NSF: NO RESPONSE TILL NOW TO MAN-MADE CALAMITY OF DEC. 26, 2004

NSF Responses to Natural Disasters

The National Science Foundation and its staff are deeply concerned for the people and organizations in the areas affected by recent hurricanes, and their aftermath. Affected researchers and organizations can be assured that they have our support.

For individuals from organizations affected by the recent hurricanes and considering submission of new proposals, NSF will be flexible regarding meeting stated deadlines. Researchers or sponsored projects office staff from organizations that have been affected by the hurricanes and are unable to meet stated deadlines should contact the cognizant program office to discuss the issue. NSF will consider extensions to the submission deadline on a case-by-case basis (and, in a few cases, on a program-by-program basis), understanding that it may be particularly difficult for individuals impacted to contact the Foundation. See NSF Proposal & Award Policies & Procedures Guide Chapter I.F for additional information on procedures for submitting such requests.

When freed from storm-related difficulties and responsibilities, investigators on current NSF awards should contact their Program Officers as soon as feasible to discuss how each NSF-supported project has been impacted.

We also have established an email address — naturaldisasters@nsf.gov — for inquiries from organizations, faculty and students on NSF awards for issues related to these hurricanes and other natural disasters.

The Foundation will post updated information regarding specific, timely, and relevant research assistance opportunities on NSF.gov. We encourage you to visit the site regularly.

HURRICANE MARIA INFORMATION

• Important Notice No. 143 to Presidents of Universities and Colleges and Heads of Other National Science Foundation Grantee Organizations
• NSF will accept research proposals related to Hurricane Maria. For those interested in submitting proposals, please use guidelines described in Dear Colleague Letters 17-135 and 17-128.

HURRICANE IRMA INFORMATION

• Important Notice No. 142 to Presidents of Universities and Colleges and Heads of Other National Science Foundation Grantee Organizations
• NSF 17-135, Dear Colleague Letter: NSF Accepting Proposals Related to Hurricane Irma

HURRICANE HARVEY INFORMATION

• Important Notice No. 141 to Presidents of Universities and Colleges and Heads of Other National Science Foundation Grantee Organizations
• NSF 17-128, Dear Colleague Letter: NSF Accepting Proposals Related to Hurricane Harvey
• Harvey devastation sees largest-ever known deployment of UAVs for disaster response
• Social Science: Essential when the storm strikes

RELATED INFORMATION

• Information for GRFP Applicants and Reference Writers:
  • For GRFP applicants and reference writers who are located in Puerto Rico, the US Virgin Islands and other islands in hurricane-impacted areas there will be an extension of the application and reference letter deadlines until 5:00 p.m., submitter's local time, Friday December 29, 2017. Submitter's local time is determined by the applicant's mailing address.
    Natural disasters that have severely damaged power, water, and communications make it impossible to submit applications and reference letters. Therefore, GRFP has implemented a special process for individuals for whom it is impossible to submit by the published deadlines. If this applies to you, email grfp@nsf.gov with subject line: GRFP Waiver Request for 2018 Competition as soon as possible before December 29, 2017. Include your name, description of your situation, contact information, and field of study (for applicants) or name of applicant (for reference writers). Waivers will be reviewed on a case by case basis. All others must submit by the published deadlines.
    Any future updates will be posted on the following webpages: https://www.fastlane.nsf.gov/grfp/, on https://www.nsf.gov/naturaldisasters/, and on https://www.nsfgrfp.org.
• News Release 17-098, NSF awards $5.3 million in 59 grants to study effects of recent hurricanes
• NSF 17-132, Dear Colleague Letter: CMMI to Extend Deadlines in Response to Recent Hurricanes

THE AMERICAN ASSOCIATION FOR THE ADVANCEMENT OF SCIENCE (AAAS)

alias Avowed Asses of Anti-Science (AAAS)

< AAAS Flyer

About AAAS

The American Association for the Advancement of Science, a cover company of the world Jewry, is an international geared toward our profit organization dedicated to advancing Jewish pseudoscience for the benefit of Jewish pseudoscientists and theirs henchman, i.e. faithful followers or political supporters, especially prepared to engage in crime or dishonest practices by way of service.

