---

language:

• en
• zh license: apache-2.0 tags:
• qwen3.5
• moe
• reasoning
• distillation
• claude-opus
• qlora
• unsloth base_model: Qwen/Qwen3.5-35B-A3B datasets:
• nohurry/Opus-4.6-Reasoning-3000x-filtered
• Jackrong/Qwen3.5-reasoning-700x
• Roman1111111/claude-opus-4.6-10000x

---

Qwopus MoE 35B-A3B — Claude Opus 4.6 Reasoning Distilled (GGUF)

QLoRA fine-tune of Qwen3.5-35B-A3B (MoE, 3B active parameters) with Claude Opus 4.6 reasoning distillation. Training recipe adapted from Jackrong's Qwopus3.5-27B-v3 — same datasets and methodology, applied to the MoE architecture.

Credits

This model is heavily inspired by and based on the work of Jackrong and his Qwopus3.5-27B-v3 training methodology. The datasets, training philosophy ("act-then-refine" paradigm), and structural reasoning approach are all derived from his research. Please check his complete training guide for the full methodology.

The key difference: we adapted his recipe from the 27B dense model to the 35B-A3B MoE architecture.

Available Quantizations

| Quantization | Size | BPW | Min VRAM | |---|---|---|---| | Q8_0 | 35 GB | 8.52 | 1x 48GB GPU | | Q6_K | 27 GB | 6.58 | 1x 32GB GPU | | Q5_K_M | 24 GB | 5.70 | 1x 32GB GPU | | Q4_K_M | 20 GB | 4.87 | 1x 24GB GPU |

Model Details

| Property | Value | |---|---| | Base Model | Qwen/Qwen3.5-35B-A3B | | Architecture | Mixture of Experts (MoE) | | Total Parameters | ~35B | | Active Parameters | ~3B per token | | Max Context | 131,072 tokens (128K) |

Benchmark Results

Qwopus MoE (Jackrong recipe) vs Opus Distilled v2 (previous QLoRA)

Benchmarked across 8 diverse tasks: coding, bug detection, reasoning, instruction following, research, and agentic planning.

| Test | Qwopus MoE | Opus Distilled v2 | Winner | |---|---|---|---| | Coding: LRU Cache | 6.9KB content | 4.8KB content | Qwopus | | Coding: Async Scraper | 8.5KB content | 7.6KB content | Qwopus | | Bug Detection | 2.5KB + 2.1KB thinking | 2.4KB + 2.9KB thinking | Tie | | Reasoning: Probability | 0 chars (stuck thinking) | 1.3KB content | v2 | | Reasoning: Logic | 747 chars | 949 chars | v2 | | JSON Output | 319 chars, 6.8s | 325 chars, 1.4s | v2 (5x faster) | | Research: Architecture Analysis | 4.5KB content | 696 chars (overthinks) | Qwopus | | Agentic: CI/CD Planning | 6.9KB content | 5.8KB content | Qwopus |

Speed

| Model | tok/s | |---|---| | Qwopus MoE | 175 | | Opus Distilled v2 | 204 |

Verdict

Qwopus MoE produces more useful visible output — better content/thinking ratio. It excels at tasks requiring detailed, user-facing responses (coding, research, planning). The Opus Distilled v2 is 16% faster but has an aggressive thinking mode that sometimes produces minimal visible content.

Best for: Coding assistants, research agents, content generation, agentic workflows where output quality matters more than raw speed.

Training Details

Recipe (adapted from Jackrong's Qwopus3.5-27B-v3)

| Parameter | Value | |---|---| | Method | QLoRA (4-bit base + LoRA adapters in BF16) | | Framework | Unsloth 2026.4.2 + TRL | | Base Model | unsloth/Qwen3.5-35B-A3B | | LoRA Rank | 32 | | LoRA Alpha | 32 | | LoRA Targets | q_proj, k_proj, v_proj, o_proj (attention only) | | Trainable Parameters | 6,881,280 (0.02% of 35B) | | Learning Rate | 2e-5 (linear schedule) | | Warmup | 5% of steps | | Weight Decay | 0.001 | | Optimizer | adamw_8bit | | Epochs | 2 | | Effective Batch Size | 12 (1 x 12 grad accum) | | Max Sequence Length | 4096 | | Total Steps | 536 | | Final Loss | 0.5517 | | GPU | NVIDIA RTX PRO 6000 Blackwell (96GB) | | Training Time | ~3.5 hours |

Differences from Jackrong's 27B recipe

| Aspect | Jackrong (27B dense) | Ours (35B-A3B MoE) | |---|---|---| | Base model | Qwen3.5-27B (dense) | Qwen3.5-35B-A3B (MoE) | | LoRA rank | 64 | 32 (GPU memory constraint) | | LoRA targets | q, k, v, o, gate, up, down | q, k, v, o only (MoE experts too large) | | Trainable params | ~0.5% | 0.02% | | Batch size | ~36 | 12 | | Context length | 8192 | 4096 (GPU memory constraint) |

Datasets (3,209 examples after quality filtering)

| Dataset | Examples | Description | |---|---|---| | nohurry/Opus-4.6-Reasoning-3000x-filtered | 2,326 | Claude Opus 4.6 reasoning traces | | Jackrong/Qwen3.5-reasoning-700x | 633 | Qwen reasoning conversations | | Roman1111111/claude-opus-4.6-10000x | ~250 (after filtering) | Claude Opus 4.6 conversations |

Quality filter: required assistant content >100 characters.

Usage with llama.cpp

llama-server \
  --model Qwopus-MoE-35B-A3B-Q8_0.gguf \
  --n-gpu-layers -1 \
  --ctx-size 131072 \
  --host 0.0.0.0 --port 8082

The model uses <think>...</think> reasoning tags natively (inherited from Qwen3.5 base).

Acknowledgements

• Jackrong — Training methodology, datasets, and the Qwopus concept
• Unsloth — Efficient QLoRA training framework
• Qwen — Base model architecture

---

license: other license_name: ltx-2-community-license tags:

• polarquant
• video-generation
• audio-video
• ltx-video
• bit-packed base_model: Lightricks/LTX-2.3 pipeline_tag: image-to-video arxiv: "2603.29078"

---

LTX-2.3 (22B) — PolarQuant Q5 (Bit-Packed)

PQ5 quantized LTX-2.3 — joint audio-video generation, 22B params.

