On Optimizing Traffic Distribution for Clusters of Network Intrusion Detection and Prevention Systems

Le, Anh

January 2008

To address the overload conditions caused by the increasing network traffic volume, recent literature in the network intrusion detection and prevention field has proposed the use of clusters of network intrusion detection and prevention systems (NIDPSs). We observe that simple traffic distribution schemes are usually used for NIDPS clusters. These schemes have two major drawbacks: (1) the loss of correlation information caused by the traffic distribution because correlated flows are not sent to the same NIDPS and (2) the unbalanced loads of the NIDPSs. The first drawback severely affects the ability to detect intrusions that require analysis of correlated flows. The second drawback greatly increases the chance of overloading an NIDPS even when loads of the others are low. In this thesis, we address these two drawbacks. In particular, we propose two novel traffic distribution systems: the Correlation-Based Load Balancer and the Correlation-Based Load Manager as two different solutions to the NIDPS traffic distribution problem. On the one hand, the Load Balancer and the Load Manager both consider the current loads of the NIDPSs while distributing traffic to provide fine-grained load balancing and dynamic load distribution, respectively. On the other hand, both systems take into account traffic correlation in their distributions, thereby significantly reducing the loss of correlation information during their distribution of traffic. We have implemented prototypes of both systems and evaluated them using extensive simulations and real traffic traces. Overall, the evaluation results show that both systems have low overhead in terms of the delays introduced to the packets. More importantly, compared to the naive hash-based distribution, the Load Balancer significantly improves the anomaly-based detection accuracy of DDoS attacks and port scans -- the two major attacks that require the analysis of correlated flows -- meanwhile, the Load Manager successfully maintains the anomaly-based detection accuracy of these two major attacks of the NIDPSs.

Load Balancing

Load Management

Intrusion Detection System

Intrusion Prevention System

Computer Science

Design of Transformer Terminal Unit for Transformer Management System

Huang, Jhao-Bi

11 July 2012

With the economic development, the high quality has become a critical issue for service continuous of power companies. To ensure the stable power supply, the asset management of power equipments is applied to prevent the system outage. With voluminous distribution transformers over very wide area, the real time monitoring of temperature has been included in the scope of smart grid. During recent years, the service outage due to transformer overloading has caused customer panic as well as deterioration of service quality. This thesis develops the Transformer Terminal Unit (TTU) by integration of computer chip for power consumption, DSP and sampling circuit of temperature measurement to achieve the functions of real time monitoring of transformer operation condition. When an abnormal operation condition such as overloading or high oil temperature occurs, the TTU can report the contingency back to the control station via the hybrid communication system so that the distribution system operators can take remedy action to prevent the contingency. The actual loading and temperature of transforms are also measured and collected in this study to develop the relationship of temperature and loading levels. By collecting transformer temperature, the power demand of a transformer can be estimated and the load shedding can then be activated to prevent the problem of overloading when the temperature exceeds the operation constraint.

demand response

load management

temperature sensitivity

load forecasting

transformer terminal unit

The development, implementation and performance evaluation of an innovative residential load management system / Abraham Zacharias Dalgleish

Dalgleish, Abraham Zacharias

January 2009

The power utility of South Africa, Eskom, expected a supply shortfall of approximately 400MW between February and August 2006 in the Western Cape. The peak of the crisis was in mid-winter (June to August). This shortfall was firstly caused when Eskom experienced a breakdown on the one of the two nuclear supply units. Secondly the remaining of the Koeberg units was due for refuelling which necessitated the shut-down of the reactor. No electricity was therefore generated by both units. It was clear that if electricity demand was not effectively curbed, extensive power outages would be experienced; which was the case. Various demand side management (DSM) programmes were rolled-out to address lighting, switching from electricity to gas for cooking, compensating customers that could generate own electricity, energy efficiency and load curtailment in the education, commercial, and industrial sectors, as well as an extensive energy efficiency campaign. It is shown in this study that the most constrained periods were expected during the evening peak and was a consequence of electricity consumption in the residential sector. The residential evening peak is very prominent and primarily caused by water heating, cooking, space heating, lighting, and appliances. None of the mentioned programmes focused on the residential evening peak. Traditional residential DSM technologies were almost impossible to implement in the short timeframe because there are more than 625,000 residences in the Western Cape. A solution was looked for that could be implemented in a relatively short period to address the residential evening peak. This study focuses on the development, implementation, and performance evaluation of Power Alert – An innovative residential load management system. The need for such a system was identified and the expected impact was determined through a feasibility study. Power Alert was designed to be a link between Eskom and the public through the national television broadcaster. It was operational during the whole Western Cape winter. A methodology to determine the impact of Power Alert was also developed to demonstrate the actual load reductions. The methodology was applied and Power Alert demonstrated that it was a valuable residential load management tool that could be designed and implemented in a much shorter time than conventional residential DSM measures. / Thesis (Ph.D. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2010.

