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title: AI Tutor BERT | |
emoji: π | |
colorFrom: red | |
colorTo: indigo | |
sdk: gradio | |
sdk_version: 4.1.2 | |
app_file: app.py | |
pinned: false | |
license: apache-2.0 | |
# AI Tutor BERT | |
This model is a BERT model fine-tuned on artificial intelligence (AI) related terms and explanations. | |
With the increasing interest in artificial intelligence, many people are taking AI-related courses and projects. However, as a graduate student in artificial intelligence, it's not common to find useful resources that are easy for AI beginners to understand. Furthermore, personalized lessons tailored to individual levels and fields are often lacking, making it difficult for many people to start learning about artificial intelligence. To address these challenges, our team has created a language model that plays the role of a tutor in the field of AI terminology. Details about the model type, training dataset, and usage are explained below, so please read them carefully and be sure to try it out. | |
## How to use? | |
<img src="https://github.com/CountingMstar/AI_BERT/assets/90711707/45afcd24-7ef9-4149-85d4-2236e23fbf69" width="1400" height="700"/> | |
https://huggingface.co/spaces/pseudolab/AI_Tutor_BERT | |
As shown above, you can input passages (context) related to artificial intelligence and questions about terms. Upon pressing "Submit," you will receive corresponding explanations and answers on the right side. (This model only supports English.) | |
## Model | |
https://huggingface.co/bert-base-uncased | |
For the model, I used BERT, which is one of the most famous natural language processing models developed by Google. For more detailed information, please refer to the website mentioned above. To make the question-answering more like a private tutoring experience, I utilized a specialized Question and Answering model within BERT. Here's how you can load it: | |
``` | |
from transformers import BertForQuestionAnswering | |
model = BertForQuestionAnswering.from_pretrained("bert-base-uncased") | |
``` | |
https://huggingface.co/CountingMstar/ai-tutor-bert-model | |
Afterwards, I fine-tuned the original BertForQuestionAnswering model using the artificial intelligence-related datasets for my project on creating an AI tutoring model. You can find the fine-tuned AI Tutor BERT model at the link provided, and the usage in Python is as follows. | |
``` | |
from transformers import BertForQuestionAnswering | |
model = BertForQuestionAnswering.from_pretrained("CountingMstar/ai-tutor-bert-model") | |
``` | |
## Dataset | |
### Wikipedia | |
https://en.wikipedia.org/wiki/Main_Page | |
### activeloop | |
https://www.activeloop.ai/resources/glossary/arima-models/ | |
### Adrien Beaulieu | |
https://product.house/100-ai-glossary-terms-explained-to-the-rest-of-us/ | |
``` | |
Context: 'Feature engineering or feature extraction or feature discovery is the process of extracting features (characteristics, properties, attributes) from raw data. Due to deep learning networks, such as convolutional neural networks, that are able to learn features by themselves, domain-specific-based feature engineering has become obsolete for vision and speech processing. Other examples of features in physics include the construction of dimensionless numbers such as Reynolds number in fluid dynamics; then Nusselt number in heat transfer; Archimedes number in sedimentation; construction of first approximations of the solution such as analytical strength of materials solutions in mechanics, etc..' | |
