Neuro-symbolic model for real-time forecasting problems

Corchado Rodríguez, Juan Manuel

January 2000

No description available.

621.3994

Mapping sub-pixel variation in land cover at the global scale using NOAA AVHRR imagery

Embashi, Mohamed Rashed Mohamed

January 1998

No description available.

621.3994

Inexact analogue CMOS neurons for VLSI neural network design

Voysey, Matthew David

January 1998

No description available.

621.3192

Intelligent hybrid approach for integrated design

Wakelam, Mark

January 1998

No description available.

620.0042029

Connectionist feedforward networks for control of nonlinear systems

Hofer, Daniel G. Sbarbaro

January 1992

No description available.

629.8

An investigation of task level programming for robotic assembly

Howarth, Martin

January 1998

No description available.

629.892

Adaptive compensation for errors due to flexibility in mechanical systems

Kabiri, Peyman

January 2000

No description available.

629.892

Neuron to symbol : relevance information in hybrid systems

Johnson, Geraint

January 1997

No description available.

005

A recurrent neural network approach to quantification of risks surrounding the Swedish property market

Vikström, Filip

January 2016

As the real estate market plays a central role in a countries financial situation, as a life insurer, a bank and a property developer, Skandia wants a method for better assessing the risks connected to the real estate market. The goal of this paper is to increase the understanding of property market risk and its covariate risks and to conduct an analysis of how a fall in real estate prices could affect Skandia’s exposed assets.This paper explores a recurrent neural network model with the aim of quantifying identified risk factors using exogenous data. The recurrent neural network model is compared to a vector autoregressive model with exogenous inputs that represent economic conditions.The results of this paper are inconclusive as to which method that produces the most accurate model under the specified settings. The recurrent neural network approach produces what seem to be better results in out-of-sample validation but both the recurrent neural network model and the vector autoregressive model fail to capture the hypothesized relationship between the exogenous and modeled variables. However producing results that does not fit previous assumptions, further research into artificial neural networks and tests with additional variables and longer sample series for calibration is suggested as the model preconditions are promising.

Artificial neural networks

Machine learning

RNN

Development of a fault location method based on fault induced transients in distribution networks with wind farm connections

Lout, Kapildev

January 2015

Electrical transmission and distribution networks are prone to short circuit faults since they span over long distances to deliver the electrical power from generating units to where the energy is required. These faults are usually caused by vegetation growing underneath bare overhead conductors, large birds short circuiting the phases, mechanical failure of pin-type insulators or even insulation failure of cables due to wear and tear, resulting in creepage current. Short circuit faults are highly undesirable for distribution network companies since they cause interruption of supply, thus affecting the reliability of their network, leading to a loss of revenue for the companies. Therefore, accurate offline fault location is required to quickly tackle the repair of permanent faults on the system so as to improve system reliability. Moreover, it also provides a tool to identify weak spots on the system following transient fault events such that these future potential sources of system failure can be checked during preventive maintenance. With these aims in mind, a novel fault location technique has been developed to accurately determine the location of short circuit faults in a distribution network consisting of feeders and spurs, using only the phase currents measured at the outgoing end of the feeder in the substation. These phase currents are analysed using the Discrete Wavelet Transform to identify distinct features for each type of fault. To achieve better accuracy and success, the scheme firstly uses these distinct features to train an Artificial Neural Network based algorithm to identify the type of fault on the system. Another Artificial Neural Network based algorithm dedicated to this type of fault then identifies the location of the fault on the feeder or spur. Finally, a series of Artificial Neural Network based algorithms estimate the distance to the point of fault along the feeder or spur. The impact of wind farm connections consisting of doubly-fed induction generators and permanent magnet synchronous generators on the accuracy of the developed algorithms has also been investigated using detailed models of these wind turbine generator types in Simulink. The results obtained showed that the developed scheme allows the accurate location of the short circuit faults in an active distribution network. Further sensitivity tests such as the change in fault inception angle, fault impedance, line length, wind farm capacity, network configuration and white noise confirm the robustness of the novel fault location technique in active distribution networks.

621.3815