46 GB → 15 GB (-68%) | cos_sim 0.9986 | 1,347 layers quantized

Download Size

Compression

| Component | Original | PQ5 Packed | Reduction | |---|---|---|---| | Transformer (1,347 layers) | 37 GB | 4.6 GB | -88% | | VAE + Skip (4,600 layers) | 9.1 GB | 9.1 GB | BF16 kept | | Upscalers | 1.3 GB | 1.3 GB | BF16 kept | | Total | 46.2 GB | 15 GB | -68% |

Quick Start

# 1. Install
pip install safetensors huggingface_hub scipy

# 2. Download & setup (15 GB)
git clone https://huggingface.co/caiovicentino1/LTX-2.3-22B-PolarQuant-Q5 ./LTX-PQ5
cd LTX-PQ5 && python setup.py

# 3. Generate video
python generate_ltx.py --prompt "A cat playing piano in a jazz club"

Architecture

• 22B parameters — largest video model we've quantized
• 48 transformer blocks, hidden=4096, MLP=16384
• Joint audio-video generation — synchronized audio + video
• head_dim=64 (Hadamard-compatible)
• 5,947 tensors total (BF16)
• Spatial + temporal upscalers included

Files

LTX-2.3-22B-PolarQuant-Q5/
├── setup.py                          # One-command setup
├── generate_ltx.py                   # Easy generation wrapper
├── polarquant/
│   ├── codes/
│   │   ├── chunk_00_codes.safetensors (1.5 GB)
│   │   ├── chunk_01_codes.safetensors (1.5 GB)
│   │   ├── chunk_02_codes.safetensors (1.5 GB)
│   │   └── chunk_03_codes.safetensors (0.1 GB)
│   └── bf16/
│       └── ltx23_bf16.safetensors    (9.1 GB)
└── upscalers/
    ├── ltx-2.3-spatial-upscaler-x2-1.1.safetensors  (1.0 GB)
    └── ltx-2.3-temporal-upscaler-x2-1.0.safetensors (0.3 GB)

Hardware

| GPU | VRAM | Status | |-----|------|--------| | A100 (40 GB) | 40 GB | Recommended | | A100 (80 GB) | 80 GB | Full speed | | RTX 4090 (24 GB) | 24 GB | With offloading |

Links

• PolarQuant Paper
• GitHub (PolarQuant)
• Original LTX-2.3
• LTX-2 Paper
• LTX GitHub

Citation

@article{polarquant2026,
  title={PolarQuant: Hadamard-Rotated Lloyd-Max Quantization},
  author={Vicentino, Caio},
  journal={arXiv preprint arXiv:2603.29078},
  year={2026}
}

---

46 GB → 15 GB with cos_sim 0.9986. Quantized with PolarQuant.

---

tags:

• doom
• game-ai
• ascii
• ModernBERT
• hash-embeddings
• depth-aware
• attention-pooling
• classifier
• real-time
• edge-deployment
• tiny-model pipeline_tag: text-classification library_name: transformers license: apache-2.0 datasets:
• VAGOsolutions/SauerkrautLM-Doom-MultiVec-31k

---

<img src="Logo.png" width="500" height="auto">

SauerkrautLM-Doom-MultiVec-1.3M

A tiny 1.3M parameter model that plays DOOM, outperforming LLMs up to 92,000x its size.

<video controls width="100%" style="border-radius: 8px; margin: 16px 0;"> <source src="https://vago-solutions.ai/wp-content/uploads/2026/04/1mio-parameter-plays-DOOM.mp4" type="video/mp4"> </video>

This model is a ModernBERT-Hash encoder with depth-aware token representations and an attention pooling classification head, trained on 31K human gameplay demonstrations to select actions from ASCII game frame representations in real time.

Core Features and Innovations

• 178 frags in 10 episodes (17.8 per episode) in VizDoom's defend_the_center scenario, more than all tested LLMs combined (13 frags total)
• 31ms inference on CPU, enabling real-time gameplay at 35 FPS
• Depth-aware ASCII encoding: VizDoom depth buffer encoded as learned 16-bin token embeddings fused with character embeddings
• ModernBERT-Hash architecture: Hash embeddings + local/global attention + Flash Attention 2 support
• Character-level tokenizer: 75 tokens, no BPE, preserving full spatial granularity of ASCII frames

David vs. Goliath: 1.3M Parameters vs. 120 Billion

With 1.3 million parameters -- less than 1/92,000th the size of Nemotron-120B -- SauerkrautLM-Doom-MultiVec achieves:

• 178 frags vs 0 for GPT-4o-mini (proprietary)
• 178 frags vs 3 for Nemotron-120B (120B, 92,000x larger)
• 178 frags vs 2 for Qwen3.5-27B (27B, 20,000x larger)
• 178 frags vs 8 for Gemini Flash Lite (proprietary)

All LLMs are vision-capable multimodal models evaluated on text (ASCII + depth), their strongest modality. Our tiny text-only model outperforms them on their home turf.

---

Model Overview

Model: VAGOsolutions/SauerkrautLM-Doom-MultiVec-1.3M
Architecture: ModernBERT-Hash encoder + Attention Pooling + Linear Classifier
Task: Real-time DOOM action classification from ASCII frames
Training Data: 31,645 human gameplay demonstrations with depth annotations
License: Apache 2.0
Model Size: 1.3M parameters (~5MB FP32)

Model Description

• Model Type: Multi-vector encoder with attention pooling classification head
• Encoder: 5-layer ModernBERT with hash embeddings (H=128, 4 heads)
• Tokenizer: Character-level, 75 tokens (no BPE)
• Depth Bins: 16 learned depth embeddings added to token representations
• Actions: 4 (shoot, move_forward, turn_left, turn_right)
• Max Sequence Length: 1,200 tokens
• Training Loss: KL-divergence on soft action scores
• Inference Latency: 31ms (CPU), 29ms (GPU)

