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The Hedgehog signalling pathway regulates autophagy (2012)

Maria Jimenez-Sanchez; Fiona M. Menzies; Yu-Yun Chang; Nikol Simecek; Thomas P. Neufeld; David C. Rubinsztein

Springer Nature

In: Nature Communications

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Publication Date: 2012-11-15

Description: The Hedgehog signalling pathway regulates autophagy Nature Communications 3, 1200 (2012). doi:10.1038/ncomms2212 Authors: Maria Jimenez-Sanchez, Fiona M. Menzies, Yu-Yun Chang, Nikol Simecek, Thomas P. Neufeld & David C. Rubinsztein

Electronic ISSN: 2041-1723

Topics: Biology , Chemistry and Pharmacology , Natural Sciences in General , Physics

Published by Springer Nature

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Development and flight test of a deployable precision landing system (1994)

Sim, Alex G. ; Reed, R. Dale ; Murray, James E. ; [et al.]

In: Other Sources

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Publication Date: 2011-08-24

Description: A joint NASA Dryden Flight Research Facility and Johnson Space Center program was conducted to determine the feasibility of the autonomous recovery of a spacecraft using a ram-air parafoil system for the final stages of entry from space that included a precision landing. The feasibility of this system was studied using a flight model of a spacecraft in the generic shape of a flattened biconic that weighed approximately 150 lb and was flown under a commercially available, ram-air parachute. Key elements of the vehicle included the Global Positioning System guidance for navigation, flight control computer, ultrasonic sensing for terminal altitude, electronic compass, and onboard data recording. A flight test program was used to develop and refine the vehicle. This vehicle completed an autonomous flight from an altitude of 10,000 ft and a lateral offset of 1.7 miles that resulted in a precision flare and landing into the wind at a predetermined location. At times, the autonomous flight was conducted in the presence of winds approximately equal to vehicle airspeed. Several novel techniques for computing the winds postflight were evaluated. Future program objectives are also presented.

Keywords: AIRCRAFT COMMUNICATIONS AND NAVIGATION

Type: Journal of Aircraft (ISSN 0021-8669); 31; 5; p. 1101-1108

Format: text

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The development and flight test of a deployable precision landing system for spacecraft recovery (1993)

Murray, James E. ; Sim, Alex G. ; Neufeld, David C. ; [et al.]

In: CASI

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Publication Date: 2019-06-28

Description: A joint NASA Dryden Flight Research Facility and Johnson Space Center program was conducted to determine the feasibility of the autonomous recovery of a spacecraft using a ram-air parafoil system for the final stages of entry from space that included a precision landing. The feasibility of this system was studied using a flight model of a spacecraft in the generic shape of a flattened biconic which weighed approximately 150 lb and was flown under a commercially available, ram-air parachute. Key elements of the vehicle included the Global Positioning System guidance for navigation, flight control computer, ultrasonic sensing for terminal altitude, electronic compass, and onboard data recording. A flight test program was used to develop and refine the vehicle. This vehicle completed an autonomous flight from an altitude of 10,000 ft and a lateral offset of 1.7 miles which resulted in a precision flare and landing into the wind at a predetermined location. At times, the autonomous flight was conducted in the presence of winds approximately equal to vehicle airspeed. Several techniques for computing the winds postflight were evaluated. Future program objectives are also presented.

Keywords: SPACE TRANSPORTATION

Type: NASA-TM-4525 , H-1933 , NAS 1.15:4525

Format: application/pdf

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4

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Further development and flight test of an autonomous precision landing system using a parafoil (1994)

Hughes, Wesley S. ; Neufeld, David C. ; Murray, James E. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: NASA Dryden Flight Research Center and NASA Johnson Space Center are jointly conducting a phased program to determine the feasibility of the autonomous recovery of a spacecraft using a ram-air parafoil system for the final stages of entry from space to a precision landing. The feasibility is being studied using a flight model of a spacecraft in the generic shape of a flattened biconic that weighs approximately 120 lb and is flown under a commercially available ram-air parafoil. Key components of the vehicle include the global positioning system (GPS) guidance for navigation, a flight control computer, an electronic compass, a yaw rate gyro, and an onboard data recorder. A flight test program is being used to develop and refine the vehicle. The primary flight goal is to demonstrate autonomous flight from an altitude of 3,000 m (10,000 ft) with a lateral offset of 1.6 km (1.0 mi) to a precision soft landing. This paper summarizes the progress to date. Much of the navigation system has been tested, including a heading tracker that was developed using parameter estimation techniques and a complementary filter. The autoland portion of the autopilot is still in development. The feasibility of conducting the flare maneuver without servoactuators was investigated as a means of significantly reducing the servoactuator rate and load requirements.

Keywords: AERODYNAMICS

Type: NASA-TM-4599 , H-1987 , NAS 1.15:4599 , AIAA PAPER 94-2141 , Biennial Flight Test Conference; Jun 20, 1994 - Jun 23, 1994; Colorado Springs, CO; United States

Format: application/pdf

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Strain Gage Loads Calibration Testing with Airbag Support for the Gulfstream III SubsoniC Research Aircraft Testbed (SCRAT) (2015)

Haraguchi, Ronnie ; Holguin, Andrew C. ; Hudson, Larry D. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: This paper describes the design and conduct of the strain-gage load calibration ground test of the SubsoniC Research Aircraft Testbed, Gulfstream III aircraft, and the subsequent data analysis and results. The goal of this effort was to create and validate multi-gage load equations for shear force, bending moment, and torque for two wing measurement stations. For some of the testing the aircraft was supported by three airbags in order to isolate the wing structure from extraneous load inputs through the main landing gear. Thirty-two strain gage bridges were installed on the left wing. Hydraulic loads were applied to the wing lower surface through a total of 16 load zones. Some dead-weight load cases were applied to the upper wing surface using shot bags. Maximum applied loads reached 54,000 lb. Twenty-six load cases were applied with the aircraft resting on its landing gear, and 16 load cases were performed with the aircraft supported by the nose gear and three airbags around the center of gravity. Maximum wing tip deflection reached 17 inches. An assortment of 2, 3, 4, and 5 strain-gage load equations were derived and evaluated against independent check cases. The better load equations had root mean square errors less than 1 percent. Test techniques and lessons learned are discussed.

Keywords: Aircraft Design, Testing and Performance

Type: DFRC-E-DAA-TN18904 , SciTech 2015; Jan 05, 2015 - Jan 09, 2015; Kissimmee, FL; United States

Format: application/pdf

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