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QUALITY MANAGEMENT, CALIBRATION, TESTING AND COMPARISON OF INSTRUMENTS AND OBSERVING SYSTEMS
WMO TECHNICAL CONFERENCE ON METEOROLOGICAL AND ENVIRONMENTAL INSTRUMENTS AND METHODS OF OBSERVATION TECO-2005 C. Bruce Baker, NOAA USA
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Note the stability
The Backbone
QUALITY MANAGEMENT, CALIBRATION, TESTING AND COMPARISON OF INSTRUMENTS AND OBSERVING SYSTEMS
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• Infrastructure in Place for Quality measurements
• Collects open access data and provides consistent quality assurance and control
• Distributes data and information (via multiple paths) in real time (varies with parameter) and ensures archival
• Abides by national / international standards and fosters the implementation of standards by local and regional observing systems
Functions of an International/National Backbone
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• Management of Network Change
• Parallel Testing• Meta Data• Data Quality and Continuity• Integrated Environmental
Assessment• Complementary Data• Continuity of Purpose• Data and Meta Data Access
Key Components
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MANAGEMENTDocumentation, Performance Measures, and Requirements
PROGRAM POLICY
Determined by Internationalor National Policy
and ScienceDriven Directives
QUALITY MANAGEMENT
SYSTEMPersonnel, Hardware, Ingest, and
Dissemination
QUALITY MANUAL
Requirements Documents
RESEARCHTesting, Intercomparisons, Transfer functions
Overlapping Measurements
IMPLEMENTATIONProgram Infrastructure
VOCABULARY
QUALITY CONTROL
Automated, Manual, Maintenance
QUALITY ASSURANCE
Documented Metadata, Performance Measures
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• Functional Requirements– Systems - parameters, ranges, accuracies,
resolutions, expandability, design life, maintainability
– Program - number of systems, cost and schedule targets, communications
• Commissioning– Defines decision point – when data are official – Sustained operation, data from each site 95% of
the time within one hour and/or successful entry into the archives within 30 days
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Configuration Management
• Change management of hardware and software items, metadata management responsibilities and procedures for CCB
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Test and Evaluation Phase
• Conducted by Evaluation Team
• Reviewed by Ad Hoc Science Working Group
• Six areas Evaluated– Site Selection– Site Installation– Field Equipment and Sensors– Communications– Data Processing and Quality Control– Maintenance
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5 Components of Data Quality Assurance (QA)
• Laboratory Calibration• Routine Maintenance and In-Field
Comparisons• Automated Quality Assurance• Manual Quality Assurance• Metadata, Metadata, Metadata• Ability to Integrate New technology
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Laboratory Calibration
• Every sensor is calibrated before deployment to verify and improve upon the manufacturer’s specifications
• Sensors are routinely rotated back into the lab from the field to be re-calibrated
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Routine Maintenance and In-Field Comparisons
Site Maintenance PassesThree visits scheduled annually
Trouble Ticket or Emergency Repairs
Malfunctioning SensorLightning StrikeCommunication ProblemsTheft and Vandalism
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Site Maintenance Passes
Sensor Inspection
Air Temperature and Humidity sensors are inspected for dust accumulation, spider webbing and wasp nests. The radiation shields of these sensors are also cleaned.