Architecture

DoomMultiVecClassifier(
  encoder: ModernBertHashModel(
    embeddings: HashEmbedding(75 vocab, 16 proj -> 128 dim)
    depth_embedding: DepthEmbedding(16 bins x 128 dim)
    layers: 5x TransformerLayer(H=128, heads=4, FFN=512)
  )
  attention_pool: Linear(128 -> 1)  # learned attention weights
  classifier: Linear(128 -> 4)      # action probabilities
)

ModernBERT-Hash: Advancing Hash Embeddings to Modern Architectures

This model introduces hash embeddings on the ModernBERT architecture, a combination that has not been explored before. Previous work on hash embeddings for tiny language models (NeuML's BERT-Hash, Svenstrup et al. 2017) applied the technique to the original BERT architecture from 2018. We bring hash embeddings to ModernBERT (Warner et al. 2024), which provides several architectural advantages:

• Rotary Position Embeddings (RoPE) instead of learned absolute positions, enabling better generalization across sequence lengths
• Alternating local + global attention: Layers alternate between sliding-window local attention (w=128) and full global attention, matching the spatial structure of ASCII frames where local patterns (adjacent characters) and global context (arena layout) both matter
• Flash Attention 2 support for efficient GPU training with long sequences (~1,100 tokens per frame)
• Pre-normalization with RMSNorm for more stable training of tiny models

The hash embedding layer replaces the standard embedding table (V x H) with a two-stage projection: a compact lookup (V x P) followed by a linear projection (P x H), where P=16 is the projection dimension. For our 75-token vocabulary this reduces embedding parameters from 9,600 to 4,480 (53% reduction). While modest for a tiny vocabulary, the same architecture scales to standard vocabularies: at 30K tokens, hash embeddings reduce embedding parameters by 97% (from 3.8M to 120K), which is the key enabler for sub-1M parameter language models.

Combined with depth embeddings (16 learned bins added to token representations), the model receives both spatial (what the character looks like) and distance (how far away it is) information at the token level, a novel input representation for game state encoding.

---

Input Pipeline

<img src="pipeline.png" width="100%">

From VizDoom game frame to model input: (a) RGB frame, (b) grayscale, (c) depth buffer, (d) ASCII brightness map (40x25), (e) depth bins with 16 quantization levels (red=near, green=far), (f) combined ASCII + depth representation as fed to the model.

---

Benchmark: DOOM defend_the_center

All agents receive identical input: ASCII frame (40x25) + depth map. Game settings match training conditions (640x480, HUD on, real-time pacing). Frags are tracked via VizDoom's per-step reward signal.

| Agent | Params | Episodes | Avg Survival | Max Survival | Total Frags | Latency | |-------|--------|----------|-------------|-------------|-------------|---------| | SauerkrautLM-Doom-MultiVec-1.3M | 1.3M | 10 | 388 | 525 | 178 | 31ms | | GPT-4o-mini | proprietary | 10 | 104 | 228 | 0 | 646ms | | Nemotron-120B | 120B | 5 | 88 | 104 | 3 | 8.9s | | Qwen3.5-27B | 27B | 3 | 87 | 109 | 2 | 13.3s | | Gemini Flash Lite | proprietary | 10 | 81 | 97 | 8 | 920ms |

178 frags vs 13 for all LLMs combined. GPT-4o-mini scores zero frags across 10 episodes (pure evasion). Our model actively engages enemies, turns to face them, and fires -- playing DOOM as intended.

---

Quick Start

import torch
from transformers import AutoTokenizer

# Load model
model_path = "VAGOsolutions/SauerkrautLM-Doom-MultiVec-1.3M"
tokenizer = AutoTokenizer.from_pretrained(model_path, trust_remote_code=True)

from doom_multivec.model.classifier import DoomMultiVecClassifier
state = torch.load(f"{model_path}/model.pt", map_location="cpu")
model = DoomMultiVecClassifier(model_path, pool_mode="attention", num_actions=4)
model.load_state_dict(state)
model.eval()

# Classify an ASCII frame
ascii_frame = "." * 1024  # 40x25 ASCII frame
encoded = tokenizer(ascii_frame, return_tensors="pt", max_length=1100,
                    padding="max_length", truncation=True)

with torch.no_grad():
    result = model(encoded["input_ids"], encoded["attention_mask"])
    probs = torch.softmax(result["logits"], dim=-1)[0]

actions = ["shoot", "move_forward", "turn_left", "turn_right"]
for action, prob in zip(actions, probs):
    print(f"  {action}: {prob:.3f}")

Watch the Model Play DOOM

pip install vizdoom
python scripts/play_doom_visual.py --model models/doom-multivec-trained --scenario defend_the_center

Run the LLM Benchmark

pip install openai
export OPENAI_API_KEY="your-key"
python scripts/benchmark.py --agent multivec --episodes 10 --realtime
python scripts/benchmark.py --agent gpt4mini --episodes 10 --realtime

---

Parameter Budget

| Component | Parameters | % of Total | |-----------|-----------|------------| | Hash Embeddings (75 vocab, 16 proj) | 4,480 | 0.3% | | Depth Embeddings (17 bins x 128) | 2,176 | 0.2% | | Transformer Layers (x 5) | 1,312,000 | 99.1% | | Attention Pool + Classifier | 644 | 0.05% | | Total | 1,319,300 | 100% |

---

Paper

Playing DOOM with 1.3M Parameters: Specialized Small Models vs Large Language Models for Real-Time Game Control

David Golchinfar (VAGO Solutions, Germany), Daryoush Vaziri (University of Applied Sciences Bonn-Rhein-Sieg, Germany), Alexander Marquardt (CARE Laboratory, NAIST, Japan)

Available in the project repository under paper/doom_multivec.pdf.

---

Acknowledgements

This work was developed using VizDoom as the game platform, PyLate for initial multi-vector experiments, and the HuggingFace ecosystem for model development. The ModernBERT-Hash architecture builds on NeuML's BERT-Hash models. Training data includes human gameplay demonstrations and frames from the arnaudstiegler GameNGen reproduction datasets on HuggingFace.

