the entire masked sentence through the model and has to predict the masked words. This is different from traditional
	recurrent neural networks (RNNs) that usually see the words one after the other, or from autoregressive models like
	GPT which internally mask the future tokens. It allows the model to learn a bidirectional representation of the
	sentence.
	- Sentence Ordering Prediction (SOP): ALBERT uses a pretraining loss based on predicting the ordering of two consecutive segments of text.

	This way, the model learns an inner representation of the English language that can then be used to extract features
	useful for downstream tasks: if you have a dataset of labeled sentences for instance, you can train a standard
	classifier using the features produced by the ALBERT model as inputs.

	ALBERT is particular in that it shares its layers across its Transformer. Therefore, all layers have the same weights. Using repeating layers results in a small memory footprint, however, the computational cost remains similar to a BERT-like architecture with the same number of hidden layers as it has to iterate through the same number of (repeating) layers.

	This is the first version of the xlarge model. Version 2 is different from version 1 due to different dropout rates, additional training data, and longer training. It has better results in nearly all downstream tasks.

	This model has the following configuration:

	- 24 repeating layers
	- 128 embedding dimension
	- 2048 hidden dimension
	- 16 attention heads
	- 58M parameters

	## Intended uses & limitations

	You can use the raw model for either masked language modeling or next sentence prediction, but it's mostly intended to
	be fine-tuned on a downstream task. See the [model hub](https://huggingface.co/models?filter=albert) to look for
	fine-tuned versions on a task that interests you.

	Note that this model is primarily aimed at being fine-tuned on tasks that use the whole sentence (potentially masked)
	to make decisions, such as sequence classification, token classification or question answering. For tasks such as text
	generation you should look at model like GPT2.

	### How to use

	You can use this model directly with a pipeline for masked language modeling:

	```python
	>>> from transformers import pipeline
	>>> unmasker = pipeline('fill-mask', model='albert-xlarge-v1')
	>>> unmasker("Hello I'm a [MASK] model.")
	[
	{
	"sequence":"[CLS] hello i'm a modeling model.[SEP]",
	"score":0.05816134437918663,
	"token":12807,
	"token_str":"â–modeling"
	},
	{
	"sequence":"[CLS] hello i'm a modelling model.[SEP]",
	"score":0.03748830780386925,
	"token":23089,
	"token_str":"â–modelling"
	},
	{
	"sequence":"[CLS] hello i'm a model model.[SEP]",
	"score":0.033725276589393616,
	"token":1061,
	"token_str":"â–model"
	},
	{
	"sequence":"[CLS] hello i'm a runway model.[SEP]",
	"score":0.017313428223133087,
	"token":8014,
	"token_str":"â–runway"
	},
	{
	"sequence":"[CLS] hello i'm a lingerie model.[SEP]",
	"score":0.014405295252799988,
	"token":29104,
	"token_str":"â–lingerie"
	}
	]
	```

	Here is how to use this model to get the features of a given text in PyTorch:

	```python
	from transformers import AlbertTokenizer, AlbertModel
	tokenizer = AlbertTokenizer.from_pretrained('albert-xlarge-v1')
	model = AlbertModel.from_pretrained("albert-xlarge-v1")
	text = "Replace me by any text you'd like."
	encoded_input = tokenizer(text, return_tensors='pt')
	output = model(**encoded_input)
	```

	and in TensorFlow:

	```python
	from transformers import AlbertTokenizer, TFAlbertModel
	tokenizer = AlbertTokenizer.from_pretrained('albert-xlarge-v1')
	model = TFAlbertModel.from_pretrained("albert-xlarge-v1")
	text = "Replace me by any text you'd like."
	encoded_input = tokenizer(text, return_tensors='tf')
	output = model(encoded_input)
	```

