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Line 3: In astronomy '''air mass''' is a measure of the amount of atmosphere between the observer and the object being observed. It is a function of the ''zenith angle'' (the angle between the line of sight an vertical) and the altitude of the observer. It is defined as the integral of the atmospheric density along the line of sight and is usually expressed relative to the air mass at zenith. Thus, looking straight up gives an air mass of one (regardless of observer's altitude) and viewing at any zenith angle greater than zero gives higher values. You will need to integrate <math>\rho</math>(h(a,z,x)) where <math>\rho</math>(h) is the atmospheric density for a given height above sea level, and h(a,z,x) is the height above sea level for a point at distance x along the line of sight. Determining this last function requires some trigonometry. For this task you can assume: :*   The density of Earth's atmosphere is proportional to exp(-a/8500 metres) :*   The Earth is a perfect sphere of radius 6731 km. ;Task: :*   Write a function that calculates the air mass for an observer at a given altitude   ''' ''a'' '''   above sea level and zenith angle   ''z' ''z.'' ''' :*   Show the air mass for zenith angles '''0''' to '''90''' in steps of '''5''' degrees for an observer at sea level. :*   Do the same for the   [https://www.nasa.gov/mission_pages/SOFIA/overview/index.html NASA SOFIA infrared telescope],   which has ana ~~orbiting~~cruising altitude of 13,700 meters   (about 8.3 miles), ::     it flies in a specially retrofitted Boeing 747 about four flights a week. <br><br> =={{header\|~~FreeBASIC~~11l}}== {{trans\|Python}} ~~<lang freebasic>~~ <syntaxhighlight lang="11l">V DEG = 0.017453292519943295769236907684886127134 V RE = 6371000 V dd = 0.001 V FIN = 10000000 F rho(a) ‘ the density of air as a function of height above sea level ’ R exp(-a / 8500.0) F height(Float a; z, d) ‘ a = altitude of observer z = zenith angle (in degrees) d = distance along line of sight ’ R sqrt((:RE + a) ^ 2 + d ^ 2 - 2 * d * (:RE + a) * cos((180 - z) * :DEG)) - :RE F column_density(a, z) ‘ integrates density along the line of sight ’ V (dsum, d) = (0.0, 0.0) L d < :FIN V delta = max(:dd, (:dd) * d) dsum += rho(height(a, z, d + 0.5 * delta)) * delta d += delta R dsum F airmass(a, z) R column_density(a, z) / column_density(a, 0) print("Angle 0 m 13700 m\n "(‘-’ * 36)) L(z) (0.<91).step(5) print(f:‘{z:3} {airmass(0, z):12.7} {airmass(13700, z):12.7}’)</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.0000000 1.0000000 5 1.0038096 1.0038096 10 1.0153847 1.0153848 15 1.0351774 1.0351776 20 1.0639905 1.0639909 25 1.1030594 1.1030601 30 1.1541897 1.1541908 35 1.2199808 1.2199825 40 1.3041893 1.3041919 45 1.4123417 1.4123457 50 1.5528040 1.5528102 55 1.7387592 1.7387692 60 1.9921200 1.9921366 65 2.3519974 2.3520272 70 2.8953137 2.8953729 75 3.7958235 3.7959615 80 5.5388581 5.5392811 85 10.0789622 10.0811598 90 34.3298114 34.3666656 </pre> =={{header\|Ada}}== {{trans\|C}} {{works with\|Ada 2012}} <syntaxhighlight lang="ada"> with Ada.Text_IO; use Ada.Text_IO; with Ada.Numerics.Generic_Elementary_Functions; with Ada.Integer_Text_IO; use Ada.Integer_Text_IO; procedure Main is subtype double is Long_Float; package double_io is new Ada.Text_IO.Float_IO (double); use double_io; package Elementary_Double is new Ada.Numerics.Generic_Elementary_Functions (Float_Type => double); use Elementary_Double; -- degrees to radians Deg : constant := 0.017_453_292_519_943_295_769_236_907_684_886_127_134; -- Earth radius in meters Re : constant := 6_371_000.0; -- integrate in this fraction of the distance already covered Dd : constant := 0.001; -- integrate only to a height of 10000km. efectively infinity Fin : constant := 10_000_000.0; function rho (a : double) return double is (Exp (-a / 8_500.0)); function height (a : double; z : double; d : double) return double is aa : double := Re + a; hh : double := Sqrt (aa * aa + d * d - 2.0 * d * aa * Cos ((180.0 - z) * Deg)); begin return hh - Re; end height; function column_density (a : double; z : double) return double is sum : double := 0.0; d : double := 0.0; d_delta : double; begin while d < Fin loop -- adaptive step size to avoid it taking forever d_delta := Dd * d; if d_delta < Dd then d_delta := Dd; end if; sum := sum + rho (height (a, z, d + 0.5 * d_delta)) * d_delta; d := d + d_delta; end loop; return sum; end column_density; function air_mass (a : double; z : double) return double is (column_density (a, z) / column_density (a, 0.0)); z : double := 0.0; begin Put_Line ("Angle 0 m 13700 m"); Put_Line ("------------------------------------"); while z <= 90.0 