license, language, library_name, tags, base_model, quantized_by, pipeline_tag
| license | language | library_name | tags | base_model | quantized_by | pipeline_tag | |||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| apache-2.0 |
|
transformers |
|
t-tech/T-pro-it-2.1 | AMAImedia | text-generation |
Qwen3-32B-T-pro-it-2.1-NOESIS-AWQ-INT4
AWQ INT4 quantization of t-tech/T-pro-it-2.1 optimized for low-VRAM consumer hardware via streaming inference.
Released as part of the NOESIS Professional Multilingual Dubbing Automation Platform (framework: DHCF-FNO — Deterministic Hybrid Control Framework for Frozen Neural Operators).
- Founder: Ilia Bolotnikov
- Organization: AMAImedia.com
- X (Twitter): @AMAImediacom
- LinkedIn: Ilia Bolotnikov
- Telegram: @djbionicl
- NOESIS version: v14.6
- License: Apache-2.0 (inherited from base model — fully permissive, commercial use allowed)
ℹ️ Architecture clarification
T-pro-it-2.1 is a dense Qwen3-32B model, NOT a Mixture-of-Experts (MoE). Upstream training used a SLERP merge of three GRPO-trained experts as a training-time technique, but the resulting checkpoint is a single set of dense weights with one forward pass and no router. This release follows that architecture exactly — there are no expert layers, no gating networks, and no conditional computation.
Model summary
| Property | Value |
|---|---|
| Base model | t-tech/T-pro-it-2.1 |
| Underlying architecture | Qwen3-32B (decoder-only transformer, 64 layers, dense) |
| Original precision | BF16 safetensors (~64 GB) |
| Quantized precision | AWQ INT4 (group_size=128, GEMM, zero_point=True) |
| Vocab size | 151936 |
| Languages | Russian (primary), English, Ukrainian, Belarusian |
| Disk footprint | ~8.5 GB |
| Inference VRAM (full-resident) | ~9 GB (does NOT fit 6 GB GPUs without streaming) |
| Inference VRAM (streaming) | ~3.4 GB peak (per-layer offload — fits 6 GB GPU) |
| Quantization library | AutoAWQ 0.2.9 |
| Calibration set | 128 prompts (70% RU / 20% EN / 10% code), max_seq_len=512 |
| RNG seed | 1729 (NOESIS reproducibility lock) |
Key feature: 6 GB GPU compatibility via streaming
Standard AWQ-INT4 of a 32B model needs ~9 GB VRAM, which excludes RTX 3060 / 4060 class hardware. NOESIS ships a per-layer weight-streaming inference path where individual transformer layers are streamed from CPU RAM onto the GPU on demand, executed, and freed. Peak VRAM stays at ~3.4 GB, well inside the SEALED 4.5 GB NOESIS specialist window.
Throughput on RTX 3060 (i7-12700H, DDR5-4800):
- Prefill: ~25 tok/s
- Per-layer load overhead: ~7 ms × 64 layers = 0.45 s amortized per batch
Suitable for: KD logits extraction, batch inference, offline summarization. For low-latency interactive chat use the same checkpoint on a 12 GB+ GPU in standard AutoAWQ inference mode.
How to use
Standard inference (12 GB+ GPU):
from awq import AutoAWQForCausalLM
from transformers import AutoTokenizer
import torch
model_id = "amaimedia/Qwen3-32B-T-pro-it-2.1-NOESIS-AWQ-INT4"
tokenizer = AutoTokenizer.from_pretrained(model_id)
model = AutoAWQForCausalLM.from_quantized(
model_id,
device_map={"": 0},
torch_dtype=torch.float16,
fuse_layers=False,
)
messages = [
{"role": "system", "content": "Ты T-pro, полезный ассистент."},
{"role": "user", "content": "Объясни принцип работы трансформера."},
]
text = tokenizer.apply_chat_template(messages, tokenize=False, add_generation_prompt=True)
inputs = tokenizer(text, return_tensors="pt").to("cuda")
out = model.generate(
**inputs,
max_new_tokens=512,
temperature=0.7, top_p=0.8, top_k=20,
repetition_penalty=1.0,
)
print(tokenizer.decode(out[0], skip_special_tokens=True))
Recommended generation parameters per upstream T-Tech guidance:
temperature=0.7, top_p=0.8, top_k=20, presence_penalty=1.0.
Both temperature and presence_penalty should be set explicitly.
Streaming inference (6 GB GPU): see the NOESIS extract_kd_streaming.py
reference implementation.
NOESIS context
In NOESIS this model serves as the Russian-language teacher for several specialists during knowledge distillation:
| Target specialist | Role | Proposed KD weight |
|---|---|---|
| M2-DUB-LM-10B | Dubbing LM (Russian segments) | 0.18 |
| M4-CHAT-10B | Chat / creative writing (Russian) | 0.18 |
| M9-ORCH-4B | Orchestrator (Russian routing) | 0.15 |
Vocab match (151936) is identical to the NOESIS base (Qwen3-8B), enabling direct logit alignment without cross-tokenizer projection — a critical property for clean KD on Russian shards.
Quantization details
Calibration distribution:
- 70% Russian: chat, technical instruction, scientific exposition, creative writing
- 20% English: technical & instructional
- 10% Code: Python, Rust (RU and EN comments)
Quantization performed on:
- CPU: Intel i7-12700H (14 cores)
- RAM: 64 GB DDR5
- GPU: RTX 3060 6 GB (per-layer scale search)
- Disk offload: NVMe (
B:\noesis_offload_tpro\, freed after quantization)
Wall time: ~3.5 hours.
Acknowledgements & citation
Base model:
@misc{stoianov2025tpro20,
title = {T-pro 2.0: An Efficient Russian Hybrid-Reasoning Model and Playground},
author = {Dmitrii Stoianov and Danil Taranets and Olga Tsymboi and others},
year = {2025},
eprint = {2512.10430},
archivePrefix = {arXiv}
}
Quantization & NOESIS integration:
@misc{noesis_v14,
title = {NOESIS v14.6: DHCF-FNO Multilingual Dubbing Platform},
author = {Bolotnikov, Ilia},
year = {2026},
publisher = {AMAImedia},
url = {https://amaimedia.com}
}