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By John Knaff NOAA/NESDIS Fort Collins, CO John.Knaff@noaa.gov

Understanding and (possibly) rectifying historical and regional wind-pressure relationship differences. By John Knaff NOAA/NESDIS Fort Collins, CO John.Knaff@noaa.gov. Why are we here?.

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By John Knaff NOAA/NESDIS Fort Collins, CO John.Knaff@noaa.gov

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  1. Understanding and (possibly) rectifying historical and regional wind-pressure relationship differences By John Knaff NOAA/NESDIS Fort Collins, CO John.Knaff@noaa.gov

  2. Why are we here? The intent of the IBTrACS project is to overcome data availability issues, and to freely disseminate this new global dataset. This was achieved by working directly with all the Regional Specialized Meteorological Centers and other international centers and individuals to create a global best track dataset, merging storm information from multiple centers into one product and archiving the data for public use. Purpose: The workshop will gather international experts in global tropical cyclone best track data to discuss a variety of topics that would serve to enhance the existing IBTrACS dataset.

  3. IBTrACS Considerations • The maximum winds/ MSLP in the best tracks • Inhomogeneous by construction • Satellite coverage / operational data access & tools • When Dvorak intensity estimates became available • Different Dvorak Tables, prior to 1978 • Visible vs. EIR techniques vs. Objective Dvorak • Different wind-pressure relationships • Different applications of wind-pressure relationships • Estimate wind • Estimate pressure • Different averaging periods • TC structure

  4. Outline • Understanding • Why wind-pressure relationships (WPRs) were developed • How they have been used historically • Why there are regional differences • Offer Possible Solutions to Enhance IBTrACS and Reanalysis efforts. • Knaff and Zehr (2007) • Courtney and Knaff (2009)

  5. Wind-Pressure Relationships were Operational (not Climatological) Tools 1940’s – 1970’s 1970’s - Present Dvorak & aircraft provide wind estimates Winds estimates now more numerous Having greater reliability Remotely sensed & survivability is not as big of an issue Wind is still most important! Pressure is estimated via WPR for legacy reasons/ model bogus input One size fits all Compromise: Pressure does not matter to the forecast (doesn’t matter, good enough) • Pressure Measurements • More numerous (ships, surface, recon) • Having greater precision • Having greater survivability • Wind is what is important! • One size fits all Compromise: To improve the stability of wind estimates use pressures to estimate the wind ( better, good enough)

  6. Historical & Regional Differences • Out of necessity • Sometimes independent • Regional considerations • Environmental pressure • Mean size • Mean latitude • Multiple formulations • Cyclostophic form • Statistical fit to data • Dvorak influences Everyone, it seems, had to have their own wind-pressure relationship

  7. Various Wind-Pressure Relationships (WPR) Some historical WPR V60 vs. ΔP • Atkinson & Holliday (1977;AH77)/Dvorak (1984 WPAC) • RMSC La Reunion • TCWC Perth (-2008) • JTWC (-2007) • Dvorak (1975) • RMSC Miami • RMSC Honolulu • Koba (1990, 1991) • RMSC Tokyo • Crane (circa 1985) • TCWC Brisbane (-2008) • Love & Murphy (1985) • Some cases TCWC Darwin (-2008)

  8. Things to consider in the IBTrACS process • How the use of WPRs has resulted ininhomogeneous historical MSLP/Intensity records • The possibility of assigning a more consistent MSLPs to historical best tracks (i.e., wind to MSLP) • Understanding howWPRs could aid reanalysis efforts at RMSCs • MSLP to Wind when MSLP available (i.e., Atlantic, N. Pacific) • Consistency checks • Inter-best track • Versus observations

  9. Minimum Requirements for WPRs • Use existing archives of operational or easily created historical information • Fixes (Aircraft, Dvorak, Drops) • Best tracks • Global Reanalyzes • Should closely follow the physics related to the problem and account for • TC wind field structure • TC environment • TC translation • Variations of latitude

  10. First Principles • Vortex in gradient balance • Steady State • Azimuthal Mean • Gradient form P≈F(lat,renv,Penv, Vt, Vt^2) This implies: Lower (higher) pressures occur at higher (lower) latitude, for larger (smaller) circulation systems, and for smaller (larger) radii of maximum winds given the same maximum wind.

