Tesslate/OmniCoder-2-9B

library_name: transformers base_model: Qwen/Qwen3.5-9B tags:

qwen3.5
code
agent
sft
omnicoder
tesslate license: apache-2.0 language:
en pipeline_tag: text-generation model-index:
name: OmniCoder-2-9B results:
- task: type: text-generation dataset: name: AIME 2025 type: custom metrics:
  - name: Accuracy type: accuracy value: 90
- task: type: text-generation dataset: name: GPQA Diamond (pass@1) type: custom metrics:
  - name: Accuracy type: accuracy value: 83
- task: type: text-generation dataset: name: GPQA Diamond (pass@3) type: custom metrics:
  - name: Accuracy type: accuracy value: 86
- task: type: text-generation dataset: name: Terminal-Bench 2.0 type: custom metrics:
  - name: Pass Rate type: accuracy value: 25.8

OmniCoder-2-9B

The second generation of OmniCoder. Faster reasoning, dramatically less repetition, completely rebuilt training pipeline.

</div>

What's New in v2

OmniCoder-2-9B is a ground-up rebuild of OmniCoder-9B, not a continuation. The entire training pipeline was redesigned to fix the core issues users reported with v1:

No more repetition loops. v1 trained on ALL tokens (system prompts, tool outputs, templates), which taught the model to reproduce repetitive boilerplate. v2 trains only on assistant tokens. The model never learns to parrot templates, so it stays coherent through long multi-turn conversations.
Faster, more focused reasoning. v1's <think> blocks were often bloated and circular. v2 produces tighter reasoning chains that get to the point faster because it only learned from the actual reasoning, not the scaffolding around it.
Much more stable in agentic loops. v1 would sometimes get stuck in repetitive tool-call cycles. v2 handles multi-step agentic tasks cleanly. It knows when to stop, when to switch tools, and when to give a final answer.
Rebuilt training pipeline. Switched from all-token cosine-schedule training to assistant-only constant-LR training (based on Schulman's "LoRA Without Regret"). The model converges faster and doesn't suffer from premature LR decay that killed v1's learning.

TL;DR: OmniCoder-2-9B fixes the repetition and instability issues from v1. Same weights, same architecture, completely different training approach.

Benchmarks

| Benchmark | OmniCoder-2-9B | OmniCoder-9B | Qwen3.5-9B | GPT-OSS-120B | GLM 4.7 | Claude Haiku 4.5 | |:---|:---:|:---:|:---:|:---:|:---:|:---:| | AIME 2025 (pass@5) | 90 | 90 | 91.6 | | | | | GPQA Diamond (pass@1) | 83 | 83.8 | 81.7 | 71.5 | | 73 | | GPQA Diamond (pass@3) | 86 | 86.4 | | | | | | Terminal-Bench 2.0 | 25.8 | 23.6 | 14.6 | | 33.4 | 27 |

</div>

Key Results

GPQA Diamond pass@1: 83% (164/198). On par with OmniCoder-9B (83.8%) and Qwen3.5-9B base (81.7%). Pass@3 improves to 86%.
Terminal-Bench 2.0: 25.8% (23/89). +2.2 points over OmniCoder-9B (23.6%), +76% over Qwen3.5-9B base (14.6%).
AIME 2025 pass@5: 90% (27/30). Parity with OmniCoder-9B.

Quickstart

Transformers

from transformers import AutoModelForCausalLM, AutoTokenizer

model_id = "Tesslate/OmniCoder-2-9B"

tokenizer = AutoTokenizer.from_pretrained(model_id)
model = AutoModelForCausalLM.from_pretrained(model_id, torch_dtype="auto", device_map="auto")

messages = [
    {"role": "system", "content": "You are a helpful coding assistant."},
    {"role": "user", "content": "Write a Python function to find the longest common subsequence of two strings."},
]

text = tokenizer.apply_chat_template(messages, tokenize=False, add_generation_prompt=True)
inputs = tokenizer([text], return_tensors="pt").to(model.device)

outputs = model.generate(**inputs, max_new_tokens=2048, temperature=0.6, top_p=0.95, top_k=20)
print(tokenizer.decode(outputs[0][inputs.input_ids.shape[-1]:], skip_special_tokens=True))

vLLM

vllm serve Tesslate/OmniCoder-2-9B --tensor-parallel-size 1 --max-model-len 65536

from openai import OpenAI

client = OpenAI(base_url="http://localhost:8000/v1", api_key="token")
response = client.chat.completions.create(
    model="Tesslate/OmniCoder-2-9B",
    messages=[{"role": "user", "content": "Explain the difference between a mutex and a semaphore."}],
    temperature=0.6,
)
print(response.choices[0].message.content)

llama.cpp (GGUF)

llama-cli --hf-repo Tesslate/OmniCoder-2-9B-GGUF --hf-file omnicoder-2-9b-q4_k_m.gguf -p "Your prompt" -c 8192

Training Details

v1 vs v2 Pipeline

| | OmniCoder-9B (v1) | OmniCoder-2-9B (v2) | |:---|:---|:---| | Loss computed on | All tokens (system, user, tool, assistant) | Assistant tokens only | | LR schedule | Cosine (decayed to zero too early) | Constant with warmup | | EOS training | Global | Per-turn (train_on_eos: turn) | | Thinking blocks | Stripped by stock template | Preserved on all turns (custom Jinja2) | | Repetition | Frequent loops in generation | Near-zero | | Convergence | LR killed learning at step 60 | Clean convergence at step 80-100 |

Training Config

| | | |:---|:---| | Base Model | Qwen3.5-9B | | Method | LoRA SFT (r=64, alpha=32, all layers incl. MLP) | | Dataset | 425K agentic trajectories from 5 sources | | Loss | Assistant tokens only (roles_to_train: [assistant]) | | Sequence Length | 65,536 tokens (sample packing) | | LR Schedule | Constant with warmup (2e-4, 10 warmup steps) | | Hardware | 4x NVIDIA H200 (DDP) | | Framework | Axolotl | | Precision | bf16 | | Optimizer | AdamW (weight_decay=0.001) | | Effective Batch | 32 | | Steps | 350 (~10% of one epoch) |

Training Data Sources

| Source | Samples | Description | |:---|---:|:---| | NVIDIA Nemotron-Terminal-Corpus | 226K | Terminal agent trajectories | | CoderForge-Preview (reward >= 0.5) | 155K | SWE-bench style coding trajectories | | Nemotron Skill-Based | 24K | Skill-based coding tasks | | Scale-SWE | 20K | Real GitHub issue patches (synthesized trajectories) | | Opus Reasoning | 2.3K | Chain-of-thought reasoning |

Why Constant LR? (Schulman "LoRA Without Regret")

v1 used a cosine LR schedule over 80 steps. The learning rate decayed to zero by step 60, killing learning before the model converged. Loss appeared to plateau at 0.45 but was actually still dropping.

v2 follows Schulman et al.'s findings:

Constant LR. No decay, no premature convergence death.
LoRA LR ~10x FullFT. Our 2e-4 is correct for 9B-class models.
LoRA on ALL layers including MLP. Attention-only LoRA significantly underperforms.
Batch size 32. LoRA is less tolerant of large batches; 32 is the sweet spot.

