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Prof. Jerker Delsing
Department of Computer Science, Electrical and Space Engineering, Luleå University of Technology, A2308 Luleå, Sweden

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Research Keywords & Expertise

0 EMC
0 sensor networks
0 Ultrasonic Sensors
0 IoT and SoS architecture
0 Sensor electronics

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Short Biography

Prof. Jerker Delsing received the M.Sc. in Engineering Physics at Lund Institute of Technology, Sweden in 1982. In 1988, he received the PhD. degree in Electrical Measurement at the Lund University. During 1985 - 1988, he worked part time at Alfa-Laval - SattControl (now ABB) with development of sensors and measurement technology. In 1994, he was promoted to associate professor in Heat and Power Engineering at Lund University. Early in 1995, he was appointed full professor in Industrial Electronics at Lulea University of Technology, where he is currently chaired professor in Cyber Physical Systems. His present research profile can be entitled IoT/SoS Automation, with applications to automation in large and complex industry and society systems. Prof. Delsing and the EISLAB group http://www.ltu.se/eislab has been a partner of several large EU projects in the field, e.g. Socrades, IMC-AESOP, Arrowhead, FAR-EDGE, Productive4.0 and Arrowhead Tools. Delsing holds positions as vice President of ARTEMIS-IA and board member of ProcessIT.EU and ProcessIT Innovations.

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Journal article
Published: 03 August 2021 in IEEE Access
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The Internet of Things (IoT) is rapidly changing the number of connected devices and the way they interact with each other. This increases the need for an automated and secure onboarding procedure for IoT devices, systems and services. Device manufacturers are entering the market with internet connected devices, ranging from small sensors to production devices, which are subject of security threats specific to IoT. The onboarding procedure is required to introduce a new device in a System of Systems (SoS) without compromising the already onboarded devices and the underlying infrastructure. Onboarding is the process of providing access to the network and registering the components for the first time in an IoT/SoS framework, thus creating a chain of trust from the hardware device to its hosted software systems and their provided services. The large number and diversity of device hardware, software systems and running services raises the challenge to establish a generic onboarding procedure. In this paper, we present an automated and secure onboarding procedure for SoS. We have implemented the onboarding procedure in the Eclipse Arrowhead framework. However, it can be easily adapted for other IoT/SoS frameworks that are based on Service-oriented Architecture (SoA) principles. The automated onboarding procedure ensures a secure and trusted communication between the new IoT devices and the Eclipse Arrowhead framework. We show its application in a smart charging use case and perform a security assessment.

ACS Style

Silia Maksuti; Ani Bicaku; Mario Zsilak; Igor Ivkic; Balint Peceli; Gabor Singler; Kristof Kovacs; Markus Tauber; Jerker Delsing. Automated and Secure Onboarding for System of Systems. IEEE Access 2021, 9, 111095 -111113.

AMA Style

Silia Maksuti, Ani Bicaku, Mario Zsilak, Igor Ivkic, Balint Peceli, Gabor Singler, Kristof Kovacs, Markus Tauber, Jerker Delsing. Automated and Secure Onboarding for System of Systems. IEEE Access. 2021; 9 ():111095-111113.

Chicago/Turabian Style

Silia Maksuti; Ani Bicaku; Mario Zsilak; Igor Ivkic; Balint Peceli; Gabor Singler; Kristof Kovacs; Markus Tauber; Jerker Delsing. 2021. "Automated and Secure Onboarding for System of Systems." IEEE Access 9, no. : 111095-111113.

Journal article
Published: 30 April 2021 in Smart Cities
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Many smart city applications have been proposed and demonstrated over the years; however, moving to large-scale deployment is still scarce. A contributing factor to this scarcity is the lack of well-established engineering methodologies for large-scale smart city applications. This paper addresses engineering methodologies and tools for large-scale smart city application engineering, implementation, deployment, and evolution. A model-based engineering approach based on IoT, SOA, and SysML is proposed and applied to a smart streetlight application. Engineering considerations for streetlight area enlargement and updated technology generations with additional capabilities are discussed. The proposed model-based engineering approach provides considerable scaling simplifications and opportunities for considerable savings on engineering costs. The model-based engineering approach also provides good documentation that enables technology evolution specifications that support both maintenance and emerging behaviours.