  11. Operational/Historical Inputs • Have from the best track • V60,V600 or MSLP estimate • Location • May have from advisories and fixes • Storm speed (instantaneous) • Pressure of Outer Closed Isobar (POCI) • Radius of Outer Closed Isobar (ROCI) • Radius of 34-, 50-, 64-, or 100-kt winds • Dvorak, Recon fixes • Radius of Maximum winds (recon, visible eye only)* • Could calculate from global re-analyzes and best track archives • Outer (@ 500 km) tangential winds (e.g., Knaff and Zehr) • ROCI • POCI • Storm speeds (6/12 –hourly) * RMW provide for model bogus requirements is often unreliable (goldilocks RMW)

  12. Solutions in hand • Can account for variations of structure (to some degree), environmental pressure, latitude and translation • Knaff & Zehr (2007) • Courtney & Knaff (2009) • Holland-based models – NEXT Talk

  13. Knaff & Zehr (2007) • Accounts for variations of latitude, size, environmental pressure and storm speed. Size and Latitude contribute most! • Uses global re-analyses to estimate • Environmental Pressure (900 km) • TC Size expressed as a ratio to climatology • Tangential windat 500km from reanalyzes • Climatological tangential windat 500km (from Knaff et al. 2007) • Fixes/advisories/best track provide • Latitude • Storm speed • Intensity (V(60,600) or MSLP) • Statistically fits the data (Explaining ≈ 90 % of the variance) • Shortcomings • Different equations for wind –to-pressure/pressure-to-wind • Inner-core structure (i.e., RMW, multiple wind maxima)* * RMW is often provided as part of the storm bogus, but is not always representative of the actual RMW, which is often more difficult to estimate.

  14. Knaff & Zehr Examples P►W Typhoon June (1975) Largest storm (Reanalysis) Size(V500/V500c) = 1.57 Leads to R34 ~ 345 nmi Environmental P (Reanalysis)= ~1008 -1005 hPa Max intensity = 160 kt (JTWC) MSLP = 875hPa Rozenkranz et al 1978 (JGR)

  15. June 1975 Vmax Estimates Vmax [kt] Best track intensity follows A&H 77 Date/Time

  16. Knaff & Zehr Examples P►W Typhoon Forrest (1983) One of the most intense (Reanalysis) Most rapid (~100 hPa/d) Size(V500/V500c) = 1.10 Leads to R34 ~ 300 nmi Environmental P (Reanalysis)= ~1012 -1006 hPa Max intensity = 150 kt (JTWC) MSLP = 883hPa

  17. Forrest 1983 Vmax Estimates Vmax [kt] Best track intensity follows A&H 77 Date/Time

  18. Courtney & Knaff (2009) • Also accounts for variations of latitude, size, environmental pressure and storm speed. Size and latitude contribute most! • Modifies Knaff and Zehr • Uses operation input • Corrects for issues related to estimating MSLP of low latitude storms • Advisories/best tracks provide • POCI from which environmental pressure is estimated (+ 2 hPa) • Mean radius of gales (non-zero quadrants) which provides TC size • Latitude • Storm Speed • Intensity (V(60,600) ) • Shortcomings • Inner-core structure (i.e., RMW, multiple wind maxima) • Published form only estimates MSLP given V(60,600) ) FORTRAN 90 routines for wind-to-pressure and pressure-to-wind using the Courtney and Knaff parameterization are available from ftp://rammftp.cira.colostate.edu/knaff/C&KWPR/

  19. The Good Blondie When it works The Bad Angel eyes When it doesn’t The wind-pressure analogy The Ugly Tuco The real issues

  20. The Good - Gustav (2008) Pressure from Wind (C&K) Wind from Pressure (C&K)

  21. The Good - Sinlaku (2008) Pressure from Wind (C&K) Wind from Pressure (C&K)

  22. The Bad - Ike (2008) Pressure from Wind (C&K) Wind from Pressure (C&K)

  23. The Problem with Ike 1 km IR 9 Sept 2218 UTC H*Wind 10 Sept 130 UTC

  24. The Ugly - Remaining Issues • Inhomogeneous intensity estimates • Poor/Biased intensity estimates • Sparse historical records (ship, landfall, estimate methods, reconnaissance) • Multiple intensity estimates (multiple agencies/ multiple methods) • Lack of information about TC structure • Man power for human review!