Architecture

OmniCoder-2 inherits Qwen3.5-9B's hybrid architecture:

Gated Delta Networks. Linear attention layers interleaved with standard attention for efficient long-range dependencies.
VLM Backbone. Built on Qwen3_5ForConditionalGeneration.
262K Native Context. Full 262,144 token context window.

Recommended Sampling Parameters

| Parameter | Value | |:---|:---| | Temperature | 0.6 | | Top-P | 0.95 | | Top-K | 20 | | Presence Penalty | 0.0 |

For agentic / tool-calling tasks, consider lower temperature (0.2-0.4) for more deterministic behavior.

Limitations

Performance on non-English tasks has not been extensively evaluated
Tool-calling format is flexible but works best with the scaffolding patterns seen in training

Acknowledgments

Special thanks to the Axolotl team and the discussion in axolotl#3453 for helping get Qwen3.5 packing support working.

Citation

@misc{omnicoder2_2025,
  title={OmniCoder-2-9B: A Frontier Open Coding Agent},
  author={Tesslate},
  year={2025},
  url={https://huggingface.co/Tesslate/OmniCoder-2-9B}
}

Built by Tesslate

</div>

Author: Tesslate

Likes: 22

Downloads: 0

Tags: transformers, safetensors, qwen3_5, image-text-to-text, qwen3.5, code, agent, sft, omnicoder, tesslate, text-generation, conversational, en, base_model:Qwen/Qwen3.5-9B, base_model:finetune:Qwen/Qwen3.5-9B, license:apache-2.0, model-index, endpoints_compatible, region:us

allenai/MolmoWeb-8B-Native

license: apache-2.0 datasets:

allenai/MolmoWeb-SyntheticTraj
allenai/MolmoWeb-HumanTrajs
allenai/MolmoWeb-HumanSkills
allenai/MolmoWeb-SyntheticSkills
allenai/MolmoWeb-SyntheticQA
allenai/MolmoWeb-SyntheticGround language:
en base_model:
Qwen/Qwen3-8B
google/siglip-so400m-patch14-384 pipeline_tag: image-text-to-text library_name: transformers tags:
multimodal
olmo
molmo
molmo2

MolmoWeb-8B-Native

Note that this is the molmo-native checkpoint, and it's NOT Huggingface/transformers-compatible. Check out allenai/MolmoWeb-8B for HF-compatible checkpoint.

MolmoWeb is a family of fully open multimodal web agents. MolmoWeb agents achieve state-of-the-art results outperforming similar scale open-weight-only models such as Fara-7B, UI-Tars-1.5-7B, and Holo1-7B. MolmoWeb-8B also surpasses set-of-marks (SoM) agents built on much larger closed frontier models like GPT-4o. We further demonstrate consistent gains through test-time scaling via parallel rollouts with best-of-N selection, achieving 94.7% and 60.5% pass@4 (compared to 78.2% and 35.3% pass@1)on WebVoyager and Online-Mind2Web respectively.

Learn more about the MolmoWeb family in our announcement blog post and tech report.

MolmoWeb-8B-Native is based on Molmo2 architecture, which uses Qwen3-8B and SigLIP 2 as vision backbone.

Ai2 is committed to open science. The MolmoWeb datasets are available here. All other artifacts used in creating MolmoWeb (training code, evaluations, intermediate checkpoints) will be made available, furthering our commitment to open-source AI development and reproducibility.

Quick links:

💬 Demo
📂 All Models
📚 All Data
📃 Paper
🎥 Blog with Videos

Usage

Please refer to our Github repo for inference code.

License and Use

This model is licensed under Apache 2.0. It is intended for research and educational use in accordance with Ai2’s Responsible Use Guidelines.

Author: allenai

Likes: 6

Downloads: 0

Tags: transformers, multimodal, olmo, molmo, molmo2, image-text-to-text, en, dataset:allenai/MolmoWeb-SyntheticTraj, dataset:allenai/MolmoWeb-HumanTrajs, dataset:allenai/MolmoWeb-HumanSkills, dataset:allenai/MolmoWeb-SyntheticSkills, dataset:allenai/MolmoWeb-SyntheticQA, dataset:allenai/MolmoWeb-SyntheticGround, arxiv:2601.10611, base_model:Qwen/Qwen3-8B, base_model:finetune:Qwen/Qwen3-8B, license:apache-2.0, endpoints_compatible, region:us

Jackrong/Qwen3.5-9B-Neo

language:

en
zh license: apache-2.0 base_model: Qwen/Qwen3.5-9B tags:
unsloth
qwen
qwen3.5
reasoning
chain-of-thought
lora
competitive-programming pipeline_tag: text-generation datasets:
Jackrong/Competitive-Programming-python-blend
stepfun-ai/Step-3.5-Flash-SFT

🌟 Jackrong/Qwen3.5-9B-Neo

📢 Announcement

Neo Update: This iteration focuses extensively on achieving meaningful gains in reasoning and mathematical performance while maintaining competitive general accuracy.

Neo introduces a highly optimized reasoning scaffold designed to eliminate redundant internal loops and circular reasoning. Unlike standard models that simply think longer when faced with difficult tasks, Neo is built to think smarter, not longer. Evaluated on the LM Evaluation Harness leaderboard suite, it delivers notable improvements in BBH (+0.87 pp), MATH Hard (+0.98 pp), and MUSR (+2.91 pp) — the benchmarks that most directly probe structured multi-step reasoning and logical deduction.

💡 Model Introduction

Jackrong/Qwen3.5-9B-Neo is a reasoning-focused fine-tune of the Qwen3.5-9B model. Its primary objective is to improve the quality of chain-of-thought generation, with a particular focus on harder reasoning and mathematical tasks, while remaining broadly competitive across general academic benchmarks.

