Explainable Artificial Intelligence for Developing Smart Cities Solutions

Thakker, Dhavalkumar; Mishra, Bhupesh Kumar; Abdullatif, Amr; Mazumdar, Suvodeep; Simpson, Sydney

doi:10.3390/smartcities3040065

Cited by 46 publications

(20 citation statements)

References 108 publications

(120 reference statements)

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“…Explainability is another important factor for Smart City analytics to be widely acceptable, specially in the area of smart health. There have been some approaches suggested towards this end, in [43] a hybrid deep learning classifier and semantic web technologies based solution is demonstrated for the application of flood monitoring. In [44], the authors present an explainable deep learning based healthcare system at the Edge for COVID-19 care based on a distributed learning paradigm with promising results.…”

Section: Big Data Analyticsmentioning

confidence: 99%

IoT in Smart Cities: A Survey of Technologies, Practices and Challenges

et al. 2021

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Internet of Things (IoT) is a system that integrates different devices and technologies, removing the necessity of human intervention. This enables the capacity of having smart (or smarter) cities around the world. By hosting different technologies and allowing interactions between them, the internet of things has spearheaded the development of smart city systems for sustainable living, increased comfort and productivity for citizens. The IoT for Smart Cities has many different domains and draws upon various underlying systems for its operation. In this paper, we provide a holistic coverage of the Internet of Things in Smart Cities. We start by discussing the fundamental components that make up the IoT based Smart City landscape followed by the technologies that enable these domains to exist in terms of architectures utilized, networking technologies used as well as the Artificial Algorithms deployed in IoT based Smart City systems. This is then followed up by a review of the most prevalent practices and applications in various Smart City domains. Lastly, the challenges that deployment of IoT systems for smart cities encounter along with mitigation measures.

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Section: Big Data Analyticsmentioning

confidence: 99%

IoT in Smart Cities: A Survey of Technologies, Practices and Challenges

et al. 2021

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“…Here the analysis is performed using AI techniques that conclude damage detection, classification, localisation and condition assessment, and remaining-life prediction, therefore, aims to save the cost of maintenance while minimising disruption [210]. Some of the areas where smart monitoring have been applied are bridge monitoring [211], flood monitoring [212], dam monitoring [213], subsea valve maintenance [214], wind turbine monitoring [215].…”

Section: • Virtual Assistants For Dynamic Customer Experiencesmentioning

confidence: 99%

“…[203] Proposed guidelines for using XAI techniques and simulations using XR for secured human-robots interactions. [233] Maximizing Explainability with SF-Lasso and Selective Inference for Video and Picture Ads [234] Attentive capsule network for click-through rate and conversion rate prediction in online advertising [212] Proposed an XAI solution using DL and Semantic Web technologies for flood monitoring [208] Proposed a SHAP-based method to interpret the outputs of a multilayer perceptron for buildingdamage assessment.…”

Section: H Summary Of the Xai Impact On 6g Applications And Technical...mentioning

confidence: 99%

Applications of Explainable AI for 6G: Technical Aspects, Use Cases, and Research Challenges

Wang¹,

Qureshi²,

Miralles-Pechuaán³

et al. 2021

Preprint

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When 5G began its commercialisation journey around 2020, the discussion on the vision of 6G also surfaced. Researchers expect 6G to have higher bandwidth, coverage, reliability, energy efficiency, lower latency, and, more importantly, an integrated "human-centric" network system powered by artificial intelligence (AI). Such a 6G network will lead to an excessive number of automated decisions made every second. These decisions can range widely, from network resource allocation to collision avoidance for self-driving cars. However, the risk of losing control over decision-making may increase due to high-speed data-intensive AI decision-making beyond designers and users' comprehension. The promising explainable AI (XAI) methods can mitigate such risks by enhancing the transparency of the black box AI decision-making process. This survey paper highlights the need for XAI towards the upcoming 6G age in every aspect, including 6G technologies (e.g., intelligent radio, zero-touch network management) and 6G use cases (e.g., industry 5.0). Moreover, we summarised the lessons learned from the recent attempts and outlined important research challenges in applying XAI for building 6G systems. This research aligns with goals 9, 11, 16, and 17 of the United Nations Sustainable Development Goals (UN-SDG) 1 , promoting innovation and building infrastructure, sustainable and inclusive human settlement, advancing justice and strong institutions, and fostering partnership at the global level.

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“…Missing values can be imputed using any of the deep learning models, such as ANNs, CNNs, and recurrent neural networks [ 51 , 52 , 53 ]. Although neural-network-based models can predict wind pressures on structures, the prediction of wind pressure data at multiple points of the structures at different time intervals remains challenging [ 54 ].…”

Section: Related Workmentioning

confidence: 99%

“…Given that MICE operates by conducting multiple imputations, it is also called sequential regression multiple imputation. MICE operates on multiple imputations to handle the statistical uncertainty caused by the single imputation procedure [ 54 , 56 ]. The chained equation approach in MICE can handle variables of varying types and complexities.…”

Section: Construction Of Wind-induced Pressure Prediction Modelmentioning

confidence: 99%

Wind-Induced Pressure Prediction on Tall Buildings Using Generative Adversarial Imputation Network

Kim

Yuvaraj

Preethaa

et al. 2021

Sensors

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Wind tunnel testing techniques are the main research tools for evaluating the wind loadings of buildings. They are significant in designing structurally safe and comfortable buildings. The wind tunnel pressure measurement technique using pressure sensors is significant for assessing the cladding pressures of buildings. However, some pressure sensors usually fail and cause loss of data, which are difficult to restore. In the literature, numerous techniques are implemented for imputing the single instance data values and data imputation for multiple instantaneous time intervals with accurate predictions needs to be addressed. Thus, the data imputation capacity of machine learning models is used to predict the missing wind pressure data for tall buildings in this study. A generative adversarial imputation network (GAIN) is proposed to predict the pressure coefficients at various instantaneous time intervals on tall buildings. The proposed model is validated by comparing the performance of GAIN with that of the K-nearest neighbor and multiple imputations by chained equation models. The experimental results show that the GAIN model provides the best fit, achieving more accurate predictions with the minimum average variance and minimum average standard deviation. The average mean-squared error for all four sides of the building was the minimum (0.016), and the average R-squared error was the maximum (0.961). The proposed model can ensure the health and prolonged existence of a structure based on wind environment.

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Explainable Artificial Intelligence for Developing Smart Cities Solutions

Cited by 46 publications

References 108 publications

IoT in Smart Cities: A Survey of Technologies, Practices and Challenges

IoT in Smart Cities: A Survey of Technologies, Practices and Challenges

Applications of Explainable AI for 6G: Technical Aspects, Use Cases, and Research Challenges

Wind-Induced Pressure Prediction on Tall Buildings Using Generative Adversarial Imputation Network

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