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Big data analytics in smart grids: a review

Abstract

Data analytics are now playing a more important role in the modern industrial systems. Driven by the development of information and communication technology, an information layer is now added to the conventional electricity transmission and distribution network for data collection, storage and analysis with the help of wide installation of smart meters and sensors. This paper introduces the big data analytics and corresponding applications in smart grids. The characterizations of big data, smart grids as well as huge amount of data collection are firstly discussed as a prelude to illustrating the motivation and potential advantages of implementing advanced data analytics in smart grids. Basic concepts and the procedures of the typical data analytics for general problems are also discussed. The advanced applications of different data analytics in smart grids are addressed as the main part of this paper. By dealing with huge amount of data from electricity network, meteorological information system, geographical information system etc., many benefits can be brought to the existing power system and improve the customer service as well as the social welfare in the era of big data. However, to advance the applications of the big data analytics in real smart grids, many issues such as techniques, awareness, synergies, etc., have to be overcome.

Introduction

With the fast development of digital technology and cloud computing, more and more data are produced through digital equipment and sensors, such as smart phones, computers, advanced measuring infrastructures, etc., as well as through human activities and communications. For instance, the size of data on the internet is now measured in exabytes (1018) and zettabytes (1021) (Emani et al., 2015). Rational, effective and efficient analysis of these data brings huge value and benefit to our daily life and company activities. However, the collected data are mounting at an exponential growth, and the structure of them is also becoming much more complicated. The processing and analysis method of these large volume data is a new challenge but opportunity at the beginning of this century with the concept of “big data” (Lv et al., 2017a; Günther et al., 2017).

Although big data is a newly-appeared term, the concept of discovering valuable information from massive collected data in commercial operation as aiding knowledge for business decision has already been proposed in 1989 by Howard Dresner as “business intelligence” (BI) (Yu, 2002). The trend of internet revolution and ubiquitous information acquisition devices successfully reduce the cost of data collection, while the huge amount and complex structure challenge the capability of traditional data analytics techniques.

In power grid, the traditional fossil fuels are facing the problem of depletion and the de-carbonization demands the power system to reduce the carbon emission. Smart grid and super grid are effective solutions to accelerate the pace for electrification of human society with high penetration of renewable energy sources (Ak et al., 2016). Although the rising awareness of sustainable development have become the impetus to the utilization of renewable energy sources, the intermittent characteristics of wind and photovoltaic energies bring huge challenges to the safe and stable operation in a low inertia power system (Wenbin & Peng, 2017; Ye et al., 2016). The data analytics based renewable energy forecasting methods are a hot research topic for a better regulation and dispatch planning in such cases. Traditional electricity meters in distribution systems only produce a small amount of data which can be manually collected and analyzed for billing purpose. While the huge volume of data collected from two-way communication smart grids at different time resolutions in nowadays need advanced data analytics to extract valuable information not only for billing information but also the status of the electricity network. For example, the high-resolution user consumption data can also be used for customer behavior analysis, demand forecasting and energy generation optimization. Predictive maintenance and fault detection based on the data analytics with advanced metering infrastructure are more crucial to the security of power system (Chunming et al., 2017).

Thus, the great progress of information and communication technology (ICT) provides a new vision for engineers to perceive and control the traditional electrical system and makes it smart. An embedded information layer into the energy network produces huge volume of data, including measurements and control instructions in the grid for collection, transmission, storage and analysis in a fast and comprehensive way. It also brings a lot of opportunities and challenges to the data analysis platform. This paper is to discuss the concepts of data analysis and their applications in smart grids. The intent of this paper is three-fold. First the potential data collected with advanced metering infrastructure in smart grid are discussed. Next, the paper briefly reviews the concepts of data analytics and the popular techniques. Finally, the paper illustrates the detailed applications of data analytics in smart grid.

Big data in smart grid

Concept of big data

The definition of big data is not very clear and uniform at present. But there is a consensus among different descriptions: this is an emerging technical problem brought by a dataset of large volume, various categories and complicated structures which needs novel framework and techniques to excavate useful information effectively. Therefore, the definition of big data depends on the ability of data mining algorithms and the corresponding hardware equipment to deal with large volume datasets (Zikopoulos & Eaton, 2011). It is a relative concept instead of an absolute definition. The big data can be understood as amount of data beyond technology’s capability to store, manage and process efficiently in (Kaisler et al., 2012) as the data size increasing along with the evolvement of ICT technologies.

Concept of smart grids

Smart grid is the power system embedded with an information layer that allows for two-way communication between the central controllers and local actuators as well as logistic units to respond digitally to urgent situations of physical elements or quickly changing of electric demand. The E.U. defined the smart grid as electricity networks that can intelligently integrate the actions of all users connected to it – generators, consumers and those that do both – in order to efficiently deliver sustainable, economic and secure electricity supplies (SmartGrids European Tech, 2010). The U.S. defined the smart grid of future in a similar way that incorporates the digital technology to improve reliability, security and efficiency of the electric system through information exchange, distributed generation and storage resources for a fully automated power delivery network (Zhen Zhang. Smart Grid in America and Europe, 2011).