The goal of this Neo model is not simply to make the model "think more," but to help it think more structuredly: eliminating unnecessary verbose over-analysis, anchoring intermediate steps, and improving multi-hop logical consistency. Based on the LM Eval Harness leaderboard evaluation (conducted by community member selimaktas), the 9B-Neo achieves improvements on three of the four sub-benchmarks — BBH, MATH Hard, and MUSR — with a notable +2.91 pp gain on MUSR (multi-step reasoning under uncertainty) and +0.98 pp on MATH Hard.

LM Eval Harness Benchmark Results 🪐

Screenshot 2026-03-25 at 12.01.47 AM

Screenshot 2026-03-25 at 12.04.03 AM

Screenshot 2026-03-24 at 11.46.19 PM

| Group / Task | Metric | Qwen3.5-9B | Qwen3.5-9B-Neo | Δ | |---|---|---|---|---| | leaderboard_bbh | acc_norm ↑ | 0.6190 | 0.6277 | +0.87 pp | | leaderboard_gpqa | acc_norm ↑ | 0.4446 | 0.4136 | −3.10 pp | | leaderboard_math_hard | exact_match ↑ | 0.3965 | 0.4063 | +0.98 pp | | leaderboard_musr | acc_norm ↑ | 0.4339 | 0.4630 | +2.91 pp |

📌 Note on IFEval: The instruction-following metrics (IFEval prompt/inst level) show a regression in this version. This is a known trade-off from the current training pipeline's emphasis on structured reasoning over format-following, and will be an area of focus in future iterations.

Evaluation conducted by community member selimaktas using the LM Evaluation Harness framework. March 2026.

🗺️ Training Pipeline Overview

Base Model (Qwen/Qwen3.5-9B)
 │
 ▼
Qwen3.5-9B fine-tuned with Unsloth
 │
 ▼
Supervised Fine-Tuning (SFT) + LoRA
(Response-Only Training masked on "<|im_start|>assistant\n<think>")
 │
 ▼
Jackrong/Qwen3.5-9B-Neo

🧠 Example of Learned Reasoning Scaffold

Through robust data cleaning and formatting, the model was conditioned to explicitly structure its thought processes inside <think>...</think> tags before emitting the final answer. This forces the model to methodically break down complex programming or logical problems without repetitive thoughts.

<|im_start|>user
[User Query here]<|im_end|>
<|im_start|>assistant
<think>
    ...
</think>
[Final concise and accurate answer]

📚 All Datasets Used

The dataset consists of high-quality, filtered reasoning distillation data merged during the pipeline. Our pipeline dynamically sampled and structured conversations, strictly maintaining the intended layout.

stepfun-ai/Step-3.5-Flash-SFT
Jackrong/Competitive-Programming-python-blend (A custom curated blend specifically for Python competitive programming and logic).

Detailed breakdown of the Competitive-Programming-python-blend:

| Source | Role in the Blend | |--------|-------------------| | nohurry/Opus-4.6-Reasoning-3000x-filtered | Reasoning-heavy synthetic SFT data | | Jackrong/Qwen3.5-reasoning-700x | Distilled reasoning and instruction-following data | | nvidia/Nemotron-SFT-Competitive-Programming-v2 (competitive_coding_python) | Primary Python competitive-programming supervision | | nvidia/Nemotron-SFT-Competitive-Programming-v2 (competitive_coding_cpp) | Small cross-language competitive-programming supplement | | nvidia/Nemotron-SFT-SWE-v2 (agentless) | Lightweight agentless SWE-style supervision | | nvidia/Nemotron-SFT-Instruction-Following-Chat-v2 (reasoning_on) | Small reasoning-oriented chat supplement |

⚠️ Limitations & Intended Use

Instruction Following Regression: This version shows reduced IFEval scores compared to the base model, reflecting the current pipeline's trade-off toward structured reasoning over rigid format compliance. This will be addressed in future iterations.
Hallucination Risk: While reasoning is strong, the model remains an autoregressive LLM; external facts provided during the thinking sequence may occasionally contain hallucinations if verifying real-world events.
Context Boundaries: In rare cases of extremely complex logic where the model struggles to converge, it may exhibit truncation events from excessive circular thinking.
Intended Scenario: Best suited for offline analytical tasks, coding, competitive programming, math, and heavy logic-dependent prompting where the user needs to transparently follow the AI's internal logic with high token efficiency.
This model is a test version intended solely for learning and demonstration purposes, and is for academic research and technical exploration use only.

🙏 Acknowledgements

Significant thanks to the Unsloth AI team for making rapid fine-tuning of large LLM models accessible. Additionally, we acknowledge Qwen internally, and the open-source community developers producing exceptional distilled datasets. Special thanks to selimaktas for conducting the LM Eval Harness benchmark evaluation.

Author: Jackrong

Likes: 6

Downloads: 48

Tags: safetensors, qwen3_5, unsloth, qwen, qwen3.5, reasoning, chain-of-thought, lora, competitive-programming, text-generation, conversational, en, zh, dataset:Jackrong/Competitive-Programming-python-blend, dataset:stepfun-ai/Step-3.5-Flash-SFT, base_model:Qwen/Qwen3.5-9B, base_model:adapter:Qwen/Qwen3.5-9B, license:apache-2.0, region:us

Tesslate/OmniCoder-2-9B-GGUF

base_model: Tesslate/OmniCoder-2-9B tags:

llama-cpp
gguf
qwen3.5
omnicoder
tesslate
code
agent license: apache-2.0

OmniCoder-9B-GGUF

GGUF quantizations of OmniCoder-9B

</div>

Available Quantizations

| Quantization | Size | Use Case | |:---|---:|:---| | Q2_K | ~3.8 GB | Extreme compression, lowest quality | | Q3_K_S | ~4.3 GB | Small footprint | | Q3_K_M | ~4.6 GB | Small footprint, balanced | | Q3_K_L | ~4.9 GB | Small footprint, higher quality | | Q4_0 | ~5.3 GB | Good balance | | Q4_K_S | ~5.4 GB | Good balance | | Q4_K_M | ~5.7 GB | Recommended for most users | | Q5_0 | ~6.3 GB | High quality | | Q5_K_S | ~6.3 GB | High quality | | Q5_K_M | ~6.5 GB | High quality, balanced | | Q6_K | ~7.4 GB | Near-lossless | | Q8_0 | ~9.5 GB | Highest quality quantization | | BF16 | ~17.9 GB | Full precision |

