GPS Could Speed Tsunami Warnings

http://www.wired.com/news/technology/0,1282,69847,00.html?tw=rss.TOP

By Elizabeth Svoboda
02:00 AM Dec. 19, 2005 PT

GPS satellite receivers are already navigational must-haves for hikers and drivers. Now scientists are hatching plans to press them into service as tsunami predictors.

International organizations like the Pacific Tsunami Warning Center, or PTWC, in Hawaii currently depend on coastal seismic stations to record deep-sea earthquakes that could cause giant waves. But according to Jeff Freymueller, a geophysicist at the University of Alaska Fairbanks, data from GPS receivers could provide quicker, more accurate estimates of the magnitude of a tsunami-causing quake, buying time for evacuation. Freymueller presented his findings at this week's American Geophysical Union conference in San Francisco.

Unlike seismometers, GPS receivers can measure the movement of the ground in real time. Because quake magnitude is a direct function of how much the earth shifts, Freymueller has demonstrated that the receivers can obtain precise measurements of a massive quake's severity in as little as 20 minutes.

"Seismometers measure the velocity of the ground, and you have to collect a number of cycles of the important wave in order to get that measurement," he said. "GPS receivers measure the static displacement of the earth, and after the first few minutes of a quake, that doesn't change much."

Freymueller envisions a new tsunami-warning strategy that would use seismic and GPS data in tandem to calculate a wave-causing quake's strength soon after its onset. This would enable more-accurate computer simulations of the coming wave, allowing more-targeted evacuation strategies. Planting the receivers every hundred miles in tsunami-prone areas, he added, could be done in a matter of months, and each receiver would cost less than $10,000.

"Early warnings from GPS could save thousands of lives," he said. "In last year's Indian Ocean tsunami, there were potentially one to two hours for evacuation, had an accurate warning system been in place. Every minute counts."

Seismic measurements of very large quakes like the one that caused last year's Indian Ocean tsunami take several hours to fine-tune, because the moving vibrations must be recorded at a variety of stations in different locations. When the quake that caused the giant Southeast Asian wave first hit, scientists at the PTWC estimated its magnitude at 8.0, but revised their estimate to 8.5 an hour later. After a few more hours passed, a team at Harvard University pegged the quake at 8.9. The final reading, 9.2, was not agreed upon until months afterward.

Yehuda Bock, a geologist at the Scripps Institution of Oceanography, has also investigated the possibilities of using GPS receivers in tsunami-warning systems. His results are similar to Freymueller's, indicating the receivers can gauge the ground movements created by tsunami-causing quakes with unprecedented precision and speed.

"With GPS, the displacements are measured second by second," said Bock, who also presented at the American Geophysical Union conference. "Within 70 seconds you have a good idea of the final deformation." In addition to predicting tsunamis, he thinks GPS modules could be used to monitor the activity of volcanoes and landslides in real time.

Like Freymueller and Bock, Peter MacDoran, a GPS expert who works for George Washington University's Space and Advanced Communications Research Institute, wants to make GPS receivers part of disaster-prediction networks. But he foresees using them in a different way: to track the movement of tsunami-associated pressure waves in the Earth's atmosphere.

"Quakes that cause tsunamis create deformation on the surface of the water, and that causes an atmospheric 'thump,'" MacDoran said. "A compression wave travels into the upper atmosphere, and that disturbance causes subtle changes in the way GPS signals travel." Digital processing of the changed signals coming from nearby receivers would indicate that a tsunami was imminent.

MacDoran has proposed setting up networks of GPS-connected personal computers to monitor these signals, especially in tsunami-prone areas like Southeast Asia, the United States' Atlantic coast and the Pacific Northwest.

He emphasized, however, that his goal is to complement seismic-based tsunami-detection strategies, not replace them. "The quake sensors we have work well. Seismic sensing is a highly developed art," he said. "It just doesn't give you all the information you need."