Compared with traditional power systems, the widespread application of distributed generators under the call of green energy resources is shaking the hegemony position of large-scale centralized power plants, which makes the conventional centralized control strategy less effective due to the unidirectional power flow. Connection of small-scale power generations (typically in the range of 3 kW to 10 kW) to the public distribution grid requires two-directional operation and control of distribution grids. Faced with the challenges of more complicated control and protection strategies, the conventional electro-mechanical electric grid is supposed to be enhanced with the help of innovations in the digital information and telecommunications network to overcome the cost from power outages and power quality disturbances as billions of dollars annually (Executive Office of the President, 2013).

Normally, the smart grid can be assessed with a Smart Grid Architecture Model (SGAM), which is a 3-dimensional framework that merges domains, zones and layers together. The conventional structure of power system can be found in the domains as generation, transmission, distribution, DER (Distributed Energy Resources) and customer premises. The zones which present the layout of power system management are composed of market, enterprise, operation, station, field and process. On top of the first two dimensions, the layout of interoperability layers includes the component, communication, information, function and business layers. SGAM as an architectural overview can be used to find the limitations and commonalities of existing smart grid standards (CEN-CENELEC-ETSI Smart Grid Working Group Reference Architecture, 2012).

Big data characteristics in smart grid

The characteristics of big data in smart grid is also in accordance with the universal 5 V big data model in many researches (Zhu et al., 2015) as below:

  1. (i)

    Volume – refers to the vast amount of data generated, which makes data sets too large to store and analyze using traditional database technology. The possible solution to this problem is the distributed systems to store data in different locations, connect them by networks and bring them together by software. In smart grid the widespread application of smart meter and advanced sensor technology provide huge amount of data.

  2. (ii)

    Velocity – refers to the speed at which new data is generated and the speed at which data moves around. The requirements for real-time exchange of data is increasing. With a sampling rate of 4 times per hour, 1 million smart meters installed in the smart grid would result in 35.04 billion records, equivalent to 2920 Tb data in quantification (SAGIROGLU et al., 2016). The following Table 1 indicates the amount of records from smart meters in a year under various collection frequency with the assumption of 1 million devices and a 5 KB record per collection.

  3. (iii)

    Variety – refers to the types of data we can now use. In the past, we focus on structured data that neatly fits into tables or rational databases such as financial or meteorological data. With big data technology, we need to handle different types of unstructured data including messages, social media conversations, digital images, sensor data, video or voice recordings, and bring them together with more traditional, structured data. According to the extensive data sources in smart grid as shown in Fig. 1, the formats and dimensions of data are diverse in structure.

  4. (iv)

    Veracity – refers to the messiness or trustworthiness of the data. The quality and accuracy are less trustworthy with such large amount of big data, which challenge the outcome data analysis. Errors of measurements in smart grid may exist due to the imperfections in devices or mistakes in data transmission. The secure and efficient power system operation relays on the data assessment and state estimation.

  5. (v)

    Value – refers to our ability to extract valuable information from the huge amount of data and derive a clear understanding of the value it brings. The larger the amount of data is, the lower the density of valuable information will be. With the improvement of intelligent devices adopted in smart grid, more and more value of big data analytics is revealed according to the various applications.

Table 1 Quantification of collected data in different sampling rates (Big Data analytics and energy consumption, 2016)
Fig. 1
figure 1

Data Sources of the Grids

Data sources in smart grids

As an intelligent system of both energy and information, smart grid is the abundant source of information, which covers the data from process of electricity generation, transmission, distribution and consumption. These data include the electrical information from distribution stations, distribution switch stations, electricity meters, and non-electrical information like marketing, meteorological as well as reginal economic data as shown in Fig. 1 (Keyan et al., 2015). Collection and analysis of them provide essential help in scheduling of power plants, operation of subsystems, maintenance for vital power equipment and business behavior in marketing.

The data sources mentioned above can be sorted into three categories: measurement data, business data and external data (Teng et al., 2014). Most of the operation parameters in power system are measured through installed sensors and smart meters, indicating the system’s current and historical status (SAGIROGLU et al., 2016) (Jiye et al., 2015). The weather conditions and social events like festivals are the external data that cannot be measured from smart meters but have an impact on the operation and planning in power system. The business data mainly includes the marketing strategies and rivals’ behaviors.

Data collection techniques in smart grid

In smart grid, the data are collected and transmitted with help of smart meters which provide energy related information to both the utility company (or DSO) and customers. For the energy consumption of residential customers, the number of smart meter readings for a large utility company is expected to rise from 24 million a year to 220 million per day (SAGIROGLU et al., 2016). As an emerging component in electricity market and smart grid, electric vehicles (EVs) and plug-in hybrid EVs (PHEVs) have seen a growing popularity with the movement of electrification in transportation sector and progress of artificial intelligence. To control the normal operation status of the distribution system, DSO traditionally relies on the measurements in the primary substation, at the beginning of each MV feeder, where the protection systems are normally installed. The current magnitude information is also needed for the automatic on-load tap changer in HV/MV transformers for voltage regulation. The measurements of a typical smart meter include the node voltage, feeder current, power factor, active and reactive power, energy over a period, total harmonic distortion as well as load demand, etc. The intelligent devices for data collection in smart grid are listed as Table 2.

Table 2 Intelligent data collection devices in smart grid

Data communication techniques in smart grid

The communication infrastructure of the smart grid is composed of three types of networks: home area network (HAN), neighborhood area network (NAN) and wide area network (WAN) as shown in Fig. 2 (Baimel et al., 2016). The functions and characteristics of the above communication infrastructures are summarized in Table 3.