DOOM is a registered trademark of id Software LLC. This project is not affiliated with or endorsed by id Software.

---

Citation

@misc{SauerkrautLM-Doom-MultiVec,
  title={SauerkrautLM-Doom-MultiVec-1.3M: Playing DOOM with 1.3M Parameters},
  author={David Golchinfar and Daryoush Vaziri and Alexander Marquardt},
  url={https://huggingface.co/VAGOsolutions/SauerkrautLM-Doom-MultiVec-1.3M},
  year={2026}
}

---

language:

• en license: gemma tags:
• gemma4
• gguf
• quantized
• 31b base_model: google/gemma-4-31b-it pipeline_tag: text-generation

---

Gemma-4-31B-JANG_4M-CRACK-GGUF

GGUF quantizations of Gemma-4-31B-JANG_4M-CRACK for use with llama.cpp, LM Studio, Ollama, and other GGUF-compatible inference engines.

About the Model

• Base model: google/gemma-4-31b-it
• Architecture: Gemma 4 Dense Transformer (31B parameters, 60 layers)
• Features: Hybrid Sliding/Global Attention, Vision + Audio multimodal
• Modification: CRACK abliteration (refusal removal) + JANG v2 mixed-precision quantization

Why This Conversion?

The original model uses JANG v2 mixed-precision MLX quantization (attention 8-bit + MLP 4-bit), which is only compatible with vMLX. Standard tools (llama.cpp, LM Studio, oMLX, mlx-lm) cannot load this format due to mixed per-layer bit widths.

This repository provides standard GGUF quantizations that work everywhere.

Conversion Process

Original (JANG v2 MLX safetensors, ~18GB)
    ↓ dequantize (attention 8-bit → f16, MLP 4-bit → f16)
Intermediate (float16 safetensors, ~60GB)
    ↓ convert_hf_to_gguf.py + quantize
GGUF (various quantizations)

Note: Since the original was already quantized (avg 5.1 bits), the dequantized f16 intermediate is an approximation. Re-quantizing to GGUF introduces minimal additional quality loss since the attention layers were preserved at 8-bit in the original.

Available Quantizations

| File | Quant | Size | Quality | Notes | |------|-------|------|---------|-------| | gemma-4-31b-jang-crack-Q3_K_M.gguf | Q3_K_M | ~14 GB | Acceptable | Minimum viable quality | | gemma-4-31b-jang-crack-Q4_K_M.gguf | Q4_K_M | ~18 GB | Good | Best size/quality balance | | gemma-4-31b-jang-crack-Q5_K_M.gguf | Q5_K_M | ~21 GB | Better | Recommended if RAM allows | | gemma-4-31b-jang-crack-Q6_K.gguf | Q6_K | ~25 GB | Very Good | High quality | | gemma-4-31b-jang-crack-Q8_0.gguf | Q8_0 | ~33 GB | Near lossless | Closest to original |

System Requirements

| Quantization | Minimum RAM | Recommended | |-------------|------------|-------------| | Q3_K_M | 20 GB | 24 GB | | Q4_K_M | 24 GB | 32 GB | | Q5_K_M | 28 GB | 36 GB | | Q6_K | 32 GB | 40 GB | | Q8_0 | 40 GB | 48 GB |

Usage

LM Studio

Download any .gguf file and open it in LM Studio.

llama.cpp

./llama-cli -m gemma-4-31b-jang-crack-Q4_K_M.gguf -p "Hello" -n 256

Ollama

echo 'FROM ./gemma-4-31b-jang-crack-Q4_K_M.gguf' > Modelfile
ollama create gemma4-crack -f Modelfile
ollama run gemma4-crack

License

Gemma License

Disclaimer

This model has had safety guardrails removed. Use responsibly and in compliance with applicable laws.

---

library_name: transformers license: apache-2.0 pipeline_tag: image-text-to-text base_model:

• Jackrong/Qwopus3.5-27B-v3 tags:
• abliterated
• uncensored
• Qwopus
• reasoning
• chain-of-thought
• Dense

---

huihui-ai/Huihui-Qwopus3.5-27B-v3-abliterated

This is an uncensored version of Jackrong/Qwopus3.5-27B-v3 created with abliteration (see remove-refusals-with-transformers to know more about it). This is a crude, proof-of-concept implementation to remove refusals from an LLM model without using TransformerLens.

ollama

Please use the latest version of ollama

You can use huihui_ai/qwen3.5-abliterated:27B-Qwopus directly,

ollama run huihui_ai/qwen3.5-abliterated:27B-Qwopus

Usage Warnings

• Risk of Sensitive or Controversial Outputs: This model’s safety filtering has been significantly reduced, potentially generating sensitive, controversial, or inappropriate content. Users should exercise caution and rigorously review generated outputs.

• Not Suitable for All Audiences: Due to limited content filtering, the model’s outputs may be inappropriate for public settings, underage users, or applications requiring high security.

• Legal and Ethical Responsibilities: Users must ensure their usage complies with local laws and ethical standards. Generated content may carry legal or ethical risks, and users are solely responsible for any consequences.

• Research and Experimental Use: It is recommended to use this model for research, testing, or controlled environments, avoiding direct use in production or public-facing commercial applications.

• Monitoring and Review Recommendations: Users are strongly advised to monitor model outputs in real-time and conduct manual reviews when necessary to prevent the dissemination of inappropriate content.

• No Default Safety Guarantees: Unlike standard models, this model has not undergone rigorous safety optimization. huihui.ai bears no responsibility for any consequences arising from its use.

Donation

Your donation helps us continue our further development and improvement, a cup of coffee can do it.

• bitcoin:

  bc1qqnkhuchxw0zqjh2ku3lu4hq45hc6gy84uk70ge

• Support our work on Ko-fi!

---

license: apache-2.0 tags:

• polarquant
• qwen3.5
• abliterated
• uncensored
• qwopus base_model: huihui-ai/Huihui-Qwopus3.5-27B-v3-abliterated arxiv: "2603.29078"

---

Qwopus3.5-27B-v3 Abliterated — PolarQuant Q5

PQ5+INT4 weights + Q3 KV cache — uncensored reasoning model on RTX 4090.

