Blockchain based Internet of Things (Debashis De, Siddhartha Bhattacharyya etc.)

D. De et al.

65. Banerjee P, Nath Mandal S, De D, Maiti B (2020) RL-sleep: temperature adaptive sleep

scheduling using reinforcement learning for sustainable connectivity in wireless sensor

networks. Sustain Comput Inform Syst 26

66. Yousef A (2019) A fog computing based architecture for IoT services and applications

development. arXiv preprint arXiv:1911.02403

67. Zhou Z, Liu P, Feng J, Zhang Y, Mumtaz S, Rodriguez J (2019) Computation resource allo-

cation and task assignment optimization in vehicular fog computing: a contract-matching

approach. IEEE Trans Veh Technol, 1–1 (Early Access). https://doi.org/10.1109/TVT.2019.

2894851

68. Li L, Guo M, Ma L, Mao H, Guan Q (2019) Online workload allocation via fog-fog-cloud

cooperation to reduce IoT task service delay. Sensors 19(18):3830

69. Marjan G (2020) Dew computing architecture for cyber-physical systems and IoT. Internet

Things 11:100186

70. Wan J, Li J, Imran M, Li D, e-Amin F (2019) A blockchain-based solution for enhancing

security and privacy in smart factory. IEEE Trans Industr Inform, 1–9 (Early Access). https://

doi.org/10.1109/TII.2019.2894573

71. Konstantinidis I, Siaminos G, Timplalexis C, Zervas P, Peristeras V, Decker S (2018)

Blockchain for business applications: a systematic literature review. In: Abramowicz W,

Paschke A (eds) Business Information Systems. Springer International Publishing, Cham,

pp 384–399

72. Kim HM, Laskowski M (2018) Toward an ontology-driven blockchain design for supply-chain

provenance. Intell Syst Accou Finan Manag 25(1):18–27

73. Tapscott A, Tapscott D (2017) How blockchain is changing ﬁnance. Harv Bus Rev 1

74. Kshetri N (2018) 1 blockchains roles in meeting key supply chain management objectives.

Int J Inf Manage 39:80–89

75. Li Z, Guo H, Wang WM, Guan Y, VatankhahBarenji A, Huang GQ, McFall KS, Chen X

(2019) A blockchain and automl approach for open and automated customer service. IEEE

Trans Industr Inform, 1–9

76. Tse D, Zhang B, Yang Y, Cheng C, Mu H (2017) Blockchain application in food supply

information security. In: 2017 IEEE international conference on industrial engineering and

engineering management (IEEM), Dec 2017, pp 1357–1361

77. Tian F (2016) An agri-food supply chain traceability system for China based on RFID

amp;amp; blockchain technology. In: 13th international conference on service systems and

service management (ICSSSM), 2016, pp 1–6

78. Sander F, Semeijn J, Mahr D (2018) The acceptance of blockchain technology in meat

traceability and transparency. British Food J

79. Bett´ın-D´ıaz R, Rojas AE, Mej´ıa-Moncayo C (2018) Methodological approach to the deﬁni-

tion of a blockchain system for the food industry supply chain traceability. In: Computational

science and its applications—ICCSA 2018. Cham: Springer International Publishing, 2018,

p. 19–33

80. Lin Q, Wang H, Pei X, Wang J (2019) Food safety traceability system based on blockchain

and epcis. IEEE Access 7:20698–20707

81. Ray ParthaPratim, Dash D, De D (2020) Real-time event-driven sensor data analytics at the

edge-Internet of Things for smart personal healthcare. J Supercomput 76(9):6648–6668

82. Li Z, Kang J, Yu R, Ye D, Deng Q, Zhang Y (Aug 2018) Consortium Blockchain for secure

energy trading in industrial internet of things. IEEE Trans Industr Inf 14(8):3690–3700

83. Aitzhan NZ, Svetinovic D (Sept 2018) Security and privacy in decentralized energy

trading through multi-signatures, blockchain and anonymous messaging streams. IEEE Trans

Dependable Secure Comput 15(5):840–852

84. Pop C, Cioara T, Antal M, Anghel I, Salomie I, Bertoncini M (2018) Blockchain-based

decentralizedmanagementofdemandresponseprogramsinsmartenergygrids.Sensors18(1);

Wang K, Shao Y, Shu L, Zhu C, Zhang Y (2016) Mobile big data fault-tolerant processing

for health networks. IEEE Netw 30(1): 36–42