Title: Tropical Cyclone Overview: Lesson 3 Applications of Microwave Data
1Tropical Cyclone Overview Lesson 3Applications
of Microwave Data
- Introduction
- SSM/I algorithms
- Overview of the Advanced Microwave Sounder Unit
(AMSU) - Review of hydrostatic and dynamical balance
approximations - Experimental intensity/structure estimation
algorithm
2GOES Imager Channels Channel 1 - Visible
- .6 µm ( .52- .72) Channel 2
- Shortwave IR - 3.9 µm (3.78- 4.03)
Channel 3 - Water Vapor - 6.7 µm (6.47-7.02)
Channel 4 - Longwave IR - 10.7 µm (10.2-11.2)
Channel 5 - Split Window - 12.0 µm
(11.5-12.5) SSM/I, AMSU Microwave Frequencies
20-150 Ghz (1.5-0.2 cm)
1 2 3 4 5
Microwave
3Special Sensor Microwave Imager (SSM/I)
- Passive Microwave Imager on DMSP polar orbiting
satellite - Conical Scan, 1400 km swath width
- Four Frequencies, Horizontal and Vertical
Polarization - 19.4 GHz (H,V), 22.2 GHz (V), 37.0 GHz (H,V),
85.5 GHz (H,V) - Note Similar frequencies on TRMM satellite
- Horizontal Resolution 15-50 km
- Senses below cloud-top
4SSM/I Products/Applications
- Vertically integrated water vapor, liquid
- Rain rate
- Sea Ice
- Ocean Surface Wind Speed
- 85 GHz ice scattering signal useful for tropical
cyclone analysis - Highlights convectively active regions below
cirrus canopy seen in IR imagery
5A
B
C
A Uses SSM/I Rain Rates B AE uses GOES Longwave
IR (Channel 4) C. GMSRA Combines all GOES channels
6Ocean Surface Winds from SSM/I
- Passive Microwave
- (SSM/I, TMI)
- 19 GHz emissivity increases as capillary waves
and sea foam are generated by wind - Rain, thick clouds degrade algorithm
- Combine 19V GHz, 22V GHz, 37V GHz, 37H GHz
- Winds limited to 40 kt
- Provides speed but not direction
7 Hurricane Jeanne 23 Sept 98 IR
VIS 85 GHz Comp. (From NRL web-site).
8Properties of NOAA-15
- Polar orbiting satellite
- 833 km above earths surface
- 14.2 revolutions per day
- Launched May 13, 1998 (Vandenberg AFB)
- Instrumentation
- AVHRR, HIRS, AMSU, SBUV
- First in new series (NOAA-K,L,M)
- NOAA-16 Launched Fall 2000
9AMSU Instrument Properties
- AMSU-A1
- 13 frequencies 50-89 GHz
- 48 km maximum resolution
- Vertical temperature profiles 0-45 km
- AMSU-A2
- 2 frequencies 23.8, 31.4 GHz
- 48 km maximum resolution
- Precipitable water, cloud water, rain rate
- AMSU-B (interference problems)
- 5 frequencies 89-183 GHz
- 16 km maximum resolution
- Water vapor soundings
10AMSU-A1 Weighting Functions
11AMSU-A2 Weighting Functions
12AMSU-B Weighting Functions
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15Hurricane Mitch AVHRR Image 27 October 1998
NOAA-15
Corresponding AMSU-B 89 GHz
16Typical AMSU Data Coverage
17AMSU-A Moisture Algorithms
- Total Precipitable Water (V)
- V cos(?) fTB(23.8),TB(31.4)
- Cloud Liquid Water (Q)
- Q cos(? ) gTB(23.8),TB(31.4)
- Rain Rate (R)
- R 0.002 Q 1.7
- Tropical Rainfall Potential (TRaP)
- TRaP Ra D/c
- Ra avg. rain rate, Dstorm dia., c Storm
Speed
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19AMSU-A Rainfall Rate for Hurricane Georges
(.01 inches/hr)
TRaP for Key West 6.7 inches
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23Temperature Retrieval Algorithm
- 15 AMSU-A channels included
- Radiances adjusted for side lobes before
conversion to brightness temperatures (BT) - BT adjusted for view angle
- Statistical algorithm converts from BT to
temperature profiles - 40 vertical levels 0.1-1000 mb
- RMS error 1.0-1.5 K compared with rawindsondes
24IR Imagery March 1, 1999
AMSU Temperature Retrieval (570 mb)
25AMSU Tropical Cyclone Applications
- Input for numerical models
- Direct assimilation of AMSU radiances
- Rain rate product input to physical
initialization procedures - Apply hydrostatic/dynamical balance constraints
to obtain height/wind fields - Height/winds input for intensity/structure
intensity estimation technique
26Hydrostatic Balance
- Approximation to vertical momentum equation
- Valid for horizontal scales gt 10 km
- dP/dz -gP/RTv (Height coordinates)
- Ppressure, zheight, Tvvirtual temperature
- Ggravitational constant, Rideal gas constant
- Allows calculation of pressure as a function of
height P(z), given temperature and moisture
profile - d? /dp -RTv/P (Pressure coordinates)
- Allows calculatation of geopotential height as a
function of pressure ?(P) - Both forms require boundary conditions
- Integration can be upwards or downwards
- Contribution from moisture is fairly small and
will be neglected (Tv replaced by T)
27Dynamical Balance Conditions Provides Diagnostic
Relationship Between Height and Wind
- High latitude, synoptic-scale flows
- Geostrophic balance
- Axisymmetric flows
- Gradient balance
- Higher-order approximation to the divergence
equation - Charney balance equation
28Geostrophic Balance(Not valid for tropical
cyclones)
U/fL
29Gradient Balance
- Start with horizontal momentum equations in
