model/README.md

metadata

tags:
  - sentence-transformers
  - sentence-similarity
  - feature-extraction
  - dense
  - generated_from_trainer
  - dataset_size:363
  - loss:CosineSimilarityLoss
base_model: sentence-transformers/all-MiniLM-L6-v2
widget:
  - source_sentence: \section{5. Correspondencia con constantes físicas}
    sentences:
      - \section{7. Simulación Python – Malla Icosaédrica y Autovalores}
      - >-
        \textbf{Interpretación:} Cada modo $n$ representa un posible estado de
        partícula, resonancia o nodo cognitivo.
      - rroc_V
  - source_sentence: >-
      \[

      S_{\rm eff} = \int d^4x \left[ \frac{R}{16 \pi G} + \lambda \log(r) +
      \mathcal{L}_{\rm matter} \right]

      \]
    sentences:
      - >-
        Sea $H$ la matriz discreta sobre la red icosaédrica. Los autovalores
        $\{E_n\}$ y vectores propios $\{\Psi_n\}$ cumplen:
      - |-
        \begin{lstlisting}[language=Python]
        import numpy as np
        import networkx as nx
        from scipy.linalg import eigh
        import matplotlib.pyplot as plt
      - \section{6. Aplicaciones en resonancia y cognición}
  - source_sentence: \section{6. Aplicaciones en resonancia y cognición}
    sentences:
      - |-
        # Visualizar malla
        pos = nx.spring_layout(G, seed=42)
        nx.draw(G, pos, with_labels=True, node_color='cyan', edge_color='gray')
        plt.show()
        \end{lstlisting}
      - |-
        \begin{lstlisting}[language=Python]
        import numpy as np
        import networkx as nx
        from scipy.linalg import eigh
        import matplotlib.pyplot as plt
      - \section{5. Correspondencia con constantes físicas}
  - source_sentence: >-
      \textbf{Interpretación:} Cada modo $n$ representa un posible estado de
      partícula, resonancia o nodo cognitivo.
    sentences:
      - |-
        \begin{lstlisting}[language=Python]
        import numpy as np
        import networkx as nx
        from scipy.linalg import eigh
        import matplotlib.pyplot as plt
      - ln(phi)
      - |-
        # Visualizar malla
        pos = nx.spring_layout(G, seed=42)
        nx.draw(G, pos, with_labels=True, node_color='cyan', edge_color='gray')
        plt.show()
        \end{lstlisting}
  - source_sentence: |-
      donde:
      \begin{itemize}
          \item $\psi_i$ son espinores icosaédricos.
          \item $r_{ij}$ es la distancia entre nodos $i$ y $j$.
          \item $A,B,C$ son acoplamientos gauge discretos.
      \end{itemize}
    sentences:
      - >-
        \begin{abstract}

        Esta versión extendida del \textbf{Resonance of Reality Framework (RRF)}
        presenta:

        \begin{itemize}
            \item Hamiltoniano discreto icosaédrico con modos normales.
            \item Corrección logarítmica gravitatoria y acoplamientos gauge explícitos.
            \item Correspondencia con constantes físicas fundamentales.
            \item Ejemplo de simulación Python que visualiza la malla icosaédrica y autovalores.
        \end{itemize}

        \end{abstract}
      - |-
        \begin{itemize}
            \item Cada nodo $\psi_i$ como \textbf{átomo de experiencia}.
            \item Patrones icosaédricos y $\phi$ guían frecuencia de resonancia.
            \item Protocolos musicales y visuales para plasticidad neuronal.
        \end{itemize}
      - |-
        \begin{itemize}
            \item Cada nodo $\psi_i$ como \textbf{átomo de experiencia}.
            \item Patrones icosaédricos y $\phi$ guían frecuencia de resonancia.
            \item Protocolos musicales y visuales para plasticidad neuronal.
        \end{itemize}
pipeline_tag: sentence-similarity
library_name: sentence-transformers

SentenceTransformer based on sentence-transformers/all-MiniLM-L6-v2

This is a sentence-transformers model finetuned from sentence-transformers/all-MiniLM-L6-v2. It maps sentences & paragraphs to a 384-dimensional dense vector space and can be used for semantic textual similarity, semantic search, paraphrase mining, text classification, clustering, and more.

