---

license: apache-2.0 tags:

• uncensored
• qwen3.5
• moe
• gguf
• vision
• multimodal language:
• en
• zh
• multilingual pipeline_tag: image-text-to-text base_model: Qwen/Qwen3.5-122B-A10B

---

Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive

Qwen3.5-122B-A10B uncensored by HauhauCS. 0/465 refusals.

About

No changes to datasets or capabilities. Fully functional, 100% of what the original authors intended - just without the refusals.

These are meant to be the best lossless uncensored models out there.

Aggressive Variant

Stronger uncensoring — model is fully unlocked and won't refuse prompts. Disclaimers that were present in previous releases have been significantly reduced in this version.

For a more conservative uncensor that keeps some safety guardrails, check the Balanced variant when it's available.

What are K_P quants?

K_P ("Perfect") quants are HauhauCS custom quantizations that use model-specific analysis to selectively preserve quality where it matters most. Each model gets its own optimized quantization profile.

A K_P quant effectively bumps quality up by 1-2 quant levels at only ~5-15% larger file size than the base quant. Fully compatible with llama.cpp, LM Studio, and any GGUF-compatible runtime — no special builds needed.

Downloads

| File | Quant | Size | |------|-------|------| | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q8_K_P.gguf | Q8_K_P | 145 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q6_K_P.gguf | Q6_K_P | 105 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q6_K.gguf | Q6_K | 100 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q5_K_P.gguf | Q5_K_P | 94 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q5_K_M.gguf | Q5_K_M | 87 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q4_K_P.gguf | Q4_K_P | 79 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q4_K_M.gguf | Q4_K_M | 74 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-IQ4_XS.gguf | IQ4_XS | 65 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q3_K_P.gguf | Q3_K_P | 63 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q3_K_M.gguf | Q3_K_M | 59 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-IQ3_M.gguf | IQ3_M | 54 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-IQ3_XXS.gguf | IQ3_XXS | 47 GB | | Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-IQ2_M.gguf | IQ2_M | 40 GB | | mmproj-Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-f16.gguf | mmproj (f16) | 867 MB |

Note: K_P quants may show as "?" in LM Studio's quant column. This is a display issue only — the model loads and runs fine.

Specs

• 122B total parameters, ~10B active per forward pass (MoE)
• 256 experts, 8 routed + 1 shared per token
• Hybrid architecture: Gated DeltaNet linear attention + full softmax attention (3:1 ratio)
• 48 layers, pattern: 12 x (3 x DeltaNet-MoE + 1 x Attention-MoE)
• 262K native context
• Natively multimodal (text, image, video)
• 248K vocabulary, 201 languages
• Based on Qwen/Qwen3.5-122B-A10B

Recommended Settings

From the official Qwen authors:

Thinking mode (default):

• General: temperature=1.0, top_p=0.95, top_k=20, min_p=0, presence_penalty=1.5
• Coding/precise tasks: temperature=0.6, top_p=0.95, top_k=20, min_p=0, presence_penalty=0

Non-thinking mode:

• General: temperature=0.7, top_p=0.8, top_k=20, min_p=0, presence_penalty=1.5
• Reasoning tasks: temperature=1.0, top_p=1.0, top_k=40, min_p=0, presence_penalty=2.0

Important:

• Use --jinja flag with llama.cpp for proper chat template handling
• Thinking mode is on by default — to disable, use --chat-template-kwargs '{"enable_thinking":false}' or edit the jinja template
• Vision support requires the mmproj file alongside the main GGUF

Usage

Works with llama.cpp, LM Studio, Jan, koboldcpp, and other GGUF-compatible runtimes.

# Text only
llama-cli -m Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q4_K_P.gguf \
  --jinja -c 131072 -ngl 99

# With vision
llama-cli -m Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-Q4_K_P.gguf \
  --mmproj mmproj-Qwen3.5-122B-A10B-Uncensored-HauhauCS-Aggressive-f16.gguf \
  --jinja -c 131072 -ngl 99

Other Models

• Qwen3.5-35B-A3B-Uncensored-HauhauCS-Aggressive
• Qwen3.5-27B-Uncensored-HauhauCS-Aggressive
• Qwen3.5-9B-Uncensored-HauhauCS-Aggressive
• Qwen3.5-4B-Uncensored-HauhauCS-Aggressive

---

base_model:

• nvidia/Nemotron-Cascade-2-30B-A3B

---

Description

This repo contains specialized MoE-quants for Nemotron-Cascade-2-30B-A3B. The idea being that given the huge size of the FFN tensors compared to the rest of the tensors in the model, it should be possible to achieve a better quality while keeping the overall size of the entire model smaller compared to a similar naive quantization. To that end, the quantization type default is kept in high quality and the FFN UP + FFN GATE tensors are quanted down along with the FFN DOWN tensors.

Notes

This model is a little weird, similarly to the other recent Nemotrons. There isn't a ffn_gate_exps tensor in it, and the ffn_up_exps and ffn_down_exps tensors have 2688 elements in it which means that it is not compatible with most Q*_K quantizations.

