HiRISE

For the Apple accessory see Twelve South

HiRISE being prepared before it is shipped for attachment to the spacecraft

High Resolution Imaging Science Experiment is a camera on board the Mars Reconnaissance Orbiter. The 65 kg (143 lb), $40 million USD instrument was built under the direction of the University of Arizona's Lunar and Planetary Laboratory by Ball Aerospace & Technologies Corp. It consists of a 0.5 m (19.7 in) aperture reflecting telescope, the largest so far of any deep space mission, which allows it to take pictures of Mars with resolutions of 0.3 m/pixel (about 1 foot), resolving objects below a meter across.

HiRISE has imaged Mars landers on the surface, including the ongoing Curiosity and Opportunity rover missions.[1]

History

Crop of one of the first images of Mars from the HiRISE camera

In the late 1980s, Alan Delamere of Ball Aerospace began planning the kind of high-resolution imaging needed to support sample return and surface exploration of Mars. In early 2001 he teamed up with Alfred McEwen of the University of Arizona to propose such a camera for the Mars Reconnaissance Orbiter (MRO), and NASA formally accepted it November 9, 2001.[2]

Ball Aerospace was given the responsibility to build the camera and they delivered HiRISE to NASA on December 6, 2004 for integration with the rest of the spacecraft.[3] It was prepared for launch on board the MRO on August 12, 2005, to the cheers of the HiRISE team who were present.[4]

Artist's rendition of HiRISE at Mars

During the cruise phase of MRO, HiRISE took multiple test shots including several of the Moon and the Jewel Box cluster. These images helped to calibrate the camera and prepare it for taking pictures of Mars.

On March 10, 2006, MRO achieved Martian orbit and primed HiRISE to acquire some initial images of Mars.[5] The instrument had two opportunities to take pictures of Mars (the first was on March 24, 2006) before MRO entered aerobraking, during which time the camera was turned off for six months.[6] It was turned on successfully September 27, and took its first high-resolution pictures of Mars on September 29.

On October 6, 2006 HiRISE took the first image of Victoria Crater, a site which is also under study by the Opportunity rover.[7]

In February 2007 seven detectors showed signs of degradation, with one IR channel almost completely degraded, and one other showing advanced signs of degradation. The problems seem to disappear when higher temperatures are used to take pictures with the camera.[8] As of March, the degradation appeared to have stabilized, but the underlying cause remained unknown.[9] Subsequent experiments with the Engineering Model (EM) at Ball Aerospace provided definitive evidence for the cause: contamination in the analog-to-digital converters (ADCs) which results in flipping bits to create the apparent noise or bad data in the images, combined with design flaws leading to delivery of poor analog waveforms to the ADCs. Further work showed that the degradation can be reversed by heating the ADCs.

On 2007-10-03, HiRISE was turned toward Earth, and took a picture of it and the Moon. In a full-resolution color image, Earth was 90 pixels across and the Moon was 24 pixels across from a distance of 142 million km.[10]

On May 25, 2008, HiRISE imaged NASA's Mars Phoenix Lander parachuting down to Mars. It was the first time that one spacecraft imaged the final descent of another spacecraft onto a planetary body.[11]

On April 1, 2010, NASA released the first images under the HiWish program in which the public suggested places for HiRISE to photograph. One of the eight locations was Aureum Chaos.[12] The first image below gives a wide view of the area. The next two images are from the HiRISE image.[13] By 2010, HiRISE had imaged about one percent of Mars's surface[14] and by 2016 the coverage was around 2.4%.[15] It was designed to capture smaller areas at high resolutionother instruments scan much more area to find things like fresh impact craters.

Purpose

Comparison of resolution of MRO HiRISE camera with predecessor, the MOC aboard MGS

The HiRISE camera is designed to view surface features of Mars in greater detail than has previously been possible.[16] It has provided a closer look at fresh martian craters, revealing alluvial fans, viscous flow features and ponded regions of pitted materials containing breccia clast.[17] This allows for the study of the age of Martian features, looking for landing sites for future Mars landers, and in general, seeing the Martian surface in far greater detail than has previously been done from orbit. By doing so, it is allowing better studies of Martian channels and valleys, volcanic landforms, possible former lakes and oceans, and other surface landforms as they exist on the Martian surface.[18]

The general public is allowed to request sites for the HiRISE camera to capture (see HiWish). For this reason, and due to the unprecedented access of pictures to the general public, shortly after they have been received and processed, the camera has been termed "The People's Camera".[19] The pictures can be viewed online, downloaded, or with the free HiView software.

Design

Earth and Moon from Mars Reconnaissance Orbiter taken by HiRISE

HiRISE was designed to be a High Resolution camera from the beginning. It consists of a large mirror, as well as a large CCD camera. Because of this, it achieves a resolution of 1 microradian, or 0.3 meter at a height of 300 km. (For comparison purposes, satellite images on Google Mars are available to 1 meter.[20]) It can image in three color bands, 400–600 nm (blue-green or B-G), 550–850 nm (red) and 800–1,000 nm (near infrared or NIR).[21]

HiRISE incorporates a 0.5-meter primary mirror, the largest optical telescope ever sent beyond Earth's orbit. The mass of the instrument is 64.2 kg.[22]

Red color images are at 20,048 pixels wide (6 km in a 300 km orbit), and Green-Blue and NIR are at 4,048 pixels wide (1.2 km). These are gathered by 14 CCD sensors, 2048 x 128 pixels. HiRISE's onboard computer reads out these lines in time with the orbiter's ground speed, meaning the images are potentially unlimited in height. Practically this is limited by the onboard computer's 28 Gbit (3.5 GByte) memory capacity. The nominal maximum size of red images (compressed to 8 bits per pixel) is about 20,000 × 126,000 pixels, or 2520 megapixels and 4,000 × 126,000 pixels (504 megapixels) for the narrower images of the B-G and NIR bands. A single uncompressed image uses up to 28 Gbit. However, these images are transmitted compressed,with a typical max size of 11.2 Gigabits. These images are released to the general public on the HiRISE website via a new format called JPEG 2000.[23][24]

To facilitate the mapping of potential landing sites, HiRISE can produce stereo pairs of images from which the topography can be measured to an accuracy of 0.25 meter.