ACS Style

Jerker Delsing. Smart City Solution Engineering. Smart Cities 2021, 4, 643 -661.

AMA Style

Jerker Delsing. Smart City Solution Engineering. Smart Cities. 2021; 4 (2):643-661.

Chicago/Turabian Style

Jerker Delsing. 2021. "Smart City Solution Engineering." Smart Cities 4, no. 2: 643-661.

Journal article
Published: 11 November 2019 in IEEE Internet of Things Journal
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The Internet of Things (IoT) enables interaction from real-world physical objects using sensors to the virtual world of computers and the Internet. The use of service-oriented architecture (SOA) is one step in the creation of basic and complex interactions between several sensors and actuators. However, the use of SOA-enabled technologies alone does not meet all requirements of how sensor and actuator systems could be integrated to create distributed monitoring and control applications. The centralized, traditional method of communication in wireless sensor networks via a gateway presents drawbacks that have to be addressed; device-to-cloud communication adds higher latency and higher power consumption and is less robust than the device-to-device communication approach. Moreover, all these characteristics reduce the scalability of the network, thus limiting the use of IoT in the industry. In this paper, the proposed method utilizes the Arrowhead framework orchestration system to generate service composition within a (wireless) network formed by IoT devices. The aim is to achieve efficient device-to-device service invocation to reduce the drawbacks of today's widely used device-to-cloud approach. The method in this paper performs efficient service composition for industrial IoT, including mapping SOA service composition in very small resource-constrained devices using the Arrowhead orchestration. The results presented in this paper at the service level can increase performance and robustness in fog computing on resource-constrained devices.

ACS Style

Cristina Paniagua; Jens Eliasson; Jerker Delsing. Efficient Device-to-Device Service Invocation Using Arrowhead Orchestration. IEEE Internet of Things Journal 2019, 7, 429 -439.

AMA Style

Cristina Paniagua, Jens Eliasson, Jerker Delsing. Efficient Device-to-Device Service Invocation Using Arrowhead Orchestration. IEEE Internet of Things Journal. 2019; 7 (1):429-439.

Chicago/Turabian Style

Cristina Paniagua; Jens Eliasson; Jerker Delsing. 2019. "Efficient Device-to-Device Service Invocation Using Arrowhead Orchestration." IEEE Internet of Things Journal 7, no. 1: 429-439.

Dataset
Published: 01 April 2019 in ENERGYO
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Exponential growth in computing, wireless communication, and energy storage efficiency is key to allowing smaller and scalable IoT solutions. These advancements have made it possible to power devices from energy harvesters (EH) and explore other energy storage solutions that can increase the lifetime and robustness of IoT devices. We summarize current trends and limits for the current paradigm as the basis of our forecast. The trend shows that conventional ceramic capacitors are sufficient for energy storage for today’s EH powered wireless IoT devices and that in the future, IoT devices can either perform more advanced tasks with their current volume or be shrunk in size.

ACS Style

Fredrik Häggström; Jerker Delsing. IoT Energy Storage - A Forecast. ENERGYO 2019, 1 .

AMA Style

Fredrik Häggström, Jerker Delsing. IoT Energy Storage - A Forecast. ENERGYO. 2019; ():1.

Chicago/Turabian Style

Fredrik Häggström; Jerker Delsing. 2019. "IoT Energy Storage - A Forecast." ENERGYO , no. : 1.

Journal article
Published: 11 February 2019 in IEEE Systems Journal
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As society has progressed through periods of evolution and revolution, technology has played a key role as an enabler. In the same manner, mechanical machines of the 1800s drove the industrial revolution, now digitalized machines are driving another industrial revolution. Manufacturers are increasing the digital footprint on the factory floor. It is challenging to harness the vast amounts of data generated, stored, analyzed, archived, and returned. Data centralization has several well-known challenges, such as collection bottlenecks, secure retrieval, single point of failure, and data scheme fragility as data heterogeneity increases. This paper proposes a method of information distribution based on the principle of data at its source. It proposes that contextual data be used at runtime through the creation of dynamic queries that build compositions of different systems. Such system of systems (SoS) compositions handle the flow of data across its life cycle and present it as information to the initiating system. The proposal starts by creating a graph model of the Arrowhead framework. Then, building on the graph model, the query-based approach for specifying, validating, and forming the SoS is proposed. The proposed graph model allows for unambiguous description of systems and their interrelations, including security relations. The proposed composer operates on the edge computing hardware and gives the production floor the ability to extract information without impacting the overall operation of the factory.