How to Build a Global Internet Tsunami Warning System in a Month

Cringley is a respected technology forecaster. Here are his words from almost a year ago, and yet we have no such system in place. His idea could work, from my personal reading of the problem statement, it doesn't seem that hard. Where have all the volunteer programmers gone?

-- tsunamiwarning

(Source: http://www.pbs.org/cringely/pulpit/pulpit20041230.html)

December 30, 2004

Wave of Change

How to Build a Global Internet Tsunami Warning System in a Month

By Robert X. Cringely

A friend of mine is missing in southern Asia.

She isn't missing in the sense that anyone saw her swept away by this week's horrible tsunami, but she and her entire family haven't been heard from, either so of course, I am worried. That worry makes real for me a disaster of such horrific proportions that without a personal connection, it simply can't be real to most of us. By the time all the bodies have been counted and estimated, probably 100,000 people will have died. If cholera follows, as it tends to in that part of the world, another 40,000 or more could follow. That's a lot of people, 140,000 -- enough people that we ought to do something to make sure it doesn't happen again. So of course, there is lots of talk about tsunami warning systems and global cooperation, but I think that's just going about solving the problem the wrong way. We don't need governments and huge sensor arrays to warn people on the beach about the next huge wave approaching at 400 miles-per-hour. Thanks to the Internet, we can probably do it by ourselves.

Here's the problem with big multi-government warning systems. First, we have a disaster. Then, we have a conference on the disaster, then plans are proposed, money is appropriated, and three to five years later, a test system is ready. It isn't the final system, of course, but it still involves vast sensor arrays both above and below the surface of the ocean, satellite communication, and a big honking computer down in the bowels of the Department of Commerce or maybe at NASA. That's just the detection part. The warning part involves multilateral discussions with a dozen nations, a treaty, more satellite communication, several computer networks, several television and radio networks, and possibly a system of emergency transmitters. Ten years, a few million dollars and we're ready.

We can't rely on governments to do this kind of work anymore. They just take too darned long and spend too much money for what you get. Besides, since governments are almost totally reactive, what they'll build is a warning system for precisely the tsunami we just had -- a tsunami bigger than any in that region since the eruption of Krakatoa in 1883. One could argue (and some experts probably will) that it might even be a waste of money to build a warning system for a disaster that might not happen for another 121 years.

What we need is a tsunami warning system not just for parts of Asia, but for anywhere in the world that might be subject to such conditions. And that decision about what beaches to protect ought to come not from Washington, D.C., or Jakarta, or any other capital city, but from the beach people, themselves. If you are concerned about a giant tidal wave taking out your village, it might be a good idea to build your own warning system, you retired engineer, you Radio Shack manager, you harbor master, you radio amateur, you nerd with a suntan.

It can be done.

The Tsunami Warning System (TWS) in the Pacific Ocean shows us how such a warning system can be run with the cooperation of 26 countries. Maybe we can do the same thing, just without all that cooperation. TWS is based on crunching two kinds of data -- seismic activity and changes in sea level measured by tide gauges. Most tsunamis begin with an earthquake, the severity and epicenter of which can tell a lot about whether a tsunami is likely, how strong it will be, and in what direction it is likely to go. From the TWS, the first warning is based purely on such seismic data. But once the big wave starts rolling it will have an effect on the level of the sea, itself, which is routinely monitored by weather stations of many types. This additional data gives a better idea of how bad the wave is really going to be, so in the TWS system, it is used to justify expanding the warning to other communities beyond those warned purely on the basis of seismic data.

Depending on where the originating earthquake is, the tsunami can be minutes or hours from crashing into a beach. This week's wave took about 90 minutes to reach Sri Lanka, just over 600 miles from the epicenter. That not only means the wave was traveling at over 400 miles-per-hour, it also means that had a warning system been in place, there would easily have been time to get the people who were affected in Sri Lanka to higher ground.

