WeatherZine #23
Number 23, August 2000


"What's happening on the Societal Aspects of Weather WWW Site."

WeatherZine is a bi-monthly on-line and e-mail distribution newsletter
for the Societal Aspects of Weather Site. It contains a summary of
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Contents:

[1] Editorial 
      Policy research for atmospheric scientists

[2] Guest Editorial
      How much "skill" is there in forecasting El Nino?
      By Chris Landsea and John Knaff 
            
[3] Correspondence 
      Correspondence from our readers

[4] Weather-Related News
      New Mailing List - The use of the Internet in Disaster Situations
      
[5] New Additions to the WWW Site:
      El Nino/La Nina
      Emergency Management
      Floods
      Summer/Winter
      General Weather Resources
      Insurance

[6] Subscribe Now!

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[1] Editorial -- Policy research for atmospheric scientists

In recent months I've received a steadily increasing number of 
inquiries from students and faculty in the atmospheric sciences 
asking about atmospheric sciences policy, what it is and how 
one might approach this area of scholarship.  Here are some 
suggestions.

Most importantly, become an expert.  Your ability to contribute 
valuable knowledge depends upon your particular expertise.  
If you are the world's expert in a particular area, then you 
will have a much stronger basis for contributing to society's 
needs.  Too often, however, knowledge of policy winds up being 
very broad and not very deep, and universities that seek to 
develop such expertise (e.g., generic "environmental studies" 
programs come to mind) often face criticism from their 
disciplinary colleagues.  But a word of caution is also due: 
being an expert in one area does not mean that you are an expert 
in other areas.  

But recognize that "expert" does not have to be a synonym for 
"narrow."  Of course, if your expertise is in a very narrow 
area, then your contributions to policy can be limited. Then 
again, in 1970 an expert on the then-obscure topic of the 
atmospheric properties of chlorofluorocarbons could not have 
anticipated the policy significance of this work over the next 
three decades.  But if you would like to enhance the chances that 
your expertise is relevant to policy, then there are other 
types of expertise that have broad relevance across policy topics.  
For example, with the growing emphasis on the use of forecasts by 
decision makers, in coming years there will likely be a great 
need for experts in forecast verification.  And a focus on policy 
decision processes, either in general or in the context of a 
particular area of science - like chlorofluorocarbons - will 
enhance the relevance of your expertise.  Once, an expert was 
defined as someone who broke knowledge into small pieces and knew 
an awful lot about one small piece.  Increasingly, the needs of 
policy require experts who can integrate diverse areas of knowledge.

If you include a focus on problems and decisions as "units of 
analysis" in your research then you will enhance the potential 
relevance of your work.  Typically researchers focus on phenomena 
(e.g., storms, precipitation) and processes (e.g., ENSO, radiative 
forcing).  Usually this sort of specialized knowledge is necessary 
but not sufficient in the policy making process.  Ultimately, 
decision makers want to know the answer to the question: "So what?"  
You will be in a much better position to contribute to the answer 
if you can clearly link your specialized knowledge of phenomena 
and processes with "Is this a problem?  For whom? Of what magnitude?  
What can be done? What should be done?" Etc.  Recognize that the 
answers to these questions often require the integration of a broad 
range of expertise.

Practice suspending judgment.  Good judgment, as John Dewey has 
written, requires that "we defer conclusions in order to infer 
more thoroughly."  It is this willingness to entertain alternative 
explanations and solutions that distinguishes the policy advocate 
from the policy analyst.  Always ask yourself, what knowledge would 
change my mind about this problem or decision?  If the answer is no 
information, then you are simply pushing a particular answer.  In 
this case you should look for expertise in marketing, not policy 
analysis.

