astro/basic/mars_events.go

package basic

import (
	"math"

	. "b612.me/astro/tools"
)

// Pos

const (
	MARS_S_PERIOD            = 1 / ((1 / 365.256363004) - (1 / 686.98))
	marsEventSearchN         = 16
	marsPhaseCoarseTolerance = 30.0 / 86400.0
)

func marsSunLongitudeDelta(jde, degree float64, filter bool) float64 {
	sub := Limit360(Limit360(MarsApparentLo(jde)-HSunApparentLo(jde)) - degree)
	if filter {
		if sub > 180 {
			sub -= 360
		}
		if sub < -180 {
			sub += 360
		}
	}
	return sub
}

func marsSunLongitudeDeltaN(jde, degree float64, filter bool, n int) float64 {
	sub := Limit360(Limit360(MarsApparentLoN(jde, n)-HSunApparentLoN(jde, n)) - degree)
	if filter {
		if sub > 180 {
			sub -= 360
		}
		if sub < -180 {
			sub += 360
		}
	}
	return sub
}

func marsRADerivative(jde, val float64) float64 {
	sub := MarsApparentRa(jde+val) - MarsApparentRa(jde-val)
	if sub > 180 {
		sub -= 360
	}
	if sub < -180 {
		sub += 360
	}
	return sub / (2 * val)
}

func marsRADerivativeN(jde, val float64, n int) float64 {
	sub := MarsApparentRaN(jde+val, n) - MarsApparentRaN(jde-val, n)
	if sub > 180 {
		sub -= 360
	}
	if sub < -180 {
		sub += 360
	}
	return sub / (2 * val)
}

func marsConjunctionFull(jde, degree float64, next uint8) float64 {
	//0=last 1=next
	daysPerDegree := MARS_S_PERIOD / 360
	currentDelta := marsSunLongitudeDelta(jde, degree, false)
	if next == 0 {
		jde -= (360 - currentDelta) * daysPerDegree
	} else {
		jde += daysPerDegree * currentDelta
	}
	estimateJD := jde
	for {
		prevJD := estimateJD
		longitudeDelta := marsSunLongitudeDelta(prevJD, degree, true)
		longitudeSlope := (marsSunLongitudeDelta(prevJD+0.000005, degree, true) - marsSunLongitudeDelta(prevJD-0.000005, degree, true)) / 0.00001
		estimateJD = prevJD - longitudeDelta/longitudeSlope
		if math.Abs(estimateJD-prevJD) <= 0.00001 {
			break
		}
	}
	return TD2UT(estimateJD, false)
}

func marsConjunction(jde, degree float64, next uint8) float64 {
	//0=last 1=next
	daysPerDegree := MARS_S_PERIOD / 360
	currentDelta := marsSunLongitudeDelta(jde, degree, false)
	if next == 0 {
		jde -= (360 - currentDelta) * daysPerDegree
	} else {
		jde += daysPerDegree * currentDelta
	}
	estimateJD := jde
	for {
		prevJD := estimateJD
		longitudeDelta := marsSunLongitudeDeltaN(prevJD, degree, true, marsEventSearchN)
		longitudeSlope := (marsSunLongitudeDeltaN(prevJD+0.000005, degree, true, marsEventSearchN) - marsSunLongitudeDeltaN(prevJD-0.000005, degree, true, marsEventSearchN)) / 0.00001
		estimateJD = prevJD - longitudeDelta/longitudeSlope
		if math.Abs(estimateJD-prevJD) <= marsPhaseCoarseTolerance {
			break
		}
	}
	for {
		prevJD := estimateJD
		longitudeDelta := marsSunLongitudeDelta(prevJD, degree, true)
		longitudeSlope := (marsSunLongitudeDelta(prevJD+0.000005, degree, true) - marsSunLongitudeDelta(prevJD-0.000005, degree, true)) / 0.00001
		estimateJD = prevJD - longitudeDelta/longitudeSlope
		if math.Abs(estimateJD-prevJD) <= 0.00001 {
			break
		}
	}
	return TD2UT(estimateJD, false)
}

func LastMarsConjunction(jde float64) float64 {
	return marsConjunction(jde, 0, 0)
}

