The University of Arizona

Phoenix Mars Mission Faces Survival Challenges

By Lori Stiles, October 28, 2008

Four heaters will be shut down one at a time over the next several weeks in an effort to conserve power.

The Surface Stereo Imager on NASA's Phoenix Mars Lander took this false color image on Oct. 21, 2008, during the 145th Martian day, or sol, since landing. The white areas seen in these trenches are part of an ice layer beneath the soil. The trench on the upper left, called "Upper Cupboard," is about 24 inches long and an inch deep. The trench in the middle, called "Ice Man," is about 12 inches long and an inch deep. The trench on the right, called "La Mancha," is about 12 inches long and two inches deep.
The Surface Stereo Imager on NASA's Phoenix Mars Lander took this false color image on Oct. 21, 2008, during the 145th Martian day, or sol, since landing. The white areas seen in these trenches are part of an ice layer beneath the soil. The trench on the upper left, called "Upper Cupboard," is about 24 inches long and an inch deep. The trench in the middle, called "Ice Man," is about 12 inches long and an inch deep. The trench on the right, called "La Mancha," is about 12 inches long and two inches deep.
The Robotic Arm Camera on NASA's Phoenix Mars Lander took this image on Oct. 18, 2008, during the 142nd Martian day, or sol, since landing. The flat patch in the center of the image has the informal name "Holy Cow," based on researchers' reaction when they saw the initial image of it only a few days after the May 25, 2008 landing. Researchers first saw this flat patch in an image taken by the Robotic Arm Camera on May 30, the fifth Martian day of the mission.
The Robotic Arm Camera on NASA's Phoenix Mars Lander took this image on Oct. 18, 2008, during the 142nd Martian day, or sol, since landing. The flat patch in the center of the image has the informal name "Holy Cow," based on researchers' reaction when they saw the initial image of it only a few days after the May 25, 2008 landing. Researchers first saw this flat patch in an image taken by the Robotic Arm Camera on May 30, the fifth Martian day of the mission.

In a race against time and the elements, engineers with NASA’s Phoenix Mars Lander mission hope to extend the lander’s survival by gradually shutting down some of its instruments and heaters, starting today.

Originally scheduled to last 90 days, Phoenix has completed a fifth month of exploration in the Martian arctic.

Peter Smith of The University of Arizona's Lunar and Planetary Laboratory is the lead scientist on the mission, the first Mars mission led by a public university.

As expected, with the Martian northern hemisphere shifting from summer to fall, the lander is generating less power due to shorter days and fewer hours of sunlight reaching its solar panels. At the same time, the spacecraft requires more power to run several survival heaters that allow it to operate even as temperatures decline.

“If we did nothing, it wouldn’t be long before the power needed to operate the spacecraft would exceed the amount of power it generates on a daily basis,” said Phoenix Project Manager Barry Goldstein of NASA’s Jet Propulsion Laboratory. “By turning off some heaters and instruments, we can extend the life of the lander by several weeks and still conduct some science.”

Over the next several weeks, four survival heaters will be shut down, one at a time, in an effort to conserve power. The heaters serve the purpose of keeping the electronics within tested survivable limits. As each heater is disabled, some of the instruments also are expected to cease operations. The energy saved is intended to power the lander’s main camera and meteorological instruments until the very end of the mission.

Later today, engineers will send commands to disable the first heater. That heater warms Phoenix’s robotic arm, robotic-arm camera and thermal and evolved-gas analyzer, known as TEGA, an instrument that bakes and sniffs Martian soil to assess volatile ingredients. Shutting down this heater is expected to save 250 watt-hours of power per Martian day.

The Phoenix team has parked the robotic arm on a representative patch of Martian soil. No additional soil samples will be gathered. The thermal and electrical-conductivity probe, or TECP, located on the wrist of the arm, has been inserted into the soil and will continue to measure soil temperature and conductivity, along with atmospheric humidity near the surface. The probe does not need a heater to operate and should continue to send back data for weeks.

Throughout the mission, the lander’s robotic arm successfully dug and scraped Martian soil and delivered it to the onboard laboratories. “We turn off this workhorse with the knowledge that it has far exceeded expectations and conducted every operation asked of it,” said Ray Arvidson, the robotic arm's co-investigator, and a professor at Washington University, St. Louis.

When power levels necessitate further action, Phoenix engineers will disable a second heater, which serves the lander’s pyrotechnic initiation unit. The unit hasn’t been used since landing, and disabling its heater is expected to add four to five days to the mission’s lifetime. Following that step, engineers would disable a third heater, which warms Phoenix’s main camera – the Surface Stereo Imager – and the meteorological suite of instruments. Electronics that operate the meteorological instruments should generate enough heat on their own to keep most of those instruments and the camera functioning.

In the final step, Phoenix engineers may turn off a fourth heater – one of two survival heaters that warm the spacecraft and its batteries. This would leave one remaining survival heater to run out on its own.

“At that point, Phoenix will be at the mercy of Mars,” said Chris Lewicki of JPL, lead mission manager.

Engineers are also preparing for solar conjunction, when the sun is directly between Earth and Mars. Between Nov. 28 and Dec. 13, Mars and the sun will be within two degrees of each other as seen from Earth, blocking radio transmission between the spacecraft and Earth. During that time, no commands will be sent to Phoenix, but daily downlinks from Phoenix will continue through NASA’s Odyssey and Mars Reconnaissance orbiters. At this time, controllers can’t predict whether the fourth heater would be disabled before or after conjunction.

The Phoenix mission is led by Smith of the UA, with project management at the Jet Propulsion Laboratory and development partnership at Lockheed Martin, Denver. International contributions come from the Canadian Space Agency; the University of Neuchatel, Switzerland; the universities of Copenhagen and Aarhus in Denmark; the Max Planck Institute in Germany; and the Finnish Meteorological Institute.