Advances in information and communication technologies have led to the emergence of Internet of

Things (IoT). In the modern health care environment, the usage of IoT technologies brings convenience

of physicians and patients, since they are applied to various medical areas (such as real-time

monitoring, patient information management, and healthcare management). The body sensor network

(BSN) technology is one of the core technologies of IoT developments in healthcare system, where a

patient can be monitored using a collection of tiny-powered and lightweight wireless sensor nodes.

However, the development of this new technology in healthcare applications without considering

security makes patient privacy vulnerable. In this paper, at first, we highlight the major security

requirements in BSN-based modern healthcare system. Subsequently, we propose a secure IoT-based

healthcare system using BSN, called BSN-Care, which can efficiently accomplish those requirements.

ETPL

IoT -001 BSN-Care: A Secure IOT-based Modern Healthcare System Using Body

Sensor Network

It is expected that the Internet of Things (IoT) applications for medical services can be one of the most

remarkable solution for taking care of aging population which is in the rapid growth. IoT consists of

communications and sensors to accomplish purpose. In the diverse kinds of networks, wireless body

area network (WBAN) is a highly suitable communication tool for the medical IoT devices. There are

many researches about WBAN and sensor network, which are mainly focused on energy efficiency.

However, in this paper, we discuss more practical issues for implementation of WBAN to healthcare

service. Therefore, we propose a multi-hop WBAN construction scheme that is consists of 4 operations,

the clustered topology setup, mobility support, and transmission efficiency enhancement. As an

auxiliary benefit, the proposed scheme achieves an energy efficient feature by reducing the number of

total control messages. Extensive simulation shows that the proposed scheme remarkably improves the

performance of WBAN.

ETPL

IoT - 002 Multi-hop WBAN Construction for Healthcare IoT System

This paper presents an effective approach for detecting abandoned luggage in surveillance videos. We

combine short- and long-term background models to extract foreground objects, where each pixel in

an input image is classified as a 2-bit code. Subsequently, we introduce a framework to identify static

foreground regions based on the temporal transition of code patterns, and to determine whether the

candidate regions contain abandoned objects by analyzing the back-traced trajectories of luggage

owners. The experimental results obtained based on video images from 2006 Performance Evaluation

of Tracking and Surveillance and 2007 Advanced Video and Signal-based Surveillance databases show

that the proposed approach is effective for detecting abandoned luggage, and that it outperforms

previous methods.

ETPL

IoT -003 Abandoned Object Detection via Temporal Consistency Modeling and

Back-Tracing Verification for Visual Surveillance

In Internet of Things (IoT) environment, IoT devices are limited to power supply, CPU capacity,

memory, etc. and have a constrained network performance such as bandwidth, wireless channel,

throughput, payload, etc., the resources of IoT devices however can be shared by other IoT devices.

Specially, in IoT healthcare service, the way of management and interoperability of patient-related and

device information are very important. In this paper, we propose the design and implementation of an

IoT healthcare system using ISO/IEEE 11073 PHD (Personal Healthcare Device) and CoAP

(Constrained Application Protocol) standards in order to enhance the interoperability and reduce the

data loss between the devices and measured information while in transmission. To demonstrate the

proposed architecture, we implement comparative performance evaluation between HTTP and CoAP

in terms of the number of packets in one transaction, the number of packets by data loss rate in during

transmission and a syntax usage between XML and JSON.

ETPL

IoT - 004 Design and implementation of interoperable IoT healthcare system based

on international standards

Wide spread of Internet of Things (IoTs) still have huddles in cost and maintenance. Energy harvesting

is a promising option to mitigate battery replacement, but the current energy harvesting methods still

rely on batteries or equivalent and power converters for the maximum power point tracking (MPPT).

Unfortunately, batteries are subject to wear and tear, which is a primary factor to prevent from being

maintenance free. Power converters are expensive, heavy and lossy as well. In this paper, we introduce

a novel energy harvesting and management technique to power the IoT, which does not require any

long-term energy storages nor voltage converters unlike traditional energy harvesting systems.