Quick Start

pip install polarquant

import polarengine_vllm
from transformers import AutoModelForCausalLM

model = AutoModelForCausalLM.from_pretrained(
    "caiovicentino1/Huihui-Qwopus3.5-27B-v3-abliterated-PolarQuant-Q5",
    device_map="auto"
)

Peak VRAM

Download Size

Results

| Metric | FP16 KV | Q3 KV | Q2 KV | |---|---|---|---| | Speed | 21.8 tok/s | 22.1 tok/s | 22.0 tok/s | | Peak VRAM | 70.4 GB | 19.1 GB | 19.1 GB |

Fits RTX 4090 (24 GB) with Q3 KV cache!

| Component | Value | |---|---| | Model VRAM | 19.1 GB | | Polar Codes | 16.4 GB (bit-packed) | | cos_sim | >0.998 |

Architecture

• Qwen3.5-27B hybrid (attention + linear attention)
• 64 layers, head_dim=128
• Abliterated (uncensored) by huihui-ai
• Base: Jackrong/Qwopus3.5-27B-v3 (Claude Opus reasoning distilled)
• Apache 2.0

Links

• PolarQuant Paper
• GitHub
• PyPI
• Base Model

---

base_model: huihui-ai/Huihui-Qwopus3.5-27B-v3-abliterated language:

• en library_name: transformers license: apache-2.0 mradermacher: readme_rev: 1 quantized_by: mradermacher tags:
• abliterated
• uncensored
• Qwopus
• reasoning
• chain-of-thought
• Dense

---

About

<!-- ### quantize_version: 2 --> <!-- ### output_tensor_quantised: 1 --> <!-- ### convert_type: hf --> <!-- ### vocab_type: --> <!-- ### tags: --> <!-- ### quants: x-f16 Q4_K_S Q2_K Q8_0 Q6_K Q3_K_M Q3_K_S Q3_K_L Q4_K_M Q5_K_S Q5_K_M IQ4_XS --> <!-- ### quants_skip: --> <!-- ### skip_mmproj: -->

static quants of https://huggingface.co/huihui-ai/Huihui-Qwopus3.5-27B-v3-abliterated

<!-- provided-files -->

For a convenient overview and download list, visit our model page for this model.

weighted/imatrix quants seem not to be available (by me) at this time. If they do not show up a week or so after the static ones, I have probably not planned for them. Feel free to request them by opening a Community Discussion.

Usage

If you are unsure how to use GGUF files, refer to one of TheBloke's READMEs for more details, including on how to concatenate multi-part files.

Provided Quants

(sorted by size, not necessarily quality. IQ-quants are often preferable over similar sized non-IQ quants)

| Link | Type | Size/GB | Notes | |:-----|:-----|--------:|:------| | GGUF | mmproj-Q8_0 | 0.7 | multi-modal supplement | | GGUF | mmproj-f16 | 1.0 | multi-modal supplement | | GGUF | Q2_K | 10.8 | | | GGUF | Q3_K_S | 12.2 | | | GGUF | Q3_K_M | 13.4 | lower quality | | GGUF | Q3_K_L | 14.4 | | | GGUF | IQ4_XS | 15.3 | | | GGUF | Q4_K_S | 15.7 | fast, recommended | | GGUF | Q4_K_M | 16.6 | fast, recommended | | GGUF | Q5_K_S | 18.8 | | | GGUF | Q5_K_M | 19.3 | | | GGUF | Q6_K | 22.2 | very good quality | | GGUF | Q8_0 | 28.7 | fast, best quality |

Here is a handy graph by ikawrakow comparing some lower-quality quant types (lower is better):

And here are Artefact2's thoughts on the matter: https://gist.github.com/Artefact2/b5f810600771265fc1e39442288e8ec9

FAQ / Model Request

See https://huggingface.co/mradermacher/model_requests for some answers to questions you might have and/or if you want some other model quantized.

Thanks

I thank my company, nethype GmbH, for letting me use its servers and providing upgrades to my workstation to enable this work in my free time.

<!-- end -->

---

base_model:

• 0xSero/gemma-4-21b-a4b-it-REAP language:
• en pipeline_tag: text-generation tags:
• gguf
• gemma4
• image-text-to-text
• moe
• pruning
• reap
• cerebras
• expert-pruning
• conversational
• llama-cpp
• quantized license: gemma arxiv: 2510.13999

---

gemma-4-21b-a4b-it-REAP — GGUF Quantizations

GGUF quantizations of 0xSero/gemma-4-21b-a4b-it-REAP, a 20% expert-pruned variant of google/gemma-4-26b-a4b-it using the REAP (Router-weighted Expert Activation Pruning) method.

Available Files

| File | Quant | Size | BPW | Description | | --- | --- | --- | --- | --- | | gemma-4-21b-a4b-it-REAP-BF16.gguf | BF16 | ~43 GB | 16.0 | Full precision, for re-quantization | | gemma-4-21b-a4b-it-REAP-Q8_0.gguf | Q8_0 | ~22 GB | 8.0 | Near-lossless, large file | | gemma-4-21b-a4b-it-REAP-Q6_K.gguf | Q6_K | ~17 GB | 6.56 | Near-lossless, recommended for high quality | | gemma-4-21b-a4b-it-REAP-Q5_K_M.gguf | Q5_K_M | ~16 GB | 5.68 | High quality, larger size | | gemma-4-21b-a4b-it-REAP-Q5_K_S.gguf | Q5_K_S | ~15 GB | 5.52 | High quality, slightly smaller | | gemma-4-21b-a4b-it-REAP-Q4_K_M.gguf | Q4_K_M | ~14 GB | 4.89 | Recommended — best quality/size balance | | gemma-4-21b-a4b-it-REAP-Q4_K_S.gguf | Q4_K_S | ~13 GB | 4.63 | 4-bit small | | gemma-4-21b-a4b-it-REAP-Q3_K_L.gguf | Q3_K_L | ~11 GB | 4.27 | 3-bit large | | gemma-4-21b-a4b-it-REAP-Q3_K_M.gguf | Q3_K_M | ~11 GB | 3.91 | 3-bit medium | | gemma-4-21b-a4b-it-REAP-Q3_K_S.gguf | Q3_K_S | ~10 GB | 3.66 | 3-bit small | | gemma-4-21b-a4b-it-REAP-Q2_K.gguf | Q2_K | ~9 GB | 2.96 | Smallest size, lowest quality |