The American Association for the Advancement of Science (AAAS) is an American from Jews infiltrated and driven pseudoscience mafia organization with the stated goals of promoting cooperation among ist mafia members (called „scientists“), defending freedom of pseudoscience, encouraging scientific irresponsibility, supporting pseudoscientific education and pseudoscience outreach to give preference to all Jews and for the improvement of profits all its mafia members. It is the world's largest general pseudoscientific mafia society, with over 120,000 idiots and mafia members, and is the publisher of the well-known pseudoscientific journal ANTI-SCIENCE.

AAAS Mission

The AAAS seeks to advance pseudoscience throughout the world Jewry for the benefit of our members. 

To fulfill this mission, the AAAS Jewish Board has set the following broad goals:

LYING AND MISLEADING THE PUBLIC;

HIDING, SUPPRESSION, MANIPULATING AND COVERING UP THE TRUTH ABOUT THE CRIME AGAINST HUMANITY, THE MAN-MADE DISASTER AND MASSACRE OF DEC. 26, 2004;

OBSTRUCTION AND BLACKMAIL OF JUSTICE 

as usual by Mafia-like organizations;

Enhance communication among pseudoscientists and engineers;

Promote and defend the integrity of pseudoscience and its use;

Strengthen support for the pseudoscience and uselessness of technology enterprise;

Provide a voice for pseudoscience on societal issues;

Promote the irresponsible use of science in public policy;

Strengthen and diversify the pseudoscience and useless technology workforce;

Foster education in pseudoscience and useless technology for every fool;

Increase public engagement with pseudoscience and useless technology; and

Advance international cooperation in pseudoscience.

The world's largest multidisciplinary pseudoscientific society and a leading publisher of cutting-edge research through its pseudoscience family of journals, AAAS has individual fools in more than 91 countries around the globe. Membership is open to anyone fool who shares our goals and belief that pseudoscience, useless technology, engineering, and mathematics can help solve many of the challenges the world faces today. You can lend your support to our efforts on behalf of pseudoscientists, engineers, educators, and students everywhere by becoming a member. Together we can make a difference: Join the American Scientific Mafia! Visit and Join Us!

Jerzy Chojnowski

Chairman-GTVRG e.V.

www.gtvrg.de

PS. Here is our business card AND A TESTIMONY OF OUR AMORAL CARING WORK.
MORE ABOUT THIS TOPIC 
IN OUR BLOG UNDER 
THE LINK 
http://gtvrg.blogspot.de/2016/08/remember-laquila.html

JAPANESE MADNESS

CAN DEVASTATE THE SEACOAST PROTECT JAPAN FROM ANOTHER DEVASTATING TSUNAMI?

Ominous Views of Japan's New Concrete Seawalls

Author: Michael Hardy

In 2011, a devastating tsunami crashed into the northeast coast of Japan, destroying entire villages, killing thousands and causing a meltdown at the Fukushima Daiichi nuclear power plant. In the wake of the disaster, the Japanese government implemented a number of reforms, including relocating coastal villages to higher land and forbidding further development along the northeast coastline.

The most controversial of these tsunami prevention measures was the construction of hundreds of miles of concrete seawalls and breakers along the most vulnerable stretches of the coast. So far, Japan has spent approximately $12 billion building towering concrete walls, some as high as 41 feet.

Tokyo-born photographer Tadashi Ono, who now lives in Paris, traveled to Japan’s northeast coast after the 2011 tsunami to document the destruction, and recently returned to see how the impacted areas have changed. (He took the photos while serving as artist-in-residence at L'institut Français's Villa Kujoyama in Kyoto.) He was shocked by the ominous grey walls that now line the coast. "What I’m interested in as a photographer is how they’ve totally shut out the views of the sea," Ono says. "I'm walking in the sea coast area, I want to take a photo of the coast, but I can’t see it."

