Energy-Efficient Communication with Lightweight M2M in IoT Networks

Gonzalo Peces, Carlos

January 2018

OMA’s Lightweight Machine to Machine (LwM2M) is an application protocol for device management in the Internet of Things (IoT) that has been recently published and widely adopted in a lot of projects. The protocol is designed to operate in sensor networks and machine-to-machine environments, where one of the main constraints is the energy consumption since the nodes are usually battery powered. Different strategies to achieve high energy efficiency in IoT networks have been developed, but there is no deep knowledge about the performance of LwM2M operating with them. Moreover, the specification of this protocol includes one strategy, called the Queue Mode, which could be more efficient than the usual ones because it has been specified for this particular protocol. This project aims to implement this Queue Mode at both sides of the communication, and then evaluate its performance by comparing it with TSCH, which is the standard MAC protocol used in IEEE 802.15.4 that defines a way of radio duty cycling. It has been proven to achieve a high energy efficiency, and that is the main reason why it is selected. The comparison is performed according to several metrics to have a comprehensive evaluation, and in different kind of scenarios, with different numbers of IoT devices and different parameters in the communication. The implementation was done inside the Contiki-NG OS for the client side, which is an operating systems designed for constrained devices. For the server side it has been carried out inside the Eclipse Leshan code, which is a LwM2M implementation in Java made by the Eclipse Foundation. As a result of the evaluation, it shown that both implementations operate correctly. This thesis contributes as a guideline for making decisions about which low power strategy is better to use depending on the IoT scenario and the type of application. It shows that for many use cases Queue Mode is a better option than TSCH because it achieves a higher energy efficiency and the rest of the metrics used in the evaluation have also improved values. TSCH has a better performance only in demanding scenarios or in cases where the communication is not produced at fixed time instants. The thesis was developed in cooperation with RISE SICS AB, Networked Embedded Systems Group. / OMA:s Lightweight Machine to Machine (LwM2M) är ett applikationsprotokoll för enhetshantering i Sakernas Internet (IoT) som nyligen har publicerats och börjat användas i många projekt. Protokollet är utformat för att fungera i sensornätverk och maskin-till-maskin miljöer, där en av de viktigaste begränsningarna är energiförbrukningen eftersom noderna vanligtvis är batteridrivna. Olika strategier för att uppnå hög energieffektivitet i sensornätverk har utvecklats, men det finns ingen djup kunskap om hur LwM2M fungerar med dem. Dessutom innehåller specifikationen av LwM2M en strategi kallad Queue Mode (köläge) som kan vara effektivare än de vanliga strategierna eftersom den har utvecklats direkt för det här protokollet.Detta examensarbete syftar till att implementera detta köläge på båda sidor av kommunikationen och sedan utvärdera prestandan genom att jämföra det med TSCH, vilket är ett MAC-protokoll specificerat i IEEE 802.15.4-standarden. Tidigare arbeten har visat att TSCH kan uppnå en låg energiförbrukning, vilket är den främsta anledningen till att detta protokoll väljs ut för att jämföra mot LwM2M:s köläge. Jämförelsen inkluderar flera olika typer av mätvärden och scenarier för att få en omfattande utvärdering, samt med flera olika antal sensor noder och parametrar.Implementationen gjordes för Contiki-NG OS på klientsidan, vilket är ett operativsystem för resursbegränsade IoT-enheter. På serversidan har implementationen gjorts för Eclipse Leshan, vilken är en LwM2M-implementation skriven i Java och publicerad av Eclipse Foundation. Som en följd av utvärderingen har det visat sig att båda implementationerna fungerar korrekt.Detta examensarbete bidrar med riktlinjer för att fatta beslut om vilken energibesparingsstrategi som är bättre att använda beroende på IoT-scenariot och typen av applikation. Utvärderingen visar hur Queue Mode i många användningsfall är ett bättre alternativ än TSCH eftersom det uppnår en högre energieffektivitet utan att de andra typerna av mätvärden påverkas av det. I vissa fall uppnås dessutom förbättrade resultat även i de andra typerna av mätvärden. TSCH har endast bättre prestanda i krävande scenarier eller i fall där kommunikationen inte genereras vid bestämda tillfällen.Examensarbetet har genomförts hos Networked Embedded Systems-gruppen på RISE SICS AB.

Elektroteknik och elektronik

Intelligence Orchestration in IoT and Cyber-Physical Systems

Jayagopan, Maheswaran, Saseendran, Ananthu

January 2022

The number of IoT and cyber-physical systems will be growing in the comingfuture. According to estimates, more than 21 billion IoT devices are expectedto exist by 2025. The adoption of Digital Twins and AI-enhanced IoTapplications is projected to fuel the expected increase in IoT spending.It is essential to accelerate the development., deployment, and administrationof these IoT applications, which can be accomplished by orchestrating IoTcomponents, devices, services, and systems. IoT Intelligence orchestrationposes several obstacles that must be overcome for a wide range of domainspecific use cases and applications to follow and support business logic.This thesis aims to create a secure and full proof way of orchestratingintelligence within IoT devices from multiple ecosystems.It also aims tobreak down the current approach of monolithic development and introduce amixture of visual programming and distributed systems considering all thenecessary cyber-security aspects,.A comparison of the developed framework and the existing tool with thenecessary characteristics like security, response time and the accuracy too isincluded.of the thesis.

IoT

Cyber-physical systems

SSL

protocols

Workflow

Route mapping

MQTT

Lwm2m

HTTP

HTTPS

Intelligence Orchestration

Distributed systems

Computer Engineering

Datorteknik

End-to-end Security Enhancement of an IoT Platform Using Object Security

Tjäder, Hampus

January 2017

The Internet of Things (IoT) is seen as one of the next Internet revolutions. In a near future the majority of all connected devices to the Internet will be IoT devices. These devices will connect previously offline constrained systems, thus it is essential to ensure end-to-end security for such devices. Object Security is a concept where the actual packet or sensitive parts of the packet are encrypted instead of the radio channel. A compromised node in the network will with this mechanism still have the data encrypted ensuring full end-to-end security. This paper proposes an architecture for using the object security format COSE in a typical constrained short-range radio based IoT platform. The IoT platform utilizes Bluetooth Low Energy and the Constrained Application Protocol for data transmission via a capillary gateway. A proof-of-concept implementation based on the architecture validates that the security solution is implementable. An overhead comparison between current channel security guidelines and the proposed object security solution results in a similar size for each data packet. The thesis concludes that object security should be seen as an alternative for ensuring end-to-end security for the Internet of Things.

Object security

COSE

IoT security

End-to-end security

CoAP

LWM2M

Bluetooth Low Energy

BLE security

Elektroteknik och elektronik