Your search keyword '"DALY, MICHAEL"' showing total 11 results

1. Bennu Shape Model Validation Model and Results

Author

Lauretta, Dante, Seabrook, Jeff, Daly, Michael, Barnouin, Olivier, Velez, Dianna, Rush, Brian, Mastrodemos, Nickolaos, Kennedy, Brian, Bellerose, Julie, and Lubey, Daniel P

Published

2021

2. Bennu Shape Model Validation Model and Results

Author

Lubey, Daniel P, Bellerose, Julie, Kennedy, Brian, Mastrodemos, Nickolaos, Rush, Brian, Velez, Dianna, Barnouin, Olivier, Daly, Michael, Seabrook, Jeff, and Lauretta, Dante

Published

2021

3. Bennu Shape Model Validation Model and Results

Author

Lauretta, Dante, Seabrook, Jeff, Daly, Michael, Barnouin, Olivier, Velez, Dianna, Rush, Brian, Mastrodemos, Nickolaos, Kennedy, Brian, Bellerose, Julie, and Lubey, Daniel P

Published

2020

4. Bennu Shape Model Validation Model and Results

Author

Lubey, Daniel P, Bellerose, Julie, Kennedy, Brian, Mastrodemos, Nickolaos, Rush, Brian, Velez, Dianna, Barnouin, Olivier, Daly, Michael, Seabrook, Jeff, and Lauretta, Dante

Published

2020

5. Bennu Shape Model Validation Methods and Results

Author

Lauretta, Dante S, Seabrook, Jeff A, Daly, Michael G, Barnouin, Olivier S, Velez, Dianna, Rush, Brian, Mastrodemos, Nikolaos, Kennedy, Brian M, Bellerose, Julie, and Lubey, Daniel P

Abstract

The OSIRIS-REx Independent Shape Modeling Team, staffed by the Jet Propulsion Laboratory (JPL), has used stereophotoclinometry (SPC) to produce a three-dimensional shape model of Bennu. The SPC process is informed by (but is separate from) orbit determination, so it is important to ensure that the resulting shape model is consistent with all available spacecraft tracking data. Specifically, checking the shape model’s consistency with LIDAR measurements can illuminate any discrepancies, because LIDAR measurements are highly correlated with the shape model. This study focuses on the JPL experience with these LIDAR measurements and the greater context of the shape model validation process.

Published

2020

6. Bennu Shape Model Validation Methods and Results

Author

Lubey, Daniel P, Bellerose, Julie, Kennedy, Brian M, Mastrodemos, Nikolaos, Rush, Brian, Velez, Dianna, Barnouin, Olivier S, Daly, Michael G, Seabrook, Jeff A, and Lauretta, Dante S

Published

2020

7. OSIRIS-REx Encounters Bennu: Initial Assessment from the Approach Phase

Author

Lauretta, Dante S, Barnouin, Olivier S, Becker, Kris, Bennett, Carina A, Bierhaus, Beau, Boynton, William V, Burke, Keara N, Christensen, Philip R, Clark, Beth, Jr, Harold C. Connolly, Crombie, Mary, Daly, Michael G, DellaGiustina, Daniella N, Dworkin, Jason P, Emery, Joshua P, Enos, Heather L, Golish, Dathon R, Hamilton, Victoria E, Hergenrother, Carl, Corre, Lucille Le, Lim, Lucy F, Michel, Patrick, Nolan, Michael C, Pajola, Maurizio, Perry, Mark E, Reuter, Dennis, Rizk, Bashar, Scheeres, Daniel Jay, Schwartz, Stephen R, Simon, Amy A, and Walsh, Kevin John

