

Soft computing applications in the field of industrial and environmental enterprises


Received: 14 June 2019 Accepted: 21 June 2019

DOI: 10.1111/exsy.12456
G U E S T E D I T O R I A L
Soft computing applications in the field of industrial and
environmental enterprises
1 | INTRODUCTION

Artificial Intelligence (AI) has proved to be a promising field of study that can greatly contribute to the development of computational systems that

successfully address an increasing number of challenges. From the very beginning, when the term was coined in 1956 during the Dartmouth Sum-

mer Research Project, researchers from this field have shared a vision that computers can be made to perform intelligent tasks (Moor, 2006). A

vast array of different techniques has been proposed so far to implement such intelligent systems, ranging from expert or knowledge‐based sys-

tems (some of the earlier products of AI) to cutting‐edge proposals such us deep and machine learning.

Among all the branches of the AI tree, in last decades, there has been significant progress in soft computing (Karray & De Silva, 2004). As

pointed out by Zadeh (1994), while hard computing focuses on precision, certainty, and rigour, soft computing requires that computation, reason-

ing, and decision making exploit a tolerance for imprecision and uncertainty wherever possible (Zadeh, 1994). Soft computing can be seen as a

family consisting of many members, including evolutionary computation, fuzzy logic, and connectionist models among others (Pratihar, 2007).

Its fascinating ability to simulate human intelligence has made it favourable in various scientific and technological disciplines (Chakraverty, Sahoo,

& Mahato, 2019) such as computer science, mathematics, control theory, structural engineering, medical, and psychology.

One of the domains where soft computing can arguably be of greatest utility is in the field of business. The current environment for businesses

is increasingly complex and demanding. Companies are affected by multiple internal and external variables that have an impact on the various

areas that make up the value chain, and this is exacerbated for those managing operations in multiple countries (i.e., exports, imports, and foreign

direct investments). Decision takers within the companies can significantly benefit from and demand tools to analyse and extract the most knowl-

edge from the large datasets generated by the interrelated activities that companies conduct.

Soft computing can be of particular value for industrial and environmental companies. Compared to other sectors such as retailing, where indi-

vidual‐level determinants are key to understand the buyer, industrial companies are characterized by a more critical role of operations efficiency in

order to succeed in the market. Likewise, given the large volume of information that is now available for environmental firms, competition in this

field is also more and more determined by a strategic and sophisticated use of data analytics.

Overall, soft computing represents a potentially key source of competitive advantage sustainable over time that organizations, especially in the

industrial and environmental field, can employ to outperform competitors, achieve higher returns, and ensure their own viability (Wernerfelt,

1984; Barney, 1991). By complementing broad analytical tools (such as Porter's five forces PESTLE or Blue Ocean; Porter, 1979; Kim &

Mauborgne, 2014), soft computing may allow firms to materialize tangible resources from strategic advantages.

This special issue compiles recent applications of soft computing techniques to the management of enterprise within industrial and environ-

mental sectors. It is aimed at both researchers and practitioners from academia and industry who are engaged in deploying soft computing solu-

tions for real‐life enterprise problems. Five papers are included in this special issue, covering a wide variety of case studies, ranging from

photovoltaic solar systems to forest biomass estimation. For each different soft computing, techniques have been applied, namely, unsupervised

neural networks, deep learning, regression models, multiagent systems, and case‐based reasoning. Thanks to the wide‐range panoramic view pre-

sented by these complementary works, readers can get a feel for developing up‐to‐date soft computing systems to solve present problems in

enterprise contexts.
2 | CONTENTS OF THE SPECIAL ISSUE

In the paper by Jove, Casteleiro‐Roca, Quintián, Méndez‐Pérez, and Calvo‐Rolle (2019), a novel approach for fault detection in industrial pro-

cesses, by means of unsupervised and projectionist techniques, is proposed. The proposed system is tested in a laboratory plant built with indus-

trial equipment where anomalies have to be detected without any previous knowledge of the data. This system was designed to control the level
Expert Systems. 2019;36:e12456.