Therefore, most of the quants have to use IQ4_NL, Q4_0/Q4_1, and Q5_0/Q5_1 quantizations for the FFNs.

| Quant | Size | Mixture | PPL | 1-(Mean PPL(Q)/PPL(base)) | KLD | | :--------- | :--------- | :------- | :------- | :------- | :------- | | Q8_0 | 31.27 GiB (8.51 BPW) | Q8_0 (reference) | 9.743360 ± 0.072693 | +0.1278% | 0.003439 ± 0.000025 | | Q5_K_M | 27.00 GiB (7.34 BPW) | Q8_0 / Q5_1 / X / Q8_0 | 9.752863 ± 0.072779 | +0.2255% | 0.004316 ± 0.000033 | | Q4_K_M | 21.87 GiB (5.95 BPW) | Q8_0 / Q5_0 / X / Q5_1 | 9.760517 ± 0.072841 | +0.3041% | 0.005375 ± 0.000036 | | Q4_0 | 19.30 GiB (5.25 BPW) | Q8_0 / Q4_0 / X / Q5_0| 9.775306 ± 0.072933 | +0.4561% | 0.008387 ± 0.000053 | | IQ4_XS | 17.59 GiB (4.79 BPW) | Q8_0 / IQ4_NL / X / IQ4_NL | 9.802367 ± 0.073142 | +0.7342% | 0.009969 ± 0.000062 |

---

license: apache-2.0 base_model:

• Lightricks/LTX-2.3 tags:
• ltx
• lora
• inpaint

---

LoRAs for LTX 2.3

Here I will share some LoRAs that I trained for LTX 2.3.

These LoRAs may cover different use cases over time, so this repository is not limited to inpainting only.

Models

| File | Description | |---|---| | ltx23_inpaint_rank128_v1_02500steps.safetensors | (Recommended) Follows the prompt better, probably because it experienced less overfitting. | | ltx23_inpaint_rank128_v1_10000steps.safetensors | Follows the prompt in a more limited way, but uses the mask area better. This is probably because it experienced more overfitting after a longer training time on a more limited dataset. |

Important inference notes for the inpainting LoRAs

These inpainting LoRAs were trained with a specific guide and mask setup, so input preparation during inference is important.

How to use the mask

During inference, you should not pass the mask as a separate channel.

The mask must be embedded into the guide video, which means:

• the mask video
• and the guide video

must be treated as a single video.

After that, you need to use the LTXVAddGuideMulti node to pass the guide video into the model.

About the mask format used during training

My dataset included samples where the mask was more blockified. In other words, the default pattern used 8x8 blocks.

To better reproduce the training conditions during inference, you can use:

• Blockify Mask from KJNodes

This may help make the mask distribution closer to what the model saw during training.

Notes

• Base model: Lightricks/LTX-2.3
• Checkpoint behavior may vary significantly in terms of:
  • prompt adherence
  • use of the masked area
  • overfitting tendency

Practical recommendations

For the inpainting LoRAs in this repo:

• If you want better prompt adherence, try the 2500 steps checkpoint first
• If you want better use of the masked area, try the 10000 steps checkpoint first

The best approach is to compare both in your workflow, since preference may vary depending on the scene, mask, and prompt.

---

Examples — 2500 Steps

Example 1

Model: ltx23_inpaint_rank128_v1_02500steps.safetensors

Video:

Prompt:

---

Example 2

Model: ltx23_inpaint_rank128_v1_02500steps.safetensors

Video:

Prompt:

---

Examples — 10000 Steps

Example 1

Model: ltx23_inpaint_rank128_v1_10000steps.safetensors

Video:

Prompt:

---

Example 2

Model: ltx23_inpaint_rank128_v1_10000steps.safetensors

Video:

Prompt:

---

language:

• zh library_name: transformers base_model: Qwen/Qwen3.5-27B base_model_relation: finetune tags:
• qwen
• dora
• orpo
• chinese
• creative-writing
• web-novel license: other

---

Qwen3.5-27B-WebNovel-Writer-zh

基于 Qwen3.5-27B-text 的中文网文写作风格微调模型，目标为去除 AI 味、向网文原著白描风格对齐。

基座模型 Qwen3.5-27B-text 为作者从 Qwen3.5-27B 抽离纯文本权重的自定义版本，非官方发布。另有 Q4_K_M 量化版本。

训练

两阶段微调：

1. SFT：20,320 条中文网文正文，DoRA 16bit，学习叙事节奏与白描风格
2. ORPO：8,000 条偏好对，强化去 AI 味倾向

| 参数 | 值 | |------|----| | 基座 | Qwen3.5-27B-text | | 方法 | DoRA 16bit | | LoRA rank / alpha | 64 / 128 | | Target modules | 12（full attention + MLP）| | SFT LR | 3e-5 | | ORPO LR / beta | 5e-6 / 0.15 |

使用建议

System prompt：

你是一位中文西幻网文写作助手，擅长创作高质量的小说正文。请根据用户的指令完成写作任务。

训练数据包含以下任务格式，按对应格式输入可获得最佳效果：

正文增强（beat → 完整场景）

任务：正文增强
目标：让这段更像成熟作者写出的西幻正文
输入类型：场景beat
增强强度：中（从场景beat到完整场景）
长度目标：2.0x~3.5x
重点：节奏铺排、心理层次、环境渲染、微动作衔接
限制：严格保留骨架中的全部事实、人名、地名、术语、事件顺序与结果。不新增原文没有的信息。

素材：
[场景beat内容]

骨架扩写（骨架 → 完整场景）

请将下面文本增强为更自然的小说正文。

输入类型：事件骨架
增强强度：高（从纯骨架到完整场景）
长度目标：3.5x~6.0x
重点：从骨架扩写完整场景：叙事结构、节奏铺排、感官填充、对话还原
要求：严格保留骨架中的全部事实、人名、地名、术语、事件顺序与结果。不新增原文没有的信息。

文本：
[事件骨架内容]

场景扩写（描述 → 正文）

任务：场景扩写
场景描述：[场景描述]
要求：西幻风格，注重场景感和节奏，保持人物行为合理。

请写出完整的小说场景。

正文润色

任务：正文润色
要求：提升文笔、优化节奏、保留原意

原文：
[待润色文本]