Identify and question assumptions.  One of the great challenges 
facing a policy analyst is to become aware of the assumptions 
that guide thinking.  For example, United States science policy 
since World War II has been guided by a linear model that holds 
that investments in "basic" research are the most effective way 
to address societal concerns.  For many decades few questioned 
this assumption.  But is this linear model actually the best?  
In the atmospheric sciences community we see a similar untested 
assumption in the area of forecasting.  Considerable resources 
are often devoted to "improving forecasts," under an assumption 
that society will benefit from such improvements.  But by 
comparison little effort is devoted to investigating the conditions 
under which this assumption is actually true.  Because assumptions 
are usually unquestioned and sometimes incorrect, there is great 
value in being able to identify and question them in a rigorous, 
scientific manner.

Dejargonify your speaking and writing.  You can never speak or 
write too clearly, and there is always room for improvement.  The 
best way to improve these skills is the tried and true formula of 
practice, practice, practice.  Seek opportunities to communicate 
with people outside your own discipline or subject area expertise.  
At times this can be frustrating and humbling, but if you truly 
want to contribute to policy debate and discussion you will have 
to translate expertise into the language of the policy process, 
and not expect the opposite!

Understand disciplinary "geography."  As an expert with interests 
in policy it is essential that you understand how other areas of 
expertise fit in relation to both your own and the broader issues 
that you are concerned with.  This places a greater burden upon 
you than on the disciplinary scholar who is satisfied to focus 
on purely disciplinary concerns.  Not surprisingly, once stripped 
of jargon and disciplinary idiosyncrasies there is a great deal 
of overlap in methods, theories, and conclusions across disparate 
disciplines, particularly in the context of policy where problems 
and decisions ultimately bring everything together.

Seek the right education and training.  Traditionally, there have 
not been strong linkages within universities between atmospheric 
sciences departments and policy programs.  For this to change will 
require the dedicated efforts of students and faculty to overcome 
the familiar obstacles that stand in the way, usually at the 
department level.  There are a number of schools - Columbia, 
Penn State, Oklahoma, and Colorado are a few examples - that have 
the requisite expertise on campus to develop a strong atmospheric 
sciences program of research and education.  And there are other 
efforts beginning as well, such as the Climate Affairs Program 
(www.esig.ucar.edu/climate_affairs/) here at NCAR and the AMS 
Policy Program (www.ametsoc.org/AMS/atmospolicy/).  For those 
interested in this area of study, begin to take advantage of 
the resources that are available to you.  As demand increases, 
universities will move to meet it.  


Help to build a network of those with like interests.  To that 
end we are announcing the initiation of a new email list-serv 
and an educational resource guide.  The list-serv is called 
weather-policy and to join send an email to majordomo@ucar.edu.  
In the body of the message include:         

subscribe weather-policy <your email address>

* do not include the <>'s.  Majordomo will ignore the subject line.    

Its purpose is to provide a forum for discussion and communication 
among those interested in the educational and research aspects of 
atmospheric sciences policy.  The educational resource guide will 
provide information directly from atmospheric sciences programs 
about their offerings in this area, as well collect this 
information, we will post it on our site or announce it in the 
WeatherZine.  As always we welcome your feedback.

- Roger A. Pielke, Jr.

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[2] Guest Editorial -- How much "skill" is there in forecasting El Nino?

Chris Landsea
NOAA/AOML/Hurricane Research Division
Miami, Florida
landsea@aoml.noaa.gov

John Knaff
NOAA/Cooperative Institute for Research in the Atmosphere
Colorado State University
Fort Collins, Colorado
Knaff@CIRA.colostate.edu

The 1997-98 El Nino had dramatic impacts, leading to drought in 
Indonesia, extreme rains in Peru and Ecuador, and a quiet Atlantic 
hurricane season.   Conventional wisdom holds that predictions of 
the event's onset, magnitude, decay, and impacts generally were 
accurate.  But a close look at the forecasts reveals that while the 
impacts of the event, once it had begun, were accurately anticipated 
based on the climatology of past El Ninos, none of the available 
forecast techniques accurately predicted the event's onset, magnitude, 
and decay.

