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TinyRoBERTa-MRQA

This is the distilled version of the VMware/roberta-large-mrqa model. This model has a comparable prediction quality to the base model and runs twice as fast.

Overview

  • Model name: tinyroberta-mrqa
  • Model type: Extractive Question Answering
  • Teacher Model: VMware/roberta-large-mrqa
  • Training dataset: MRQA (Machine Reading for Question Answering)
  • Training data size: 516,819 examples
  • Language: English
  • Framework: PyTorch
  • Model version: 1.0

Hyperparameters

Distillation Hyperparameters

batch_size = 96
n_epochs = 4
base_LM_model = "deepset/tinyroberta-squad2-step1"
max_seq_len = 384
learning_rate = 3e-5
lr_schedule = LinearWarmup
warmup_proportion = 0.2
doc_stride = 128
max_query_length = 64
distillation_loss_weight = 0.75
temperature = 1.5
teacher = "VMware/roberta-large-mrqa"

Finetunning Hyperparameters

We have finetuned on the MRQA training set.

    learning_rate=1e-5,
    num_train_epochs=3,
    weight_decay=0.01,
    per_device_train_batch_size=16,
    n_gpus = 1

Distillation

This model is inspired by deepset/tinyroberta-squad2 and the TinyBERT paper. We start with a base checkpoint of deepset/roberta-base-squad2 and perform further task prediction layer distillation on VMware/roberta-large-mrqa. We then fine-tune it on MRQA.

Usage

In Transformers

from transformers import AutoModelForQuestionAnswering, AutoTokenizer, pipeline

model_name = "VMware/tinyroberta-mrqa"

# a) Get predictions
nlp = pipeline('question-answering', model=model_name, tokenizer=model_name)
QA_input = {
context : "We present the results of the Machine Reading for Question Answering (MRQA) 2019 shared task on evaluating the generalization capabilities of reading comprehension systems. In this task, we adapted and unified 18 distinct question answering datasets into the same format. Among them, six datasets were made available for training, six datasets were made available for development, and the final six were hidden for final evaluation. Ten teams submitted systems, which explored various ideas including data sampling, multi-task learning, adversarial training and ensembling. The best system achieved an average F1 score of 72.5 on the 12 held-out datasets, 10.7 absolute points higher than our initial baseline based on BERT."
question :  "What is MRQA?"
}
res = nlp(QA_input)

# b) Load model & tokenizer
model = AutoModelForQuestionAnswering.from_pretrained(model_name)
tokenizer = AutoTokenizer.from_pretrained(model_name)

Model Family Performance

Parent Language Model Number of Parameters Training Time Eval Time Test Time Eval EM Eval F1 Test EM Test F1
BERT-Tiny 4,369,666 26:11 0:41 0:04 22.78 32.42 10.18 18.72
BERT-Base 108,893,186 8:39:10 18:42 2:13 64.48 76.14 48.89 59.89
BERT-Large 334,094,338 28:35:38 1:00:56 7:14 69.52 80.50 55.00 65.78
DeBERTa-v3-Extra-Small 70,682,882 5:19:05 11:29 1:16 65.58 77.17 50.92 62.58
DeBERTa-v3-Base 183,833,090 12:13:41 28:18 3:09 71.43 82.59 59.49 70.46
DeBERTa-v3-Large 434,014,210 38:36:13 1:25:47 9:33 76.08 86.23 64.27 75.22
ELECTRA-Small 13,483,522 2:16:36 3:55 0:27 57.63 69.38 38.68 51.56
ELECTRA-Base 108,893,186 8:40:57 18:41 2:12 68.78 80.16 54.70 65.80
ELECTRA-Large-Discriminator 334,094,338 28:31:59 1:00:40 7:13 74.15 84.96 62.35 73.28
MiniLMv2-L6-H384-from-BERT-Large 22,566,146 2:12:48 4:23 0:40 59.31 71.09 41.78 53.30
MiniLMv2-L6-H768-from-BERT-Large 66,365,954 4:42:59 10:01 1:10 64.27 75.84 49.05 59.82
MiniLMv2-L6-H384-from-RoBERTa-Large 30,147,842 2:15:10 4:19 0:30 59.27 70.64 42.95 54.03
MiniLMv2-L12-H384-from-RoBERTa-Large 40,794,626 4:14:22 8:27 0:58 64.58 76.23 51.28 62.83
MiniLMv2-L6-H768-from-RoBERTa-Large 81,529,346 4:39:02 9:34 1:06 65.80 77.17 51.72 63.27
RoBERTa-Base 124,056,578 8:50:29 18:59 2:11 69.06 80.08 55.53 66.49
RoBERTa-Large 354,312,194 29:16:06 1:01:10 7:04 74.08 84.38 62.20 72.88
TinyRoBERTa 81,529.346 4:27:06 * 9:54 1:04 69.38 80.07 53.29 64.16

*: Training times aren't perfectly comparable as TinyRoBERTa was distilled from VMware/roberta-large-mrqa that was already trained on MRQA

Limitations and Bias

The model is based on a large and diverse dataset, but it may still have limitations and biases in certain areas. Some limitations include:

  • Language: The model is designed to work with English text only and may not perform as well on other languages.

  • Domain-specific knowledge: The model has been trained on a general dataset and may not perform well on questions that require domain-specific knowledge.

  • Out-of-distribution questions: The model may struggle with questions that are outside the scope of the MRQA dataset. This is best demonstrated by the delta between its scores on the eval vs test datasets.

In addition, the model may have some bias in terms of the data it was trained on. The dataset includes questions from a variety of sources, but it may not be representative of all populations or perspectives. As a result, the model may perform better or worse for certain types of questions or on certain types of texts.


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Dataset used to train VMware/tinyroberta-mrqa

Evaluation results