Standardizing an Ontology of Physics - PowerPoint PPT Presentation

1 / 14

About This Presentation

Title:

Standardizing an Ontology of Physics

Description:

Meta-Physics, not metaphysics! The language we must use to describe physics ... Standardized concepts, constructs for standardizing physical descriptions ... – PowerPoint PPT presentation

Number of Views:40

Avg rating:3.0/5.0

Slides: 15

Provided by: JC951

Category:

more less

Transcript and Presenter's Notes

Title: Standardizing an Ontology of Physics

1
Standardizing anOntology of Physics

Joseph B. Collins
Naval Research Laboratory

2
An Ontology of Physics (OoP)

Meta-Physics, not metaphysics!
The language we must use to describe physics
Applied physics, not physics research
Standardized concepts, constructs for
standardizing physical descriptions
Applicable to all physics-based models
Environmental models are physics-based

3
Why a Standard Ontology?

No black boxes anymore
Documentation, transparency
Enables informed use of models
Automated understanding
Enables search, retrieval of models
What http did for the web, OoP can do for
models
Composability
Facilitate meaningful model composition

4
SEDRIS

Provides Spatial Reference Model (SRM) for
spatial relationships
Provides Environmental Data Coding Specification
(EDCS) for concepts
Many physical concepts here!
Provides Data Representation Model (DRM) for
(static) discretized model transmittals
No math (derivatives, integrals)
No dynamics ( like F ma )

5
Semantic RelationshipsOntologies Taxonomies

Taxonomy implies hierarchy (tree)
Ontology is a web (graph) of relationships
Semantic relationships MAY form a taxonomy in
special cases
Graphs (webs) can represent any relationship
topology
They teach concept webbing in Elementary
School! (Inspiration)

Trees
Graph / Web
6
A Physics-Based Model Ontology Layercake

The referent
Language of physics
The easier solution
Lets get an answer!
The next guys grid
Each layer to layer transition is informal,
one-to-many

Physical concepts
Mathematical Expr.
Mathematical approx
Discretized approx
Interpolate
Can we infer the Physical Concept from the last
layer? No!
7
Composing Physical Objects
Electron

Physical objects combine - composition
Composition is not simple plugging together
Division between Internal and External forces and
motion

Proton
Hydrogen
Photon
8
Why is Measurement Important?

The Real World
The ultimate source of input to simulation
The thing referred to
Sensor Model
Observation and detection (analog / digital)
Measured Parameters / uncertainty, error
Translation to other model parameters
Data normalization, inference, transformations

9
Example MODAS

Oceanographic Model
Highly appreciated by the ASW community
A Dynamic Climatology (whats that?)
Measurement Input, Model Type, Output Variables
Measures (daily) sea surface temperature,
elevation, historical temp, salinity profiles
Empirical (Regression) Model
Output Ocean temperature, salinity profiles

10
Ocean, Atmosphere

Navier-Stokes basis (mathematical equations)
Derived from conservation laws for fluid continua
Approximations
Inviscid, compressible / incompressible
Turbulence model, eqn. of state
Named discretized models
Princeton Ocean Model, NCOM, NLOM, ECOM, MODAS,
NOGAPS, COAMPS
Data Sources
measurement data, data drivers (BCs)
Similarly characterized (high-level to low-level)

11
Marking Up

Physics Concept an applied force causes a mass
to accelerate - (marking up a math statement)
Math Concept Equation - A three dimensional real
valued vector, F, is equal to the scalar, m,
multiplied by the three dimensional real valued
vector, a.
Numerical (discrete math) Concept

ltforce unitnewtongt F lt/forcegt ltPhysObj.mass
unitkilogmgt m lt/PhysObj.massgt ltPhysObj.accelera
tiongt a lt/PhysObj.accelerationgt
12
The IdealModel
Physics-based description
physics gtltphysics
Mathematical description

SEDRIS description
model.xml gt
Production code version
Validation data
Config. Mngmnt. data
13
Benefits