基于EEMD的太阳绕太阳系质心运动和太阳活动Hallstatt周期分析

doi:10.12118/j.issn.1000–6060.2021.01.23

干旱区地理 ›› 2021, Vol. 44 ›› Issue (1): 221-228.doi: 10.12118/j.issn.1000–6060.2021.01.23

基于EEMD的太阳绕太阳系质心运动和太阳活动Hallstatt周期分析

王琳琳¹(),王建^1,²,孙威^3,⁴,王婕¹()

1.南京师范大学地理科学学院,江苏南京 210023
2.江苏第二师范学院城市与资源环境学院,江苏南京 211200
3.上海工程技术大学数理与统计学院,上海 201620
4.安庆师范大学资源环境学院,安徽安庆 246133

收稿日期:2019-12-04 修回日期:2020-08-19 出版日期:2021-01-25 发布日期:2021-03-09
通讯作者: 王建
作者简介:王琳琳（1995-）,女,博士研究生,主要从事行星系统与太阳运动、气候变化方面的研究工作. E-mail: wanglinlin1224@163.com
基金资助:
国家自然科学基金项目(41807437);安徽省自然科学基金项目(1808085QD99);安徽省自然科学基金项目(KJ2017A371)

Hallstatt cycle of solar inertial motion and solar activity based on ensemble empirical mode decomposition

WANG Linlin¹(),WANG Jian^1,²,SUN Wei^3,⁴,WANG Jie¹()

1. School of Geography, Nanjing Normal University, Nanjing 210023, Jiangsu, China
2. School of Urban & Resources and Environment, Jiangsu Second Normal University, Nanjing 211200, Jiangsu, China
3. School of Mathematic, Physics and Statistics, Shanghai University of Engineering Science, Shanghai 201620, China
4. School of Resources and Environment, Anqing Normal University, Anqing 246133, Anhui, China

Received:2019-12-04 Revised:2020-08-19 Online:2021-01-25 Published:2021-03-09
Contact: Jian WANG

摘要/Abstract

摘要：

基于行星会合指数运动学方程,推演出太阳质心到太阳系质心距离变化的计算公式,并利用该公式重建太阳质心相对于太阳系质心的距离变化时间序列,作为太阳轨道运动的替代性指标,使用聚合经验模态分解（Ensemble empirical mode decomposition,EEMD）方法分析0~25.0 ka BP太阳质心到太阳系质心的距离与Δ¹⁴C时间序列。结果显示：两者均存在蕴含~2300 a 周期（Hallstatt cycle）的IMF分量;互相关分析证实两者蕴含的Hallstatt周期分量间具有相关性,0~13.9 ka BP与13.9~25.0 ka BP年代相关系数分别可达0.52、0.44,并且太阳质心到太阳系质心距离的变化超前于太阳活动指标Δ¹⁴C的变化。表明太阳质心远离太阳系质心时,大气¹⁴C含量增加,对应于太阳活动较弱的时期;太阳质心靠近太阳系质心时,大气¹⁴C含量减小,对应于太阳活动较强的时期。这一认识对于进一步探究太阳活动Hallstatt周期的成因机制提供了新的依据和思路。

关键词: 太阳系质心, 太阳活动, Hallstatt周期, 聚合经验模态分解（EEMD）

Abstract:

Solar activity, evidenced by ¹⁴C proxies, shows a period of ~2300 years (Hallstatt cycle). Its physical origin remains uncertain. Recent studies suggested that ~2300-year Hallstatt oscillations of solar activity may be caused by the solar inertial motion (the Sun motion around the center of mass of the solar system). In this study, a formula for calculating the distance between the solar centroid and the solar system’s centroid is deduced based on the kinematic equation of the planet juncture index. In the appropriate proxy of solar inertial motion, the time series of distance change is reconstructed using this formula. Ensemble empirical mode decomposition (EEMD) is a method with which any complicated signal can be decomposed into several intrinsic mode functions (IMFs). This decomposition method is adaptive and highly efficient. It applies to nonlinear and non-stationary processes since the decomposition is based on the local characteristic time scale of the data. To compare the radiocarbon series of INTCAL13 data with the variations of the distance between the solar centroid and the solar system’s centroid from 0 to 25.0 ka BP, we employ the empirical mode decomposition method. The analysis results are as follows: (1) Various components have been identified by decomposing the distance signal, including a significant component with a period of ~2300 years. (2) Following the analysis of the time series of distance change, there is also a component with ~2300-year Hallstatt cycle in the data on the production rate of radiocarbon. The traditional method of Δ¹⁴C record preprocessing, applying a pre-selected detrending function, amounts to injecting external information into data. Different from the traditional method the true and more physical meaningful component with the Hallstatt cycle is decomposed by the adaptive EEMD method. (3) Next, the ~2300-year variations of the two series considered are compared. The last 13900 years data in INTCAL13 record derive mostly from tree-ring chronologies, while the older data is made using mostly marine records. Thus, cross-correlation analysis is applied to the above two time-frames of the components with the Hallstatt cycle decomposed from the time series of the distance and Δ ¹⁴C. The cross-correlation coefficient is 0.52 from 0 to 13.9 ka BP, and 0.44 from 13.9 to 25.0 ka BP. The values confirm the assumption that the variations of the distance between the solar centroid and the solar system’s centroid and the production rate of radiocarbon are related. As discussed above, the study of the relationship between solar inertial motion and solar activity covers the Holocene and extends to 25.0 ka BP. (4) It appears that solar inertial motion is the cause of the Hallstatt cycle found in solar activity proxy. The¹⁴C concentration of the atmosphere increases when the solar centroid moves away from the solar system’s centroid, which corresponds to the period of weak solar activity. When the solar centroid is near the solar system’s centroid, the¹⁴C concentration decreases which corresponds to the period of strong solar activity.

Key words: solar inertial motion, solar activity, Hallstatt cycle, ensemble empirical mode decomposition (EEMD)

王琳琳,王建,孙威,王婕. 基于EEMD的太阳绕太阳系质心运动和太阳活动Hallstatt周期分析[J]. 干旱区地理, 2021, 44(1): 221-228.

WANG Linlin,WANG Jian,SUN Wei,WANG Jie. Hallstatt cycle of solar inertial motion and solar activity based on ensemble empirical mode decomposition[J]. Arid Land Geography, 2021, 44(1): 221-228.

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名称	与不变平面倾角/°	平均角速度/rad·a^-1	平均轨道半径/AU	质量/10²⁴kg	质量权重半径/AU	日心经度/°	转换成弧度/rad
水星	6.35	26.088408	0.38709893	0.33	0.000048	252.25084	4.402608
金星	2.15	10.213444	0.72333199	4.87	0.001321	181.97973	3.176145
地球	1.57	6.283185	1.00000011	5.97	0.002238	100.46435	1.753434
火星	1.63	3.340667	1.52366231	0.64	0.000366	355.45332	6.203831
木星	0.32	0.529700	5.20336301	1898.19	3.702624	34.40438	0.600470
土星	0.93	0.213303	9.53707032	568.34	2.031931	49.94432	0.871693
天王星	0.99	0.074790	19.19126393	86.81	0.624538	313.23218	5.466933
海王星	0.74	0.038129	30.06896348	102.41	1.154374	304.88003	5.321160

模态分量	质心距离准周期/a	Δ¹⁴C准周期/a
IMF1	3.9~12.8	22.6~41.0
IMF2	12.8	74.0
IMF3	19.8	130.0~208.0
IMF4	35.3~45.4	357.0
IMF5	60.9~92.6	446.0~961.0
IMF6	171.0~185.0	926.0~2084.0
IMF7	568.0	2456.0
IMF8	735.0~1191.0	6253.0
IMF9	1136.0	25000.0
IMF10	2273.0	25000.0
IMF11	6250.0	-
IMF12	12500.0	-
IMF13	25000.0	-

基于EEMD的太阳绕太阳系质心运动和太阳活动Hallstatt周期分析

Hallstatt cycle of solar inertial motion and solar activity based on ensemble empirical mode decomposition

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