---

base_model:

• google/gemma-3-270m-it
• huihui-ai/Huihui-gemma-3-270m-it-abliterated
• AxionLab-official/DogeAI-v1.5-Coder
• gokaygokay/prompt-enhancer-gemma-3-270m-it
• broadfield-dev/gemma-3-270m-tuned-0106-1020-tuned-0106-1726 library_name: transformers tags:
• mergekit
• merge datasets:
• microsoft/rStar-Coder
• gokaygokay/prompt-enhancement-75k
• gokaygokay/prompt-enhancer-dataset

---

Gemma-3-Prompt-Coder-270m-it (Uncensored)

This is a merge of pre-trained language models created using mergekit.

Merge Details

Merge Method

This model was merged using the SLERP merge method.

Models Merged

The following models were included in the merge:

• huihui-ai-Huihui-gemma-3-270m-it-abliterated
• AxionLab-official-DogeAI-v1.5-Coder
• gokaygokay-prompt-enhancer-gemma-3-270m-it
• broadfield-dev-gemma-3-270m-tuned-0106-1726

1. This Is a fine-tuned model based on google/gemma-3-270m-it for enhancing and expanding short prompts into detailed, context-rich descriptions.
2. This is an uncensored version of google/gemma-3-270m-it, achieved through fine-tuning with the TRL framework.
3. This model is a fine-tuned version of google/gemma-3-270m-it on the microsoft/rStar-Coder dataset.

****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.

---

license: other license_name: paramtatva-commercial license_link: LICENSE language:

• sa tags:
• reinforcement-learning
• ppo
• mujoco
• hopper
• gymnasium
• robotics
• sanskrit
• eval_results datasets:
• custom metrics:
• reward model-index:
• name: sanskrit-ppo-hopper-v5 results:
  • task: type: reinforcement-learning name: Continuous Control dataset: type: gymnasium name: Hopper-v5 metrics:
    • type: mean_reward value: 3183.2 name: Best Return (seed=3, 2M steps)
  • task: type: reinforcement-learning name: Continuous Control dataset: type: gymnasium name: Walker2d-v5 metrics:
    • type: mean_reward value: 4918.5 name: Best Return (seed=42, 3M steps)
  • task: type: reinforcement-learning name: Continuous Control dataset: type: gymnasium name: HalfCheetah-v5 metrics:
    • type: mean_reward value: 5803.9 name: Best Return (seed=2, 3M steps, still training)
  • task: type: reinforcement-learning name: Continuous Control dataset: type: gymnasium name: Reacher-v5 metrics:
    • type: mean_reward value: -4.2 name: Best Return (seeds 1,3)

---

<p align="center"> <img src="banner.png" alt="Sanskrit-PPO Banner" width="100%"> </p>

🕉️ Sanskrit-PPO: Hopper-v5 SOTA

2979.5 peak reward on Hopper-v5 — 125% of the CleanRL benchmark (2382 ± 271).

This is the base PPO policy from the SanskritLM project — a research initiative by ParamTatva.org exploring how Sanskrit linguistic embeddings can drive robotic control. This release establishes the SOTA baseline; the Sanskrit-conditioned multi-task policy (which accepts behavioral commands in Sanskrit) is coming in a future release.

What's in This Release

| File | Description | |---|---| | hopper_v5_sota.pt | Trained PPO weights (135 KB) — 125% of CleanRL SOTA | | model.py | Agent architecture (2-layer MLP, ~10K params) | | train.py | Fully reproducible training script | | inference.py | CLI inference tool with --render support |

Results

| Metric | Value | |---|---| | Peak avg return (last 20) | 2979.5 | | Best checkpoint return | 2731.3 | | CleanRL benchmark | 2382 ± 271 | | Our ratio vs SOTA | 125% | | Training time | ~1 hour (single GPU) | | Steps to SOTA | ~300K of 1M |

Training Curve

Update  50  | 102K steps | Return:  716
Update  80  | 163K steps | Return: 2023
Update 150  | 307K steps | Return: 2296
Update 230  | 471K steps | Return: 2620
Update 375  | 768K steps | Return: 2731
PEAK                     | Return: 2979  ← 125% of CleanRL SOTA

Architecture

| Component | Details | |---|---| | Algorithm | PPO (Proximal Policy Optimization) | | Actor | MLP: 11 → 64 → 64 → 3, Tanh activations | | Critic | MLP: 11 → 64 → 64 → 1, Tanh activations | | Initialization | Orthogonal (√2 hidden, 0.01 actor, 1.0 critic) | | Parameters | ~10K |

