Comparar métodos
Revisa los métodos seleccionados uno junto a otro; las filas que difieren aparecen resaltadas.
| Coherencia Ondicular× | Transformada de Onda Cruzada× | |
|---|---|---|
| Campo | Series temporales | Series temporales |
| Familia | Process / pipeline | Process / pipeline |
| Año de origen≠ | 1999 | 1998 |
| Autor original | Christopher Torrence | Christopher Torrence |
| Tipo≠ | Multi-scale correlation and phase | Bivariate wavelet interaction |
| Fuente seminal≠ | Torrence, C., & Webster, P. J. (1999). Interdecadal changes in the ENSO–monsoon system. Journal of Climate, 12(8), 2679–2690. DOI ↗ | Torrence, C., & Compo, G. P. (1998). A practical guide to wavelet analysis. Bulletin of the American Meteorological Society, 79(1), 61–78. DOI ↗ |
| Alias≠ | WTC, Wavelet coherency, Continuous wavelet coherence | XWT, Cross-spectrum wavelet |
| Relacionados | 1 | 1 |
| Resumen≠ | Wavelet coherence (WTC) is a normalized measure of correlation between two time series in the time-frequency domain, eliminating the amplitude-dependence of the raw cross-wavelet transform. Introduced by Torrence and Webster (1999) and formalized by Grinsted, Moore, and Jevrejeva (2004), WTC quantifies how tightly two signals are coupled at each time-frequency point, independent of their individual power levels. It is the wavelet analog of classical spectral coherence, revealing time-localized relationships across all frequencies. | The cross-wavelet transform (XWT) is a bivariate extension of the continuous wavelet transform that measures the joint time-frequency representation of two signals. Introduced by Torrence and Compo (1998) and applied extensively by Grinsted, Moore, and Jevrejeva (2004) to geophysical data, XWT reveals where two signals share common spectral power and the phase relationship between them at each time-frequency point. This is the natural generalization of classical cross-spectral analysis to the time-varying domain. |
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