بررسی ایستایی و غیرخطی بودن سری‌های زمانی جریان روزانه رودخانه بر اساس آزمون‌های آماری مختلف (مطالعه موردی: رودخانه‌های حوضه بالادست سد زرینه‌رود)

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشگاه تبریز

2 پردیس فنی و مهندسی شهید عباسپور، دانشگاه شهید بهشتی

چکیده

یکی از ابزارهای مهم برای ارزیابی و مدل‌سازی فرآیندهای هیدرولوژیکی، به منظور حل مسائل مرتبط به مدیریت منابع آب، مدل‌های سری زمانی می‌باشد. فرآیند جریان رودخانه معمولاً به صورت مکانیسم غیرخطی در نظر گرفته می‌شوند، درحالی که در بسیاری از مطالعات به منظور مدل‌سازی سری‌های زمانی دبی رودخانه از مدل‌های خطی استفاده می‌شوند. در این مطالعه، سری زمانی دبی‌ روزانه 6 ایستگاه آبسنجی واقع بر رودخانه‌های حوضه بالادست سد زرینه‌رود برای دوره آماری 2011-1997، به منظور بررسی ایستایی و غیرخطی ‌بودن در نظر گرفته شده‌اند. این 15 سال داده دارای دوره زمانی مشترک (طول داده‌ها 5475 عدد) و دارای صحت و سقم کافی می‌باشند. در این مطالعه، برای بررسی ایستایی از آزمون‌های ADF و KPSS و برای بررسی غیرخطی ‌بودن از آزمون‌های BDS، Keenan و TLRT استفاده شده است. در مورد تحلیل ایستایی، نتایج نشان داد که سری زمانی دبی روزانه همه‌ ایستگاه‌ها به طور معنی‌داری ایستا هستند. بر اساس آزمون BDS، نتایج نشان داد که سری‌های روزانه ماهیت غیرخطی شدیدی دارند، اما بر اساس آزمون Keenan با لگاریتم‌گیری و غیرفصلی ‌کردن می‌توان رفتار خطی را در آنها مشاهده کرد. نتایج آزمون TLRT نیز نشان داد که داده‌ها دارای رفتار غیرخطی بوده و می‌توان مدل‌های غیرخطی خودهمبسته آستانه مناسب را بر آنها برازش داد. بنابراین، به منظور مدل‌سازی سری‌های زمانی دبی روزانه می‌توان مدل‌های خطی و غیرخطی را استفاده کرد و نتایج آنها را مورد ارزیابی قرار داد.

کلیدواژه‌ها

عنوان مقاله [English]

Testing for Stationarity and Nonlinearity of Daily Streamflow Time Series Based on Different Statistical Tests (Case Study: Upstream Basin Rivers of Zarrineh Roud Dam)

نویسندگان [English]

  • Farshad Fathian 1
  • Ahmad Fakheri Fard 1
  • Yagob Dinpashoh 1
  • Seyed Saeid Mousavi Nadoshani 2
1 University of Tabriz
2 Abbaspour School of Engineering, Shahid Beheshti University
چکیده [English]

Introduction: Time series models are one of the most important tools for investigating and modeling hydrological processes in order to solve problems related to water resources management. Many hydrological time series shows nonstationary and nonlinear behaviors. One of the important hydrological modeling tasks is determining the existence of nonstationarity and the way through which we can access the stationarity accordingly. On the other hand, streamflow processes are usually considered as nonlinear mechanisms while in many studies linear time series models are used to model streamflow time series. However, it is not clear what kind of nonlinearity is acting underlying the streamflowprocesses and how intensive it is.
Materials and Methods: Streamflow time series of 6 hydro-gauge stations located in the upstream basin rivers of ZarrinehRoud dam (located in the southern part of Urmia Lake basin) have been considered to investigate stationarity and nonlinearity. All data series used here to startfrom January 1, 1997, and end on December 31, 2011. In this study, stationarity is tested by ADF and KPSS tests and nonlinearity is tested by BDS, Keenan and TLRT tests. The stationarity test is carried out with two methods. Thefirst one method is the augmented Dickey-Fuller (ADF) unit root test first proposed by Dickey and Fuller (1979) and modified by Said and Dickey (1984), which examinsthe presence of unit roots in time series.The second onemethod is KPSS test, proposed by Kwiatkowski et al. (1992), which examinesthestationarity around a deterministic trend (trend stationarity) and the stationarity around a fixed level (level stationarity). The BDS test (Brock et al., 1996) is a nonparametric method for testing the serial independence and nonlinear structure in time series based on the correlation integral of the series. The null hypothesis is the time series sample comes from an independent identically distributed (i.i.d.) process. The alternative hypothesis arenot specified. Keenan test has also been proposed for assessing the linearity or nonlinearitybehavior of a time series in time series analysis. Keenan (1985) derived a test for nonlinearity analogous to Tukey’s degree of freedom for nonadditivity test. Keenan’s test is motivated by approximation a nonlinear stationary time series by a second-order Volterra expansion. While Keenan’s test for nonlinearity is designed for detecting quadratic nonlinearity, it may not be sensitive to threshold nonlinearity. Here, we applied the likelihood ratio test (TLRT) with the threshold model as the specific alternative.The null hypothesis of the TLRT approach for threshold nonlinearity is the fitted model to the series is an AR (p) model, and the alternative hypothesis is the fitted model to the series is a threshold autoregressive (TAR) model with autoregressive order p in each regime.
Results and Discussion: Because both the ADF and KPSS tests are based on linear regression, which has the normal distribution assumption, logarithmization can convert exponential trend possibly present in the data into a linear trend. In the case of stationary analysis, the results showed the standardized daily streamflow time series of all stations are significantly stationary. According to KPSS stationary test, the daily standardized streamflow time series are stationary around a fixed level, but they are not stationary around a trend stationaryin low lag values. Based on the BDS test, the results showed the daily streamflowseries have strong nonlinear structure, but based on the Keenan test, it can be seen the linear structure in thembyusing logarithmization and deseasonalization operators, and it means the coefficients of the double sum part are zero. It should be considered the Keenan test is used to detect quadratic nonlinearity, and it cannot be adequatelyfor threshold autoregressive models since they are linear in each regime.
Conclusion: Streamflow processes of main rivers at 6 stations located in the southern partof Urmia Lake basin were investigated for testingthenonstationarity and nonlinearity behaviors. In general, streamflowprocesses have been considered as nonlinear behaviors. But, the type and intensity of nonlinearity have not been detected at different time scale due to the existence of several evaluation tests. In this study, all daily streamflow series appear to be significantly stationary and have the nonlinearity behavior. Therefore, to model the daily streamflow time series, linear and nonlinear models can be used and their results can be evaluated.

کلیدواژه‌ها [English]

  • Hydrological processes
  • Nonlinearity tests
  • Stationary tests
  • Time series modeling
  • Urmia Lake

مراجع

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آب و خاک
دوره 30، شماره 4 - شماره پیاپی 48
مهر و آبان 1395
صفحه 1009-1024

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  • تاریخ دریافت: 14 بهمن 1393
  • تاریخ پذیرش: 14 بهمن 1393
  • تاریخ اولین انتشار: 01 آبان 1395

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