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2 of 4 GUEST EDITORIAL
of liquid in a tank where the liquid is initially stored in a different tank placed at a lower level, and it is boosted by a three‐phase pump driven by a

variable frequency driver. The objective tank has also two built‐in output valves; one of them is a proportional electric, and the other one is man-

ual. In such a system, considered failures are water leaks from the main water tank to the lower tank through a valve. The correct operation of the

plant meant that the output electrovalve had to be completely closed. The feasibility of the proposed method was checked by opening the

electrovalve and simulating a water leak.

In order to address such a problem, dimensionality reduction techniques are applied to support the visualization of the operation point in a

two‐dimensional graph regardless of the number of variables. More precisely, data are analysed by means of Principal Component Analysis

(PCA), Maximum Likelihood Hebbian Learning (MLHL), Beta Hebbian Learning algorithm (BHL), curvilinear Component Analysis (CCA), and

ISOMAP. As the industrial plants usually work in one or a few working points, all the visualized data in an operation point should be near to each

other. The data are projected into two‐dimension graph, and the user could define a contour in the data. With the defined contour, the proposed

algorithm detects whether the working point is out of the previously defined working area. To validate the proposed system, two datasets with

different levels of complexity (in terms of quantity and quality of information) have been used. The obtained results have been satisfactory,

although the accuracy varies depending on the employed technique and the complexity of the dataset (the higher the complexity of the data,

the less accurate the results are).

Torres, Troncoso, Koprinska, Wang, and Martínez‐Álvarez (2019) propose a Deep Learning approach, based on feed‐forward neural net-

works for big data time series, for predicting the electricity power generated by photovoltaic solar systems for the next day (at half‐hourly

intervals). As it is well known, solar energy is highly variable as it depends on meteorological conditions (solar radiation, cloud cover, rainfall,

and temperature). This dependency creates uncertainty about the amount of solar power that will be generated, which makes it difficult to

integrate solar power into the electricity grid and electricity markets. Hence, an accurate prediction of the generated solar power is a task

of utmost importance and relevance for both energy managers and electricity traders, in order to minimize uncertainty and ensure reliable

electricity supply at acceptable cost. Day ahead predictions are one of the most common industry‐requested operational forecasts, as they

are needed for operational planning, switching sources, programming backups, short‐term power purchases, and for planning of reserve usage

and peak load matching.

To perform such a short‐term forecast of big solar‐power time series data, a solution based on Deep Learning (DL) feed‐forward neural

networks is conceived. To find a good combination of hyper‐parameters of the applied neural network, the H20 grid search method is applied.

The proposed DL solution is compared to the Pattern Sequence‐based Forecasting (PSF) algorithm, which uses clustering and similarity of pat-

terns, and a neural network‐based model with one hidden layer, used as a reference method. All these models are applied to Australian solar

power data gathered during 2 years and compared in terms of the Mean Absolute Error and the Root Mean Squared Error. The accuracy of

the applied methods is compared when using weather and weather forecast data as an additional input, taking into account different scenarios

corresponding to different percentages of noise in the weather forecast data. Finally, the effect of varying the size of the historical window is

also studied.

In peer‐to‐peer lending, it is important to predict the repayment of the borrower to reduce the lender's financial loss. Such a topic is addressed

in the paper by J.‐Y. Kim and Cho (2019) that proposes a deep dense convolutional network for repayment prediction in social lending. It maintains

the borrower's semantic information and obtains a good representation by automatically extracting important low‐ and high‐level features simul-

taneously. The proposed model classifies the loan status of a borrower by learning the pattern while maintaining and extracting discriminative fea-

tures according to the loan status and improves the overall performance with a good representation.

Authors assume that it would be easier to predict the loan status in the feature space if the network captures the inherent properties of the

lending data of a borrower and generalizes them to other borrowers. Consequently, the feature space is learned by a DenseNet network that con-

sists of several dense blocks and transition layers, in order to obtain a good representation from the social lending data of many borrowers. The

lending data are then projected onto the learned feature space using the trained network and are predicted using the softmax classifier. Extensive

experiments are conducted on data coming from the U.S. Lending Club.

