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Slip Sliding Away

March 09, 2004

Opportunity failed to complete the first big climb of the outcrop on February 8 due to the wheels slipping up the martian slope.
Opportunity failed to complete the first big climb of the outcrop on February 8 due to the wheels slipping up the martian slope.
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On February 9, the wake up song for Opportunity was "Slip Sliding Away" by Simon and Garfunkel in honor of the experience the prior day when Opportunity first tried to scoot up the crater slope at Meridiani Planum. The ambitious rover aimed for its target and willingly went forth up the slope; nevertheless, Opportunity slipped and slid in the sand, making it only half way to its target.

But ignorance is bliss, and while Opportunity's wheels had a hard time gaining traction on the sandy surface, the rover's brain (or computer) had a hard time grasping that it hadn't successfully made it to its target. The little rover didn't have to encourage itself to make it up the crater slope later by chanting, "I think I can, I think I can," because the little rover thought it actually did make it up the slope the first time.


Randy Lindemann, Rover Mobility Lead
Randy Lindemann, Rover Mobility Lead
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Measuring the Distance Traveled on Mars

"Like a car on Earth, each Mars rover uses an odometer to click off the distance its wheels travel to measure and register how far the vehicle has moved," explains Randy Lindemann, rover mobility lead. One revolution of the rover wheel equals 80 centimeters or 2.6 feet, so after the wheels have revolved four times, the rover believes that it has moved forward 320 centimeters or 10.5 feet (80 centimeters X 4 = 320 centimeters).

Alas, Opportunity's wheels had a hard time grasping onto the sandy ground around the crater and the wheels spun in place before they actually gained tracking. "As Opportunity's wheels turned and ticked off 80 centimeters (2.6 feet) each revolution, they eventually spun four times, calculating to what it thought was a distance of 320 centimeters (10.5 feet). Thus, Opportunity believed it had reached its goal, when in reality, it had spun in place 50 percent of the revolutions and only really made it 160 centimeters (5.25 feet)," said Lindemann.


Rover Driver Eric Baumgartner in action, making commands for one of Opportunity's drives.  Rover Drivers join scientists in daily Science Operations Working Group meetings to create rover plans in real-time.
Rover Driver Eric Baumgartner in action, making commands for one of Opportunity's drives. Rover Drivers join scientists in daily Science Operations Working Group meetings to create rover plans in real-time.
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Outwitting the Odometer

In order to prevent any future missed targets, Opportunity's mobility experts quickly started trying to predict exactly how far the rover would slip down a slope or fall short of a target while climbing up a slope due to the loose terrain along the steep angles of the crater wall. "Since the rover isn't on cruise control and can't rev its engine to get some extra oompf to go up a hill, we continually have to outwit Opportunity's odometer and command the rover to go farther or shorter than the real target distance," said Rover Driver Eric Baumgartner.


Mobility experts tested the rover engineering model in a sandbox while the real rovers were cruising to Mars.
Mobility experts tested the rover engineering model in a sandbox while the real rovers were cruising to Mars.
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Rover Drivers and their Crystal Ball

"Well, we don't quite have a crystal ball to predict slippage of the rover wheels," said Lindemann, "but our team of mobility experts and rover drivers can make predictions using a rather nice piece of paper with a curved line on a standard plot."

How well does this prediction on paper work? It's all about prior testing. While Opportunity was cruising through deep space on the way to Mars, engineers on Earth tested the rover's mobility using an engineering model of the rover of the same weight and size with identical wheels. Engineers affectionately named it the "SSTB-lite rover." SSTB-lite stands for Surface System TestBed, and the lite means that this rover doesn't have any of the appendages, such as the robotic arm, high-gain antenna, or panoramic camera mast assembly.

"Our sandbox was a variable-tilt platform covered with 6 inches of dry, loose sand similar to what is used with construction cement. Throughout the weeklong test, we plotted how much the test rover slipped at different angles going up, down and across the simulated martian terrain," explained Lindemann.

"We never expected the incredible result that the rover's slipping behavior at the Meridiani site would be almost identical to its behavior on dry and loose sand. The reason that this surprised us so much is that the soil at Meridiani is nothing like dry beach sand from the Earth in terms of the minerals that it is made of or even how it was formed. What we have learned is that the primary characteristic of any loose soil in terms of how the rover will drive on it is determined by the characteristics of the friction between all of the tiny grains -- pretty much no matter what they are made of," said Lindemann.


Engineers' trustworthy mobility plots predict slips up and down the slopes of Mars.
Engineers' trustworthy mobility plots predict slips up and down the slopes of Mars.
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How Far Will Rovers Slip and Slide?

The test created a set of trustworthy mobility plots. The plots show rover drivers that, at a 15-degree angle facing down, the rover will slide an extra 25 centimeters downward for every meter it is trying to go. The chart is not a straight, even line. At a 20-degree angle downward, the rover will slide 55 centimeters (1.8 feet) down, whereas at 20-degree angle upward, the rover will slip 90 centimeters (2.9 feet) in place and only move forward 10 centimeters (3.9 inches) out of a drive of 100 centimeters (3.3 feet).