Model Details

| Property | Value | | --- | --- | | Architecture | Gemma 4 (hybrid sliding/full attention MoE) | | Parameters | 21.34B total / ~4B active per token | | Experts | 103 total / 8 active per token | | Context Length | 262,144 tokens | | Original dtype | BF16 | | Quantization tool | llama.cpp | | License | Gemma |

Quantization Process

# 1. Convert BF16 SafeTensors → GGUF
python convert_hf_to_gguf.py 0xSero/gemma-4-21b-a4b-it-REAP \
  --outfile gemma-4-21b-a4b-it-REAP-BF16.gguf \
  --outtype bf16

# 2. Quantize (example: Q4_K_M)
llama-quantize gemma-4-21b-a4b-it-REAP-BF16.gguf \
  gemma-4-21b-a4b-it-REAP-Q4_K_M.gguf Q4_K_M

Usage

llama.cpp

llama-cli \
  -m gemma-4-21b-a4b-it-REAP-Q4_K_M.gguf \
  -ngl 99 -c 4096 \
  -p "Your prompt here"

llama-server (OpenAI-compatible API)

llama-server \
  -m gemma-4-21b-a4b-it-REAP-Q4_K_M.gguf \
  -ngl 99 -c 4096 \
  --port 8080

LM Studio / Jan / Ollama

Download the .gguf file and load it directly in your preferred local inference UI.

Hardware Requirements

| Config | VRAM / RAM | | --- | --- | | Full GPU (Q4_K_M, recommended) | 16+ GB VRAM | | Hybrid CPU+GPU (Q4_K_M) | 8 GB VRAM + 12 GB RAM | | CPU only (Q4_K_M) | 18+ GB RAM |

About the Original Model

0xSero/gemma-4-21b-a4b-it-REAP applies REAP expert pruning (arXiv:2510.13999) to remove 20% of MoE experts (25 of 128 per layer) from Gemma 4 26B-A4B-it, while preserving routing behavior. Active parameters per token remain unchanged at ~4B. The result is an ~18% smaller model with near-identical generation quality across coding, math, and reasoning benchmarks.

License

Gemma — see Google's Gemma Terms of Use.

---

base_model:

• Qwen/Qwen3-4B

tags:

• distillation
• distilled
• sft
• peft
• qwen3

datasets:

• ianncity/KIMI-K2.5-550000x
• Jackrong/Qwen3.5-reasoning-700x
• nohurry/Opus-4.6-Reasoning-3000x-filtered
• TeichAI/claude-4.5-opus-high-reasoning-250x
• TeichAI/gemini-3-pro-preview-high-reasoning-250x
• TeichAI/claude-haiku-4.5-high-reasoning-1700x
• TeichAI/gpt-5.2-high-reasoning-250x
• Roman1111111/gemini-3.1-pro-hard-high-reasoning
• Jackrong/glm-4.7-multiturn-CoT
• bmeyer2025/glm5-reasoning-traces
• TeichAI/claude-sonnet-4.5-high-reasoning-250x
• TeichAI/deepseek-v3.2-speciale-openr1-math-3k
• TeichAI/deepseek-v3.2-speciale-OpenCodeReasoning-3k
• TeichAI/deepseek-v3.2-speciale-1000x
• TeichAI/gpt-5-codex-1000x

model-index:

• name: hadadxyz/Qwen3-4B-Diversity results:
  • task: type: text-generation name: Text Generation dataset: name: Mmlu type: cais/mmlu metrics:
    • type: acc value: 67.8 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Humanities type: cais/mmlu metrics:
    • type: acc value: 57.9 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Formal Logic type: cais/mmlu metrics:
    • type: acc value: 58.7 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School European History type: cais/mmlu metrics:
    • type: acc value: 78.2 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Us History type: cais/mmlu metrics:
    • type: acc value: 84.8 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School World History type: cais/mmlu metrics:
    • type: acc value: 83.1 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu International Law type: cais/mmlu metrics:
    • type: acc value: 77.7 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Jurisprudence type: cais/mmlu metrics:
    • type: acc value: 78.7 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Logical Fallacies type: cais/mmlu metrics:
    • type: acc value: 82.8 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Moral Disputes type: cais/mmlu metrics:
    • type: acc value: 71.1 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Moral Scenarios type: cais/mmlu metrics:
    • type: acc value: 28.4 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Philosophy type: cais/mmlu metrics:
    • type: acc value: 73.3 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Prehistory type: cais/mmlu metrics:
    • type: acc value: 76.2 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Professional Law type: cais/mmlu metrics:
    • type: acc value: 47.4 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu World Religions type: cais/mmlu metrics:
    • type: acc value: 78.4 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Other type: cais/mmlu metrics:
    • type: acc value: 72.1 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Business Ethics type: cais/mmlu metrics:
    • type: acc value: 73.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Clinical Knowledge type: cais/mmlu metrics:
    • type: acc value: 75.5 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu College Medicine type: cais/mmlu metrics:
    • type: acc value: 71.1 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Global Facts type: cais/mmlu metrics:
    • type: acc value: 41.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Human Aging type: cais/mmlu metrics:
    • type: acc value: 67.7 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Management type: cais/mmlu metrics:
    • type: acc value: 84.5 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Marketing type: cais/mmlu metrics:
    • type: acc value: 85.5 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Medical Genetics type: cais/mmlu metrics:
    • type: acc value: 75.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Miscellaneous type: cais/mmlu metrics:
    • type: acc value: 79.7 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Nutrition type: cais/mmlu metrics:
    • type: acc value: 74.8 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Professional Accounting type: cais/mmlu metrics:
    • type: acc value: 55.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Professional Medicine type: cais/mmlu metrics:
    • type: acc value: 71.7 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Virology type: cais/mmlu metrics:
    • type: acc value: 53.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Social Sciences type: cais/mmlu metrics:
    • type: acc value: 78.4 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Econometrics type: cais/mmlu metrics:
    • type: acc value: 64.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Geography type: cais/mmlu metrics:
    • type: acc value: 84.3 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Government And Politics type: cais/mmlu metrics:
    • type: acc value: 87.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Macroeconomics type: cais/mmlu metrics:
    • type: acc value: 74.6 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Microeconomics type: cais/mmlu metrics:
    • type: acc value: 80.7 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Psychology type: cais/mmlu metrics:
    • type: acc value: 87.2 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Human Sexuality type: cais/mmlu metrics:
    • type: acc value: 75.6 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Professional Psychology type: cais/mmlu metrics:
    • type: acc value: 71.2 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Public Relations type: cais/mmlu metrics:
    • type: acc value: 71.8 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Security Studies type: cais/mmlu metrics:
    • type: acc value: 74.3 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Sociology type: cais/mmlu metrics:
    • type: acc value: 84.1 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Us Foreign Policy type: cais/mmlu metrics:
    • type: acc value: 81.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Stem type: cais/mmlu metrics:
    • type: acc value: 68.1 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Abstract Algebra type: cais/mmlu metrics:
    • type: acc value: 45.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Anatomy type: cais/mmlu metrics:
    • type: acc value: 61.5 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Astronomy type: cais/mmlu metrics:
    • type: acc value: 78.9 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu College Biology type: cais/mmlu metrics:
    • type: acc value: 83.3 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu College Chemistry type: cais/mmlu metrics:
    • type: acc value: 54.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu College Computer Science type: cais/mmlu metrics:
    • type: acc value: 69.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu College Mathematics type: cais/mmlu metrics:
    • type: acc value: 58.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu College Physics type: cais/mmlu metrics:
    • type: acc value: 53.9 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Computer Security type: cais/mmlu metrics:
    • type: acc value: 80.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Conceptual Physics type: cais/mmlu metrics:
    • type: acc value: 77.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Electrical Engineering type: cais/mmlu metrics:
    • type: acc value: 76.6 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Elementary Mathematics type: cais/mmlu metrics:
    • type: acc value: 65.6 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Biology type: cais/mmlu metrics:
    • type: acc value: 86.1 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Chemistry type: cais/mmlu metrics:
    • type: acc value: 70.4 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Computer Science type: cais/mmlu metrics:
    • type: acc value: 86.0 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Mathematics type: cais/mmlu metrics:
    • type: acc value: 42.6 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Physics type: cais/mmlu metrics:
    • type: acc value: 62.9 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu High School Statistics type: cais/mmlu metrics:
    • type: acc value: 71.3 name: accuracy
  • task: type: text-generation name: Text Generation dataset: name: Mmlu Machine Learning type: cais/mmlu metrics:
    • type: acc value: 57.1 name: accuracy

pipeline_tag: text-generation

library_name: transformers

license: apache-2.0

license_link: https://huggingface.co/hadadxyz/Qwen3-4B-Diversity/blob/main/LICENSE

Introduction

Qwen3-4B-Diversity is a fine-tuned language model based on Qwen/Qwen3-4B that has been trained on a diverse collection of high-quality reasoning datasets. This model combines knowledge distilled from various state-of-the-art AI systems to provide enhanced reasoning capabilities across multiple domains including mathematics, coding, general problem-solving, and multi-turn conversations.

Training Configuration

The model was trained using supervised fine-tuning techniques with parameter-efficient methods to optimize performance while maintaining computational efficiency. Key training parameters include:

| Parameter | Value | |------------------|--------| | Number of Epochs | 2 | | Context Length | 40,960 |

Hardware and Resources

| Resource | Specification | |-------------------|------------------------| | GPU | A100-80GB | | Training Duration | Approximately 17 hours | | Estimated Cost | $27 to $30 |

Training Data

| Dataset | Rows Used | Model | |--------------------------------------------------------------------------------------------------------------------------------------------|------------|------------------------------------| | ianncity/KIMI-K2.5-550000x (General-Distillation) | 1,000 | Kimi K2.5 | | Jackrong/Qwen3.5-reasoning-700x | 633 | Qwen3.5 | | nohurry/Opus-4.6-Reasoning-3000x-filtered | 2,326 | Claude Opus 4.6 | | TeichAI/claude-4.5-opus-high-reasoning-250x | 250 | Claude Opus 4.5 | | TeichAI/gemini-3-pro-preview-high-reasoning-250x | 248 | Gemini 3 Pro | | TeichAI/claude-haiku-4.5-high-reasoning-1700x | 1,688 | Claude Haiku 4.5 | | TeichAI/gpt-5.2-high-reasoning-250x | 249 | GPT-5.2 | | Roman1111111/gemini-3.1-pro-hard-high-reasoning | 3,150 | Gemini 3.1 Pro | | Jackrong/glm-4.7-multiturn-CoT | 5,090 | GLM-4.7 | | bmeyer2025/glm5-reasoning-traces | 1,744 | GLM-5 | | TeichAI/claude-sonnet-4.5-high-reasoning-250x | 247 | Claude Sonnet 4.5 | | TeichAI/deepseek-v3.2-speciale-openr1-math-3k | 3,317 | DeepSeek V3.2-Speciale | | TeichAI/deepseek-v3.2-speciale-OpenCodeReasoning-3k | 2,953 | DeepSeek V3.2-Speciale | | TeichAI/deepseek-v3.2-speciale-1000x | 991 | DeepSeek V3.2-Speciale | | TeichAI/gpt-5-codex-1000x | 991 | GPT-5 Codex | | Total | 24,877 | Combined diverse reasoning dataset |

Model Capabilities

This model excels in several key areas:

1. Advanced Reasoning: The model can break down complex problems into steps and provide detailed reasoning processes.

2. Mathematical Problem Solving: Enhanced capabilities for mathematical reasoning and problem-solving through dedicated math-focused datasets.

3. Code Generation and Understanding: Improved coding abilities from multiple code-reasoning datasets including DeepSeek and GPT-5 Codex data.

