Tighten abstract, add Muon optimizer mention, update ckpt_comparison figure

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ViperEkura 2026-07-08 22:27:33 +08:00
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2 changed files with 12 additions and 16 deletions

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\maketitle \maketitle
\begin{abstract} \begin{abstract}
Training billion-parameter language models requires careful co-design of We present {\sc AstrAI}, an open-source framework for end-to-end training
data infrastructure, distributed execution, and numerical precision of a 1.2B-parameter Transformer on 15B tokens. The pipeline covers
management. This paper presents {\sc AstrAI}, an open-source framework JSON-driven BBPE preprocessing with multi-strategy packing, HDF5/mmap
for end-to-end training of a 1.2B-parameter autoregressive Transformer storage backends, and a companion SFT pipeline ({\sc Alembic}) with MinHash
over 15B tokens. We describe the full pipeline: JSON-driven preprocessing deduplication and LLM-as-Judge scoring. The 24-layer decoder uses GQA, SwiGLU,
with BBPE tokenization and multi-strategy packing, HDF5 and memory-mapped RoPE, and RMSNorm, trained with a hybrid Muon/AdamW optimizer and cosine scheduling under DDP/FSDP.
storage backends, and a companion SFT pipeline ({\sc Alembic}) with A focused BF16 stability analysis shows that GPT-2 residual scaling
MinHash-based near-duplicate detection and LLM-as-Judge scoring. The ($\sigma = 0.02/\sqrt{2L}$) reduces per-block residual variance by a factor
model is a 24-layer decoder-only Transformer with Grouped Query Attention, of 48, containing post-24-layer variance at 1.34 versus 17.5 under standard
SwiGLU, RoPE, and RMSNorm, trained with AdamW and cosine scheduling via initialization. Empirically, this scaling yields a sustained loss advantage
DDP/FSDP. A central focus is BF16 numerical stability: variance propagation over Kaiming initialization, with the gap peaking at $\Delta = 0.79$ in the
analysis shows that GPT-2 residual scaling reduces per-block residual mid-training regime.
variance by a factor of 48, containing post-24-layer variance at 1.34
compared to 17.5 without scaling. Empirical evaluations confirm that
residual scaling consistently outperforms Kaiming initialization, with the
loss gap peaking at 0.79 in the mid-training regime.
\end{abstract} \end{abstract}
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