func NextMarsConjunction(jde float64) float64 {
	return marsConjunction(jde, 0, 1)
}

func LastMarsOpposition(jde float64) float64 {
	return marsConjunction(jde, 180, 0)
}

func NextMarsOpposition(jde float64) float64 {
	return marsConjunction(jde, 180, 1)
}

func NextMarsEasternQuadrature(jde float64) float64 {
	return marsConjunction(jde, 90, 1)
}

func LastMarsEasternQuadrature(jde float64) float64 {
	return marsConjunction(jde, 90, 0)
}

func NextMarsWesternQuadrature(jde float64) float64 {
	return marsConjunction(jde, 270, 1)
}

func LastMarsWesternQuadrature(jde float64) float64 {
	return marsConjunction(jde, 270, 0)
}

func marsRetrograde(jde float64, searchBeforeOpposition bool) float64 {
	//0=last 1=next
	jde = marsConjunctionFull(jde, 180, 1)
	if searchBeforeOpposition {
		jde -= 60
	} else {
		jde += 60
	}
	for {
		currentRate := marsRADerivative(jde, 1.0/86400.0)
		if math.Abs(currentRate) > 0.55 {
			jde += 2
			continue
		}
		break
	}
	estimateJD := jde
	for {
		prevJD := estimateJD
		rateValue := marsRADerivative(prevJD, 2.0/86400.0)
		rateSlope := (marsRADerivative(prevJD+15.0/86400.0, 2.0/86400.0) - marsRADerivative(prevJD-15.0/86400.0, 2.0/86400.0)) / (30.0 / 86400.0)
		estimateJD = prevJD - rateValue/rateSlope
		if math.Abs(estimateJD-prevJD) <= 30.0/86400.0 {
			break
		}
	}
	bestJD := eventZeroRefine(estimateJD, 15.0/86400.0, 0.5/86400.0, func(jd float64) float64 {
		return marsRADerivative(jd, 0.5/86400.0)
	})
	return TD2UT(bestJD, false)
}

func NextMarsRetrogradeToPrograde(jde float64) float64 {
	date := marsRetrograde(jde, false)
	if date < jde {
		oppositionJD := marsConjunctionFull(jde, 180, 1)
		return marsRetrograde(oppositionJD+10, false)
	}
	return date
}

func LastMarsRetrogradeToPrograde(jde float64) float64 {
	jde = marsConjunctionFull(jde, 180, 0) - 10
	date := marsRetrograde(jde, false)
	if date > jde {
		oppositionJD := marsConjunctionFull(jde, 180, 0)
		return marsRetrograde(oppositionJD-10, false)
	}
	return date
}

func NextMarsProgradeToRetrograde(jde float64) float64 {
	date := marsRetrograde(jde, true)
	if date < jde {
		oppositionJD := marsConjunctionFull(jde, 180, 1)
		return marsRetrograde(oppositionJD+10, true)
	}
	return date
}

func LastMarsProgradeToRetrograde(jde float64) float64 {
	jde = marsConjunctionFull(jde, 180, 0) - 10
	date := marsRetrograde(jde, true)
	if date > jde {
		oppositionJD := marsConjunctionFull(jde, 180, 0)
		return marsRetrograde(oppositionJD-10, true)
	}
	return date
}
feat: 扩展天文计算能力 - 新增日食、月食、本地可见性、中心线、半影区域、SVG 图示与沙罗周期信息 - 新增行星冲合、留、方照、物理星历、视直径、相位、亮肢角、轨道节点等计算 - 新增木星伽利略卫星位置、现象与接触事件计算 - 新增恒星星表、星座判定、自行修正与观测辅助能力 - 新增 coord、formula、orbit、sundial、lite/sun、lite/moon 等扩展包 - 完善农历年号、月相英文别名、视差角、大气质量、折射、日晷与双星计算 - 增加 NASA、JPL Horizons、IMCCE 等回归测试数据与基线测试 - 重构基础算法文件组织，补充大量公开 API 注释和语义回归测试 - 更新中文和英文 README，补充示例、精度说明、SVG 配图 2026-05-01 22:38:44 +08:00			`package basic`