Extensive simulations and measurements from our prototype demonstrate that the proposed method

harvests 8% more energy and extends the operation time of the device 60% more during a day. This

paper also demonstrates a UV (ultraviolet) level meter for skin protect, named SmartPatch, using the

proposed energy harvesting method. The proposed method is not limited to photovoltaic energy

harvesting but applicable to most energy harvesting IoT power supplies that require impedance

tracking.

ETPL

IoT -005 Powering the IOT: Storage-less and converter less energy harvesting

Internet of Things (IoT) envisions a future in which anything/anyone/anyservice can be linked by

means of appropriate information and communication technologies which will bring technological

revolution in the fields of domestics, smart homes, healthcare systems, goods monitoring and logistics.

This paper presents the applications of IoT and addresses some essential parameters and characteristics

of each of the applications of IoT. In this paper, we have deeply explored the role of IoT in healthcare

delivery and its technological aspects that make it a reality and examine the opportunities. A cloud

based conceptual framework has been proposed which will be beneficial to the healthcare industry

implementing IoT healthcare solutions.

ETPL

IoT - 006 A conceptual framework for IoT-based healthcare system using cloud

computing

The concept of a Smart City highlights the need to enhance quality, interconnection and performance

of various urban services with the use of information and communication technologies (ICT). Smart

City technologies promote cloud-based and Internet of Things (IoT) based services in which real-world

user interfaces use smart phones, sensors and RFIDs. Cloud computing and IoT are presently two most

important ICT models that are shaping the next generation of computing. Both concepts have major

impact on how we build and deploy smart applications/solutions for smart cities. Cloud computing

represents the delivery of hardware and software resources on demand over the Internet-as-a-service.

On the other hand, IoT concept envisions a new generation of devices (sensors, both virtual and

physical) that are connected to the Internet and provide different services for value-added applications.

This paper addresses the convergent domain of cloud computing and IoT for any smart city application

deployment. Dubai as a smart city is discussed with some application-based scenarios. An IoT-based

healthcare framework is also proposed in the paper.

ETPL

IoT -007 Building smart cities applications using IoT and cloud-based architectures

In the Internet of Things (IoT), things will be able to sense, communicate, and interact. They will also

exchange data and information and locate themselves and other things that surround them. To interact,

the things must recognize that they're in proximity of other things. It's anticipated that a widespread

component of the IoT will be passive RFID tags, because they're inexpensive and provide automatic

identification. However, passive RFID tags can't perform complex operations, such as proximity

detection and localization. In this article, the authors describe existing problems with current RFID

systems and survey potential solutions for proximity detection. They then present a new RFID device,

called "Sense-a-Tag" (ST) that can passively detect and decode backscatter signals from tags in its

proximity. The authors show that when STs are added to a standard RFID system, the problems of

proximity detection in the IoT with RFID tags can readily be resolved. They demonstrate the feasibility

of an ST-based RFID system through proximity detection experiments.

ETPL

IoT - 008 Proximity Detection with RFID: A Step towards the Internet of Things

In this paper we use a locally developed adaptive watering system as an example of a remote controlled

laboratory (RCL) developed with standard open hardware and using libraries taken from the e-lab. This

experiment is a particular case that could benefit from a large number of RCLs proposing different

water budget strategies, allowing the studies of the best controller algorithm to save water. The water

consumption log can be monitored in real-time and served to any user as a distributed remote laboratory

with support of a Raspberry PI and a web connection, using an open source Arduino board and custom

made shield. The ultimate goal of RCLs will be achieved when anyone can easily publish their own

experiment in the WWW.

