CONDUIT®

CONtrol Designer's Uniﬁed InTerface

CONDUIT® in Aerospace

Figure 1: CONtrol Designer's Uniﬁed InTerface

The CONtrol Designer's Uniﬁed InTerface (CONDUIT^®) is a state-of-the-art computational facility for aircraft ﬂight control design, evaluation, and integration for modern ﬁxed- and rotary-wing aircraft. The CONDUIT^® system employs an interactive graphical user interface to bring together the three areas of aircraft design: dynamics modeling, control law design, and evaluation of aircraft handling qualities speciﬁcations.

CONDUIT^® enables users to:

Perform analysis of aircraft handling qualities
Rapidly display the effects of changes to model or control system dynamics
Optimize designated parameters to tune the system to multiple speciﬁcations
Generate analysis plots for each speciﬁcation

Introduction to CONDUIT^®

The U.S. Army Combat Capabilities Development Command (DEVCOM) Aviation & Missile Center (AvMC) and San José State University Research Foundation (SJSURF) jointly distribute CONDUIT^®, a state-of-the-art computational facility for aircraft ﬂight control design and evaluation. CONDUIT^® provides an environment for design integration and data resources.

Background

The design, integration, and ﬂight test development of ﬂight control systems for modern ﬁxed- and rotary-wing aircraft presents a challenging task that factors signiﬁcantly in aircraft development. Comprehensive speciﬁcations and sophisticated time- and frequency-domain evaluation techniques are applied to ensure desired performance and handling-qualities of modern aircraft, and to minimize ﬂight test tuning. The overlap of ﬂexible airframe modes and high-bandwidth control laws drives the requirement for incorporating increasingly higher-order analytical and identiﬁcation-derived simulation models, and automated gain selection techniques in the control system design process.

The control law design and evaluation for a single design point is made very laborious as a result of the numerous and often competing design speciﬁcations. This process must be repeated for the tens or even hundreds of conﬁguration design points that are evaluated for a full ﬂight envelope control system. Further, the control system design engineer must continually update and integrate improvements in the math models as hardware test data become available. Often, design speciﬁcations are also introduced during the course of aircraft development, which as with the other changes requires control law re-tuning across the ﬂight envelop. Since current tools generally do not facilitate the study of the trade-offs between competing speciﬁcations, hardware characteristics, and performance metrics, the ﬁnal design may not make the best use of available control authority for modern control-conﬁgured vehicles. The failure to consider such trade-offs can compromise control system performance and handling-qualities. Clearly, sophisticated interactive computational tools are needed to integrate these many aspects of the ﬂight control design process.

CONDUIT® Flight Control Engineer

Figure 2: CONDUIT^® — Control Designer's Unified Interface

What is CONDUIT^®?

CONDUIT^® is a sophisticated "associate" that provides comprehensive analysis support and design guidance to a knowledgeable control system designer. CONDUIT^® enables users to deﬁne design speciﬁcations and system models and to perform multi-objective function optimization to tune selected design parameters. The system has been used to successfully exploit trade-offs between design speciﬁcations to signiﬁcantly improve expected handling qualities and has potential for reducing the time and cost of control system ﬂight test optimization.

CONDUIT® System Dashboard

Figure 3: Control System Fight Test Optimization User Interface

Additional Information

CONDUIT® Technical Papers

SALES & OTHER INQUIRIES CONTACT
San José State University Research Foundation
flight-control-sta@sjsu.edu