Usage

# Install llama.cpp
brew install llama.cpp  # macOS
# or build from source: https://github.com/ggml-org/llama.cpp

# Interactive chat
llama-cli --hf-repo Tesslate/OmniCoder-2-9B-GGUF --hf-file omnicoder-9b-q4_k_m.gguf -p "Your prompt" -c 8192

# Server mode (OpenAI-compatible API)
llama-server --hf-repo Tesslate/OmniCoder-2-9B-GGUF --hf-file omnicoder-9b-q4_k_m.gguf -c 8192

Built by Tesslate | See full model card: OmniCoder-9B

</div>

Author: Tesslate

Likes: 3

Downloads: 0

Tags: gguf, llama-cpp, qwen3.5, omnicoder, tesslate, code, agent, base_model:Tesslate/OmniCoder-2-9B, base_model:quantized:Tesslate/OmniCoder-2-9B, license:apache-2.0, endpoints_compatible, region:us, conversational

elix3r/LTX-2.3-22b-AV-LoRA-talking-head

license: openrail base_model: Lightricks/LTX-2.3 tags:

lora
ltx-video
talking-head
video-generation
audio-visual
ltx-2-3
ltx-2 language:
en pipeline_tag: image-to-video library_name: diffusers

elix3r/LTX-2.3-22b-AV-LoRA-talking-head

Overview

This is the first community audio-visual (AV) LoRA for LTX-Video 2.3, trained using the joint audio-video cross-attention architecture of the LTX-2.3 22B model. The LoRA enables talking head video generation with synchronized lip sync and internalized voice characteristics from a reference character.

This release is a character-specific implementation and reference pipeline. The weights demonstrate a working AV LoRA trained on a custom dataset. The methodology, dataset structure, caption format, and training config are fully documented and reusable for training your own character-specific AV LoRA.

What It Does

Generates talking head videos with synchronized lip sync from a reference image
Internalizes voice characteristics without requiring external audio input at inference time
Preserves character identity across unseen reference images and backgrounds

Demo Results (v1)

Lip sync: accurate and consistent
Identity preservation: locks in at step 1250, improves linearly to step 2000
Voice characteristics: internalized from training data
Known limitations: slight audio buzz artifacts, occasional eye blinking inconsistency, seed-dependent output quality

How To Use

Requirements

ComfyUI Workflow (examples)
LTX-2.3 Model
Power Lora Loader node

Loading the LoRA

Load LTX-2.3-22b-AV-LoRA-talking-head-v1.safetensors via the Power Lora Loader node in ComfyUI.

Set LoRA strength to 1.0.

Recommended Inference Settings

| Parameter | Value | |-----------|-------| | Resolution | 1280x736 | | FPS | 24 | | Video length | Any (10+ seconds recommended) | | LoRA strength | 1.0 | | Trigger word | OHWXPERSON | | CFG scale | 1.0 |

Note: 1280x736 @ 24fps is recommended for image-to-video inference. For image + audio to video inference, use 1280x704 @ 25fps to match the training distribution.

Prompt Format

Include the trigger word OHWXPERSON and end the prompt with the speech transcript:

OHWXPERSON, [visual description]. The person is talking, and he says: "[transcript]"

Training Your Own AV LoRA

This section documents the full pipeline so you can train a character-specific AV LoRA for your own subject.

Pipeline Overview

Reference Images
      |
      v
Flux.1 Kontext / Flux.2 Klein     -- Image generation
      |
      v
Fish Audio S2 Pro                 -- Voice cloning + TTS
      |
      v
LTX-Video 2.3                     -- Talking head video generation
      |
      v
LTX-2 trainer                     -- AV LoRA training
      |
      v
Trained AV LoRA weights

Step 1 -- Generate Reference Images

Use Flux Kontext in ComfyUI to generate consistent reference images of your character across varied poses, angles, lighting conditions, and expressions.

[KONTEXT WORKFLOW]

Key settings used in this project:

Flux Kontext dev Q6_K GGUF
Sampler: res_3s + res_2m (RES4LYF)
FluxGuidance: 1
denoise: 1

Step 2 -- Clone the Voice

Use Fish Audio S2 Pro (model) with a 10-15 second reference audio clip of your target voice. Supports [pause], [short pause], and [emphasis] tags for pacing control.

Generate TTS audio for each clip's script using the cloned voice.

Step 3 -- Generate Training Clips

Use LTX-2.3 in ComfyUI to generate talking head clips from your reference images.

[LTX-2.3 IMAGE + AUDIO TO VIDEO WORKFLOW]

Dataset requirements:

25-30 clips minimum
Resolution: 1280x704
FPS: 25
Length: 6-10 seconds per clip after trimming
Variety: front facing, 3/4 angles, side profile, different backgrounds, multiple emotions

Prompt format for each clip:

[scene description]. Mouth partially open during speech with only the front teeth partially visible, lips moving naturally without fully exposing all teeth. Smooth continuous motion, cinematic, realistic, sharp focus on subject. The person is talking, and he says: "[transcript]"

Background complexity directly impacts lip sync quality. Simple and dark backgrounds produce the best results. Complex backgrounds with many competing elements reduce lip sync accuracy.

Step 4 -- Prepare the Dataset

Structure your dataset folder as follows:

ohwxperson_dataset_v1/
  clip_001.mp4          # video with embedded audio from LTX-2.3
  clip_002.mp4
  ...
  CAPTIONS.json

Caption format in CAPTIONS.json:

{
  "captions": [
    {
      "file": "clip_001.mp4",
      "caption": "[VISUAL] OHWXPERSON, [visual description of scene, pose, clothing, background]. [SPEECH] OHWXPERSON speaks in a [voice description]: \"[exact transcript]\""
    }
  ]
}

A reference CAPTIONS.json from this project is included in this repository.