ETPL

IoT - 009 Turning the internet of (My) Things into a remote controlled Laboratory

The recent advancements in technology and the availability of the Internet make it possible to connect

various devices that can communicate with each other and share data. The Internet of Things (IoT) is

a new concept that allows users to connect various sensors and smart devices to collect real-time data

from the environment. However, it has been observed that a comprehensive platform is still missing in

the e-Health and m-Health architectures to use smartphone sensors to sense and transmit important

data related to a patient's health. In this paper, our contribution is twofold. Firstly, we critically evaluate

the existing literature, which discusses the effective ways to deploy IoT in the field of medical and

smart health care. Secondly, we propose a new semantic model for patients' e-Health. The proposed

model named as `k-Healthcare' makes use of 4 layers; the sensor layer, the network layer, the Internet

layer and the services layer. All layers cooperate with each other effectively and efficiently to provide

a platform for accessing patients' health data using smart phones.

ETPL

IoT - 010 Effective ways to use Internet of Things in the field of medical and smart

health care

The Internet of Things (IoT) has become a popular subject in the technology industry and will soon

reach the popularity level of smartphones. With the rapid technological advancements of sensors,

Wireless Sensor Networks (WSNs) has become the main technology for IoT. We investigated the

security of WSNs in an environmental monitoring system with the goal to improve the overall security.

We implemented a Secure Temperature Monitoring System (STMS), which served as our

investigational environment. Our results revealed a security flaw found in the bootstrap loader (BSL)

password used to protect firmware found in the MSP430 MCU. We demonstrated how the BSL

password could be brute forced in a matter of days. Furthermore, to our knowledge we illustrated the

first sample of how an attacker can reverse engineer firmware and obtain WSN cryptographic keys.

Our sample provides a step-by-step procedure on how to reverse engineer MSP430 firmware. We

contributed a solution to improve the BSL password and better protect firmware found in the MSP430

chips. The Secure-BSL software we contributed allows the randomization of the BSL password. Our

solution guarantees brute force times in a matter of decades. The impractical brute force time assures

the security of firmware and prevents future reverse engineering tactics. In addition, our Secure-BSL

software supports two-factor authentication, therefore adding another layer of security. The two-factor

authentication feature allows developers to specify a user-defined passphrase to further protect the

MSP430 MCU. Our research serves as proof that any security implemented in a WSN environment is

broken if an attacker has access to firmware found in sensor devices.

ETPL

IoT - 011 Improving the security of wireless sensor networks in an IoT

environmental monitoring system

Smart cities applications and infrastructures are actively being developed and rolled out. However,

maintenance complexity is significant, often limiting deployments to small regions or small cities. To

support gradual or spontaneous infrastructure scaling at region or national levels, infrastructure

management that monitors end device connectivity and ensures overall IoT communication reliability

becomes key. This article describes a method using intercontinental research facilities that

programmatically manages smart devices and their communication with the ultimate aim to elastically

deploy IoT servers in the cloud. Implementation details and experimental results of real devices are

included.

ETPL

IoT - 012 Towards programmable and scalable IoT infrastructures for smart cities

With development of technologies and industry, our living becomes more comfortable. However, a

problem of today's world is population aging. Over last decades the number of older people has been

increasing. The goal of many researches is to enable elderly people to live independently. The ambient

assisted living encompasses technical systems, infrastructures, and services to support elderly people

in their daily routine and to allow an independent and safe lifestyle as long as possible. One of those

projects is eWALL project. IoT is a concept that is used in these projects and it represents the

connections between humans and smart objects that are part of this environments. In these kinds of

smart environments, different technologies are used for communication. These technologies are: Wi-

Fi, Bluetooth, Bluetooth Low Energy and ZigBee. The goal of this work is to show possible problems

in coexistence of above mentioned technologies. Also, cognitive radio is considered as a solution for

interference problem caused by coexistence of different technologies in home environment.

