moonshine-tiny-ar: transcribe.cpp GGUF
GGUF conversions of UsefulSensors/moonshine-tiny-ar for use with transcribe.cpp.
Ported from upstream commit 99e7fee, pinned 2026-05-12. Validated against the transformers reference at transcribe.cpp commit 90bf720 on 2026-05-12.
UsefulSensors' Moonshine tiny fine-tuned on Arabic. Same encoder-decoder transformer architecture as moonshine-tiny (27M parameters): consumes 16 kHz raw PCM via a three-layer Conv1d stem (no STFT, no mel filterbank) and emits transcript-only output. Single-language (ar); no translation, no language detection, no timestamps.
Downloads
| Quantization | Download | Size | WER (FLEURS ar test) |
|---|---|---|---|
| F32 | moonshine-tiny-ar-F32.gguf | 105 MB | 27.11% |
| F16 | moonshine-tiny-ar-F16.gguf | 57 MB | 27.11% |
| Q8_0 | moonshine-tiny-ar-Q8_0.gguf | 34 MB | 26.79% |
WER measured on the FLEURS-ar test split (428 utterances) using the transcribe.cpp default decode (greedy, num_beams=1, max_length=192 — matching the upstream generation_config).
UsefulSensors does not publish a per-language WER number
for this variant. As a comparable baseline we ran the Transformers F32
reference (MoonshineForConditionalGeneration, fp32 on MPS) on the
same manifest: 27.13% WER. The C++ F32/F16 numbers
above match the reference within bootstrap-CI noise; Q8_0 introduces
a small additional drift from F16 (typically within 0.1pp).
Usage
Build transcribe.cpp from source:
git clone git@github.com:handy-computer/transcribe.cpp.git
cd transcribe.cpp
cmake -B build && cmake --build build
Run on a 16 kHz mono WAV:
build/bin/transcribe-cli \
-m moonshine-tiny-ar-Q8_0.gguf \
input.wav
If your audio isn't already 16 kHz mono WAV, convert it first:
ffmpeg -i input.mp3 -ar 16000 -ac 1 output.wav
See the transcribe.cpp model page for performance numbers, numerical validation, and reproduction steps.
License
Inherited from the base model: MIT. See the upstream model card for full terms.
Original Model Card
The section below is reproduced from UsefulSensors/moonshine-tiny-ar at commit
99e7feefor offline reference. The upstream card is the authoritative source.
Moonshine
This model is part of the Moonshine family of tiny specialized Automatic Speech Recognition (ASR) models for edge devices, as described in Flavors of Moonshine: Tiny Specialized ASR Models for Edge Devices.
[Paper] | [Code] | [Installation]
This is the model card for running the automatic speech recognition (ASR) models (Moonshine models) trained and released by Moonshine AI (f.k.a Useful Sensors.)
Following Model Cards for Model Reporting (Mitchell et al.), we're providing some information about the automatic speech recognition model. More information on how these models were trained and evaluated can be found in the paper. Note, a lot of the text has been copied verbatim from the model card for the Whisper model developed by OpenAI, because both models serve identical purposes, and carry identical risks.
Usage
Moonshine is supported in Hugging Face 🤗 Transformers. To run the model, first install the Transformers library. For this example, we'll also install 🤗 Datasets to load toy audio dataset from the Hugging Face Hub, and 🤗 Accelerate to reduce the model loading time:
pip install --upgrade pip
pip install --upgrade transformers datasets[audio]
from transformers import MoonshineForConditionalGeneration, AutoProcessor
from datasets import load_dataset, Audio
import torch
device = "cuda:0" if torch.cuda.is_available() else "cpu"
torch_dtype = torch.float16 if torch.cuda.is_available() else torch.float32
model = MoonshineForConditionalGeneration.from_pretrained('UsefulSensors/moonshine-tiny-ar').to(device).to(torch_dtype)
processor = AutoProcessor.from_pretrained('UsefulSensors/moonshine-tiny-ar')
dataset = load_dataset('UsefulSensors/multilingual_examples', split='ar')
dataset = dataset.cast_column("audio", Audio(processor.feature_extractor.sampling_rate))
sample = dataset[0]["audio"]
inputs = processor(
sample["array"],
return_tensors="pt",
sampling_rate=processor.feature_extractor.sampling_rate
)
inputs = inputs.to(device, torch_dtype)
# to avoid hallucination loops, we limit the maximum length of the generated text based expected number of tokens per second
token_limit_factor = 13 / processor.feature_extractor.sampling_rate
seq_lens = inputs.attention_mask.sum(dim=-1)
max_length = int((seq_lens * token_limit_factor).max().item())
generated_ids = model.generate(**inputs, max_length=max_length)
print(processor.decode(generated_ids[0], skip_special_tokens=True))
Model Details
This Moonshine model is trained for the speech recognition task, capable of transcribing Arabic speech audio into Arabic text (with code-switching.) Moonshine AI developed the models to support their business direction of developing real time speech transcription products based on low cost hardware. The following table shows comparisons of common ASR evaluations sets. For more information about evaluation, please refer to the paper.
