2,632 research outputs found
Online power quality disturbance detection by support vector machine in smart meter
Power quality assessment is an important performance measurement in smart grids. Utility companies are interested in power quality monitoring even in the low level distribution side such as smart meters. Addressing this issue, in this study, we propose segregation of the power disturbance from regular values using one-class support vector machine (OCSVM). To precisely detect the power disturbances of a voltage wave, some practical wavelet filters are applied. Considering the unlimited types of waveform abnormalities, OCSVM is picked as a semi-supervised machine learning algorithm which needs to be trained solely on a relatively large sample of normal data. This model is able to automatically detect the existence of any types of disturbances in real time, even unknown types which are not available in the training time. In the case of existence, the disturbances are further classified into different types such as sag, swell, transients and unbalanced. Being light weighted and fast, the proposed technique can be integrated into smart grid devices such as smart meter in order to perform a real-time disturbance monitoring. The continuous monitoring of power quality in smart meters will give helpful insight for quality power transmission and management
The University Defence Research Collaboration In Signal Processing
This chapter describes the development of algorithms for automatic detection of anomalies from multi-dimensional, undersampled and incomplete datasets. The challenge in this work is to identify and classify behaviours as normal or abnormal, safe or threatening, from an irregular and often heterogeneous sensor network. Many defence and civilian applications can be modelled as complex networks of interconnected nodes with unknown or uncertain spatio-temporal relations. The behavior of such heterogeneous networks can exhibit dynamic properties, reflecting evolution in both network structure (new nodes appearing and existing nodes disappearing), as well as inter-node relations.
The UDRC work has addressed not only the detection of anomalies, but also the identification of their nature and their statistical characteristics. Normal patterns and changes in behavior have been incorporated to provide an acceptable balance between true positive rate, false positive rate, performance and computational cost. Data quality measures have been used to ensure the models of normality are not corrupted by unreliable and ambiguous data. The context for the activity of each node in complex networks offers an even more efficient anomaly detection mechanism. This has allowed the development of efficient approaches which not only detect anomalies but which also go on to classify their behaviour
Computational intelligence in extra low voltage direct currrent pico-grids
Ph. D. ThesisThe modern power system has gone through a lot of changes over the past few years. It
is no longer about providing one-way power from sources to various loads. Power monitoring
and management have become an increasingly essential task with the growing trend to provide
users more information about the status of the loads within their energy consumption so that
they can make an informed decision to reduce usage and cost or request desired maintenance.
Computational intelligence has been successfully implemented in the electrical power systems
to aid the user, but these research studies about this are generally conducted on the conventional
alternative current (AC) macro-grids. Until now, little work has been done on direct current
(DC) and the focus on smaller DC grids has been even less. In recent years, the evolution of
electrical power system has seen the proliferation of direct current (DC) appliances and
equipment such as buildings, households and office loads. This number keeps increasing with
the advancement in technology and consumer lifestyles changes. Given that DC power supplies
are getting more popular in the form of photovoltaic panels and batteries, it is possible for Extra
Low Voltage (ELV) DC households or office pico-grids to come into use soon. This research
recognises and addresses this research gap in the monitoring and managing of the DC picogrids.
It recommends and applies the bottom-up monitoring and management approach in
smaller scale grids and in larger scale grids. It innovatively categorises the loads in the grids
into dumb loads that do not have intelligence and communication features and smart loads that
have these features. While targeting at these ELV DC pico-grids, this research presents
solutions that provide users useful information on load classification, load disaggregation,
anomaly warning and early fault detection. It provides local and remote sensing with the
alternative use of hardware to lessen the computational burden from the main computer. The
inclusion of remote monitoring has opened a window of opportunities for Internet of Things
(IoT) implementation. These solutions involve the blending of computational intelligence
techniques with enhanced algorithms, such as K-Means algorithm, k-Nearest Neighbours (kNN)
classification, Naïve Bayes Classification (NBC) Theorem, Statistical Process Control (SPC)
and Long Short-Term Memory Recurrent Neural Network (LSTM RNN). As demonstrated in
this research, these solutions produce high accuracy results in load classification and early
anomaly detection in both AC and DC pico-grids. In addition to the load side, this research
features a short-term PV energy forecasting technique that is easily comprehensible to users.