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Trouble Ticket or Emergency Repairs
Trouble Tickets •Issued by the Data QA Manager
•Priorities range from 2 to 30 business days (based on sensor)
•QA Manager provides a description of the problem
•Technicians complete the form with time of fix, serial numbers of sensors and a description of the repairs made
•Technicians may also generate tickets in the field and submit them to the QA Manager
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Quality Assurance of Instruments
Documented in Anomaly Tracking System Users ManualReports of Incidences collected, evaluated, maintenance as neededMetadata records updated
Quality Control Data
Documented in Data Management – Ingest to AccessData ingest
Tests for proper message form, communication errors, etc.Automated
Limits - Gross limits checkVariance - Limits for individual parametersRedundancy - Data inter-comparison relies on multiple sensors
Manual -- Handbook of Manual Monitoring
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Metadata ManagementSurvey to Operations
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Communications Network
Field Sites
Instrument Suite
Communications Device
Processing Unit
Internet
User Community
Access
Ingest
Processing
Quality Control
Maintenance Notification
Maintenance Provider
Flagged-Data Archive
Raw-Data Archive
online
offline
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114 CONUS Geographic Locations Required
• Captures 98% of variance in monthly temperature,
95% in annual precipitation for CONUS.• Average annual error <0.1ºC for temperature,
<1.5% for precipitation• Trend “errors” <0.05ºC per decade• IPCC: projects warming of 0.1-0.3ºC/decade and
precipitation changes of 0–2%/decade for CONUS.
Performance Measures
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Determine the Actual Long-term Changes in Temperature and Precipitation of the Contiguous U.S. (CONUS)
FY2005 Target: Capture more than 96.9% and 91.1% of the temperature and precipitation trends.
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RESEARCH
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Cumulative Precipitation Gauge Comparison Sterling, VA
0.00
4.00
8.00
12.00
16.00
20.00
24.00
Geonor #2
Ott-704
Ott-754
Geonor #1
TB#1
TB#2
Frise-C1
Frise-D3
8"S
8"N
Ott-706
Ott-705
8" Std
8" DFIR
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Tretyakov Shield with OttTretyakov Shield with Ott
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Double Alter with GeonorDouble Alter with Geonor
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Air Temperature & RH MonitoringAt
High Plains Regional Climate Center(Lincoln)
DewTrack MET2010 Standard RMY
New ASOS
ASOS
USCRN Shield
MMTS CRS Gill
Standard HMP243
PMT
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Network Integration
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Cross-Network Transfer Functions
Cooperative Observer Network (~10,000 Stations)
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Planned USCRN Stations at end of 2008 (114* stations)
* Does not Include Alaska, Canada, Hawaii, & GCOS stations
Installed Paired Locations
Installed Single Locations
As of April 26, 2005
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Experimental Product
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Siting Standards Documents Representativeness
• Network Plan• Site Acquisition Plan• Site Information Handbook• Site Survey Plan• Site Survey Handbook• Site Survey Checklist• Site Acquisition Checklist
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Major Principles of Station Siting
• Site is representative of climate of region.• Minimal microclimatic influences.• Long-term (50-100 year) land tenure• Minimal prospects for human development• Avoids agriculture, major water bodies, major forested
areas, basin terrain.• Accessible for calibration & maintenance.• Stable Host Agency or Organization.• Follows WMO Climate Station Siting Guidelines
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Objective Site Scoring
• An objective scoring sheet was developed based on the Leroy method. The score for a station becomes part of the metadata for the station
• Re-scoring of stations is part of the annual maintenance visit; allows tracking time change in representativeness of station meteorology
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• U.S Representative on the Canadian National Monitoring Change Management Board
• Canadian Reference Climate Network program participates on the USCRN Science Review Panel
• USCRN hardware architecture incorporated into Canadian Climate Monitoring Network
• Two nations will exchange and co-locate reference climate stations FY04
International Cooperation ,Collaboration and Partnerships
First step in international cooperation to have commonalityestablished for surface observing systems to monitor climate change
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QUESTIONS
• How do we continue to expand International and National Partnerships??
• What is the best way for the exchange of information??
• How do we glue the system of systems together??
E-Mail: Bruce.Baker@noaa.gov
URL: http://www.ncdc.noaa.gov/oa/climate/uscrn/index.html
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Network Characteristics
• Benchmark Network for temperature and precipitation• Anchor points for USHCN and full COOP network• Long-Term Stability of Observing Site (50+ years) likely to
be free from human encroachment • Sensors Calibrated to Traceable Standards• Planned redundancy of sensors and selected stations• Network Performance Monitoring - Hourly and Daily • Strong Science & Research Component
Recommended