loop Put(Item => Integer(z), Width => 2); Put (Item => air_mass (0.0, z), Fore => 8, Aft => 8, Exp => 0); Put (Item => air_mass (13_700.0, z), Fore => 8, Aft => 8, Exp => 0); New_Line; z := z + 5.0; end loop; end Main; </syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|AWK}}== <syntaxhighlight lang="awk"> # syntax: GAWK -f AIR_MASS.AWK # converted from FreeBASIC BEGIN { dd = 0.001 # integrate in this fraction of the distance already covered DEG = 0.017453292519943295769236907684886127134 # degrees to radians RE = 6371000 # Earth radius in meters print("Angle 0 m 13700 m") for (z=0; z<=90; z+=5) { printf("%5d %12.8f %12.8f\n",z,am_airmass(0,z),am_airmass(13700,z)) } exit(0) } function am_airmass(a,z) { return am_column_density(a,z) / am_column_density(a,0) } function am_column_density(a,z, d,delta,sum) { # integrates density along the line of sight while (d < 10000000) { # integrate only to a height of 10000km, effectively infinity delta = max(dd,(dd)d) # adaptive step size to avoid it taking forever sum += am_rho(am_height(a,z,d+0.5delta))delta d += delta } return(sum) } function am_height(a,z,d, aa,hh) { # a - altitude of observer # z - zenith angle in degrees # d - distance along line of sight aa = RE + a hh = sqrt(aa^2 + d^2 - 2daacos((180-z)DEG)) return(hh-RE) } function am_rho(a) { # density of air as a function of height above sea level return exp(-a/8500.0) } function max(x,y) { return((x > y) ? x : y) } </syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|BASIC}}== ==={{header\|BASIC256}}=== {{trans\|FreeBASIC}} <syntaxhighlight lang="freebasic">global RE, dd, LIM RE = 6371000 #Earth radius in meters dd = 0.001 #integrate in this fraction of the distance already covered LIM = 10000000 #integrate only to a height of 10000km, effectively inLIMity print "Angle 0 m 13700 m" print "------------------------------------" for z = 0 to 90 step 5 print rjust(z,2); " "; ljust(airmass(0, z),13,"0"); " "; ljust(airmass(13700, z),13,"0") next z end function max(a, b) if a > b then return a else return b end function function rho(a) #the density of air as a function of height above sea level return exp(-a/8500.0) end function function height(a, z, d) #a = altitude of observer #z = zenith angle (in degrees) #d = distance along line of sight AA = RE + a HH = sqr(AA^2 + d^2 - 2dAAcos(radians(180-z))) return HH - RE end function function column_density(a, z) #integrates density along the line of sight sum = 0.0 d = 0.0 while d < LIM delta = max(dd, (dd)d) #adaptive step size to avoid it taking forever: sum += rho(height(a, z, d+0.5delta)) * delta d += delta end while return sum end function function airmass(a, z) return column_density(a, z) / column_density(a, 0) end function</syntaxhighlight> ==={{header\|FreeBASIC}}=== <syntaxhighlight lang="freebasic"> #define DEG 0.017453292519943295769236907684886127134 'degrees to radians #define RE 6371000 'Earth radius in meters Line 57 ⟶ 328: print using "## ##.######## ##.########";z;airmass(0, z);airmass(13700, z) next z </syntaxhighlight> ~~</lang>~~ {{out}} Line 83 ⟶ 354: 90 34.32981136 34.36666557 </pre> ==={{header\|True BASIC}}=== {{trans\|FreeBASIC}} <syntaxhighlight lang="qbasic">FUNCTION max(a, b) IF a > b then LET max = a else LET max = b END FUNCTION FUNCTION rho(a) !the density of air as a function of height above sea level LET rho = exp(-a/8500) END FUNCTION FUNCTION height(a, z, d) !a = altitude of observer !z = zenith angle (in degrees) !d = distance along line of sight LET aa = re+a LET hh = sqr(aa^2+d^2-2daacos((180-z)deg)) LET height = hh-re END FUNCTION FUNCTION columndensity(a, z) !integrates density along the line of sight LET sum = 0 LET d = 0 DO while d < lim LET delta = max(dd, (dd)d) !adaptive step size to avoid it taking forever: LET sum = sum+rho(height(a, z, d+.5delta))delta LET d = d+delta LOOP LET columndensity = sum END FUNCTION FUNCTION airmass(a, z) LET airmass = columndensity(a, z)/columndensity(a, 0) END FUNCTION LET deg = .0174532925199433 !degrees to radians LET re = 6371000 !Earth radius in meters LET dd = .001 !integrate in this fraction of the distance already covered LET lim = 10000000 !integrate only to a height of 10000km, effectively infinity PRINT "Angle 0 m 13700 m" PRINT "------------------------------------" FOR z = 0 to 90 step 5 PRINT using "## ##.######## ##.