8/12/98

Integrated Sensor Training (IST) PDS Outline
11-12 August 1998


GOAL:  Integrated Sensor Training will provide training and education to support the integration of all sensor data (remote and in-situ) into operational weather forecasting using AWIPS

Executive Producer: Anthony Mostek OM/COMET

(Other Units - ASOS (TC - Beckman)
		- RAOB (NAOS) - FSL (T. Schllater)

1. UNIT 1: Profiler - Gary H., Tom S., Sam B.
(Producer - T. Schllater, ???)
Goal:	 Evaluate profiler obs and integrate them with other meteorological information.
	(Draft 12 Aug 1998 by Sam Beckman, Gary Hufford, and Tom Schlatter)

Description of job competency to be achieved
	Exploit fully profiler observations in the daily forecast routine.

Description of need
	Forecasters need to understand the capabilities and limitation of three closely	related component systems referred to as "profiler":
		wind profiling radar
		Radio Acoustic Sounding System (RASS)
		Integrated Precipitable Water (IPW) from GPS signal analysis
	Forecasters need to learn the applications of profiler data to nowcasting and very short-term prediction.

Specific job task skills and knowledge
	
A. For each profiler component system
1) principles of operation
2) conditions of valid  measurement
3) quality control procedures
4) system status
5) methods of display
6) interpretation
B. Application to specific forecast problems
1) low-level jet
2) characterizing shear environment for thunderstorms
3) application to mountain wave activity
4) diagnosing turbulence
5) timing arrival of upper air features
6) inversion depth
C. How do profilers supplement or complement other observing systems?
Profilers versus:	raobs
			ACARS
			WSR-88D
			GOES
			POES

Instructional components
	4 manuals / 4 videotapes - FSL
	NWSTC note guide
		(These two sources address wind profiling radar almost exclusively; they need updating)
	Need new material on RASS and GPS/IPW
	Use of Web sites for training (modify existing sites?)
	Use of 6-min moment data - teletraining
		Returned power (zeroth moment)
		Radial velocity (first moment)
		Spectrum width (second moment)
	Make 6-min data available on AWIPS.
	Inferring vertical moisture gradient from 0th, 1st, and 2nd moment data
	Web site for watching local changes in IPW

Proposed evaluation
	Application oriented evaluation



2. UNIT 2: Lightning - Don B., Dick L., Fred M. 
(Proposed Producers: SR/SSD (Dan Smith and Ken Waters)
  Proposed SME: Dick Orville with DFW Office )

Description of Job Duty Competency to be Achieved

Develop an understanding of the causes of lightning and relate that understanding to the internal conditions of thunderstorm development and decay for various meteorological conditions. 

Description of Need.

As part of the NWS Warnings and QPF decision making processes, forecasters should know how to relate remotely sensed lightning to conceptual models of thunderstorm structures and processes.   Forecasters need to understand the strengths and limitations of this new data set.

Specific Job Task Skills and Knowledge

1. Knowledge 

Evaluate the strengths and limitations of the lightning data to augment radar and satellite date as related to thunderstorm evolution.

2. Task Skill

Determine the magnitude and extent of thunderstorm hazards to the public, aviation and fire weather.

Instructional Components

1. Storm Electrification Processes

This component will focus on what causes charge separation within thunderstorms that lead to lightning.  Topics will include charge separation mechanisms, temperature/ liquid water/ ice relationships to charge separation; discharge processes; positive vs negative flash polarity; strokes vs flashes; current; cloud-to-ground vs intracloud.

2. Lightning Detection Systems

This component will focus on the lightning detection systems.  Topics will include theory of operation, direction finding technology, time of arrival technology, Lightning Mapper system; ASOS and other single site sensors, the current National Lightning Detection Network (NLDN; proprietary) and the NLDN detection efficiency, location accuracy, and uniformity of coverage; system status and plans(?).

3. Lightning Climatology

This component will focus on the historic distribution of thunderstorms.  Topics will cover thunderstorm day climatologies, the 10 year NLDN climatology, regional climatologies, local climatologies (develop), and studies of lightning deaths and injuries; lightning safety rules.

4. Lightning Applications to Weather Phenomena

This component will relate lightning to specific weather phenomena.  Topics will include heavy rain, severe thunderstorms (tornado, hail, microbursts, and MCS), hurricane and tropical storms, winter events, and convective hazards to aircraft.

5. Examples

This component will provide interactive examples for various meteorological situations on how to incorporate into NWS products and services.  Case studies would include a severe storm case, a hail case, a heavy rain case, a heavy snow case, and other case studies of interest.

6. References/ Glossary

This component will provide an on line list of references and related reading material.  A glossary of terms used should also be provided.