The Key Insight: Environment Wrappers

The breakthrough was using Gymnasium's built-in normalization wrappers. Without them, PPO plateaus at ~474. With them: 2979.

env = gym.make("Hopper-v5")
env = gym.wrappers.RecordEpisodeStatistics(env)
env = gym.wrappers.FlattenObservation(env)
env = gym.wrappers.NormalizeObservation(env)
env = gym.wrappers.NormalizeReward(env, gamma=0.99)

Full investigation: The 371 Wall — A Detective Story

Quick Start

Inference

import torch
import gymnasium as gym
from model import Agent

agent = Agent(obs_dim=11, act_dim=3)
ckpt = torch.load("hopper_v5_sota.pt", map_location="cpu")
agent.load_state_dict(ckpt["model_state_dict"])
agent.eval()

env = gym.make("Hopper-v5", render_mode="human")
obs, _ = env.reset()
total_reward = 0

for _ in range(1000):
    with torch.no_grad():
        action, _, _, _ = agent.get_action_and_value(
            torch.FloatTensor(obs).unsqueeze(0)
        )
    obs, reward, term, trunc, _ = env.step(action.numpy().flatten())
    total_reward += reward
    if term or trunc: break

print(f"Episode reward: {total_reward:.0f}")

Train from Scratch

pip install gymnasium[mujoco] torch numpy
python train.py

~1 hour on a single GPU (T4/A100), ~4 hours on CPU.

🕉️ Coming Soon: Sanskrit-Conditioned Multi-Task Policy

This release is the base PPO agent — it takes raw observations and produces actions without any language conditioning.

The full SanskritLM pipeline adds a proprietary encoder that accepts behavioral commands in Sanskrit (Devanagari script) and conditions the policy via Feature-wise Linear Modulation (FiLM). A single policy learns multiple behaviors from Sanskrit commands:

| Sanskrit Command | Transliteration | Meaning | Behavior | |---|---|---|---| | अग्रे गच्छ | agre gaccha | "go forward" | Forward locomotion | | पृष्ठतः गच्छ | pṛṣṭhataḥ gaccha | "go backward" | Backward locomotion | | ऊर्ध्वं कूर्द | ūrdhvaṃ kūrda | "jump up" | Hopping/jumping | | तिष्ठ | tiṣṭha | "stand still" | Stationary balance |

Why Sanskrit? Sanskrit's compositional morphology (sandhi, vibhakti, dhātu system) produces inherently structured embeddings. A single verb root (dhātu) encodes motion type, direction, intensity, and aspect — information that requires multiple English words. This linguistic density gives the encoder a natural advantage for encoding complex behavioral commands.

The multi-task release will include:

• Sanskrit-conditioned policy weights for Hopper, HalfCheetah, Walker2d, Humanoid, Ant, and Reacher
• The encoder interface (commands must be in Sanskrit — use an LLM or translation API to generate Devanagari input)
• Multi-environment benchmark results

🔔 Watch this repo for the multi-task release, or visit ParamTatva.org for updates.

Hyperparameters

| Parameter | Value | |---|---| | Total timesteps | 1,000,000 | | Learning rate | 3e-4 (linear anneal) | | Rollout steps | 2,048 | | Minibatch size | 64 | | Update epochs | 10 | | Gamma | 0.99 | | GAE Lambda | 0.95 | | Clip coefficient | 0.2 | | Value function clipping | ✓ | | Entropy coefficient | 0.0 | | Value loss coefficient | 0.5 | | Max gradient norm | 0.5 | | Seed | 1 |

License

Released under the ParamTatva Commercial License. See LICENSE.

• ✅ Academic research and evaluation
• ✅ Personal/educational use
• ❌ Commercial deployment requires a separate license
• ❌ Redistribution of weights without attribution

Citation

@misc{paramtatva2026ppohopper,
  title={Sanskrit-PPO: SOTA Reinforcement Learning with Linguistic Embeddings},
  author={ParamTatva Research},
  year={2026},
  url={https://huggingface.co/paramtatva/sanskrit-ppo-hopper-v5}
}

Contact

For commercial licensing and multi-task model access, contact the ParamTatva team at ParamTatva.org.

---

license: other license_name: circlestone-labs-non-commercial-license license_link: https://huggingface.co/circlestone-labs/Anima/raw/main/LICENSE.md tags:

• diffusion-single-file
• comfyui base_model:
• circlestone-labs/Anima base_model_relation: quantized

---

Quantized weights using Learned Rounding indended for ComfyUI

Original Model Card:

<img src="https://huggingface.co/circlestone-labs/Anima/resolve/main/example.png" width="400">

Anima is a 2 billion parameter text-to-image model created via a collaboration between CircleStone Labs and Comfy Org. It is focused mainly on anime concepts, characters, and styles, but is also capable of generating a wide variety of other non-photorealistic content. The model is designed for making illustrations and artistic images, and will not work well at realism.

