国债远期利率的量子场理论模型构建

雷丽梅; 冯玲

doi:10.7498/aps.67.20180424

摘要

随着我国利率市场化改革的全面推进和利率衍生品数量的增加，如何对远期利率进行精确与合理建模，就显得十分重要和紧迫.本文利用金融物理学中可有效纳入日历时间和到期时间两个维度上的国债远期利率之间不完全相关性的量子场论方法，对2011年1月4日到2016年12月30日的国债瞬时远期利率的实际市场演化进行建模，并将其结果与传统金融只能考虑日历时间方向上的相关性的主流两因子Heath-Jarrow-Morton（HJM）模型的实证结果进行比较.研究结果表明，考虑心理感知剩余时间变量后的量子场理论模型，提供了对实际的国债远期利率的92.67%的拟合优度，优于经典的最优两因子HJM模型69.02%的拟合精度.此外，分别将估计所得的最优参数代入最优量子场理论模型和两因子HJM模型下的远期利率更新方程，对2017年1月3日到2017年12月30日的100个期限的瞬时远期利率的250个瞬时远期利率的期限结构进行回测检验，从平均瞬时远期利率、均方根误差和Theil不等系数三个方面的结果均显示出量子场理论模型对国债远期利率建模的优越性.这些结果对将量子场理论引入到以国债为标的各种金融产品的定价和相关的利率风险管理、银行和金融公司的量化分析以及固定收益证券领域的实践者们均具有重要意义.

关键词:

Abstract

With the further reform of interest rate liberalization and the increasing of interest rate derivatives, it becomes more important and urgent to model the forward rate accurately and rationally in China. In this paper, we use the quantum field theory in econophysics, which can effectively incorporate the incomplete correlations between forward interest rates with different maturities, to model the Chinese treasury bond instantaneous forward rates. Firstly, we start with the correlation structure of the instantaneous change of treasury forward rates, one of the most important variables for a quantum field, during the period from January 4, 2011 to December 30, 2016, then apply the quantum field theory to model the actual market evolution of the treasury instantaneous forward rates directly. Secondly, we also use the mainstream two-factor Heath-Jarrow-Morton (HJM) model commonly used in financial industry, which requires the particular form of forward rate volatility functions to be set in advance, to model the treasury instantaneous forward rates, then compare the results with those of the quantum field model. The empirical results show that the quantum field model based on stiff action provides a fitting accuracy of 63.23% for actual treasury bond instantaneous forward rate, but this fitting accuracy increases to 92.67% for the quantum field model with taking into account the psychological perceptive remaining time, which is also superior to the classic optimal two-factor HJM model with a fitting accuracy of 69.02%. Finally, the optimal parameters estimated are respectively substituted into the forward interest rate update equations of the quantum field model with the psychological perception time in mind and the classical two-factor HJM model to conduct the back testing of forward rates with one hundred maturities, from January 3, 2017 to December 30, 2017. From the results of average instantaneous forward rate, root mean square error and Theil inequality coefficient, we can see the superiority of using the quantum field theory to model the term structure of treasury forward rates compared with traditionally used two-factor HJM model in financial industry. In conclusion, the quantum field model we constructed, is more consistent with the actual situation, and all the parameters estimated by this model are obtained directly from the market data, without making any assumption of the specific form of forward rate volatility function, thus greatly improving the accuracy of applying the quantum field theory to finance. These findings are not only of great theoretic and practical significance for applying the quantum field theory to pricing those financial products linked to treasury bonds and for managing its relevant interest rate risk, but also have reference value for quantitatively analyzing banks and finance companies in financial field, and also for practitioners in the field of fixed-income securities.

Keywords:

作者及机构信息

雷丽梅,
冯玲

1.
福州大学经济与管理学院, 福州 350002

通信作者: 冯玲, 332714502@qq.com

基金项目: 国家自然科学基金（批准号：71573043）资助的课题.

Authors and contacts

1.
School of Economics and Management, Fuzhou University, Fuzhou 350002, China

Corresponding author: Feng Ling, 332714502@qq.com

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 71573043).