ACS Style

Hasan Derhamy; Jens Eliasson; Jerker Delsing. System of System Composition Based on Decentralized Service-Oriented Architecture. IEEE Systems Journal 2019, 13, 3675 -3686.

AMA Style

Hasan Derhamy, Jens Eliasson, Jerker Delsing. System of System Composition Based on Decentralized Service-Oriented Architecture. IEEE Systems Journal. 2019; 13 (4):3675-3686.

Chicago/Turabian Style

Hasan Derhamy; Jens Eliasson; Jerker Delsing. 2019. "System of System Composition Based on Decentralized Service-Oriented Architecture." IEEE Systems Journal 13, no. 4: 3675-3686.

Journal article
Published: 20 September 2018 in Energy Harvesting and Systems
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Exponential growth in computing, wireless communication, and energy storage efficiency is key to allowing smaller and scalable IoT solutions. These advancements have made it possible to power devices from energy harvesters (EH) and explore other energy storage solutions that can increase the lifetime and robustness of IoT devices. We summarize current trends and limits for the current paradigm as the basis of our forecast. The trend shows that conventional ceramic capacitors are sufficient for energy storage for today’s EH powered wireless IoT devices and that in the future, IoT devices can either perform more advanced tasks with their current volume or be shrunk in size.

ACS Style

Fredrik Häggström; Jerker Delsing. IoT Energy Storage - A Forecast. Energy Harvesting and Systems 2018, 5, 43 -51.

AMA Style

Fredrik Häggström, Jerker Delsing. IoT Energy Storage - A Forecast. Energy Harvesting and Systems. 2018; 5 (3-4):43-51.

Chicago/Turabian Style

Fredrik Häggström; Jerker Delsing. 2018. "IoT Energy Storage - A Forecast." Energy Harvesting and Systems 5, no. 3-4: 43-51.

Journal article
Published: 27 December 2017 in IEEE Industrial Electronics Magazine
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The hype concerning digitalization is increasing the demand for new generations of automation systems. Concepts like Reference Architecture Model Industry 4.0 (RAMI 4.0) give us models but do not tell us how to facilitate actual implementations. This article discusses the transition from legacy automation technology as defined by ISA-95 to highly distributed Internet of Things (IoT)- and system of systems (SoS)- based automation systems that fully utilize Internet technologies, thus enabling the implementation of Industry 4.0 and RAMI 4.0 models. Distributed IoT automation systems have a number of general requirements concerning real-time performance, security, engineering cost, scalability, and interoperability. Meeting these requirements is necessary to enable possibilities for a realworld implementation of IoT automation. A key concept is local automation clouds. The discussion is based on a particular example of such an automation integration platform, the Arrowhead Framework.

ACS Style

Jerker Delsing. Local Cloud Internet of Things Automation: Technology and Business Model Features of Distributed Internet of Things Automation Solutions. IEEE Industrial Electronics Magazine 2017, 11, 8 -21.

AMA Style

Jerker Delsing. Local Cloud Internet of Things Automation: Technology and Business Model Features of Distributed Internet of Things Automation Solutions. IEEE Industrial Electronics Magazine. 2017; 11 (4):8-21.

Chicago/Turabian Style

Jerker Delsing. 2017. "Local Cloud Internet of Things Automation: Technology and Business Model Features of Distributed Internet of Things Automation Solutions." IEEE Industrial Electronics Magazine 11, no. 4: 8-21.