Residential load management

Demand side management

Power alert

Human behaviour

Measurement and verification

The development, implementation and performance evaluation of an innovative residential load management system / Abraham Zacharias Dalgleish

Dalgleish, Abraham Zacharias

January 2009

The power utility of South Africa, Eskom, expected a supply shortfall of approximately 400MW between February and August 2006 in the Western Cape. The peak of the crisis was in mid-winter (June to August). This shortfall was firstly caused when Eskom experienced a breakdown on the one of the two nuclear supply units. Secondly the remaining of the Koeberg units was due for refuelling which necessitated the shut-down of the reactor. No electricity was therefore generated by both units. It was clear that if electricity demand was not effectively curbed, extensive power outages would be experienced; which was the case. Various demand side management (DSM) programmes were rolled-out to address lighting, switching from electricity to gas for cooking, compensating customers that could generate own electricity, energy efficiency and load curtailment in the education, commercial, and industrial sectors, as well as an extensive energy efficiency campaign. It is shown in this study that the most constrained periods were expected during the evening peak and was a consequence of electricity consumption in the residential sector. The residential evening peak is very prominent and primarily caused by water heating, cooking, space heating, lighting, and appliances. None of the mentioned programmes focused on the residential evening peak. Traditional residential DSM technologies were almost impossible to implement in the short timeframe because there are more than 625,000 residences in the Western Cape. A solution was looked for that could be implemented in a relatively short period to address the residential evening peak. This study focuses on the development, implementation, and performance evaluation of Power Alert – An innovative residential load management system. The need for such a system was identified and the expected impact was determined through a feasibility study. Power Alert was designed to be a link between Eskom and the public through the national television broadcaster. It was operational during the whole Western Cape winter. A methodology to determine the impact of Power Alert was also developed to demonstrate the actual load reductions. The methodology was applied and Power Alert demonstrated that it was a valuable residential load management tool that could be designed and implemented in a much shorter time than conventional residential DSM measures. / Thesis (Ph.D. (Mechanical Engineering))--North-West University, Potchefstroom Campus, 2010.

Residential load management

Demand side management

Power alert

Human behaviour

Measurement and verification

Voltage-led load management in UK distribution networks

Ballanti, Andrea

January 2018

The growing uptake of wind and photovoltaic technologies requires further sources of system-level flexibility to avoid or defer significant investments. The ability to control, to some extent, customer demand (load management, LM) is one of these sources of flexibility. However, the direct involvement of a large number of customers makes the scalability of such approach a major challenge. A mostly unexplored solution to overcome the challenges of managing thousands or millions of customers is to leverage the positive correlation between voltage and demand. More precisely, Distribution Network Operators (DNOs) can control existing regulation devices to reduce customer voltages and so triggering a reduction in demand. This scheme, hereafter called voltage-led LM, avoids the direct involvement of customers overcoming one of the major barriers of traditional LM solutions. To understand whether this approach can be of any significance, a methodology able to quantify such reduction in demand need to be developed. However, the few methodologies available in the literature neglect the interactions across voltage levels and their influence on the benefits of the scheme. Moreover, time-varying demand profiles and load models are not always considered. Finally, the impact that the widespread adoption of distributed energy resources might have, is also neglected. This thesis addressed these gaps by developing a four-stage approach in which the time-varying volume of demand reduction that the scheme can unlock is quantified considering for the first time the influences among all voltage levels in distribution network. To reduce the complexity each voltage level is analysed separately whilst maintaining the corresponding dependencies. The methodology, also able to extrapolate the results at national scale, can quantify the impact that the uptake of residential scale PV units might have on the scheme. The methodology is demonstrated with a real UK case study where 10-min resolution time-series daily and seasonal analysis are performed. For the first time real network models across the whole distribution network, from 132 kV to 400 V, have been adopted. The interactions across voltage levels, the adoption of realistic load models, the variety of network models and the use of a time-varying approach, all aspects simultaneously considered for the first time in a case study, have shown to play a key role in the quantification. In Great Britain the scheme is expected to provide a significant volume of flexibility of around 1.8GW (60 GW of peak demand). The presence of PV, at least in the short term, has shown to have only a marginally effect on the benefits unlocked by the voltage-led LM scheme, making such scheme promising even in a low carbon future.