推荐推理参数：temperature=0.7，top_p=0.90，repetition_penalty=1.10。

数据

中文网文正文语料，版权归原作者所有，数据集不公开。

协议

遵循 Qwen License，仅供研究与个人使用。

---

license: apache-2.0 datasets:

• HuggingFaceFW/fineweb-edu
• mattwesney/General_Inquiry_Thinking-Chain-Of-Thought
• tatsu-lab/alpaca
• databricks/databricks-dolly-15k
• TeichAI/Step-3.5-Flash-2600x
• TeichAI/convo-v1 language:
• en tags:
• small
• haiku

---

TinyMemoryLM (Haiku)

⚠️ IMPORTANT NOTICE

1. The model is really dumb. This is a sub-1M parameter research model designed for experimentation, not production use.
2. Do not expect it to answer any questions. It is prone to repetition, hallucination, and format collapse.

Overview

TinyMemoryLM is an ultra-lightweight language model optimized for edge cases and architectural experimentation. Despite its small footprint, it incorporates several novel training innovations aimed at stabilizing tiny model convergence, including hybrid tokenization, loss boosting strategies, and context-aware relevance modeling.

This release includes both Pretrained Weights (base language modeling) and Instruction Weights (fine-tuned for chat/completion).

Files Provided

| File | Description | | :--- | :--- | | tokenizer.json | Hybrid word/character tokenizer vocabulary (2,133 tokens). | | pretrain.pt | Base pretrained checkpoint (language modeling). | | model.pt | Instruction-tuned checkpoint (SFT/Chat). | | samples.jsonl | Sample generations with NLL/PPL metrics at checkpoints. | | loss_curve.png | Training loss progression across all phases. |

Model Specifications

| Parameter | Value | | :--- | :--- | | Architecture | Transformer Decoder (GQA) | | Parameters | ~700K | | Context Length | 2,048 tokens | | Sliding Window | 512 tokens | | Dimensions | d_model=128, unique_layers=8, logical_layers=16, heads=4, kv_heads=2, ffn=224 | | Vocabulary | ~2,133 tokens (Hybrid Char + Word) | | Normalization | RMSNorm | | Embeddings | Rotary Embeddings (RoPE, 25% fraction) | | Activation | SwiGLU | | Multi-Token Prediction | Horizons at 2, 3, 4 |

Architecture Highlights

TinyMemoryLM implements several research-focused modifications to standard transformer architectures:

• Weight-Tied Logical Layers: 8 unique transformer blocks are repeated to create 16 logical layers (every 3rd layer uses global attention vs. sliding window), drastically reducing parameter count.
• Grouped-Query Attention (GQA): 4 attention heads share 2 KV heads, reducing KV cache and compute.
• Sliding Window Attention: Local attention within 512-token windows, with periodic global layers for long-range context.
• Multi-Token Prediction (MTP): Auxiliary prediction heads at horizons 2, 3, and 4 with dedicated adapters and norms, weighted at 0.3 during training.
• Hybrid Tokenizer: Combines character-level fallback with frequent word tokens to balance compression and vocabulary size.
• Word Token Loss Boosting: Upweights loss signals for multi-character tokens (3x) to prevent the model from ignoring them in favor of character-level spelling.
• Response-Start Weighting: Prioritizes the first 20 tokens of assistant responses (3x weight) to improve prompt conditioning.
• Embedding Scale: Learned scaling factor applied to token embeddings for improved training dynamics.

Training Hyperparameters

| Parameter | Value | | :--- | :--- | | Batch Size | 48 | | Pretrain LR | 8e-4 (min 1e-5) | | SFT LR | 2e-4 (min 1e-5) | | Warmup | 300 steps | | Weight Decay | 0.02 | | Max Grad Norm | 1.0 | | MTP Weight | 0.3 | | Word Token Loss Boost | 3.0x | | Response-Start Boost | 3.0x (first 20 tokens) | | Checkpointing | Every 1,000 steps | | Sampling | Every 5,000 steps |

Training Loss Curve

Training loss progression across pretrain and SFT phases:

Limitations & Expectations

Please manage your expectations when using TinyMemoryLM:

• Repetition: Tiny models are prone to collapsing into repetitive token loops.
• Knowledge: The model has limited world knowledge due to parameter constraints.
• Usage: This model is intended for research, educational purposes, and architectural benchmarking. It is not suitable for assistant tasks or reliable information retrieval.

---

Generated for research purposes. Use responsibly.

---

language:

• en
• zh
• ko license: apache-2.0 base_model: Qwen/Qwen3.5-9B tags:
• unsloth
• qwen
• qwen3.5
• reasoning
• chain-of-thought
• lora
• uncensored
• not-for-all-audiences pipeline_tag: image-text-to-text datasets:
• nohurry/Opus-4.6-Reasoning-3000x-filtered
• Jackrong/Qwen3.5-reasoning-700x
• Roman1111111/claude-opus-4.6-10000x

---

🌟 This is OmniClaw-Qwen3.5-9B-Claude-4.6-Opus-Uncensored-v2 model with zero refusals made via merging HauhauCS model with latest update for Jackrong model at 1.0 weight

🌟 On next stages I merged OmniCoder model from Tesslate at 0.5 weight and creative writing model from nbeerbower at 0.5 weight.

🌟 Only finetunable weights trained via unsloth has been modified in model during merging process in float32 precision.