Journal article
Published: 10 November 2017 in International Journal of Computer Integrated Manufacturing
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ABSTARCT The use of Service Oriented Architectures (SOAs) in industrial automation promises an improved cross-layer integration as well as a functionality decoupled from the technical implementation. Compared with the earlier investigated manufacturing industry, control systems in the process industry reveal additional challenges in terms of migration from a legacy control system to an SOA control system. The successful migration of a highly integrated process control system, without reducing reliability or availability and, at the same time, preserving functionality and productivity, requires a detailed plan and certain specialised technology. This paper presents the challenges in the migration of a process control system and proposes a structured method for migration. The migration procedure proposed comprises four steps: initiation, configuration, data processing, and control execution. A technology demonstration at a pelletizing plant illustrates how the first of these steps could be implemented.

ACS Style

Oscar Carlsson; Jerker Delsing; Fredrik Arrigucci; Armando W Colombo; Thomas Bangemann; Philippe Nappey. Migration of industrial process control systems to service-oriented architectures. International Journal of Computer Integrated Manufacturing 2017, 31, 175 -198.

AMA Style

Oscar Carlsson, Jerker Delsing, Fredrik Arrigucci, Armando W Colombo, Thomas Bangemann, Philippe Nappey. Migration of industrial process control systems to service-oriented architectures. International Journal of Computer Integrated Manufacturing. 2017; 31 (2):175-198.

Chicago/Turabian Style

Oscar Carlsson; Jerker Delsing; Fredrik Arrigucci; Armando W Colombo; Thomas Bangemann; Philippe Nappey. 2017. "Migration of industrial process control systems to service-oriented architectures." International Journal of Computer Integrated Manufacturing 31, no. 2: 175-198.

Journal article
Published: 01 October 2017 in International Symposium on Microelectronics
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This work investigates the capability of drilling and metallization of microvias of diameter less than 10 μm with aspect ratios of 1–10, using a fully additive process. The microvia has been produced using a sequential build up layer of urethane through which the via has been produced. The urethane layer is applied using spin-coating. Current process setting produces a 15 μm layer thickness. For thicker urethane, multiple layers are applied. Drilling of the via-hole through is made using 266 nm UV laser. The metallisation of the via-hole was made using a process called Covalent Bonded Metallisation (CBM). This process modifies the urethane surface by a grafting process where polymers are covalently bonded to the surface where metallisation is desired. A roughly 5 μm thin film of the used grafting solution is applied to the substrate surface. The grafting process is initiated by laser which draws the patterns where copper is desired. After laser drawing, the substrate is cleaned with deionized water. Next, the substrate is through a commercial chemical-copper process which builds copper only at the laser initiated patterns. Copper thicknesses of 1 μm is easily achievable. To increase the copper thickness, the substrate may be run into thick building chemical-copper process to achieve thicknesses up to 8 μm.

ACS Style

Abdelghani Renbi; Jerker Delsing. A novel production process for 10 μm microvias. International Symposium on Microelectronics 2017, 2017, 000468 -000472.

AMA Style

Abdelghani Renbi, Jerker Delsing. A novel production process for 10 μm microvias. International Symposium on Microelectronics. 2017; 2017 (1):000468-000472.

Chicago/Turabian Style

Abdelghani Renbi; Jerker Delsing. 2017. "A novel production process for 10 μm microvias." International Symposium on Microelectronics 2017, no. 1: 000468-000472.

Journal article
Published: 01 June 2017 in Energy Procedia
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ACS Style

Jan Van Deventer; Hasan Derhamy; Khalid Atta; Jerker Delsing. Service Oriented Architecture enabling the 4 th Generation of District Heating. Energy Procedia 2017, 116, 500 -509.

AMA Style

Jan Van Deventer, Hasan Derhamy, Khalid Atta, Jerker Delsing. Service Oriented Architecture enabling the 4 th Generation of District Heating. Energy Procedia. 2017; 116 ():500-509.

Chicago/Turabian Style

Jan Van Deventer; Hasan Derhamy; Khalid Atta; Jerker Delsing. 2017. "Service Oriented Architecture enabling the 4 th Generation of District Heating." Energy Procedia 116, no. : 500-509.

