Search

Your search keyword '"Chris L. Blanken"' showing total 8 results
Start Over Author "Chris L. Blanken"
8 results on '"Chris L. Blanken"'

1. Tiltrotor Flight Control Design and High-Speed Handling Qualities Assessment

Author

Tom Berger, Chris L. Blanken, Jeff A. Lusardi, Mark B. Tischler, and Joseph F. Horn

Abstract

To provide the government with independent control-system design, handling qualities analysis, and simulation research capabilities in support of Future Vertical Lift, the U. S. Army Combat Capabilities Development Command Aviation & Missile Center has developed generic high-fidelity flight-dynamics models of several advanced high-speed rotorcraft configurations including a tiltrotor. Full flight envelope explicit model following control laws were designed for the generic tiltrotor using a multiobjective optimization approach to meet a comprehensive set of stability, handling qualities, and performance specifications. Helicopter response types were used for hover/low-speed, while typical fixed-wing response types (normal acceleration and sideslip command) were used at high speed. The control laws were evaluated in a piloted simulation experiment at the NASA Ames Vertical Motion Simulator using a series of previously developed high-speed handling qualities demonstration maneuvers. This paper discusses the control laws and the results of the piloted handling qualities assessment which show overall assigned Level 1 handling qualities in high-speed and Level 2 in transition.

Published
2022

2. Coaxial-Compound Helicopter Flight Control Design and High-Speed Handling Qualities Assessment

Author

Tom Berger, Chris L. Blanken, Jeff A. Lusardi, Mark B. Tischler, and Joseph F. Horn

Subjects
ComputerApplications_COMPUTERSINOTHERSYSTEMS
Abstract

To provide the government with independent control-system design, handling qualities analysis, and simulation research capabilities in support of Future Vertical Lift, the U. S. Army Combat Capabilities Development Command Aviation & Missile Center has developed generic high-fidelity flight-dynamics models of several advanced high-speed rotorcraft configurations. One of the configurations modeled is a lift offset coaxial-compound helicopter with a pusher propeller. Full flight envelope explicit model following control laws were designed for the generic coaxial-compound helicopter using a multiobjective optimization approach to meet a comprehensive set of stability, handling qualities, and performance specifications. Helicopter response types were used for hover/low-speed, while typical fixed-wing response types (normal acceleration and sideslip command) were used at high speed. The control laws were evaluated in a piloted simulation experiment at the NASA Ames Vertical Motion Simulator using a series of previously developed high-speed handling qualities demonstration maneuvers. This paper discusses the control laws and the results of the piloted handling qualities assessment, which showed assigned Level 1 handling qualities for six of the seven maneuvers evaluated.

Published
2022

3. Piloted Simulation Evaluation of Tracking Mission Task Elements for the Assessment of High-Speed Handling Qualities

Author

Joseph F. Horn, James Rigsby, Ltc Carl Ott, P. Chase Schulze, Ray Mulato, Frank Conway, Cody Fegely, Roy Brewer, Chris L. Blanken, David H. Klyde, Sean P. Pitoniak, William C. Fell, Paul Ruckel, and Hong Xin

Subjects
Computer science, Real-time computing, Tracking (particle physics), Task (project management)
Abstract

Updates to the military rotorcraft handling qualities specification are currently being considered that address the high-speed flight regime envisioned for the Future Vertical Lift platform of the U. S. Army. A team that features industry and academia has developed and evaluated a set of mission task elements (MTEs) that are defined to address vertical takeoff and landing (VTOL) high-speed handling qualities. Following the mission-oriented approach upon which ADS-33E-PRF is based, the MTEs were designed to meet different levels of precision and aggressiveness. Tracking MTEs based on a sum-of-sines (SOS) command signal were defined for precision, aggressive, and precision, nonaggressive applications. The command signals were derived from fixed-wing analogs that have long been used to evaluate aircraft handling qualities. While the precision, aggressive SOS tracking tasks, the primary subject of this paper, are surrogates for air-to-air tracking and nap-of-the-earth tracking, the known forcing function allows for complete open- and closed-loop pilot—vehicle system identification. The MTE objectives, descriptions, and performance criteria were assessed and refined via several checkout piloted simulation sessions. Formal evaluations were then conducted by Army test pilots at four simulator facilities, each featuring a unique high-speed platform including a generic winged-compound helicopter, two tiltrotor configurations, and a compound helicopter with coaxial rotors. To aid in the MTE evaluation process, baseline VTOL configurations were varied to achieve different handling qualities levels. Quantitative measures based on task performance and qualitative measures based on pilot ratings, comments, and debrief questionnaires were used to assess MTE effectiveness. The piloted simulation results demonstrated that the SOS tracking MTEs provided an effective means to discern precision, aggressive handling qualities in high-speed flight.

Published
2020

6. Flight Testing the ADS-33E Cargo Helicopter Handling Qualities Requirements Using a CH-53G

Author

Marc T. Hoefinger and Chris L. Blanken

Subjects
ADS-33, Engineering, CH-53, Aeronautics, business.industry, Handling Qualities, Rotorcraft, flight test, Design standard, Hubschrauber, business, Flight test, helicopter
Abstract

Flight tests with a German Army Sikorsky CH-53G helicopter were performed to evaluate the applicability and repeatability of the U.S. Army's Aeronautical Design Standard (ADS)-33E-PRF cargo helicopter handling qualities requirements. The objectives were to corroborate earlier findings and to propose modifications if deemed necessary. The CH-53G was chosen because it is the largest helicopter operated by the German Army, and its dedicated role is cargo and troop transport. The quantitative criteria and the associated boundaries as specified in the standard were largely confirmed. Several flight test maneuvers were revised and tailored. Generally, the heights for performing the near-earth maneuvers were increased. The time/tolerances experienced were borderline desired/adequate or adequate.

Published
2013

7. Investigation of the Effects of Bandwidth and Time Delay on Helicopter Roll‐Axis Handling Qualities

Author

Chris L. Blanken and Heinz-Ju¨rgen Pausder

Subjects
Time delays, Task (computing), Aeromechanics, Computer science, Cooperative research, Range (aeronautics), Band width, Bandwidth (computing), Simulation, Group delay and phase delay
Abstract

Several years of cooperative research conducted under the U.S./German Memorandum of Understanding (MOU) in helicopter aeromechanics have recently resulted in a successful handling qualities study. The focus of this cooperative research has been the effect of time delays in a high bandwidth vehicle on handling qualities. The jointly performed study included the use of U.S. ground-based simulation and German in-flight simulation facilities. The NASA-Ames Vertical Motion Simulator (VMS) was used to develop a high bandwidth slalom tracking task which took into consideration the constraints of the facilities. The VMS was used to define a range of the test parameters and to perform initial handling qualities evaluations. The flight tests were conducted using DLR's variable-stability BO 105 S3 Advanced Technology Testing Helicopter System (ATTHeS). Configurations included a rate command and an attitude command response system with added time delays of up to 160 milliseconds over the baseline and band width values between 1.5 and 4.5 rad/sec. Sixty-six evaluations were performed in about 25 hours of flight time during ten days of testing. The results indicate a need to more tightly constrain the allowable roll axis phase delay for the Level 1 and Level 2 requirements in the U.S. Army's specification for helicopter handling qualities Aeronautical Design Standard (ADS)-33C.

Published
1994

Catalog

Books, media, physical & digital resources
See catalog results