A TDMA-Based Data Gathering Protocol for Molecular Communication via Diffusion-Based Nano-Sensor Networks

Shitiri, Ethungshan; Cho, Ho-Shin

doi:10.1109/jsen.2021.3091494

Cited by 9 publications

(3 citation statements)

References 64 publications

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“…This could be attributed to the fact that a higher corresponds to a faster channel and it also determines the speed at which the molecules move in the channel. Consequently, the number of molecules received increased; and as a result, the propagation delay variation decreased, which has also been reported in [44]. Furthermore, the , which determines the speed at which the molecules move in the channel, was inversely proportional to the variations in the propagation delay; thus, RMSE of both cases for 597.25µm 2 /s was lower than those at other lower .…”

Section: ) Changes In the Rmse As A Function Of The Diffusion Coeffic...supporting

confidence: 71%

In-Body Sequential Multidrug Delivery Scheme Using Molecular Communication

2022

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This study explores the application of molecular communication (MC) for the enhancement of the performance of sequential drug delivery in combination therapy-a multi-drug treatment procedure. To achieve high efficacy, it is essential to maintain a delivery time interval (DTI) between consecutive drug administrations. To this end, this study proposes a coordination scheme that enables the control of the release times of a network of drug-carrying nanomachines to ensure the maintenance of the DTI. Particularly, MC is employed to develop a centralized network, wherein the release times of the drugs from the drug-carrying nanomachines are managed by a controller nanomachine. This nanomachine is named the internal controller nanomachine, as it is placed within the human body. The performance of the proposed scheme is evaluated in terms of the DTI error. Furthermore, the analytical expression of the error is derived and its correctness is validated using simulations. INDEX TERMSMolecular communication, nanomedicine, nanonetworks, targeted drug delivery, combination therapy. TANIA ISLAM (Student Member, IEEE) received the B.Sc. Engg. (CSE), M.Sc. (CS), and M.Sc. Engg. (CSE) degrees from Patuakhali Science and Technology University (PSTU), Jahangirnagar University (JU), and Khulna University (KU), Bangladesh, in 2012, 2014, and 2018, respectively. She is currently pursuing the Ph.D. degree in information and communication engineering with

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Section: ) Changes In the Rmse As A Function Of The Diffusion Coeffic...supporting

confidence: 71%

In-Body Sequential Multidrug Delivery Scheme Using Molecular Communication

2022

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“…The transmitters are time-synchronized with the receiver and access the channel in a time-slotted manner, similar to time-division multiple access [6], [35], [36]. As shown in Fig.…”

Section: System Modelmentioning

confidence: 99%

“…Each transmitter is allocated one symbol period in each transmission round. Hence, each transmitter knows when to transmit without collision [36].…”

Section: System Modelmentioning

confidence: 99%

An M-Ary Concentration-Shift Keying With Common Detection Thresholds for Multitransmitter Molecular Communication

Shitiri,

Cho

2024

IEEE Internet Things J.

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Concentration shift keying (CSK) is a widely studied modulation technique for molecular communication-based nanonetworks, which is a key enabler for the Internet of Bio-NanoThings (IoBNT). Existing CSK methods, while offering optimal error performance, suffer from increased operational complexity that scales poorly as the number of transmitters, K, grows. In this study, a novel M-ary CSK method is proposed: CSK with common detection thresholds (CSK-CT). CSK-CT uses common thresholds, set sufficiently low to guarantee the reliable detection of symbols from all transmitters, regardless of distance. Closed-form expressions are derived to obtain the common thresholds and release concentrations. To further enhance error performance, the release concentration is optimized using a scaling exponent that also optimizes the common thresholds. The performance of CSK-CT is evaluated against the benchmark CSK across various K and M values. CSK-CT has an error probability between 10 −7 and 10 −4 , which is a substantial improvement from that of the benchmark CSK (from 10 −4 to 10 −3 ). In terms of complexity, CSK-CT is O n and does not scale with K but M (M K), whereas the benchmark is O n 2 . Furthermore, CSK-CT can mitigate inter-symbol interference (ISI), although this facet merits further investigation. Owing to its low error rates, improved scalability, reduced complexity, and potential ISI mitigation features, CSK-CT is particularly advantageous for IoBNT applications focused on data gathering. Its effectiveness is especially notable in scenarios where a computationally limited receiver is tasked with collecting vital health data from multiple transmitters.

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