Step 5 -- Train with ltx-trainer

Recommended training configuration:

model:
  model_path: ltx-2.3-22b-dev.safetensors
  text_encoder_path: gemma
  training_mode: lora

lora:
  rank: 32
  alpha: 32
  target_modules: [to_k, to_q, to_v, to_out.0]

training_strategy:
  name: text_to_video
  with_audio: true
  first_frame_conditioning_p: 0.5

optimization:
  steps: 2000
  learning_rate: 1.0e-04
  batch_size: 1
  gradient_accumulation_steps: 1
  optimizer_type: adamw
  scheduler_type: linear
  mixed_precision_mode: bf16
  enable_gradient_checkpointing: true

validation:
  interval: 250
  inference_steps: 30
  guidance_scale: 4.0

Training Details

| Parameter | Value | |-----------|-------| | Base model | LTX-Video 2.3 22B | | Training mode | LoRA | | LoRA rank | 32 | | LoRA alpha | 32 | | Steps | 2000 | | Learning rate | 1e-4 | | Batch size | 1 | | Mixed precision | bf16 | | Dataset size | 26 clips | | Peak VRAM usage | 77.08 GB | | Training time | ~7.8 hours | | Training cost | ~$5.33 (GCP Spot G4 instance, RTX PRO 6000 96GB) | | Identity lock | Step 1250 |

Known Limitations (v1)

Slight audio buzz artifacts present in outputs
Eye blinking occasionally inconsistent (can be fixed by manual prompting)
Output quality is seed dependent -- sweep 3-5 seeds per generation
Character-specific weights -- lip sync and voice are tied to the trained character
Best results at 1280x736 @ 24fps

v2 Roadmap

Audio preprocessing with MelBand Roformer before training to eliminate buzz artifacts
Explicit eye blinking captions and dedicated blinking clips in dataset
Extended training to 2500-3000 steps
Larger and more diverse dataset

Files

| File | Description | |------|-------------| | LTX-2.3-22b-AV-LoRA-talking-head-v1.safetensors | Final trained LoRA weights (v1) | | CAPTIONS.json | Reference caption file for dataset structure | | ohwxperson_av_lora.yaml | Full training configuration | | flux_kontext_clownsharkextended.json | Flux Kontext workflow for generating reference images | | LTX-2-3-I2V.json | LTX-Video 2.3 Image to Video workflow | | LTX-2-3-I2V-Custom-Audio.json | LTX-Video 2.3 Image + Custom Audio to Video workflow |

Citation

If you use this model or methodology in your work, please credit this repository.

License

The LoRA weights are released for research and personal use. Commercial use requires separate permission.

Author: elix3r

Likes: 3

Downloads: 0

Tags: diffusers, lora, ltx-video, talking-head, video-generation, audio-visual, ltx-2-3, ltx-2, image-to-video, en, base_model:Lightricks/LTX-2.3, base_model:adapter:Lightricks/LTX-2.3, license:openrail, region:us

alvdansen/illustration-1.0-flux-dev

language:

en library_name: peft base_model: black-forest-labs/FLUX.1-dev tags:
flux
lora
illustration
anime
style
text-to-image
bande-dessinee
graphic-novel
risograph license: other

Alvdansen Illustration 1.0 - Flux Dev

A style LoRA for FLUX.1-dev trained on 244 curated illustration and anime reference images across diverse visual styles. Produces images spanning cute anime character design, European bande dessinee, indie risograph prints, storybook watercolor, retro shoujo manga, and graphic novel illustration.

Style Influences

Japanese anime and manga illustration -- clean cel shading, expressive character design, shoujo and slice-of-life aesthetics
European graphic novel and bande dessinee -- ink crosshatching, atmospheric landscapes, ligne claire
Indie illustration and zine culture -- risograph print textures, limited palettes, grainy halftone
Children's book and storybook illustration -- watercolor washes, warm palettes, charming character proportions
Retro anime aesthetics -- 80s/90s anime film stills, VHS grain, bold color blocking
Concept art and character design -- flat color fills, turnaround sheets, fashion illustration

Usage

No trigger word -- this is a style LoRA. Describe what you want and add style cues like "ink and watercolor", "clean cel shading", "risograph print" to steer the output.

Recommended Inference Settings

Sampler: dpmpp_2m
Scheduler: sgm_uniform
CFG: 1.0
Steps: 35 (20-50 works well)
LoRA strength: 0.8-1.0

Sample Generations

"close-up, a girl with short messy silver hair and round glasses, wearing a chunky knit turtleneck sweater, one hand tucking hair behind her ear, looking slightly past the viewer with half-closed eyes, anime style" -- 50 steps

"a girl with short hair in a bomber jacket leaning against a wall, clean cel shading, bold graphic composition, 90s ranma era anime, film grain" -- 35 steps

"a knight on horseback crossing a stone bridge, european bande dessinee, fine ink crosshatching, muted sage and ochre palette, atmospheric perspective" -- 50 steps

"a fox sleeping in a hollowed-out log, children's book watercolor, soft wet-on-wet washes, autumn leaf palette" -- 35 steps

"a wanderer approaching a stone gate in the desert, european graphic novel, detailed ink hatching, warm sand tones" -- 35 steps

"portrait, a girl with star-shaped hair clips, bold graphic shapes, limited three-color palette, screen print flatness, harajuku fashion illustration" -- 35 steps

"a cat wearing a tiny cape perched on a fence post, indie risograph print, two-color teal and coral, grainy paper texture" -- 50 steps

"an astronaut sitting on a rocky surface with a small robot, retro watercolor, warm olive and cream tones, hand-painted feel" -- 35 steps

"wide shot, a girl on a bicycle coasting downhill, ghibli film still, clean cel shading, golden hour warmth, anime style lofi" -- 35 steps

"wide shot, a lone figure on a cliff overlooking the sea with seagulls, bande dessinee, fine ink hatching, muted blue-gray" -- 35 steps

"wide shot, an abandoned greenhouse overgrown with wildflowers and ferns, glass panels cracked and missing, a rusty bicycle leaning against a broken door, afternoon sunlight streaming through the gaps" -- 35 steps

"portrait, a girl with flowers growing from her hair, risograph print, three-color pink blue and cream, grainy texture" -- 35 steps

"a dragon curled around a lighthouse, detailed ink linework, teal and coral duotone, screen print aesthetic" -- 35 steps

"two kids running through tall grass at sunset, loose ink and flat color, dusty pink sky, over the garden wall aesthetic" -- 35 steps

"a girl with short hair in a bomber jacket leaning against a wall, clean cel shading, bold graphic composition, pink and black, 90s anime, film grain" -- 35 steps

"profile view, a woman with flowers braided into her hair, art nouveau linework, flowing organic curves, muted sage and gold" -- 20 steps

"wide shot, a lighthouse keeper climbing spiral stairs, bande dessinee vertical panel, detailed architectural perspective, steel blue monochrome" -- 50 steps

"a lone traveler on horseback crossing a vast desert plain toward enormous turquoise crystal pillars rising from the sand, a ringed planet low on the horizon, long shadows stretching across the dunes" -- 35 steps

"a girl with headphones sitting on a rooftop water tank, 90s anime screenshot, soft cel shading, hazy pink sunset" -- 60 steps