[en] LOAD MANAGEMENT IN A COMPETITIVE ENVIRONMENT / [pt] O GERENCIAMENTO DA DEMANDA EM AMBIENTE COMPETITIVO

MARCELO CHAVES MAIA

17 July 2006

[pt] Este trabalho consiste em apresentar um modelo de gerenciamento da demanda baseado na análise do sistema elétrico identificando as áreas ou barras mais sensíveis a reduções de demanda, portanto indicando os melhores pontos do sistema para implementações de programas de gerenciamento pelo lado da demanda (GLD). A análise é feita através de um modelo de otimização que minimiza os custos de operação dos sistema considerando certas restrições operativas. Este modelo considera ainda, as incertezas associadas a diferentes cenários futuros. A partir das sensibilidades obtidas da solução do problema, ainda é possível se obter o montante ótimo de energia a ser reduzida de forma a tornar algum programa de gerenciamento da demanda viável economicamente para uma companhia de eletricidade. / [en] This work presents a model for load management based on eletric system analysis that identifies the areas or bus with more sensitive to demand reductions, therfore indicating the best points demand side management programs (DSM) impleementations. The analysis is done by a optimzation model that minimizes the electric system operating costs under operation constraints. This model also considers the uncertanly associated to different configurated scenarios. Through the sensitivities calculated by the optimization problem solution, it´s also possible to know the optimum amount of energy to be decreased in order to make any load management program economicaly feasible to an eletric utility.

[pt] ENERGIA

[en] ENERGY

[pt] INCERTEZA

[en] UNCERTAINTY

[pt] GERENCIAMENTO DA DEMANDA

[en] LOAD MANAGEMENT

Design of an Energy Management System Using a Distribution Class Locational Marginal Price as a Discrete Control Signal

January 2013

abstract: The subject of this thesis is distribution level load management using a pricing signal in a Smart Grid infrastructure. The Smart Grid implements advanced meters, sensory devices and near real time communication between the elements of the system, including the distribution operator and the customer. A stated objective of the Smart Grid is to use sensory information to operate the electrical power grid more efficiently and cost effectively. One potential function of the Smart Grid is energy management at the distribution level, namely at the individual customer. The Smart Grid allows control of distribution level devices, including distributed energy storage and distributed generation, in operational real time. One method of load control uses an electric energy price as a control signal. The control is achieved through customer preference as the customer allows loads to respond to a dynamic pricing signal. In this thesis, a pricing signal is used to control loads for energy management at the distribution level. The model for the energy management system is created and analyzed in the z-domain due to the envisioned discrete time implementation. Test cases are used to illustrate stability and performance by analytic calculations using Mathcad and by simulation using Matlab Simulink. The envisioned control strategy is applied to the Future Renewable Electric Energy Distribution Management (FREEDM) system. The FREEDM system implements electronic (semiconductor) controls and therefore makes the proposed energy management feasible. The pricing control strategy is demonstrated to be an effective method of performing energy management in a distribution system. It is also shown that stability and near optimal response can be achieved by controlling the parameters of the system. Addition-ally, the communication bandwidth requirements for a pricing control signal are evaluated. / Dissertation/Thesis / M.S. Electrical Engineering 2013

Electrical engineering

Control

Distribution

Energy management

Load management

Locational Marginal Price

Z domain

Evaluation and Assessment of New Demand Response Products based on the use of Flexibility in Industrial Processes: Application to the Food Industry

Alcázar Ortega, Manuel

25 February 2011

En el marco de un mercado de la electricidad con precios cada vez más altos y donde la participación de fuentes renovables de generación está jugando un papel cada vez más importante, esta tesis supone un enfoque innovador hacia la participación de recursos de demanda en mercados de operación, prestando una atención especial a segmentos industriales como el sector alimentario con un consumo energético intensivo. En primer lugar, esta tesis describe detalladamente la situación actual de los programas de respuesta de la demanda que existen en diferentes partes del mundo. Este estudio permite concluir que los consumidores no han sido tenidos en cuenta suficientemente en la fase de diseño de los programas existentes, lo que ha provocado la infrautilización de recursos de demanda que, actualmente, permanecen sin explorar. Por otro lado, los consumidores no son conscientes del valor que su flexibilidad podría tener para el sistema eléctrico en su conjunto, ignorando que puedan existir otros agentes dispuestos a pagarles a cambio de reducir sus cargas en períodos determinados. Como resultado, esta tesis desarrolla una nueva metodología para explorar y valorar nuevos mecanismos de respuesta de la demanda donde el punto de vista de consumidores, operadores de red y cualquier otro agente interesado pueda ser tenido en cuenta. Esta metodología, basada en la evaluación y análisis detallado de los procesos, proporciona a los consumidores las herramientas adecuadas para evaluar su capacidad para reaccionar al precio de la electricidad, lo que permitiría al regulador poner en valor el beneficio social de dicha flexibilidad si pudiera ser utilizada en mercados de operación, ayudándole a definir los programas necesarios para utilizar de forma adecuada el potencial identificado por los consumidores. La metodología desarrollada en esta tesis ha sido aplicada satisfactoriamente al sub-segmento de la industria cárnica, por lo que varias fábricas pertenecientes a este segmento han sido estudiadas en detalle. En concreto, la factibilidad de las acciones propuestas ha sido probada y validada satisfactoriamente en una fábrica dedicada a la producción de jamón curado en España, en la que se han evaluado diferentes estrategias de flexibilidad. Finalmente, se ha realizado una evaluación económica de la rentabilidad de la aplicación de las acciones de flexibilidad propuestas tanto para el consumidor como para el sistema eléctrico en su conjunto, donde se han considerado los precios reales de los mercados de operación en España, aun cuando los consumidores no puedan participar realmente en dichos mercados en la actualidad. / Alcázar Ortega, M. (2011). Evaluation and Assessment of New Demand Response Products based on the use of Flexibility in Industrial Processes: Application to the Food Industry [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/10078 / Palancia

