TY  - CONF
Y1  - 2019///
PB  - Association for Computing Machinery
SN  - 9781450365734
A1  - Shukla, S.
A1  - Hassan, M.F.
A1  - Jung, L.T.
A1  - Awang, A.
A1  - Khan, M.K.
UR  - https://www.scopus.com/inward/record.uri?eid=2-s2.0-85066030196&doi=10.1145%2f3316615.3318222&partnerID=40&md5=ee902224a3379398d2d63f0e6206a58c
EP  - 528
VL  - Part F
AV  - none
N2  - Healthcare Internet-of-things comprises a huge number of wearable sensors and interconnected computers. The high volume of IoT data is transacted over servers leading to servers overloading with high traffic causing network congestion. These cloud servers are typically for analyzing, retrieving and storing the large data generated from IoT devices. There exist challenges regarding sending real-time healthcare data from cloud servers to end-users. These challenges include the high computational latency, high communication latency, and high network latency. Due to these challenges, IoTs may not be able to send data in real-time to end-users. Fog nodes can be used to play a major role in reducing the high delay and high traffic. It can be a solution to increase system performance. In this paper, we proposed a 3-tier architecture, an analytical model for healthcare IoT using a hybrid approach consisting of fuzzy logic and reinforcement learning in a fog computing environment. The aim is to minimize network latency. The proposed model and 3-tier architecture are simulated using iFogSim simulator. © 2019 Association for Computing Machinery.
N1  - cited By 15; Conference of 8th International Conference on Software and Computer Applications, ICSCA 2019 ; Conference Date: 19 February 2019 Through 21 February 2019; Conference Code:147956
SP  - 522
ID  - scholars12163
TI  - A 3-tier architecture for network latency reduction in healthcare internet-of-things using fog computing and machine learning
KW  - Application programs; Cloud computing; Computer architecture; Computer circuits; Fog; Fuzzy logic; Health care; Internet of things; Learning systems; Medical computing; Network architecture; Reinforcement learning
KW  -  Cloud servers; Communication latency; Computing environments; Hybrid approach; Interconnected computer; Network congestions; Network latencies; Real-time healthcares
KW  -  Fog computing
ER  -