ETPL

IoT - 014 Interoperability of IoT wireless technologies in ambient assisted living

environments

Agriculture sector being the backbone of the Indian economy deserves security. Security not in terms

of resources only but also agricultural products needs security and protection at very initial stage, like

protection from attacks of rodents or insects, in fields or grain stores. Such challenges should also be

taken into consideration. Security systems which are being used now a days are not smart enough to

provide real time notification after sensing the problem. The integration of traditional methodology

with latest technologies as Internet of Things and Wireless Sensor Networks can lead to agricultural

modernization. Keeping this scenario in our mind we have designed, tested and analysed an 'Internet

of Things' based device which is capable of analysing the sensed information and then transmitting it

to the user. This device can be controlled and monitored from remote location and it can be

implemented in agricultural fields, grain stores and cold stores for security purpose. This paper is

oriented to accentuate the methods to solve such problems like identification of rodents, threats to crops

and delivering real time notification based on information analysis and processing without human

intervention. In this device, mentioned sensors and electronic devices are integrated using Python

scripts. Based on attempted test cases, we were able to achieve success in 84.8% test cases.

ETPL

IoT - 013 Development of IoT based smart security and monitoring devices for

agriculture

In this paper, we propose a new model for parent alerting and automatic attendance marking using of

RFID (Radio-Frequency Identification) and GSM (Global System for Mobile Communication). This

system will enable automated and reliable attendance, informing parents and school administration

about the same. For implementing this system each student and professor will be having a unique RFID

card. A micro controller is attached to the classroom door which is used to match the RFID of the

student with the RFID present in the database. If they are match the door will open. This is done by

using a GSM module.

ETPL

IoT - 015 Attendance generating system using RFID and GSM

The concept of a Smart City highlights the need to enhance quality, interconnection and performance

of various urban services with the use of information and communication technologies (ICT). Smart

City technologies promote cloud-based and Internet of Things (IoT) based services in which real-world

user interfaces use smart phones, sensors and RFIDs. Cloud computing and IoT are presently two most

important ICT models that are shaping the next generation of computing. Both concepts have major

impact on how we build and deploy smart applications/solutions for smart cities. Cloud computing

represents the delivery of hardware and software resources on demand over the Internet-as-a-service.

On the other hand, IoT concept envisions a new generation of devices (sensors, both virtual and

physical) that are connected to the Internet and provide different services for value-added applications.

This paper addresses the convergent domain of cloud computing and IoT for any smart city application

deployment. Dubai as a smart city is discussed with some application-based scenarios. An IoT-based

healthcare framework is also proposed in the paper.

ETPL

IoT - 016 Building smart cities applications using IoT and cloud-based architectures

In recent years, the rapid development of Internet of Technology (IOT) makes the intelligent home

come true as people expect. The intelligent home system creates the more comfortable, safer, humane

and intelligent living environment. It can resolve the problems facing by the people who have busy

schedules and get a very less amount of time to spend at home which is increasing rapidly around the

world. For the solution of this problem, user can depend on the automated machines and gadgets like

smart phones. These smart gadgets are using cloud computing which sends and receives signal o the

cloud. The data that is of our use can be fetched by matching some key values using the concept of

information retrieval. The key objective of this paper is to create a full-fledged application which could

let user to operate the lights of their house from any remote location. The user have a list of options to

select which light is to be on and when. The only requirement is to have working Wi-Fi at home to

which the lights are connected. The developed in Lua Language by using the Esplorer Integrated

Development Environment (IDE). We have also used the micro controller chip ESP 8266 to build our

board.

ETPL

IoT - 017 An IOT by information retrieval approach: Smart lights controlled using

WiFi

The rapid progress in electronics, sensing, actuation, signal processing, and communication networking

has spurred emergence of new technologies like Internet of Things (IoT). In this paper, we report our

work on a multi-function IoT (MioT) platform. The MioT supports multiple wireless waveforms that

can be used for long as well as short range and beyond-line-of-sight environments and an IEEE

802.15.4 ultra-wide band (UWB) waveform for accurate and precise RF-positioning system in harsh

wireless environments, e.g., indoor and industrial environments. With the MioT a library of software

APIs are provided to configure different parameters of the device through the USB interface. Besides,

USB can also be used to transfer data from host to the MioT and vice-versa. Using the MioT we develop

a flexible implementation of the DMR access technology. This implementation is used to provide a

robust long-range link for robotic command and control and for cognitive management of WiFi mesh-

networks in a project for robotic-assisted search and rescue operations in disaster areas. We also report

our preliminary results on RF-ranging based on the UWB waveform.

