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| The SPECTRA Procedure |
Example 25.1 Spectral Analysis of Sunspot Activity
This example analyzes Wolfer’s sunspot data (Anderson 1971). The following statements read and plot the data.
title "Wolfer's Sunspot Data"; data sunspot; input year wolfer @@; datalines; ... more lines ...
proc sgplot data=sunspot; series x=year y=wolfer / markers markerattrs=(symbol=circlefilled); xaxis values=(1740 to 1930 by 10); yaxis values=(0 to 1600 by 200); run;
The plot of the sunspot series is shown in Output 25.1.1.
The spectral analysis of the sunspot series is performed by the following statements:
proc spectra data=sunspot out=b p s adjmean whitetest; var wolfer; weights 1 2 3 4 3 2 1; run;
proc print data=b(obs=12); run;
The PROC SPECTRA statement specifies the P and S options to write the periodogram and spectral density estimates to the OUT= data set B. The WEIGHTS statement specifies a triangular spectral window for smoothing the periodogram to produce the spectral density estimate. The ADJMEAN option zeros the frequency 0 value and avoids the need to exclude that observation from the plots. The WHITETEST option prints tests for white noise.
The Fisher’s Kappa test statistic of 16.070 is larger than the 5% critical value of 7.2, so the null hypothesis that the sunspot series is white noise is rejected (see the table of critical values in Fuller (1976)).
The Bartlett’s Kolmogorov-Smirnov statistic is 0.6501, and its approximate p-value is 
. The small p-value associated with this test leads to the rejection of the null hypothesis that the spectrum represents white noise.
The printed output produced by PROC SPECTRA is shown in Output 25.1.2. The output data set B created by PROC SPECTRA is shown in part in Output 25.1.3.
| Test for White Noise for Variable wolfer |
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|---|---|
| M-1 | 87 |
| Max(P(*)) | 4062267 |
| Sum(P(*)) | 21156512 |
| Wolfer's Sunspot Data |
| Obs | FREQ | PERIOD | P_01 | S_01 |
|---|---|---|---|---|
| 1 | 0.00000 | . | 0.00 | 59327.52 |
| 2 | 0.03570 | 176.000 | 3178.15 | 61757.98 |
| 3 | 0.07140 | 88.000 | 2435433.22 | 69528.68 |
| 4 | 0.10710 | 58.667 | 1077495.76 | 66087.57 |
| 5 | 0.14280 | 44.000 | 491850.36 | 53352.02 |
| 6 | 0.17850 | 35.200 | 2581.12 | 36678.14 |
| 7 | 0.21420 | 29.333 | 181163.15 | 20604.52 |
| 8 | 0.24990 | 25.143 | 283057.60 | 15132.81 |
| 9 | 0.28560 | 22.000 | 188672.97 | 13265.89 |
| 10 | 0.32130 | 19.556 | 122673.94 | 14953.32 |
| 11 | 0.35700 | 17.600 | 58532.93 | 16402.84 |
| 12 | 0.39270 | 16.000 | 213405.16 | 18562.13 |
The following statements plot the periodogram and spectral density estimate by the frequency and period.
proc sgplot data=b; series x=freq y=p_01 / markers markerattrs=(symbol=circlefilled); run;
proc sgplot data=b; series x=period y=p_01 / markers markerattrs=(symbol=circlefilled); run;
proc sgplot data=b; series x=freq y=s_01 / markers markerattrs=(symbol=circlefilled); run;
proc sgplot data=b; series x=period y=s_01 / markers markerattrs=(symbol=circlefilled); run;
The periodogram is plotted against the frequency in Output 25.1.4 and plotted against the period in Output 25.1.5. The spectral density estimate is plotted against the frequency in Output 25.1.6 and plotted against the period in Output 25.1.7.
Since PERIOD is the reciprocal of frequency, the plot axis for PERIOD is stretched for low frequencies and compressed at high frequencies. One way to correct for this is to use a WHERE statement to restrict the plots and exclude the low frequency components. The following statements plot the spectral density for periods less than 50.
proc sgplot data=b; where period < 50; series x=period y=s_01 / markers markerattrs=(symbol=circlefilled); refline 11 / axis=x; run; title;
The spectral analysis of the sunspot series confirms a strong 11-year cycle of sunspot activity. The plot makes this clear by drawing a reference line at the 11 year period, which highlights the position of the main peak in the spectral density.
Output 25.1.8 shows the plot. Contrast Output 25.1.8 with Output 25.1.7.
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