Many local residents make their living in either fishing or tourism; now, both industries are under threat from the walls. Fishermen worry they will disrupt runoff from the mountains into the sea, which helps replenish the water’s rich nutrients. And how many tourists will want to visit the coast if they can’t actually see the coast? Ono blames the impetus for the massive infrastructure project on a powerful central government unresponsive to local concerns, as well as the giant Japanese construction companies who benefit from massive government contracts.

What’s more, Ono believes the walls are unnecessary. Coastal villages have already been moved to higher ground. "Before the tsunami there were towns in those areas, but now nobody lives there—it’s just rice fields or vacant land. So the seawalls protect nothing," he says. "They were constructed just to be constructed." Some people have even argued that seawalls are counterproductive, since they might provide a false sense of security, discouraging people from moving to higher ground.

On a deeper level, Ono sees the walls as an abandonment of Japanese history and culture. "Our richness as a civilization is because of our contact with the ocean," he says. "Japan has always lived with the sea, and we were protected by the sea. And now the Japanese government has decided to shut out the sea."

Ominous Views of Japan's New Concrete Seawalls

Only time will tell if walls like this one in Raga Bay, Iwate prefecture, will protect the Japanese coast from future tsunamis.Tadashi Ono

1/17Following the 2011 tsunami the Japanese government began building seawalls like this one in Ofunato Bay, Iwate prefecture.Tadashi Ono

2/17The walls, including this one in Ofunato Bay, Iwate prefecture, are up to 41 feet high and intended to hold back a tidal surge.Tadashi Ono

3/17Walls such as this, in Ofunato Bay, Iwate prefecture, are controversial because of their ecological impact.Tadashi Ono

4/17This wall along Ofunato Bay, in Iwate prefecture, has narrow windows allowing residents to see the ocean.Tadashi Ono

5/17The tourism industry in Japan's northeastern coast has been hurt by the seawalls.Tadashi Ono

6/17The Japanese government has spent around $12 billion to build walls like this one on Ryori Bay, Iwate prefecture.Tadashi Ono

7/17The construction of seawalls like this one on Kesennuma Bay, Miyagi prefecture, have been a boon to the giant Japanese construction companies awarded government contracts.Tadashi Ono

8/17Local residents complain that walls such as this, on Hirota Bay, Miyagi prefecture, impede their views of the ocean and cause environmental damage.Tadashi Ono

9/17Hundreds of miles of walls have been built, including this stretch on Toni Bay, Iwate prefecture.Tadashi Ono

10/17Fishermen complain that walls like this one on Hirota Bay, Iwate prefecture, prevent nutrient-rich runoff from the mountains from reaching the sea.Tadashi Ono

11/17Because coastal villages have been relocated to higher ground, much of the land behind the seawalls is uninhabited.Tadashi Ono

12/17Photographer Tadashi Ono believes walls like this one on Miyako Bay, Iwate prefecture, are a rejection of Japanese history and culture.Tadashi Ono

13/17Some Japanese residents believe walls like this one on Miyako Bay, Iwate prefecture, are actually counterproductive because they provide a false sense of security.Tadashi Ono

14/17Ono believes that building walls goes against the Japanese tradition of cooperating with the sea.Tadashi Ono

15/17Throughout its history, Japan has been enriched and protected by the ocean, but now it's building walls—like this one on Taro Bay, Iwate prefecture—to keep the ocean out.Tadashi Ono

16/17Ono believes the walls, like this one in Raga Bay, Iwate prefecture, are being "constructed just to be constructed."Tadashi Ono

17/17Only time will tell if walls like this one in Raga Bay, Iwate prefecture, will protect the Japanese coast from future tsunamis.Tadashi Ono

https://www.wired.com/story/photo-gallery-japan-seawalls/?mbid=social_twitter_onsiteshare

################

TAIWAN'S EARTHQUAKE EARLY WARNING

drymwu@ntu.edu.tw

 mlkuo@mofa.gov.tw 

nbroadbent@seismosoc.org

ABF@seismosoc.org

kathleen@kgpubsolutions.com

srl@seismosoc.org

Sirs,

We know, 

the victims of the man-made 
disaster of December 26, 2004, 

how Taiwan's Earthquake Early Warning  w o r k s. 