Demand side management

Food engineering

Load management

Power control

Power demand

Production management

INGENIERIA ELECTRICA

An integrated energy efficiency strategy for deep mine ventilation and refrigeration / Abraham Jacobus Schutte

Schutte, Abraham Jacobus

January 2014

South Africa’s electricity supply is under pressure. Mining is one of South Africa’s largest electricity consumers with electricity-intensive services such as compressed air, cooling, ventilation, etc. More than 40% of mine electricity consumption is used for cooling and ventilation. There is a need to reduce the operational cost on a mine as electricity prices are set to increase at least 2% above South Africa’s inflation target. The mine-cooling and ventilation system was investigated for energy cost-saving. No clear energy and cost-saving strategy for the entire mine-cooling and ventilation system was found. Projects are implemented ad hoc and scattered throughout the system. A strategy is needed to help realise the total saving available on the entire mine-cooling and ventilation system. An implementation strategy for load-management and energy-saving projects on a mine-cooling and ventilation system was developed. A peak clip project on the surface BAC was developed and added to the strategy. The resultant strategy attains all savings throughout the entire mine-cooling and ventilation system. A peak clip project on the surface BAC of a typical mine results in an annual saving of R1.4 million. Implementing this new project on other mines could save R11 million annually. Implementing the sequenced combination of cooperative projects on a typical mine results in a saving of R30 million. That is a saving of 38% on the ventilation and cooling cost and 16% on the total mine electricity bill. / PhD (Mechanical Engineering), North-West University, Potchefstroom Campus, 2014

Strategy

Sequence

Combination

Energy efficiency

Load management

Ventilation

Refrigeration

Surface BAC

Strategie

Volgorde

Kombinasie

Energiedoeltreffendheid

Lasbeheer

Ventilasie

Verkoeling

Grootmaat oppervlaklugverkoelingseenhede

An integrated energy efficiency strategy for deep mine ventilation and refrigeration / Abraham Jacobus Schutte

Schutte, Abraham Jacobus

January 2014

South Africa’s electricity supply is under pressure. Mining is one of South Africa’s largest electricity consumers with electricity-intensive services such as compressed air, cooling, ventilation, etc. More than 40% of mine electricity consumption is used for cooling and ventilation. There is a need to reduce the operational cost on a mine as electricity prices are set to increase at least 2% above South Africa’s inflation target. The mine-cooling and ventilation system was investigated for energy cost-saving. No clear energy and cost-saving strategy for the entire mine-cooling and ventilation system was found. Projects are implemented ad hoc and scattered throughout the system. A strategy is needed to help realise the total saving available on the entire mine-cooling and ventilation system. An implementation strategy for load-management and energy-saving projects on a mine-cooling and ventilation system was developed. A peak clip project on the surface BAC was developed and added to the strategy. The resultant strategy attains all savings throughout the entire mine-cooling and ventilation system. A peak clip project on the surface BAC of a typical mine results in an annual saving of R1.4 million. Implementing this new project on other mines could save R11 million annually. Implementing the sequenced combination of cooperative projects on a typical mine results in a saving of R30 million. That is a saving of 38% on the ventilation and cooling cost and 16% on the total mine electricity bill. / PhD (Mechanical Engineering), North-West University, Potchefstroom Campus, 2014

Strategy

Sequence

Combination

Energy efficiency

Load management

Ventilation

Refrigeration

Surface BAC

Strategie

Volgorde

Kombinasie

Energiedoeltreffendheid

Lasbeheer

Ventilasie

Verkoeling

Grootmaat oppervlaklugverkoelingseenhede