Defining Emergent Software Using Continuous Self-Assembly, Perception, and Learning

Filho, Roberto Rodrigues; Porter, B.

doi:10.1145/3092691

Cited by 24 publications

(46 citation statements)

References 23 publications

(13 reference statements)

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“…1 the distribution between the different types on learning approaches used in the papers are shown. Most of the ML papers apply an online learning approach [31][32][33][34][35][36][37][38][39], a few use offline [40][41][42], or a hybrid [43][44][45][46] which is a combination of both online and offline approaches, but the industrial deployed systems tends to have a lower level of autonomy or specifically focuses on a few numbers of challenges. A/B/n testing papers [5,[47][48][49][50] simple adaption is done online in deployed systems.…”

Section: Techniques For Autonomously Improvement Of Systemsmentioning

confidence: 99%

Autonomously Improving Systems in Industry: A Systematic Literature Review

Green

Bosch

Olsson

2021

Lecture Notes in Business Information Processing

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A significant amount of research effort is put into studying machine learning (ML) and deep learning (DL) technologies. Real-world ML applications help companies to improve products and automate tasks such as classification, image recognition and automation. However, a traditional "fixed" approach where the system is frozen before deployment leads to a sub-optimal system performance. Systems autonomously experimenting with and improving their own behavior and performance could improve business outcomes but we need to know how this could actually work in practice. While there is some research on autonomously improving systems, the focus on the concepts and theoretical algorithms. However, less research is focused on empirical industry validation of the proposed theory. Empirical validations are usually done through simulations or by using synthetic or manually alteration of datasets. The contribution of this paper is twofold. First, we conduct a systematic literature review in which we focus on papers describing industrial deployments of autonomously improving systems and their real-world applications. Secondly, we identify open research questions and derive a model that classifies the level of autonomy based on our findings in the literature review.

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Section: Techniques For Autonomously Improvement Of Systemsmentioning

confidence: 99%

Autonomously Improving Systems in Industry: A Systematic Literature Review

Green

Bosch

Olsson

2021

Lecture Notes in Business Information Processing

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“…The related work is classified into two categories concerning workflow variability: solution space variability and Models@Runtime. We omit approaches using variability at the planning-level (e.g., [12]) as they do not propose any model constructs for supporting workflow variability, but they are built on top of existing component models with reconfiguration capabilities (e.g., Fractal [13]).…”

Section: Related Workmentioning

confidence: 99%

Workflow Variability for Autonomic IoT Systems

Arellanes

Lau

2019

2019 IEEE International Conference on Autonomic Computing (ICAC)

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Autonomic IoT systems require variable behaviour at runtime to adapt to different system contexts. Building suitable models that span both design-time and runtime is thus essential for such systems. However, existing approaches separate the variability model from the behavioural model, leading to synchronization issues such as the need for dynamic reconfiguration and dependency management. Some approaches define a fixed number of behaviour variants and are therefore unsuitable for highly variable contexts. This paper extends the semantics of the DX-MAN service model so as to combine variability with behaviour. The model allows the design of composite services that define an infinite number of workflow variants which can be chosen at runtime without any reconfiguration mechanism. We describe the autonomic capabilities of our model by using a case study in the domain of smart homes.

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“…Emergent Software Systems, as described in [4,8], use continuous self-assembly over a pool of small software building blocks to derive systems that are autonomously composed as a factor of the operating environment and human-provided high-level goals. Starting from no initial knowledge, the ideal composition of behaviour for each range of observed deployment environment conditions is automonously learned using real-time reinforcement learning.…”

Section: Emergent Software Systemsmentioning

confidence: 99%

Towards emergent microservices for client-tailored design

Filho

Sá

Porter

et al. 2018

Proceedings of the 19th Workshop on Adaptive and Reflexive Middleware

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Contemporary systems are increasingly complex, with both large codebases and constantly changing environments which make them challenging to develop, deploy and manage. We consider two recent efforts to tackle this complexity: microservices and emergent software. Microservices have gained recent popularity in industry, in which monoliths of software are broken down into compositions of single-objective, end-to-end services running on HTTP which can be scaled out on cloud hosting systems. From the research community, the emergent systems concept demonstrates promise in using real-time learning to autonomously compose and optimise software systems from small building blocks, rapidly finding the best behavioural composition to match the current deployment conditions. We argue that emergent software and microservice architectures have strong potential for synergy in complex systems, offering mutually compatible lessons in dealing with complexity via scale-out design and real-time client-tailored behaviour. We explore self-designing microservices, built with emergent software, to demonstrate the complementary boundaries of both concepts-and how future intersections may offer novel architectures that lie at a compelling point between human-and machine-designed systems. We present the conceptual synergy and demonstrate a specific microservice architecture for a smart city example where scoped microservices are continually self-composed according to the demands of the applications and operating environment. For the purpose of reproducibility of the study, we make available all the code used in the evaluation of the proposed approach.

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Defining Emergent Software Using Continuous Self-Assembly, Perception, and Learning

Cited by 24 publications

References 23 publications

Autonomously Improving Systems in Industry: A Systematic Literature Review

Autonomously Improving Systems in Industry: A Systematic Literature Review

Workflow Variability for Autonomic IoT Systems

Towards emergent microservices for client-tailored design

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