########": z, airmass(0, z), airmass(13700, z) NEXT z END</syntaxhighlight> =={{header\|C}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="c">#include <math.h> #include <stdio.h> #define DEG 0.017453292519943295769236907684886127134 // degrees to radians #define RE 6371000.0 // Earth radius in meters #define DD 0.001 // integrate in this fraction of the distance already covered #define FIN 10000000.0 // integrate only to a height of 10000km, effectively infinity static double rho(double a) { // the density of air as a function of height above sea level return exp(-a / 8500.0); } static double height(double a, double z, double d) { // a = altitude of observer // z = zenith angle (in degrees) // d = distance along line of sight double aa = RE + a; double hh = sqrt(aa aa + d * d - 2.0 * d * aa * cos((180 - z) * DEG)); return hh - RE; } static double column_density(double a, double z) { // integrates density along the line of sight double sum = 0.0, d = 0.0; while (d < FIN) { // adaptive step size to avoid it taking forever double delta = DD * d; if (delta < DD) delta = DD; sum += rho(height(a, z, d + 0.5 * delta)) * delta; d += delta; } return sum; } static double airmass(double a, double z) { return column_density(a, z) / column_density(a, 0.0); } int main() { puts("Angle 0 m 13700 m"); puts("------------------------------------"); for (double z = 0; z <= 90; z+= 5) { printf("%2.0f %11.8f %11.8f\n", z, airmass(0.0, z), airmass(13700.0, z)); } }</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|Delphi}}== {{works with\|Delphi\|6.0}} {{trans\|GO}} {{libheader\|SysUtils,StdCtrls}} <syntaxhighlight lang="Delphi"> const RE = 6371000; { radius of earth in meters} const DD = 0.001; { integrate in this fraction of the distance already covered} const FIN = 1e7; { integrate only to a height of 10000km, effectively infinity} function rho(a: double): double; { The density of air as a function of height above sea level.} begin Result:=Exp(-a / 8500); end; function Radians(degrees: double): double; { Converts degrees to radians} begin Result:= degrees * Pi / 180 end; function Height(A, Z, D: double): double; { a = altitude of observer} { z = zenith angle (in degrees)} { d = distance along line of sight} var AA,HH: double; begin AA := RE + A; HH := Sqrt(AAAA + DD - 2DAACos(Radians(180-z))); Result:= HH - RE; end; function ColumnDensity(A, Z: double): double; { Integrates density along the line of sight.} var Sum,D,Delta: double; begin Sum := 0.0; D := 0.0; while D < FIN do begin delta := Max(DD, DDD); { adaptive step size to avoid it taking forever} Sum:=Sum + Rho(Height(A, Z, D+0.5Delta)) Delta; D:=D + delta; end; Result:= Sum; end; function AirMass(A, Z: double): double; begin Result:= ColumnDensity(A, Z) / ColumnDensity(a, 0); end; procedure ShowAirMass(Memo: TMemo); var Z: integer; begin Memo.Lines.Add('Angle 0 m 13700 m'); Memo.Lines.Add('------------------------------------'); Z:=0; while Z<=90 do begin Memo.Lines.Add(Format('%2d %11.8f %11.8f', [z, airmass(0, Z), airmass(13700, Z)])); Z:=Z+5; end; end; </syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 Elapsed Time: 189.304 ms. </pre> =={{header\|EasyLang}}== {{trans\|FreeBASIC}} <syntaxhighlight lang=easylang> func rho a . return pow 2.718281828459 (-a / 8500) . func height a z d . AA = 6371000 + a HH = sqrt (AA * AA + d * d - 2 * d * AA * cos (180 - z)) return HH - 6371000 . func density a z . while d < 10000000 delta = higher 0.001 (0.001 * d) sum += rho height a z (d + 0.5 * delta) * delta d += delta . return sum . func airmass a z . return density a z / density a 0 . numfmt 8 2 print "Angle 0 m 13700 m" print "------------------------" for z = 0 step 5 to 90 print z & " " & airmass 0 z & " " & airmass 13700 z . </syntaxhighlight> =={{header\|Factor}}== {{trans\|FreeBASIC}} {{works with\|Factor\|0.99 2021-02-05}} <syntaxhighlight lang="factor">USING: formatting io kernel math math.functions math.order math.ranges math.trig sequences ; CONSTANT: RE 6,371,000 ! Earth's radius in meters CONSTANT: dd 0.001 ! integrate in this fraction of the distance already covered CONSTANT: FIN 10,000,000 ! integrate to a height of 10000km ! the density of air as a function of height above sea level : rho ( a -- x ) neg 8500 / e^ ; ! z = zenith angle (in degrees) ! d = distance along line of sight ! a = altitude of observer :: height ( a z d -- x ) RE a + :> AA AA sq d sq + 180 z - deg>rad cos AA * d * 2 * - sqrt RE - ; :: column-density ( a z -- x ) ! integrates along the line of sight 0 0 :> ( s! d! ) [ d FIN < ] [ dd dd d * max :> delta ! adaptive step size to avoid taking it forever s a z d 0.5 delta * + height rho delta * + s! d delta + d! ] while s ; : airmass ( a z -- x ) [ column-density ] [ drop 0 column-density ] 2bi / ; "Angle 0 m 13700 m" print "------------------------------------" print 0 90 5 <range> [ dup [ 0 swap airmass ] [ 13700 swap airmass ] bi "%2d %15.8f %17.8f\n" printf ] each</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|Go}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="go">package