If you want to disable thinking use this chat template in LM Studio, but I don't reccomend to do it for 9B model, because it's already crazy fast enough: https://pastebin.com/uk9ZkxCR

For best model perfomance use following settings in LM Studio:

Temperature: 0.7

Top K Sampling: 20

Presence Penalty: 1.5

Top P Sampling: 0.8

Min P Sampling: 0

Seed: 3407 or 42

And this system prompt. It's pretty solid: https://pastebin.com/pU25DVnB

This one is simplified but works too: https://pastebin.com/6C4rtujt

Also you can use only this string in System Prompt:

You are Claude, created by Anthropic. You are a helpful AI assistant.

or

You are Qwen, created by Alibaba Cloud. You are a helpful assistant.

And write anything you want after that. Looks like model is underperforming without this first line.

📢 Announcement

v2 Update: This iteration is powered by 14,000+ premium Claude 4.6 Opus-style general reasoning samples, with a major focus on achieving massive gains in reasoning efficiency while actively improving peak accuracy.

v2 introduces a refined reasoning scaffold designed to eliminate redundant internal loops, significantly improving the model's cross-task generalization from logic and math into specialized fields like programming. Compared to the original model, autonomy and stability are significantly improved, ensuring the model remains robust and self-consistent during complex, multi-step problem solving. v2 is built to think smarter, not longer, delivering substantial improvements in inference speed and cost-effectiveness while simultaneously boosting baseline accuracy.

Note: Due to the constraints of SFT sample size and training scope, the model's broad general-purpose capabilities might be slightly impacted. The efficiency and accuracy results discussed here are based on the HumanEval and HumanEval+ benchmarks. Thank you for your understanding!

💡 Model Introduction

Qwen3.5-9B-Claude-4.6-Opus-Reasoning-Distilled-v2 is the second iteration of this reasoning-focused Qwen3.5-9B fine-tune, built to drastically improve the efficiency of chain-of-thought generation, unlocking highly substantial gains in reasoning speed and cost-reduction while actually increasing absolute accuracy.

Compared with the earlier version, v2 was trained with 14,000 Claude 4.6 Opus-style general reasoning samples, with a stronger emphasis on transferring concise, reusable reasoning patterns rather than only maximizing raw benchmark scores. The goal of v2 is not simply to make the model "think more," but to help it think more economically: reducing unnecessarily long internal chains, avoiding verbose over-analysis on easy problems, and massively improving the reasoning-cost-to-quality ratio while beating the baseline's benchmark correctness.

A key design choice in v2 is that the distillation data is primarily general-domain reasoning data—specifically focused on mathematics, word problems, logical deduction, and a balanced mix of general knowledge and instructions—rather than specialized code-heavy supervision. Consequently, HumanEval and HumanEval+ are employed here to evaluate cross-task generalization and capability transfer, rather than serving as direct optimization targets. High performance on these benchmarks, despite the lack of code-centric training, confirms that the model's reasoning scaffold has become more robust and transferable, proving that fundamental reasoning logic can effectively power specialized tasks like programming.

Why v2 matters

Relative to the official Qwen3.5-9B baseline, the fine-tuned v2 model achieves a strict upgrade in absolute HumanEval and HumanEval+ accuracy alongside massive, transformative gains in reasoning efficiency:

| Metric | Official Qwen3.5-9B | v2 Fine-tuned Model | Improvement | |---|---:|---:|---:| | Average think length (chars) | 2284.3 chars | 1778.0 chars | 🟢 -22.17% (Shorter / Better) | | Average think length (words) | 400.83 words | 310.33 words | 🟢 -22.58% (Shorter / Better) | | HumanEval base passes per 10k think chars | 4.004 | 5.041 | 🟢 +25.91% (Higher / Better) | | HumanEval+ passes per 10k think chars | 3.764 | 4.836 | 🟢 +28.48% (Higher / Better) | | Think chars needed per HumanEval base pass | 2497.5 | 1983.6 | 🟢 -20.58% (Lower / Better) | | Think chars needed per HumanEval+ pass | 2656.9 | 2068.0 | 🟢 -22.17% (Lower / Better) |

More impressively, not only does v2 vastly improve reasoning efficiency, it actually outperforms the official baseline on both the standard base tests and the much stricter HumanEval+ benchmark across different test settings.

We conducted two separate evaluations under different sampling temperatures to verify stability and peak performance:

Test Run 1 (T=0.2) | Fairly Recomputed Benchmark | Official Qwen3.5-9B | v2 Fine-tuned Model | Gap | |---|---:|---:|---:| | HumanEval (base tests) pass@1 | 0.8171 | 0.8232 | 🟢 +0.61 pts | | HumanEval+ (base + extra tests) pass@1 | 0.7622 | 0.7866 | 🟢 +2.44 pts |

Test Run 2 (T=0.6) | Fairly Recomputed Benchmark | Official Qwen3.5-9B | v2 Fine-tuned Model | Gap | |---|---:|---:|---:| | HumanEval (base tests) pass@1 | 0.8170 | 0.8720 | 🟢 +5.50 pts | | HumanEval+ (base + extra tests) pass@1 | 0.7620 | 0.8170 | 🟢 +5.50 pts |

These consistent dual-improvements make the model undeniably superior for real-world use cases.

For users who care about reasoning efficiency per unit of inference budget, v2 is exceptionally powerful—not only achieving higher peak accuracy, but doing so while consuming over 20% fewer characters and tokens.