			`import (`
			`"math"`

			`. "b612.me/astro/tools"`
			`)`

			`// Pos`

			`const (`
			`MARS_S_PERIOD = 1 / ((1 / 365.256363004) - (1 / 686.98))`
			`marsEventSearchN = 16`
			`marsPhaseCoarseTolerance = 30.0 / 86400.0`
			`)`

			`func marsSunLongitudeDelta(jde, degree float64, filter bool) float64 {`
			`sub := Limit360(Limit360(MarsApparentLo(jde)-HSunApparentLo(jde)) - degree)`
			`if filter {`
			`if sub > 180 {`
			`sub -= 360`
			`}`
			`if sub < -180 {`
			`sub += 360`
			`}`
			`}`
			`return sub`
			`}`

			`func marsSunLongitudeDeltaN(jde, degree float64, filter bool, n int) float64 {`
			`sub := Limit360(Limit360(MarsApparentLoN(jde, n)-HSunApparentLoN(jde, n)) - degree)`
			`if filter {`
			`if sub > 180 {`
			`sub -= 360`
			`}`
			`if sub < -180 {`
			`sub += 360`
			`}`
			`}`
			`return sub`
			`}`

			`func marsRADerivative(jde, val float64) float64 {`
			`sub := MarsApparentRa(jde+val) - MarsApparentRa(jde-val)`
			`if sub > 180 {`
			`sub -= 360`
			`}`
			`if sub < -180 {`
			`sub += 360`
			`}`
			`return sub / (2 * val)`
			`}`

			`func marsRADerivativeN(jde, val float64, n int) float64 {`
			`sub := MarsApparentRaN(jde+val, n) - MarsApparentRaN(jde-val, n)`
			`if sub > 180 {`
			`sub -= 360`
			`}`
			`if sub < -180 {`
			`sub += 360`
			`}`
			`return sub / (2 * val)`
			`}`

			`func marsConjunctionFull(jde, degree float64, next uint8) float64 {`
			`//0=last 1=next`
			`daysPerDegree := MARS_S_PERIOD / 360`
			`currentDelta := marsSunLongitudeDelta(jde, degree, false)`
			`if next == 0 {`
			`jde -= (360 - currentDelta) * daysPerDegree`
			`} else {`
			`jde += daysPerDegree * currentDelta`
			`}`
			`estimateJD := jde`
			`for {`
			`prevJD := estimateJD`
			`longitudeDelta := marsSunLongitudeDelta(prevJD, degree, true)`
			`longitudeSlope := (marsSunLongitudeDelta(prevJD+0.000005, degree, true) - marsSunLongitudeDelta(prevJD-0.000005, degree, true)) / 0.00001`
			`estimateJD = prevJD - longitudeDelta/longitudeSlope`
			`if math.Abs(estimateJD-prevJD) <= 0.00001 {`
			`break`
			`}`
			`}`
			`return TD2UT(estimateJD, false)`
			`}`

			`func marsConjunction(jde, degree float64, next uint8) float64 {`
			`//0=last 1=next`
			`daysPerDegree := MARS_S_PERIOD / 360`
			`currentDelta := marsSunLongitudeDelta(jde, degree, false)`
			`if next == 0 {`
			`jde -= (360 - currentDelta) * daysPerDegree`
			`} else {`
			`jde += daysPerDegree * currentDelta`
			`}`
			`estimateJD := jde`
			`for {`
			`prevJD := estimateJD`
			`longitudeDelta := marsSunLongitudeDeltaN(prevJD, degree, true, marsEventSearchN)`
			`longitudeSlope := (marsSunLongitudeDeltaN(prevJD+0.000005, degree, true, marsEventSearchN) - marsSunLongitudeDeltaN(prevJD-0.000005, degree, true, marsEventSearchN)) / 0.00001`
			`estimateJD = prevJD - longitudeDelta/longitudeSlope`
			`if math.Abs(estimateJD-prevJD) <= marsPhaseCoarseTolerance {`
			`break`
			`}`
			`}`
			`for {`
			`prevJD := estimateJD`
			`longitudeDelta := marsSunLongitudeDelta(prevJD, degree, true)`
			`longitudeSlope := (marsSunLongitudeDelta(prevJD+0.000005, degree, true) - marsSunLongitudeDelta(prevJD-0.000005, degree, true)) / 0.00001`
			`estimateJD = prevJD - longitudeDelta/longitudeSlope`
			`if math.Abs(estimateJD-prevJD) <= 0.00001 {`
			`break`
			`}`
			`}`
			`return TD2UT(estimateJD, false)`
			`}`

