Toward Standardized Performance Evaluation of Flow-guided Nanoscale Localization
Nanoscale devices with Terahertz (THz) communication capabilities are envisioned to be deployed within human bloodstreams. Such devices will enable fine-grained sensing-based applications for detecting early indications (i.e., biomarkers) of various health conditions, as well as actuation-based ones...
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| creator | López, Arnau Brosa Lemic, Filip Struye, Jakob Gómez, Jorge Torres Municio, Esteban Delgado, Carmen Bartra, Gerard Calvo Dressler, Falko Alarcón, Eduard Famaey, Jeroen Abadal, Sergi Pérez, Xavier Costa |
| description | Nanoscale devices with Terahertz (THz) communication capabilities are
envisioned to be deployed within human bloodstreams. Such devices will enable
fine-grained sensing-based applications for detecting early indications (i.e.,
biomarkers) of various health conditions, as well as actuation-based ones such
as targeted drug delivery. Associating the locations of such events with the
events themselves would provide an additional utility for precision diagnostics
and treatment. This vision yielded a new class of in-body localization coined
under the term "flow-guided nanoscale localization". Such localization can be
piggybacked on THz communication for detecting body regions in which biological
events were observed based on the duration of one circulation of a nanodevice
in the bloodstream. From a decades-long research on objective benchmarking of
"traditional" indoor localization, as well as its eventual standardization
(e.g., ISO/IEC 18305:2016), we know that in early stages the reported
performance results were often incomplete (e.g., targeting a subset of relevant
performance metrics), carrying out benchmarking experiments in different
evaluation environments and scenarios, and utilizing inconsistent performance
indicators. To avoid such a "lock-in" in flow-guided localization, in this
paper we propose a workflow for standardized performance evaluation of such
localization. The workflow is implemented in the form of an open-source
simulation framework that is able to jointly account for the mobility of the
nanodevices, in-body THz communication between with on-body anchors, and
energy-related and other technological constraints (e.g., pulse-based
modulation) at the nanodevice level. Accounting for these constraints, the
framework is able to generate the raw data that can be streamlined into
different flow-guided localization solutions for generating standardized
performance benchmarks. |
| doi_str_mv | 10.48550/arxiv.2303.07804 |
| format | Article |
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envisioned to be deployed within human bloodstreams. Such devices will enable
fine-grained sensing-based applications for detecting early indications (i.e.,
biomarkers) of various health conditions, as well as actuation-based ones such
as targeted drug delivery. Associating the locations of such events with the
events themselves would provide an additional utility for precision diagnostics
and treatment. This vision yielded a new class of in-body localization coined
under the term "flow-guided nanoscale localization". Such localization can be
piggybacked on THz communication for detecting body regions in which biological
events were observed based on the duration of one circulation of a nanodevice
in the bloodstream. From a decades-long research on objective benchmarking of
"traditional" indoor localization, as well as its eventual standardization
(e.g., ISO/IEC 18305:2016), we know that in early stages the reported
performance results were often incomplete (e.g., targeting a subset of relevant
performance metrics), carrying out benchmarking experiments in different
evaluation environments and scenarios, and utilizing inconsistent performance
indicators. To avoid such a "lock-in" in flow-guided localization, in this
paper we propose a workflow for standardized performance evaluation of such
localization. The workflow is implemented in the form of an open-source
simulation framework that is able to jointly account for the mobility of the
nanodevices, in-body THz communication between with on-body anchors, and
energy-related and other technological constraints (e.g., pulse-based
modulation) at the nanodevice level. Accounting for these constraints, the
framework is able to generate the raw data that can be streamlined into
different flow-guided localization solutions for generating standardized
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envisioned to be deployed within human bloodstreams. Such devices will enable
fine-grained sensing-based applications for detecting early indications (i.e.,
biomarkers) of various health conditions, as well as actuation-based ones such
as targeted drug delivery. Associating the locations of such events with the
events themselves would provide an additional utility for precision diagnostics
and treatment. This vision yielded a new class of in-body localization coined
under the term "flow-guided nanoscale localization". Such localization can be
piggybacked on THz communication for detecting body regions in which biological
events were observed based on the duration of one circulation of a nanodevice
in the bloodstream. From a decades-long research on objective benchmarking of
"traditional" indoor localization, as well as its eventual standardization
(e.g., ISO/IEC 18305:2016), we know that in early stages the reported
performance results were often incomplete (e.g., targeting a subset of relevant
performance metrics), carrying out benchmarking experiments in different
evaluation environments and scenarios, and utilizing inconsistent performance
indicators. To avoid such a "lock-in" in flow-guided localization, in this
paper we propose a workflow for standardized performance evaluation of such