  25. Questions?

  26. References Courtney, J., and J. Knaff, 2009: Adapting the Knaff and Zehr Wind-Pressure Relationship for operational use in Tropical Cyclone Warning Centres. Aust. Met. Mag., in Review/Revised. Holland, G., 2008: A Revised Hurricane Pressure–Wind Model. Mon. Wea. Rev., 136, 3432–3445. Knaff, J.A. and R.M. Zehr, 2008:  Reply. Weather and Forecasting, 23:4, 762-770. Knaff, J.A., and R.M. Zehr, 2007: Reexamination of Tropical Cyclone Wind-Pressure Relationships. Wea Forecasting, 22:1, 71–88.  Knaff, J.A., C. R. Sampson, M. DeMaria, T. P. Marchok, J. M. Gross, and C. J. McAdie, 2007: Statistical Tropical Cyclone Wind Radii Prediction Using Climatology and Persistence, Wea. Forecasting, 22:4, 781–791.  Landsea, C. W., C. Anderson, N. Charles, G. Clark, J. Dunion, J. Fernandez-Partagas, P. Hungerford, C. Neumann, and M. Zimmer, 2004: The Atlantic hurricane database re-analysis project: Documentation for the 1851-1910 alterations and additions to the HURDAT database. _Hurricanes and Typhoons: Past, Present and Future_, R. J. Murnane and K.-B. Liu, Eds., Columbia University Press, 177-221.

  27. Extra Slides

  28. Knaff & Zehr (2007) • WPR based upon • Environmental Pressure (Penv) • Reanalysis MSLP averaged at 900 km from the center • TC Size (S) • TC Speed (c) • Latitude (ⱷ) • Parameterizations

  29. Knaff & Zehr (2007) Cont • Statistically fits the data (Explaining ≈ 90 % of the variance) • Shortcomings • Different equations for wind –to-pressure/pressure-to-wind • Inner-core structure (i.e., RMW, multiple wind maxima)* * RMW is often provided as part of the storm bogus, but is not always representative of the actual RMW, which is often more difficult to estimate.

  30. Courtney & Knaff (2009) • Modifies Knaff and Zehr • Uses operation input • Corrects for issues related to estimating MSLP of low latitude storms • Advisories/best tracks provide • POCI from which environmental pressure is estimated • Mean radius of gales (non-zero quadrants) which provides TC size • Latitude • Storm Speed • Intensity (V(60,600) ) • Parameterizations

  31. Courtney & Knaff (2009) cont. • Shortcomings • Inner-core structure (i.e., RMW, multiple wind maxima) • Published form only estimates MSLP give n V(60,600) ) FORTRAN 90 routines for wind-to-pressure and pressure-to- wind using the Courtney and Knaff parameterization are available from ftp://rammftp.cira.colostate.edu/knaff/C&KWPR/

  32. Courtney & Knaff (2009) • Modifies Knaff and Zehr • Uses operation input • Corrects for issues related to estimating MSLP of low latitude storms • Advisories/best tracks provide • POCI from which environmental pressure is estimated • Mean radius of gales (non-zero quadrants) which provides TC size • Latitude • Storm Speed • Intensity (V(60,600) ) • Shortcomings • Inner-core structure (i.e., RMW, multiple wind maxima) • Published form only estimates MSLP give n V(60,600) ) FORTRAN 90 routines for wind-to-pressure and pressure-to- wind using the Courtney and Knaff parameterization are available from ftp://rammftp.cira.colostate.edu/knaff/C&KWPR/

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