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miércoles, 30 de enero de 2019

Engineers program marine robots to take calculated risks

We know far less about the Earth’s oceans than we do about the surface of the moon or Mars. The sea floor is carved with expansive canyons, towering seamounts, deep trenches, and sheer cliffs, most of which are considered too dangerous or inaccessible for autonomous underwater vehicles (AUV) to navigate.

But what if the reward for traversing such places was worth the risk?

MIT engineers have now developed an algorithm that lets AUVs weigh the risks and potential rewards of exploring an unknown region. For instance, if a vehicle tasked with identifying underwater oil seeps approached a steep, rocky trench, the algorithm could assess the reward level (the probability that an oil seep exists near this trench), and the risk level (the probability of colliding with an obstacle), if it were to take a path through the trench.  

“If we were very conservative with our expensive vehicle, saying its survivability was paramount above all, then we wouldn’t find anything of interest,” Ayton says. “But if we understand there’s a tradeoff between the reward of what you gather, and the risk or threat of going toward these dangerous geographies, we can take certain risks when it’s worthwhile.”

Ayton says the new algorithm can compute tradeoffs of risk versus reward in real time, as a vehicle decides where to explore next. He and his colleagues in the lab of Brian Williams, professor of aeronautics and astronautics, are implementing this algorithm and others on AUVs, with the vision of deploying fleets of bold, intelligent robotic explorers for a number of missions, including looking for offshore oil deposits, investigating the impact of climate change on coral reefs, and exploring extreme environments analogous to Europa, an ice-covered moon of Jupiter that the team hopes vehicles will one day traverse.

“If we went to Europa and had a very strong reason to believe that there might be a billion-dollar observation in a cave or crevasse, which would justify sending a spacecraft to Europa, then we would absolutely want to risk going in that cave,” Ayton says. “But algorithms that don’t consider risk are never going to find that potentially history-changing observation.”

Ayton and Williams, along with Richard Camilli of the Woods Hole Oceanographic Institution, will present their new algorithm at the Association for the Advancement of Artificial Intelligence conference this week in Honolulu.

A bold path

The team’s new algorithm is the first to enable “risk-bounded adaptive sampling.” An adaptive sampling mission is designed, for instance, to automatically adapt an AUV’s path, based on new measurements that the vehicle takes as it explores a given region. Most adaptive sampling missions that consider risk typically do so by finding paths with a concrete, acceptable level of risk. For instance, AUVs may be programmed to only chart paths with a chance of collision that doesn’t exceed 5 percent.

But the researchers found that accounting for risk alone could severely limit a mission’s potential rewards. 

“Before we go into a mission, we want to specify the risk we’re willing to take for a certain level of reward,” Ayton says. “For instance, if a path were to take us to more hydrothermal vents, we would be willing to take this amount of risk, but if we’re not going to see anything, we would be willing to take less risk.”

The team’s algorithm takes in bathymetric data, or information about the ocean topography, including any surrounding obstacles, along with the vehicle’s dynamics and inertial measurements, to compute the level of risk for a certain proposed path. The algorithm also takes in all previous measurements that the AUV has taken, to compute the probability that such high-reward measurements may exist along the proposed path.

If the risk-to-reward ratio meets a certain value, determined by scientists beforehand, then the AUV goes ahead with the proposed path, taking more measurements that feed back into the algorithm to help it evaluate the risk and reward of other paths as the vehicle moves forward.

The researchers tested their algorithm in a simulation of an AUV mission east of Boston Harbor. They used bathymetric data collected from the region during a previous NOAA survey, and simulated an AUV exploring at a depth of 15 meters through regions at relatively high temperatures. They looked at how the algorithm planned out the vehicle’s route under three different scenarios of acceptable risk.

In the scenario with the lowest acceptable risk, meaning that the vehicle should avoid any regions that would have a very high chance of collision, the algorithm mapped out a conservative path, keeping the vehicle in a safe region that also did not have any high rewards — in this case, high temperatures. For scenarios of higher acceptable risk, the algorithm charted bolder paths that took a vehicle through a narrow chasm, and ultimately to a high-reward region.

The team also ran the algorithm through 10,000 numerical simulations, generating random environments in each simulation through which to plan a path, and found that the algorithm “trades off risk against reward intuitively, taking dangerous actions only when justified by the reward.”

A risky slope

Last December, Ayton, Williams, and others spent two weeks on a cruise off the coast of Costa Rica, deploying underwater gliders, on which they tested several algorithms, including this newest one. For the most part, the algorithm’s path planning agreed with those proposed by several onboard geologists who were looking for the best routes to find oil seeps.

