README.md

---
license: gemma
language:
- en
base_model:
- google/gemma-2-2b-it
pipeline_tag: text-generation
library_name: transformers
tags:
- gemma
- 2b
- CoT
- text-generation-inference
- gwq2b
- gemma-with-question
- safetensors
---
![gwq2.png](https://cdn-uploads.huggingface.co/production/uploads/65bb837dbfb878f46c77de4c/Ayc6YKE6FKYKb8Mible4z.png)
<a target="_blank" href="https://huggingface.co/spaces/prithivMLmods/GWQ-2B">
  <img src="https://huggingface.co/datasets/huggingface/badges/raw/main/open-in-hf-spaces-sm.svg" alt="gwq2b.hf.space"/>
</a>
# **GWQ2b - Gemma with Questions2b**

GWQ2b is a family of lightweight, state-of-the-art open models from Google, built using the same research and technology employed to create the Gemini models. These models are text-to-text, decoder-only large language models, available in English, with open weights for both pre-trained and instruction-tuned variants. GWQ2b models are well-suited for a variety of text generation tasks, including question answering, summarization, and reasoning. GWQ2b is fine-tuned on the Chain of Continuous Thought Synthetic Dataset, built upon the Gemma2forCasualLM architecture.

# **Running GWQ2b Demo**

```python
# pip install accelerate
from transformers import AutoTokenizer, AutoModelForCausalLM
import torch

tokenizer = AutoTokenizer.from_pretrained("prithivMLmods/GWQ2b")
model = AutoModelForCausalLM.from_pretrained(
    "prithivMLmods/GWQ2b",
    device_map="auto",
    torch_dtype=torch.bfloat16,
)

input_text = "Write me a poem about Machine Learning."
input_ids = tokenizer(input_text, return_tensors="pt").to("cuda")

outputs = model.generate(**input_ids, max_new_tokens=32)
print(tokenizer.decode(outputs[0]))
```

You can ensure the correct chat template is applied by using `tokenizer.apply_chat_template` as follows:
```python
messages = [
    {"role": "user", "content": "Write me a poem about Machine Learning."},
]
input_ids = tokenizer.apply_chat_template(messages, return_tensors="pt", return_dict=True).to("cuda")

outputs = model.generate(**input_ids, max_new_tokens=256)
print(tokenizer.decode(outputs[0]))
```
# **Key Architecture**

1. **Transformer-Based Design**:  
   GWQ2b leverages the transformer architecture, utilizing self-attention mechanisms to process input text and capture contextual relationships effectively.

2. **Lightweight and Efficient**:  
   It is designed to be computationally efficient, with fewer parameters compared to larger models, making it ideal for deployment on resource-constrained devices or environments.

3. **Modular Layers**:  
   The architecture consists of modular encoder and decoder layers, allowing flexibility in adapting the model for specific tasks like text generation, summarization, or classification.

4. **Attention Mechanisms**:  
   GWQ2b employs multi-head self-attention to focus on relevant parts of the input text, improving its ability to handle long-range dependencies and complex language structures.

5. **Pre-training and Fine-Tuning**:  
   The model is pre-trained on large text corpora and can be fine-tuned for specific tasks, such as markdown processing in ReadM.Md, to enhance its performance on domain-specific data.

6. **Scalability**:  
   The architecture supports scaling up or down based on the application's requirements, balancing performance and resource usage.

7. **Open-Source and Customizable**:  
   Being open-source, GWQ2b allows developers to modify and extend its architecture to suit specific use cases, such as integrating it into tools like ReadM.Md for markdown-related tasks.

# **Intended Use of GWQ2b (Gemma with Questions2b)**

1. **Question Answering:**  
   The model excels in generating concise and relevant answers to user-provided queries across various domains.

2. **Summarization:**  
   It can be used to summarize large bodies of text, making it suitable for news aggregation, academic research, and report generation.

3. **Reasoning Tasks:**  
   GWQ2b is fine-tuned on the Chain of Continuous Thought Synthetic Dataset, which enhances its ability to perform reasoning, multi-step problem solving, and logical inferences.

4. **Text Generation:**  
   The model is ideal for creative writing tasks such as generating poems, stories, and essays. It can also be used for generating code comments, documentation, and markdown files.

5. **Instruction Following:**  
   GWQ2b’s instruction-tuned variant is suitable for generating responses based on user instructions, making it useful for virtual assistants, tutoring systems, and automated customer support.

6. **Domain-Specific Applications:**  
   Thanks to its modular design and open-source nature, the model can be fine-tuned for specific tasks like legal document summarization, medical record analysis, or financial report generation.

# **Limitations of GWQ2b**

1. **Resource Requirements:**  
   Although lightweight compared to larger models, the 9B parameter size still requires significant computational resources, including GPUs with large memory for inference.

2. **Knowledge Cutoff:**  
   The model’s pre-training data may not include recent information, making it less effective for answering queries on current events or newly developed topics.

3. **Bias in Outputs:**  
   Since the model is trained on publicly available datasets, it may inherit biases present in those datasets, leading to potentially biased or harmful outputs in sensitive contexts.

4. **Hallucinations:**  
   Like other large language models, GWQ2b can occasionally generate incorrect or nonsensical information, especially when asked for facts or reasoning outside its training scope.

5. **Lack of Common-Sense Reasoning:**  
   While GWQ2b is fine-tuned for reasoning, it may still struggle with tasks requiring deep common-sense knowledge or nuanced understanding of human behavior and emotions.

6. **Dependency on Fine-Tuning:**  
   For optimal performance on domain-specific tasks, fine-tuning on relevant datasets is required, which demands additional computational resources and expertise.
  
7. **Context Length Limitation:**  
   The model’s ability to process long documents is limited by its maximum context window size. If the input exceeds this limit, truncation may lead to loss of important information.