cylindrical/pressure coordinates - Assume no variation in the azimuthal direction
- Radial momentum equation reduces to
- V2/r fV d?/dr
- V tangential wind, r radius
- f Coriolis parameter
- ? geopotential height from hydrostatic
equation -
30Charney Nonlinear Balance Equation
- NBE reduces to gradient wind in axisymmetric case
- NBE reduces to geostrophic wind in low-amplitude
case
31Balance Winds from AMSU Data
- Start with Advanced Microwave Sounder Unit (AMSU)
data from NOAA-15 - Apply NESDIS statistical retrieval algorithm to
get T from radiances - Use hydrostatic equation to get height field
- NCEP analysis for lower boundary condition
- Apply gradient (2-D) or Charney (3-D) balance to
get winds - NCEP analysis for lateral boundary condition
322-D AMSU Wind RetrievalSolution of the Gradient
Wind Equation
- Gradient Wind Equation V2/r fV ?r
- Find ? from V ? ?(V2/r fV )dr
- Find V from ? V -fr/2 (fr/2)2 r ?r1/2
- Requires choice of root and (fr/2)2 r ?r gt 0
332D Analyses - Hurricane Gert
Temperature(r,z)
Sfc Pressure (x,y)
Tangential Wind(r,z)
Uncorrected
34Correction for Attenuation by Cloud Liquid Water
and Ice Scattering
- Use data base of 120 cases from 1999 hurricane
season - Derive statistical correction to temperature as a
function of CLW for P lt 300 hPa - Identify isolated cold anomalies related to ice
scattering using threshold technique - Patch cold regions using Laplacian filter from
surrounding data
352-D AMSU Wind Retrieval Results
- gt250 cases analyzed in Atlantic and East Pacific
basins during 1999-2000 - Inner core winds not resolved due to limited
AMSU-A spatial resolution - Statistical relationship between AMSU analyses
and intensity - Large differences in storm sizes
- Useful for wind radii estimation
- Analyses appear to capture vertical structure
changes - 2-D analysis algorithm available for evaluation
in West Pacific
36Isaac 092800 120 kt Joyce 092700 70 kt
AMSU 2-D Winds For Large and Small Storms
37Low-Shear High-Shear
AMSU 2-D Winds In Low-Shear and High-Shear
Storm Environments. (Note the deeper cyclonic
flow in the low-shear cases.)
38Statistical Intensity Estimation
- AMSU resolution prevents direct measurement of
inner core - Correlate parameters from AMSU analyses with
observed storm intensity - AMSU Predictors from 1999 storm sample
- r600 to r0 km pressure drop
- Max tangential wind at 0 and 3 km
- Max upper-level temperature anomaly
- Average cloud-liquid water
- Algorithm explains 70 of variance
- Algorithm will be tested on 2000 data
39Predicted vs. Observerd Maximum
Winds(Preliminary Results with Dependent Data)
40Statistical Size Estimation
- Correlate parameters from AMSU analyses with
observed storm size - Average radius of 34, 50 and 64 kt winds
- AMSU Predictors from 1999 storm sample
- R600 to r0 km pressure drop
- Max tangential wind at 0 and 3 km
- Storm latitude
- Estimated maximum wind
- Average cloud-liquid water
- Algorithm explains 80 of variance
- Algorithm will be tested on 2000 data
41Predicted vs. Observed 34 kt Wind
Radius(Preliminary Results with Dependent Data)
423-D AMSU Wind RetrievalCharney Nonlinear
Balance Equation
- Charney balance equation
- ?2? -(ux)2 2vxuy (vy)2 f? - ?u
- For nondivergent flow u-?y, v ?x, ? ? 2?
- ? 2? -2(?xy)2 2(?xx ?yy) f ? 2? ? ?y
- Find ? from u,v Poisson equation
- Requires boundary values for ?
- Find u,v from ? Monge-Ampere Equation
- Requires boundary values for u,v (or ?)
- Ellipticity condition ? 2? 1/2f2 gt 0
- Possibility of two solutions
43Charney Balance Equation Iterative Solution
- Developed for early NWP models
- Write balance equation as
?2 f? - (ux)2 (vx)2 (uy)2
(vy)2 ?u ? 2? 0 ?2 f? - N
0
where ? ? 2? u -?y v ?x - Solve for ?
? -(f/2) (f/2)2
N1/2 - N N(?) so iteration is necessary
44Charney Balance Equation Variational Solution
- Iterative method sometimes fails for tropical
cyclone case - Variational solution method
- Define cost function as square of balance
equation integrated over domain of interest - Add smoothness penalty term to cost function
- Find u,v to minimize cost function
- Minimization requires cost function gradient,
determined from adjoint of balance equation - Boundary conditions for u,v from NCEP analysis
45Balance Equation Variational Solution - Hurricane
Floyd
46Hurricane Floyd 850 mb Isotachs (kt)
-80 -60 -40 -20 0
47Evaluation of AMSU Winds
AMSU
RECON
48Summary of Lesson 3
- Passive microwave data can penetrate through
cloud tops - Data available from DMSP(SSM/I), NOAA-15/16
(AMSU), and TRMM (TMI) satellites - Algorithms available for ocean surface wind
speed, integrated water content, rainfall rate,
sea ice/snow cover - Data useful for qualitative analysis of tropical
cyclone structure (banding, eye wall, etc) - AMSU temperature sounding can be combined with
hydrostatic/dynamical balance constraints for
tropical cyclone analysis