main import ( "fmt" "math" ) const ( RE = 6371000 // radius of earth in meters DD = 0.001 // integrate in this fraction of the distance already covered FIN = 1e7 // integrate only to a height of 10000km, effectively infinity ) // The density of air as a function of height above sea level. func rho(a float64) float64 { return math.Exp(-a / 8500) } // Converts degrees to radians func radians(degrees float64) float64 { return degrees * math.Pi / 180 } // a = altitude of observer // z = zenith angle (in degrees) // d = distance along line of sight func height(a, z, d float64) float64 { aa := RE + a hh := math.Sqrt(aaaa + dd - 2daamath.Cos(radians(180-z))) return hh - RE } // Integrates density along the line of sight. func columnDensity(a, z float64) float64 { sum := 0.0 d := 0.0 for d < FIN { delta := math.Max(DD, DDd) // adaptive step size to avoid it taking forever sum += rho(height(a, z, d+0.5delta)) delta d += delta } return sum } func airmass(a, z float64) float64 { return columnDensity(a, z) / columnDensity(a, 0) } func main() { fmt.Println("Angle 0 m 13700 m") fmt.Println("------------------------------------") for z := 0; z <= 90; z += 5 { fz := float64(z) fmt.Printf("%2d %11.8f %11.8f\n", z, airmass(0, fz), airmass(13700, fz)) } }</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|Java}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="java">public class AirMass { public static void main(String[] args) { System.out.println("Angle 0 m 13700 m"); System.out.println("------------------------------------"); for (double z = 0; z <= 90; z+= 5) { System.out.printf("%2.0f %11.8f %11.8f\n", z, airmass(0.0, z), airmass(13700.0, z)); } } private static double rho(double a) { // the density of air as a function of height above sea level return Math.exp(-a / 8500.0); } private static double height(double a, double z, double d) { // a = altitude of observer // z = zenith angle (in degrees) // d = distance along line of sight double aa = RE + a; double hh = Math.sqrt(aa * aa + d * d - 2.0 * d * aa * Math.cos(Math.toRadians(180 - z))); return hh - RE; } private static double columnDensity(double a, double z) { // integrates density along the line of sight double sum = 0.0, d = 0.0; while (d < FIN) { // adaptive step size to avoid it taking forever double delta = Math.max(DD * d, DD); sum += rho(height(a, z, d + 0.5 * delta)) * delta; d += delta; } return sum; } private static double airmass(double a, double z) { return columnDensity(a, z) / columnDensity(a, 0.0); } private static final double RE = 6371000.0; // Earth radius in meters private static final double DD = 0.001; // integrate in this fraction of the distance already covered private static final double FIN = 10000000.0; // integrate only to a height of 10000km, effectively infinity }</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|jq}}== '''Adapted from [[#Wren\|Wren]]''' {{works with\|jq}} '''Works with gojq, the Go implementation of jq''' '''Preliminaries''' <syntaxhighlight lang="jq">def pi: 4 * (1\|atan); def radians: . * pi / 180; def lpad($len): tostring \| ($len - length) as $l \| (" " * $l)[:$l] + .; # Input: a number # Output: a string with $digits fractional decimal digits, with proper rounding def fmt($width; $digits): . as $in \| tostring \| index(".") as $ix \| if test("[eE]") then . elif $ix then pow(10; $digits) as $p \| ($in * $p \| round \| tostring) as $s \| if test("[eE]") then $s else ($s \| index(".")) as $ix \| if $ix then $s[:$ix + 1] + $s[$ix+1: $ix+1+$digits] else $s[:-$digits] + "." + $s[-$digits:] end end else . + "." + "0" * digits end \| lpad($width);</syntaxhighlight> '''Physics''' <syntaxhighlight lang="jq"># constants def RE: 6371000; # radius of earth in meters def DD: 0.001; # integrate in this fraction of the distance already covered def FIN: 1e7; # integrate only to a height of 10000km, effectively infinity # The density of air as a function of height above sea level. def rho: (-./8500) \| exp; # a = altitude of observer (in m) # z = zenith angle (in degrees) # d = distance along line of sight (in m) def height($a; $z; $d): (RE + $a) as $aa \| (($aa * $aa + $d * $d - 2 * $d * $aa * ((180-$z)\|radians\|cos) )\|sqrt ) - RE; # Integrates density along the line of sight. def columnDensity($a; $z): { sum: 0, d: 0 } \| until (.d >= FIN; ([DD, DD * .d] \| max) as $delta # adaptive step size to avoid it taking forever \| .sum = .sum + ((height($a; $z; .d + 0.5 * $delta))\|rho) * $delta \| .d += $delta ) \| .sum ; def airmass(a; z): columnDensity(a; z) / columnDensity(a; 0); "Angle 0 m 13700 m", "------------------------------------", ( range(0; 91; 5) \| "\(lpad(2)) \(airmass(0; .)\|fmt(11;8)) \(airmass(13700; .)