Model Details

Model Description

• Model Type: Sentence Transformer
• Base model: sentence-transformers/all-MiniLM-L6-v2
• Maximum Sequence Length: 256 tokens
• Output Dimensionality: 384 dimensions
• Similarity Function: Cosine Similarity

Model Sources

• Documentation: Sentence Transformers Documentation
• Repository: Sentence Transformers on GitHub
• Hugging Face: Sentence Transformers on Hugging Face

Full Model Architecture

SentenceTransformer(
  (0): Transformer({'max_seq_length': 256, 'do_lower_case': False, 'architecture': 'BertModel'})
  (1): Pooling({'word_embedding_dimension': 384, 'pooling_mode_cls_token': False, 'pooling_mode_mean_tokens': True, 'pooling_mode_max_tokens': False, 'pooling_mode_mean_sqrt_len_tokens': False, 'pooling_mode_weightedmean_tokens': False, 'pooling_mode_lasttoken': False, 'include_prompt': True})
  (2): Normalize()
)

Usage

Direct Usage (Sentence Transformers)

First install the Sentence Transformers library:

pip install -U sentence-transformers

Then you can load this model and run inference.

from sentence_transformers import SentenceTransformer

# Download from the 🤗 Hub
model = SentenceTransformer("sentence_transformers_model_id")
# Run inference
sentences = [
    'donde:\n\\begin{itemize}\n    \\item $\\psi_i$ son espinores icosaédricos.\n    \\item $r_{ij}$ es la distancia entre nodos $i$ y $j$.\n    \\item $A,B,C$ son acoplamientos gauge discretos.\n\\end{itemize}',
    '\\begin{itemize}\n    \\item Cada nodo $\\psi_i$ como \\textbf{átomo de experiencia}.\n    \\item Patrones icosaédricos y $\\phi$ guían frecuencia de resonancia.\n    \\item Protocolos musicales y visuales para plasticidad neuronal.\n\\end{itemize}',
    '\\begin{abstract}\nEsta versión extendida del \\textbf{Resonance of Reality Framework (RRF)} presenta:\n\\begin{itemize}\n    \\item Hamiltoniano discreto icosaédrico con modos normales.\n    \\item Corrección logarítmica gravitatoria y acoplamientos gauge explícitos.\n    \\item Correspondencia con constantes físicas fundamentales.\n    \\item Ejemplo de simulación Python que visualiza la malla icosaédrica y autovalores.\n\\end{itemize}\n\\end{abstract}',
]
embeddings = model.encode(sentences)
print(embeddings.shape)
# [3, 384]

# Get the similarity scores for the embeddings
similarities = model.similarity(embeddings, embeddings)
print(similarities)
# tensor([[1.0000, 0.7950, 0.7297],
#         [0.7950, 1.0000, 0.7343],
#         [0.7297, 0.7343, 1.0000]])

Training Details

Training Dataset

Unnamed Dataset

• Size: 363 training samples
• Columns: sentence_0, sentence_1, and label
• Approximate statistics based on the first 363 samples:

  	sentence_0	sentence_1	label
  type	string	string	float
  details	min: 16 tokens mean: 65.29 tokens max: 127 tokens	min: 3 tokens mean: 38.02 tokens max: 127 tokens	min: 0.0 mean: 0.5 max: 1.0

• Samples:

  sentence_0	sentence_1	label
  Sea $H$ la matriz discreta sobre la red icosaédrica. Los autovalores ${E_n}$ y vectores propios ${\Psi_n}$ cumplen:	# Crear grafo icosaédrico G = nx.icosahedral_graph() n = G.number_of_nodes()	0.4647801650468898
  [ i \hbar \frac{\partial \Psi}{\partial t} = H \Psi ]	\begin{align*} \alpha_{\rm fine} &\approx f(E_n, \text{geometría icosaédrica}) \ m_\nu &\approx g(\text{acoplamientos SU(2)/SU(3) discretos}) \ \Lambda &\approx h(\text{energía de vacío logarítmica}) \end{align*}	0.4930957329947213
  \title{Resonance of Reality Framework (RRF) Extendido\ Hamiltoniano Icosaédrico, Gravedad Logarítmica y Simulación} \author{Antony Padilla Morales} \date{\today}	donde: \begin{itemize} \item $\psi_i$ son espinores icosaédricos. \item $r_{ij}$ es la distancia entre nodos $i$ y $j$. \item $A,B,C$ son acoplamientos gauge discretos. \end{itemize}	0.5762137786115148

• Loss: CosineSimilarityLoss with these parameters:

  {
      "loss_fct": "torch.nn.modules.loss.MSELoss"
  }
  

Training Hyperparameters

Non-Default Hyperparameters

• per_device_train_batch_size: 16
• per_device_eval_batch_size: 16
• multi_dataset_batch_sampler: round_robin