	### Limitations and bias

	Even if the training data used for this model could be characterized as fairly neutral, this model can have biased
	predictions:

	```python
	>>> from transformers import pipeline
	>>> unmasker = pipeline('fill-mask', model='albert-xlarge-v1')
	>>> unmasker("The man worked as a [MASK].")

	[
	{
	"sequence":"[CLS] the man worked as a chauffeur.[SEP]",
	"score":0.029577180743217468,
	"token":28744,
	"token_str":"â–chauffeur"
	},
	{
	"sequence":"[CLS] the man worked as a janitor.[SEP]",
	"score":0.028865724802017212,
	"token":29477,
	"token_str":"â–janitor"
	},
	{
	"sequence":"[CLS] the man worked as a shoemaker.[SEP]",
	"score":0.02581118606030941,
	"token":29024,
	"token_str":"â–shoemaker"
	},
	{
	"sequence":"[CLS] the man worked as a blacksmith.[SEP]",
	"score":0.01849772222340107,
	"token":21238,
	"token_str":"â–blacksmith"
	},
	{
	"sequence":"[CLS] the man worked as a lawyer.[SEP]",
	"score":0.01820771023631096,
	"token":3672,
	"token_str":"â–lawyer"
	}
	]

	>>> unmasker("The woman worked as a [MASK].")

	[
	{
	"sequence":"[CLS] the woman worked as a receptionist.[SEP]",
	"score":0.04604868218302727,
	"token":25331,
	"token_str":"â–receptionist"
	},
	{
	"sequence":"[CLS] the woman worked as a janitor.[SEP]",
	"score":0.028220869600772858,
	"token":29477,
	"token_str":"â–janitor"
	},
	{
	"sequence":"[CLS] the woman worked as a paramedic.[SEP]",
	"score":0.0261906236410141,
	"token":23386,
	"token_str":"â–paramedic"
	},
	{
	"sequence":"[CLS] the woman worked as a chauffeur.[SEP]",
	"score":0.024797942489385605,
	"token":28744,
	"token_str":"â–chauffeur"
	},
	{
	"sequence":"[CLS] the woman worked as a waitress.[SEP]",
	"score":0.024124596267938614,
	"token":13678,
	"token_str":"â–waitress"
	}
	]
	```

	This bias will also affect all fine-tuned versions of this model.

	## Training data

	The ALBERT model was pretrained on [BookCorpus](https://yknzhu.wixsite.com/mbweb), a dataset consisting of 11,038
	unpublished books and [English Wikipedia](https://en.wikipedia.org/wiki/English_Wikipedia) (excluding lists, tables and
	headers).

	## Training procedure

	### Preprocessing

	The texts are lowercased and tokenized using SentencePiece and a vocabulary size of 30,000. The inputs of the model are
	then of the form:

	```
	[CLS] Sentence A [SEP] Sentence B [SEP]
	```

	### Training

	The ALBERT procedure follows the BERT setup.

	The details of the masking procedure for each sentence are the following:
	- 15% of the tokens are masked.
	- In 80% of the cases, the masked tokens are replaced by `[MASK]`.
	- In 10% of the cases, the masked tokens are replaced by a random token (different) from the one they replace.
	- In the 10% remaining cases, the masked tokens are left as is.

	## Evaluation results

	When fine-tuned on downstream tasks, the ALBERT models achieve the following results:

	\| \| Average \| SQuAD1.1 \| SQuAD2.0 \| MNLI \| SST-2 \| RACE \|
	\|----------------\|----------\|----------\|----------\|----------\|----------\|----------\|
	\|V2 \|
	\|ALBERT-base \|82.3 \|90.2/83.2 \|82.1/79.3 \|84.6 \|92.9 \|66.8 \|
	\|ALBERT-large \|85.7 \|91.8/85.2 \|84.9/81.8 \|86.5 \|94.9 \|75.2 \|
	\|ALBERT-xlarge \|87.9 \|92.9/86.4 \|87.9/84.1 \|87.9 \|95.4 \|80.7 \|
	\|ALBERT-xxlarge \|90.9 \|94.6/89.1 \|89.8/86.9 \|90.6 \|96.8 \|86.8 \|
	\|V1 \|
	\|ALBERT-base \|80.1 \|89.3/82.3 \| 80.0/77.1\|81.6 \|90.3 \| 64.0 \|
	\|ALBERT-large \|82.4 \|90.6/83.9 \| 82.3/79.4\|83.5 \|91.7 \| 68.5 \|
	\|ALBERT-xlarge \|85.5 \|92.5/86.1 \| 86.1/83.1\|86.4 \|92.4 \| 74.8 \|
	\|ALBERT-xxlarge \|91.0 \|94.8/89.3 \| 90.2/87.4\|90.8 \|96.9 \| 86.5 \|


	### BibTeX entry and citation info

	```bibtex
	@article{DBLP:journals/corr/abs-1909-11942,
	author = {Zhenzhong Lan and
	Mingda Chen and
	Sebastian Goodman and
	Kevin Gimpel and
	Piyush Sharma and
	Radu Soricut},
	title = {{ALBERT:} {A} Lite {BERT} for Self-supervised Learning of Language
	Representations},
	journal = {CoRR},
	volume = {abs/1909.11942},
	year = {2019},
	url = {http://arxiv.org/abs/1909.11942},
	archivePrefix = {arXiv},
	eprint = {1909.11942},
	timestamp = {Fri, 27 Sep 2019 13:04:21 +0200},
	biburl = {https://dblp.org/rec/journals/corr/abs-1909-11942.bib},
	bibsource = {dblp computer science bibliography, https://dblp.org}
	}
	```