Testing for serial correlation in least squares regression. II.

A great deal of use has undoubtedly been made of least squares regression methods in circumstances in which they are known to be inapplicable. In particular, they have often been employed for the analysis of time series and similar data in which successive observations are serially correlated. The resulting complications are well known and have recently been studied from the standpoint of the econometrician by Cochrane & Orcutt (1949). A basic assumption underlying the application of the least squares method is that the error terms in the regression model are independent. When this assumption—among others—is satisfied the procedure is valid whether or not the observations themselves are serially correlated. The problem of testing the errors for independence forms the subject of this paper and its successor. The present paper deals mainly with the theory on which the test is based, while the second paper describes the test procedures in detail and gives tables of bounds to the significance points of the test criterion adopted. We shall not be concerned in either paper with the question of what should be done if the test gives an unfavourable result.

[1]  R. Courant,et al.  Methoden der mathematischen Physik , .

[2]  R. Courant,et al.  Methoden der Mathematischen Physik: Erster Band , 1931 .

[3]  M. S. Bartlett,et al.  The vector representation of a sample , 1934, Mathematical Proceedings of the Cambridge Philosophical Society.

[4]  A. C. Aitken IV.—On Least Squares and Linear Combination of Observations , 1936 .

[5]  E. J. G. Pitman,et al.  The “closest” estimates of statistical parameters , 1937, Mathematical Proceedings of the Cambridge Philosophical Society.

[6]  W. G. Cochran The Omission or Addition of an Independent Variate in Multiple Linear Regression , 1938 .

[7]  The Theory and Measurement of Demand , 1939 .

[8]  H. O. Hartley,et al.  Tables of Percentage Points of the Incomplete Beta-Function , 1941 .

[9]  J. Neumann Distribution of the Ratio of the Mean Square Successive Difference to the Variance , 1941 .

[10]  R. Anderson Distribution of the Serial Correlation Coefficient , 1942 .

[11]  R. Anderson,et al.  Tables of orthogonal polynomial values extended to N=104 , 1942 .

[12]  Tjalling C. Koopmans,et al.  Serial Correlation and Quadratic Forms in Normal Variables , 1942 .

[13]  John von Neumann,et al.  Tabulation of the Probabilities for the Ratio of the Mean Square Successive Difference to the Variance , 1942 .

[14]  Wilfrid J. Dixon,et al.  Further Contributions to the Problem of Serial Correlation , 1944 .

[15]  H. Rubin On the Distribution of the Serial Correlation Coefficient , 1945 .

[16]  Approximation to percentage points of the Z-distribution. , 1947 .

[17]  T. W. Anderson On the theory of testing serial correlation , 1948 .

[18]  A. Prest,et al.  Some Experiments in Demand Analysis , 1949 .

[19]  P. Moran,et al.  A test for the serial independence of residuals. , 1950, Biometrika.

[20]  T. W. Anderson,et al.  Distribution of the Circular Serial Correlation Coefficient for Residuals from a Fitted Fourier Series , 1950 .

[21]  Jan Tinbergen,et al.  Economic fluctuations in the United States 1921-1941 , 1951 .

[22]  The incomplete beta function as a contour integral and a quickly converging series for its inverse. , 1950 .

[23]  J. Durbin,et al.  Exact Tests of Serial Correlation using Noncircular Statistics , 1951 .

[24]  K. Pearson Tables of the incomplete beta-function , 1951 .