Fig. 2
figure 2

Smart grid communication infrastructure

Table 3 Summary of communication infrastructure in smart grid

Basic types of communication technologies for smart meters include wired and wireless infrastructures. The wireless communication technology allows the data center to gather measurement information from smart meters with low costs and simple connections while it may face the electromagnetic problem. Power line communication (PLC) is a wired communication technology by add a modulated carrier signal to the power cables and already successfully implemented in power system. The existing communication technology include ZigBee, WALN, cellular communication, WiMAX, PLC, etc. (Baimel et al., 2016).

As one of the first countries for smart metering infrastructure development, Italy has deployed smart meter to nearly all the customers with the PLC technology to transfer smart meter data to the nearest data concentrator located in the MV/LV substation. Then these data are sent to the DSO’s data centers for recording and data analysis. There are around 30 million meters and 400,000 secondary substation concentrators installed (Bahmanyar et al., 2016).

Data analysis techniques

The most important stage of the big data processing system is data analysis, which is the basis for discovering valuable information and supporting the decision-making (Fan et al., 2018; Cheng et al., 2018). There are several similar concepts relevant to data analysis listed in Table 4.

Table 4 Concepts related to data analysis

From a general point of view, the data analytics or data mining is the computational process to reveal the potential relations between variables with the techniques including database, statistics, pattern recognition, machine learning, etc. However, due to the diverse sources, the collected data sets may have different levels of quality in terms of noise, redundancy and consistency.

Data preprocessing

The data pre-processing techniques are necessary to improve data quality as shown in Fig. 3.

Fig. 3
figure 3

Data Pre-processing Techniques

Data integration techniques aim to aggregate data collected from disparate sources in an effective way with a unified view (Roya et al., 2018). For example, when combining the datasets of weather condition records and power system interruption events, the attribute of “date time” would appear twice. But apparently only one attribute of “date time” is needed for the following data analytics process. The same attributes with different name as well as the different attributes with the same name is to be identified in this process (Lim et al., 1996). Normally, the correlation analysis is used in the redundancy identification to abandon the highly correlated attributes and reduce the size of datasets. In most cases, the datasets would contain some missing values which influence the results of data analytics. Deletion or interpolation are the frequent techniques to solve such kind of problems. As to the abnormal values, the first step is to check whether this is rational based on the professional knowledge for the application. If it is caused by an error in sensors or data processing platform, we can treat it as a missing value or try to find the real value, otherwise it is supposed to be kept in the dataset as a “black swan”. The logarithm is an effective way to “correct” the distribution shape of data with severe skewness, because some data analytics algorithms are sensitive to imbalanced data. New attributes such as the temperature difference can be calculated in the pre-processing step if there is only maximum and minimum value of temperature in the initial dataset. The new constructed attributes are usually helpful to improve the accuracy of data analytics results.

Data analytics techniques

The most frequently used data mining or machine learning algorithms are usually categorized as supervised or unsupervised learning depending on whether there is a label attached to each item in datasets as shown in Table 5. For the supervised learning algorithms, the data analytics model can be trained based on the given data to discover the relation between data attributes and the corresponding categories or values. While for those without labels, the data analytics model is usually designed to recognize the possible groups among all the items (Di Zhua & Zhang, 2018).

Table 5 Data Analytics Algorithms

Procedures of data Mining in Smart Grids

As shown in Fig. 4, the main procedure of data analytics in smart grid is to extract valuable information from historical data for guiding the operation and maintenance with the comparison to real-time data (Siryani et al., 2017). The huge amount of data collected from smart meters and sensors are arranged and stored with data management techniques. After preparation, the mathematical model can be established through data mining techniques based on the clean data. With the input of real-time measurements, the state status can be evaluated in the derived model, which provides the possible schemes to guide practical actions and solve potential problems.

Fig. 4
figure 4

Example of big data analytic procedures in smart grid

Big data analytics in smart grid

Fault detection

The carbon emission reduction and sustainability of environment are the driving force and construction purpose of smart grid, which is designed in a decentralized structure. The employment of distributed generator units in modern power distribution system now provides an effective means for the utilization of widespread renewable energy such as wind and solar energy. These emerging microgrids are vital for the expectation of a low-carbon society. Moreover, the close distance between the generator and loads in microgrid improves the reliability of power delivery and reduces the power transmission loss. The ability to operate in an island mode also protects the load from damages caused by power system including voltage fluctuation, frequency deviation, etc. (Mishra et al., 2016).

However, the intermittent characteristic of renewable energy increases the uncertainty in power grid, whose typical solution is to use inverter interfaced distributed generators (IIDGs) for a better power quality. In contrast with the traditional bulk generators like large-volume thermal, nuclear or hydro generators, the much lower inertia of IIDGs is a severe potential threat when the faults in microgrids cannot be detected and cleared in a short time due to the limited current carrying capacity. Most of the traditional techniques relying on the detection of overcurrent and negative sequence current origin from the large-scale centralized power system and seem less effective in microgrids. A statistical classifier-based protection scheme using local current measurements is proposed by applying the wavelet transform and the decision tree (DT) model in (Mishra et al., 2016). The wavelet transform can decompose the signal in time-frequency domain with the time localization reserved. Energy, Shannon entropy and standard deviation of the wavelet coefficients which contain the information during transient events are calculated. Finally, 15 statistical features extracted from the current data for one cycle by sequence analyzer and wavelet transformation are fed into the DT models for fault detection and classification. A differential protection scheme for microgrid is proposed in (Kar et al., 2017) with the most sensitive features at both ends of the respective feeder processed by the discrete Fourier transform. These differential features are then utilized in the decision tree-based data-mining model for determining the final relaying decision.