参考文献

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[2]	Henrard M 2010 Wilm. J. 2 135
[3]	Beliaeva N, Nawalkha S 2012 J. Bank Financ. 36 151
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[7]	Montagna G, Nicrosini O, Moreni N 2002 Physica A 310 450
[8]	Contreras M, Montalva R, Pellicer R, Villena M 2010 Physica A 389 3552
[9]	Kim M J, Hwang D I, Lee S Y, Kim S Y 2011 Physica A 390 847
[10]	Wu T L, Xu S Q 2014 J. Futur. Mark. 34 580
[11]	Fan H 2014 Acta Phys. Sin. 63 038902 (in Chinese) [范宏 2014 物理学报 63 038902]
[12]	Zhou R W, Li J C, Dong Z W, Li Y X, Qian Z W 2017 Acta Phys. Sin. 66 040501 (in Chinese) [周若微, 李江城, 董志伟, 李云仙, 钱振伟 2017 物理学报 66 040501]
[13]	Tang Z P, Chen W H, Ran M 2017 Acta Phys. Sin. 66 120203 (in Chinese) [唐振鹏, 陈尾虹, 冉梦 2017 物理学报 66 120203]
[14]	Tarasov V E, Tarasova V V 2017 Ann. Phys. 383 579
[15]	Henkel C 2017 Physica A 469 447
[16]	Ma C, Ma Q H, Yao H X, Hou T C 2018 Physica A 494 87
[17]	Baaquie B E 2001 Phys. Rev. E 64 016121
[18]	Baaquie B E 2002 Phys. Rev. E 65 056122
[19]	Baaquie B E 2004 Quantum Finance (Singapore:Cambridge University Press) p147
[20]	Baaquie B E 2009 Interest Rates and Coupon Bonds in Quantum Finance (UK:Cambridge University Press) p91
[21]	Baaquie B E, Pan T 2012 Physica A 391 1287
[22]	Baaquie B E, Du X, Tang P, Cao Y 2014 Physica A 401 182
[23]	Baaquie B E, Yu M, Bhanap J 2018 Physica A 492 222
[24]	Heath D, Jarrow R, Morton A 1992 Econometrica 60 77
[25]	Kennedy D P 1994 Math. Financ. 4 247
[26]	Kennedy D P 1997 Math. Financ. 7 107
[27]	Goldstein P 2000 J. Financ. Stud. 13 365
[28]	Santa-Clara P, Sornette D 2001 Rev. Financ. Stud. 14 149
[29]	Kim M L, Hwang D I, Lee S Y, Kim S Y 2011 Physica A 390 847
[30]	Amin K I, Morton A J 1994 J. Financ. Econ. 35 141

施引文献

[1]	Andersen L, Andreasen J 2000 Appl. Math. Financ. 7 1
[2]	Henrard M 2010 Wilm. J. 2 135
[3]	Beliaeva N, Nawalkha S 2012 J. Bank Financ. 36 151
[4]	Chen Z Y, Jiang L 2016 J. Syst. Eng. 31 202 (in Chinese) [陈志勇, 江良 2016 系统工程学报 31 202]
[5]	Ma J H, Sun B 2017 Syst. Eng.： Theory Pract. 37 288 (in Chinese) [马俊海, 孙斌 2017 系统工程理论与实践 37 288]
[6]	Haven E E 2002 Physica A 304 507
[7]	Montagna G, Nicrosini O, Moreni N 2002 Physica A 310 450
[8]	Contreras M, Montalva R, Pellicer R, Villena M 2010 Physica A 389 3552
[9]	Kim M J, Hwang D I, Lee S Y, Kim S Y 2011 Physica A 390 847
[10]	Wu T L, Xu S Q 2014 J. Futur. Mark. 34 580
[11]	Fan H 2014 Acta Phys. Sin. 63 038902 (in Chinese) [范宏 2014 物理学报 63 038902]
[12]	Zhou R W, Li J C, Dong Z W, Li Y X, Qian Z W 2017 Acta Phys. Sin. 66 040501 (in Chinese) [周若微, 李江城, 董志伟, 李云仙, 钱振伟 2017 物理学报 66 040501]
[13]	Tang Z P, Chen W H, Ran M 2017 Acta Phys. Sin. 66 120203 (in Chinese) [唐振鹏, 陈尾虹, 冉梦 2017 物理学报 66 120203]
[14]	Tarasov V E, Tarasova V V 2017 Ann. Phys. 383 579
[15]	Henkel C 2017 Physica A 469 447
[16]	Ma C, Ma Q H, Yao H X, Hou T C 2018 Physica A 494 87
[17]	Baaquie B E 2001 Phys. Rev. E 64 016121
[18]	Baaquie B E 2002 Phys. Rev. E 65 056122
[19]	Baaquie B E 2004 Quantum Finance (Singapore:Cambridge University Press) p147
[20]	Baaquie B E 2009 Interest Rates and Coupon Bonds in Quantum Finance (UK:Cambridge University Press) p91
[21]	Baaquie B E, Pan T 2012 Physica A 391 1287
[22]	Baaquie B E, Du X, Tang P, Cao Y 2014 Physica A 401 182
[23]	Baaquie B E, Yu M, Bhanap J 2018 Physica A 492 222
[24]	Heath D, Jarrow R, Morton A 1992 Econometrica 60 77
[25]	Kennedy D P 1994 Math. Financ. 4 247
[26]	Kennedy D P 1997 Math. Financ. 7 107
[27]	Goldstein P 2000 J. Financ. Stud. 13 365
[28]	Santa-Clara P, Sornette D 2001 Rev. Financ. Stud. 14 149
[29]	Kim M L, Hwang D I, Lee S Y, Kim S Y 2011 Physica A 390 847
[30]	Amin K I, Morton A J 1994 J. Financ. Econ. 35 141

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