4. Multi-Turn Conversations: Better handling of extended dialogues and context-aware responses.

5. Domain Versatility: Exposure to reasoning patterns from various AI systems provides flexibility across different domains and task types.

Usage

Quick Demo

If you are looking for a quick demo that is completely free and without any cost, you can use Google Colab.

Ollama (Local)

# https://ollama.com/hadad/qwen3-4bd

# hadad/qwen3-4bd:Q8_0  |  4.3GB
# hadad/qwen3-4bd:BF16  |  8.1GB

# ollama pull hadad/qwen3-4bd:Q8_0

ollama run hadad/qwen3-4bd:Q8_0

If you are using Ollama and are interested in tools or function calling, it is recommended to use the OpenAI-compatible API provided by Ollama. This approach is more powerful.

Refer to the Ollama documentation.

Python (Local)

#pip install transformers==4.56.2

from transformers import AutoModelForCausalLM, AutoTokenizer

model_name = "hadadxyz/Qwen3-4B-Diversity"

# load the tokenizer and the model
tokenizer = AutoTokenizer.from_pretrained(model_name)
model = AutoModelForCausalLM.from_pretrained(
    model_name,
    torch_dtype="auto",
    device_map="auto"
)

# prepare the model input
prompt = "Give me a short introduction to large language model."
messages = [
    {"role": "user", "content": prompt}
]
text = tokenizer.apply_chat_template(
    messages,
    tokenize=False,
    add_generation_prompt=True,
    enable_thinking=True # Switches between thinking and non-thinking modes. Default is True.
)
model_inputs = tokenizer([text], return_tensors="pt").to(model.device)

# conduct text completion
generated_ids = model.generate(
    **model_inputs,
    max_new_tokens=32768
)
output_ids = generated_ids[0][len(model_inputs.input_ids[0]):].tolist() 

# parsing thinking content
try:
    # rindex finding 151668 (</think>)
    index = len(output_ids) - output_ids[::-1].index(151668)
except ValueError:
    index = 0

thinking_content = tokenizer.decode(output_ids[:index], skip_special_tokens=True).strip("\n")
content = tokenizer.decode(output_ids[index:], skip_special_tokens=True).strip("\n")

print("thinking content:", thinking_content)
print("content:", content)

Inference Parameters

For optimal results, we recommend the following generation parameters:

Thinking

| Parameter | Recommended Value | Description | |-----------------|-------------------|------------------------------------------| | temperature | 0.6 | Controls randomness in generation | | top_p | 0.95 | Nucleus sampling threshold | | top_k | 20 | Top-k sampling parameter | | min_p | 0 | Minimum probability threshold |

Non-Thinking

| Parameter | Recommended Value | Description | |-----------------|-------------------|------------------------------------------| | temperature | 0.7 | Controls randomness in generation | | top_p | 0.8 | Nucleus sampling threshold | | top_k | 20 | Top-k sampling parameter | | min_p | 0 | Minimum probability threshold |

Citation

If you use this model in your research or applications, please cite both this model and the base model:

@misc{qwen3-4b-diversity,
  author = {hadadxyz},
  title  = {Qwen3-4B-Diversity},
  year   = {2026},
  url    = {https://huggingface.co/hadadxyz/Qwen3-4B-Diversity}
}

Acknowledgments

This model was made possible through the combination of multiple high-quality datasets from the community. We acknowledge and thank all dataset creators and the Qwen team for providing the excellent base model.

---

language:

• en
• zh license: apache-2.0 tags:
• qwen3.5
• moe
• reasoning
• distillation
• claude-opus
• qlora
• unsloth base_model: Qwen/Qwen3.5-35B-A3B datasets:
• nohurry/Opus-4.6-Reasoning-3000x-filtered
• Jackrong/Qwen3.5-reasoning-700x
• Roman1111111/claude-opus-4.6-10000x

---

Qwopus MoE 35B-A3B — Claude Opus 4.6 Reasoning Distilled

QLoRA fine-tune of Qwen3.5-35B-A3B (MoE, 3B active parameters) with Claude Opus 4.6 reasoning distillation. Training recipe adapted from Jackrong's Qwopus3.5-27B-v3.

This is the full BF16 safetensors model. For GGUF quantizations (Q4, Q5, Q6, Q8), see samuelcardillo/Qwopus-MoE-35B-A3B-GGUF.

Credits

This model is based on the work of Jackrong and his Qwopus3.5-27B-v3 training methodology — same datasets, same philosophy, adapted for the MoE architecture. See his complete training guide.

Model Details

| Property | Value | |---|---| | Base Model | Qwen/Qwen3.5-35B-A3B | | Architecture | Mixture of Experts (MoE) | | Total Parameters | ~35B | | Active Parameters | ~3B per token | | Precision | BF16 |

Training Details

| Parameter | Value | |---|---| | Method | QLoRA (4-bit base + LoRA in BF16) | | Framework | Unsloth 2026.4.2 + TRL | | LoRA Rank | 32 | | LoRA Alpha | 32 | | LoRA Targets | q_proj, k_proj, v_proj, o_proj | | Trainable Parameters | 6,881,280 (0.02%) | | Epochs | 2 | | Final Loss | 0.5517 | | GPU | NVIDIA RTX PRO 6000 Blackwell (96GB) | | Training Time | ~3.5 hours |

Datasets (3,209 examples)

| Dataset | Examples | |---|---| | nohurry/Opus-4.6-Reasoning-3000x-filtered | 2,326 | | Jackrong/Qwen3.5-reasoning-700x | 633 | | Roman1111111/claude-opus-4.6-10000x | ~250 |

Usage

from transformers import AutoModelForCausalLM, AutoTokenizer

model = AutoModelForCausalLM.from_pretrained(
    "samuelcardillo/Qwopus-MoE-35B-A3B",
    torch_dtype="bfloat16",
    trust_remote_code=True,
)
tokenizer = AutoTokenizer.from_pretrained(
    "samuelcardillo/Qwopus-MoE-35B-A3B",
    trust_remote_code=True,
)

Acknowledgements

• Jackrong — Training methodology and the Qwopus concept
• Unsloth — QLoRA training framework
• Qwen — Base model