Conflitos de interesse e suas repercussões na ciência

The Internet of Things is growing at a dramatic rate and extending into various application domains. We have designed, implemented and evaluated a resilient and decentralized system to enable dynamic IoT choreographies. We applied it to maintaining the functionality of building automation systems, so that new devices can appear and vanish on-the-fly.Pervasive connectivity in machine to machine communication as well as advancements in sensor and actuator technology has given rise to the Internet of Things (IoT). For companies such as Siemens, the IoT concept plays a tremendous role for their ongoing evolution towards full digitalization. Smarter cities, eHealth systems, or Industry 4.0-enabled manufacturing plants are transforming into IoT environments. In this paper, we take an application from the building automation domain as an example to illustrate our solution. While building automation systems (BAS) have certain specific constraints and characteristics, the solutions presented in this paper are applicable to other IoT domains. In today's building infrastructures, we find heterogeneous devices such as lights, switches, window shutters, air conditioners, light sensors, or thermostats, which are being IoT-enabled. I.e., the communication with such components is based on Internet and Web technologies, such as the HTTP or CoAP, REST interfaces and data are exchanged via JSON. In the future, such IoT environments will become very dynamic. New devices will vanish and appear on-the-fly during their lifetime or change their properties.As an example, imagine a reconfigurable multi-purpose room that users can partition into multiple rooms by movable walls. When users move walls in the room, the installed equipment should automatically adapt to the new room configuration, which requires dynamic reconfiguration of the building system.The operation of such a dynamic room today requires the involvement of technicians at each reconfiguration stage, or provide a suboptimal user experience, with light switches not operating

show abstract

Running Distributed and Dynamic IoT Choreographies

Seeger

Deshmukh

Bröring

2018

View full text Add to dashboard Cite

IoT systems are growing larger and larger and are becoming suitable for basic automation tasks. One of the features IoT automation systems can provide is dealing with a dynamic system -Devices leaving and joining the system during operation. Additionally, IoT automation systems operate in a decentralized manner. Current commercial automation systems have difficulty providing these features. Integrating new devices into an automation system takes manual intervention. Additionally, automation systems also require central entities to orchestrate the operation of participants. With smarter sensors and actors, we can move control operations into software deployed on a decentralized network of devices, and provide support for dynamic systems. In this paper, we present a framework for automation systems that demonstrates these two properties (distributed and dynamic). We represent applications as semantically described data flows that are run decentrally on participating devices, and connected at runtime via rules. This allows integrating new devices into applications without manual interaction and removes central controllers from the equation. This approach provides similar features to current automation systems (central engineering, multiple instantiation of applications), but enables distributed and dynamic operation. We also quantitatively evaluate the performance of our chosen approach.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

hi@scite.ai

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Jan Seeger

A 50-Gb/s IP router

Bipolar Radiofrequency‐Induced Thermotherapy of Turbinate Hypertrophy: Pilot Study and 20 Months' Follow‐up

Recipes for IoT applications

Dynamic IoT Choreographies

Running Distributed and Dynamic IoT Choreographies

Contact Info

Product

Resources

About