What is an accurate forecast?  One definition of forecast accuracy 
is based on a concept called "skill."  Atmospheric scientists define 
"skill" as a prediction's improvement upon some naive baseline.  
For example, absent other information a best guess for the high 
temperature in Washington, DC on September 1 might be the historical 
average high temperature for that date.  A forecast that is closer 
than the historical average to the actual temperature on September 
1 thus has skill.  A forecast methodology that consistently improves 
upon a naive baseline is a skillful methodology.  Consequently, 
judgments of the appropriate baseline against which to measure 
skill are crucial to claims of forecast accuracy.  

Traditionally, scientists have judged seasonal El Nino forecasts 
of sea surface temperature (SST) in the equatorial eastern Pacific 
Ocean "skillful" if they improve upon a baseline based upon 
"persistence."  A forecast of "persistence" simply uses current 
conditions as a predictor of future conditions.  For example, if 
the SSTs were 0.7 C above average, persistence would simply 
forecast 0.7 C above average for the following months and seasons.  
Because SSTs associated with El Nino are part of a cycle (the El 
Nino-Southern Oscillation or ENSO), it turns out that persistence 
is a very easy baseline to outforecast.

To provide a more stringent, but still naive baseline of skill in 
El Nino forecasting, we developed the El Nino-Southern Oscillation 
CLImatology and PERsistence (www.aoml.noaa.gov/hrd/Landsea/cliper/) 
model as a simple statistical tool that takes advantage of the 
climatology of past El Nino events, persistence, and contemporary 
trends.  Thus, we recommend that the output of ENSO-CLIPER replace 
the use of persistence as a skill threshold. There are, of course, 
other simple statistical models that could be used to set this 
threshold.  In our proposal, "skill" is defined as the ability of 
a forecast or forecast methodology to improve upon ENSO-CLIPER - 
which is a more difficult task.

In next month's Bulletin of the American Meteorological Society 
(www.aoml.noaa.gov/hrd/Landsea/skill/) we evaluate twelve 
statistical and dynamical models which were available in real-time 
for the 1997/98 event.  We conclude that some of the models were 
able to outperform ENSO-CLIPER in predicting either the onset or 
the decay of the 1997-98 El Nino, but none was successful at 
predicting both onset and decay for a medium-range (6-11 months) 
lead time.  Also, no predictive approaches, including the 
ENSO-CLIPER baseline, were able to anticipate even one-half of 
the actual magnitude of the El Nino at medium-range (6-11 months) 
lead.  In addition, none of the models showed skill at short- to 
medium-range lead times (0-8 months).  No dynamical model and only 
two of the statistical models outperformed ENSO-CLIPER by more 
than 5% (of the root mean square error) at 9 to 14 months lead-time.  

A lesson to be learned from this evaluation is that since the 
best performing models for the very strong 1997-98 El Nino event 
were statistical ones, it appears that the use of more complex, 
physically realistic dynamical models does not automatically provide 
more accurate forecasts.  Increased complexity can increase by 
orders of magnitude the sources for error, which can cause 
degradation in skill.  Despite the lack of skill in forecasting 
ENSO up to 8 months in advance, once the 1997-98 El Nino had begun 
national meteorological centers were able to anticipate correctly 
many of the impacts because of the tendency for El Nino events 
to persist into and peak during the winter.  Indeed, the U.S. 
Climate Prediction Center's most skillful tools for predicting 
U.S. seasonal precipitation were statistical rather than dynamical 
models.  For seasonal temperature anomalies in the United States, 
the statistical and dynamical approaches were about equal in skill.  
This implies that in this case the use of dynamical models was 
not needed to anticipate a wet and stormy winter for the southern 
tier of the United States and a warm winter for the northern 
tier of states.

We have two recommendations based on this work:  1) a distinct 
need exists for the forecasting community to debate and agree 
on the naive baseline against which "skill" is to be measured 
in forecasts of ENSO phenomena.  Use of the simple persistence 
is much too easy a benchmark.  If not ENSO-CLIPER, then some 
other more rigorous but simple test is essential for evaluating 
ENSO forecasting in a useful manner; and 2) for the 1997-98 
event none of the more sophisticated models- both other 
statistical schemes as well as numerical techniques - outperformed 
the naive ENSO-CLIPER baseline for short to medium lead times 
(0 to 8 months).  Thus these more complex models may not be 
doing much more than carrying out pattern recognition and 
extrapolation.  National meteorological centers and research 
agencies may wish to consider carefully their resource priorities 
(personnel, computers, and budgets) when the most accurate tools 
presently appear to be the relatively cheap statistical systems, 
compared to the expensive (developmentally and computationally) 
dynamical models.