So to start, we need raw seismic data. If you take a look at the fourth of this week's links, you'll see that plenty of such data are available. Thanks to the Pacific Northwest Seismograph Network, here is one place where you can find real time data from 199 seismographs around the world. There are also links to a dozen regional operations that consolidate such data. The data is available. Tide gauge data is available, too, though there is less of it, and aggregation will require more effort, so I say let's just stick to seismic data for our warning system.

Here's where we need the help of a tsunami expert, someone who can help us calculate the size and direction of a likely tsunami based on the available seismic data. Fortunately, there has been quite a bit of work done in this area of study (see link #5), and appropriate computer codes that can be run on a personal computer either exist or can be derived, perhaps by reflexively evaluating seismic data from known tsunami events. But remember that what we care about here is not global tsunami warning but LOCAL tsunami warning (Is it going to hit MY beach?), so the required seismic data sources can pretty easily be limited to those with an uninterrupted aspect of the target beach, which means half a dozen seismographs, not 199.

Since the basic question is fairly simple -- "Is my beach going to be hit by a destructive tsunami and when?" -- and the required data sources are limited, I figure we won't need a supercomputer.

The seismographs are online, we gather the data using XML, continuously crunch it using the codes I am assuming already exist, then we need the warning, which I would flash on the screen of my PC down at the surf shop using a Javascript widget built with Konfabulator, the most beautiful widget generator of all. Looking just like a TV weather map, the widget would flash a warning and even include a countdown timer just like in the movies.

You don't need an international consortium to build such a local tsunami warning system. You don't even need broadband. The data is available, processing power is abundant and cheap. With local effort, there is no reason why every populated beach on earth can't have a practical tsunami warning system up and running a month from now. That's Internet time for you, but in this case, its application can protect friends everywhere from senseless and easily avoidable death.

Links of the Week

Computerworld
Computerworld says we need a tsunami warning network.
(http://www.computerworld.com/managementtopics/management/
itspending/story/0,10801,98582,00.html?source=NLT_PM&nid=98582)

Krakatoa
Krakatoa in 1883 was a far bigger seismic event, but loss of life was less simply because the coastal populations then were smaller.
(http://www.alertnet.org/thenews/newsdesk/SP134319.htm)

Tsunami Warning System
There already is a tsunami warning system for the Pacific Ocean, just not one for the Indian Ocean.
(http://www.geophys.washington.edu/tsunami/general/
warning/warning.html)

Raw Seismic Data
Raw seismic data and plenty of it.
(http://www.geophys.washington.edu/seismosurfing.html)

Konfabulator
Konfabulator, my favorite widget builder.
(http://www.konfabulator.com)

Official announcement : An Indian Tsunami early warning system in the Indian Ocean soon

Thursday, December 15, 2005

PRESS INFORMATION BUREAU, GOVERNMENT OF INDIA

SETTING UP OF AN EARLY WARNING SYSTEM FOR TSUNAMI AND STORM SURGES IN INDIAN OCEAN

16:41 IST

Rajya Sabha

The Government is setting up an Early Warning system for Tsunami and Storm Surges in Indian Ocean at the total cost of Rs. 125 crores with the following components:

Strengthening of the existing seismological network to indicate, near real time occurrence of tsunamigenic earthquakes;

Installation of tsunami warning sensors close to the ocean bottom at appropriate locales in the Indian Ocean, with real time connectivity;

Tide gauge and data buoys networking to validate arrival of tsunami waves at the coast;

Modelling of the inundation scenarios for the entire coast and mapping of potential risk areas;

Collection of information, analysis and generating status advisories.

A centre would be set up at Indian National Centre for Ocean Information Services (ICOIS), Hyderabad, Andhra Pradesh on a 24X7 basis. The system is scheduled to be operationalized by September, 2007. The Tsunami Warning System is for the whole country.

In a written reply in Rajya Sabha, the Minister for Science and Technology and Ocean Development, Shri Kapil Sibal said there is no assistance taken from foreign firms in this regard. He said the Indian system is the best system for our country.

PRA:AD:NC