Landing on Titan: The new movies

May 04, 2006

Scientists at the University of Arizona Lunar and Planetary Laboratory (LPL) have made two new movies of the Huygens probe's landing on Saturn's giant moon, Titan, on Jan. 14, 2005.

The movies -- made from images taken by Huygens' Descent Imager/Spectral Radiometer (DISR) during its 147-minute plunge through Titan's thick orange-brown atmosphere to a soft sandy riverbed -- are the most realistic way yet to experience the far-out-world landing.

The movies are being released today on these Web sites:,, and

DISR was developed with NASA funding by UA and Lockheed Martin researchers on a team headed by LPL Research Professor Martin Tomasko. The European Space Agency (ESA) Huygens probe is part of the joint NASA, ESA and Italian Space Agency Cassini-Huygens mission to the Saturn system. The probe landing was the most distant touchdown ever made by a human-built spacecraft.

LPL senior staff scientist and DISR team member Erich Karkoschka created the new Huygens landing movie and the new DISR movie.

Scientists were extremely busy analyzing data for months after the landing, Karkoschka said. They didn't have a chance to give the public a good overview of what was going on until later. "I hope the new movies help to put the different results into context," he said.

In the Huygens movie, "I wanted to show what the Huygens probe 'saw' within a few hours," Karkoschka said. "At first, the Huygens camera just saw fog over the distant surface. But after landing, the probe's camera could resolve little grains of sand millions and millions times smaller than Titan. A movie is a perfect medium to show such a huge change of scale."

DISR team member Chuck See scripted this narrated movie, "The View from Huygens on January 14, 2005," which runs 4 minutes 40 seconds. KUAT radio broadcaster David Harrington of Tucson, Ariz., narrates. Another version is accompanied by a recording of Beethoven's Piano Concerto No. 4 performed by Debbie Hu of Yelm, Wa.

For the second, more technical movie, Karkoschka shows DISR's 4-hour operating life in less than five minutes, too. It takes some text to follow all the graphics and sidebar information that comes with this version. Karkoschka's text describing the movie is online at

"DISR was a very complicated instrument," Karkoschka said. "It had to be programmed to take its 3,500 exposures in a way to get the most science. It had to decide where and when to take exposures."

DISR was designed when the best images showed Titan as a featureless, hazy disk. "We didn't know the dynamics of Titan's atmosphere very well, and we didn't know how fast Huygens would rotate and swing," Karkoschka said. "It was an extremely challenging programming task to make DISR work well under every imaginable condition."

A movie is ideal for showing how DISR worked.

For example, the first part of the movie shows how Titan looked to DISR as it acquired more and more images during the probe's descent. Each DISR image has a small field of view, and dozens of images were made into mosaics of the whole scene.

Karkoschka analyzed Huygens' speed, direction of motion, rotation and swinging during descent. His DISR movie includes sidebar graphics that show such things as:

(Lower left corner) Huygens' trajectory views from the south, a scale bar for comparison to the height of Mount Everest, colored arrows that point to the sun and to the Cassini orbiter.
(Top left corner) A close-up view of the Huygens probe highlighting large and unexpected parachute movements, and a scale bar for comparison to human height.
(Lower right corner) A compass that shows the changing direction of view as Huygens rotates, along with the relative positions of the sun and Cassini.
(Upper right corner) A clock that shows Universal Time, also referred to as Greenwich Mean Time, on Jan. 14, 2005. Above the clock, events are listed in Mission Time, which starts with the deployment of the first parachute.

A musical score comes with this movie, too. But it's definitely modern, not classical.

"There's so much information in the different displays that come with this movie that one can easily miss something important," Karkoschka said. "Therefore, I added sound to track the most important features, because the ears hear all the sound no matter where you look."

Sounds from a left speaker trace Huygens' motion, with tones changing with rotational speed and the tilt of the parachute. There also are clicks that clock the rotational counter, as well as sounds for the probe's heat shield hitting Titan's atmosphere, parachute deployments, heat shield release, jettison of the DISR cover and touch down.

Sounds from a right speaker go with DISR activity. There's a continuous tone that represents the strength of Huygens' signal to Cassini. Then there are 13 different chimes - one for each of DISR's 13 different science parts - that keep time with flashing-white-dot exposure counters.

All parts of DISR worked together as programmed, Karkoschka said. It was pure harmony.
University of Arizona Lunar and Planetary Laboratory scientist Martin Tomasko leads the DISR team. Team members are based throughout the United States and Europe, with the largest contributing groups from the UA in the United States, from the Max Planck Institute in Germany, and the Paris Observatory in Meudon, France.

The Cassini-Huygens mission to Saturn and Titan is a joint mission of NASA, the European Space Agency (ESA) and the Italian Space Agency (ASI). ESA supplied and manages the Huygens probe that descended to Titan's surface Jan. 14, 2005. NASA's Jet Propulsion Laboratory, a division of the California Institute of Technology in Pasadena, manages the mission for NASA's Science Mission Directorate in Washington, D.C. NASA funded the Descent Imager-Spectral Radiometer, which was built by Lockheed Martin.

University of Arizona

Related Titan Articles from Brightsurf:

Life on Titan cannot rely on cell membranes, according to computational simulations
Researchers from Chalmers University of Technology, Sweden, have made a new contribution to the ongoing search into the possibility of life on Titan, Saturn's largest moon.

Galactic cosmic rays affect Titan's atmosphere
Planetary scientists using the Atacama Large Millimeter/submillimeter Array (ALMA) revealed the secrets of the atmosphere of Titan, the largest moon of Saturn.

Nitrogen explosions created craters on Saturn moon Titan
Lakes of liquid methane on the surface of Titan, Saturn's largest moon, were likely formed by explosive, pressurized nitrogen just under the moon's surface, according to new research.

'Bathtub rings' around Titan's lakes might be made of alien crystals
The frigid lakeshores of Saturn's moon Titan might be encrusted with strange, unearthly minerals, according to new research being presented at the 2019 Astrobiology Science Conference, June 24-28, co-hosted by AGU and NASA in Bellevue, Wa.

SwRI scientist sheds light on Titan's mysterious atmosphere
A new Southwest Research Institute study tackles one of the greatest mysteries about Titan, one of Saturn's moons: the origin of its thick, nitrogen-rich atmosphere.

Astronomers find a cosmic Titan in the early universe
An international team of astronomers has discovered a titanic structure in the early universe, just two billion years after the Big Bang.

Unexpected atmospheric vortex behavior on Saturn's moon Titan
A new study led by a University of Bristol earth scientist has shown that recently reported unexpected behavior on Titan, the largest moon of Saturn, is due to its unique atmospheric chemistry.

Cassini's legacy and the atmospheric chemistry of Titan (video)
The Cassini-Huygens mission to Saturn, a collaboration between NASA and the European Space Agency, is set to end on Sept.

ALMA confirms complex chemistry in Titan's atmosphere
Saturn's frigid moon Titan has a curious atmosphere. In addition to a hazy mixture of nitrogen and hydrocarbons, like methane and ethane, Titan's atmosphere also contains an array of more complex organic molecules, including vinyl cyanide, which astronomers recently uncovered in archival ALMA data.

Scientists describe origins of topographic relief on Titan
Fluid erosion has carved river networks in at least three bodies in our solar system in the form of water on Earth and Mars and liquid hydrocarbons on Titan.

Read More: Titan News and Titan Current Events is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to