\|fmt(11;8))" )</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|Julia}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="julia">using Printf const DEG = 0.017453292519943295769236907684886127134 # degrees to radians const RE = 6371000 # Earth radius in meters const dd = 0.001 # integrate in this fraction of the distance already covered const FIN = 10000000 # integrate only to a height of 10000km, effectively infinity """ the density of air as a function of height above sea level """ rho(a::Float64)::Float64 = exp(-a / 8500.0) """ a = altitude of observer z = zenith angle (in degrees) d = distance along line of sight """ height(a, z, d) = sqrt((RE + a)^2 + d^2 - 2 * d * (RE + a) * cosd(180 - z)) - RE """ integrates density along the line of sight """ function column_density(a, z) dsum, d = 0.0, 0.0 while d < FIN delta = max(dd, (dd)d) # adaptive step size to avoid it taking forever: dsum += rho(height(a, z, d + 0.5 delta)) * delta d += delta end return dsum end airmass(a, z) = column_density(a, z) / column_density(a, 0) println("Angle 0 m 13700 m\n", "-"^36) for z in 0:5:90 @printf("%2d %11.8f %11.8f\n", z, airmass(0, z), airmass(13700, z)) end </syntaxhighlight>{{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|Nim}}== {{trans\|Wren}} <syntaxhighlight lang="nim">import math, strformat const Re = 6371000 # Radius of earth in meters. Dd= 0.001 # Integrate in this fraction of the distance already covered. Fin = 1e7 # Integrate only to a height of 10000km, effectively infinity. func rho(a: float): float = ## The density of air as a function of height above sea level. exp(-a / 8500) func height(a, z, d: float): float = ## Height as a function of altitude (a), zenith angle (z) ## in degrees and distance along line of sight (d). let aa = Re + a let hh = sqrt(aa * aa + d * d - 2 * d * aa * cos(degToRad(180-z))) result = hh - Re func columnDensity(a, z: float): float = ## Integrates density along the line of sight. var d = 0.0 while d < Fin: let delta = max(Dd, Dd * d) # Adaptive step size to avoid it taking forever. result += rho(height(a, z, d + 0.5 * delta)) * delta d += delta func airmass(a, z: float): float = columnDensity(a, z) / columnDensity(a, 0) echo "Angle 0 m 13700 m" echo "------------------------------------" var z = 0.0 while z <= 90: echo &"{z:2} {airmass(0, z):11.8f} {airmass(13700, z):11.8f}" z += 5</syntaxhighlight> {{out}} <pre>Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557</pre> =={{header\|Perl}}== {{trans\|Raku}} <syntaxhighlight lang="perl">use strict; use warnings; use feature <say signatures>; no warnings 'experimental::signatures'; use List::Util 'max'; use constant PI => 2atan2(1,0); # π use constant DEG => PI/180; # degrees to radians use constant RE => 6371000; # Earth radius in meters use constant dd => 0.001; # integrate in this fraction of the distance already covered use constant FIN => 10000000; # integrate only to a height of 10000km, effectively infinity # Density of air as a function of height above sea level sub rho ( $a ) { exp( -$a / 8500 ); } sub height ( $a, $z, $d ) { # a = altitude of observer # z = zenith angle (in degrees) # d = distance along line of sight my $AA = RE + $a; my $HH = sqrt $AA2 + $d2 - 2 $d * $AA * cos( (180-$z)DEG ); $HH - RE; } # Integrates density along the line of sight sub column_density ( $a, $z ) { my $sum = 0; my $d = 0; while ($d < FIN) { my $delta = max(dd, dd $d); # Adaptive step size to avoid it taking forever $sum += rho(height($a, $z, $d + $delta/2))$delta; $d += $delta; } $sum; } sub airmass ( $a, $z ) { column_density($a, $z) / column_density($a, 0); } say 'Angle 0 m 13700 m'; say '------------------------------------'; for my $z (map{ 5$_ } 0..18) { printf "%2d %11.8f %11.8f\n", $z, airmass(0, $z), airmass(13700, $z); }</syntaxhighlight> {{out}} <pre>Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557</pre> =={{header\|Phix}}== <!--<~~lang~~syntaxhighlight ~~Phix~~lang="phix">(phixonline)--> <span style="color: #008080;">constant</span> <span style="color: #000000;">RE</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">6371000</span><span style="color: #0000FF;">,</span> <span style="color: #000080;font-style:italic;">// radius of earth in meters</span> <span style="color: #000000;">DD</span> <span style="color: #0000FF;">=</span> <span style="color: #000000;">0.001</span><span style="color: #0000FF;">,</span> <span style="color: #000080;font-style:italic;">// integrate in this fraction of the distance already covered</span> Line 121 ⟶ 1,146: <span style="color: #7060A8;">printf</span><span style="color: #0000FF;">(</span><span style="color: #000000;">1</span><span style="color: #0000FF;">,</span><span