SDUS38 PAFC 311629 NVWODN 0Lr-'f0.LrLr- 9<  244 55''5665EE5TT5cc5qq555555555555##5225AA5PP5__5nn5||55555 ZZZ@@gg  TIMEALT KFT  1629 1624 1619 Y1614 21608  1602 1557 1552 1546 s1541 L1535 1 2 3 4 5x 6j 7[ 8L 9=10.111213141516171819202224|25m26_28P30A35240#4550 : ;" C) G- G, |H- nH+ _F. P9 AF/ 2?, #K. "1 ]6 W/ `1 >0 D 9" B, F* H+ |G- nB( _H- P() AB0 2/% #H, 6, cC R0 A2 D1 A, E] 6^# 6 :  A, E/ G- |J+ nB _F AA0 2 #) 1/ M+ R+  2/ [) g7 g:  gB+ gG* gE' g|E! gn9# g_J gP?2 gAE. g2& g#>2 g@5 g?2 gB1 gTF& @D @: @C+ @G) @K+ @|K% @nS @_O @PV @AO @2;' @4 @H1 @I5 @E\ @ A# E+ H, H+ |N" nT _@1 PU) A6 2@2 ?1  R( >- A2 Y) 6Z @ ?! D+ F( J* |F' nX _R PU' A=) #@1 I  U% K ?  C* F) D+ |J& n>( _@, P; A=+ 2F" #9 G( \& @* P$ X' @) C G M >! B, ?0 >/ |@. nA, _=, P?, A;, 2;. #<- :1 ?+ >, ?* D* B) >' G& K' Q EY J ;  A) >0 =0 |D+ nB( _D PO AC 2= #@$ @( @' ?) @+ E' F( D) D# O* ]  Ef 6[ ZG Z: ZD+ ZE/ ZG- Z|D" ZnC Z_I ZPB  ZAF Z2@ Z#I ZA  Z>( ZB( ZA$ ZF' ZG ZC) ZD ZK ZS Z[ ZT]) ZEZ" Z6TNDNDNDNDND|NDmND_NDPNDAND2ND#NDNDNDNDNDND|NDmND_NDPND#NDNDLNDNDNDNDND|NDmND_NDPNDAND2ND#NDND`ND`ND`ND`ND`ND`ND`ND`|ND`mND`_ND`AND`2ND`#ND`ND9ND9ND9ND9ND9ND9ND9ND9ND9|ND9mND9_ND9PND92ND9#ND9NDNDNDNDNDND|NDmND_NDPNDAND#NDND.NDNDNDNDNDNDNDNDND|NDmND_NDPNDAND2ND#NDNDNDND|NDmND_NDPNDAND2ND#NDND|NDmND_NDPND2ND#NDNDz|NDzmNDz_NDzPNDz#NDzNDSmNDS_NDS#NDSNDXdPfdLrLr- 9<P VAD Algorithm Output 07/31/23 16:29 P ALT U V W DIR SPD RMS DIV SRNG ELEV P 100ft m/s m/s cm/s deg kts kts E-3/s nm deg P 007 -3.9 -2.6 NA 056 009 6.0 NA 5.67 0.5 P 010 -7.1 -4.4 NA 058 016 7.1 NA 5.67 0.9 P 010 -7.4 -4.6 NA 058 017 6.5 NA 5.90 0.9 P 014 -9.9 -5.9 -0.6 059 022 8.5 0.0198 16.20 0.5 P 020 -15.0 -9.0 NA 059 034 6.0 NA 6.13 2.4 P 021 -16.7 -9.9 -1.9 059 038 6.0 0.0592 16.20 0.9 P 029 -20.3 -9.2 -2.5 066 043 3.3 0.0243 16.20 1.3 P 030 -19.2 -8.3 NA 067 041 5.4 NA 7.74 3.1 P 038 -20.4 -7.5 -2.4 070 042 3.8 -0.0089 16.20 1.8 P 040 -21.8 -7.7 NA 071 045 4.2 NA 8.35 4.0 P 048 -20.6 -7.2 -2.7 071 042 3.0 0.0072 16.20 2.4 P 050 -21.5 -7.3 NA 071 044 2.4 NA 17.18 2.4 P 060 -21.8 -7.3 NA 072 045 2.3 NA 12.90 4.0 P 060 -21.8 -7.2 -2.1 072 045 1.8 -0.0181 16.20 3.1 P VAD Algorithm Output 07/31/23 16:29 P ALT U V W DIR SPD RMS DIV SRNG ELEV P 100ft m/s m/s cm/s deg kts kts E-3/s nm deg P 070 -20.9 -6.6 NA 072 043 3.5 NA 12.00 5.1 P 075 -22.7 -6.9 -2.5 073 046 1.8 0.0070 16.20 4.0 P 080 -22.0 -8.0 NA 070 046 2.7 NA 13.79 5.1 P 090 -8.9 -28.2 NA 018 057 9.1 NA 12.51 6.4 P 094 -22.6 -8.8 -0.8 069 047 1.5 -0.0335 16.20 5.1 P 100 -22.5 -8.4 NA 070 047 1.6 NA 13.95 6.4 P 110 -20.1 -10.4 NA 063 044 6.8 NA 12.39 8.0 P 120 -22.7 -6.2 NA 075 046 3.3 NA 13.55 8.0 P 130 -14.1 -20.8 NA 034 049 6.3 NA 14.70 8.0 P 140 -27.7 1.3 NA 093 054 5.2 NA 15.85 8.0 P 143 -27.1 2.0 -50.8 094 053 2.8 0.3406 16.20 8.0 P 150 -24.2 -1.1 NA 087 047 2.8 NA 17.00 8.0 P 160 -24.8 2.6 NA 096 049 3.3 NA 18.15 8.0 P 200 -21.8 -11.3 NA 062 048 3.2 NA 43.03 4.0 2 ADAPTABLE PARAMETERS - WIND PROFILE 2 2 2 VAD ANALYSIS SLANT RANGE 16.2 NMI 2 2 BEGINNING AZIMUTH ANGLE 0.0 DEGREE 2 2 ENDING AZIMUTH ANGLE 0.0 DEGREE 2 2 NUMBER OF PASSES 2 2 2 RMS THRESHOLD 9.7 KNOTS 2 2 SYMMETRY THRESHOLD 13.6 KNOTS 2 2 DATA POINTS THRESHOLD 25 2 2 2 2 2 2 ALTITUDES SELECTED 2 1000 2000 3000 4000 5000 6000 2 7000 8000 9000 10000 11000 12000 2 13000 14000 15000 16000 17000 18000 2 19000 20000 22000 24000 25000 26000 2 28000 30000 35000 40000 45000 50000 2 2 OPTIMUM SLANT RANGE 16.2 2 2 2 2 2