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	---
	license: mit
	datasets:
	- Taylor658/photonic-integrated-circuit-yield
	language:
	- en
	---
	# Model Card

	## Model Overview 🦙✨
	Model Name: Photonics_Distill_Llama_70B
	Model Type: Distilled Reasoning Model
	Languages: English
	License: MIT

	Photonics_Distill_Llama_70B is a distilled reasoning model that excels at advanced logical inference and domain specific problem solving. It is distilled from a larger reasoning model, then further fine tuned using reinforcement learning 🚀 on the photonic_integrated_circuit_yield dataset. This process refines its performance on complex tasks in photonics and integrated circuit yield optimization, making it a great tool for researchers and professionals.

	## Model Details 🔧
	Developers: A Taylor
	Model Architecture: Transformer-based model enhanced with distillation techniques to optimize reasoning performance
	Parameters: 70 Billion
	Native Function Calling: Supported
	Multimodal Capabilities: Also Supports Multimodal Use Cases

	## Intended Use 🎯
	Primary Application:
	- Assist photonics researchers & engineers in analyzing and predicting integrated circuit yield.
	- Provide computational reasoning for design optimization and troubleshooting in photonic manufacturing.
	- Serve as an educational resource by offering clear explanations and insights based on simulation and experimental data.

	Usage Scenarios:
	- Explaining how specific variations in photonic design parameters (e.g., waveguide dimensions) impact yield.
	- Interpreting simulation data and theoretical models in photonic research.
	- Offering recommendations for improving manufacturing processes and design strategies in integrated photonics.

	## Training Data 📚
	Dataset Name: photonic_integrated_circuit_yield
	Description:
	A comprehensive dataset comprising synthetic simulation results, computational models, and theoretical analyses pertinent to photonic integrated circuits yield. This dataset is entirely generated through synthetic data creation techniques, designed to simulate a wide range of manufacturing scenarios, yield metrics, and performance benchmarks. It enables the model to learn nuanced reasoning strategies in photonic applications without relying on real-world experimental data.

	Data Modalities:
	- Text: Artificially generated synthetic research articles, technical reports, and simulation summaries.
	- Code: Simulation scripts and algorithms relevant to photonic circuit analysis, crafted to mimic real-world processes.

	## Training Procedure ⚙️
	The model is fine tuned via a reinforcement learning framework.
	Key enhancements include:

	- Domain-Specific Fine-Tuning: Leveraging the synthetic photonic_integrated_circuit_yield dataset to adjust model parameters for optimal performance in simulated photonic reasoning tasks.
	- Reinforcement Learning: Utilizing reward-based feedback 🚀 to reinforce accurate, insightful, and contextually relevant responses based on synthetic data.
	- Validation and Testing: Rigorous evaluation against established simulation benchmarks and theoretical models to ensure reliable performance.
	- Iterative Refinement: Incorporating continuous feedback from domain experts to progressively improve the model’s output quality.

	## How to Use 💡
	Input Format:
	The model accepts natural language queries or prompts focused on photonic integrated circuits, yield analysis, simulation data interpretation, and related technical topics.

	Examples:
	- "How does a variation in waveguide width affect the overall yield of a photonic integrated circuit according to synthetic simulation models?"
	- "What simulation parameters are most critical when assessing yield in photonic manufacturing processes using synthetic data?"
	- "Explain the influence of material properties on photonic integrated circuit performance based on recent synthetic data."

	## Limitations ⚠️
	- Work in Progress: The model is under continuous development; performance improvements and updates are expected over time.
	- Domain Specificity: Optimized for photonic integrated circuits yield analysis; performance may degrade when applied to unrelated domains.
	- Synthetic Data Disclaimer: As the model is trained exclusively on synthetic data, its outputs should be validated against real world data and expert judgment when applied to practical scenarios.

	## Ethical Considerations 🤝
	- Accuracy: Intended as a research and educational aid, the model should complement rather than replace expert judgment, especially in high-stakes applications.
	- Transparency: Users must be aware that the model’s insights are derived from synthetic data and may not fully capture the complexities of real-world photonic manufacturing.

	## License 📜
	- Model License: MIT

	## Future Work 🔮
	- Enhanced Reasoning Capabilities: Further refine reinforcement learning strategies to boost the model’s reasoning depth and accuracy.
	- Expanded Domain Coverage: Integrate additional synthetic datasets related to photonic design and manufacturing to broaden the model's expertise.
	- Performance Optimization: Explore methods to reduce computational overhead without compromising performance and accuracy.