style="color: #008000;">"%2d %11.8f %11.8f\n"</span><span style="color: #0000FF;">,</span> <span style="color: #0000FF;">{</span><span style="color: #000000;">z</span><span style="color: #0000FF;">,</span> <span style="color: #000000;">airmass</span><span style="color: #0000FF;">(</span><span style="color: #000000;">0</span><span style="color: #0000FF;">,</span><span style="color: #000000;">z</span><span style="color: #0000FF;">),</span> <span style="color: #000000;">airmass</span><span style="color: #0000FF;">(</span><span style="color: #000000;">13700</span><span style="color: #0000FF;">,</span><span style="color: #000000;">z</span><span style="color: #0000FF;">)})</span> <span style="color: #008080;">end</span> <span style="color: #008080;">for</span> <!--</~~lang~~syntaxhighlight>--> {{out}} <pre> Line 146 ⟶ 1,171: 90 34.32981136 34.36666557 </pre> =={{header\|Python}}== <syntaxhighlight lang="python">""" Rosetta Code task: Air_mass """ from math import sqrt, cos, exp DEG = 0.017453292519943295769236907684886127134 # degrees to radians RE = 6371000 # Earth radius in meters dd = 0.001 # integrate in this fraction of the distance already covered FIN = 10000000 # integrate only to a height of 10000km, effectively infinity def rho(a): """ the density of air as a function of height above sea level """ return exp(-a / 8500.0) def height(a, z, d): """ a = altitude of observer z = zenith angle (in degrees) d = distance along line of sight """ return sqrt((RE + a)2 + d2 - 2 * d * (RE + a) * cos((180 - z) * DEG)) - RE def column_density(a, z): """ integrates density along the line of sight """ dsum, d = 0.0, 0.0 while d < FIN: delta = max(dd, (dd)d) # adaptive step size to avoid it taking forever: dsum += rho(height(a, z, d + 0.5 delta)) * delta d += delta return dsum def airmass(a, z): return column_density(a, z) / column_density(a, 0) print('Angle 0 m 13700 m\n', '-' * 36) for z in range(0, 91, 5): print(f"{z: 3d} {airmass(0, z): 12.7f} {airmass(13700, z): 12.7f}") </syntaxhighlight>{{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.0000000 1.0000000 5 1.0038096 1.0038096 10 1.0153847 1.0153848 15 1.0351774 1.0351776 20 1.0639905 1.0639909 25 1.1030594 1.1030601 30 1.1541897 1.1541908 35 1.2199808 1.2199825 40 1.3041893 1.3041919 45 1.4123417 1.4123457 50 1.5528040 1.5528102 55 1.7387592 1.7387692 60 1.9921200 1.9921366 65 2.3519974 2.3520272 70 2.8953137 2.8953729 75 3.7958235 3.7959615 80 5.5388581 5.5392811 85 10.0789622 10.0811598 90 34.3298114 34.3666656 </pre> =={{header\|Raku}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="raku" line>constant DEG = pi/180; # degrees to radians constant RE = 6371000; # Earth radius in meters constant dd = 0.001; # integrate in this fraction of the distance already covered constant FIN = 10000000; # integrate only to a height of 10000km, effectively infinity #\| Density of air as a function of height above sea level sub rho ( \a ) { exp( -a / 8500 ) } sub height ( \a, \z, \d ) { # a = altitude of observer # z = zenith angle (in degrees) # d = distance along line of sight my \AA = RE + a; sqrt( AA² + d² - 2dAAcos((180-z)DEG) ) - AA; } #\| Integrates density along the line of sight sub column_density ( \a, \z ) { my $sum = 0; my $d = 0; while $d < FIN { my \delta = max(dd, (dd)$d); # Adaptive step size to avoid it taking forever $sum += rho(height(a, z, $d + delta/2))delta; $d += delta; } $sum; } sub airmass ( \a, \z ) { column_density( a, z ) / column_density( a, 0 ) } say 'Angle 0 m 13700 m'; say '------------------------------------'; say join "\n", (0, 5 ... 90).hyper(:3batch).map: -> \z { sprintf "%2d %11.8f %11.8f", z, airmass( 0, z), airmass(13700, z); }</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557</pre> =={{header\|REXX}}== {{trans\|FreeBASIC}} <~~lang~~syntaxhighlight lang="rexx">/REXX pgm calculates the air mass above an observer and an object for various angles./ numeric digits (length(pi()) - length(.)) % 4 /calculate the number of digits to use/ parse arg aLO aHI aBY oHT . /obtain optional arguments from the CL/ Line 157 ⟶ 1,308: if oHT=='' \| oHT=="," then oHT= 13700 /* " " " " " " / w= 30; @ama= 'air mass at' /column width for the two air_masses. / say 'angle\|'center(@ama "sea level", w) center(@ama ~~comma~~commas(oHT) "'meters"', w) /title/ say '"─────┼'"copies(center(""'', w, '"─'"), 2)'─' /display the title sep for the output./ y= left('', w-20) /~~pad~~Y: for alignment of the output cols./ do j=aLO to aHI by aBY; am0= airM(0, j); amht= airM(oHT, j) say center(j, 5)'│'right( format(am0, , 8), w-10)y right( format(amht, , 8), w-10)y end /j/ say "─────┴"copies(center('', w, "─"), 2)'─' /display the foot separator for output/ exit 0 /stick a fork in it, we're all done. / /──────────────────────────────────────────────────────────────────────────────────────/ Line 172 ⟶ 1,325: r2r: return arg(1) // (pi() 2) /normalize radians ──► a unit circle. / e: e= 2.718281828459045235360287471352662497757247093699959574966967627724; return e ~~comma~~commas: parse arg ?; do jc=length(?)