Journal article
Published: 24 April 2017 in IEEE Internet of Things Journal
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In the Industrial Internet of Things there is a clear need for a high level of interoperability between independently developed systems, often from different vendors. Traditional methods of interoperability including protocol gateways and adapters are often used at the network layer. Recent work on application interoperability has emphasized the use of middleware or protocol proxy/gateway. However, middleware tends to move the interoperability problem rather than solving it, and there are scalability issues with increasing the number of proxies; re-configuration effort, and required bandwidth and processing overheads. This paper proposes a secure, on-demand and transparent protocol translator for the Industrial Internet of Things. Targeting the challenge of interoperability between IP-based communication protocols, the paper analyses current solutions and develops a set of requirements to be met by IoT protocol interoperability. The proposed protocol translator is not a middleware, it is a SOAbased participant, it is used on-demand when needed, it does not introduce design time dependencies, it operates transparently, it supports low-latency, and it is secured through the use of Arrowhead authorization and authentication.

ACS Style

Hasan Derhamy; Jens Eliasson; Jerker Delsing. IoT Interoperability—On-Demand and Low Latency Transparent Multiprotocol Translator. IEEE Internet of Things Journal 2017, 4, 1754 -1763.

AMA Style

Hasan Derhamy, Jens Eliasson, Jerker Delsing. IoT Interoperability—On-Demand and Low Latency Transparent Multiprotocol Translator. IEEE Internet of Things Journal. 2017; 4 (5):1754-1763.

Chicago/Turabian Style

Hasan Derhamy; Jens Eliasson; Jerker Delsing. 2017. "IoT Interoperability—On-Demand and Low Latency Transparent Multiprotocol Translator." IEEE Internet of Things Journal 4, no. 5: 1754-1763.

Book chapter
Published: 16 February 2017 in IoT Automation
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ACS Style

Oscar Carlsson; Daniel Vera; Eduardo Arceredillo; Markus G. Tauber; Bilal Ahmad; Christoph Schmittner; Sandor Plosz; Thomas Ruprechter; Andreas Aldrian; Jerker Delsing. 6 Engineering of IoT automation systems. IoT Automation 2017, 161 -210.

AMA Style

Oscar Carlsson, Daniel Vera, Eduardo Arceredillo, Markus G. Tauber, Bilal Ahmad, Christoph Schmittner, Sandor Plosz, Thomas Ruprechter, Andreas Aldrian, Jerker Delsing. 6 Engineering of IoT automation systems. IoT Automation. 2017; ():161-210.

Chicago/Turabian Style

Oscar Carlsson; Daniel Vera; Eduardo Arceredillo; Markus G. Tauber; Bilal Ahmad; Christoph Schmittner; Sandor Plosz; Thomas Ruprechter; Andreas Aldrian; Jerker Delsing. 2017. "6 Engineering of IoT automation systems." IoT Automation , no. : 161-210.

Book chapter
Published: 16 February 2017 in IoT Automation
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ACS Style

Michele Albano; Arne Skou; Luis L Ferreira; Thibaut Le Guilly; Per D Pedersen; Torben Bach Pedersen; Petur Olsen; Laurynas Šikšnys; Radislav Smid; Petr Stluka; Claude Le Pape; Chloé Desdouits; Rodrigo Castiñeira; Rafael Socorro; Inge Isasa; Jani Jokinen; Lorenzo Manero; Aitor Milo; Javier Monge; Anatolijs Zabasta; Kaspars Kondratjevs; Nadezhda Kunicina; Jerker Delsing. 7 Application system design - energy optimisation. IoT Automation 2017, 211 -246.

AMA Style

Michele Albano, Arne Skou, Luis L Ferreira, Thibaut Le Guilly, Per D Pedersen, Torben Bach Pedersen, Petur Olsen, Laurynas Šikšnys, Radislav Smid, Petr Stluka, Claude Le Pape, Chloé Desdouits, Rodrigo Castiñeira, Rafael Socorro, Inge Isasa, Jani Jokinen, Lorenzo Manero, Aitor Milo, Javier Monge, Anatolijs Zabasta, Kaspars Kondratjevs, Nadezhda Kunicina, Jerker Delsing. 7 Application system design - energy optimisation. IoT Automation. 2017; ():211-246.