Ayton says there was a particular moment when the risk-bounded algorithm proved especially handy. An AUV was making its way up a precarious slump, or landslide, where the vehicle couldn’t take too many risks.

“The algorithm found a method to get us up the slump quickly, while being the most worthwhile,” Ayton says. “It took us up a path that, while it didn’t help us discover oil seeps, it did help us refine our understanding of the environment.”

“What was really interesting was to watch how the machine algorithms began to ‘learn’ after the findings of several dives, and began to choose sites that we geologists might not have chosen initially,” says Lori Summa, a geologist and guest investigator at the Woods Hole Oceanographic Institution, who took part in the cruise.  “This part of the process is still evolving, but it was exciting to watch the algorithms begin to identify the new patterns from large amounts of data, and couple that information to an efficient, ‘safe’ search strategy.” 

In their long-term vision, the researchers hope to use such algorithms to help autonomous vehicles explore environments beyond Earth.

“If we went to Europa and weren’t willing to take any risks in order to preserve a probe, then the probability of finding life would be very, very low,” Ayton says. “You have to risk a little to get more reward, which is generally true in life as well.”

This research was supported, in part, by Exxon Mobile, as part of the MIT Energy Initiative, and by NASA.



from MIT News - Oceanography and ocean engineering http://bit.ly/2BbfNFI

martes, 22 de enero de 2019

Sallie “Penny” Chisholm awarded the 2019 Crafoord Prize

MIT Institute Professor Sallie “Penny” Chisholm of the departments of Civil and Environmental Engineering and Biology is the recipient of the 2019 Crafoord Prize.

Announced on Jan. 17, Chisholm was awarded the prize “for the discovery and pioneering studies of the most abundant photosynthesizing organism on Earth, Prochlorococcus.”

Prochlorococcus is a type of phytoplankton found in the ocean that is able to photosynthesize like plants on land.  The process of photosynthesis is responsible for the oxygen humans breathe, which makes it critical to life on Earth. Prochlorococcus accounts for approximately 10 percent of all ocean photosynthesis, which draws carbon dioxide out of the atmosphere, provides it with oxygen, and forms the base of the food chain.

While the organism is the most abundant photosynthesizer on the planet (the total amount of Prochlorococcus on Earth has been estimated to be 3*1027, or 3,000,000,000,000,000,000,000,000,000), it wasn’t until the mid-1980’s that Prochlorococcus was discovered by Chisholm and colleagues at the Woods Hole Oceanographic Institution. The reason the organism remained unknown for so long can be attributed to its small size. The tiny bacteria is half of a micrometer in size, 1/100 the width of a human hair, making it the smallest photosynthesizing organism.

Since its discovery, Chisholm and her team have found that although each cell has only 2,000 genes, the species as a whole has more than 80,000 different genes in its gene pool, which is four times more than the genetic makeup of humans. This vast diversity of genes distributed among the global population contributes to why Prochlorococcus is able to exist prominently in various environments containing different levels of light, heat, and nutrients.

Chisholm, who has been at MIT since 1976, now studies how Prochlorococcus interacts with various components of seawater and other microorganisms found in the ocean; its role in shaping the ocean ecosystem over evolutionary time; and how its populations may shift in response to climate change.

In April, Chisholm delivered a TED Talk that dove deeper into the properties of Prochlorococcus, comparing the organism’s genetic diversity to iPhone apps, and expanded on the the beauty of this microorganism as the smallest living thing that can convert solar energy and carbon dioxide into fuel through photosynthesis. Understanding its simple design could aid in efforts to engineer artificial photosynthesis machines — reducing our dependency on fossil fuels.  

Prochlorococcus has even inspired Chisholm to educate future generations of scientists through a series of children’s books called the “Sunlight Series,” with co-author and illustrator Molly Bang. The series describes the Earth’s natural processes in layman’s terms and through imagery. While none of Chisholm’s books mention Prochlorococcus by name, Chisholm says the simplicity of Prochlorococcus compelled her to create the series.

Chisholm will present her prize lecture in Sweden at Lund University on May 13, and will receive her prize at the Royal Swedish Academy of Sciences prize award ceremony on May 15, in the presence of H. M. King Carl XVI Gustaf and H. M. Queen Silvia of Sweden.

The Crafoord Prize is awarded in partnership between the Royal Swedish Academy of Sciences and the Crafoord Foundation, with the academy responsible for selecting the Crafoord Laureates. Awards are presented in one of four disciplines each year: mathematics and astronomy, geosciences, biosciences, or polyarthritis (such as rheumatoid arthritis).



from MIT News - Oceanography and ocean engineering http://bit.ly/2DrUgdr