Question: 'What is large language model?' | |
Answer: 'A large language model (LLM) is a type of language model notable for its ability to achieve general-purpose language understanding and generation.' | |
``` | |
The training dataset consists of three components: context, questions, and answers, all related to artificial intelligence. The response (correct answer) data is included within the context data, and the sentence order in the context data has been rearranged to augment the dataset. The question data is focused on artificial intelligence terms as the topic. You can refer to the example above for better understanding. In total, there are over 3,300 data points, stored in pickle files in the 'data' folder. The data has been extracted and processed using HTML from sources such as Wikipedia and other websites. The sources are as mentioned above. | |
## Training and Result | |
https://github.com/CountingMstar/AI_BERT/blob/main/MY_AI_BERT_final.ipynb | |
The training process involves loading data from the 'data' folder and utilizing the BERT Question and Answering model. Detailed instructions for model training and usage can be found in the link provided above. | |
``` | |
N_EPOCHS = 10 | |
optim = AdamW(model.parameters(), lr=5e-5) | |
``` | |
I used 10 epochs for training, and I employed the Adam optimizer with a learning rate of 5e-5. | |
<img src="https://github.com/CountingMstar/AI_BERT/assets/90711707/72142ff8-f5c8-47ea-9f19-1e6abb4072cd" width="500" height="400"/> | |
<img src="https://github.com/CountingMstar/AI_BERT/assets/90711707/2dd78573-34eb-4ce9-ad4d-2237fc7a5b1e" width="500" height="400"/> | |
The results, as shown in the graphs above, indicate that, at the last epoch, the loss is 6.917126256477786, and the accuracy is 0.9819078947368421, demonstrating that the model has been trained quite effectively. | |
Thank you. | |
--- | |
# AI Tutor BERT (μΈκ³΅μ§λ₯ κ³ΌμΈ μ μλ BERT) | |
μ΄ λͺ¨λΈμ μΈκ³΅μ§λ₯(AI) κ΄λ ¨ μ©μ΄ λ° μ€λͺ μ νμΈνλ(fine-tuning)ν BERT λͺ¨λΈμ λλ€. | |
μ΅κ·Ό μΈκ³΅μ§λ₯μ κ΄ν κ΄μ¬μ΄ λμμ§λ©΄μ λ§μ μ¬λμ΄ μΈκ³΅μ§λ₯ κ΄λ ¨ μμ λ° νλ‘μ νΈλ₯Ό μ§ννκ³ μμ΅λλ€. κ·Έλ¬λ μΈκ³΅μ§λ₯ κ΄λ ¨ λνμμμΌλ‘μ μ΄λ¬ν μμμ λΉν΄ μΈκ³΅μ§λ₯ μ΄λ³΄μλ€μ΄ μ μμλ€μ μ μλ μ μ©ν μλ£λ νμΉ μμ΅λλ€. λλΆμ΄ κ°μμ μμ€κ³Ό λΆμΌμ κ°μΈνλ κ°μ λν λΆμ‘±ν μν©μ΄μ΄μ λ§μ μ¬λλ€μ΄ μΈκ³΅μ§λ₯ νμ΅μ μμνκΈ° μ΄λ €μνκ³ μμ΅λλ€. μ΄λ¬ν λ¬Έμ λ₯Ό ν΄κ²°νκ³ μ, μ ν¬ νμ μΈκ³΅μ§λ₯ μ©μ΄ λλ©μΈμμ κ³ΌμΈ μ μλ μν μ νλ μΈμ΄λͺ¨λΈμ λ§λ€μμ΅λλ€. λͺ¨λΈμ μ’ λ₯, νμ΅ λ°μ΄ν°μ , μ¬μ©λ² λ±μ΄ μλμ μ€λͺ λμ΄ μμΌλ μμΈν μ½μ΄λ³΄μκ³ , κΌ μ¬μ©ν΄ 보μκΈ° λ°λλλ€. | |
## How to use? | |
<img src="https://github.com/CountingMstar/AI_BERT/assets/90711707/45afcd24-7ef9-4149-85d4-2236e23fbf69" width="1400" height="700"/> | |
https://huggingface.co/spaces/pseudolab/AI_Tutor_BERT | |
μ κ·Έλ¦Όκ³Ό κ°μ΄ μΈκ³΅μ§λ₯κ΄λ ¨ μ§λ¬Έ(λ¬Έλ§₯)κ³Ό μ©μ΄ κ΄λ ¨ μ§λ¬Έμ μ λ ₯ν΄μ£Όκ³ Submitμ λλ¬μ£Όλ©΄, μ€λ₯Έμͺ½μ ν΄λΉ μ©μ΄μ λν μ€λͺ λ΅λ³μ΄ λμ΅λλ€. | |
## Model | |
https://huggingface.co/bert-base-uncased | |
λͺ¨λΈμ κ²½μ° μμ°μ΄ μ²λ¦¬ λͺ¨λΈ μ€ κ°μ₯ μ λͺ ν Googleμμ κ°λ°ν BERTλ₯Ό μ¬μ©νμ΅λλ€. μμΈν μ€λͺ μ μ μ¬μ΄νΈλ₯Ό μ°Έκ³ νμκΈ° λ°λλλ€. μ§μμλ΅μ΄ μ£ΌμΈ κ³ΌμΈ μ μλλ΅κ², BERT μ€μμλ μ§μμλ΅μ νΉνλ Question and Answering λͺ¨λΈμ μ¬μ©νμμ΅λλ€. λΆλ¬μ€λ λ²μ λ€μκ³Ό κ°μ΅λλ€. | |