For a grid-connected microgrid, the severe weather conditions or grid blackouts may trigger an unintentional islanding accident, which threats the safety operation and causes technical issues. Artificial neural networks (ANNs) are trained in (Hashemi et al., 2017) with features extracted from the differential transient of the rate of change of frequency (ROCOF) signal in order to identify islanding accidents. A support vector machine (SVM) classifier is established in (Alam et al., 2017) with multiple features extracted from system variables as an islanding detection approach. The feature extraction process is implemented with a sliding window whose width is optimized for the highest detection rate.

As a real-time social sensor for the smart grid, social media like Twitter or Facebook could contain potential information indicating the occurrence and location of power outages (Bauman et al., 2017). A probabilistic framework is devised in (Sun et al., 2016) for detecting a targeted event from the fragmented and noisy tweets. The method shows a good performance in locating accrual outage areas in experiment, which could be integrated to a social data-driven outage management.

Predictive maintenance/condition based maintenance

Distribution automation (DA) is a concept of smart grid which focuses on the operation and system reliability at the distribution level. A successful DA has the capability to localize and isolate the faults in distribution system with a reduced restoration time and improved customer satisfaction. Under the concept of DA, increasing volume of operational data have been collected from supervisory control and data acquisition (SCADA) or advanced metering infrastructure (AMI) for state monitoring and fault diagnosis.

Reference (Wang et al., 2017a) proposes an analyzing scheme for preventative measures to avoid or minimize the outages with the data related to pole mounted auto-recloser (PMAR). PMAR is a kind of protection intelligent electronic device installed on the overhead lines of a distribution network which attempts several recloses after an interruption happened in the downstream of the feeder.

Thanks to the development of ICT technology in power systems, a huge volume of data can be collected via AMI and communication infrastructures. Power system operating data, weather information and log data of relay protection devices are processed as the input of a one class classification system, which is a data-driven model of fault phenomena based on a hybridization of evolutionary learning and clustering techniques in (De Santis et al., 2015; De Santis et al., 2017). This fault recognition system is validated in the medium voltage power grid in Rome. The traditional statistical methods such as linear discriminant analysis (LDA) and logistic regression are discussed for mining the relation between power system faults and the features extracted from raw data (Cai & Chow, 2009).

As a potential threat to the security of transmission systems, the galloping of power lines can cause structural and electrical failures. After analyzing the impact factors of galloping, a data-driven model based on SVM and AdaBoost bi-level classifiers is proposed in (Wang et al., 2016a) for early warning. The extreme learning machine (ELM) algorithm is applied in an intelligent early-warning system for reliable online detection of risky events in power system in (Zhang et al., 2017). Since the weights in ELM training are randomly chosen and then determined through matrix computation without iterative parameter adjustment, the learning speed is much faster than conventional algorithms, which is an ideal solution in “big data” cases. The optimal balance between earning accuracy and warning earliness of the data-driven framework is also discussed. Reference (Cui et al., 2017) provides a method to extract electrical features from high-impedance fault current and voltage signals and build an effective feature set (EFS) via a ranking algorithm. Therefore, only a small number of signal channels are required to build a statistical classifier for fault detection. Reference (Jiang et al., 2016) also provides an effective method to reduce the huge volume of PMU data while retaining the critical information for fault detection in power system.

Transient stability analysis

Transient stability is a critical issue closely related to the safely operation of power system. However, the increasing demand for electricity, growing penetration of renewable energy sources and deregulated market force power grid to operate near their secure operating limits (Liu et al., 2014). Facing with the challenges from a more complex system, transient stability analysis (TSA) for the study of dynamic behavior taking the electromechanical and electromagnetic process in power system taken into consideration is becoming a hot research topic. The transient process and new operating conditions need be calculated with the TSA technique after a severe interruption in power grid for a comprehensive protection scheme. Traditional TSA based on the time-domain simulation is not able to provide universal results due to so many uncertainties.

Under the concept of smart grid, a large amount of data collected via AMI are involved in the state assessment of power systems to support the energy management, system operation and decision making. Therefore, efficient summarization techniques are required for extracting useful patterns and discovering valuable information from redundant measurements in power system. A DT-based framework is proposed in (Liu et al., 2014) (Vittal, 2013) for the dynamic security assessment (DSA) in power system with high penetration of DGs. Two contingency-oriented DTs are trained based on the databases generated from real-time simulations. One of the well-trained DT is fed with real-time wide-area measurements to identify potential security issues, and the other DT provides the online corresponding preventive control strategies to deal with the problems. In (He et al., 2016) the dominant instability generation group (DIGG) in power system is identified without time domain simulation since the features adopted for TSA are extracted from steady-state variables. Reference (Parate et al., 2016) proposed an approach to classify the collected data from smart grid into two classes called vulnerable and non-vulnerable data sets with the data analytics such as multichannel singular spectrum analysis (MSSA), principal component analysis (PCA) and SVM. A framework for online contingency screening is presented in (Dimitrovska et al., 2017) with respect to first swing transient stability. The large spectrum of pre-fault operating state variables and critical clearing times of several contingencies are collected to compose a dataset for pattern recognition methods. The metric which can be used for operating condition evaluation is developed through PCA.