This research contributes to the implementation of the Smart Grid with possible IoT features in
DC pico-grids
Energy Efficient Neocortex-Inspired Systems with On-Device Learning
Shifting the compute workloads from cloud toward edge devices can significantly improve the overall latency for inference and learning. On the contrary this paradigm shift exacerbates the resource constraints on the edge devices. Neuromorphic computing architectures, inspired by the neural processes, are natural substrates for edge devices. They offer co-located memory, in-situ training, energy efficiency, high memory density, and compute capacity in a small form factor. Owing to these features, in the recent past, there has been a rapid proliferation of hybrid CMOS/Memristor neuromorphic computing systems. However, most of these systems offer limited plasticity, target either spatial or temporal input streams, and are not demonstrated on large scale heterogeneous tasks. There is a critical knowledge gap in designing scalable neuromorphic systems that can support hybrid plasticity for spatio-temporal input streams on edge devices.
This research proposes Pyragrid, a low latency and energy efficient neuromorphic computing system for processing spatio-temporal information natively on the edge. Pyragrid is a full-scale custom hybrid CMOS/Memristor architecture with analog computational modules and an underlying digital communication scheme. Pyragrid is designed for hierarchical temporal memory, a biomimetic sequence memory algorithm inspired by the neocortex. It features a novel synthetic synapses representation that enables dynamic synaptic pathways with reduced memory usage and interconnects. The dynamic growth in the synaptic pathways is emulated in the memristor device physical behavior, while the synaptic modulation is enabled through a custom training scheme optimized for area and power.
Pyragrid features data reuse, in-memory computing, and event-driven sparse local computing to reduce data movement by ~44x and maximize system throughput and power efficiency by ~3x and ~161x over custom CMOS digital design. The innate sparsity in Pyragrid results in overall robustness to noise and device failure, particularly when processing visual input and predicting time series sequences. Porting the proposed system on edge devices can enhance their computational capability, response time, and battery life
Comparison of Radio Frequency Distinct Native Attribute and Matched Filtering Techniques for Device Discrimination and Operation Identification
The research presented here provides a comparison of classification, verification, and computational time for three techniques used to analyze Unintentional Radio- Frequency (RF) Emissions (URE) from semiconductor devices for the purposes of device discrimination and operation identification. URE from ten MSP430F5529 16-bit microcontrollers were analyzed using: 1) RF Distinct Native Attribute (RFDNA) fingerprints paired with Multiple Discriminant Analysis/Maximum Likelihood (MDA/ML) classification, 2) RF-DNA fingerprints paired with Generalized Relevance Learning Vector Quantized-Improved (GRLVQI) classification, and 3) Time Domain (TD) signals paired with matched filtering. These techniques were considered for potential applications to detect counterfeit/Trojan hardware infiltrating supply chains and to defend against cyber attacks by monitoring executed operations of embedded systems in critical Supervisory Control And Data Acquisition (SCADA) networks
Radio Frequency Based Programmable Logic Controller Anomaly Detection
The research goal involved developing improved methods for securing Programmable Logic Controller (PLC) devices against unauthorized entry and mitigating the risk of Supervisory Control and Data Acquisition (SCADA) attack by detecting malicious software and/or trojan hardware. A Correlation Based Anomaly Detection (CBAD) process was developed to enable 1) software anomaly detection discriminating between various operating conditions to detect malfunctioning or malicious software, firmware, etc., and 2) hardware component discrimination discriminating between various hardware components to detect malfunctioning or counterfeit, trojan, etc., components
Ultrafast single-channel machine vision based on neuro-inspired photonic computing
High-speed machine vision is increasing its importance in both scientific and
technological applications. Neuro-inspired photonic computing is a promising
approach to speed-up machine vision processing with ultralow latency. However,
the processing rate is fundamentally limited by the low frame rate of image
sensors, typically operating at tens of hertz. Here, we propose an
image-sensor-free machine vision framework, which optically processes
real-world visual information with only a single input channel, based on a
random temporal encoding technique. This approach allows for compressive
acquisitions of visual information with a single channel at gigahertz rates,
outperforming conventional approaches, and enables its direct photonic
processing using a photonic reservoir computer in a time domain. We
experimentally demonstrate that the proposed approach is capable of high-speed
image recognition and anomaly detection, and furthermore, it can be used for
high-speed imaging. The proposed approach is multipurpose and can be extended
for a wide range of applications, including tracking, controlling, and
capturing sub-nanosecond phenomena.Comment: 30 pages, 12 figure
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