ETPL

IoT - 018 Software-defined wireless communications and positioning device for IoT

development

Smart environments such as smart grid, smart transportation, smart buildings are upon us because of

major advances in sensor, communication, cloud and other cyber-physical system technologies. The

collective name for interconnected sensors, placed on "things" within fixed cyber-physical

infrastructures, is Internet of Things (IoT). IoT enables cities and rural areas to become smarter and to

offer new digital services and functions to diverse groups of users. However, IoT often represents

interconnection of static things, which are built-in into the physical infrastructures of users' homes,

offices, roads and other physical and critical infrastructures. In this paper, we analyze things that are

mobile, and explore the space of Internet of Mobile Things (IoMT). Mobility of digital devices such

as phones and vehicles has been with us for some time, but as the number of sensors in mobile devices

increases, the density of mobile devices increases, and users' reliance on mobile devices increases,

mobile things become very much an integral fabric of our smart environment. In this paper, our goal

is to discuss challenges, selective designs and implementations of IoMT. We show the impact of

mobility and the care we collectively have to take when designing the next generation of smart

environments with mobile things in them.

ETPL

IoT - 019 Internet of Mobile Things: Mobility-Driven Challenges, Designs and

Implementations

The pervasiveness of IoT devices will usher an unprecedented growth in the amount of digital data

produced and consumed. Realizing the rich class of applications enabled by IoT devices requires large-

scale machine learning systems to analyze, organize and draw inferences from data. State-of-the-art

machine learning algorithms are highly compute and data intensive, posing significant computational

challenges across the spectrum of computing devices, from low-power client devices to the cloud. As

benefits due to semiconductor technology scaling diminish, addressing the computational gap requires

identifying new sources of computing efficiency. We highlight 3 approaches viz. machine learning

accelerators, approximate computing and post-CMOS technologies that demonstrate significant

promise in bridging the efficiency gap. Such technologies may be instrumental in enabling machine

learning based IoT applications to enter the mainstream.

ETPL

IoT - 020 Efficient embedded learning for IoT devices

The Internet of Things (IoT) is driving the technology and advances of the Internet and every day it is

becoming more popular to talk about IoT systems in multiple domains: Smart Cities, Agriculture, and

Industrial Internet, etc. Increasingly, IoT systems will need to interact and be interconnected for

offering the always-promoted everything-connected paradigm. Current IoT systems rely on semantic

web technologies for integrating data and ensure web services interoperability. However there are yet

a gap to ensure semantic interoperability among IoT systems. Most of the existing proposed (open)

approaches and solutions lack on formal methodologies for interoperability in technology and standard

format of the data. We studied and analyzed most available semantic-based IoT approaches to identify

the main requirements hindering IoT semantic interoperability. In this paper, we present SEG 3.0 a

methodology to federate, unify and provide semantic interoperability. SEG 3.0 emerges from

methodologies for ontology engineering and the idea of unification and federated systems. We propose

SEG 3.0 and apply it to Internet of Things (IoT) and particularly on use cases for smart cities as proof

of concept. Firstly, we define characteristics required for the methodology. Secondly, we describe the

processes and the different formal steps. Thirdly, we provide a proof of concept framework and

architecture applying this methodology, thus the benefits of using SEG 3.0 methodology in IoT

domains are described. Finally, we demonstrate that the SEG 3.0 methodology is applied to three use

cases: (1) the M3 framework to assist developers in designing semantic-based IoT applications, (2) the

VITAL EU project for smart cities, and (3) the FIESTA-IoT EU project for IoT semantic

interoperability. SEG 3.0 is a formal methodology generic enough to be applied to other domains than

IoT and smart cities, since the main benefit of the SEG 3.0 is integrating heterogeneous data and adding

value to it - o build innovative applications.

