Salvato in:
Dettagli Bibliografici
Autori principali: Lunar, Mohammad Mosiur, Vuran, Mehmet C.
Natura: Preprint
Pubblicazione: 2026
Soggetti:
Accesso online:https://arxiv.org/abs/2605.10825
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
_version_ 1866909033452011520
author Lunar, Mohammad Mosiur
Vuran, Mehmet C.
author_facet Lunar, Mohammad Mosiur
Vuran, Mehmet C.
contents Dynamic spectrum access (DSA) has become a key pillar of next-generation wireless systems to address the spectrum scarcity due to the rapid growth of connected devices. Accurate short-term spectrum forecasting is critical for DSA, where data-driven approaches have proven most effective. Recent advances in and widespread adoption of large language model (LLM) architectures present new opportunities for spectrum prediction. In this paper, foundational large spectrum models (LSMs) are presented. A novel RF tokenizer is introduced to convert raw IQ measurements into token sequences by mapping each power-spectral density value to a fixed vocabulary along with embedding gain, frequency, FFT bin, and timestamp information. Five established open-source LLM architectures (Gemma-2B, GPT-2, LLaMA-7B, Mistral-7B, and Phi-1) are trained on this tokenized spectrum data for the task of spectrum forecasting, yielding LSMs. To leverage the scaling gains of LSMs, a fully automated outdoor wireless testbed is employed to collect over 22 TB of raw spectrum data across 33 sub-GHz frequency bands, yielding 8.4B tokens in total. Across all 33 bands, the best model (LSM-Mistral) achieves a root-mean-square error of 3.25 dB and 97% of predictions have a mean absolute error below 5 dB. Generalization of LSMs is illustrated by fine-tuning the models on data collected in different locations, where RMSE is maintained below 3.7 dB. These results demonstrate that widespread decoder-only transformer architectures can serve as effective predictive models for large-scale RF spectrum forecasting.
format Preprint
id arxiv_https___arxiv_org_abs_2605_10825
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Large Spectrum Models (LSMs): Decoder-Only Transformer-Powered Spectrum Activity Forecasting via Tokenized RF Data
Lunar, Mohammad Mosiur
Vuran, Mehmet C.
Networking and Internet Architecture
Dynamic spectrum access (DSA) has become a key pillar of next-generation wireless systems to address the spectrum scarcity due to the rapid growth of connected devices. Accurate short-term spectrum forecasting is critical for DSA, where data-driven approaches have proven most effective. Recent advances in and widespread adoption of large language model (LLM) architectures present new opportunities for spectrum prediction. In this paper, foundational large spectrum models (LSMs) are presented. A novel RF tokenizer is introduced to convert raw IQ measurements into token sequences by mapping each power-spectral density value to a fixed vocabulary along with embedding gain, frequency, FFT bin, and timestamp information. Five established open-source LLM architectures (Gemma-2B, GPT-2, LLaMA-7B, Mistral-7B, and Phi-1) are trained on this tokenized spectrum data for the task of spectrum forecasting, yielding LSMs. To leverage the scaling gains of LSMs, a fully automated outdoor wireless testbed is employed to collect over 22 TB of raw spectrum data across 33 sub-GHz frequency bands, yielding 8.4B tokens in total. Across all 33 bands, the best model (LSM-Mistral) achieves a root-mean-square error of 3.25 dB and 97% of predictions have a mean absolute error below 5 dB. Generalization of LSMs is illustrated by fine-tuning the models on data collected in different locations, where RMSE is maintained below 3.7 dB. These results demonstrate that widespread decoder-only transformer architectures can serve as effective predictive models for large-scale RF spectrum forecasting.
title Large Spectrum Models (LSMs): Decoder-Only Transformer-Powered Spectrum Activity Forecasting via Tokenized RF Data
topic Networking and Internet Architecture
url https://arxiv.org/abs/2605.10825