``` | |
from transformers import BertForQuestionAnswering | |
model = BertForQuestionAnswering.from_pretrained("bert-base-uncased") | |
``` | |
https://huggingface.co/CountingMstar/ai-tutor-bert-model | |
μ΄ν μ€λ¦¬μ§λ BertForQuestionAnswering λͺ¨λΈμ μ΄ νλ‘μ νΈ μ£Όμ μΈ μΈκ³΅μ§λ₯ κ³ΌμΈ μ μλ λͺ¨λΈλ‘ λ§λ€κΈ° μν΄ μλμ μΈκ³΅μ§λ₯ κ΄λ ¨ λ°μ΄ν°μ μΌλ‘ νμΈνλμ ν΄μ€¬μ΅λλ€. μ΄λ κ² νμΈνλλ AI Tutor BERT λͺ¨λΈμ μ λ§ν¬μμ μ°Ύμλ³΄μ€ μ μμΌλ©°, νμ΄μ¬μμμ μ¬μ©λ°©λ²μ μλμ κ°μ΅λλ€. | |
``` | |
from transformers import BertForQuestionAnswering | |
model = BertForQuestionAnswering.from_pretrained("CountingMstar/ai-tutor-bert-model") | |
``` | |
## Dataset | |
### Wikipedia | |
https://en.wikipedia.org/wiki/Main_Page | |
### activeloop | |
https://www.activeloop.ai/resources/glossary/arima-models/ | |
### Adrien Beaulieu | |
https://product.house/100-ai-glossary-terms-explained-to-the-rest-of-us/ | |
``` | |
Context: 'Feature engineering or feature extraction or feature discovery is the process of extracting features (characteristics, properties, attributes) from raw data. Due to deep learning networks, such as convolutional neural networks, that are able to learn features by themselves, domain-specific-based feature engineering has become obsolete for vision and speech processing. Other examples of features in physics include the construction of dimensionless numbers such as Reynolds number in fluid dynamics; then Nusselt number in heat transfer; Archimedes number in sedimentation; construction of first approximations of the solution such as analytical strength of materials solutions in mechanics, etc..' | |
Question: 'What is large language model?' | |
Answer: 'A large language model (LLM) is a type of language model notable for its ability to achieve general-purpose language understanding and generation.' | |
``` | |
νμ΅ λ°μ΄ν°μ μ μΈκ³΅μ§λ₯ κ΄λ ¨ λ¬Έλ§₯, μ§λ¬Έ, κ·Έλ¦¬κ³ μλ΅ μ΄λ κ² 3κ°μ§λ‘ ꡬμ±μ΄ λμ΄μμ΅λλ€. μλ΅(μ λ΅) λ°μ΄ν°λ λ¬Έλ§₯ λ°μ΄ν° μμ ν¬ν¨λμ΄ μκ³ , λ¬Έλ§₯ λ°μ΄ν°μ λ¬Έμ₯ μμλ₯Ό λ°κΏμ£Όμ΄ λ°μ΄ν°λ₯Ό μ¦κ°νμμ΅λλ€. μ§λ¬Έ λ°μ΄ν°λ μ£Όμ κ° λλ μΈκ³΅μ§λ₯ μ©μ΄λ‘ μ€μ νμ΅λλ€. μμ μμλ₯Ό 보μλ©΄ μ΄ν΄νμκΈ° νΈνμ€ κ²λλ€. μ΄ λ°μ΄ν° μλ 3300μ¬ κ°λ‘ data ν΄λμ pickle νμΌ ννλ‘ μ μ₯λμ΄ μκ³ , λ°μ΄ν°λ Wikipedia λ° λ€λ₯Έ μ¬μ΄νΈλ€μ μμ htmlμ μ΄μ©νμ¬ μΆμΆ λ° κ°κ³΅νμ¬ μ μνμμ΅λλ€. ν΄λΉ μΆμ²λ μμ κ°μ΅λλ€. | |
## Training and Result | |
https://github.com/CountingMstar/AI_BERT/blob/main/MY_AI_BERT_final.ipynb | |
νμ΅ λ°©μμ data ν΄λμ λ°μ΄ν°μ BERT Question and Answering λͺ¨λΈμ λΆμ΄μ μ§νλ©λλ€. μμΈν λͺ¨λΈ νμ΅ λ° μ¬μ©λ²μ μμ λ§ν¬μ μ€λͺ λμ΄ μμ΅λλ€. | |
``` | |
N_EPOCHS = 10 | |
optim = AdamW(model.parameters(), lr=5e-5) | |
``` | |
μν¬ν¬(epoch)λ 10μ μ¬μ©νμΌλ©°, μλ΄ μ΅ν°λ§μ΄μ Έμ λ¬λλ μ΄νΈλ 5e-5λ₯Ό μ¬μ©νμ΅λλ€. | |
<img src="https://github.com/CountingMstar/AI_BERT/assets/90711707/72142ff8-f5c8-47ea-9f19-1e6abb4072cd" width="500" height="400"/> | |
<img src="https://github.com/CountingMstar/AI_BERT/assets/90711707/2dd78573-34eb-4ce9-ad4d-2237fc7a5b1e" width="500" height="400"/> | |
κ²°κ³Όλ μ κ·Έλνλ€κ³Ό κ°μ΄ λ§μ§λ§ μν¬ν¬ κΈ°μ€ loss = 6.917126256477786, accuracy = 0.9819078947368421λ‘ μλΉν νμ΅μ΄ μ λ λͺ¨μ΅μ 보μ¬μ€λλ€. | |
κ°μ¬ν©λλ€. | |
Check out the configuration reference at https://huggingface.co/docs/hub/spaces-config-reference | |