Training Details

Base model: FLUX.1-dev (8-bit quantized)
Training steps: 53,500
Rank/Alpha: 42/42
Learning rate: 5e-5
Optimizer: AdamW 8-bit
Caption dropout: 0.35
EMA: enabled (decay 0.99)
Dataset: 244 curated images across 4 subsets, trained sequentially then consolidated on the full dataset
Trainer: ai-toolkit by Ostris

Author: alvdansen

Likes: 3

Downloads: 0

Tags: peft, flux, lora, illustration, anime, style, text-to-image, bande-dessinee, graphic-novel, risograph, en, base_model:black-forest-labs/FLUX.1-dev, base_model:adapter:black-forest-labs/FLUX.1-dev, license:other, region:us

ReadyArt/Omega-Evolution-9B-v1.0

base_model:

Qwen/Qwen3.5-9B base_model_relation: finetune tags:
nsfw
explicit
roleplay
unaligned
dangerous
ERP
Other License license: apache-2.0

Author: ReadyArt

Likes: 3

Downloads: 0

Tags: safetensors, qwen3_5, nsfw, explicit, roleplay, unaligned, dangerous, ERP, Other License, base_model:Qwen/Qwen3.5-9B, base_model:finetune:Qwen/Qwen3.5-9B, license:apache-2.0, region:us

LocalDoc/LocRet-small

language:

az license: apache-2.0 tags:
sentence-transformers
feature-extraction
sentence-similarity
retrieval
azerbaijani
embedding library_name: sentence-transformers pipeline_tag: sentence-similarity datasets:
LocalDoc/msmarco-az-reranked
LocalDoc/azerbaijani_retriever_corpus-reranked
LocalDoc/ldquad_v2_retrieval-reranked
LocalDoc/azerbaijani_books_retriever_corpus-reranked base_model: intfloat/multilingual-e5-small model-index:
name: LocRet-small results:
- task: type: retrieval dataset: name: AZ-MIRAGE type: custom metrics:
  - type: mrr@10 value: 0.5250
  - type: ndcg@10 value: 0.6162
  - type: recall@10 value: 0.8948

LocRet-small — Azerbaijani Retrieval Embedding Model

LocRet-small is a compact, high-performance retrieval embedding model specialized for the Azerbaijani language. Despite being 4.8× smaller than BGE-m3, it significantly outperforms it on Azerbaijani retrieval benchmarks.

Key Results

AZ-MIRAGE Benchmark (Native Azerbaijani Retrieval)

| Rank | Model | Parameters | MRR@10 | P@1 | R@5 | R@10 | NDCG@5 | NDCG@10 | |:----:|:------|:---------:|:------:|:---:|:---:|:----:|:------:|:-------:| | #1 | LocRet-small | 118M | 0.5250 | 0.3132 | 0.8267 | 0.8948 | 0.5938 | 0.6162 | | #2 | BAAI/bge-m3 | 568M | 0.4204 | 0.2310 | 0.6905 | 0.7787 | 0.4791 | 0.5079 | | #3 | perplexity-ai/pplx-embed-v1-0.6b | 600M | 0.4117 | 0.2276 | 0.6715 | 0.7605 | 0.4677 | 0.4968 | | #4 | intfloat/multilingual-e5-large | 560M | 0.4043 | 0.2264 | 0.6571 | 0.7454 | 0.4584 | 0.4875 | | #5 | intfloat/multilingual-e5-base | 278M | 0.3852 | 0.2116 | 0.6353 | 0.7216 | 0.4390 | 0.4672 | | #6 | Snowflake/snowflake-arctic-embed-l-v2.0 | 568M | 0.3746 | 0.2135 | 0.6006 | 0.6916 | 0.4218 | 0.4516 | | #7 | Qwen/Qwen3-Embedding-4B | 4B | 0.3602 | 0.1869 | 0.6067 | 0.7036 | 0.4119 | 0.4437 | | #8 | intfloat/multilingual-e5-small (base) | 118M | 0.3586 | 0.1958 | 0.5927 | 0.6834 | 0.4079 | 0.4375 | | #9 | Qwen/Qwen3-Embedding-0.6B | 600M | 0.2951 | 0.1516 | 0.4926 | 0.5956 | 0.3339 | 0.3676 |

Usage

from sentence_transformers import SentenceTransformer

model = SentenceTransformer("LocalDoc/LocRet-small")

queries = ["query: Azərbaycanın paytaxtı hansı şəhərdir?"]
passages = [
    "passage: Bakı Azərbaycan Respublikasının paytaxtı və ən böyük şəhəridir.",
    "passage: Gəncə Azərbaycanın ikinci böyük şəhəridir.",
]

query_embeddings = model.encode(queries)
passage_embeddings = model.encode(passages)

similarities = model.similarity(query_embeddings, passage_embeddings)
print(similarities)

Important: Always use "query: " prefix for queries and "passage: " prefix for documents.

Training

Method

LocRet-small is fine-tuned from multilingual-e5-small using listwise KL distillation combined with a contrastive loss:

$$\mathcal{L} = \mathcal{L}{\text{KL}} + 0.1 \cdot \mathcal{L}{\text{InfoNCE}}$$

Listwise KL divergence: Distills the ranking distribution from a cross-encoder teacher (bge-reranker-v2-m3) over candidate lists of 1 positive + up to 10 hard negatives per query. Teacher and student softmax distributions use asymmetric temperatures (τ_teacher = 0.3, τ_student = 0.05).
In-batch contrastive loss (InfoNCE): Provides additional diversity through in-batch negatives on positive passages.

This approach preserves the full teacher ranking signal rather than reducing it to binary relevance labels, which is critical for training on top of already strong pre-trained retrievers.

Data

The model was trained on approximately 3.5 million Azerbaijani query-passage pairs from four datasets:

| Dataset | Pairs | Domain | Type | |:--------|------:|:-------|:-----| | msmarco-az-reranked | ~1.4M | General web QA | Translated EN→AZ | | azerbaijani_books_retriever_corpus-reranked | ~1.6M | Books, politics, history | Native AZ | | azerbaijani_retriever_corpus-reranked | ~189K | News, culture | Native AZ | | ldquad_v2_retrieval-reranked | ~330K | Wikipedia QA | Native AZ |

All datasets include hard negatives scored by a cross-encoder reranker, which serve as the teacher signal for listwise distillation. False negatives were filtered using normalized score thresholds.