ETPL

IoT - 021 Connected Smart Cities: Interoperability with SEG 3.0 for the Internet of

Things

The Internet of Things with its enormous growth widens its applications to the living environment of

the people by changing a home to smart home. Smart home is a connected home that connects all type

of digital devices to communicate each other through the internet. These devices form a home area

network where communications are enabled by different protocols. As these devices are designed by

different companies with different standards and technologies there is a problem exists in their

connectivity. This paper aims at describing the wireless standards used in home network and how these

protocols face the connectivity challenges in the smart home network.

ETPL

IoT - 022 A review of connectivity challenges in IoT-smart home

Following a surgical procedure, patients are monitored in an ICU until physically stable, after which

are discharged to a ward for further evaluation and recovery. Usually, ward evaluation does not imply

continuous physiological parameters monitoring and therefore patient relapse is not uncommon. The

present paper describes the steps taken to design and build a low-cost modular monitoring system

prototype. This system aims to offer mobile support in order to facilitate faster and better medical

interventions in emergency cases and has been developed using low-power dedicated sensor arrays for

EKG, SpO2, temperature and movement. The interfaces for these sensors have been developed

according to the IoT model: a central control unit exposes a RESTful based Web interface that ensures

a platform agnostic behaviour and provides a flexible mechanism to integrate new components.

ETPL

IoT - 023 An IoT based system for remote patient monitoring

Healthcare is one of the most rapidly expanding application areas of the Internet of Things (IoT)

technology. IoT devices can be used to enable remote health monitoring of patients with chronic

diseases such as cardiovascular diseases (CVD). In this paper we develop an algorithm for ECG

analysis and classification for heartbeat diagnosis, and implement it on an IoT-based embedded

platform. This algorithm is our proposal for a wearable ECG diagnosis device, suitable for 24-hour

continuous monitoring of the patient. We use Discrete Wavelet Transform (DWT) for the ECG

analysis, and a Support Vector Machine (SVM) classifier. The best classification accuracy achieved is

98.9%, for a feature vector of size 18, and 2493 support vectors. Different implementations of the

algorithm on the Galileo board, help demonstrate that the computational cost is such, that the ECG

analysis and classification can be performed in real-time.

ETPL

IoT - 024 ECG signal analysis and arrhythmia detection on IoT wearable medical

devices

The new technologies characterizing the Internet of Things (IoT) allow realizing real smart

environments able to provide advanced services to the users. Recently, these smart environments are

also being exploited to renovate the users' interest on the cultural heritage, by guaranteeing real

interactive cultural experiences. In this paper, we design and validate an indoor location-aware

architecture able to enhance the user experience in a museum. In particular, the proposed system relies

on a wearable device that combines image recognition and localization capabilities to automatically

provide the users with cultural contents related to the observed artworks. The localization information

is obtained by a Bluetooth low energy (BLE) infrastructure installed in the museum. Moreover, the

system interacts with the Cloud to store multimedia contents produced by the user and to share

environment-generated events on his/her social networks. Finally, several location-aware services,

running in the system, control the environment status also according to users' movements. These

services interact with physical devices through a multiprotocol middleware. The system has been

designed to be easily extensible to other IoT technologies and its effectiveness has been evaluated in

the MUST museum, Lecce, Italy.

ETPL

IoT - 025 An Indoor Location-Aware System for an IoT-Based Smart Museum

Internet of Things (IoT) envisions a future in which anything/anyone/anyservice can be linked by

means of appropriate information and communication technologies which will bring technological

revolution in the fields of domestics, smart homes, healthcare systems, goods monitoring and logistics.

This paper presents the applications of IoT and addresses some essential parameters and characteristics

of each of the applications of IoT. In this paper, we have deeply explored the role of IoT in healthcare

delivery and its technological aspects that make it a reality and examine the opportunities. A cloud

based conceptual framework has been proposed which will be beneficial to the healthcare industry

implementing IoT healthcare solutions.