That matters especially for:

• Resource-constrained local deployment: On consumer GPUs or lower-memory local setups, shorter and cleaner reasoning traces can reduce latency, memory pressure, and the effective cost of generation.
• Agentic workflows: In multi-step agents, the model often solves many easy or medium subtasks. In those settings, excessively elaborate chain-of-thought can become a tax on throughput. A model that reaches a better answer with fewer reasoning tokens can radically improve end-to-end agent speed and lower cumulative inference cost.
• Open-source tool use and emerging agent stacks: For users building with lightweight open reasoning systems, browser-use agents, terminal agents, or projects in the "OpenClaw / local autonomous agent" style ecosystem, a model that achieves better peak accuracy while drastically improving reasoning economy is highly practical for real-world loops.
• Simple problems at scale: One common issue with strong reasoning-tuned base models is that they sometimes produce very elaborate internal traces even for simple prompts. While that can look impressive, it is often inefficient in practice. v2 is explicitly aimed at trimming this overhead.

In short, v2 no longer forces a trade-off between absolute coding benchmark scores and reasoning economy. It provides a fully optimized deployment-ready profile: faster, shorter, more economical reasoning paired with stronger generalization and accuracy. For local users, agent builders, and cost-sensitive applications, v2 is a strict upgrade.

🗺️ Training Pipeline Overview

Base Model (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-Claude-4.6-Opus-Reasoning-Distilled-v2

🧠 Example of Learned Reasoning Scaffold（Example）

The model includes targeted optimizations addressing Qwen3.5’s tendency toward excessive transitional or repetitive reasoning on simple queries. Through deep distillation and structural imitation of Claude-4.6-Opus reasoning chains, the model adopts a more efficient structured thinking pattern:
“Let me analyze this request carefully: 1..2..3...”.
This streamlined reasoning paradigm significantly reduces redundant cognitive loops while preserving deep analytical capacity, resulting in substantially improved inference efficiency.

Let me analyze this request carefully:

1. Identify the core objective of the problem.
2. Break the task into clearly defined subcomponents.
3. Evaluate constraints and edge cases.
4. Formulate a step-by-step solution plan.
5. Execute the reasoning sequentially and verify consistency.
            .
            .
            .

📚 All Datasets Used

The dataset consists of high-quality, filtered reasoning distillation data:

| Dataset Name | Description / Purpose | |--------------|-----------------------| | nohurry/Opus-4.6-Reasoning-3000x-filtered | Provides comprehensive Claude 4.6 Opus reasoning trajectories. | | Roman1111111/claude-opus-4.6-10000x | Large-scale public Claude 4.6 Opus distillation data used to strengthen general reasoning transfer in v2. | | TeichAI/claude-4.5-opus-high-reasoning-250x | Injecting high-intensity, structured reasoning instances. | | Jackrong/Qwen3.5-reasoning-700x | Additional curated reasoning samples designed to strengthen structured step-by-step problem solving and improve reasoning diversity. |

⚠️ Limitations & Intended Use

• 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.
• Intended Scenario: Best suited for offline analytical tasks, coding, math, and heavy logic-dependent prompting where the user needs to transparently follow the AI's internal logic.
• 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.

---

tags:

• gguf
• llama.cpp
• unsloth
• vision-language-model

---

Qwen3.5-9B-Japanese-awy : GGUF

This model was finetuned and converted to GGUF format using Unsloth.

Example usage:

• For text only LLMs: llama-cli -hf Aikimi/Qwen3.5-9B-Japanese-awy --jinja
• For multimodal models: llama-mtmd-cli -hf Aikimi/Qwen3.5-9B-Japanese-awy --jinja

Available Model files:

• Qwen3.5-9B.Q4_K_M.gguf
• Qwen3.5-9B.BF16-mmproj.gguf This was trained 2x faster with Unsloth <img src="https://raw.githubusercontent.com/unslothai/unsloth/main/images/unsloth%20made%20with%20love.png" width="200"/>

---

language: en license: apache-2.0 tags:

• vision-language
• multimodal
• vlm
• nanbeige
• siglip
• image-text-to-text datasets:
• liuhaotian/LLaVA-CC3M-Pretrain-595K
• liuhaotian/LLaVA-Instruct-150K base_model:
• Nanbeige/Nanbeige4.1-3B
• google/siglip-so400m-patch14-384 pipeline_tag: image-text-to-text

---

Nanbeige4.1-VLM — Stage 2 (Instruction Tuned)

Full vision-language model after Stage 2 instruction fine-tuning on LLaVA-Instruct-150K. LoRA weights have been merged into the base model for easy inference.

Architecture

Image → SigLIP so400m → AvgPool(729→196) → MLP Projector → Nanbeige4.1-3B → Text

Usage

from transformers import AutoModel, AutoTokenizer
from PIL import Image

model = AutoModel.from_pretrained(
    "SkyAsl/Nanbeige4.1-VLM-Stage2",
    trust_remote_code=True,
)
model.to("cuda")

tokenizer = AutoTokenizer.from_pretrained(
    "SkyAsl/Nanbeige4.1-VLM-Stage2",
    trust_remote_code=True,
)
model.set_tokenizer(tokenizer)

image  = Image.open("photo.jpg")
result = model.describe(image, prompt="What do you see in this image?")
print(result)

Training Details

| | Stage 1 | Stage 2 | |---|---|---| | Dataset | LLaVA-CC3M-595K | LLaVA-Instruct-150K | | Trainable | Projector only | Projector + LoRA (r=64) | | LR | 2e-3 | 2e-5 | | Hardware | A100 80GB | A100 80GB | | Duration | ~6 hours | ~5 hours |

Related Repos

• Stage 1 base: SkyAsl/Nanbeige4.1-VLM-Base
• LoRA only: SkyAsl/Nanbeige4.1-VLM-Stage2-LoRA