All Hyperparameters

Click to expand

• overwrite_output_dir: False
• do_predict: False
• eval_strategy: no
• prediction_loss_only: True
• per_device_train_batch_size: 16
• per_device_eval_batch_size: 16
• per_gpu_train_batch_size: None
• per_gpu_eval_batch_size: None
• gradient_accumulation_steps: 1
• eval_accumulation_steps: None
• torch_empty_cache_steps: None
• learning_rate: 5e-05
• weight_decay: 0.0
• adam_beta1: 0.9
• adam_beta2: 0.999
• adam_epsilon: 1e-08
• max_grad_norm: 1
• num_train_epochs: 3
• max_steps: -1
• lr_scheduler_type: linear
• lr_scheduler_kwargs: {}
• warmup_ratio: 0.0
• warmup_steps: 0
• log_level: passive
• log_level_replica: warning
• log_on_each_node: True
• logging_nan_inf_filter: True
• save_safetensors: True
• save_on_each_node: False
• save_only_model: False
• restore_callback_states_from_checkpoint: False
• no_cuda: False
• use_cpu: False
• use_mps_device: False
• seed: 42
• data_seed: None
• jit_mode_eval: False
• bf16: False
• fp16: False
• fp16_opt_level: O1
• half_precision_backend: auto
• bf16_full_eval: False
• fp16_full_eval: False
• tf32: None
• local_rank: 0
• ddp_backend: None
• tpu_num_cores: None
• tpu_metrics_debug: False
• debug: []
• dataloader_drop_last: False
• dataloader_num_workers: 0
• dataloader_prefetch_factor: None
• past_index: -1
• disable_tqdm: False
• remove_unused_columns: True
• label_names: None
• load_best_model_at_end: False
• ignore_data_skip: False
• fsdp: []
• fsdp_min_num_params: 0
• fsdp_config: {'min_num_params': 0, 'xla': False, 'xla_fsdp_v2': False, 'xla_fsdp_grad_ckpt': False}
• fsdp_transformer_layer_cls_to_wrap: None
• accelerator_config: {'split_batches': False, 'dispatch_batches': None, 'even_batches': True, 'use_seedable_sampler': True, 'non_blocking': False, 'gradient_accumulation_kwargs': None}
• parallelism_config: None
• deepspeed: None
• label_smoothing_factor: 0.0
• optim: adamw_torch_fused
• optim_args: None
• adafactor: False
• group_by_length: False
• length_column_name: length
• project: huggingface
• trackio_space_id: trackio
• ddp_find_unused_parameters: None
• ddp_bucket_cap_mb: None
• ddp_broadcast_buffers: False
• dataloader_pin_memory: True
• dataloader_persistent_workers: False
• skip_memory_metrics: True
• use_legacy_prediction_loop: False
• push_to_hub: False
• resume_from_checkpoint: None
• hub_model_id: None
• hub_strategy: every_save
• hub_private_repo: None
• hub_always_push: False
• hub_revision: None
• gradient_checkpointing: False
• gradient_checkpointing_kwargs: None
• include_inputs_for_metrics: False
• include_for_metrics: []
• eval_do_concat_batches: True
• fp16_backend: auto
• push_to_hub_model_id: None
• push_to_hub_organization: None
• mp_parameters:
• auto_find_batch_size: False
• full_determinism: False
• torchdynamo: None
• ray_scope: last
• ddp_timeout: 1800
• torch_compile: False
• torch_compile_backend: None
• torch_compile_mode: None
• include_tokens_per_second: False
• include_num_input_tokens_seen: no
• neftune_noise_alpha: None
• optim_target_modules: None
• batch_eval_metrics: False
• eval_on_start: False
• use_liger_kernel: False
• liger_kernel_config: None
• eval_use_gather_object: False
• average_tokens_across_devices: True
• prompts: None
• batch_sampler: batch_sampler
• multi_dataset_batch_sampler: round_robin
• router_mapping: {}
• learning_rate_mapping: {}

Framework Versions

• Python: 3.12.12
• Sentence Transformers: 5.1.1
• Transformers: 4.57.0
• PyTorch: 2.8.0+cu126
• Accelerate: 1.10.1
• Datasets: 4.0.0
• Tokenizers: 0.22.1

Citation

BibTeX

Sentence Transformers

@inproceedings{reimers-2019-sentence-bert,
    title = "Sentence-BERT: Sentence Embeddings using Siamese BERT-Networks",
    author = "Reimers, Nils and Gurevych, Iryna",
    booktitle = "Proceedings of the 2019 Conference on Empirical Methods in Natural Language Processing",
    month = "11",
    year = "2019",
    publisher = "Association for Computational Linguistics",
    url = "https://arxiv.org/abs/1908.10084",
}