localization. The workflow is implemented in the form of an open-source
simulation framework that is able to jointly account for the mobility of the
nanodevices, in-body THz communication between with on-body anchors, and
energy-related and other technological constraints (e.g., pulse-based
modulation) at the nanodevice level. Accounting for these constraints, the
framework is able to generate the raw data that can be streamlined into
different flow-guided localization solutions for generating standardized
performance benchmarks.</description><subject>Computer Science - Emerging Technologies</subject><subject>Computer Science - Networking and Internet Architecture</subject><subject>Computer Science - Systems and Control</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNotj8tOwzAQRb1hgQofwAr_QMLEjzhdoqoFpAgqkX002DPIUhoj9wX9ekKp7uLexdGVjhB3FZSmsRYeMH_HQ6k06BJcA-ZarLt0xBzk-w7HMI14oiDXlDnlDY6e5PKAwx53MY0ysVwN6Vh87mOYqFcc09bjQLJNU8XTmboRV4zDlm4vPRPdatktnov27ell8dgWWDtTsGfroJ7ChtFZD0CV1828dtaEQB5ZNfABSikdlAvGz7Wt2FoiglCxnon7_9uzUv-V4wbzT_-n1p_V9C-mcko2</recordid><startdate>20230314</startdate><enddate>20230314</enddate><creator>López, Arnau Brosa</creator><creator>Lemic, Filip</creator><creator>Struye, Jakob</creator><creator>Gómez, Jorge Torres</creator><creator>Municio, Esteban</creator><creator>Delgado, Carmen</creator><creator>Bartra, Gerard Calvo</creator><creator>Dressler, Falko</creator><creator>Alarcón, Eduard</creator><creator>Famaey, Jeroen</creator><creator>Abadal, Sergi</creator><creator>Pérez, Xavier Costa</creator><scope>AKY</scope><scope>GOX</scope></search><sort><creationdate>20230314</creationdate><title>Toward Standardized Performance Evaluation of Flow-guided Nanoscale Localization</title><author>López, Arnau Brosa ; Lemic, Filip ; Struye, Jakob ; Gómez, Jorge Torres ; Municio, Esteban ; Delgado, Carmen ; Bartra, Gerard Calvo ; Dressler, Falko ; Alarcón, Eduard ; Famaey, Jeroen ; Abadal, Sergi ; Pérez, Xavier Costa</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a674-fcf5706060f4fa75c00e1c3896754ddecaf280b02223d27d4c9351f55eee0d1f3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2023</creationdate><topic>Computer Science - Emerging Technologies</topic><topic>Computer Science - Networking and Internet Architecture</topic><topic>Computer Science - Systems and Control</topic><toplevel>online_resources</toplevel><creatorcontrib>López, Arnau Brosa</creatorcontrib><creatorcontrib>Lemic, Filip</creatorcontrib><creatorcontrib>Struye, Jakob</creatorcontrib><creatorcontrib>Gómez, Jorge Torres</creatorcontrib><creatorcontrib>Municio, Esteban</creatorcontrib><creatorcontrib>Delgado, Carmen</creatorcontrib><creatorcontrib>Bartra, Gerard Calvo</creatorcontrib><creatorcontrib>Dressler, Falko</creatorcontrib><creatorcontrib>Alarcón, Eduard</creatorcontrib><creatorcontrib>Famaey, Jeroen</creatorcontrib><creatorcontrib>Abadal, Sergi</creatorcontrib><creatorcontrib>Pérez, Xavier Costa</creatorcontrib><collection>arXiv Computer Science</collection><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>López, Arnau Brosa</au><au>Lemic, Filip</au><au>Struye, Jakob</au><au>Gómez, Jorge Torres</au><au>Municio, Esteban</au><au>Delgado, Carmen</au><au>Bartra, Gerard Calvo</au><au>Dressler, Falko</au><au>Alarcón, Eduard</au><au>Famaey, Jeroen</au><au>Abadal, Sergi</au><au>Pérez, Xavier Costa</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Toward Standardized Performance Evaluation of Flow-guided Nanoscale Localization</atitle><date>2023-03-14</date><risdate>2023</risdate><abstract>Nanoscale devices with Terahertz (THz) communication capabilities are
envisioned to be deployed within human bloodstreams. Such devices will enable
fine-grained sensing-based applications for detecting early indications (i.e.,
biomarkers) of various health conditions, as well as actuation-based ones such
as targeted drug delivery. Associating the locations of such events with the
events themselves would provide an additional utility for precision diagnostics
and treatment. This vision yielded a new class of in-body localization coined
under the term "flow-guided nanoscale localization". Such localization can be
piggybacked on THz communication for detecting body regions in which biological
events were observed based on the duration of one circulation of a nanodevice
in the bloodstream. From a decades-long research on objective benchmarking of
"traditional" indoor localization, as well as its eventual standardization
(e.g., ISO/IEC 18305:2016), we know that in early stages the reported
performance results were often incomplete (e.g., targeting a subset of relevant
performance metrics), carrying out benchmarking experiments in different
evaluation environments and scenarios, and utilizing inconsistent performance
indicators. To avoid such a "lock-in" in flow-guided localization, in this
paper we propose a workflow for standardized performance evaluation of such
localization. The workflow is implemented in the form of an open-source
simulation framework that is able to jointly account for the mobility of the
nanodevices, in-body THz communication between with on-body anchors, and
energy-related and other technological constraints (e.g., pulse-based
modulation) at the nanodevice level. Accounting for these constraints, the
framework is able to generate the raw data that can be streamlined into
different flow-guided localization solutions for generating standardized
performance benchmarks.</abstract><doi>10.48550/arxiv.2303.07804</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Emerging Technologies Computer Science - Networking and Internet Architecture Computer Science - Systems and Control |
| title | Toward Standardized Performance Evaluation of Flow-guided Nanoscale Localization |
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