package basic import ( "b612.me/astro/tools" "fmt" "math" "testing" "time" ) func Test_Jq(t *testing.T) { data := GetJieqiLoops(2019, 24) for i := 1; i < 25; i++ { fmt.Println(JDE2Date(data[i])) } //fmt.Println(JDE2Date(GetWHTime(2019, 10))) //fmt.Println(JDE2Date(GetJQTime(2020, 0))) //date := TD2UT(GetJQTime(2020, 0), true) //fmt.Println(HSunApparentLo(date)) } func TestZD(t *testing.T) { jde := 2452982.9872345612 zd := HJZD(jde) fmt.Println(zd) if zd != -0.003746747950462434 { t.Fatal("not equal") } zd = JJZD(jde) fmt.Println(zd) if zd != 0.001513453926274198 { t.Fatal("not equal") } } func Test_SunLo(t *testing.T) { fmt.Printf("%.14f\n", HSunTrueLo(2458840.0134162)) fmt.Printf("%.14f", HSunApparentLo(2458840.0134162)) } func Test_SunDiff(t *testing.T) { n := JDECalc(2000, 1, 1) var maxRa, maxDec, maxLo float64 for i := float64(0); i < 365.2422*30; i++ { tLo := HSunApparentLo(n + i) tRa, tDec := HSunApparentRaDec(n + i) fRa, fDec := SunApparentRaDec(n + i) fLo := SunApparentLo(n + i) tmp := tools.Limit360(math.Abs(tRa - fRa)) if tmp > 300 { tmp = 360 - tmp } if tmp > maxRa { maxRa = tmp } tmp = tools.Limit360(math.Abs(tDec - fDec)) if tmp > 300 { tmp = 360 - tmp } if tmp > maxDec { maxDec = tmp } tmp = tools.Limit360(math.Abs(tLo - fLo)) if tmp > 300 { tmp = 360 - tmp } if tmp > maxLo { maxLo = tmp } } fmt.Printf("%.15f %.15f %.15f\n", maxRa*3600, maxDec*3600, maxLo*3600) } func Benchmark_SunRise(b *testing.B) { jde := GetNowJDE() for i := 0; i < b.N; i++ { //GetNowJDE() GetSunRiseTime(jde, 115, 32, 8, 0, 10) } } func Benchmark_SunLo(b *testing.B) { jde := GetNowJDE() for i := 0; i < b.N; i++ { //GetNowJDE() HSunApparentLo(jde) } } func Test_Cal(t *testing.T) { fmt.Println(JDE2Date(GetSolar(2020, 1, 1, false, 8.0/24.0))) fmt.Println(JDE2Date(GetSolar(2020, 4, 1, false, 8.0/24.0))) fmt.Println(JDE2Date(GetSolar(2020, 4, 1, true, 8.0/24.0))) fmt.Println(JDE2Date(GetSolar(2033, 11, 3, false, 8.0/24.0))) fmt.Println(JDE2Date(GetSolar(2033, 11, 3, true, 8.0/24.0))) fmt.Println(JDE2Date(GetSolar(2034, 1, 1, false, 8.0/24.0))) } func Test_SunRise(t *testing.T) { a := time.Now().UnixNano() //b := GetSunRiseTime(GetNowJDE(), 120, 32, 8, 0) //b = GetSunRiseTime(GetNowJDE()+1, 145, 32, 8, 0) //b = GetSunRiseTime(GetNowJDE()+2, 135, 50, 8, 0) //b = GetSunRiseTime(GetNowJDE()+3, 125, 32, 8, 0) //b = GetSunRiseTime(GetNowJDE()+4, 75, 32, 8, 0) //b = GetSunRiseTime(GetNowJDE()+5, 85, 32, 8, 0) //b = GetSunRiseTime(GetNowJDE()+6, 95, 32, 8, 0) //b = GetSunRiseTime(GetNowJDE()+7, 105, 32, 8, 0) //b = GetSunRiseTime(GetNowJDE()+8, 115, 32, 8, 0) b := GetSunRiseTime(GetNowJDE()+9, 125, 32, 8, 0, 10) fmt.Println(time.Now().UnixNano() - a) fmt.Println(SunHeight(b, 115, 32, 8)) fmt.Println(JDE2Date((b))) fmt.Println(time.Now().UnixNano() - a) } func Test_SunTwilightMo(t *testing.T) { cst := time.FixedZone("cst", 8*3600) jde := Date2JDE(time.Date(2023, 10, 3, 15, 59, 0, 0, cst)) fmt.Println(GetAsaTime(jde, 113.58880556, 87.66833333, 8, -6)) for i := 10.0; i < 90.0; i += 0.3 { fmt.Println(i, GetAsaTime(jde, 125.45506654, float64(i), 8, -6)) } } func Test_SunTwilightEv(t *testing.T) { cst := time.FixedZone("cst", 8*3600) jde := Date2JDE(time.Date(2023, 10, 3, 15, 59, 0, 0, cst)) for i := 10.0; i < 90.0; i += 0.3 { fmt.Println(i, GetBanTime(jde, 115, float64(i), 8, -18)) } } func Test_SunRiseRound(t *testing.T) { jde := GetNowJDE() for i := 10.0; i < 90.0; i += 0.3 { fmt.Println(i, GetSunRiseTime(jde, 115, float64(i), 8, 0, 0)) } } func Test_SunDown(t *testing.T) { jde := GetNowJDE() for i := 10.0; i < 90.0; i += 0.3 { fmt.Println(i, GetSunDownTime(jde, 115, float64(i), 8, 0, 0)) } } func Test_SunAz(t *testing.T) { cst := time.FixedZone("cst", 8*3600) fmt.Println(SunAngle(Date2JDE(time.Date(2022, 5, 30, 11, 55, 0, 0, cst)), 120, 30, 8.0)) }