Genre
ip Report 83 20 The Utility of Level Effort . Stanford Jeffrey S. Singh Mar 1983 II
Meta-level control, in an Artificial Intelligence system, can provide increased capabilities and improved performanct. This improvement, however, is achieved at the cost of the meta-level effort itself. To ensure an overall increase in system efficiency, the savings brought about at the base level cannot be exceeded by the effort at the meta-level. This paper outlines a formalization of the costs involved in choosing between independent problem-solving methods: the cost of meta-level control is explicitly included. It is shown that when meta-level effort is related to its efficacy, there exists an amount of this effort that should optimally be expended. Too much or too little meta -le-,e1 effort can result in a loss of overall system performance.
Integration of A Computer-Based Consultant Into the Clinical Setting Miriam B. BischofT, Edward H. Shortliffe, A. Carlisle Scottl, Robert W. Carlson, and Charlotte D. Jacobs
ONCOC1N's design and implementation has occurred in unison with a set of studies and analyses Intended to help us better understand the demands of physicians as computer users. Our study of physician attitudes towards computer-based clinical consultation systems 112: emphasized the importance of a system's explanation capabilities and helped convince us of the important role that Al techniques are likely to play in the development of optimal decision aids.
The Science of Biomedical Computing
This is a remarkab'y exciting time to be involved professionally in the field of medical informatics. The underlying scientific principles are beginning to be identified and defined, educators are increasingly acknowledging the importance of thc field for physicians of the present and future, and the tec mology itself is growing at rates that make the future of the field both unbounded and impossible to predict. One has the sense that what was once a field for pioneers is now reaching the stage of established settlements, with a history, traditions, and a feel of permanence. It is therefore appropriate that, at the beginning of ddiberations designed to achieve significant educational goals for the field, we might start by considering the discipline itself and the characteristics that hnve tended to separate it from other traditional academic and research medical specialties. I would like to begin by assuming that certain basic points are well accepted and need not be defended here: first that medical informatics holds both realized and potential importance for the science anc practice of medicine, and second, that there is a need for all medical practitioners to be familiar both with information handling technology and with the underlying principles that make the field relevant, regardless of whether computers are involved.
Knowledge-Based Simulation of Genetic Regulation in Bacteriophage Lambda. Scott Meyers, Peter Friedland, Aug 1983 card 1 of 1
Simuldtois serve two major purposes: the first is the verification of scientific thP.ories the second is xperimental result prcliction. Thr? verification function is called upon when existing t:leories are btling cxtended or new theories are being ç enerated to explain experimental data: the predictive capabilities are used to predict laboratory results in order to eliminate a great deal of experimmtal effort. An esoecially important role for a simulation pro.warn would be as par; of a larger employing art ficial innelligence techniques to develop mcd.els of a biological system bar:ed on experimental OUSerwitiOris. Such a program would accept as Input observations of a s; stem cud would!fiocii:ce as output a model for tn.t system that could account for the observations. The r.:niu!ation portion of such a program would be a crucial tool for ensuring that on:y theories mat were con::..-4 with thc data were dewloocci. It's a major research goal Cf the HOLDEN pi met to explore methods tor building a systym