These results may be surprising given the general perception that 
seasonal El Nino forecasts from dynamical models have been quite 
successful and may even be considered a solved problem.  A 
particular report in Science in 1998 - "Models win big in 
forecasting El Nino"  - generated widespread publicity for 
the success in forecasting the 1997-98 El Nino's onset by the 
comprehensive dynamical models.  This report was based upon a 
conference paper by NOAA's Tony Barnston, which only considered 
El Nino's onset at the time of the report in October 1997.  No 
follow-up in Science was forthcoming when  Barnston and colleagues 
published a  paper  in the Bulletin of the American Meteorological 
Society last year showing that the comprehensive dynamical models 
did not "win big" after all.  (It is worth mentioning that the 
results from Barnston and colleagues do indeed agree quite well 
in general with our paper, though the interpretation is very 
different.)

Also disturbing is the use of the supposed success in dynamical 
El Nino forecasting to support other agendas.  For example, a 
1999 overview paper by Ledley and colleagues in support of the 
American Geophysical Union's "Position Statement on Climate 
Change and Greenhouse Gases" said the following:

"Confidence in [comprehensive coupled] models [for anthropogenic 
global warming scenarios] is also gained from their emerging 
predictive capability.  An example of this capability is the 
development of a hierarchy of models to study the El Nino-Southern 
Oscillation (ENSO) phenomena..... These models can 
predict the lower frequency responses of the climate system, 
such as anomalies in monthly and season averages of the sea 
surface temperatures in the tropical Pacific."

To the contrary, under this logic and with the results of our 
study, one could even have less confidence in anthropogenic 
global warming predictions because of the lack of skill in 
predicting El Nino. The inability of dynamical models to 
outperform a relatively simple statistical scheme for ENSO 
calls into question the consensus opinion that coupled dynamical 
models are the best way to accurately predict short-term 
climate variability.  The bottom line is that the successes 
in ENSO forecasting have been overstated (sometimes drastically) 
and misapplied in other arenas.

We are now engaged in an assessment of the forecast skill of 
the strong 1998-2000 La Nina event, which immediately 
followed the 1997-1998 El Nino.  Given  the most recent 
complete ENSO warm and cold cycle, it may be that truly 
skillful predictions from models are available.  But the current 
answer to the question posed in this article's title is that 
there was essentially no skill in forecasting the very strong 
1997-98 El Nino at lead times ranging from 0 to 8 months using 
the performance of ENSO-CLIPER as the naive baseline.  Moreover, 
the lack of skill at the short- to medium-range lead times 
continues to confirm what was also observed in independent 
tests of real-time ENSO prediction models for the period 
1993-96 in our earlier work.

For further reading

Barnston, A. G., M. H. Glantz, and Y. He, 1999:  
Predictive skill of statistical and dynamical climate models 
in SST forecasts during the 1997-98 El Nino episode and the 
1998 La Nina onset.  Bull. Amer. Meteor. Soc., 80, 217-243.
(Available at: www.esig.ucar.edu/BAMS8002.pdf)

Kerr, R. A., 1998:  Models win big in forecasting El Nino.  
Science, 280, 522-523.

Knaff, J.A, and C.W. Landsea, 1997:  An El Nino-Southern 
Oscillation CLImatology and PERsistence (CLIPER) forecasting 
scheme.  Wea. Forecasting, 12, 633-652. (Available at: 
www.aoml.noaa.gov/hrd/Landsea/cliper/)

Landsea, C.W., and J.A. Knaff, 2000:  How much skill was 
there in forecasting the very strong 1997-98 El Nino?  
Bull. Amer. Meteor. Soc., (in press, September issue).
(Available at: www.aoml.noaa.gov/hrd/Landsea/skill/)

Ledley, T. S., E. T. Sundquist, S. E. Schwartz, D. K. Hall, 
J. D. Fellows, and T. L. Killeen, 1999: Climate change and 
greenhouse gases. Eos, 80, 453-458. 

