Hydrology Lab Overview George Smith July 13, 2004

1. Hydrology Lab Overview George Smith July 13, 2004

2. Work Areas in the Hydro Lab • New NWSRFS software architecture (CHPS) • Overall ensemble forecast research & tools • AWIPS Regular Releases (3.1, 3.3, 4.0, 4.x, 5, 6) • - NWSRFS enhancements, WHFS enhancements, IHFS DB conversion (Postgres) • HSD Bug List & Consultation • Precipitation Frequency Analysis • HADS • Hydromet Forcing • - PE estimates, gauge QC, prob. QPE, NEXRAD improvements, RCA/CSSA, temperature forcing • Distributed Hydrologic Modeling • - Frozen ground, large scale hydro modeling DHMS project, DMIP2, Flash flood stat distributed hydrologic model, soil parameters, calibration • River Mechanics models/tools • - DamCrest/DamAT, FLDVIEW/FLDXS, FLDAT, FLDWAV/SHRT, coastal river modeling, other GIS • OHD/NSSL collaborations • - QPESUMS evals, QPE-to-estuary modeling, NMQ, Satellite QPE, Dual Polarization

3. Outline • Hydrologic Operational Service Improvement Process • OHD End-to-end Projects • Distributed Hydrologic Modeling • Range Correction Algorithm • FLDWAV Update for FLDVIEW • Probabilistic QPF/QTF • Site Specific (add SAC-SMA) • Precipitation Frequency Studies • NWS Integrated Water Science

4. Hydrologic Operations & Service Improvement Process (HOSIP) Status • Definition & Implementation of a Requirements-based Process that Ensures Field Review of Science Infusion and Software Engineering Projects • Basic Process and Controls Defined • Implementation on Selected Projects • Distributed Hydrologic Modeling System • Statement of Need (SON) & Concept of Operations (CONOPS) Developed • Operational Requirements (ORD) Developed & Field Review Scheduled • Flood Mapping • SON, CONOPS, & ORD Developed & Field Review Underway • WSR88D Range Correction Algorithm • SON, CONOPS, ORD • RFC Forecast Verification Re-host on the RAX • Requirements analysis, design specifications, reviews, system/user documentation • Automated Tool Set Adaptation to Scientific Process • Adapting Software Engineering Tools to Streamline Development • Requirements Definition Before Development Activities

5. HOSIP Plans • Develop & Implement Quality Assurance Procedures • Institutionalize HOSIP • Use on All Projects • Ensure Field Review & Verification of Projects • Develop Support Documentation in Accordance with Development Plans • Develop Common Plans & Plan Review Procedures • Tie to Quad Charts • Tie to NOAA & NWS Strategic Plans • Complete Adaptation of Automated Tools to HOSIP • Continue to Coordinate with NWS OSIP

6. Distributed Hydrologic Modeling System (DHMS) Status • Collaborated with ABRFC and a contractor (Apex) to develop DHMS 1.0, a prototype operational distributed hydrologic modeling system, to help define functional requirements for DHMS 2.0 (the AWIPS-ready version) • Compiled ABRFC and WGRFC feedback on DHMS 2.0 functional requirements after 4 months of operational testing • Conducted a software engineering functional requirements analysis using the “use-case” approach • Defined Users (8)  Use Cases (26)  Functional Requirements (150) • Initiated a peer review of the derived use cases and functional requirements

7. DHMS Future Work • Finish Research and Analysis, HOSIP Stage 3 • Complete requirements review to validate, refine, and prioritize functional requirements • OHD, OCWWS/HSD, ABRFC, WGRFC • Get OHD/HL approval to move to HOSIP stage 4 • Conduct Operational Development, HOSIP Stage 4 • Derive system level requirements (technical/architectural) • Design DHMS • Design overall DHMS • Take advantage of CHPS where possible • Design initial components for DHMS 2.0 • Create test plans/procedures for DHMS 2.0 • Develop and Test DHMS 2.0 • Submit DHMS 2.0 to AWIPS

8. Range Correction Algorithm (RCA) Project Status Field evaluation at 6 WFOs completed on June 11: • Charleston, WV; Portland, OR; Norman, OK; Pleasant Hill, MO; Minneapolis, MN; Pittsburgh, PA • Level II data delivered from WFOs to clone RPG systems at NWSHQ; web interface provided for field participants to review data • Purpose of field evaluation: • to validate science using real-time data from NWS sites around the nation • to solicit feedback from operational forecasters • Results: • Overall impression: positive • Some minor adjustments in logic needed to take into account unforeseen situations Formal project documentation underway: • Concept of operations (1st draft complete) • Operational Requirements definition • Scientific Algorithm description Independent Validation & Verification (IV&V) of science at Radar Operations Center (ROC) System resource issue: • ROC engineering analysis says software consumes too much cpu • HSEB NEXRAD Development Group currently focusing on improving source code efficiency