| Size | Parameters | Fleurs (WER) ↓ | Common Voice 17 (WER) ↓ |
|---|---|---|---|
| whisper tiny | 39 M | 66.01 | 88.98 |
| whisper medium | 769 M | 18.79 | 36.09 |
| moonshine tiny | 27 M | 20.76 | 36.55 |
Release date
September 2025
Model type
Sequence-to-sequence ASR (automatic speech recognition) and speech translation model
Model Use
Evaluated Use
The primary intended users of these models are AI developers that want to deploy Arabic speech recognition systems in platforms that are severely constrained in memory capacity and computational resources. We recognize that once models are released, it is impossible to restrict access to only “intended” uses or to draw reasonable guidelines around what is or is not safe use.
The models are primarily trained and evaluated on Arabic ASR task. They may exhibit additional capabilities, particularly if fine-tuned on certain tasks like voice activity detection, speaker classification, or speaker diarization but have not been robustly evaluated in these areas. We strongly recommend that users perform robust evaluations of the models in a particular context and domain before deploying them.
In particular, we caution against using Moonshine models to transcribe recordings of individuals taken without their consent or purporting to use these models for any kind of subjective classification. We recommend against use in high-risk domains like decision-making contexts, where flaws in accuracy can lead to pronounced flaws in outcomes. The models are intended to transcribe Arabic speech, use of the model for classification is not only not evaluated but also not appropriate, particularly to infer human attributes.
Training Data
The models are trained on 15,500 hours of audio and the corresponding transcripts collected from the internet, as well as datasets openly available and accessible on HuggingFace. The open datasets used are listed in the the accompanying paper.
Performance and Limitations
Our evaluations show that, the models exhibit greater accuracy on standard datasets over existing ASR systems of both similar and larger sizes.
However, like any machine learning model, the predictions may include texts that are not actually spoken in the audio input (i.e. hallucination). We hypothesize that this happens because, given their general knowledge of language, the models combine trying to predict the next word in audio with trying to transcribe the audio itself.
In addition, the sequence-to-sequence architecture of the model makes it prone to generating repetitive texts, which can be mitigated to some degree by beam search and temperature scheduling but not perfectly. It is likely that this behavior and hallucinations may be worse for short audio segments, or segments where parts of words are cut off at the beginning or the end of the segment.
Broader Implications
We anticipate that Moonshine models’ transcription capabilities may be used for improving accessibility tools, especially for real-time transcription. The real value of beneficial applications built on top of Moonshine models suggests that the disparate performance of these models may have real economic implications.
There are also potential dual-use concerns that come with releasing Moonshine. While we hope the technology will be used primarily for beneficial purposes, making ASR technology more accessible could enable more actors to build capable surveillance technologies or scale up existing surveillance efforts, as the speed and accuracy allow for affordable automatic transcription and translation of large volumes of audio communication. Moreover, these models may have some capabilities to recognize specific individuals out of the box, which in turn presents safety concerns related both to dual use and disparate performance. In practice, we expect that the cost of transcription is not the limiting factor of scaling up surveillance projects.
Citation
If you benefit from our work, please cite us:
@misc{king2025flavorsmoonshinetinyspecialized,
title={Flavors of Moonshine: Tiny Specialized ASR Models for Edge Devices},
author={Evan King and Adam Sabra and Manjunath Kudlur and James Wang and Pete Warden},
year={2025},
eprint={2509.02523},
archivePrefix={arXiv},
primaryClass={cs.CL},
url={https://arxiv.org/abs/2509.02523},
}
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