In addition to the renewable energy micro-sources distributed in smart grid (SG), the grid-connected high capacity wind farms are also widely accepted and applied for an effective utilization of pollution free and abundant nature resources. The improvement of technologies for large wind turbine generators and high capacity power converters accelerate the amount of wind energy integration into power system. To address the potential deterioration and stability problem caused by the large integration of wind energy to power grid, reference (Andalib-Bin-Karim et al., 2017) proposed data-driven analytics to determine the Q-V characteristic curve at the point of interconnection of the wind farm with valuable information for voltage stability extracted. Without prior knowledge of the system configuration and parameters, different curve-fitting techniques are adopted in a real case study in Canada.

Power swing is the oscillation of power flow on transmission lines when the angles of rotors of synchronous machines are advancing or retracting to each other which may cause a large disturbance. Heavy load shedding, generator triggering and short-circuit faults clearance are all the potential reasons. Reference (Swetapadma & Yadav, 2016) used a decision tree-based scheme for fault detection and classification during power swing within half cycle time. The decision tree algorithm is also adopted in (Jena & Samantaray, 2016) with 21 potential features extracted from phasor measurement unit (PMU) data after Kalman filter process for intelligent relaying in transmission system. A probabilistic framework is established in (Papadopoulos et al., 2018) based on the decision tree and hierarchical clustering for dynamic behavior of power systems after an occurrence of interruption. The unstable groups which may lose synchronism can be successfully detected.

Although the PMU and WAMS provide high-resolution datasets for engineers to discover patterns of normal and abnormal operation, the low probability of events that occur in power grid leads to a severe class imbalance problem. The conventional data analytics are difficult to extract the features of rare instability from massive synchrophasor measurements. Reference (Zhu et al., 2017) develops a systematic imbalance learning machine for online short-term voltage assessment. A forecasting-based nonlinear synthetic minority oversampling technique is adopted in the cost-sensitive learning algorithm to deal with the class skewness. To take full advantage of massive power grid data, the random matrix theory is introduced in (Wei et al., 2016; XUXinyi, 2016) with a high-order data-driven model to present the power system parameters and external data like meteorological information. The eigenvalue-based analysis method is proven to deal with online transient state analysis. An online monitor of instantaneous electromechanical dynamics in transmission system is presented in (Zhang et al., 2016a) based on the parallel computing and k-nearest neighbors learning algorithms. The information that indicating time-varying correlations of power generation and consumption is extracted with the proposed framework. An active learning solution is proposed in (Malbasa et al., 2017) to solve the problems for online data-driven model updating and offline training, which provide an efficient way for data sets preparation. A novel PMU-based robust state estimation method is proposed in (Zhao et al., 2016) for online state estimation of a power system under different operation conditions with the help of an adaptive weight assignment function to dynamically adjust the measurement weight according to the large disturbance revealed from PMU data. A similar framework is proposed in (Shah et al., 2017) to enable the utility company for real-time data processing. The core vector machine (CVM) is used for a two-class classification in (Wang et al., 2016b) to process the huge amount of PMU data from power grid. The CVM model is trained offline with 24 features extracted from the raw data for an online assessment evaluation for the TSA problem. The transient stability boundary of large-scale power systems is analyzed in (Lv et al., 2017b) by a statistical nonparametric regression methodology based on the critical clearing time to determine whether a steady-state condition can recover after a given fault.

Electric device state estimation/health monitoring

As a vital component for electrical energy conversion, a failure in power transformers may cause catastrophic blackouts in power system (Reinhardt & Reinhardt, 2016). Therefore, the life-cycle management of power transformers based on an accurate estimation attracts a lot of researches for a more stable and reliable power grid. The existing diagnosis methods for power transformers mainly focus on limited state parameters with the threshold-based diagnosis. To take information of system operation and meteorological conditions into state estimation analysis, three classical algorithms for association rule mining are discussed in (Sheng et al., 2018), namely, Apriori, AprioriTid and AprioriHybrid. The rule mining methods are combined with probabilistic graphical model for potential failure prediction.

In most commercial buildings, the building automation system (BAS) are designed and adopted to control the heating, ventilating and airing conditioning (HVAC) system to maintain proper temperature and humidity for the occupants. If the indoor smart grids can be monitored on a continuous or regular basis, a proper operation strategy may be proposed for the improvement of energy efficiency, fault diagnosis and system reliability. In (Allen et al., 2016) a novel health monitoring system is proposed by the fuzzy logic for abnormal operating condition detection. The fault signatures for various fault types are generated by the ANN classification technique.

As the rising number of aging assets in power system is becoming a potential threat to the safety operation, a lot of failure models are proposed focusing on variables of aging time or conditions. Reference (Murthy et al., 2004) proposed a failure rate model for general electric power equipment with the lifecycle data of service age, maintainer, health index taken into consideration. In order to make the best use of these data, the stratified proportional hazards model (PHM) is developed as a nonparametric regression method to process and classify the lifecycle data into multi-type recurrent events quantitatively (Qiu et al., 2016). The potential risk problem and health condition can be predicted with the help of this PHM method (Colombo et al., 1985).

