Smart epidemic tunnel: IoT-based sensor-fusion assistive technology for COVID-19 disinfection

Purpose: The purpose of the presented IoT based sensor-fusion assistive technology for COVID-19 disinfection termed as “Smart epidemic tunnel” is to protect an individual using an automatic sanitizer spray system equipped with a sanitizer sensing unit based on individual using an automatic sanitizer spray system equipped with a sanitizer sensing unit based on human motion detection Design/methodology/approach: The presented research work discusses a smart epidemic tunnel that can assist an individual in immediate disinfection from COVID-19 infections The authors have presented a sensor-fusion-based automatic sanitizer tunnel that detects a human using an ultrasonic sensor from the height of 1 5 feet and disinfects him/her using the spread of a sanitizer spray The presented smart tunnel operates using a solar cell during the day time and switched to a solar power-bank power mode during night timings using a light-dependent register sensing unit Findings: The investigation results validate the performance evaluation of the presented smart epidemic tunnel mechanism The presented smart tunnel can prevent or disinfect an outsider who is entering a particular building or a premise from COVID-19 infection possibilities Furthermore, it has also been observed that the presented sensor-fusion-based mechanism can disinfect a person in a time of span of just 10 s The presented smart epidemic tunnel is embedded with an intelligent sanitizer sensing unit which stores the essential information in a cloud platform such as Google Fire-base Thus, the proposed system favours society by saving time and helps in lowering the spread of coronavirus It also provides daily, weekly and monthly reports of the counts of individuals, along with in-out timestamps and power usage reports Practical implications: The presented system has been designed and developed after the lock-down period to disinfect an individual from the possibility of COVID-19 infections Social implications: The presented smart epidemic tunnel reduced the possibility by disinfecting an outside individual/COVID-19 suspect from spreading the COVID-19 infections in a particular building or a premise Originality/value: The presented system is an original work done by all the authors which have been installed at the Symbiosis Institute of Technology premise and have undergone rigorous experimentation and testing by the authors and end-users © 2020, Emerald Publishing Limited

[1]  Shruti Mishra,et al.  A Review of COVID-19 (Coronavirus Disease-2019) Diagnosis, Treatments and Prevention , 2020 .

[2]  Sudip Mittal,et al.  Enabling and Enforcing Social Distancing Measures using Smart City and ITS Infrastructures: A COVID-19 Use Case , 2020, ArXiv.

[3]  Mahendra Kumar Gohil,et al.  Development of Autonomous Advanced Disinfection Tunnel to Tackle External Surface Disinfection of COVID-19 Virus in Public Places , 2020, Transactions of the Indian National Academy of Engineering.

[4]  J. Mathew,et al.  Invention, Innovation, and Imitation in India—Necessity Arising from the COVID-19 Pandemic , 2020, Annals of the National Academy of Medical Sciences (India).

[5]  Saad Motahhir,et al.  Preliminary Design of a Smart Wristband Disinfectant to Help in Covid-19 Fight , 2020 .

[6]  Jin Yong Kim,et al.  Drive-Through Screening Center for COVID-19: a Safe and Efficient Screening System against Massive Community Outbreak , 2020, Journal of Korean medical science.

[7]  Le Qin,et al.  Infection Control for CT Equipment and Radiographers' Personal Protection During the Coronavirus Disease (COVID-19) Outbreak in China. , 2020, AJR. American journal of roentgenology.

[8]  Ji Yong Lee,et al.  Walk-Through Screening Center for COVID-19: an Accessible and Efficient Screening System in a Pandemic Situation , 2020, Journal of Korean medical science.

[9]  Khosrow Adeli,et al.  Biosafety measures for preventing infection from COVID-19 in clinical laboratories: IFCC Taskforce Recommendations , 2020, Clinical chemistry and laboratory medicine.

[10]  Kazuyoshi Yagishita,et al.  Principles of Disinfectant Use and Safety Operation in Medical Facilities During Coronavirus Disease 2019 (COVID-19) Outbreak , 2020, SN Comprehensive Clinical Medicine.

[11]  Ganti S. Murthy An Automatic Disinfection System for Passenger Luggage at Airports and Train/Bus Stations , 2020, Transactions of the Indian National Academy of Engineering.

[12]  A. Dall'Asta,et al.  ISUOG Safety Committee Position Statement on safe performance of obstetric and gynecological scans and equipment cleaning in context of COVID‐19 , 2020, Ultrasound in obstetrics & gynecology : the official journal of the International Society of Ultrasound in Obstetrics and Gynecology.

[13]  Nassim Ahmed Mahammedi,et al.  Standalone Solar-Powered Ultraviolet Mobile Disinfectant: Bringing Solar Energy in the Global Fight against COVID-19 , 2020 .

[14]  Jaiteerth R. Joshi COVSACK: an innovative portable isolated and safe COVID-19 sample collection kiosk with automatic disinfection , 2020, Transactions of the Indian National Academy of Engineering.