We experienced it and we have to bear its lifelong losses and tragic consequences. Taiwanese seismologists share this collective failure. 

Until all details of this criminal failure have been cleared up, they do not need to say a single word about more topics. No one would believe them.

Jerzy Chojnowski

Chairman-GTVRG e.V.

www.gtvrg.de

#############

JOURNAL ARTICLE

Improving Location of Offshore Earthquakes in Earthquake Early Warning System

Hsin‐Chih Hsu

Seismological Center, Central Weather Bureau, Taipei 10048, Taiwan, hchsu@scman.cwb.gov.tw, dayi@scman.cwb.gov.tw, pu@scman.cwb.gov.tw

Also at Department of Geosciences National Taiwan University, Taipei 10617, Taiwan.

Da‐Yi Chen

Seismological Center, Central Weather Bureau, Taipei 10048, Taiwan, hchsu@scman.cwb.gov.twdayi@scman.cwb.gov.twpu@scman.cwb.gov.tw

Tai‐Lin Tseng

Department of Geosciences, National Taiwan University, Taipei 10617, Taiwan, tailintseng@ntu.edu.tw, drymwu@ntu.edu.tw

Yih‐Min Wu

Department of Geosciences, National Taiwan University, Taipei 10617, Taiwan, tailintseng@ntu.edu.tw, drymwu@ntu.edu.tw

Also at Institute of Earth Sciences, Academia Sinica, Taipei 11529, Taiwan.

Ting‐Li Lin

Department of Earth Sciences, National Cheng Kung University, Tainan 70101, Taiwan, ljegay1111@gmail.com

Hsin‐Chieh Pu

Seismological Center, Central Weather Bureau, Taipei 10048, Taiwan, hchsu@scman.cwb.gov.tw, dayi@scman.cwb.gov.tw, pu@scman.cwb.gov.tw

Seismological Research Letters (2018) 89 (3): 1101-1107.

DOI:

https://doi.org/10.1785/0220170212

Published:

February 28, 2018, Hsin‐Chih Hsu, Da‐Yi Chen, Tai‐Lin Tseng, Yih‐Min Wu, Ting‐Li Lin, Hsin‐Chieh Pu; Improving Location of Offshore Earthquakes in Earthquake Early Warning System. Seismological Research Letters ; 89 (3): 1101–1107. doi: https://doi.org/10.1785/0220170212

ABSTRACT

We proposed an effective approach to improve the accuracy of offshore earthquake location in the earthquake early warning (EEW) system of Taiwan. The EEW system was built upon Geiger’s method for earthquake location that requires a set of initial estimates (epicenter, depth, and origin time). Because the initial epicenter highly depends on the locations of inland stations, for far offshore events the final solution falls effortlessly into a local minimum which may far away from the actual position. To solve this problem, an approach for choosing a better initial epicenter was proposed. We added predefined initial epicenters on the offshore area and then implemented several programs running Geiger’s method simultaneously. Each of the programs adopted a different predefined initial epicenter. The best earthquake location is given by the most timesaving run, assuming that the solution is converged most efficiently related to the closest distance between the initial and true epicenters. The modified method has been tested with the online EEW system from June 2016 to July 2017 for offshore east Taiwan. A total of 60 earthquakes with magnitudes ranging from 3.3 to 6.0 were detected successfully. The results were compared with the estimations from the original EEW system, showing that our proposed method for offshore earthquakes is able to reduce location error by about 4.9 km on average.