Power quality monitoring

As a worldwide issue, Electric power quality (PQ) refers to the magnitude, frequency and waveform of voltage and current in power system and highly related to the safe operation of power grid as well as the satisfaction of consumers. With the increasing application of nonlinear and power electronics based loads and generators, the harmonic distortions and instable situations frequently appears in power grid. Deep learning is successfully employed for the classification of PQ events of the electricity networks in (Balouji & Salor, 2017). Instead of sampling the voltage data of the PQ event data like the existing analysis methods, the image files of the three-phase PQ events are processed for classification by deep learning techniques. Due to the high cost for installation of advance metering devices, the conventional electromechanical analog meters still work in some residential areas and the data analytics-based PQ analysis cannot be properly utilized. Reference (Tang et al., 2015) presents a framework that collecting electricity information of from analog meters via image processing techniques. The power consumption information can then be collected to a cloud server through online data exchange. Under the consideration of balance between computation capability and the satisfactory performance of the algorithm, a compact method is presented in (Borges et al., 2016) for feature extraction from the raw data in smart grid to get information that is highly related to the field of power quality. A robust and fast processing pattern recognition algorithm is proposed in power quality events (PQE) classification is illustrated in (Ferhat et al., 2016). The features highly correlated to the PQE are extracted with the discrete wavelet transform-entropy and basic statistical criteria for the establishment of ELM classifier.

Topology identification

Taking the advantage of information layers in smart grid is an effective means to approach the challenges from the renewable energy sources (RES) in distribution network. The measurement, monitoring, communication and control of smart grids by advanced sensors and devices are making the complex network sensible and perceptible. The randomness of RES and uncertainty of the load are increasing the urgency and necessity for a comprehensive decision based on huge volume of data collecting and processing. The SCADA and WAMS provide voltage and power data of smart grid in near real-time sampling rate (Gungor et al., 2011) (Ghosh et al., 2013). Since the network-constrained economic dispatch problems are supposed to be solved by the real-time electricity process in a contemporary whole-sale electricity market, the potential of recovering the topology of a grid is explored with market data in (Kekatos et al., 2014). Another dynamic solution for online SG topology identification (TI) is proposed in (Babakmehr et al., 2016) which is reformulated as a sparse-recovery problem. Grapy theory and probabilistic DC optimal power flow are adopted for building the network model.

With the purpose for a greener society, the low carbon technologies (LCTs) are driven by the government by application of heat pumps, photovoltaic, electric vehicles and other smart appliances in low voltage (LV) distribution networks. Therefore, the visualization of LV networks with limited metering and data acquisition equipment attracts increasing research interests. The network load profiling based on the identification of representative load profiles of LV systems is an economical alternative method. A novel three-stage network load profiling method proposed in (Li et al., 2015a; Li et al., 2015b) aims to evaluate the capabilities of the current LV networks to accommodate the LCTs by clustering, classification and scaling. The first two stages are used to identify the load conditions of unmonitored LV systems with similar fixed data to those monitored LV substations. The contribution factor for each LV template is then determined by the cluster-wise weighted constrained regression algorithm.

Renewable energy forecasting

The abundant and environmental friendly RES such as wind and photovoltaic energies are supposed to be the dominant energy source for the next generation of power grid. However, the randomness and intermittent characteristics are always obstacles for a large-scale utilization of RES in a stable way. To deal with such enormous challenges and get an improved dispatch planning, maintenance scheduling as well as regulation, an accurate and reliable RES forecasting approach has become the hot spot around the world (Ak et al., 2016). A data mining based method consisting of k-means and neural networks is proposed in (Wenbin & Peng, 2017). The meteorological information in historical records are used for clustering approach to classify the days into different categories. Then the bagging algorithm based neural network is trained to get the forecasting results of wind energy. Instead of using the neural network, (Ye et al., 2016) utilizes the support vector regression method to predict the wind speed with the time series historical wind speed processed by empirical mode decomposition into several intrinsic mode functions and residue. In (Yang et al., 2015) a short-term probabilistic wind generation forecast method is presented based on the sparse Bayesian classification and Dempster-Shafer theory as a nonparametric approach. Reference (Khodayar et al., 2017) studies the ultra-short-term wind forecasting with the deep learning method through unsupervised feature learning from the unlabeled historical wind speed data. The forecasting approach of distributed solar energy systems from macro- and micro-aspects is discussed in a general way in (ZHAO et al., 2017) with clustering of capacity and location of PV system. The data-driven forecasting approach of PV diffusion is proposed based on cellular automation in microscopic analysis. By decomposing the time-series data with discrete wavelet transform, the proposed recurrent neural network (RNN) model in (Nazaripouya et al., 2016) is developed for ultra-short-term solar power prediction.

Load forecasting

Like the RES prediction, an accurate short-term load forecasting is the essential basis for energy management, system operation and market analysis. As is mentioned in (Bunn & Farmer, 1985; Ni et al., 2016), an increase of forecasting accuracy may bring a lot of benefits and save the investments. With the emerging active role of customers in smart grid, the high efficient dynamic electricity market is also based on a good performance of electricity consumption prediction. Since electricity consumption is affected by the weather conditions to some extent, reference (Liu et al., 2018) proposed a Map/Reduce programming framework for distributed load forecasting by partitioning the geographical area according to local weather information. An extreme learning machine ensembled with a novel wavelet transform is used for electricity consumption in (Li et al., 2016a) after a conditional mutual information based feature selection, which is also used in (Ahmad et al., 2017). To overcome the volatility and uncertainty of load profiles, the recurrent neural network is adopted with a novel pooling layer to avoid overfitting problems in (Shi et al., 2017). Rather than the aggregated load forecasting, the energy consumption in a single house is usually volatile and difficult to be predicted. Driven by the recent success of deep learning, a long short-term memory recurrent neural network based framework in (Kong et al., 2017) is applied to the residential load forecasting as the latest deep learning techniques. A hidden mode Markov decision process model is developed in (Li & Jayaweera, 2015) to the forecast the customers’ real-time behavior. Reference (Moreno-Munoz et al., 2016) analysis the emerging trends and challenges in the new era of using social media through mobile apps to improve their customer engagement and load forecast. Reference (Cai et al., 2017) considers the impact of social activities on the prosumers’ arrangements for their generation and consumption patterns and further discuss the overall impact on the final load and the network usage.