7. Proposed evaluation
	Application oriented evaluation





3. UNIT 3: Radar - Done (D. Burgess)

4. UNIT 4: Satellite - Done (T. Mostek)


5. UNIT 5: AWIPS Multi-Source Data Displays
(Don H., Kevin S., Brian M., Laurie H.)
Producer - Brian Motta

Description of Job Duty Competency to be Achieved
Access, evaluate, and integrate information  from various data sources used in NWS products and services.

Description of Need
As part of the integrated data analysis and forecasting process, forecasters should know how to properly integrate and display in-situ, remote sensing, map, and model data. Forecasters need to understand the strengths and limitations of the various data sets, displays, and procedures necessary to expeditiously and accurately determine the most relevant depictions from all available data.

Specific Job Task Skills and Knowledge
1) Develop a basic proficiency with the AWIPS user interface for each data source.
a) animation
b) image display
c) overlay
d) map databases

2) Create AWIPS procedures (macros) for various data displays

3) Display point/grid data with an image background

4) Know the necessary steps for image combinations necessary to perform multi-data-source analysis
a) image combination tool
b) product maker *
c) volume browser

5)  Incorporate image combinations with other data sources.

6) Knowledge of all AWIPS data intervals and spatial resolutions available for all domains (scales).     (not covered elsewhere)

7) Knowledge of appropriate color tables for particular data sets.
a) discrete versus continuous data

8) Skill in creating and comparing vertical profiles (RAOB, model, RADAR, profiler)

9) Knowledge of appropriate use of "hot cursor" functionality in analysis of data sets.

10) Skill in using merged data sets with the fade tool. 

11) Skill in using the feature tracking tool to compare with various image data sources and algorithm outputs.

12) Skill in using cross-sections from various data sources.

13) Understand the limitations of image combinations (geolocation)

14) Knowledge and skill in interpreting mosaic-ed imagery.

15) Knowledge and skill in understanding the display consequences of AWIPS remapping


Instructional Components 
1) Display products
a) AWIPS User's Guide
b) additional considerations (we provide)

2) AWIPS procedure creation
a) AWIPS User's Guide
b) additional considerations of procedure creation (we provide)

3) (web page) Maximizing image combinations and modifying color tables in order to best produce the merged product. 

4) (web page) Module will explain the AWIPS versions of the data sets' intervals, spatial resolutions, and domains.

5) (teletraining/www) Learn about the way color tables are used to display data

6) Learn the differences in measurement techniques and which measurements should be compared.

7) Develop cross-sectional analysis skills using appropriate AWIPS data sets.

8) Examine sensor and observation geolocations on scales from greater than synoptic to less than WFO (ie. county scale) for warning/analysis and forecast applications.

9) Understand the time-matching and data compositing processes for observational data sets (ie. satellite, radar, etc.)

Proposed Evaluation

Proficiency Checklist

6. UNIT 6: Model Data Assessment - 
Producer - L. Spayd
(Ken W., LeRoy S., Tony M.)

Description of Job Competency: Assess the mesoscale and synoptic scale numerical model analysis using integrated datasets to determine timing and accuracy of key features.

Description of Need: As part of the model data assessment, forecasters should know how to evaluate the accuracy of the current model analysis/initialization based on the integrated datasets. To improve the selection of the appropriate model guidance and to adjust this guidance for analysis errors, known biases and systematic errors.

Job Task Skills and Knowledge:

1. Use available integrated datasets and products to identify key synoptic and sub-synoptic scale features.

2. Use model overlay display capability to verify previous model forecast and new model analysis using model and integrated datasets.

3. Use available integrated datasets and products to identify key mesoscale features to analyze problem of the day.

4. Use mesoscale model and continuous data assimilation cycles to obtain understanding of the current state of the models with respect to the key mesoscale features and problem of the day.


7. UNIT 7: Phenomena-Based Case Studies Demonstrating Forecast Process 
– Scott Bachmeier, Mike Eilts, Mike Massig, Karen Winston
– Producer: Scott Bachmeier

Purpose: Demonstrate the effective use of AWIPS in solving a variety of forecast problems; build a library of short case studies (similar to the CIRA Satellite Interpretation Discussion and the CIMSS GOES Gallery); solicit input from WFO's for case study candidates or topics

Case studies should be short and concise (2-3 Web pages),  phenomenon-based, and contain the following points:

1. Statement of the Forecast Problem

2. Conceptual models which are applicable

3. Case-specific details
- Explain the Forecast Process
- Discuss the various sensor and algorithm strengths/weaknesses
- Outline specific AWIPS procedures, with links to more detailed instructions if needed
- Show why the integrated approach is helpful

4. Allow the ability to pose questions to Subject Matter Experts (SME's) via threaded discussion groups