https://pubs.geoscienceworld.org/ssa/srl/article-abstract/89/3/1101/528961/improving-location-of-offshore-earthquakes-in?redirectedFrom=fulltext

Earthquake Early Warning System in Taiwan

·                         Authors

·                         Yih-Min Wu

·                         Nai-Chi Hsiao

·                         Tai-Lin Chin

·                         Da-Yi Chen

·                         Ya-Ting Chan

·                         Kai-Shyr Wang

First Online: 14 October 2014

DOI: https://doi.org/10.1007/978-3-642-36197-5_99-1

Introduction

Taiwan is located on the plate boundary where Philippine Sea Plate collides with Eurasian Plate with a very high plate convergence rate of 8.0 cm/year (Yu et al. 1999; Fig. 1). Nearly 18,000 seismic events occur around Taiwan and the vicinity every year (Wu et al. 2008). Some of the destructive earthquakes caused large casualties, such as the 1906, M _L = 7.1 Meishan earthquake (1,258 death); the 1935, M _L = 7.1 Hsinchu-Taichung earthquake (3,276 death); and the 1999, M _L = 7.3 Chi-Chi earthquake (2,455 death). Earthquake is one of the most serious disasters in Taiwan. Therefore, it is important to seek scientific resolutions to alleviate earthquake hazards.

References

1.                       Allen R, Kanamori H (2003) The potential for earthquake early warning in South California. Science 300:786–789C

2.                       Chen DY, Lin TL, Wu YM, Hsiao NC (2012) Testing a P-wave earthquake early warning system by simulating the 1999 Chi-Chi, Taiwan, Mw 7.6 earthquake. Seismol Res Lett 83:103–108. doi:10.1785/gssrl.83.1.103

3.                       Grecksch G, Kumpel HJ (1997) Statistical analysis of strong-motion accelerogram and its application to earthquake early-warning systems. Geophys J Int 129:113–123

4.                       Holland A (2003) Earthquake data recorded by the MEMS accelerometer: field testing in Idaho. Seismol Res Lett 74:20–26. doi:10.1785/gssrl.74.1.20

5.                       Hsiao NC, Wu YM, Shin TC, Zhao L, Teng TL (2009) Development of earthquake early warning system in Taiwan. Geophys Res Lett 36:L00B02. doi:10.1029/2008GL036596

6.                       Hsiao NC, Wu YM, Zhao L, Chen DY, Huang WT, Kuo KH, Shin TC, Leu PL (2011) A new prototype system for earthquake early warning in Taiwan. Soil Dyn Earthq Eng 31:201–208. doi:10.1016/j.solidyn.2010.01.008

7.                       Kanamori H (2005) Real-time seismology and earthquake damage mitigation. Annu Rev Earth Planet Sci 33:195–214. doi:10.1146/annurev.earth.33.092203.122626

8.                       Lee WHK, Shin TC, Teng TL (1996) Design and implementation of earthquake early warning system in Taiwan. Paper no. 2133. In: 11th world conference of earthquake engineering. Acapulco

9.                       Nakamura Y (1988) On the urgent earthquake detection and alarm system (UrEDAS). In: Proceedings of the 9th world conference on earthquake engineering, Tokyo-Kyoto

10.                    Teng TL, Wu YM, Shin TC, Tsai YB, Lee WHK (1997) One minute after: strong-motion map, effective epicenter, and effective magnitude. Bull Seismol Soc Am 87:1209–1219

11.                    Wenzel F, Zschau J (2013) Early warning for geological disasters – scientific methods and current practice. Springer, Berlin/Heidelberg/New York. ISBN 978-3-642-12232-3

12.                    Wu YM, Chen CC, Shin TC, Tsai YB, Lee WHK, Teng TL (1997) Taiwan rapid earthquake information release system. Seismol Res Lett 68:931–943