Load profiling

Load profiling is a way to describe the typical behavior of electric consumption, which is usually represented in time domain for load forecasting, demand-side management and capital planning (Wenhao et al., 2016; Claessens et al., 2016; Granell et al., 2015; Singh & Yassine, 2017; IMRAN et al., 2016). As an effective method for energy management, the tariff structure designed before is usually based on the type of activity, which is not able to indicate the electrical behavior in a comprehensive way (Ahmed et al., 2017). Reference (Bo et al., 2016) utilized a two-stage clustering algorithm to classify customers according to their load curves. In the first-stage, the load patterns are clustered into different categories according to the evaluation index, and then the customers are classified according to the comprehensive load shape factors defined in the first-stage with SVM algorithm. In contrary to the time domain analysis (Al-Otaibi et al., 2016), the DFT method is adopted in (Zhong & Tam, 2012) to discover the information of customers’ behavior, which can be accurately reconstructed using limited frequency components and still satisfy the strict requirements. The residential electricity consumption usually can be divided into three parts: fixed, regulable and deferrable loads, which is the theoretical basis for the optimal energy management of the demand response (DR) mechanism. DR is used to initiate a change in the customers’ consumption or feed-in pattern with an incentive from costs or ecological information. Reference (Li et al., 2017) utilizes the spectral domain analysis methods DWT and DFT to decompose smart metering data with the extracted coefficients. Results show that DWT performs better than DFT in individual level while DFT is more suitable to be used in the analysis at a highly aggregated level. A learning based DR strategy combining data analytics and optimization is developed for regulatable loads focusing on the residential HVAC (Zhang et al., 2016b). Because when the customers’ behavior is obtained, an optimal DR technique for household HVAC unit can be designed based on weather prediction, day-ahead electricity price. Reference (Jindal et al., 2016) takes the advantage of the social networking to minimize the peak power consumption of the electrical appliances by proposing a “family plan” approach which leverages the social network topology and statistical energy usage patterns of the users.

To better understand the information behind the stochasticity and irregularity of residential energy consumption, an in-depth analysis is presented in (Grindrod, 2016) with a finite mixture model-based clustering technique. The self-organizing maps (SOM) as a type of ANN is used in (Verdú et al., 2006) to reduce the dimension of collected raw data for load pattern extraction. The frequency-domain data analytics in the SOM shows a superiority over the time-domain data with a higher accuracy in new customer classification. As one of the main tasks of load profiling, a better understanding of the flexibility of customers’ electricity consumption is the basis for DR, which can be used to release the pressure of distribution system in terms of thermal and voltage constrains. A multi-resolution analysis method based on wavelet analysis is proposed in (Li et al., 2016b) to extract spectral and time-domain features of load data. Different permutations of typical load profiles provide a more flexible load profiling with a reduction of computation. With the popularization of electric vehicles (EVs), learning the charging load patterns of them is becoming a key step for the stability of power grids. An unsupervised clustering algorithm is used in (Munshi & Mohamed, 2018) to extract the pattern of EV charging loads with only the real power measurements. Furthermore, the flexibility of the collective EV charging demand is analyzed with Bayesian maximum likelihood. References (Tong et al., 2016; Wang et al., 2017b) focus on the problem brought by the huge load profile data with the popularity of smart meters installed at the household level, which poses challenges to the communication and storage of measurement data as well as the vital information extraction from massive records. K-SVD sparse representation technique is used to decompose the load profiles into several partial usage patterns for a linear SVM based method to recognize the type of customers.

Load disaggregation

Load disaggregation is also called non-intrusive load monitoring (NILM), aiming to segregate the overall load profiles at household level into the energy consumption of individual appliances. Unlike direct appliance monitoring framework, the NILM from only one smart meter installed in the house is easier to be accepted by the customers (Liang et al., 2010a; Liang et al., 2010b; Gillis et al., 2016). Since different types of the household electric appliances have different potential to be involved in the DR program, the appliance-level load profiles allow the utilities to understand the customers’ behavior better and helps to develop a more energy efficient strategy. The early techniques for NILM are mainly based on the detection of “edge” in power signal to indicate the state “on” or “off” of a known device (Sultanem, 1991). The more effective and complex appliance signatures are then proposed with the harmonics computation of steady-state power or current (Berges et al., 2009; Lee et al., 2004). The hidden Markov models (HMMs) are adopted in (Kong et al., 2018) with the segmented integer quadratic constraint programming to disaggregate the household power profile at an average frequency of 0.3 Hz into the appliance level. In (Henao et al., 2017) a NILM approach based on the subtractive clustering the maximum likelihood classifier is proposed for a low-sampling-rate date set of 1 Hz sampling rate. The appliances are modeled as ON/OFF states in this event-based load disaggregation algorithm. As a single channel blind source separation problem, the dictionary learning based approaches can be used in NILM. A deep learning approach with multiple layers of dictionaries trained for each device as “deep sparse coding” is utilized in (Singh & Majumdar, 2017; Zico Kolter et al., 2010). Compared with HMM, the latter method is not suitable for real-time application. By combining the decision tree and nearest-neighbor algorithms, the semi-supervised machine learning is applied to the NILM problem in (Gillis & Morsi, 2017) with the signal features extracted by matching a set of net wavelets to the load classes.