ETPL

IoT - 026 A conceptual framework for IoT-based healthcare system using cloud

computing

One of the challenges faced by today's Internet of Things (IoT) is to efficiently support machine-to-

machine communication, given that the remote sensors and the gateway devices are connected through

low bandwidth, unreliable, or intermittent wireless communication links. In this paper, we

quantitatively compare the performance of IoT protocols, namely MQTT (Message Queuing Telemetry

Transport), CoAP (Constrained Application Protocol), DDS (Data Distribution Service) and a custom

UDP-based protocol in a medical setting. The performance of the protocols was evaluated using a

network emulator, allowing us to emulate a low bandwidth, high system latency, and high packet loss

wireless access network. This paper reports the observed performance of the protocols and arrives at

the conclusion that although DDS results in higher bandwidth usage than MQTT, its superior

performance with regard to data latency and reliability makes it an attractive choice for medical IoT

applications and beyond.

ETPL

IoT - 027 Performance evaluation of IoT protocols under a constrained wireless

access network

The Concepts of Internet of Things (IoT) are applied to a number of applications ranging from home

automation to industrial IoT, Where connecting physical things, from anywhere through a network.

Let them take an active part in the Internet, exchanging information about themselves and their

surroundings. This will give immediate access to information about the physical world and the objects

in it leading to innovative services and increase in efficiency and productivity. The proposal of system

is to develop an IoT based Interactive Industrial Home wireless system, Energy management system

and embedded data acquisition system to display on web page using GPRS, SMS & E-mail alert. This

device is essential for sensor data collection and controlling of the industrial Home Wireless Sensor

Networks (WSN) in the Internet of Things (IoT) environment. It is planned to style a re-configurable

sensible device interface for industrial WSN in IoT atmosphere, during which ARM is adopted as the

core controller. Thus, it will scan information in parallel and in real time with high speed on multiple

completely different device information. Intelligent device interface specification is adopted for this

style. The device is combined with the most recent ARM programmable technology and intelligent

device specification. By detecting the values of sensors it can be easily find out the Temperature,

Smoke, and Fire present in the industrial environment on the Website and we can handle any situation

from anywhere in the world through IOT. So that critical situation can be avoided and preventive

measures are successfully implemented.

ETPL

IoT - 028 IoT based Interactive Industrial Home wireless system, Energy

management system and embedded data acquisition system

IoT(Internet of Things) is global infrastructure that enables any object to communicate. The term IoT

is being widely used and that technologies are being applied to various areas. IoT technologies is

expected to increase many services' convenience, expandability, accessibility and interoperability, but

existing ICT environment could be exposed new security threats due to increased openness and IoT

device's specialty. Actually, IoT devices' vulnerabilities and exploits are reported. If attacks on IoT

devices succeed, it can cause much damage over the various areas. Therefore, we categorize IoT

devices and examines threats of each category. Finally we deduct security requirements of IoT devices.

ETPL

IoT - 029 A Study on Device Security in IoT Convergence

To kick-start the process of morphing Messina into a "smart" city, an explicit mission for the crowd

funded #Smart ME project, it is essential to set up an infrastructure of smart devices embedding sensors

and actuators, to be scattered all over the urban area. A horizontal framework coupled with the Fog

computing approach, by moving logic toward the "extreme" edge of the Internet where data needs to

be quickly elaborated, decisions made, and actions performed, is a suitable solution for data- intensive

services with time-bound constraints as those usually required by citizens. This is especially true in the

context of IoT and Smart City where thousands of smart objects, vehicles, mobiles, and people interact

to provide innovative services. We thus designed Stack4Things as an Open Stack-based framework

spanning the Infrastructure-as-a-Service and Platform-as-a-Service layers. We present some of the core

Stack4Things functionalities implementing a Fog computing approach towards a run- time "rewire

able" Smart City paradigm, by outlining node management and contextualization mechanisms, also

describing its usage in terms of already supported and developed verticals, as well as a specific example

related to environmental data collection through #Smart ME.

ETPL

IoT - 030 An IoT Testbed for the Software Defined City Vision: The #SmartMe

Project