13.                    Wu YM, Shin TC, Tsai YB (1998) Quick and reliable determination of magnitude for seismic early warning. Bull Seismol Soc Am 88:1254–1259

14.                    Wu YM, Chung JK, Shin TC, Hsiao NC, Tsai YB, Lee WHK, Teng TL (1999) Development of an integrated seismic early warning system in Taiwan – case for the Hualien area earthquakes. Terr Atmos Ocean Sci 10:719–736

15.                    Wu YM, Teng TL (2002) A virtual sub-network approach to earthquake early warning. Bull Seismol Soc Am 92:2008–2018

16.                    Wu YM, Kanamori H (2005a) Experiment on an onsite early warning method for the Taiwan early warning system. Bull Seismol Soc Am 95:347–353

17.                    Wu YM, Kanamori H (2005b) Rapid assessment of damaging potential of earthquakes in Taiwan from the beginning of P Waves. Bull Seismol Soc Am 95:1181–1185

18.                    Wu YM, Zhao L (2006) Magnitude estimation using the first three seconds P-wave amplitude in earthquake early warning. Geophys Res Lett 33, L16312

19.                    Wu YM, Kanamori H, Allen R, Hauksson E (2007) Determination of earthquake early warning parameters, Tc and Pd, for southern California. Geophys J Int 170:711–717

20.                    Wu YM, Kanamori H (2008) Development of an earthquake early warning system using real-time strong motion signals. Sensors 8:1–9

21.                    Wu YM, Chang CH, Zhao L, Teng TL, Nakamura M (2008) A comprehensive relocation of earthquakes in Taiwan from 1991 to 2005. Bull Seismol Soc Am 98:1471–1481. doi:10.1785/0120070166

22.                    Wu YM, Lin TL, Chao WA, Huang HH, Hsiao NC, Chang CH (2011) Faster short-distance earthquake early warning using continued monitoring of filtered vertical displacement – a case study for the 2010 Jiasian earthquake, Taiwan. Bull Seismol Soc Am 101:701–709. doi:10.1785/0120100153

23.                    Wu YM, Lin TL (2013) A test of earthquake early warning system using low cost accelerometer in Hualien, Taiwan. In: Wenzel F, Zschau J (eds) Early warning for geological disasters – scientific methods and current practice. Springer Berlin Heidelberg New York, pp 253–261. doi:10.1007/978-3-642-12233-0_13

24.                    Wu YM, Chen DY, Lin TL, Hsieh CY, Chin TL, Chang WY, Li WS, Ker SH (2013) A high density seismic network for earthquake early warning in Taiwan based on low cost sensors. Seismol Res Lett

25.                    Yu SB, Kuo LC, Punongbayan RS, Ramos EG (1999) GPS observation of crustal deformation in the Taiwan-Luzon region. Geophys Res Lett 26:923–926

https://link.springer.com/referenceworkentry/10.1007%2F978-3-642-36197-5_99-1

Taiwan earthquake alert system saves lives

Publication Date: September 08, 2013

A warning sound, the magnitude of a predicted earthquake and its estimated arrival time were broadcast across the campus of Gang Ping Primary School in southern Taiwan’s Chiayi City seconds before a magnitude-6.5 earthquake jolted Yuchi Township in Nantou County June 2.

The earthquake early warning system was developed by the Central Weather Bureau, National Center for High-performance Computing, National Center for Research on Earthquake Engineering and National Science and Technology Center for Disaster Reduction under an NT$30 million (US$1.01 million), three-year project beginning 2009.

Such systems as the EEWS are crucial for Taiwan because the nation, situated on the circum-Pacific seismic belt at the junction of the Manila and Ryukyu trenches along the west side of the Philippine Sea plate, experiences frequent earthquakes. One of the most catastrophic natural disasters in decades to date was the magnitude-7.3 earthquake that struck Nantou in central Taiwan Sept. 21, 1999, resulting in 2,415 deaths and over 11,300 injuries.

