71 research outputs found
Ebola and Marburg Hemorrhagic Fevers: Neglected Tropical Diseases?
Ebola hemorrhagic fever (EHF) and Marburg hemorrhagic fever (MHF) are rare viral
diseases, endemic to central Africa. The overall burden of EHF and MHF is small
in comparison to the more common protozoan, helminth, and bacterial diseases
typically referred to as neglected tropical diseases (NTDs). However, EHF and
MHF outbreaks typically occur in resource-limited settings, and many aspects of
these outbreaks are a direct consequence of impoverished conditions. We will
discuss aspects of EHF and MHF disease, in comparison to the
âclassicâ NTDs, and examine potential ways forward in the prevention
and control of EHF and MHF in sub-Saharan Africa, as well as examine the
potential for application of novel vaccines or antiviral drugs for prevention or
control of EHF and MHF among populations at highest risk for disease
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A virtual control panel configuration tool for the X-window system
Computer Graphics Workstations are becoming increasingly popular for use as virtual process control and read back panels. The workstations's CRT, keyboard, and pointing device are used in concert to produce a display that is in essence a control panel, even if actual switches and gauges are not present. The code behind these displays is most often specific to one display and not reusable for any other display. Recently, programs have been written allowing many of these virtual control panel displays to be configured without writing additional code. This approach allows the initial programming effort to be reapplied to many different display instances with minimal effort. These programs often incorporate many of the features of a graphics editor, allowing a pictorial model of the process under control to be incorporated into the control panel. We have just finished writing a second generation software system of this type for use with the X-window system and the Experimental Physics and Industrial Control System (EPICS). This paper describes the primary features of our software, the framework of our design, and our observations after initial installation
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A Transient Tolerant Automated Control System for the LEDA 75kV Injector
The Low-Energy Demonstration Accelerator (LEDA) injector is designed to inject 75-keV, 110-mA, proton beams into the LEDA RFQ. The injector operation has been automated to provide long term, high availability operation using the Experimental Physics and Industrial Control System (EPICS). Automated recovery from spark-downs demands reliable spark detection and sequence execution by the injector controller. Reliable computer control in the high-energy transient environment required transient suppression and isolation of hundreds of analog and binary data lines connecting the EPICS computer controller to the injector and it's power supplies and diagnostics. A transient suppression design based on measured and modeled spark transient parameters provides robust injector operation. This paper describes the control system hardware and software design, implementation and operational performance
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