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[3] Correspondence -- Correspondence from our readers

Dear WeatherZine: 

In response to your editorial in WeatherZine #21 
(Six Heretical Notions About Weather Policy, 
www.esig.ucar.edu/socasp/zine/21/editorial.html):

When weather disasters happened in the past, the National 
Weather Service frequently benefited from an infusion of funds.  
After a 1974 tornado outbreak, for example, a research group 
was set up at the National Severe Storms Forecast Center.  
Lately, disasters come and go with little benefit to the weather 
community.  The problem is that we have been ineffectual at 
convincing the public and policy-makers that (a) they are getting 
a bargain at the current cost, and (b) they could do even better 
with a larger investment.  

If we ignore the role that human forecasters have in the process 
of generating forecasts, then we will get less from any level of 
investment than is possible.  Although it seems we are on a 
juggernaut aimed at removing any role for human forecasters in 
the public weather service by 2050 (my forecast!), properly 
educated and trained humans can add considerable value to what 
any model can generate.  We have chosen not to invest in meaningful 
training of our weather forecasters, thereby putting our hopes 
into improvement of the numerical model forecasts. 

Much collected data goes unused because of a lack of access.  
Operational data has not been collected to be used in research.  
Once these data are used by the operational agencies, they go 
into some "black hole" where retrieval is difficult and expensive.  
Moreover, data quality issues tied to operationally-collected 
observations can be a serious barrier to their use. 

Access to data collected in field programs typically is controlled 
and often limited to those directly involved in the data collection.  
This can seriously limit the general value of the data sets.  We 
often are our own worst enemies at getting the full value from the 
data we collect at taxpayer expense.

As for forecast quality, the NWS continues to put forth only a 
token effort into a truly meaningful forecast verification program.  
Virtually nothing is happening with respect to "closing the loop" 
on any verification effort.  

Another critical gap in our understanding is what it takes to be 
a high-quality human weather forecaster.  We have no idea what 
characterizes the best human forecasters, by any measure of forecast 
quality.  An obvious implication is that there is no role envisioned 
for them in the far future ...learning how humans do their part of 
the forecasting job well is apparently seen as a meaningless, 
dead-end task.  The lack of any interest in this also tends to 
become a self-fulfilling prophecy.

We are very bad at applying what we know in the real world of 
operational forecasting.  Decision-makers in research and 
operations are ignorant of the other's needs and interests so 
that whatever happens to address the gap is done by individuals 
with little or no support from either set of decision-makers.  
If only a small fraction of what is known from research is being 
applied in operations, we have only ourselves to blame!

The operational bureaucracy is very reluctant to change procedures 
to reflect new knowledge.  We are still putting out superannuated 
"zone" forecasts when it is possible to provide gridded model 
fields of virtually any forecast quantity over the Internet.  
If obsolete products are allowed to continue indefinitely, there 
is little value to any research tied to product improvement.

The NWS is simply not equipped to provide good answers about the 
value of what they do, in spite of my belief that even their 
current forecast quality still manages to be extremely valuable, 
in spite of being significantly lower than what it could be if 
they made forecast quality a priority.  I see little indication 
that anyone is doing much to address these critical issues.  
Defensive reactions to your "heresies" indicate a lack of 
understanding of what you are trying to accomplish with this dialog.

Dr. Charles A. Doswell III     
NOAA/National Severe Storms Laboratory
doswell@nssl.noaa.gov
www.nssl.noaa.gov/~doswell
Standard disclaimer ... my views are my own, so don't blame my employer.

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[4] Weather-Related News -- 
New Mailing List - The use of the Internet in Disaster Situations

A new mailing list has been created to discuss the development 
of improved ways of collecting and communicating information 
during and after disasters by use of the Internet.  The purpose 
of this list is to promote the use and development of the 
Internet by public agencies, and to discuss the development 
of other Internet-based systems for collecting and distributing 
the "disaster message."