Non-technical loss detection

The nontechnical loss (NTL), which is probably caused by the electrical theft or errors in accounting, is one of the prominent concerns that have plagued the power system utilities for a long time (Leung, 2016; Zhan et al., 2016; Non-Cooperative Game Model Applied to an Advanced Metering Infrastructure for Non-Technical Loss Screening in Micro-Distribution Systems, 2014; Guerrero et al., 2018). According to the survey published by Northeast Group, LLC, the loss caused by electricity theft reached more than $89.3 billion in the world every year (PR Newswire, 2014). Furthermore, large scale electricity fraudulent behavior may cause severe imbalance problems in power system. Therefore, the effective framework to detect the NTL in the complex power grid has appealed many research interests. A comprehensive top-down scheme based on DT and SVM is proposed in (Jindal et al., 2016). DT is trained with various features including heavy appliances, number of persons, weather conditions to get the expected value of electricity consumption for the customer during a particular time. Then the calculated consumption along with other features are fed to the SVM classifier which is already trained based on the collected dataset to determine whether the customer’s behavior is normal or fraud. In (Zanetti et al., 2017) the fraud detection is triggered when a discrepancy is detected between energy supplied from the power system and collected information from smart meters. The anomalies in consumption patterns are discovered with the fuzzy clustering algorithm.

Open issues for the application of big data analytics in smart grids

Even though there are increasing researches on the big data analytics in smart grids, the deployed applications are few. There are still many open issues needed to be addressed before the techniques can create implications in reality.

With the fast deployment of smart meters and advanced sensors, huge amount of data with multiple types and structures from deference sources with a variety of protocols are generated every second. However, the lack of standard data format for the information software and database structures, as well as the issue of interoperability of different information and communication systems deployed in the smart grids, make it complicated and difficult to obtain data for real application. The traditional way of isolated storage of the data in various systems also increases the barrier for data sharing among applications.

As a conventionally sensitive industry, most of the data generated in the smart grid are considered as confidential or related with privacy issues; therefore, it is impractical for researchers to conduct highly relevant studies which can be smoothly transferred later on into deployment. Thus, most of the researches are still about the algorithms which are tested with ideal data, and hence stay in the Ivory tower.

In addition, due to the lack of strategic vision, top design of application, large investment in reality, combined with the short-sighted recognition of the value of the data, the applications of big data in real systems are growing very slow. Even though, the majority of utility companies showed great interests in the big data analytics and their application in their business, they are still waiting to see convincing results before they are willing to put more efforts and investment.

Last but not least, the big data analytics in smart grids is a comprehensive and complicated field, which does not only depend on the mathematic algorithms or techniques, it also depends on the operation of the systems, the behaviors of vast number of autonomous users, the ICT technologies, the expertise of the field, etc. Therefore, it needs the synergy among experts from different fields if we would like to see the benefits of it in the smart grids.

Conclusion

In this article, the big data in smart grid and the corresponding state-of-the-art analysis methods have been reviewed and discussed. The data which may contain valuable information are collected from smart meters installed in the power system, electricity market, GIS, meteorological information system, social media, and so on. The purpose of advanced ICT technology in power system is to associate the traditional physical parameters in power system to the external variables to discover potential regulations and scientific problems. Eleven applications of data analytics mentioned in the paper are nearly involved in every aspect of smart grids, including the operation, maintenance, load/output forecasting, protection as well as fault detection and location. After extracting the useful features from raw information with the background knowledge of electrical engineering, typical data analytics methods, such as neural network, k-means, and support vector machine, could be widely applied. Secure and efficient operation strategies as well as optimal business decisions are supposed to be made with the data analytics from a more unified view.

With more advanced ICT technologies applied in power system, the fast and efficient data analytics framework for huge volume of data would become a challenging requirement. Moreover, the cyber security and privacy protection could become as important as a relay protection in power system. Even though the interactive communication with customers provides a potential solution for more accurate demand response, it also increases the difficulties in consumption behavior analysis at the same time. A secure and high-performance data analytics platform would be crucial for the social welfare and power companies’ interests in the future. As the application of data analytics in smart grids is a comprehensive and complicated field, involving mathematics, ICT technologies, computer science, electrical engineering, etc., thus, it needs the synergy among experts from different fields as well as the strategic visions for the top designs.

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EB carried out the smart grid studies, participated in the concepts of big data in power system and the structure of the paper. TH participated in the frontier technologies in smart grid and drafted part of the manuscript. YZ participated in the data analysis application survey in smart grid and drafted the manuscript. All authors read and approved the final manuscript.

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Zhang, Y., Huang, T. & Bompard, E.F. Big data analytics in smart grids: a review. Energy Inform 1, 8 (2018). https://doi.org/10.1186/s42162-018-0007-5

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