Images naming conventions

Whirlwind trails on Martian sand dunes
Gullies in the southern highlands of Mars

HIRISE images are available to the public, so it can be useful to know how they are named. This is an excerpt from the official documentation:

Name:
ppp_oooooo_tttt_ffff_c.IMG
ppp = Mission Phase:
  INT = Integration and Testing
  CAL = Calibration Observations
  ATL = ATLO Observations
  KSC = Kennedy Space Center Observations
  SVT = Sequence Verification Test
  LAU = Launch
  CRU = Cruise Observations
  APR = Mars Approach Observations
  AEB = Aerobraking Phase
  TRA = Transition Phase
  PSP = Primary Science Orbit (nov 2006-nov 2008)
  REL = Relay phase
  E01 = 1st Extended Mission Phase if needed
  Exx = Additional extended Missions if needed
oooooo = MRO orbit number
tttt = Target code
ffff Filter/CCD designation:
RED0-RED9 - Red filter CCDs
IR10-IR11 – Near-Infrared filter CCDs
BG12-BG13 – Blue-Green filter CCDs
c = Channel number of CCD (0 or 1)

The target code refers to the latitudinal position of the center of the planned observation relative to the start of orbit. The start of orbit is located at the equator on the descending side (night side) of the orbit. A target code of 0000 refers to the start of orbit. The target code increases in value along the orbit track ranging from 0000 to 3595. This convention allows the file name ordering to be time sequential. The first three digits refers to the number of whole degrees from the start of orbit, the fourth digit refers to the fractional degrees rounded to the nearest 0.5 degrees. Values greater than 3595 identify observations as off-Mars or special observations.

Examples of target code:

0000 – planned observation at the equator on descending side of orbit.
0900 – planned observation at the south pole.
1800 – planned observation at the equator on the ascending side (day side) of the orbit.
2700 – planned observation at the north pole.

Off-Mars and Special Observations Values:

4000 – Star Observation
4001 – Phobos Observation
4002 – Deimos Observation
4003 – Special Calibration Observation

Footnotes

  1. VOA News - Mars Orbiter Photographs Old NASA Lander (February 9, 2012)
  2. "UA-Led Team's Ultra-High Resolution Camera Selected for 2005 Launch to Mars" (Press release). UANews. 2001-11-09. Retrieved 2006-06-08.
  3. "Ultra-sharp, Mars-Bound HiRISE Camera Delivered" (Press release). UANews. 2004-12-06. Retrieved 2006-06-08.
  4. "UA Team Cheers Launch of Mars Reconnaissance Orbiter, HiRISE" (Press release). UANews. 2005-08-08. Retrieved 2006-06-08.
  5. "Mars Reconnaissance Orbiter Successfully Enters Orbit Around Mars!". NASA MRO website. Archived from the original on 2006-06-03. Retrieved 2006-06-08.
  6. "UA Team Cheers Launch of Mars Reconnaissance Orbiter, HiRISE" (Press release). NASA. 2006-03-24. Retrieved 2006-06-08.
  7. HiRISE | Victoria Crater at Meridiani Planum (TRA_000873_1780)
  8. "Spacecraft Set to Reach Milestone, Reports Technical Glitches" (Press release). NASA. 2007-02-07. Retrieved 2007-03-06.
  9. Shiga, David (16 March 2007). "Ailing Mars camera is stable – for now". NewScientist.com news service. Retrieved 2007-03-18.
  10. "Earth and Moon as Seen from Mars". NASA. 2008-03-03. Retrieved 2008-06-21.
  11. "Camera on Mars Orbiter Snaps Phoenix During Landing". JPL website. Retrieved 2008-05-28.
  12. http://uahirise.org/releases/hiwish-captions.php
  13. http://hirise.lpl.arizona.edu/ESP_016869_1775
  14. "Microsoft and NASA Bring Mars Down to Earth Through the WorldWide Telescope". NASA. Retrieved 2012-12-07.
  15. "HiRISE: 45,000 Mars Orbits and Counting". The University of Arizona. Retrieved 2016-03-23.
  16. Alan Delamere (2003). "MRO HiRISE: Instrument Development" (PDF). 6th International Mars Conference. Retrieved 2008-05-25.
  17. "Lunar Reconnaissance Orbiter Science Targeting Meeting - Program and Abstract Volume". NASA. NASA Technical Reports Server. Retrieved 26 September 2011.
  18. "Science Goals". Lunar and Planetary Laboratory, University of Arizona. Retrieved June 7, 2006.
  19. "HiRISE". Lunar and Planetary Laboratory, University of Arizona. Retrieved 19 March 2006.
  20. "Google Earth FAQ" Google Earth Website.
  21. "MRO HiRISE Camera Specifications". HiRISE website. Retrieved 2 January 2006.
  22. Mission to Mars: the HiRISE camera on-board MRO, Focal plane arrays for space telescopes III, 27–28 August 2007, San Diego, California, USA
  23. "HiRISE: Instrument Development" (PDF). NASA Ames Research Center website. Retrieved 7 February 2006.
  24. "Fact Sheet: HiRISE" (PDF). National Air and Space Museum. Retrieved 18 February 2006.
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