Beam Knowledge Rep Sept 04

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Beam Knowledge Representation Meeting, Sept. 21-23, 2004

Participants

• Mark Schildhauer
• Deana Pennington
• Rich Williams
• Chad Berkley
• Jianting Zhang
• Shawn Bowers
• Kristin Vanderbilt
• Evan Weiher
• David Chalcraft
• Dan Higgins
• Bertram Ludaescher
• Katy Suding
• Steve Cox
• Bob Waide

September 21st

• Introductions (8:30-3:45)
• Mark presentation on SEEK background
• Deana presentation on Biodiversity, etc.
• Discussion
• Species traits
• Data sets, availability
• Integration
• Chad / Dan Presented on Kepler
• Much interface discussion
• Showed Pred/Prey and Bio index models
• Rich Williams on ontologies
• Restricted to certain axis; spatial patterns (naturally occuring gradients); abundance; temporal
• In a particular control plot, how are things changing, and are those changes in the same trajectory (in the same gradient change)?
• Ton of data in range management
• Q: Are most of these datasets freely available on the web; are people sharing them? A: Few available on web ... Q: But is it possible to get them? A: It is a very divergent / diverse community. Q: W

September 22nd

• Agenda Setting
• Some overlapping stuff on every biodiversity analysis
• Methods / Design focus
• Analysis focus
• Mark: Goal is to compartmentalize that provides general utility for next project, for some other analysis; a standard type of function that we want to capture and describe to use for others
• Bob: At one point there was a database with various scripts that provided the full spectrum of data integration
• They aren't there anymore (they were on KNB bio)
• Everthing that was done using scripts, no manual work
• From 16 or so grasslands
• Raw data that read in the scripts
• Project technically still ongoing
• Aug 2002 first working group
• Then six months of work after that
• It would be a good test case / use case to look into
• Steve: Jornado would be the test case

• Data Integration
• Katy
• Predicting species response to increased rousource availability (history, questions, dataset)
• what happens when you increase productivity (experimentally), and then look at what happens to diversity
• N (nitrogen) Fertilization experiments (KBS oldfields, ARC heath)
• if you add nitrogen, it generally increases productivity (Gough et al. 2000)
• Every experiment found that as you increase productivy it decreases diversity, which doesn't follow the natural productivity/species-richness curve (this is gaining interest: we are increasing productivity of systems in general with environmental change going on, e.g., urbanization increases nitrogen/fertizilation, and a desire to know the result on diversity)
• What is Primary Productivity "can of worms"
• Want to aggregate data at many different scales / communities to get many types of graphs; you want to ultimately go from smallest possible scale to largest scale
• decision making that goes in, before any analysis happens. This goes into the data discovery/integration. Deana: can we build a repository of methodologies.
• primarily using herbaceous sites
• you do a broad category of the dataset, but not the details (a little bit of woody stuff, ...)
• Bob: need a step where someone can look at the methodology ...
• Rich: Need to capture what it is you are measuring; it isn't as much a methodology issue
• Bob: Clark and Clark paper covers some of this (Bob said he'd dig up the ref)
• most of the time, productivity scales well, i.e., it is a linear scaling, e.g., anpp vs. area is a linear relationship. so for exmaple, even though they are smaller plots, you can get g/m^2 measures. Basically, productivity doubles as area doubles...
• n addition decresases species diversity: plot at lter sites of anpp (above-ground primary productivity) versus relative species density; species density is the number of species observed in a given area
• two studies, measures at different scales: either you simulate or measure a species area curve, and extrapolate to different areas.
• N fertilization positivevly effects productivity negatively effects diversity
• N fert. interacts with environment; species sorting (dominance composition) negatively effects diversity
• species response to fertilization:
• in the case of increased fertility, can we predict what species we will lose? What species will become dominant?
• are these responses contingent on system characteristics?
• dataset: 8 lter sites, 28 community types (mainly vegetation classifications, based on the experiments/manipulations done at the sites); 831 species
• dataset characteristics
• n added (g/m^2/yr), 10 (ARC), 9.5 (CDR), 60/wk (GCE), etc.
• Form of N: NH4-NO3 pellets (ARC), Liguid Urea-N, NH4-NO3 pellets, etc.
• Treatment plot size (m^2): differs from 900 to .25
• Sample plot size (m^2): .25 to 10 (these don't differ that much really: .32, .30, .25, 1) ... it isn't, however, appropriate to compare directly, without the species area curves, the .3's with the 1's
• Replication: 2 to 10
• Duration (yrs): 2 to 13