Torre‐Tojal, Lopez‐Guede, and Graña Romay (2019) propose the application of machine‐learning‐based predictive systems for the extrac-

tion of biomass information from Light Detection and Ranging (LiDAR) data. LiDAR is a remote sensing tool that retrieves surface elevation

measurements at high spatial resolutions, even in rough terrains and heavily forested areas. It is based on the emission of pulses by an

infrared laser sensor emitting pulses and recording of the echoes returning to the sensor after being reflected by ground surfaces. Authors

of this paper focus on the application of LiDAR for forest biomass estimation, what may have economic value owing to the use of

biomass as a source of energy source or as the raw material for a wide variety of elaborate products such as construction materials, furniture,

and paper.

In order to predict the forest biomass from LiDAR data, three predictive machine learning approaches are applied, namely, Multiple Linear

Regression, Random Forest, and Support Vector Regression. To test such models, they have been applied (under a fivefold cross‐validation

schema) to the Pinus radiata species using public data gathered from a LiDAR flight conducted by the Basque Government (Spain) in 2012 and

the dendometric data coming from the Fourth National Forestal Inventory that were gathered in 2011. The modelling performance results

obtained in this study are comparable with those in other studies concerning plot‐level biomass estimations.


GUEST EDITORIAL 3 of 4
Finally, a job‐offer recommender system for careers is proposed by Rivas, Chamoso, González‐Briones, Casado‐Vara, and Corchado (2019). It is

a hybrid system whose architecture is based on a multiagent system that consists of (a) a Case‐Based Reasoning (CBR) system powered by a series

of metrics that calculate the affinity between job offers and users and (b) an argumentation framework that extends the functionality of the CBR,

thus making it possible for agents to have a dialogue. Individual solutions proposed by each one of the agents are first debated and settled before

a single final suggestion is obtained.

The proposed hybrid intelligent system is able to carry out analyses of user profiles and job offers found on the beBee social network. Con-

sequently, it has been evaluated on a sample set of such users actively searching for employment in periods of 15 days during 4 months. As a

result of the activity, a total of 118,882 recommendations have been made. The acceptance rate average of users who did interact with the pro-

posed system is 75.81% out of the 42,478 user applications. There has been an evolution of the analysed rates during the 4 months in which the

evaluation has been performed; the users' acceptance rate has increased from 73.72% to 78.6%, while the rejection rate has decrease from

26.28% to 21.4% in the last month. On the other hand, the interaction of companies has been also studied; their acceptance rate has increased

from 21.74% to 24.03% during the 4 months.

ACKNOWLEDGEMENTS

The guest editors wish to thank Dr. Jon G. Hall (Editor‐in‐Chief of the Wiley‐Blackwell Journal Expert Systems: The Journal of Knowledge Engi-

neering) for providing the opportunity to edit this special issue. We would also like to thank the referees who have thoroughly evaluated the

papers and the editorial staff for their support.

CONFLICT OF INTEREST

None.

ORCID

Alfredo Jimenez https://orcid.org/0000-0001-7811-5113

Álvaro Herrero https://orcid.org/0000-0002-2444-5384

Alfredo Jimenez1

Álvaro Herrero2

1Department of Management, KEDGE Business School, Bordeaux, France
2Grupo de Inteligencia Computacional Aplicada (GICAP), Departamento de Ingeniería Civil, Escuela Politécnica Superior, Universidad de Burgos, Burgos,

Spain

Correspondence

Álvaro Herrero, Grupo de Inteligencia Computacional Aplicada (GICAP), Departamento de Ingeniería Civil,

Escuela Politécnica Superior, Universidad de Burgos, Av. Cantabria s/n, Burgos 09006, Spain.

Email: ahcosio@ubu.es

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https://orcid.org/0000-0001-7811-5113
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