For the type of sand Opportunity is in, the dead-end point where the rover simply can't climb upwards anymore, regardless of how many times the wheels turn, is 25 degrees," explained Baumgartner. "We've already gone up slopes as steep as 22 degrees on Opportunity Ledge. Luckily, the Long Term Planning team has found places around the crater with slopes lower than 25 degrees, so we can eventually get out of this crater where we landed," said Baumgartner.


Navigation camera image taken from Opportunity on February 27.  Notice the large tilt of the horizon due to the success of the climb up the outcrop.  As Opportunity tilts up the slope, the rover's cameras snap pictures at an angle.
Navigation camera image taken from Opportunity on February 27. Notice the large tilt of the horizon due to the success of the climb up the outcrop. As Opportunity tilts up the slope, the rover's cameras snap pictures at an angle.
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Driving Spirit Versus Opportunity

Baumgartner is one of eight rover drivers. There are four for Spirit and four for Opportunity. Two rover drivers are on station for any given sol. "It's a lot of fun to come to work and drive the rovers on Mars and drive the rover arm, which is a whole other story in itself," said Baumgartner. The rover drivers for the two rovers have had very different experiences due to the difference in terrain at the two sites.

"At the Opportunity site, it's like we're driving on snow with little traction on the slopes, but the Spirit site is like monster truck driving with the rocky terrain," laughed Baumgartner.


Spirit's traverse map after the rover had driven 131 meters (430 feet) in 45 sols.
Spirit's traverse map after the rover had driven 131 meters (430 feet) in 45 sols.
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Spirit is on flat, rocky terrain, while Opportunity is in steep terrain with a low distribution of rocks, so the two rover driving teams will be swapping lessons learned when each rover moves to a different location. "If Spirit makes it to Bonneville crater, the rover drivers will have to rely on what we've learned at Meridiani, and once we get out of the crater at Meridiani, we may need to learn how to drive far in a rock-strewn landscape from the Spirit team," said Baumgartner.


Screenshot of the software rover drivers use to simulate the commands sent to the rovers every sol.
Screenshot of the software rover drivers use to simulate the commands sent to the rovers every sol.
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On Your Mark, Get Set, Rove!

In order to build the drive commands for Spirit and Opportunity, rover drivers use sophisticated software created at NASA's Jet Propulsion Laboratory to make a three-dimension simulation of the martian terrain using navigation camera images and a simulation of the actual movement of the rover. Rover drivers must simulate the rover movement in a computer program because there isn't enough time to sprint to a test bed (a sandbox with an engineering rover model) every day to run the command sequence. Schedules are extremely tight to turn around new, complex robot moves and send the commands to a planet over 150 million miles away.


Software screenshot of the turn maneuver in simulated rover drive sequence.
Software screenshot of the turn maneuver in simulated rover drive sequence.
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"We run many, many simulations -- up to 20 per move -- to figure out what the best path is for each segment of the drive," explains Baumgartner. Rover drivers for Opportunity have to add in the slippage estimates created by the mobility experts. Rover drivers use the slope information and tell the rover to stop short of its target when it's heading down a slope so that the rover will slide into home plate on its own. When the rover has to trek up a slope, engineers do the opposite since it is harder for the wheels to churn upward. If the rover needs to go up a slope, engineers command the rover to actually go farther than necessary to compensate for the upward tilt.


Final screenshot from software which simulates each segment of every move of the rover's traverse on Mars.
Final screenshot from software which simulates each segment of every move of the rover's traverse on Mars.
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"I didn't think adding in slippage would be part of my work as a rover driver," said Baumgartner. "The foresight of mechanical team was tremendous, and if we didn't have the slippage chart, we would be putting our thumbs to the air and saying, ‘I think the rover will slip about this much here,'" laughed Baumgartner. "Within about five hours every day, we have to write hundreds of lines of commands to drive the rover to the scientists' dream location. Without the efficient slip estimates, which the mobility team constantly refines, we would be in a lot of trouble here," said Baumgartner.


Body Movin'

On February 18, the wake up song for Opportunity was ‘Body Movin' by the Beastie Boys in honor of the 15-meter (49-foot) drive, which was Opportunity's farthest distance to date. "We were off by less than 0.5 meters (1.6 feet) from our desired final destination, which is an error of about 3%. In contrast, Opportunity actually slipped between 10% and 17%, so without this slippage planning, we would have been off by as much as 2.6 meters (8.5 feet). That would have cost us another day on Mars to get close enough for the pancam and mini-TES work that was planned at the target," said Lindemann.

"We've moved from sad folk music to body movin' rap music for wake up songs, so I'm pretty happy," said Lindemann with a smile.

Watch a video of Testing the Rovers for the Treacherous Martian Terrain

More information about Moving Around on Mars

Mars Exploration Rover Drivers
Brian Cooper Chris Leger Eric Baumgartner Frank Hartman
Jeff Biesiadecki John Wright Robert Bonitz Scott Maxwell
     
Ashitey
Trebi-Ollennu
     
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