426 research outputs found
High-Throughput First-Principles Prediction of Interfacial Adhesion Energies in Metal-on-Metal Contacts
: Adhesion energy, a measure of the strength by which two surfaces bind together, ultimately dictates the mechanical behavior and failure of interfaces. As natural and artificial solid interfaces are ubiquitous, adhesion energy represents a key quantity in a variety of fields ranging from geology to nanotechnology. Because of intrinsic difficulties in the simulation of systems where two different lattices are matched, and despite their importance, no systematic, accurate first-principles determination of heterostructure adhesion energy is available. We have developed robust, automatic high-throughput workflow able to fill this gap by systematically searching for the optimal interface geometry and accurately determining adhesion energies. We apply it here for the first time to perform the screening of around a hundred metallic heterostructures relevant for technological applications. This allows us to populate a database of accurate values, which can be used as input parameters for macroscopic models. Moreover, it allows us to benchmark commonly used, empirical relations that link adhesion energies to the surface energies of its constituent and to improve their predictivity employing only quantities that are easily measurable or computable
Non-Autoregressive Coarse-to-Fine Video Captioning
It is encouraged to see that progress has been made to bridge videos and
natural language. However, mainstream video captioning methods suffer from slow
inference speed due to the sequential manner of autoregressive decoding, and
prefer generating generic descriptions due to the insufficient training of
visual words (e.g., nouns and verbs) and inadequate decoding paradigm. In this
paper, we propose a non-autoregressive decoding based model with a
coarse-to-fine captioning procedure to alleviate these defects. In
implementations, we employ a bi-directional self-attention based network as our
language model for achieving inference speedup, based on which we decompose the
captioning procedure into two stages, where the model has different focuses.
Specifically, given that visual words determine the semantic correctness of
captions, we design a mechanism of generating visual words to not only promote
the training of scene-related words but also capture relevant details from
videos to construct a coarse-grained sentence "template". Thereafter, we devise
dedicated decoding algorithms that fill in the "template" with suitable words
and modify inappropriate phrasing via iterative refinement to obtain a
fine-grained description. Extensive experiments on two mainstream video
captioning benchmarks, i.e., MSVD and MSR-VTT, demonstrate that our approach
achieves state-of-the-art performance, generates diverse descriptions, and
obtains high inference efficiency. Our code is available at
https://github.com/yangbang18/Non-Autoregressive-Video-Captioning.Comment: 9 pages, 6 figures, to be published in AAAI2021. Our code is
available at
https://github.com/yangbang18/Non-Autoregressive-Video-Captionin
Hybrid Advanced Optimization Methods with Evolutionary Computation Techniques in Energy Forecasting
More accurate and precise energy demand forecasts are required when energy decisions are made in a competitive environment. Particularly in the Big Data era, forecasting models are always based on a complex function combination, and energy data are always complicated. Examples include seasonality, cyclicity, fluctuation, dynamic nonlinearity, and so on. These forecasting models have resulted in an over-reliance on the use of informal judgment and higher expenses when lacking the ability to determine data characteristics and patterns. The hybridization of optimization methods and superior evolutionary algorithms can provide important improvements via good parameter determinations in the optimization process, which is of great assistance to actions taken by energy decision-makers. This book aimed to attract researchers with an interest in the research areas described above. Specifically, it sought contributions to the development of any hybrid optimization methods (e.g., quadratic programming techniques, chaotic mapping, fuzzy inference theory, quantum computing, etc.) with advanced algorithms (e.g., genetic algorithms, ant colony optimization, particle swarm optimization algorithm, etc.) that have superior capabilities over the traditional optimization approaches to overcome some embedded drawbacks, and the application of these advanced hybrid approaches to significantly improve forecasting accuracy
人・ユーザー中心の移動サービスと群集マネジメントのためのモデリング,シミュレーションと最適化
Tohoku University博士(情報科学)thesi
EQUIVALENT MODELS FOR PHOTOVOLTAIC CELL – A REVIEW
Over the years, the contribution of photovoltaic energy to an eco-friendly world is continually increasing. Photovoltaic (PV) cells are commonly modelled as circuits, so finding the appropriate circuit model parameters of PV cells is crucial for performance evaluation, control, efficiency computations and maximum power point tracking of solar PV systems. The problem of finding circuit model of solar PV cells is referred to as “PV cell equivalent model problem”. In this paper, the existing research works on PV cell model parameter estimation problem are classified according to error quali-quantitative analysis, number of parameters, translation equations and PV technology. The existent models were discussed pointing out its different levels of approximation. A qualitative comparative ranking was made and four models were found to be the best ones for simulating PV cells. Besides, based on the conducted review, some recommendations for future research are provided
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Integrating Recognition and Decision Making to Close the Interaction Loop for Autonomous Systems
Intelligent systems are becoming increasingly ubiquitous in daily life. Mobile devices are providing machine-generated support to users, robots are coming out of their cages in manufacturing to interact with co-workers, and cars with various degrees of self-driving capabilities operate amongst pedestrians and the driver. However, these interactive intelligent systems\u27 effectiveness depends on their understanding and recognition of human activities and goals, as well as their responses to people in a timely manner. The average person does not follow instructions step-by-step or act in a formulaic manner, but instead varies the order of actions and timing when performing a given task. People explore their surroundings, make mistakes, and may interrupt an activity to handle more urgent matters. The decisions that an autonomous intelligent system makes should account for such noise and variance regardless of the form of interaction, which includes adapting action choices and possibly its own goals.While most people take these aspects of interaction for granted, they are complex and involve many specific tasks that have primarily been studied independently within artificial intelligence. This results in open-loop interactive experiences where the user must perform a fixed input command or the intelligent system performs a hard-coded output response---one of the components of the interaction cannot adapt with respect to the other for longer-term back-and-forth interactions. This dissertation explores how developments in plan recognition, activity recognition, intent recognition, and autonomous planning can work together to develop more adaptive interactive experiences between autonomous intelligent systems and the people around them. In particular, we consider a unifying perspective of recognition algorithms that provides sufficient information to dynamically produce short-term automated planning problems, and we present ways to run these algorithms faster for the real-time needs of interaction. This exploration leads to the introduction of the Planning and Recognition Together Close the Interaction Loop (PReTCIL) framework that serves as a first step towards identifying how we can address the problem of closing the interaction loop, in addition to new questions that need to be considered
Where have you been? A Study of Privacy Risk for Point-of-Interest Recommendation
As location-based services (LBS) have grown in popularity, the collection of
human mobility data has become increasingly extensive to build machine learning
(ML) models offering enhanced convenience to LBS users. However, the
convenience comes with the risk of privacy leakage since this type of data
might contain sensitive information related to user identities, such as
home/work locations. Prior work focuses on protecting mobility data privacy
during transmission or prior to release, lacking the privacy risk evaluation of
mobility data-based ML models. To better understand and quantify the privacy
leakage in mobility data-based ML models, we design a privacy attack suite
containing data extraction and membership inference attacks tailored for
point-of-interest (POI) recommendation models, one of the most widely used
mobility data-based ML models. These attacks in our attack suite assume
different adversary knowledge and aim to extract different types of sensitive
information from mobility data, providing a holistic privacy risk assessment
for POI recommendation models. Our experimental evaluation using two real-world
mobility datasets demonstrates that current POI recommendation models are
vulnerable to our attacks. We also present unique findings to understand what
types of mobility data are more susceptible to privacy attacks. Finally, we
evaluate defenses against these attacks and highlight future directions and
challenges.Comment: 26 page
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