			`func LastMarsConjunction(jde float64) float64 {`
			`return marsConjunction(jde, 0, 0)`
			`}`

			`func NextMarsConjunction(jde float64) float64 {`
			`return marsConjunction(jde, 0, 1)`
			`}`

			`func LastMarsOpposition(jde float64) float64 {`
			`return marsConjunction(jde, 180, 0)`
			`}`

			`func NextMarsOpposition(jde float64) float64 {`
			`return marsConjunction(jde, 180, 1)`
			`}`

			`func NextMarsEasternQuadrature(jde float64) float64 {`
			`return marsConjunction(jde, 90, 1)`
			`}`

			`func LastMarsEasternQuadrature(jde float64) float64 {`
			`return marsConjunction(jde, 90, 0)`
			`}`

			`func NextMarsWesternQuadrature(jde float64) float64 {`
			`return marsConjunction(jde, 270, 1)`
			`}`

			`func LastMarsWesternQuadrature(jde float64) float64 {`
			`return marsConjunction(jde, 270, 0)`
			`}`

			`func marsRetrograde(jde float64, searchBeforeOpposition bool) float64 {`
			`//0=last 1=next`
			`jde = marsConjunctionFull(jde, 180, 1)`
			`if searchBeforeOpposition {`
			`jde -= 60`
			`} else {`
			`jde += 60`
			`}`
			`for {`
			`currentRate := marsRADerivative(jde, 1.0/86400.0)`
			`if math.Abs(currentRate) > 0.55 {`
			`jde += 2`
			`continue`
			`}`
			`break`
			`}`
			`estimateJD := jde`
			`for {`
			`prevJD := estimateJD`
			`rateValue := marsRADerivative(prevJD, 2.0/86400.0)`
			`rateSlope := (marsRADerivative(prevJD+15.0/86400.0, 2.0/86400.0) - marsRADerivative(prevJD-15.0/86400.0, 2.0/86400.0)) / (30.0 / 86400.0)`
			`estimateJD = prevJD - rateValue/rateSlope`
			`if math.Abs(estimateJD-prevJD) <= 30.0/86400.0 {`
			`break`
			`}`
			`}`
			`bestJD := eventZeroRefine(estimateJD, 15.0/86400.0, 0.5/86400.0, func(jd float64) float64 {`
			`return marsRADerivative(jd, 0.5/86400.0)`
			`})`
			`return TD2UT(bestJD, false)`
			`}`

			`func NextMarsRetrogradeToPrograde(jde float64) float64 {`
			`date := marsRetrograde(jde, false)`
			`if date < jde {`
			`oppositionJD := marsConjunctionFull(jde, 180, 1)`
			`return marsRetrograde(oppositionJD+10, false)`
			`}`
			`return date`
			`}`

			`func LastMarsRetrogradeToPrograde(jde float64) float64 {`
			`jde = marsConjunctionFull(jde, 180, 0) - 10`
			`date := marsRetrograde(jde, false)`
			`if date > jde {`
			`oppositionJD := marsConjunctionFull(jde, 180, 0)`
			`return marsRetrograde(oppositionJD-10, false)`
			`}`
			`return date`
			`}`

			`func NextMarsProgradeToRetrograde(jde float64) float64 {`
			`date := marsRetrograde(jde, true)`
			`if date < jde {`
			`oppositionJD := marsConjunctionFull(jde, 180, 1)`
			`return marsRetrograde(oppositionJD+10, true)`
			`}`
			`return date`
			`}`

			`func LastMarsProgradeToRetrograde(jde float64) float64 {`
			`jde = marsConjunctionFull(jde, 180, 0) - 10`
			`date := marsRetrograde(jde, true)`
			`if date > jde {`
			`oppositionJD := marsConjunctionFull(jde, 180, 0)`
			`return marsRetrograde(oppositionJD-10, true)`
			`}`
			`return date`
			`}`