To subscribe or unsubscribe to this list send an email to: 
disastercom-request@disastercenter.com with the word subscribe 
or the word unsubscribe only, in the body of the message.

Christopher Effgen
build@micronet.net

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[5] New Additions to the WWW Site:

El Nino/La Nina

El Niņo and La Niņa: Tracing the Dance of Ocean and Atmosphere 
(www4.nationalacademies.org/opus/home.nsf/web/elnino?OpenDocument) 
This publication surveys basic scientific studies of the last century 
that have led to our current understanding of El Nino/Southern 
Oscillation (ENSO). 


Emergency Management

Overview:The National Pre-Disaster Mitigation Plan 
(www.civil.buffalo.edu/aawe/aawe-text/publication/NIBS/NEWFEMA.htm
#Document)  The National Pre-Disaster Mitigation Plan articulates 
the vision, mission, goals and objectives of this nation's effort 
to reduce the escalating cost of natural disasters. 

Congressional Natural Hazards Caucus  
(www.senate.gov/~edwards/cnhc/index.html)  The Caucus hopes to 
foster an important dialogue on steps governments can take to 
lessen the severity of natural disasters.

Multi Hazard Identification and Risk Assessment 
(www.fema.gov/mit/tsd/ft_mhira.htm)  This site clarifies and 
documents previous efforts to identify natural and technological 
hazards, and to assess associated risks.  

World Disaster Report (www.ifrc.org/publicat/wdr2000/)  
The 2000 World Disaster Report focuses on public health in disasters.

Surviving Disaster with Renewable Energy 
(www.nrel.gov/surviving_disaster/)  This site highlights the 
National Renewable Energy Lab's role in emergency preparedness 
and response, disaster mitigation and relief, and sustainable 
development.

Natural Hazards Review (www.pubs.asce.org/journals/nhnews.html)  
The Natural Hazards Review is "the first cross-disciplinary 
journal to address all aspects of natural hazards loss and 
cost reduction."

Emergency Preparedness Information Project (EPIP) Emergency Gateway 
(www.epipgateway.com)  This site is designed to provide minority 
communities with information about creating disaster resistant 
families, communities, institutions, businesses and organizations.

Bandelier National Monument Cerro Grande Prescribed Fire 
Investigation Report (www.nps.gov/cerrogrande/)  This is the 
interagency Fire Investigation Team's report on the Bandelier 
National Monument fire.  The report of the Independent Review 
Board can be found at www.doi.gov/secretary/reviewteamfinal.htm.


Floods

Significant Floods in the United States During the 20th Century - 
USGS Measures a Century of Floods 
(ks.water.usgs.gov/Kansas/pubs/fact-sheets/fs.024-00.html)  This 
report lists, by type of flood, 32 of the most significant 20th 
century U.S. floods in terms of number of lives lost and/or 
property damage.


Summer/Winter

Heat Waves and Hot Nights: Ozone Action (www.ozone.org/heatstress/); 
Heat Waves and Hot Nights: Physicians for Social Responsibility  
(www.psr.org/heatsheet.html)  This report shows that extreme heat 
waves and overheated nights are becoming more frequent in cities 
and regions across the United States. 


General Weather Resources

NOAA Photo Collection (www.photolib.noaa.gov)  This site includes 
hundreds of images of natural hazards from the National Severe 
Storms Laboratory and the National Weather Service Historical 
Image Collection.


Insurance

Society for Risk Analysis 1999 meeting 
(www.riskworld.com/Abstract/AB9ME001.HTM)  This site includes 
abstracts of the 373 papers presented at the 1999 meeting of 
the Society for Risk Analysis.  

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Weather Impacts Group
Societal Aspects of Weather
Environmental and Societal Impacts Group
National Center for Atmospheric Research
US Weather Research Program

Societal Aspects of Weather Web Site:  www.esig.ucar.edu/socasp/
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