Hyperparameters

| Parameter | Value | |:----------|:------| | Base model | intfloat/multilingual-e5-small | | Max sequence length | 512 | | Effective batch size | 256 | | Learning rate | 5e-5 | | Schedule | Linear warmup (5%) + cosine decay | | Precision | FP16 | | Epochs | 1 | | Training time | ~25 hours | | Hardware | 4× NVIDIA RTX 5090 (32GB) |

Training Insights

Listwise KL distillation outperforms standard contrastive training (MultipleNegativesRankingLoss) for fine-tuning pre-trained retrievers, consistent with findings from Arctic-Embed 2.0 and cadet-embed.
Retrieval pre-training matters more than language-specific pre-training for retrieval tasks: multilingual-e5-small (with retrieval pre-training) significantly outperforms XLM-RoBERTa and other BERT variants (without retrieval pre-training) as a base model.
A mix of translated and native data prevents catastrophic forgetting while enabling language specialization.

Benchmark

AZ-MIRAGE

A native Azerbaijani retrieval benchmark (https://github.com/LocalDoc-Azerbaijan/AZ-MIRAGE) with 7,373 queries and 40,448 document chunks covering diverse topics. Evaluates retrieval quality on naturally written Azerbaijani text.

Model Details

| Property | Value | |:---------|:------| | Architecture | BERT (XLM-RoBERTa) | | Parameters | 118M | | Embedding dimension | 384 | | Max tokens | 512 | | Vocabulary | SentencePiece (250K) | | Similarity function | Cosine similarity | | Language | Azerbaijani (az) | | License | Apache 2.0 |

Limitations

Optimized for Azerbaijani text retrieval. Performance on other languages may be lower than the base multilingual-e5-small model.
Requires "query: " and "passage: " prefixes for optimal performance.
Maximum input length is 512 tokens. Longer documents should be chunked.

Citation

@misc{locret-small-2026,
  title={LocRet-small: A Compact Azerbaijani Retrieval Embedding Model},
  author={LocalDoc},
  year={2026},
  url={https://huggingface.co/LocalDoc/LocRet-small}
}

Acknowledgments

Base model: intfloat/multilingual-e5-small
Teacher reranker: BAAI/bge-reranker-v2-m3
Training methodology inspired by Arctic-Embed 2.0 and cross-encoder listwise distillation research.

Author: LocalDoc

Likes: 2

Downloads: 0

Tags: sentence-transformers, safetensors, bert, feature-extraction, sentence-similarity, retrieval, azerbaijani, embedding, az, dataset:LocalDoc/msmarco-az-reranked, dataset:LocalDoc/azerbaijani_retriever_corpus-reranked, dataset:LocalDoc/ldquad_v2_retrieval-reranked, dataset:LocalDoc/azerbaijani_books_retriever_corpus-reranked, arxiv:2412.04506, arxiv:2505.19274, base_model:intfloat/multilingual-e5-small, base_model:finetune:intfloat/multilingual-e5-small, license:apache-2.0, model-index, text-embeddings-inference, endpoints_compatible, region:us

Naphula/Goetia-24B-v1.4

Author: Naphula

Likes: 2

Downloads: 0

Tags: safetensors, mistral, region:us

adamjen/Devstral-Small-2-24B-Opus-Reasoning

license: apache-2.0 base_model: mistralai/Devstral-Small-2-24B-Instruct-2512 datasets:

nohurry/Opus-4.6-Reasoning-3000x-filtered language:
en tags:
mistral
ministral3
code
reasoning
lora
gguf
unsloth
knowledge-distillation pipeline_tag: text-generation

Devstral-Small-2-24B Opus Reasoning

A LoRA fine-tune of Devstral-Small-2-24B distilled on Claude 4.6 Opus <think>...</think> reasoning traces. The goal: give Devstral's strong coding foundation explicit chain-of-thought reasoning before it writes code.

Model Details

| | | |---|---| | Base model | mistralai/Devstral-Small-2-24B-Instruct-2512 | | Fine-tune type | QLoRA (4-bit NF4 base + BF16 LoRA adapters) | | LoRA rank | r=16, alpha=16 | | Target modules | q_proj, k_proj, v_proj, o_proj, gate_proj, up_proj, down_proj | | Training data | nohurry/Opus-4.6-Reasoning-3000x-filtered (2,322 samples) | | Checkpoint used | checkpoint-1200 (end of epoch 2 — best generalisation) | | Hardware | RTX 3090 24GB VRAM | | Framework | Unsloth 2026.3.10 + TRL SFTTrainer | | Sequence length | 2048 |

Files

| File | Description | |---|---| | adapter_model.safetensors | LoRA adapter weights (~400MB) | | adapter_config.json | LoRA config (rank, target modules, base model path) | | Devstral-Small-2-24B-Opus-Reasoning.Q4_K_M.gguf | Quantised GGUF — ready for llama.cpp / Ollama / llama-swap | | Devstral-Small-2-24B-Opus-Reasoning.Q5_K_M.gguf | Higher quality GGUF — recommended for local use |

Training Data

nohurry/Opus-4.6-Reasoning-3000x-filtered — 2,324 problems with Claude 4.6 Opus <think> reasoning traces and solutions, filtered to < 20,000 characters combined length.

Each sample was formatted as:

[INST] {problem} [/INST]<think>
{thinking}
</think>

{solution}

Loss was computed on the assistant turn only (train_on_responses_only).

Training Loss

| Step | Epoch | Loss | |------|-------|------| | 5 | 0.01 | 0.7949 | | 100 | 0.17 | 0.5708 | | 300 | 0.52 | 0.5800 | | 600 | 1.03 | 0.3559 | | 900 | 1.55 | 0.3858 | | 1100 | 1.89 | 0.3469 | | 1160 | 2.00 | 0.3752 | | 1200 | 2.07 | 0.1493 |

Checkpoint 1200 (end of epoch 2) was selected over the full epoch 3 run — for reasoning distillation tasks, epoch 3 typically overfits to the trace style while epoch 2 gives the best generalisation.

Usage

GGUF (llama.cpp / Ollama / llama-swap)

Download Devstral-Small-2-24B-Opus-Reasoning.Q5_K_M.gguf for best quality, or Devstral-Small-2-24B-Opus-Reasoning.Q4_K_M.gguf if VRAM is tight.