9. RCA Project Plans Schedule delays: • Postpone from AWIPS OB6 to OB7 (pending outcome of OB6 AWIPS SREC) • Postpone from RPG Build 8 to Build 9 (system resource issues requires more effort) • Deploy Spring 2006 July 2004: ROC completes IV&V July 2004: Presentation to NEXRAD Technical Advisory Committee (TAC): • committee to review field evaluation results and cost benefit • committee to provide recommendation for proceeding to operational implementation August 2004: • Develop strategy for improving system resource usage • Revise project plan October 2004: presentation to NEXRAD System Recommendation Evaluation Committee (SREC) for RPG Build assignment

10. FLDWAV Update for FLDVIEW Project Status • Accomplishments: • Incorporated the features of the HSMB Prototype FLDWAV into the OB4 baseline. • Allowing FLDVIEW input data to be generated by baseline FLDWAV • Added significant regression test cases for FLDWAV to AWIPS software baseline. • Formalized a process to migrate FLDWAV capabilities to the AWIPS baseline. • Decreasing the time it takes for Prototype features to get into the baseline (specific process steps derived from HOSIP)

11. FLDWAV Update for FLDVIEW Project Plans • Underway: • Adding the capability to generate multi-scenario FLDVIEW input to the OB5 baseline via the FLDWAV Migration Process. • Wrap-up FLDWAV Update Project. • Further River Mechanics tasks will be part a new end-to-end projects. • Implement Simplified Hydraulic Routing Technique (SHRT). • Put FLDVIEW into AWIPS.

12. PQPF-PQTF Project Status • Within HOSIP Stage 3, aims at enhancing the Ensemble Pre-Processor of the ESP system to: • Produce seamless probabilistic forecasts for precipitation and temperature for all lead times (1 hour to 1 year) • Incorporate skill of deterministic forecasts (QPF/QTF), correct forecast bias, and account for forecast uncertainty • Provide an interim step until global/regional ensembles are skillful enough to be used directly • Current status: • Integrated new science for short-term (days 1-5) using the RFC QPF/QTF • Unified the processes for all lead times (including days 1-365 climate adjustments from NCEP/CPC) • Set up prototype at 3 demo RFCs for testing and feedback • Developed a probabilistic verification program to do retrospective verification of short-term PQPF/PQTF

13. PQPF-PQTF Project Future Work • Ensemble generation: • Enhance short-term functionality: integrate HPC QPF if no RFC QPF available, improve PQTF methodology • Enhance medium-term functionality : include procedures for incorporating CPC days 6-14 forecasts • Ensemble calibration: • Enhance short-term calibration programs • Deliver a calibration prototype for all lead times • Ensemble verification: • Integrate more diagnosis measures • Deliver a probabilistic verification program for short- and medium-term PQPF/PQTF • Communication: • Papers to present short-term methodology and verification results • Experience shared with other global/regional ensemble projects • Plan to move ensemble pre-processor components through operational development to deployment

14. Site Specific Status • AWIPS OB4 – to be deployed September, 2004 • Added SAC-SMA rainfall-runoff model, which requires • Parameter and state data transfer from RFC • Significant RFC involvement for calibration and state maintenance • Still includes MBRFC API • Provides graphical editing of MAP, with immediate forecast hydrograph recalculation and display • OB4/ Field Test Sites • SERFC/SJU, MBRFC, NWRFC pending • End Site Specific SAC-SMA Project

15. Precipitation Frequency Studies

16. Precipitation Frequency Estimates • Durations • 5 minutes to 60 days • Annual Exceedance Probabilities • 1 in 2 to 1 in 1000 • Annual Maximum and Partial Duration Results • High Resolution Spatial Estimates • 30 arc second • Confidence Limits • upper and lower 90%

17. Precip Frequency Products & Delivery • Web Based Delivery • “Precipitation Frequency Data Server” • response is very favorable • High Quality Maps Produced Using GIS • Interactive Tables and Charts • Base Grids • Seasonality • Areal Reduction Factors • Temporal Distributions • Documentation

18. Example map from Precipitation Frequency Data Server hdsc.nws.noaa.gov/hdsc/pfds/

19. NWS Integrated Water Science Planning • Objective • Carry out a wide-ranging assessment of NWS water science and technology development necessary to implement a comprehensive suite of high-resolution digital hydrology and water resources analysis and forecast products in the next 5 to 10 years • Activities (Apr through Aug) • Review relevant NWS water science activities by OHD/HL, OCWWS/NOHRSC, NCEP/EMC, and RFCs • Assess whether current activities can support efficient and effective delivery of new science for operational implementation of high-resolution gridded water resources products, and if the ongoing R&D efforts are adequate to overcome the foremost science challenges in meeting the objective • Recommend approaches to maximize the strengths of each NWS water science component with respect to interactions with other NOAA freshwater researchers and with the external community to streamline science-to-operations paths in meeting the objective • Deliverable (end of Aug) • An executable plan compatible with the NWS Science and Technology Infusion Plan • Membership (Gary Carter, Mentor) • D.-J. Seo (OHD/HL), Don Cline (OCWWS/NOHRSC), Ken Mitchell (NCEP/EMC), Jiayu Zhou (OST), Rob Hartman (RFC)