	## Contact Information 📧

	Author: https://huggingface.co/Taylor658

	---
	license: mit
	datasets:
	- Taylor658/photonic-integrated-circuit-yield
	language:
	- en
	---
	# Model Card

	## Model Overview 🦙✨
	Model Name: Photonics_Distill_Llama_70B
	Model Type: Distilled Reasoning Model
	Languages: English
	License: MIT

	Photonics_Distill_Llama_70B is a distilled reasoning model that excels at advanced logical inference and domain specific problem solving. It is distilled from a larger reasoning model, then further fine tuned using reinforcement learning 🚀 on the photonic_integrated_circuit_yield dataset. This process refines its performance on complex tasks in photonics and integrated circuit yield optimization, making it a great tool for researchers and professionals.

	## Model Details 🔧
	Developers: A Taylor
	Model Architecture: Transformer-based model enhanced with distillation techniques to optimize reasoning performance
	Parameters: 70 Billion
	Native Function Calling: Supported
	Multimodal Capabilities: Also Supports Multimodal Use Cases

	## Intended Use 🎯
	Primary Application:
	- Assist photonics researchers & engineers in analyzing and predicting integrated circuit yield.
	- Provide computational reasoning for design optimization and troubleshooting in photonic manufacturing.
	- Serve as an educational resource by offering clear explanations and insights based on simulation and experimental data.

	Usage Scenarios:
	- Explaining how specific variations in photonic design parameters (e.g., waveguide dimensions) impact yield.
	- Interpreting simulation data and theoretical models in photonic research.
	- Offering recommendations for improving manufacturing processes and design strategies in integrated photonics.

	## Training Data 📚
	Dataset Name: photonic_integrated_circuit_yield
	Description:
	A comprehensive dataset comprising synthetic simulation results, computational models, and theoretical analyses pertinent to photonic integrated circuits yield. This dataset is entirely generated through synthetic data creation techniques, designed to simulate a wide range of manufacturing scenarios, yield metrics, and performance benchmarks. It enables the model to learn nuanced reasoning strategies in photonic applications without relying on real-world experimental data.

	Data Modalities:
	- Text: Artificially generated synthetic research articles, technical reports, and simulation summaries.
	- Code: Simulation scripts and algorithms relevant to photonic circuit analysis, crafted to mimic real-world processes.

	## Training Procedure ⚙️
	The model is fine tuned via a reinforcement learning framework.
	Key enhancements include:

	- Domain-Specific Fine-Tuning: Leveraging the synthetic photonic_integrated_circuit_yield dataset to adjust model parameters for optimal performance in simulated photonic reasoning tasks.
	- Reinforcement Learning: Utilizing reward-based feedback 🚀 to reinforce accurate, insightful, and contextually relevant responses based on synthetic data.
	- Validation and Testing: Rigorous evaluation against established simulation benchmarks and theoretical models to ensure reliable performance.
	- Iterative Refinement: Incorporating continuous feedback from domain experts to progressively improve the model’s output quality.

	## How to Use 💡
	Input Format:
	The model accepts natural language queries or prompts focused on photonic integrated circuits, yield analysis, simulation data interpretation, and related technical topics.

	Examples:
	- "How does a variation in waveguide width affect the overall yield of a photonic integrated circuit according to synthetic simulation models?"
	- "What simulation parameters are most critical when assessing yield in photonic manufacturing processes using synthetic data?"
	- "Explain the influence of material properties on photonic integrated circuit performance based on recent synthetic data."

	## Limitations ⚠️
	- Work in Progress: The model is under continuous development; performance improvements and updates are expected over time.
	- Domain Specificity: Optimized for photonic integrated circuits yield analysis; performance may degrade when applied to unrelated domains.
	- Synthetic Data Disclaimer: As the model is trained exclusively on synthetic data, its outputs should be validated against real world data and expert judgment when applied to practical scenarios.

	## Ethical Considerations 🤝
	- Accuracy: Intended as a research and educational aid, the model should complement rather than replace expert judgment, especially in high-stakes applications.
	- Transparency: Users must be aware that the model’s insights are derived from synthetic data and may not fully capture the complexities of real-world photonic manufacturing.

	## License 📜
	- Model License: MIT

	## Future Work 🔮
	- Enhanced Reasoning Capabilities: Further refine reinforcement learning strategies to boost the model’s reasoning depth and accuracy.
	- Expanded Domain Coverage: Integrate additional synthetic datasets related to photonic design and manufacturing to broaden the model's expertise.
	- Performance Optimization: Explore methods to reduce computational overhead without compromising performance and accuracy.

	## Contact Information 📧

	Author: https://huggingface.co/Taylor658