# llama.cpp
./llama-cli -m unsloth.Q5_K_M.gguf \
  --chat-template mistral \
  -p "[INST] Write a Python function to find all prime numbers up to n using a sieve. [/INST]"

LoRA Adapter (Python)

Requires the base model. Because Devstral is a VLM (Pixtral vision encoder), the easiest path is the text-only extracted weights — see the technical notes below.

import torch
from unsloth import FastLanguageModel
from peft import PeftModel

base_model_path = "path/to/Devstral-Small-2-24B-textonly"  # see notes
adapter_path    = "adamjen/Devstral-Small-2-24B-Opus-Reasoning"

model, tokenizer = FastLanguageModel.from_pretrained(
    model_name     = base_model_path,
    max_seq_length = 2048,
    dtype          = torch.bfloat16,
    load_in_4bit   = True,
)
model = PeftModel.from_pretrained(model, adapter_path)

messages = [{"role": "user", "content": "Write a binary search in Python."}]
text = tokenizer.apply_chat_template(messages, tokenize=False, add_generation_prompt=True)
inputs = tokenizer(text, return_tensors="pt").to("cuda")

outputs = model.generate(**inputs, max_new_tokens=2048, temperature=0.7)
print(tokenizer.decode(outputs[0], skip_special_tokens=True))

Chat Template

This model uses Mistral's [INST]...[/INST] format. The model will produce a <think>...</think> block before its response.

[INST] Your question here [/INST]<think>
... reasoning ...
</think>

... answer ...

Technical Notes: The Devstral Extraction Problem

Devstral-Small-2-24B ships as a Mistral3ForConditionalGeneration (VLM) with a Pixtral vision encoder. Training it as a text-only model on a single 24GB GPU hits several problems:

FP8 weights: The official instruct release uses FP8 quantisation, which requires compute capability ≥ 8.9. RTX 3090 is 8.6 — incompatible. Requires dequantising to BF16 first.
Vision encoder VRAM: The Pixtral encoder consumes ~4GB VRAM, leaving insufficient headroom for 4-bit QLoRA + gradients.
Device map splitting: With a VLM loaded via device_map="auto", accelerate splits layers across GPU/CPU, breaking distributed training mode.
transformers 5.x concurrent loader: The async tensor loader materialises all BF16 tensors simultaneously before quantisation → OOM. Fix: HF_DEACTIVATE_ASYNC_LOAD=1.

Solution: Extract the Ministral3ForCausalLM language layers into a standalone text-only model directory (stripping vision_tower.* and multi_modal_projector.*, renaming language_model.model.* → model.*). This produces a clean 23B causal LM loadable by FastLanguageModel.

Full write-up with all fixes: Fine-tuning Devstral on an RTX 3090

Hardware Requirements

| Format | Min VRAM | |---|---| | Q4_K_M GGUF | ~16GB | | Q5_K_M GGUF | ~18GB | | LoRA inference (4-bit) | ~20GB | | LoRA training (QLoRA) | 24GB |

Limitations

Trained on 2,322 samples — a small dataset. Performance gains on reasoning are real but limited in breadth.
Max sequence length 2048 tokens (training constraint). Longer contexts may degrade quality.
The <think> block reasoning style is inherited from Claude Opus traces — the model may produce verbose reasoning.
Not evaluated on formal benchmarks.

Author

Adam Jenner — adamjenner.com.au

Author: adamjen

Likes: 2

Downloads: 0

Tags: safetensors, gguf, mistral, ministral3, code, reasoning, lora, unsloth, knowledge-distillation, text-generation, conversational, en, dataset:nohurry/Opus-4.6-Reasoning-3000x-filtered, base_model:mistralai/Devstral-Small-2-24B-Instruct-2512, base_model:adapter:mistralai/Devstral-Small-2-24B-Instruct-2512, license:apache-2.0, endpoints_compatible, region:us

Todays AI Summary

AI Developments: Ling-flash-2.0 Achieves SOTA Performance, Magistral Small 1.2 Adds Multimodality, and More

Research Highlights

Model Releases

Key Takeaways

AI Papers for 2026-03-25

WorldCache: Content-Aware Caching for Accelerated Video World Models

End-to-End Training for Unified Tokenization and Latent Denoising

UniMotion: A Unified Framework for Motion-Text-Vision Understanding and Generation

ThinkJEPA: Empowering Latent World Models with Large Vision-Language Reasoning Model

3D-Layout-R1: Structured Reasoning for Language-Instructed Spatial Editing

TiCo: Time-Controllable Training for Spoken Dialogue Models

Confidence-Based Decoding is Provably Efficient for Diffusion Language Models

One Model, Two Markets: Bid-Aware Generative Recommendation

SpatialReward: Verifiable Spatial Reward Modeling for Fine-Grained Spatial Consistency in Text-to-Image Generation

Dyadic: A Scalable Platform for Human-Human and Human-AI Conversation Research

AI Models

Tesslate/OmniCoder-2-9B

OmniCoder-2-9B

The second generation of OmniCoder. Faster reasoning, dramatically less repetition, completely rebuilt training pipeline.

What's New in v2

Benchmarks

Key Results

Quickstart

Transformers

vLLM

llama.cpp (GGUF)

Training Details

v1 vs v2 Pipeline

Training Config

Training Data Sources

Why Constant LR? (Schulman "LoRA Without Regret")

Architecture

Recommended Sampling Parameters

Limitations

Acknowledgments

Citation

allenai/MolmoWeb-8B-Native

MolmoWeb-8B-Native

Usage

License and Use

Jackrong/Qwen3.5-9B-Neo

🌟 Jackrong/Qwen3.5-9B-Neo

📢 Announcement

💡 Model Introduction

LM Eval Harness Benchmark Results 🪐

🗺️ Training Pipeline Overview

🧠 Example of Learned Reasoning Scaffold

📚 All Datasets Used

⚠️ Limitations & Intended Use

🙏 Acknowledgements

Tesslate/OmniCoder-2-9B-GGUF

OmniCoder-9B-GGUF

GGUF quantizations of OmniCoder-9B

Available Quantizations

Usage

elix3r/LTX-2.3-22b-AV-LoRA-talking-head

elix3r/LTX-2.3-22b-AV-LoRA-talking-head

Overview

What It Does

Demo Results (v1)

How To Use

Requirements

Loading the LoRA

Recommended Inference Settings

Prompt Format

Training Your Own AV LoRA

Pipeline Overview

Step 1 -- Generate Reference Images

Step 2 -- Clone the Voice

Step 3 -- Generate Training Clips

Step 4 -- Prepare the Dataset

Step 5 -- Train with ltx-trainer

Training Details

Known Limitations (v1)

v2 Roadmap

Files

Citation

License

alvdansen/illustration-1.0-flux-dev