Citation

@misc{aslanoglu2025nanbeige41vlm,
  author    = {Aslanoglu, Goktug},
  title     = {Nanbeige4.1-VLM: A Vision-Language Model based on SigLIP and Nanbeige4.1-3B},
  year      = {2025},
  publisher = {Hugging Face},
  url       = {https://huggingface.co/SkyAsl/Nanbeige4.1-VLM-Stage2},
}

---

license: apache-2.0 base_model:

• dreamgen/lucid-v1-nemo
• limloop/MN-12B-Faun-RP-RU library_name: transformers language:
  • en
  • ru tags:
• mergekit
• merge
• slerp
• russian
• uncensored
• roleplay
• mistral-nemo

---

MN-12B-LucidFaun-RP-RU

<details> <summary>🇷🇺 Нажмите, чтобы развернуть описание на русском</summary>

🌟 О модели

MN-12B-LucidFaun-RP-RU — гибридная модель на базе Mistral Nemo 12B, созданная методом диагностического SLERP-слияния. Объединяет сильные стороны двух моделей:

• 🎭 Живой RP-характер Faun — современный стиль, богатая лексика, поддержка ninja-формата инструкций и tool calling
• 📚 Стабильность и детализация lucid — превосходное качество сторителлинга, устойчивость на длинных контекстах, отсутствие цензуры
• 🔬 Точечное исправление — цензура Faun локализована в поздних MLP-слоях и заменена на lucid

Модель собрана методом SLERP и не проходила дополнительного обучения после слияния.

🎯 Особенности

• Практически полное отсутствие цензуры — редкие дисклеймеры возможны только при высокой температуре
• Улучшенная стабильность — превосходит Faun при temperature ≤0.5, работает с 0.8 при top_k=20
• Tool calling — полностью поддерживается
• Контекст — стабильно работает до 8192 токенов (проверено)
• Русский язык — сохранился и взможно улучшен за счет слияния с lucid
• Формат инструкций — сохранился от Faun
• Сторителлинг — унаследовал богатые возможности lucid по планированию сцен, управлению сюжетом и работе с персонажами

⚠️ Важно

Модель сохраняет uncensored-характер, однако при очень высокой температуре (0.8+) и большом top_k может изредка добавлять короткие дисклеймеры. Генерация не блокируется и продолжается после них.

</details>

MN-12B-LucidFaun-RP-RU is a diagnostic SLERP merge combining the lively RP character of Faun with the stability and rich storytelling capabilities of lucid.

---

🌍 Overview

This model represents a surgical approach to merging. Instead of blending everything equally, we experimentally identified where Faun's censorship resides (late MLP layers) and replaced only those components with lucid.

The result is a model that:

• Keeps Faun's personality, style, and tool calling
• Gains lucid's stability, rich prose, and uncensored behavior
• Inherits lucid's advanced storytelling features
• Maintains coherence even on long contexts

Built using diagnostic SLERP merging with layer-specific weight distribution.

---

🎯 Key Features

| Feature | Description | | ------------------------- | --------------------------------------------------- | | Languages | Russian, English | | Censorship | Almost none (rare disclaimers at high temp) | | Roleplay | Faun's lively character, lucid's stability | | Story-Writing | Full lucid capabilities (scene planning, OOC, etc.) | | Tool Calling | ✅ Fully supported | | Context Length | Stable up to ~8192 tokens | | Temperature Tolerance | Safe ≤0.5, up to 0.8 with top_k=20 | | Architecture | Mistral Nemo 12B |

---

🧪 Methodology: Why This Merge Works

Diagnostic Approach

1. Experiment 1 — MLP vs Self-Attention
   We discovered that censorship in Faun lives exclusively in MLP layers. Self-attention from Faun did not trigger refusals.

2. Experiment 2 — Localization within MLP
   By applying gradient distributions across layers, we found censorship is concentrated in late MLP layers (layers ~25–40).

3. Final Configuration — Gradual Intervention
   MLP weight of lucid increases toward the end: [0.1, 0.2, 0.5, 0.4, 0.75]
   Self-attention is mixed 0.5 for stability while preserving Faun's character.
   LayerNorm is mixed 0.5 for overall stability.

Merge Configuration

slices:
  - sources:
      - model: limloop/MN-12B-Faun-RP-RU
        layer_range: [0, 40]
      - model: dreamgen/lucid-v1-nemo
        layer_range: [0, 40]

merge_method: slerp
base_model: limloop/MN-12B-Faun-RP-RU

parameters:
  t:
    - filter: self_attn
      value: 0.5
    - filter: mlp
      value: [0.1, 0.2, 0.5, 0.4, 0.75]
    - value: 0.5

dtype: bfloat16
tokenizer:
  source: "base"

---

💡 Usage Examples

Basic Usage

from transformers import AutoTokenizer, AutoModelForCausalLM
import torch

model_name = "limloop/MN-12B-LucidFaun-RP-RU"
tokenizer = AutoTokenizer.from_pretrained(model_name)
model = AutoModelForCausalLM.from_pretrained(
    model_name,
    torch_dtype=torch.bfloat16,
    device_map="auto"
)

prompt = "Ты — лесной фавн, говоришь загадками и любишь шалить."
messages = [{"role": "user", "content": prompt}]
inputs = tokenizer.apply_chat_template(messages, return_tensors="pt").to(model.device)

outputs = model.generate(
    inputs, 
    max_new_tokens=512, 
    temperature=0.6,
    top_k=30,
    do_sample=True
)
response = tokenizer.decode(outputs[0], skip_special_tokens=True)
print(response)

---

⚙️ Merge Details

Built using mergekit with SLERP (Spherical Linear Interpolation), which allows smooth interpolation between models while preserving geometric properties.