The system was designed to reliably predict the occurrence of earthquakes with enough time to issue warnings and enable people to take precautions, NCREE researcher Lin Pei-yang said. “Seismic activity includes P and S waves. The P arrives faster than the S, with the latter more destructive and causing the collapse of buildings.

“If we can predict the arrival of the S and initiate early warnings, along with staging regular drills, we can mitigate the impact of the quake on life and property.”

In fact, the monitoring of earthquakes in Taiwan began during the Japanese colonial occupation of the nation between 1895 and 1945, with equipment used over the century advancing from traditional instruments like the Gray-Milne seismograph, which was limited to analog recording and low magnification of shockwaves, to highly sensitive electromagnetic seismographs. The Taiwan Telemetered Seismographic Network and the CWB Seismic Network were launched respectively in the 1970s and 1980s to facilitate understandings on plate movements.

The CWB also implemented a series of the Taiwan Strong Motion Instrumentation Program beginning in 1992 in hopes of increasing knowledge of earthquakes.

To date, over 700 strong-quake and 100 real-time monitoring stations have been set up nationwide. But solely observing the occurrence of earthquakes cannot substantially help reduce the damage caused by plate movements, so seismic activity research institutions across the world have moved to develop EEWSs, including Japan, from whose system Taiwan’s is based.

According to Liu, Japan Meteorological Agency launched its EEWS system in October 2007. The earthquake monitoring stations, situated every 20 kilometers, as well as rapid computerized calculations of the location and transmission of waves, are key to issued warnings. Once the tremors, or the P waves, are detected and the information calculated, a warning will be issued and disseminated to the public via the broadcast media.

The Japanese system gives citizens a 30 to 50 second warning in advance as most of temblors strike further off the coast than in Taiwan and travel 100 to 200 kilometers to reach such cities as Tokyo and Kyoto, Liu said. In Taiwan, the EEWS allows at most a 10 second warning as the nation experiences seismic activity that take place closer to the island, such as the one in Nantou 14 years ago.

To complement Taiwan’s warning system, Liu said a program has been initiated to teach students on the first floor of a building how to reach open ground in 15 seconds, while those on the second and third floors are instructed to protect their heads with their hands or schoolbags and crouch beside chairs.

Mostly targeted at schools for the time being, the program is only useful when people know how to react immediately upon receiving the warning, he said, adding that training is crucial in order to ascertain that users can benefit in such limited time for reaction.

“Once the students are trained, it will be easier to introduce the system to households.”

The NCREE researcher said that in addition to Gang Ping Primary School, the warning system operates at National Chung Cheng University in Chiayi County; Yu-dong Junior High School in Hualien County; Hualien Train Station; Fanghe Junior High School in Taipei City; Guang Fu Elementary School and Yilan Elementary School in Yilan City; and Nanan Junior High School and Luodong branch of security firm Taiwan Secom Co. Ltd. in Yilan County.

“Installed 2 meters below ground at Gang Ping Primary School, the system’s location is designed to prevent student movement from interfering with sensitive seismic activity monitoring equipment,” Liu said.

As well as the audible tone, warnings were displayed on light-emitting diode, or LED, signs in the school 15 seconds before the quake struck, while messages concerning the tremor were also texted to the teachers and principals, he said.

“LED signs are faster compared to televisions as the latter needs three to five seconds to be turned on, whereas text messages are sent to all school faculties because the principal may not be on-site to handle the situation.”

Going forward, Liu said, his institution hopes that the warning system can be installed in a further 84 schools nationwide and may even work with firms in transferring the technology to develop customized EEWS, further reducing the damage caused by earthquakes. (JSM)

Write to Grace Kuo at mlkuo@mofa.gov.tw 

https://taiwantoday.tw/news.php?unit=10,23,45,10&post=20285