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| Main Authors: | , , |
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| Format: | Preprint |
| Published: |
2026
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2605.17094 |
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| _version_ | 1866917505019150336 |
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| author | Schex, Leon Cremer, Markus Dettmar, Uwe |
| author_facet | Schex, Leon Cremer, Markus Dettmar, Uwe |
| contents | Bluetooth Core Specification v6.0 introduces Channel Sounding (CS) as a standardized high-accuracy ranging primitive for Bluetooth Low Energy (BLE). However, standard CS usage remains tied to per-pair LE asynchronous connection logical transport (LE ACL) connections, which adds initiation overhead, limits concurrent partners, and transfers results over the connection itself. We present a connectionless CS architecture that combines the LE CS Test command with Periodic Advertising with Responses (PAwR). A Central Orchestrator, a Gateway, and synchronized Tag/Anchor devices coordinate measurement configurations and aggregate results at the application layer. Each device derives its role, channel sequence, and response slot assignment from its device index and a Peer-to-Peer Assignment Matrix distributed via PAwR. The deterministic channel sequence prevents same-step collisions across parallel CS procedures, while matrix updates reconfigure arbitrary device-to-device pairings within a PAwR subevent group. A compact data plane omits fields recoverable from the shared measurement configuration and reduces the serialized ranging-data payload by approximately 69%, enabling result reporting through PAwR response slots. A proof-of-concept evaluation on the Nordic nRF54L15 platform shows that deterministic channel management eliminates the collision-induced outliers observed under simulated dense-deployment channel overlaps. At a 1 s update cycle, the architecture reduces steady-state active charge by 40-48% relative to a fair connected baseline and cuts per-switch initiation overhead by approximately 98%. Under per-cycle partner switching, these effects combine to up to 88% lower total charge over a 24 h horizon. An empirical timing model projects a capacity upper bound of 16,384 active devices per PAwR train at four CS procedures per device per cycle, 37 channels, and a single antenna path. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2605_17094 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Connectionless Bluetooth LE Channel Sounding via PAwR for Scalable and Energy-Efficient Ranging Schex, Leon Cremer, Markus Dettmar, Uwe Signal Processing Bluetooth Core Specification v6.0 introduces Channel Sounding (CS) as a standardized high-accuracy ranging primitive for Bluetooth Low Energy (BLE). However, standard CS usage remains tied to per-pair LE asynchronous connection logical transport (LE ACL) connections, which adds initiation overhead, limits concurrent partners, and transfers results over the connection itself. We present a connectionless CS architecture that combines the LE CS Test command with Periodic Advertising with Responses (PAwR). A Central Orchestrator, a Gateway, and synchronized Tag/Anchor devices coordinate measurement configurations and aggregate results at the application layer. Each device derives its role, channel sequence, and response slot assignment from its device index and a Peer-to-Peer Assignment Matrix distributed via PAwR. The deterministic channel sequence prevents same-step collisions across parallel CS procedures, while matrix updates reconfigure arbitrary device-to-device pairings within a PAwR subevent group. A compact data plane omits fields recoverable from the shared measurement configuration and reduces the serialized ranging-data payload by approximately 69%, enabling result reporting through PAwR response slots. A proof-of-concept evaluation on the Nordic nRF54L15 platform shows that deterministic channel management eliminates the collision-induced outliers observed under simulated dense-deployment channel overlaps. At a 1 s update cycle, the architecture reduces steady-state active charge by 40-48% relative to a fair connected baseline and cuts per-switch initiation overhead by approximately 98%. Under per-cycle partner switching, these effects combine to up to 88% lower total charge over a 24 h horizon. An empirical timing model projects a capacity upper bound of 16,384 active devices per PAwR train at four CS procedures per device per cycle, 37 channels, and a single antenna path. |
| title | Connectionless Bluetooth LE Channel Sounding via PAwR for Scalable and Energy-Efficient Ranging |
| topic | Signal Processing |
| url | https://arxiv.org/abs/2605.17094 |