Subjects

Astronomy

Abstract

The OSIRIS-REx spacecraft launched on September 8, 2016, on a seven-year journey to return samples from asteroid (101955) Bennu. This presentation summarizes the scientific results from the Approach and Preliminary Survey phases. Bennu observations are set to begin on August 17, 2018,when the asteroid is bright enough for detection by the PolyCam. PolyCam and MapCam collect data to survey the asteroid environment for any hazards and characterize the asteroid point-source photometric properties. Resolved images acquired during final approach, starting in late October 2018, allow the creation of a shape model using stereophotoclinometry (SPC), needed by both the navigation team and science planners. The OVIRS and OTES spectrometers characterize the point- source spectral properties over a full rotation period, providing a first look at any features and thermophysical properties. TAGSAM is released from the launch container and deployed into the sampling configuration then returned to the stow position.Preliminary Survey follows the Approach Phase in early December 2018. This phase consists of a series of hyperbolic trajectories that cross over the North and South poles and the equator of Bennu at a close-approach distance of 7 km. Images from these Preliminary Survey passes provide data to complete the 75-cm resolution SPC global shape model and solve for the rotation state. Once the shape model is complete, the asteroid coordinate system is defined for co-registration of all data products. These higher-resolution images also constrain the photometric properties and allow for an initial assessment of the geology. In Preliminary Survey the team also obtains the first OLA data, providing a measure of the surface topography. OVIRS and OTES collect data as "ride-along" instruments, with the spacecraft pointing driven by imaging constraints. These data provide a first look at the spectral variation across the surface of Bennu. Radio science measurements, combined with altimetry and imagery, determine Bennu's mass, a prerequisite to placing the spacecraft into orbit in late December 2018. Together, data from the Approach and Preliminary Survey phases set the stage for the extensive mapping planned for 2019. These dates are the baseline plan. Any contingency or unexpected discovery may change this mission profile.

Published

2018

8. Overview of Primitive Object Volatile Explorer (PrOVE) CubeSat or Smallsat Concept

Author

Clark, Pamela S, Hewagama, Tilak, Aslam, Shahid, Bauer, James, and Daly, Michael

Subjects

Spacecraft Design, Testing And Performance

Abstract

Here we describe the Primitive Object Volatile Explorer (PrOVE), a smallsat mission concept to study the surface structure and volatile inventory of comets in their perihelion passage phase when volatile activity is near peak. CubeSat infrastructure imposes limits on propulsion systems, which are compounded by sensitivity to the spacecraft disposal state from the launch platform and potential launch delays. We propose circumventing launch platform complications by using waypoints in space to park a deep space SmallSat or CubeSat while awaiting the opportunity to enter a trajectory to flyby a suitable target. In our Planetary Science Deep Space SmallSat Studies (PSDS3) project, we investigated scientific goals, waypoint options, potential concept of operations (ConOps) for periodic and new comets, spacecraft bus infrastructure requirements, launch platforms, and mission operations and phases. Our payload would include two low-risk instruments: a visible image (VisCAM) for 5-10 m resolution surface maps; and a highly versatile multispectral Comet CAMera (ComCAM) will measure 1) H2O, CO2, CO, and organics non-thermal fluorescence signatures in the 2-5 μm MWIR, and 2) 7-10 and 8-14 μm thermal (LWIR) emission. This payload would return unique data not obtainable from ground-based telescopes and complement data from Earth-orbiting observatories. Thus, the PrOVE mission would (1) acquire visible surface maps, (2) investigate chemical heterogeneity of a comet nucleus by quantifying volatile species abundance and changes with solar insolation, (3) map the spatial distribution of volatiles and determine any variations, and (4) determine the frequency and distribution of outbursts.