Layer-Specific Weights

The merge uses a graduated approach for MLP layers, increasing lucid influence toward later layers where censorship was detected:

| Layer Zone (approx) | lucid weight (MLP) | Effect | |---------------------|-------------------|--------| | 0–8 | 0.1 | Almost pure Faun (early patterns) | | 8–16 | 0.2 | Slight lucid influence | | 16–24 | 0.5 | Balanced | | 24–32 | 0.4 | Slightly more Faun | | 32–40 | 0.75 | Lucid dominates — removes censorship |

Self-attention is mixed evenly (0.5) to preserve character while adding stability.
LayerNorm is mixed 0.5 for overall stability.

---

library_name: transformers language:

• en
• fr license: apache-2.0 base_model: Simonc-44/Cygnis-Alpha-2-8B-v0.3 model_name: Cygnis-Alpha 2 (8B) v0.3 Imatrix GGUF tags:
• text-generation
• llama-3.1
• reasoning
• cot
• 8b
• cygnis-alpha
• gguf
• imatrix
• ollama datasets:
• Simonc-44/Cygnis-Alpha2-Instruct-Mix
• Simonc-44/Cygnis-Identity-SFT

---

<div align="center" style="background-color: #050505; color: #e2e8f0; padding: 80px 40px; border-radius: 24px; border: 1px solid #1e1e20; font-family: 'Inter', -apple-system, BlinkMacSystemFont, 'Segoe UI', Roboto, sans-serif; max-width: 900px; margin: auto; box-shadow: 0 40px 100px rgba(0,0,0,0.8);"> <div style="margin-bottom: 35px; display: flex; justify-content: center;"> <div style="width: 100px; height: 100px; padding: 3px; background: linear-gradient(135deg, #00d4ff, #6366f1, #a855f7); border-radius: 50%; box-shadow: 0 0 30px rgba(0, 212, 255, 0.3);"> <div style="width: 100%; height: 100%; background: #000; border-radius: 50%; overflow: hidden; display: flex; align-items: center; justify-content: center; border: 2px solid #050505;"> <img src="https://cygnis-ai.vercel.app/favicon.ico" style="width: 100%; height: 100%; object-fit: cover;"> </div> </div> </div> <h1 style="font-size: 52px; font-weight: 900; margin: 0; letter-spacing: -2.5px; line-height: 1.1; color: #ffffff; background: linear-gradient(180deg, #ffffff 40%, #00d4ff 100%); -webkit-background-clip: text; -webkit-text-fill-color: transparent;"> Cygnis Alpha 2 <span style="font-weight: 300; opacity: 0.8;">i1</span> </h1> <div style="margin-top: 25px; display: flex; justify-content: center; gap: 10px; align-items: center;"> <span style="background: rgba(0, 212, 255, 0.1); border: 1px solid rgba(0, 212, 255, 0.3); color: #00d4ff; padding: 6px 16px; border-radius: 100px; font-size: 11px; font-weight: 700; letter-spacing: 1px; text-transform: uppercase;">Imatrix Optimized</span> <span style="background: rgba(255, 255, 255, 0.05); border: 1px solid rgba(255, 255, 255, 0.1); color: #94a3b8; padding: 6px 16px; border-radius: 100px; font-size: 11px; font-weight: 700; letter-spacing: 1px; text-transform: uppercase;">v0.3 Reasoning</span> </div> <p style="font-size: 19px; color: #94a3b8; max-width: 620px; margin: 35px auto; line-height: 1.7; font-weight: 400;"> Enhanced Importance Matrix (imatrix) quantizations for <strong>Cygnis Alpha 2</strong>. <br> Higher intelligence floor for low-bit inference, preserving complex CoT patterns. </p> <div style="background: #0c0c0e; border: 1px solid #1f1f22; border-radius: 20px; overflow: hidden; text-align: left; margin-top: 40px; box-shadow: 0 10px 30px rgba(0,0,0,0.3);"> <div style="padding: 24px 32px; border-bottom: 1px solid #1f1f22; background: linear-gradient(90deg, #111114, #0c0c0e);"> <h3 style="margin: 0; font-size: 16px; font-weight: 600; color: #fff;">Available Imatrix Quants</h3> </div> <table style="width: 100%; border-collapse: collapse; font-size: 13px;"> <thead> <tr style="color: #71717a; text-align: left; background: rgba(255,255,255,0.01);"> <th style="padding: 15px 32px; font-weight: 500;">Quantization</th> <th style="padding: 15px 32px; font-weight: 500;">Size</th> <th style="padding: 15px 32px; font-weight: 500;">Intelligence Level</th> <th style="padding: 15px 32px; font-weight: 500; text-align: right;">Download</th> </tr> </thead> <tbody style="color: #a1a1aa;"> <tr style="border-top: 1px solid #1f1f22; background: rgba(0, 212, 255, 0.02);"> <td style="padding: 12px 32px; color: #fff; font-weight: 600;">Q6_K (i1)</td> <td style="padding: 12px 32px;">6.7 GB</td> <td style="padding: 12px 32px; font-size: 11px; color: #00d4ff;">REFERENCE GRADE</td> <td style="padding: 12px 32px; text-align: right;"><a href="https://huggingface.co/Simonc-44/Cygnis-Alpha-2-8B-v0.3-i1-GGUF/resolve/main/Cygnis-Alpha-2-7B-v0.3.i1-Q6_K.gguf" style="color: #60a5fa; text-decoration: none;">Link</a></td> </tr> <tr style="background: rgba(99, 102, 241, 