SDUS38 PAFC 200028 NVWAKC 0Mz'88+0 !MzMz =i@<  244 55''5665EE5TT5cc5qq555555555555##5225AA5PP5__5nn5||55555 ZZZ@@gg  TIMEALT KFT  0028 0024 0019 Y0014 20010  0005 0000 2355 2350 s2345 L2340 1 2 3 4 5x 6j 7[ 8L 9=10.111213141516171819202122|23m24_25P26A28230#3540 O s!  `" k# |v& nv' _t) Pu) As+ 2s- #o, n6 p7 p8 i= N y/ a t* j$ |n% np* _|( Pu) At+ 2s/ #p. s1 r7 q8 k> jC Q _ g d  l$ |s& ny( _% P$ Ax* 2u. #u. u2 t5 s9 r9 p; o: i8 gG gW ge gd! gg& g|s' gny( g_& gPw* gAu- g2u/ g#u0 gt2 gv4 gt8 gs9 gs; gl6 gr; gkB @I @b @h @e @h% @|r) @nv+ @_{' @Pw- @At- @2u0 @#u1 @u2 @u4 @w8 @s9 @q: @h: @t> @o> @eC M k i j p& |s) ny) _{( P}& As- 2u1 #u/ u4 u5 v9 o< q: h; |@ o; P g j g r& |t( n{( _}' P~% Ay) 2x+ #t0 u3 u6 q8 v9 p: k; {? iB j@ Q f o g m# |u' nx) _}' P~% Ay) 2x+ #w, t3 t6 s8 r9 n; j; {> p? mB rI M a X f  q) |v( nx) _|( Pz& Av* 2u. #t. t4 t6 r8 p8 l: i9 f9 V D U b" w- |t( nx* _~' Px( At, 2t. #s1 s3 s6 r8 o7 k9 f; xC }A k? yH ZX Zd Z_ Zg Zn% Z|s( Znx) Z_}' ZPu& ZAs) Z2s. Z#q2 Zs4 Zr6 Zq8 Zp7 Zk9 Zi; ZxF Zn< Zl@NDNDNDNDNDND|NDmND_NDPNDAND2ND#NDNDNDNDNDNDND|NDmND_NDPNDAND2ND#NDNDNDNDND|NDmND_NDPNDAND2ND#NDND`ND`ND`|ND`mND`_ND`PND`AND`2ND`#ND`ND9ND9|ND9mND9_ND9PND9AND92ND9#ND9NDNDND|NDmND_NDPNDAND2ND#NDNDND|NDmND_NDPNDAND2ND#NDND|NDmND_NDPNDAND2ND#NDNDNDNDND|NDmND_NDPNDAND2ND#NDNDz|NDzmNDz_NDzPNDzANDz2NDz#NDzNDSNDS|NDSmNDS_NDSPNDSANDS2NDS#NDSNDXdP88+d!MzMz =i@<P VAD Algorithm Output 04/20/24 00:28 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 005 -9.8 1.3 NA 098 019 5.9 NA 5.67 0.5 P 007 -11.9 0.8 NA 094 023 5.2 NA 5.67 0.9 P 010 -9.8 -1.9 NA 079 019 6.4 NA 6.02 1.3 P 012 -4.8 -5.3 -0.1 042 014 4.5 0.0039 16.20 0.5 P 019 -6.0 -5.5 -0.1 048 016 3.5 0.0001 16.20 0.9 P 020 -15.5 7.1 NA 115 033 4.7 NA 17.19 0.9 P 026 -14.2 3.0 -3.6 102 028 5.1 0.1690 16.20 1.3 P 030 -5.2 -12.4 NA 023 026 1.4 NA 14.19 1.8 P 035 -17.1 5.2 -7.9 107 035 4.1 0.1501 16.20 1.8 P 040 -17.2 1.8 NA 096 034 6.3 NA 32.38 0.9 P 046 -19.4 7.5 -13.0 111 040 3.7 0.1530 16.20 2.4 P 050 -17.3 5.2 NA 107 035 5.1 NA 30.35 1.3 P 058 -18.7 7.8 -18.4 113 039 3.3 0.1330 16.20 3.1 P 060 -17.1 9.0 NA 118 038 2.6 NA 17.17 3.1 P VAD Algorithm Output 04/20/24 00:28 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 -17.8 9.6 NA 118 039 1.6 NA 15.75 4.0 P 073 -19.6 8.6 -17.2 114 042 1.4 -0.0448 16.20 4.0 P 080 -19.2 9.2 NA 116 041 1.6 NA 17.98 4.0 P 090 -18.5 9.5 NA 117 041 3.0 NA 31.89 2.4 P 092 -18.4 10.0 -14.0 119 041 2.4 -0.0742 16.20 5.1 P 100 -19.8 9.3 NA 115 043 4.0 NA 28.23 3.1 P 110 -21.1 10.0 NA 115 045 3.7 NA 24.57 4.0 P 114 -20.5 8.9 -18.7 113 044 2.8 0.0545 16.20 6.4 P 120 -20.9 8.1 NA 111 044 2.4 NA 17.19 6.4 P 130 -26.0 9.3 NA 110 054 2.8 NA 28.89 4.0 P 140 -26.4 10.5 NA 112 055 1.3 NA 20.03 6.4 P 140 -25.6 13.0 -27.1 117 056 2.4 0.0855 16.20 19.5 P 150 -26.5 10.7 NA 112 056 1.4 NA 21.44 6.4 P 160 -30.4 8.0 NA 105 061 1.1 NA 35.27 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 21000 22000 23000 24000 2 25000 26000 28000 30000 35000 40000 2 2 OPTIMUM SLANT RANGE 16.2 2 2 2 2 2