It is trained on several million anime images and about 800k non-anime artistic images. No synthetic data was used for training. The knowledge cut-off date for the anime training data is September 2025.

This preview version is an intermediate model checkpoint. The model is still training and the final version will improve, especially for fine details and overall aesthetics.

Installing and running

The model is natively supported in ComfyUI. The above image contains a workflow; you can open it in ComfyUI or drag-and-drop to get the workflow. The model files go in their respective folders inside your model directory:

• anima-preview.safetensors goes in ComfyUI/models/diffusion_models
• qwen_3_06b_base.safetensors goes in ComfyUI/models/text_encoders
• qwen_image_vae.safetensors goes in ComfyUI/models/vae (this is the Qwen-Image VAE, you might already have it)

Generation settings

• The preview version should be used at about 1MP resolution. E.g. 1024x1024, 896x1152, 1152x896, etc.
• 30-50 steps, CFG 4-5.
• A variety of samplers work. Some of my favorites:
  • er_sde: neutral style, flat colors, sharp lines. I use this as a reasonable default.
  • euler_a: Softer, thinner lines. Can sometimes tend towards a 2.5D look. CFG can be pushed a bit higher than other samplers without burning the image.
  • dpmpp_2m_sde_gpu: similar in style to er_sde but can produce more variety and be more "creative". Depending on the prompt it can get too wild sometimes.

Prompting

The model is trained on Danbooru-style tags, natural language captions, and combinations of tags and captions.

Tag order

[quality/meta/year/safety tags] [1girl/1boy/1other etc] [character] [series] [artist] [general tags]

Within each tag section, the tags can be in arbitrary order.

Quality tags

Human score based: masterpiece, best quality, good quality, normal quality, low quality, worst quality

PonyV7 aesthetic model based: score_9, score_8, ..., score_1

You can use either the human score quality tags, the aesthetic model tags, both together, or neither. All combinations work.

Time period tags

Specific year: year 2025, year 2024, ...

Period: newest, recent, mid, early, old

Meta tags

highres, absurdres, anime screenshot, jpeg artifacts, official art, etc

Safety tags

safe, sensitive, nsfw, explicit

Artist tags

Prefix artist with @. E.g. "@big chungus". You must put @ in front of the artist. The effect will be very weak if you don't.

Full tag example

year 2025, newest, normal quality, score_5, highres, safe, 1girl, oomuro sakurako, yuru yuri, @nnn yryr, smile, brown hair, hat, solo, fur-trimmed gloves, open mouth, long hair, gift box, fang, skirt, red gloves, blunt bangs, gloves, one eye closed, shirt, brown eyes, santa costume, red hat, skin fang, twitter username, white background, holding bag, fur trim, simple background, brown skirt, bag, gift bag, looking at viewer, santa hat, ;d, red shirt, box, gift, fur-trimmed headwear, holding, red capelet, holding box, capelet

Tag dropout

The model was trained with random tag dropout. You don't need to include every single relevant tag for the image.

Dataset tags

To improve style and content diversity, the model was additionally trained on two non-anime datasets: LAION-POP (specifically the ye-pop version) and DeviantArt. Both were filtered to exclude photos. Because these datasets are qualitatively different from anime datasets, captions from them have been labeled with a "dataset tag". This occurs at the very beginning of a prompt followed by a newline. Optionally, the second line can contain either the image alt-text (ye-pop) or the title of the work (DeviantArt). Examples:

ye-pop<br> For Sale: Others by Arun Prem<br> Abstract, oil painting of three faceless, blue-skinned figures. Left: white, draped figure; center: yellow-shirted, dark-haired figure; right: red-veiled, dark-haired figure carrying another. Bold, textured colors, minimalist style.

deviantart<br> Flame<br> Digital painting of a fiery dragon with glowing yellow eyes, black horns, and a long, sinuous tail, perched on a glowing, molten rock formation. The background is a gradient of dark purple to orange.

Natural language prompting tips

• If using pure natural langauge, more descriptive is better. Aim for at least 2 sentences. Extremely short prompts can give unexpected results (this will be better in the final version).
• You can mix tags and natural language in arbitrary order.
• You can put quality / artist tags at the beginning of a natural language prompt.
  • "masterpiece, best quality, @big chungus. An anime girl with medium-length blonde hair is..."
• Name a character, then describe their basic appearance.
  • "Digital artwork of Fern from Sousou no Frieren, with long purple hair and purple eyes, wearing a black coat over a white dress with puffy sleeves..."
  • This is extra important when prompting for multiple characters. If you just list off character names with no description of appearance, the model can get confused.

