ChARM: NextG Spectrum Sharing Through Data-Driven Real-Time O-RAN Dynamic Control
Today's radio access networks (RANs) are monolithic entities which often operate statically on a given set of parameters for the entirety of their operations. To implement realistic and effective spectrum sharing policies, RANs will need to seamlessly and intelligently change their operational...
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| creator | Baldesi, Luca Restuccia, Francesco Melodia, Tommaso |
| description | Today's radio access networks (RANs) are monolithic entities which often
operate statically on a given set of parameters for the entirety of their
operations. To implement realistic and effective spectrum sharing policies,
RANs will need to seamlessly and intelligently change their operational
parameters. In stark contrast with existing paradigms, the new O-RAN
architectures for 5G-and-beyond networks (NextG) separate the logic that
controls the RAN from its hardware substrate, allowing unprecedented real-time
fine-grained control of RAN components. In this context, we propose the
Channel-Aware Reactive Mechanism (ChARM), a data-driven O-RAN-compliant
framework that allows (i) sensing the spectrum to infer the presence of
interference and (ii) reacting in real time by switching the distributed unit
(DU) and radio unit (RU) operational parameters according to a specified
spectrum access policy. ChARM is based on neural networks operating directly on
unprocessed I/Q waveforms to determine the current spectrum context. ChARM does
not require any modification to the existing 3GPP standards. It is designed to
operate within the O-RAN specifications, and can be used in conjunction with
other spectrum sharing mechanisms (e.g., LTE-U, LTE-LAA or MulteFire). We
demonstrate the performance of ChARM in the context of spectrum sharing among
LTE and Wi-Fi in unlicensed bands, where a controller operating over a RAN
Intelligent Controller (RIC) senses the spectrum and switches cell frequency to
avoid Wi-Fi. We develop a prototype of ChARM using srsRAN, and leverage the
Colosseum channel emulator to collect a large-scale waveform dataset to train
our neural networks with. Experimental results show that ChARM achieves
accuracy of up to 96% on Colosseum and 85% on an over-the-air testbed,
demonstrating the capacity of ChARM to exploit the considered spectrum
channels. |
| doi_str_mv | 10.48550/arxiv.2201.06326 |
| format | Article |
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operate statically on a given set of parameters for the entirety of their
operations. To implement realistic and effective spectrum sharing policies,
RANs will need to seamlessly and intelligently change their operational
parameters. In stark contrast with existing paradigms, the new O-RAN
architectures for 5G-and-beyond networks (NextG) separate the logic that
controls the RAN from its hardware substrate, allowing unprecedented real-time
fine-grained control of RAN components. In this context, we propose the
Channel-Aware Reactive Mechanism (ChARM), a data-driven O-RAN-compliant
framework that allows (i) sensing the spectrum to infer the presence of
interference and (ii) reacting in real time by switching the distributed unit
(DU) and radio unit (RU) operational parameters according to a specified
spectrum access policy. ChARM is based on neural networks operating directly on
unprocessed I/Q waveforms to determine the current spectrum context. ChARM does
not require any modification to the existing 3GPP standards. It is designed to
operate within the O-RAN specifications, and can be used in conjunction with
other spectrum sharing mechanisms (e.g., LTE-U, LTE-LAA or MulteFire). We
demonstrate the performance of ChARM in the context of spectrum sharing among
LTE and Wi-Fi in unlicensed bands, where a controller operating over a RAN
Intelligent Controller (RIC) senses the spectrum and switches cell frequency to
avoid Wi-Fi. We develop a prototype of ChARM using srsRAN, and leverage the
Colosseum channel emulator to collect a large-scale waveform dataset to train
our neural networks with. Experimental results show that ChARM achieves
accuracy of up to 96% on Colosseum and 85% on an over-the-air testbed,
demonstrating the capacity of ChARM to exploit the considered spectrum