-3 to 1 by -3; ?=insert(',', ?, jc); end; return ? /──────────────────────────────────────────────────────────────────────────────────────/ cos: procedure; parse arg x; x= r2r(x); a= abs(x); numeric fuzz min(6, digits() - 3) Line 193 ⟶ 1,346: aa= earthRad + a; return sqrt(aa2 + d2 - 2daacos( d2r(180-z) ) ) - earthRad /──────────────────────────────────────────────────────────────────────────────────────/ colD: procedure; parse arg a,z; sum= 0; d= 0; dd= .001; infinity= 10000000 do while d<infinity; delta= max(dd, ddd) sum= sum + rho( elev(a, z, d + 0.5delta) ) delta; d= d + delta end /while/ return sum</~~lang~~syntaxhighlight> {{out\|output\|text=  when using the default inputs:}} <pre> Line 221 ⟶ 1,374: 85 │ 10.07896219 10.08115981 90 │ 34.32981136 34.36666557 ─────┴───────────────────────────────────────────────────────────── </pre> =={{header\|RPL}}== {{trans\|FreeBASIC}} ≪ → a ≪ a NEG 8500 / EXP ≫ ≫ ‘'''RHO'''’ STO ≪ ''''RHO'''(√(aa^2+D^2-2aaDCOS(180-Z))-re)' EVAL ≫ ‘'''COLD'''’ STO ≪ 6371000 3 PICK OVER + → a z re aa ≪ DEG z 'Z' STO ''''COLD'''' { D 0 1E7 } 1E-7 ∫ DROP 0 'Z' STO ''''COLD'''' { D 0 1E7 } 1E-7 ∫ DROP / ≫ ≫ ‘'''AM'''’ STO ≪ { } 0 90 '''FOR''' z z + z '''AM''' + 5 '''STEP''' ≫ {{out}} <pre> 1: { 0 1 5 1.00380686363 10 1.01537368745 15 1.03515302646 20 1.06394782383 25 1.10299392042 30 1.15409753978 35 1.21985818096 40 1.30403285254 45 1.41214767977 50 1.55256798138 55 1.73847475415 60 1.99177718552 65 2.35157928673 70 2.89478919419 75 3.79512945489 80 5.53784169364 85 10.0771111633 90 34.3235064081 } </pre> =={{header\|Rust}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="rust">const RE: f64 = 6371000.0; // Earth radius in meters const DD: f64 = 0.001; // integrate in this fraction of the distance already covered const FIN: f64 = 10000000.0; // integrate only to a height of 10000km, effectively infinity fn rho(a: f64) -> f64 { // the density of air as a function of height above sea level (-a / 8500.0).exp() } fn height(a: f64, z: f64, d: f64) -> f64 { // a = altitude of observer // z = zenith angle (in degrees) // d = distance along line of sight let aa = RE + a; let hh = (aa aa + d * d - 2.0 * d * aa * (180.0 - z).to_radians().cos()).sqrt(); hh - RE } fn column_density(a: f64, z: f64) -> f64 { // integrates density along the line of sight let mut sum = 0.0; let mut d = 0.0; while d < FIN { // adaptive step size to avoid it taking forever let mut delta = DD * d; if delta < DD { delta = DD; } sum += rho(height(a, z, d + 0.5 * delta)) * delta; d += delta; } sum } fn airmass(a: f64, z: f64) -> f64 { column_density(a, z) / column_density(a, 0.0) } fn main() { println!("Angle 0 m 13700 m"); println!("------------------------------------"); for a in (0..=90).step_by(5) { let z = a as f64; println!( "{:2} {:11.8} {:11.8}", z, airmass(0.0, z), airmass(13700.0, z) ); } }</syntaxhighlight> {{out}} <pre>Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|Seed7}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="seed7">$ include "seed7_05.s7i"; include "float.s7i"; include "math.s7i"; const float: DEG is 0.017453292519943295769236907684886127134; #degrees to radians const float: RE is 6371000.0; #Earth radius in meters const float: dd is 0.001; #integrate in this fraction of the distance already covered const float: FIN is 10000000.0; #integrate only to a height of 10000km, effectively infinity const func float: rho (in float: a) is #the density of air as a function of height above sea level return exp(-a / 8500.0); const func float: height (in float: a, in float: z, in float: d) is func #a is altitude of observer #z is zenith angle (in degrees) #d is distance along line of sight result var float: r is 0.0; local var float: AA is 0.0; var float: HH is 0.0; begin AA := RE + a; HH := sqrt( AA 2.0 + d 2.0 - 2.0 * d * AA * cos((180.0 - z) * DEG) ); r := HH - RE; end func; const func float: columnDensity (in float: a, in float: z) is func #integrates density along line of sight result var float: sum is 0.0; local var float: d is 0.0; var float: delta is 0.0; begin while d < FIN do delta := max(dd, dd * d); #adaptive step size to avoid taking it forever sum +:= rho(height(a, z, d + 0.5 * delta)) * delta; d +:= delta; end while; end func; const func float: airmass (in float: a, in float: z) is return columnDensity(a, z) / columnDensity(a, 0.0); const proc: main is func local var integer: zz is 0; var float: z is 0.0; begin writeln("Angle 0 m 13700 m"); writeln("------------------------------------"); for zz range 0 to 90 step 5 do z := flt(zz); write(z lpad 4); write(airmass(0.0, z) digits 8 lpad 15); writeln(airmass(13700.0, z) digits 8 lpad 17); end for; end func;</syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0.0 1.00000000 1.00000000 5.0 1.00380963 1.00380965 10.0 1.01538466 1.01538475 15.0 1.03517744 1.03517765 20.0 1.06399053 1.06399093 25.0 1.10305937 1.10306005 30.0 1.15418974 1.15419083 35.0 1.21998076 1.21998246 40.0 1.30418931 1.30419190 45.0 1.41234169 1.41234567 50.0 1.55280404 1.55281025 55.0 1.73875921 1.73876915 60.0 1.99212000 1.99213665 65.0 2.35199740 2.35202722 70.0 2.89531368 2.89537287 75.0 3.79582352 3.79596149 80.0 5.53885809 5.53928113 85.0 10.07896219 10.08115981 90.0 34.32981136 34.36666557 </pre> =={{header\|Swift}}== {{trans\|Go}} <syntaxhighlight lang="swift">import Foundation extension Double { var radians: Double { self * .pi / 180 } } func columnDensity(_ a: Double, _ z: Double) -> Double { func rho(_ a: Double) -> Double { exp(-a / 8500) } func height(_ d: Double) -> Double { let aa = 6_371_000 + a let hh = aa * aa + d * d - 2 * d * aa * cos((180 - z).radians) return hh.squareRoot() - 6_371_000 } var sum = 0.0 var d = 0.0 while d < 1e7 { let delta = max(0.001, 0.001 * d) sum += rho(height(d + 0.5 * delta)) * delta d += delta } return sum } func airMass(altitude: Double, zenith: Double) -> Double { return columnDensity(altitude, zenith) / columnDensity(altitude, 0) } print("Angle 0 m 13700 m") print("------------------------------------") for z in stride(from: 0.0, through: 90.0, by: 5.0) { let air = String( format: "%2.0f %11.8f %11.8f", z, airMass(altitude: 0, zenith: z), airMass(altitude: 13700, zenith: z) ) print(air) }</syntaxhighlight> {{out}} <pre>Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557</pre> =={{header\|Wren}}== Line 227 ⟶ 1,661: {{libheader\|Wren-math}} {{libheader\|Wren-fmt}} <~~lang~~syntaxhighlight ~~ecmascript~~lang="wren">import "./math" for Math import "./fmt" for Fmt // constants Line 236 ⟶ 1,670: // The density of air as a function of height above sea level. var rho = Fn.new { \|a\| ~~Math.exp~~(-a/8500).exp } // a = altitude of observer Line 252 ⟶ 1,686: var d = 0 while (d < FIN) { var delta = ~~Math~~DD.max(~~DD,~~ DD * d) // adaptive step size to avoid it taking forever sum = sum + rho.call(height.call(a, z, d + 0.5 * delta)) * delta d = d + delta Line 267 ⟶ 1,701: Fmt.print("$2d $11.8f $11.8f", z, airmass.call(0, z), airmass.call(13700, z)) z = z + 5 }</~~lang~~syntaxhighlight> {{out}} <pre> Angle 0 m 13700 m ------------------------------------ 0 1.00000000 1.00000000 5 1.00380963 1.00380965 10 1.01538466 1.01538475 15 1.03517744 1.03517765 20 1.06399053 1.06399093 25 1.10305937 1.10306005 30 1.15418974 1.15419083 35 1.21998076 1.21998246 40 1.30418931 1.30419190 45 1.41234169 1.41234567 50 1.55280404 1.55281025 55 1.73875921 1.73876915 60 1.99212000 1.99213665 65 2.35199740 2.35202722 70 2.89531368 2.89537287 75 3.79582352 3.79596149 80 5.53885809 5.53928113 85 10.07896219 10.08115981 90 34.32981136 34.36666557 </pre> =={{header\|XPL0}}== {{trans\|FreeBASIC}} <syntaxhighlight lang="xpl0">define DEG = 0.017453292519943295769236907684886127134; \degrees to radians define RE = 6371000.; \Earth radius in meters define DD = 0.001; \integrate in this fraction of the distance already covered define FIN = 10000000.; \integrate only to a height of 10000km, effectively infinity function real Max(A, B); real A, B; return (if A>B then A else B); function real Rho(A); real A; [ \the density of air as a function of height above sea level return Exp(-A/8500.0) end; \function function real Height( A, Z, D ); real A, \= altitude of observer Z, \= zenith angle (in degrees) D; \= distance along line of sight real AA, HH; [ AA:= RE + A; HH:= sqrt( AAAA + DD - 2.DAACos((180.-Z)DEG) ); return HH - RE; end; \function function real Column_density( A, Z ); real A, Z; \integrates density along the line of sight real Sum, D, Delta; [ Sum:= 0.0; D:= 0.0; while D<FIN do [Delta:= Max(DD, (DD)D); \adaptive step size to avoid it taking forever: Sum:= Sum + Rho(Height(A, Z, D+0.5Delta))*Delta; D:= D + Delta; ]; return Sum; end; \function function real Airmass( A, Z ); real A, Z; [ return Column_density( A, Z ) / Column_density( A, 0. ); end; \function real Z; [Text(0, "Angle 0 m 13700 m^M^J"); Text(0, "------------------------------------^M^J"); Z:= 0.; while Z<=90. do [Format(2, 0); RlOut(0, Z); Format(8, 8); RlOut(0, Airmass(0., Z)); RlOut(0, Airmass(13700., Z)); CrLf(0); Z:= Z + 5.; ] ]</syntaxhighlight> {{out}}