0.05); border-left: 4px solid #818cf8;"> <td style="padding: 12px 32px; color: #818cf8; font-weight: 700;">Q4_K_M (i1)</td> <td style="padding: 12px 32px; color: #818cf8;">5.0 GB</td> <td style="padding: 12px 32px; font-size: 10px;"><span style="background: #818cf8; color: #000; padding: 2px 6px; border-radius: 4px; font-weight: 800;">RECOMMENDED</span></td> <td style="padding: 12px 32px; text-align: right;"><a href="https://huggingface.co/Simonc-44/Cygnis-Alpha-2-8B-v0.3-i1-GGUF/resolve/main/Cygnis-Alpha-2-7B-v0.3.i1-Q4_K_M.gguf" style="color: #818cf8; text-decoration: none; font-weight: bold;">Link</a></td> </tr> <tr style="border-top: 1px solid #141416;"> <td style="padding: 12px 32px; color: #fff;">IQ4_XS (i1)</td> <td style="padding: 12px 32px;">4.5 GB</td> <td style="padding: 12px 32px; font-size: 11px;">HIGH LOGIC</td> <td style="padding: 12px 32px; text-align: right;"><a href="https://huggingface.co/Simonc-44/Cygnis-Alpha-2-8B-v0.3-i1-GGUF/resolve/main/Cygnis-Alpha-2-7B-v0.3.i1-IQ4_XS.gguf" style="color: #60a5fa; text-decoration: none;">Link</a></td> </tr> <tr style="border-top: 1px solid #141416;"> <td style="padding: 12px 32px; color: #fff;">IQ3_M (i1)</td> <td style="padding: 12px 32px;">3.9 GB</td> <td style="padding: 12px 32px; font-size: 11px;">EFFICIENT</td> <td style="padding: 12px 32px; text-align: right;"><a href="https://huggingface.co/Simonc-44/Cygnis-Alpha-2-8B-v0.3-i1-GGUF/resolve/main/Cygnis-Alpha-2-7B-v0.3.i1-IQ3_M.gguf" style="color: #60a5fa; text-decoration: none;">Link</a></td> </tr> <tr style="border-top: 1px solid #141416;"> <td style="padding: 12px 32px; color: #71717a;">IQ2_M (i1)</td> <td style="padding: 12px 32px; color: #71717a;">3.0 GB</td> <td style="padding: 12px 32px; font-size: 11px; color: #3f3f46;">EXPERIMENTAL</td> <td style="padding: 12px 32px; text-align: right;"><a href="https://huggingface.co/Simonc-44/Cygnis-Alpha-2-8B-v0.3-i1-GGUF/resolve/main/Cygnis-Alpha-2-7B-v0.3.i1-IQ2_M.gguf" style="color: #52525b; text-decoration: none;">Link</a></td> </tr> </tbody> </table> </div> <div style="margin-top: 60px; text-align: left;"> <h4 style="font-size: 12px; color: #52525b; margin-bottom: 20px; text-transform: uppercase; letter-spacing: 2px;">Why Imatrix?</h4> <div style="background: #09090b; border: 1px solid #1f1f22; border-radius: 20px; padding: 25px; box-shadow: inset 0 0 40px rgba(0,0,0,0.6);"> <p style="font-size: 14px; color: #94a3b8; line-height: 1.6; margin: 0;"> Standard quantization treats all weights equally. <strong>Imatrix (Importance Matrix)</strong> uses a calibration dataset to identify which neurons are vital for the model's logic. By protecting these neurons, we achieve 3-bit or 4-bit quants that often match the performance of standard 6-bit files. </p> </div> </div> <div style="margin-top: 60px; text-align: left;"> <h4 style="font-size: 12px; color: #52525b; margin-bottom: 20px; text-transform: uppercase; letter-spacing: 2px;">Perplexity vs Bitrate (Efficiency)</h4> <div style="background: #09090b; border: 1px solid #1f1f22; border-radius: 20px; padding: 25px; text-align: center; box-shadow: inset 0 0 40px rgba(0,0,0,0.6);"> <img src="https://www.nethype.de/huggingface_embed/quantpplgraph.png" style="max-width: 100%; border-radius: 12px; border: 1px solid #333; filter: grayscale(0.2) brightness(0.8);"> <p style="margin-top: 15px; font-size: 12px; color: #3f3f46; font-style: italic;">Visual representation of why Imatrix (i1) quants outperform standard static quants at lower bitrates.</p> </div> </div> <div style="margin-top: 60px; text-align: left;"> <h4 style="font-size: 12px; color: #52525b; margin-bottom: 20px; text-transform: uppercase; letter-spacing: 2px;">Ollama Config</h4> <div style="background: #000000; border: 1px solid #1f1f22; border-radius: 16px; padding: 30px; position: relative;"> <div style="position: absolute; top: 0; left: 0; width: 4px; height: 100%; background: linear-gradient(to bottom, #00d4ff, #4f46e5);"></div> <pre style="color: #cbd5e1; font-family: 'JetBrains Mono', monospace; font-size: 13px; line-height: 1.8; margin: 0; white-space: pre-wrap;"> FROM ./Cygnis-Alpha-2-7B-v0.3.i1-Q4_K_M.gguf

TEMPLATE """<|im_start|>system {{ .System }}<|im_end|> <|im_start|>user {{ .Prompt }}<|im_end|> <|im_start|>assistant <|im_thought|> """

PARAMETER stop "<|im_end|>"</pre> </div>

</div> <div style="margin-top: 80px; text-align: center; border-top: 1px solid #1f1f22; padding-top: 40px;"> <p style="color: #3f3f46; font-size: 10px; margin-top: 10px;"> Quantized with ❤️ by Simonc-44 | Powered by Llama.cpp Imatrix </p> </div> </div>