Model comparison

You may be interested in comparing Anima's outputs with other models. A ComfyUI workflow, anima_comparison.json, is provided. This workflow generates a grid of images where each model is a column and the rows are different seeds. It can be configured to compare any number of models you select by changing a few output nodes. Supported model architectures: Anima, SDXL, Lumina, Chroma, Newbie-Image. The default configuration compares Anima, NetaYume, and Newbie-Image.

Limitations

• The model doesn't do realism well. This is intended. It is an anime / illustration / art focused model.
• The model may generate undesired content, especially if the prompt is short or lacking details.
  • Avoid this by using the appropriate safety tags in the positive and negative prompts, and by writing sufficiently detailed prompts.
• The model isn't great at text rendering. It can generally do single words and sometimes short phrases, but lengthy text rendering won't work well.
• The preview model isn't that good at higher resolutions yet.
  • It is a medium-resolution intermediate checkpoint, trained on a small amount of high-res images.
  • The final version will have been trained on a dedicated high-res phase. Details and overall image composition will improve.
• The preview model is a true base model. It hasn't been aesthetic tuned on a curated dataset. The default style is very plain and neutral, which is especially apparent if you don't use artist or quality tags.

License

This model is licensed under the CircleStone Labs Non-Commercial License. The model and derivatives are only usable for non-commercial purposes. Additionally, this model constitutes a "Derivative Model" of Cosmos-Predict2-2B-Text2Image, and therefore is subject to the NVIDIA Open Model License Agreement insofar as it applies to Derivative Models.

The details of the commercial licensing process are still being worked out. For now, you can express your interest in acquiring a commercial license by emailing tdrussell1@proton.me

Built on NVIDIA Cosmos.

---

license: creativeml-openrail-m

https://civitai.com/models/376130?modelVersionId=2648201

---

license: apache-2.0 datasets:

• tomg-group-umd/wikipedia-en-2k-samples
• BASF-AI/WikipediaEasy10Classification language:
• en

---

SLiNeP

Super Low Parameter Wikipedia-based Neural Predictor Super small gpt 2 based model trained from 11.6 Mb of wikipedia data.

Each topic starts with Topic Name : Topic Text and ends with <|endmsg|>. This is the giant version repo. The model will be done fully trained by feb 14th.

---

base_model: MuXodious/GLM-4.7-Flash-REAP-23B-A3B-absolute-heresy language:

• en library_name: transformers license: mit license_link: https://huggingface.co/zai-org/GLM-4.7-Flash/blob/main/LICENSE mradermacher: readme_rev: 1 quantized_by: mradermacher tags:
• glm
• MOE
• pruning
• compression
• heretic
• uncensored
• decensored
• abliterated

---

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/MuXodious/GLM-4.7-Flash-REAP-23B-A3B-absolute-heresy

<!-- 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 | Q2_K | 8.6 | | | GGUF | Q3_K_M | 11.2 | lower quality | | GGUF | Q4_K_S | 13.2 | fast, recommended | | GGUF | Q6_K | 19.0 | very good quality | | GGUF | Q8_0 | 24.6 | 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 -->

---

language:

• da tags:
• text-to-speech
• tts
• danish
• kanade license: apache-2.0 pipeline_tag: text-to-speech

---

Plapre Compact - Danish Text-to-Speech

A compact Danish TTS model based on SmolLM2-360M with a stripped vocabulary optimized for speech synthesis.

Architecture

• Base model: SmolLM2-360M-Instruct (transformer layers)
• Vocab: 12,885 tokens (compact - only phoneme + audio tokens, no unused text tokens)
• Parameters: 327M
• Audio tokenizer: Kanade (frothywater/kanade-25hz-clean) - 12,800 codebook, 25 tokens/sec, 24kHz
• Phonemizer: espeak-ng (Danish)
• Speaker embedding: 128-dim global embedding from Kanade (supports voice cloning)

How It Works

Text -> espeak-ng phonemizer -> phoneme tokens -> model generates audio tokens -> Kanade vocoder -> waveform

The model uses a simple sequence format:

<phonemes><phone_h><phone_ɑ><phone_j></phonemes><audio><audio_100><audio_200>...</audio><eos>

Usage

Install dependencies

pip install torch transformers phonemizer soundfile
pip install git+https://github.com/frothywater/kanade-tokenizer

You also need espeak-ng installed:

# Ubuntu/Debian
apt-get install espeak-ng

# macOS
brew install espeak-ng

Quick start

import torch
import soundfile as sf
from phonemizer import phonemize
from transformers import AutoModelForCausalLM, AutoTokenizer
from kanade_tokenizer import KanadeModel, load_vocoder, vocode

AUDIO_TOKEN_START = 85
AUDIO_TOKEN_END = 12884

device = torch.device("cuda" if torch.cuda.is_available() else "cpu")

# Load model
tokenizer = AutoTokenizer.from_pretrained("syvai/plapre-compact")
model = AutoModelForCausalLM.from_pretrained(
    "syvai/plapre-compact", torch_dtype=torch.bfloat16
).to(device).eval()

# Load Kanade vocoder
kanade = KanadeModel.from_pretrained("frothywater/kanade-25hz-clean").eval().to(device)
vocoder = load_vocoder(kanade.config.vocoder_name).to(device)

# Phonemize Danish text
text = "Hej, hvordan har du det?"
phones = phonemize(
    [text], language="da", backend="espeak",
    strip=True, preserve_punctuation=True, language_switch="remove-flags"
)[0].strip()

# Build prompt tokens
phone_ids = [
    tokenizer.convert_tokens_to_ids(f"<phone_{c}>")
    for c in phones
    if tokenizer.convert_tokens_to_ids(f"<phone_{c}>") != tokenizer.unk_token_id
]
ps = tokenizer.convert_tokens_to_ids("<phonemes>")
pe = tokenizer.convert_tokens_to_ids("</phonemes>")
a_s = tokenizer.convert_tokens_to_ids("<audio>")
a_e = tokenizer.convert_tokens_to_ids("</audio>")

ids = [ps] + phone_ids + [pe, a_s]
input_ids = torch.tensor([ids], device=device)

# Generate audio tokens
with torch.no_grad():
    out = model.generate(
        input_ids=input_ids, max_new_tokens=500, do_sample=True,
        temperature=0.8, top_p=0.95, top_k=50,
        eos_token_id=[a_e, tokenizer.eos_token_id],
        pad_token_id=tokenizer.eos_token_id,
    )

# Extract and decode
gen = out[0].tolist()[len(ids):]
kanade_idx = [t - AUDIO_TOKEN_START for t in gen if AUDIO_TOKEN_START <= t <= AUDIO_TOKEN_END]

global_emb = torch.zeros(128, dtype=torch.float32, device=device)  # neutral voice
tokens_t = torch.tensor(kanade_idx, dtype=torch.long, device=device)

with torch.no_grad():
    mel = kanade.decode(content_token_indices=tokens_t, global_embedding=global_emb)
    waveform = vocode(vocoder, mel.unsqueeze(0))

sf.write("output.wav", waveform.squeeze().cpu().numpy(), 24000)

Voice cloning

Clone a voice by extracting a speaker embedding from a reference wav:

import torchaudio

wav, sr = torchaudio.load("reference_speaker.wav")
if sr != 24000:
    wav = torchaudio.functional.resample(wav, sr, 24000)

with torch.no_grad():
    features = kanade.encode(wav.to(device))
global_emb = features.global_embedding  # use this instead of zeros

CLI inference

# Basic usage
python inference_tts.py --text "Hej, hvordan har du det?"

# With voice cloning
python inference_tts.py --text "Hej verden" --speaker-wav reference.wav --output cloned.wav

# Adjust generation parameters
python inference_tts.py --text "Godmorgen" --temperature 0.7 --top-k 30

Training Details

• Dataset: CoRal-TTS + CoRal-v2 read_aloud (208,244 samples, 339 hours, 538 speakers)
• Tokenization: Kanade 25Hz audio tokens + espeak-ng Danish phonemes
• Training: 5 epochs, LR 5e-3, cosine schedule, 20% warmup, effective batch size 32
• Best checkpoint: epoch 4, val_loss 4.07, audio_accuracy 3.3%

Token Layout

| ID Range | Count | Description | |----------|-------|-------------| | 0 | 1 | <pad> | | 1 | 1 | <eos> | | 2 | 1 | <unk> | | 3-6 | 4 | Separators: <phonemes>, </phonemes>, <audio>, </audio> | | 7-84 | 78 | Phoneme tokens (<phone_X>) | | 85-12884 | 12,800 | Audio tokens (<audio_0> to <audio_12799>) |

Limitations

• Danish language only
• Requires espeak-ng for phonemization
• Audio quality depends on the Kanade vocoder
• Short utterances (< 1s) may be less stable

---

license: apache-2.0

---

license: mit