channels.</description><identifier>DOI: 10.48550/arxiv.2201.06326</identifier><language>eng</language><subject>Computer Science - Networking and Internet Architecture</subject><creationdate>2022-01</creationdate><rights>http://arxiv.org/licenses/nonexclusive-distrib/1.0</rights><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>228,230,776,881</link.rule.ids><linktorsrc>$$Uhttps://arxiv.org/abs/2201.06326$$EView_record_in_Cornell_University$$FView_record_in_$$GCornell_University$$Hfree_for_read</linktorsrc><backlink>$$Uhttps://doi.org/10.48550/arXiv.2201.06326$$DView paper in arXiv$$Hfree_for_read</backlink></links><search><creatorcontrib>Baldesi, Luca</creatorcontrib><creatorcontrib>Restuccia, Francesco</creatorcontrib><creatorcontrib>Melodia, Tommaso</creatorcontrib><title>ChARM: NextG Spectrum Sharing Through Data-Driven Real-Time O-RAN Dynamic Control</title><description>Today's radio access networks (RANs) are monolithic entities which often
operate statically on a given set of parameters for the entirety of their
operations. To implement realistic and effective spectrum sharing policies,
RANs will need to seamlessly and intelligently change their operational
parameters. In stark contrast with existing paradigms, the new O-RAN
architectures for 5G-and-beyond networks (NextG) separate the logic that
controls the RAN from its hardware substrate, allowing unprecedented real-time
fine-grained control of RAN components. In this context, we propose the
Channel-Aware Reactive Mechanism (ChARM), a data-driven O-RAN-compliant
framework that allows (i) sensing the spectrum to infer the presence of
interference and (ii) reacting in real time by switching the distributed unit
(DU) and radio unit (RU) operational parameters according to a specified
spectrum access policy. ChARM is based on neural networks operating directly on
unprocessed I/Q waveforms to determine the current spectrum context. ChARM does
not require any modification to the existing 3GPP standards. It is designed to
operate within the O-RAN specifications, and can be used in conjunction with
other spectrum sharing mechanisms (e.g., LTE-U, LTE-LAA or MulteFire). We
demonstrate the performance of ChARM in the context of spectrum sharing among
LTE and Wi-Fi in unlicensed bands, where a controller operating over a RAN
Intelligent Controller (RIC) senses the spectrum and switches cell frequency to
avoid Wi-Fi. We develop a prototype of ChARM using srsRAN, and leverage the
Colosseum channel emulator to collect a large-scale waveform dataset to train
our neural networks with. Experimental results show that ChARM achieves
accuracy of up to 96% on Colosseum and 85% on an over-the-air testbed,
demonstrating the capacity of ChARM to exploit the considered spectrum
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operate statically on a given set of parameters for the entirety of their
operations. To implement realistic and effective spectrum sharing policies,
RANs will need to seamlessly and intelligently change their operational
parameters. In stark contrast with existing paradigms, the new O-RAN
architectures for 5G-and-beyond networks (NextG) separate the logic that
controls the RAN from its hardware substrate, allowing unprecedented real-time
fine-grained control of RAN components. In this context, we propose the
Channel-Aware Reactive Mechanism (ChARM), a data-driven O-RAN-compliant
framework that allows (i) sensing the spectrum to infer the presence of
interference and (ii) reacting in real time by switching the distributed unit
(DU) and radio unit (RU) operational parameters according to a specified
spectrum access policy. ChARM is based on neural networks operating directly on
unprocessed I/Q waveforms to determine the current spectrum context. ChARM does
not require any modification to the existing 3GPP standards. It is designed to
operate within the O-RAN specifications, and can be used in conjunction with
other spectrum sharing mechanisms (e.g., LTE-U, LTE-LAA or MulteFire). We
demonstrate the performance of ChARM in the context of spectrum sharing among
LTE and Wi-Fi in unlicensed bands, where a controller operating over a RAN
Intelligent Controller (RIC) senses the spectrum and switches cell frequency to
avoid Wi-Fi. We develop a prototype of ChARM using srsRAN, and leverage the
Colosseum channel emulator to collect a large-scale waveform dataset to train
our neural networks with. Experimental results show that ChARM achieves
accuracy of up to 96% on Colosseum and 85% on an over-the-air testbed,
demonstrating the capacity of ChARM to exploit the considered spectrum
channels.</abstract><doi>10.48550/arxiv.2201.06326</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Networking and Internet Architecture |
| title | ChARM: NextG Spectrum Sharing Through Data-Driven Real-Time O-RAN Dynamic Control |
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