30 research outputs found
What impact did a Paediatric Early Warning system have on emergency admissions to the paediatric intensive care unit? An observational cohort study
Summary
The ideology underpinning Paediatric Early Warning systems (PEWs) is that earlier recognition of deteriorating in-patients would improve clinical outcomes.
Objective
To explore how the introduction of PEWs at a tertiary children's hospital affects emergency admissions to the Paediatric Intensive Care Unit (PICU) and the impact on service delivery. To compare ‘in-house’ emergency admissions to PICU with ‘external’ admissions transferred from District General Hospitals (without PEWs).
Method
A before-and-after observational study August 2005–July 2006 (pre), August 2006–July 2007 (post) implementation of PEWs at the tertiary children's hospital.
Results
The median Paediatric Index of Mortality (PIM2) reduced; 0.44 vs 0.60 (p < 0.001). Fewer admissions required invasive ventilation 62.7% vs 75.2% (p = 0.015) for a shorter median duration; four to two days. The median length of PICU stay reduced; five to three days (p = 0.002). There was a non-significant reduction in mortality (p = 0.47). There was no comparable improvement in outcome seen in external emergency admissions to PICU. A 39% reduction in emergency admission total beds days reduced cancellation of major elective surgical cases and refusal of external PICU referrals.
Conclusions
Following introduction of PEWs at a tertiary children's hospital PIM2 was reduced, patients required less PICU interventions and had a shorter length of stay. PICU service delivery improved
Numerical approach at non-abelian gauge theory
SIGLELD:D47766/83 / BLDSC - British Library Document Supply CentreGBUnited Kingdo
Neural network identification and control of an underwater vehicle
Real-time predictive control requires a forward model that is both accurate and fast. This paper introduces two nonlinear internal memory network architectures and compares their performance with a Multi-layer Perceptron (MLP) augmented with the use of spread encoding. The test plant is a single component from an Underwater Robotic Vehicle (URV), comprising a thruster encased in a steel frame and provided with buoyancy. This assemblv is free to move under water and is controlled for depth.
The internal memory networks are of comparable accuracy to the MLP but more parsimonious, resulting, in a faster response which makes them better suited for on-line control. Although a particular case study is presented as the focus of this paper, the algorithms and methods developed have generic applicability
Neural Network Modelling and Control for Underwater Vehicles
Neural networks are currently finding practical applications ranging from ‘soft’ regulatory control in consumer products to accurate control of non-linear plant in the process industries. This paper describes the application of neural networks to modelling and control of a prototype underwater vehicle, as an example of a system containing severe non-linearities. The most common implementation strategy for neural control is model predictive control, where a model of the process is developed first and is used off-line to design an appropriate compensator. The accuracy and robustness of this control strategy relies on the quality of the non-linear process model, in particular its ability to predict the plant response accurately multiple-steps ahead. In this paper, several neural network architectures are used to evaluate a long-range model predictive control structure, both in simulation and for on-line control of vehicle depth, achieving accurate control with a smooth actuator signal
Neural Network Based Predictive Control Systems for Underwater Robotic Vehicles
Oceanographic exploration is one of the fast emerging applications of robotics, and the design of controllers for Underwater Robotic Vehicles (URVs) is as challenging as for land based ones. The difficulties in modelling an URV and its hazardous environment restrict the use of conventional controllers. This paper presents an approach for control and system identification of a prototype URV, as an example of a system containing severe non-linearities, using neural networks (NNs). NNs models are developed and then incorporated into a predictive control strategy which are evaluated on-line. Results are shown for both the modelling and control of the system including hybrid control strategies which combine neural predictive with conventional three term controllers
Machine learning in cancer research : implications for personalised medicine
Driven by the growing demand of personalization of medical
procedures, data-based, computer-aided cancer research in human patients
is advancing at an accelerating pace, providing a broadening landscape
of opportunity for Machine Learning methods. This landscape can be
observed from the wide-reaching view of population studies down to the
genotype detail. In this brief paper, we provide a sweeping glimpse, by no
means exhaustive, of the state-of-the-art in this field at the different scales
of data measurement and analysis
Are model-based clustering and neural clustering consistent? A case study from bioinformatics
A novel neural network clustering algorithm, CoRe, is benchmarked against previously published results on a breast cancer data set and applying the method of Partition Around Medoids (PAM). The data serve to compare the samples partitions obtained with the neural network, PAM and model-based algorithms, namely Gaussian Mixture Model (GMM), Variational Bayesian Gaussian Mixture (VBG) and Variational Bayesian Mixtures with Splitting (VBS). It is found that CoRe, on the one hand, agrees with the previously published partitions; on the other hand, it supports the existence of a supplementary cluster that we hypothesize to be an additional tumor subgroup with respect to those previously identified by PAM