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Themes - Training in the Transformation Process -- Challenges to the Training System of the Air Force
In: Europäische Sicherheit: Politik, Streitkräfte, Wirtschaft, Technik, Band 55, Heft 4, S. 40-45
ISSN: 0940-4171
TRAINING FOR THE OPERATIONAL LEVEL
In: Parameters: the US Army War College quarterly, Band 16, Heft 1
ISSN: 2158-2106
Simulation of Operational Equipment with a Computer-based Instructional System: A Low Cost Training Technology
In: Human factors: the journal of the Human Factors Society, Band 20, Heft 2, S. 215-223
ISSN: 1547-8181
The feasibility and effectiveness of teaching performance skills using a computer-based training (CBT) methodology were investigated. Graphic simulations of the appearance and functions of a system in an anti-submarine aircraft were presented to students within an instructional framework. Programmed logics controlled the dynamic representations of the equipment in response to student input made through a touch panel. The objective was to determine whether CBT could be used for low cost, part-task training. The performance of CBT students, as measured on a high fidelity simulator, was compared to that of students who had gone through conventional training consisting of workbook study and hands-on practice in the simulator. Results showed that CBT students performed the necessary skills as well before practice in the simulator as conventionally trained students could after this practice. The theoretical and cost implications are discussed.
Operational research in weapon system
"The paper is divided into three parts: (a) The first part deals with what operational research is. (b)The second part gives what we mean by Weapon Systems and discusses considerations that determine the choice of a particular weapon system from a class weapon systems. (c)The third part deals with some aspects of weapon replacement policy.The effectiveness of a weapon system is defined as E=D/C where E is weapon effectiveness (a comparative figure of merit); D is total damage inflicted or prevented and C is total cost, D and C being reduced to common dimensions. During the course of investigations, criteria regarding to choice of weapon or weapons from a set of weapon systems are established through production function and military effect curves. A procedure is described which maximizes the expectation of military utility in order to select a weapon system from the class of weapon systems. This is done under the following simplifying assumptions: (a) Non- decreasing utility function; (b) Constant average cost for each kind of weapons; and (c) Independence of the performance of each unit of weapon. Some of the difficulties which arises when any of these restrictions is relaxed are briefly mentioned. Finally, the policy of weapon replacement and the factors governing the same are described."
BASE
The transformation of the defense innovation system: knowledge bases, disruptive technologies, and operational capabilities
International audience ; The forces that drive much of the transformation of Defense Innovation Systems are manifold. The economic structure and institutional organization supporting defense innovation have been altered by technological as well as political changes. Increasing competitive pressures, together with the growing complexity of knowledge and technology have also shaped how defense companies, military services and procurement agencies adapted their core business models, competences, and strategies in order to be capable of providing their customers with the innovative products and services they need. This contribution builds on a ISTE-Wiley edition's recently published book untitled Disruptive Technology and Defence Innovation Ecosystems ([BAR 19b]) that aimed at improving our understanding of the transformation ofdefense innovation systems, by focusing on three interrelated dimensions. The first dimension is concerned with changes affecting defense-related knowledge bases, in particular the development of dual-use knowledge and the increasing complexity of defense-related knowledge structures. The second dimension is related to technology itself with a particular emphasis on the disruptive impacts of certain technological trajectories emerging from the outside of traditional boundaries of the defense industrial base. The third dimension is connected to the evolution of military customers' doctrines and capabilities towards netcentricity and multi-domains command and control (C²), the latter having a structuring effect on defense innovation systems.
BASE
Wyeth Pharmaceuticals in 2009: Operational Transformation
In: Darden Case No. UVA-OM-1400
SSRN
Training of Employees of the Justice System in the Context of Transformations in Modern Russia
In: Teorija i praktika obščestvennogo razvitija: meždunarodnyj naučnyj žurnal : sociologija, ėkonomika, pravo, Heft 7, S. 112-116
ISSN: 2072-7623
Training in Operational Command For Fire Services
In: Modern simulation & training: MS & T ; the international training journal, Heft 6, S. 20-29
ISSN: 0937-6348
Training & Education Design in the Context of Operational Art
In: Marine corps gazette: the Marine Corps Association newsletter, Band 94, Heft 10, S. 16-22
ISSN: 0025-3170
Operational Sequence Diagrams in System Design
In: Human factors: the journal of the Human Factors Society, Band 3, Heft 1, S. 66-73
ISSN: 1547-8181
Operational sequence diagrams pictorially display information-decision-action sequences within a man-machine system. In its various versions as a time-sequence process chart, a spatial flow chart, and as an adjunct to symbolic logic, the OSD can he used in establishing system requirements, allocating man-machine functions, determining sequence of operations, and in evaluating equipment layouts.