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2016, vol. 64, br. 3, str. 838-849
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Implementacija upravljanja petoosnim simulatorom leta rakete i cilja u otvorenoj petlji
Open loop control of the five-axis missile and target flight motion simulator implementation
Sažetak
Razvoj raketnih sistema podrazumeva važne faze testiranja i simulacije leta rakete u uslovima okruženja koje diktira operacija za koju je sistem izrađen. Kako terenska ispitivanja ovako složenih sistema zahtevaju veliki utrošak finansijskih resursa, a i mnogo vremena, simulacije koje podrazumevaju hardver u petlji (Hardware in the loop - HIL) predstavljaju vrlo efikasno rešenje za smanjenje troškova razvoja i testiranja. U ovom radu predstavljena je implementacija upravljanja, odnosno sinhronizovanog generisanja i akvizicije podataka na petoosnom simulatoru leta rakete i cilja laboratorije za hardver u petlji (HIL laboratorije). Opisana aplikacija za simulaciju javila se kao rezultat potrebe inženjera razvoja raketa za jednostavnim načinom akviziranja informacja o odzivu realne rakete na željena i zadata upravljanja. Rešenje je realizovano u LabVIEW softverskom paketu primenom robusne arhitekture softvera, takozvane klasične mašine stanja.
Abstract
An important phase in missile systems development is flight testing and simulation in the environmental conditions dictated by the operation the system is made for. Since field testing of complex systems means a big financial burden and a time consuming process, hardware in the loop (HIL) simulations represent a very effective solution for saving both costs and time. This paper presents an implementation of a control application that integrates synchronized data generation and acquisition on the five-axis missile and target flight motion simulator owned by the HIL laboratory. The described simulation application is a result of a missile development engineer's need for a simple way to acquire information on a real missile response, when desired control signals are provided. The solution is realized in Lab VIEW software using a robust software design architecture named 'classic state machine'.
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