1. MOVES: �EPA=s new generation �mobile source emission model�
2. 2 What Is MOVES? MOtor Vehicle Emission Simulator
New software framework intended to:
Replace MOBILE & NONROAD
Expand Capabilities
Additional Sources: Aircraft, Commercial Marine, Locomotive
Additional Pollutants: Greenhouse Gases
Additional Scope: Life Cycle Analysis
3. 3 Why A New Approach? Improve the science
Requires data collection - especially in-use, on-road data
Opportunity exists with new technology to vastly improve quality
Improve the software
Current questions exceed current tools
Analyses at finer scales
Cross-pollutant and cross-source impacts
Toxics, PM, Greenhouse Gases
Respond to external review
National Research Council, “Modeling Mobile Source Emissions”
4. 4 Key Changes from MOBILE Inventory estimation
MOBILE estimates emission factors (grams/mile)
Multi-scale analysis
Emission rates on modal basis
MOBILE rates based on aggregate driving cycles
Software framework
Relational database structure
Graphical User Interface
Object-oriented programming approach
At this point is important to step back and look at the key differences between MOVES and MOBILE, listed here. At this point is important to step back and look at the key differences between MOVES and MOBILE, listed here.
5. 5 MOVES2004 – the first step On-road energy (total, petroleum, fossil) and emissions of CO2, CH4, N2O
U.S., state or county level
1999 through 2050
Well-to-Pump energy/emissions via GREET
Broad range of “what-if” analyses
Foundation for full MOVES implementation
6. 6 MOVES Long-Term Schedule Current thinking is that MOVES would not replace MOBILE6 or NONROAD in time to be used for 8-hour SIP analyses
Specific milestones
MOVES2005: Draft Aircraft, Commercial Marine, Locomotives
MOVES2006: Final A/CM/L, Draft on-road criteria pollutants & toxics
MOVES2007: Final on-road (MOBILE6 replacement), Draft off-road
7. 7 MOVES Software Framework Language: Java™
Fleet, activity, emission rate data stored in relational database
Open-source relational database system (MySQL™)
Graphical user interface or batch mode
Designed for single or multiple-computer processing
8. MOVES2004 GUI (Main Window)
9. Geography
10. Vehicle/Fuel Choices
11. Time Spans
12. Roadway Types
13. Pollutants/Processes
14. 14 Default Fleet & Activity Data Sources R.L. Polk
Registration data, especially used for light duty
VIUS97
Census survey of truck data
FHWA
VMT data and registration data
Annual Energy Outlook (NEMS)
VMT and technology projections
Driving Surveys
Real-worlds driving patterns by source type, road type, average speed
16. Advanced Technologies in MOVES
17. Advanced Vehicle & Fuel Strategy
18. Life Cycle – The Big Picture
19. GREET Pathway Options
20. MOVES/GREET provides unprecedented “what-if” capability Now on the implementation.
The scope is huge, so we’re breaking it up into pieces to make it manageable, make sure it works, and give users a chance to ramp up.
Three basic implementations…Now on the implementation.
The scope is huge, so we’re breaking it up into pieces to make it manageable, make sure it works, and give users a chance to ramp up.
Three basic implementations…
21. 21 Looking Ahead… Aircraft, Commercial Marine, Locomotive
On-road criteria pollutant/toxics
Evaporative emissions
High emitter and I/M design
Multi-scale implementation
Includes coordination with DOT on TRANSIMS
23. Custom Implementations
24. 24 Planned Implementations U.S. National Inventory (macroscale)
Default county-level emissions
Local inventory development with user-supplied inputs
On-road, off-road, aircraft, commercial marine, locomotives
Link-Based (mesoscale)
Based on output from travel demand model
Intersection Modeling (microscale)
In conjunction with CAL3QHC
TRANSIMS
MOVES will replace current emission module That completes the top-level design of the model. Now we talk about the specific implementations we plan to build, or support building.
As mentioned the bulk of implementation will happen in the generators, specifically the total activity and operating mode distribution generators.
For the first three implementation we’ve developed specific mathematical formulations for these generators, which I’ll walk through in a very general wayThat completes the top-level design of the model. Now we talk about the specific implementations we plan to build, or support building.
As mentioned the bulk of implementation will happen in the generators, specifically the total activity and operating mode distribution generators.
For the first three implementation we’ve developed specific mathematical formulations for these generators, which I’ll walk through in a very general way
25. 25 Long-Term Plan Custom implementations developed by users to meet specific use cases, e.g.
State-specific implementation
Commercial transportation models
New generation dispersion models
Control strategies That completes the top-level design of the model. Now we talk about the specific implementations we plan to build, or support building.
As mentioned the bulk of implementation will happen in the generators, specifically the total activity and operating mode distribution generators.
For the first three implementation we’ve developed specific mathematical formulations for these generators, which I’ll walk through in a very general wayThat completes the top-level design of the model. Now we talk about the specific implementations we plan to build, or support building.
As mentioned the bulk of implementation will happen in the generators, specifically the total activity and operating mode distribution generators.
For the first three implementation we’ve developed specific mathematical formulations for these generators, which I’ll walk through in a very general way
28. 28 MOVES Resources Web site:
http://www.epa.gov/otaq/ngm.htm
Email Listserver:
EPA-MOBILENEWS
Email address:
mobile@epa.gov