Chicago/Turabian Style

Michele Albano; Arne Skou; Luis L Ferreira; Thibaut Le Guilly; Per D Pedersen; Torben Bach Pedersen; Petur Olsen; Laurynas Šikšnys; Radislav Smid; Petr Stluka; Claude Le Pape; Chloé Desdouits; Rodrigo Castiñeira; Rafael Socorro; Inge Isasa; Jani Jokinen; Lorenzo Manero; Aitor Milo; Javier Monge; Anatolijs Zabasta; Kaspars Kondratjevs; Nadezhda Kunicina; Jerker Delsing. 2017. "7 Application system design - energy optimisation." IoT Automation , no. : 211-246.

Journal article
Published: 19 August 2015 in Journal of Electronic Testing
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This paper introduces a practical test method that combines statistics with a contactless test approach. Experiments using real PCBs show the effectiveness of the method, where significant z-scores are obtained to discriminate defective interconnects. The studied test cases involve conventional Printed Circuit Boards (PCBs) with Ball Grid Array (BGA) packages and open sockets.

ACS Style

Abdelghani Renbi; Jerker Delsing. Application of Contactless Testing to PCBs with BGAs and Open Sockets. Journal of Electronic Testing 2015, 31, 339 -347.

AMA Style

Abdelghani Renbi, Jerker Delsing. Application of Contactless Testing to PCBs with BGAs and Open Sockets. Journal of Electronic Testing. 2015; 31 (4):339-347.

Chicago/Turabian Style

Abdelghani Renbi; Jerker Delsing. 2015. "Application of Contactless Testing to PCBs with BGAs and Open Sockets." Journal of Electronic Testing 31, no. 4: 339-347.

Journal article
Published: 01 June 2015 in Journal of Electronic Testing
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State-of-the-art printed circuit boards (PCBs) have become extremely dense and are not fully accessible for applying physical testing solutions. Extra steps are required in the design and manufacturing process for testing advanced printed wiring boards (PWBs) with embedded passive components. This processing is further complicated by upcoming sequential build-up (SBU) technologies that provide feature sizes smaller than 10 μm and that do not allow physical access for testing the interconnect between two pads. In this paper, we propose a new contactless technique for overcoming the SBU challenge for testing interconnects between embedded components. A test trace is employed as a sensor, which senses the terminations of the trace being tested. The simulation and analysis results of this study demonstrate the feasibility of this concept for application to SBU and conventional PCB/PWB interconnect testing to overcome the barriers to physical access. Robustness of the approach has been studied against packaging deviations and possible testing process variations. To ensure defect detection with feasible margins, design for testability (DfT) rules have been established for practical PCB dimensions.

ACS Style

Abdelghani Renbi; Jerker Delsing. Contactless Testing of Circuit Interconnects. Journal of Electronic Testing 2015, 31, 229 -253.

AMA Style

Abdelghani Renbi, Jerker Delsing. Contactless Testing of Circuit Interconnects. Journal of Electronic Testing. 2015; 31 (3):229-253.

Chicago/Turabian Style

Abdelghani Renbi; Jerker Delsing. 2015. "Contactless Testing of Circuit Interconnects." Journal of Electronic Testing 31, no. 3: 229-253.

Conference paper
Published: 01 March 2015 in 2015 IEEE International Conference on Industrial Technology (ICIT)
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Interoperability between shop floor devices and upper layer systems is a key challenge for enabling Internet of Things in industrial applications. Standardized protocols such as IPv6, CoAP, and XML can be used to address this issue. Widely used XML-based technologies such as SenML, EEML, OPC-UA as well as others rely on XML to be able to support a wide range of sensor and actuator applications. However, this approach results in high communication overhead due to the verbose nature of plain text messages encoded in XML. When devices are communicating using 6LoWPAN over IEEE 802.15.4, it is important to keep the messages small enough to fit into one MAC-layer frame to avoid fragmentation and hence conserving bandwidth and transmission energy. One possible solution is to integrate differential binary delta-encoding with a service-based framework based on CoAP, SenML and EXI. The proposed efficient communication approach for service-based architecture can compress a series of events up to 90-95%. The proposed framework is a holistic approach for enabling distributed monitoring and control applications and a move towards realizing the vision of Services of Things.