Published

2018

9. Overview of Primitive Volatile Explorer (PrOVE) Cubesat or Smallsat Concept

Author

Clark, Pamela, Hewagama, Tilak, Aslam, Shahid, Daly, Michael, Feaga, Lori, Folta, Dave, Gorius, Nicolas, Hurford, Terry, Livengood, Tim, Malphrus, Ben, Mumma, Michael, Nixon, Conor, Sunshine, Jessica, Villanueva, Geronimo, and Zucherman, Aaron

Published

2018

10. Overview of Primitive Volatile Explorer (PrOVE) Cubesat or Smallsat Concept

Author

Zucherman, Aaron, Villanueva, Geronimo, Sunshine, Jessica, Nixon, Conor, Mumma, Michael, Malphrus, Ben, Livengood, Tim, Hurford, Terry, Gorius, Nicolas, Folta, Dave, Feaga, Lori, Daly, Michael, Aslam, Shahid, Hewagama, Tilak, and Clark, Pamela

Abstract

Here we describe the Primitive Object Volatile Explorer (PrOVE), a smallsat mission concept to study the surface structure and volatile inventory of comets in their perihelion passage phase when volatile activity is near peak. CubeSat infrastructure imposes limits on propulsion systems, which are compounded by sensitivity to the spacecraft disposal state from the launch platform and potential launch delays. We propose circumventing launch platform complications by using waypoints in space to park a deep space SmallSat or CubeSat while awaiting the opportunity to enter a trajectory to flyby a suitable target. In our Planetary Science Deep Space SmallSat Studies (PSDS3) project, we investigated scientific goals, waypoint options, potential concept of operations (ConOps) for periodic and new comets, spacecraft bus infrastructure requirements, launch platforms, and mission operations and phases. Our payload would include two low-risk instruments: a visible image (VisCAM) for 5-10 m resolution surface maps; and a highly versatile multispectral Comet CAMera (ComCAM) will measure 1) H2O, CO2, CO, and organics non-thermal fluorescence signatures in the 2-5 µm MWIR, and 2) 7-10 and 8-14 µm thermal (LWIR) emission. This payload would return unique data not obtainable from ground-based telescopes and complement data from Earth-orbiting observatories. Thus, the PrOVE mission would (1) acquire visible surface maps, (2) investigate chemical heterogeneity of a comet nucleus by quantifying volatile species abundance and changes with solar insolation, (3) map the spatial distribution of volatiles and determine any variations, and (4) determine the frequency and distribution of outbursts.

Published

2018

11. Lessons Learned from OSIRIS-Rex Autonomous Navigation Using Natural Feature Tracking

Author

Lorenz, David A, Olds, Ryan, May, Alexander, Mario, Courtney, Perry, Mark E, Palmer, Eric E, and Daly, Michael

Subjects

Engineering (General), Aeronautics (General)

Abstract

The Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer (Osiris-REx) spacecraft is scheduled to launch in September, 2016 to embark on an asteroid sample return mission. It is expected to rendezvous with the asteroid, Bennu, navigate to the surface, collect a sample (July 20), and return the sample to Earth (September 23). The original mission design called for using one of two Flash Lidar units to provide autonomous navigation to the surface. Following Preliminary design and initial development of the Lidars, reliability issues with the hardware and test program prompted the project to begin development of an alternative navigation technique to be used as a backup to the Lidar. At the critical design review, Natural Feature Tracking (NFT) was added to the mission. NFT is an onboard optical navigation system that compares observed images to a set of asteroid terrain models which are rendered in real-time from a catalog stored in memory on the flight computer. Onboard knowledge of the spacecraft state is then updated by a Kalman filter using the measured residuals between the rendered reference images and the actual observed images. The asteroid terrain models used by NFT are built from a shape model generated from observations collected during earlier phases of the mission and include both terrain shape and albedo information about the asteroid surface. As a result, the success of NFT is highly dependent on selecting a set of topographic features that can be both identified during descent as well as reliably rendered using the shape model data available. During development, the OSIRIS-REx team faced significant challenges in developing a process conducive to robust operation. This was especially true for terrain models to be used as the spacecraft gets close to the asteroid and higher fidelity models are required for reliable image correlation. This paper will present some of the challenges and lessons learned from the development of the NFT system which includes not just the flight hardware and software but the development of the terrain models used to generate the onboard rendered images.

Published

2017