SDUS33 KILX 182010 NVWILX 0Mx{+%0MxMxz 7 < \L 244 55''5665EE5TT5cc5qq555555555555##5225AA5PP5__5nn5||55555 ZZZ@@gg  TIMEALT KFT  2010 2006 2002 Y1957 21953  1948 1943 1939 1934 s1929 L1925 1 2 3 4 5x 6j 7[ 8L 9=10.111213141516171819202224|25m26_28P30A35240#4550    ! # |( n- _. P* A) 2( $ ' ' * . . + ) ( * , q0 c4 T7      # |( n- _. P+ A( 2) ) ' ( - 0 . * ( ( * . q7 c(    ! " |& n- _. P, A( 2' #) % ) , / 0 . * ( ( ) 0 q9 c= g g g g  g  g|& gn. g_/ gP, gA) g2& g#$ g& g* g- g/ g/ g, g( g' g) g* g: gq8 gc1 gT0 @ @ @ @ @! @|' @n. @_0 @P- @A) @2* @#) @) @* @, @/ @. @+ @' @' @' @* @; @q8 @c9        |$ n- _0 P- A* 2) #' . * . / . ( ( ' & + A q7 c2 T7      " |$ n, _0 P/ A+ 2* #' ( ( 1 / - ) ( ' ' 6 6 q7 c4        |' n- _1 P. A+ 2+ #) , ) + . . ) ' & & 9 8 q: c)     ! |$ n, _1 P. A, 2+ #0 / ) * . - * ( ) : = 7 q9 c5     ! |& n, _1 P1 A, 2+ #3 * ) * ( + * ( ' * < + q1 c, Z Z Z Z Z  Z|& Zn, Z_2 ZP/ ZA, Z2, Z#( Z+ Z' Z( Z( Z( Z* Z( Z( Z+ Z= Z; Zq? Zc %NDAND2ND#NDNDNDPNDAND2ND#NDNDPNDAND2ND#NDND`AND`2ND`#ND`ND9PND9AND92ND9#ND9NDAND2ND#NDNDPNDAND2ND#NDNDPNDAND2ND#NDNDPNDAND2ND#NDNDzPNDzANDz2NDz#NDzNDSPNDSANDS2NDS#NDSNDd%dMxMxz 7 <P VAD Algorithm Output 04/18/24 20:10 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 010 -7.1 9.2 NA 143 023 6.9 NA 4.78 0.5 P 011 -7.3 9.3 NA 142 023 3.2 NA 5.67 0.5 P 013 -7.9 9.4 NA 140 024 2.6 NA 5.67 0.9 P 018 -6.1 9.9 0.7 148 023 3.0 -0.0209 16.20 0.5 P 020 -7.2 10.5 NA 146 025 4.6 NA 6.49 1.8 P 025 -6.2 11.5 0.1 152 025 2.8 0.0310 16.20 0.9 P 030 -4.1 13.3 NA 163 027 3.7 NA 15.24 1.3 P 033 -2.4 14.5 -2.1 171 029 4.0 0.0949 16.20 1.3 P 040 2.7 16.5 NA 189 033 4.7 NA 12.41 2.4 P 041 3.0 15.7 -2.3 191 031 5.1 0.0042 16.20 1.8 P 050 9.4 15.3 NA 212 035 4.3 NA 16.04 2.4 P 052 10.2 15.0 -1.6 214 035 4.3 -0.0228 16.20 2.4 P 060 13.7 15.5 NA 221 040 3.1 NA 15.50 3.1 P 064 14.1 16.4 3.1 221 042 2.7 -0.1325 16.20 3.1 P VAD Algorithm Output 04/18/24 20:10 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 15.3 17.6 NA 221 045 3.2 NA 9.17 6.4 P 079 16.9 16.9 5.9 225 046 3.0 -0.0561 16.20 4.0 P 080 16.9 16.6 NA 225 046 3.1 NA 16.67 4.0 P 090 15.5 15.4 NA 225 042 2.7 NA 15.01 5.1 P 098 14.6 15.5 5.7 223 041 3.0 0.0090 16.20 5.1 P 100 14.5 15.0 NA 224 041 3.0 NA 13.49 6.4 P 110 11.3 17.1 NA 213 040 2.4 NA 45.79 1.8 P 130 12.3 14.1 NA 221 036 0.8 NA 27.63 4.0 P 140 14.8 13.7 NA 227 039 2.0 NA 37.30 3.1 P 147 15.1 12.9 0.1 229 039 1.6 0.0444 16.20 19.5 P 150 14.2 13.9 NA 226 039 1.3 NA 20.61 6.4 P 160 17.2 13.0 NA 233 042 1.7 NA 22.02 6.4 P 170 20.3 11.8 NA 240 046 1.7 NA 23.43 6.4 P 180 19.6 13.4 NA 236 046 1.5 NA 24.83 6.4 P VAD Algorithm Output 04/18/24 20:10 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 190 18.2 12.6 NA 235 043 1.6 NA 26.23 6.4 P 200 17.7 11.1 NA 238 041 2.1 NA 27.63 6.4 P 220 18.2 10.0 NA 241 040 2.1 NA 30.41 6.4 P 240 19.0 10.6 NA 241 042 2.1 NA 33.17 6.4 P 250 20.6 9.5 NA 245 044 2.4 NA 34.55 6.4 P 260 23.3 8.7 NA 249 048 3.1 NA 44.15 5.1 P 280 20.9 16.7 NA 231 052 4.3 NA 58.46 4.0 P 300 27.6 6.5 NA 257 055 1.5 NA 41.37 6.4 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