ACS Style

Jens Eliasson; Jerker Delsing; Hasan Derhamy; Zoran Salcic; Kevin Wang. Towards industrial Internet of Things: An efficient and interoperable communication framework. 2015 IEEE International Conference on Industrial Technology (ICIT) 2015, 2198 -2204.

AMA Style

Jens Eliasson, Jerker Delsing, Hasan Derhamy, Zoran Salcic, Kevin Wang. Towards industrial Internet of Things: An efficient and interoperable communication framework. 2015 IEEE International Conference on Industrial Technology (ICIT). 2015; ():2198-2204.

Chicago/Turabian Style

Jens Eliasson; Jerker Delsing; Hasan Derhamy; Zoran Salcic; Kevin Wang. 2015. "Towards industrial Internet of Things: An efficient and interoperable communication framework." 2015 IEEE International Conference on Industrial Technology (ICIT) , no. : 2198-2204.

Journal article
Published: 21 August 2014 in Sensors
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Hardwired sensor installations using proprietary protocols found in today’s district heating substations limit the potential usability of the sensors in and around the substations. If sensor resources can be shared and re-used in a variety of applications, the cost of sensors and installation can be reduced, and their functionality and operability can be increased. In this paper, we present a new concept of district heating substation control and monitoring, where a service oriented architecture (SOA) is deployed in a wireless sensor network (WSN), which is integrated with the substation. IP-networking is exclusively used from sensor to server; hence, no middleware is needed for Internet integration. Further, by enabling thousands of sensors with SOA capabilities, a System of Systems approach can be applied. The results of this paper show that it is possible to utilize SOA solutions with heavily resource-constrained embedded devices in contexts where the real-time constrains are limited, such as in a district heating substation.

ACS Style

Jonas Gustafsson; Rumen Kyusakov; Henrik Mäkitaavola; Jerker Delsing. Application of Service Oriented Architecture for Sensors and Actuators in District Heating Substations. Sensors 2014, 14, 15553 -15572.

AMA Style

Jonas Gustafsson, Rumen Kyusakov, Henrik Mäkitaavola, Jerker Delsing. Application of Service Oriented Architecture for Sensors and Actuators in District Heating Substations. Sensors. 2014; 14 (8):15553-15572.

Chicago/Turabian Style

Jonas Gustafsson; Rumen Kyusakov; Henrik Mäkitaavola; Jerker Delsing. 2014. "Application of Service Oriented Architecture for Sensors and Actuators in District Heating Substations." Sensors 14, no. 8: 15553-15572.

Book chapter
Published: 09 May 2014 in Industrial Cloud-Based Cyber-Physical Systems
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Engineering methods and tools are seen as key for designing, testing, deploying and operating future infrastructures. They accompany critical processes from ‘cradle-to-grave’. Here we provide an overview of the user and business requirements for engineering tools, including system development, modelling, visualisation, commissioning and change in an SOA engineering environment. An appraisal of existing engineering tools appropriate to IMC-AESOP, both commercial and development prototypes are presented, culminating in the presentation of tool cartography graphically, defining the impact of these tools within the enterprise and system lifecycle.

ACS Style

Robert Harrison; C. Stuart McLeod; Giacomo Tavola; Marco Taisch; Armando W. Colombo; Stamatis Karnouskos; Marcel Tilly; Petr Stluka; François Jammes; Roberto Camp; Jerker Delsing; Jens Eliasson; J. Marco Mendes. Next Generation of Engineering Methods and Tools for SOA-Based Large-Scale and Distributed Process Applications. Industrial Cloud-Based Cyber-Physical Systems 2014, 137 -165.

AMA Style

Robert Harrison, C. Stuart McLeod, Giacomo Tavola, Marco Taisch, Armando W. Colombo, Stamatis Karnouskos, Marcel Tilly, Petr Stluka, François Jammes, Roberto Camp, Jerker Delsing, Jens Eliasson, J. Marco Mendes. Next Generation of Engineering Methods and Tools for SOA-Based Large-Scale and Distributed Process Applications. Industrial Cloud-Based Cyber-Physical Systems. 2014; ():137-165.

