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Main Authors: Li, Ruigang, Zhu, Yongxu
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.12712
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author Li, Ruigang
Zhu, Yongxu
author_facet Li, Ruigang
Zhu, Yongxu
contents Existing multi-timbre transcription models struggle with generalization beyond pre-trained instruments, rigid source-count constraints, and high computational demands that hinder deployment on low-resource devices. We address these limitations with a lightweight model that extends a timbre-agnostic transcription backbone with a dedicated timbre encoder and performs deep clustering at the note level, enabling joint transcription and dynamic separation of arbitrary instruments given a specified number of instrument classes. Practical optimizations including spectral normalization, dilated convolutions, and contrastive clustering further improve efficiency and robustness. Despite its small size and fast inference, the model achieves competitive performance with heavier baselines in terms of transcription accuracy and separation quality, and shows promising generalization ability, making it highly suitable for real-world deployment in practical and resource-constrained settings.
format Preprint
id arxiv_https___arxiv_org_abs_2509_12712
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Lightweight Two-Branch Architecture for Multi-Instrument Transcription via Note-Level Contrastive Clustering
Li, Ruigang
Zhu, Yongxu
Sound
Information Retrieval
Existing multi-timbre transcription models struggle with generalization beyond pre-trained instruments, rigid source-count constraints, and high computational demands that hinder deployment on low-resource devices. We address these limitations with a lightweight model that extends a timbre-agnostic transcription backbone with a dedicated timbre encoder and performs deep clustering at the note level, enabling joint transcription and dynamic separation of arbitrary instruments given a specified number of instrument classes. Practical optimizations including spectral normalization, dilated convolutions, and contrastive clustering further improve efficiency and robustness. Despite its small size and fast inference, the model achieves competitive performance with heavier baselines in terms of transcription accuracy and separation quality, and shows promising generalization ability, making it highly suitable for real-world deployment in practical and resource-constrained settings.
title A Lightweight Two-Branch Architecture for Multi-Instrument Transcription via Note-Level Contrastive Clustering
topic Sound
Information Retrieval
url https://arxiv.org/abs/2509.12712