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| "value": "name:Estimation of Foliar Carotenoid Content Using | | "value": "name:Estimation of Foliar Carotenoid Content Using |
| Spectroscopy Wavelet-Based Vegetation | | Spectroscopy Wavelet-Based Vegetation |
| n | Indices~~title_type::unkn~~language::unav" | n | Indices~~title_type::unkn~~language::en||name:Estimaci\u00f3n del |
| | | contenido de carotenoides foliares mediante \u00edndices de |
| | | vegetaci\u00f3n basados \u200b\u200ben ondas |
| | | espectrosc\u00f3picas~~title_type::unkn~~language::es" |
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| "name": "observacion-de-la-tierra", | | "name": "observacion-de-la-tierra", |
| "title": "Observaci\u00f3n de la Tierra" | | "title": "Observaci\u00f3n de la Tierra" |
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| "license_title": "rights:CC-BY", | | "license_title": "rights:CC-BY", |
| "maintainer": "name:Lopatin, Javier~~creator_name_type::tba", | | "maintainer": "name:Lopatin, Javier~~creator_name_type::tba", |
| "maintainer_email": "do-catalog@dataobservatory.net", | | "maintainer_email": "do-catalog@dataobservatory.net", |
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| "name": | | "name": |
| arotenoid_content_using_spectroscopy_waveletbased_vegetation_indices", | | arotenoid_content_using_spectroscopy_waveletbased_vegetation_indices", |
| "notes": "description:The plant carotenoid (Car) content plays a | | "notes": "description:The plant carotenoid (Car) content plays a |
| crucial role in the xanthophyll cycle and provides essential | | crucial role in the xanthophyll cycle and provides essential |
| information on the physiological adaptations of plants to | | information on the physiological adaptations of plants to |
| environmental stress. Spectroscopy data are essential for the | | environmental stress. Spectroscopy data are essential for the |
| nondestructive prediction of Car and other traits. However, Car | | nondestructive prediction of Car and other traits. However, Car |
| content estimation is still behind in terms of accuracy compared to | | content estimation is still behind in terms of accuracy compared to |
| other pigments, such as chlorophyll (Chl). Here, I examined the | | other pigments, such as chlorophyll (Chl). Here, I examined the |
| potential of using the continuous wavelet transform (CWT) on leaf | | potential of using the continuous wavelet transform (CWT) on leaf |
| reflectance data to create vegetation indices (VIs). I compared six | | reflectance data to create vegetation indices (VIs). I compared six |
| CWT mother families and six scales and selected the best overall | | CWT mother families and six scales and selected the best overall |
| dataset using random forest (RF) regressions. Using a brute-force | | dataset using random forest (RF) regressions. Using a brute-force |
| approach, I created wavelet-based VIs on the best mother family and | | approach, I created wavelet-based VIs on the best mother family and |
| compared them against established Car reflectance-based VIs. I found | | compared them against established Car reflectance-based VIs. I found |
| that wavelet-based indices have high linear sensitivity to the Car | | that wavelet-based indices have high linear sensitivity to the Car |
| content, contrary to typical nonlinear relationships depicted by the | | content, contrary to typical nonlinear relationships depicted by the |
| reflectance-based VIs. These relations were theoretically contrasted | | reflectance-based VIs. These relations were theoretically contrasted |
| with the synthetic data created using the PROSPECT-D radiative | | with the synthetic data created using the PROSPECT-D radiative |
| transfer model. However, the best selection of wavelength bands in | | transfer model. However, the best selection of wavelength bands in |
| wavelet-based VIs varies greatly depending on the spectral | | wavelet-based VIs varies greatly depending on the spectral |
| characteristics of the input data before the | | characteristics of the input data before the |
| t | | t | transformation.~~language::en||description: El contenido de |
| | | carotenoides (Car) de las plantas juega un papel crucial en el ciclo |
| | | de las xantofilas y proporciona informaci\u00f3n esencial sobre las |
| | | adaptaciones fisiol\u00f3gicas de las plantas al estr\u00e9s |
| | | ambiental. Los datos de espectroscopia son esenciales para la |
| | | predicci\u00f3n no destructiva de Car y otros rasgos. Sin embargo, la |
| | | estimaci\u00f3n del contenido de Car a\u00fan est\u00e1 por |
| | | detr\u00e1s en t\u00e9rminos de precisi\u00f3n en comparaci\u00f3n con |
| | | otros pigmentos, como la clorofila (Chl). Aqu\u00ed, examin\u00e9 el |
| | | potencial de utilizar la transformada wavelet continua (CWT) en datos |
| | | de reflectancia de hojas para crear \u00edndices de vegetaci\u00f3n |
| | | (VI). Compar\u00e9 seis familias madre de CWT y seis escalas y |
| | | seleccion\u00e9 el mejor conjunto de datos general utilizando |
| | | regresiones de bosque aleatorio (RF). Utilizando un enfoque de fuerza |
| | | bruta, cre\u00e9 VI basados \u200b\u200ben wavelets en la mejor |
| | | familia madre y los compar\u00e9 con VI establecidos basados |
| | | \u200b\u200ben la reflectancia del autom\u00f3vil. Descubr\u00ed que |
| | | los \u00edndices basados \u200b\u200ben wavelets tienen una alta |
| | | sensibilidad lineal al contenido de Car, contrariamente a las |
| | | relaciones no lineales t\u00edpicas representadas por los VI basados |
| | | \u200b\u200ben reflectancia. Estas relaciones se contrastaron |
| | | te\u00f3ricamente con los datos sint\u00e9ticos creados utilizando el |
| | | modelo de transferencia radiativa PROSPECT-D. Sin embargo, la mejor |
| | | selecci\u00f3n de bandas de longitud de onda en VI basados |
| | | \u200b\u200ben wavelets var\u00eda mucho dependiendo de las |
| | | caracter\u00edsticas espectrales de los datos de entrada antes de la |
| transformation.~~language::none", | | transformaci\u00f3n. ~~language::es", |
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| "title": "Estimation of Foliar Carotenoid Content Using Spectroscopy | | "title": "Estimation of Foliar Carotenoid Content Using Spectroscopy |
| Wavelet-Based Vegetation Indices", | | Wavelet-Based Vegetation Indices", |
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