Chicago/Turabian Style

Robert Harrison; C. Stuart McLeod; Giacomo Tavola; Marco Taisch; Armando W. Colombo; Stamatis Karnouskos; Marcel Tilly; Petr Stluka; François Jammes; Roberto Camp; Jerker Delsing; Jens Eliasson; J. Marco Mendes. 2014. "Next Generation of Engineering Methods and Tools for SOA-Based Large-Scale and Distributed Process Applications." Industrial Cloud-Based Cyber-Physical Systems , no. : 137-165.

Chapter
Published: 09 May 2014 in Industrial Cloud-Based Cyber-Physical Systems
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In the last years service-oriented architectures have been extensively used to enable seamless interaction and integration among the various heterogeneous systems and devices found in modern factories. The emerging Industrial Automation Systems are increasingly utilising them. In the cloud-based vision of IMC-AESOP such technologies take an even more key role as they empower the backbone of the new concepts and approaches under development. Here we report about the investigations and assessments performed to find answers to some of the major questions that arise as key when technologies have to be selected and used in an industrial context utilizing Service-Oriented Architecture (SOA)-based distributed large-scale process monitoring and control system. Aspects of integration, real-timeness, distributeness, event-based interaction, service-enablement, etc., are approached from different angles and some of the promising technologies are analysed and assessed.

ACS Style

François Jammes; Stamatis Karnouskos; Bernard Bony; Philippe Nappey; Armando W. Colombo; Jerker Delsing; Jens Eliasson; Rumen Kyusakov; Petr Stluka; Marcel Tilly; Thomas Bangemann. Promising Technologies for SOA-Based Industrial Automation Systems. Industrial Cloud-Based Cyber-Physical Systems 2014, 89 -109.

AMA Style

François Jammes, Stamatis Karnouskos, Bernard Bony, Philippe Nappey, Armando W. Colombo, Jerker Delsing, Jens Eliasson, Rumen Kyusakov, Petr Stluka, Marcel Tilly, Thomas Bangemann. Promising Technologies for SOA-Based Industrial Automation Systems. Industrial Cloud-Based Cyber-Physical Systems. 2014; ():89-109.

Chicago/Turabian Style

François Jammes; Stamatis Karnouskos; Bernard Bony; Philippe Nappey; Armando W. Colombo; Jerker Delsing; Jens Eliasson; Rumen Kyusakov; Petr Stluka; Marcel Tilly; Thomas Bangemann. 2014. "Promising Technologies for SOA-Based Industrial Automation Systems." Industrial Cloud-Based Cyber-Physical Systems , no. : 89-109.

Book chapter
Published: 09 May 2014 in Industrial Cloud-Based Cyber-Physical Systems
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The IMC-AESOP architecture has been used to implemente a smart house demonstration. Six different systems has been integrated with local (802.11, 802.15.4) and global (telecom) communication. The six systems integrated are: Car arrival detection system, Garage door opening system, House security system, External house lightning system, External electrical outlet system, House energy control system. The SOA technologies used are CoAP and EXI using SenML to encode the services. Engineering tools have been used to simulate the usage scenario and provide prediction of system behaviour.

ACS Style

Jerker Delsing; Jens Eliasson; Jonas Gustafsson; Rumen Kyusakov; Andrey Kruglyak; Stuart McLeod; Robert Harrison; Armando W. Colombo; J. Marco Mendes. Building System of Systems with SOA Technology: A Smart House Use Case. Industrial Cloud-Based Cyber-Physical Systems 2014, 219 -230.

AMA Style

Jerker Delsing, Jens Eliasson, Jonas Gustafsson, Rumen Kyusakov, Andrey Kruglyak, Stuart McLeod, Robert Harrison, Armando W. Colombo, J. Marco Mendes. Building System of Systems with SOA Technology: A Smart House Use Case. Industrial Cloud-Based Cyber-Physical Systems. 2014; ():219-230.

Chicago/Turabian Style

Jerker Delsing; Jens Eliasson; Jonas Gustafsson; Rumen Kyusakov; Andrey Kruglyak; Stuart McLeod; Robert Harrison; Armando W. Colombo; J. Marco Mendes. 2014. "Building System of Systems with SOA Technology: A Smart House Use Case." Industrial Cloud-Based Cyber-Physical Systems , no. : 219-230.