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VIIRS-derived Chlorophyll-a using the Ocean Color Index method SeungHyun Son 1,2 and Menghua Wang 1 1 NOAA/NESDIS/STAR, E/RA3, College Park, MD, USA 2.

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Presentation on theme: "VIIRS-derived Chlorophyll-a using the Ocean Color Index method SeungHyun Son 1,2 and Menghua Wang 1 1 NOAA/NESDIS/STAR, E/RA3, College Park, MD, USA 2."— Presentation transcript:

1 VIIRS-derived Chlorophyll-a using the Ocean Color Index method SeungHyun Son 1,2 and Menghua Wang 1 1 NOAA/NESDIS/STAR, E/RA3, College Park, MD, USA 2 CIRA/Colorado State Univ., Fort Collins, CO, USA STAR JPSS 2016 Annual Science Meeting, College Park, MD, USA August 10, 2016 Acknowledgements: This work was supported by JPSS and NOAA Ocean Remote Sensing (ORS) funding.

2 INTRODUCTION   For satellite ocean color remote sensing, phytoplankton chlorophyll-a (Chl-a) concentrations are generally measured using empirical regressions of spectral ratios of normalized water-leaving reflectances (or remote sensing reflectances).   Widely used Chl-a algorithm for the ocean color satellite sensors such as SeaWiFS, MODIS, & VIIRS is based on the ocean chlorophyll-type (OCx) (O’Reilly et al., 1998) (e.g., OC3V for VIIRS).   The band ratio-based Chl-a algorithm can have considerable noise errors for oligotrophic waters (Hu et al., 2012). A new Chl-a algorithm based on the color index (CI) has been developed (Hu et al., 2012).   The CI-based Chl-a algorithm can improve VIIRS Chl-a data over oligotrophic waters with much reduced data noise from instrument calibration and the imperfect atmospheric correction.   However, the CI-based Chl-a algorithm is only applicable for low Chl-a concentration (< ~0.3 mg m -3 ). A merging method between CI-based and OCx Chl-a algorithms has been proposed based on Chl-a concentration.   All coefficient related to the CI-based Chl-a algorithm need to be re-derived for VIIRS spectral bands.   It is noticed that there are obvious discontinuities for VIIRS Chl-a data in the Chl-a transition between the two algorithms.

3 OBJECTIVES   To Evaluate Performance of the original OCI-derived Chl-a products from VIIRS measurements with comparison of the VIIRS OC3V- derived Chl-a products for the global ocean.   To Improve the CI-based Chl-a algorithm for VIIRS spectral bands and to be overall consistent with the OC3V-derived Chl-a data.   To develop a new merging method for the two Chl-a algorithms between CI-based and OC3V algorithms.   To Implement the newly improved OCI-based Chl-a algorithm to the VIIRS ocean color products.

4   In situ hyperspectral radiometeric measurements at the MOBY site moored off the island of Lanai in Hawaii (Clark et al., 1997) were used.   VIIRS spectral-band-weighted MOBY in situ normalized water-leaving radiance, nL w (λ), data at 410, 443, 486, 551, and 671 nm are obtained from the NOAA CoastWatch website (http://coastwatch.noaa.gov/moby/).   MOBY-derived Chl-a data using the CI-based and OC3V-based Chl-a algorithms were compared with VIIRS-derived Chl-a data to evaluate performance of the CI-based Chl-a algorithm. MOBY In Situ Measurements

5 Satellite Ocean Color Data   NOAA Multi-Sensor Level-1 to Level-2 (MSL12) ocean color data processing system has been used for processing satellite ocean color data from Level-1B to Level-2.   Science Quality VIIRS ocean color product data were generated using NOAA- MSL12. VIIRS ocean color Environmental Data Records (EDR) (or Level-2) were processed from the improved Sensor Data Records (SDR) (or Level-1B) (Sun & Wang, 2015).   The VIIRS EDR data were derived using the NIR-SWIR combined atmospheric correction algorithm.   VIIRS ocean color Level-3 data products for the global ocean were processed from the VIIRS-derived Level-2 products with a spatial resolution of 9 km.   Matchups of VIIRS and in situ Chl-a data were developed using pixels with a 5×5 box centered at the location of in situ measurements following the procedure of Wang et al. (2009).

6 OCx Based Chl-a Algorithm   OC3V Chl-a algorithm for VIIRS Chl-a = 10^[a 0 +a 1 ∙R +a 2 ∙R 2 +a 3 ∙R 3 +a 4 ∙R 4 ] where R = Log 10 { Max[R rs (443),R rs (486)] / R rs (551) } a = [0.2228,-2.4683,1.5867,-0.4275,-0.7768]

7 Color Index based Chl-a Algorithm   Color Index based Chl-a algorithm (Hu et al., 2012): CI = R rs (555) – [R rs (443)+(B 2 -B 1 )/(B 3 -B 1 )(R rs (670)-R rs (443)] where B 1 =443, B 2 =555, B 3 =670 Chl CI = 10^[191.6590 ∙ CI – 0.4909](CI ≤ -0.0005 sr -1 ) Chl OCI = Chl CI ( CHL CI ≤ 0.25 mg m -3 ) Chl OC4 ( CHL CI > 0.30 mg m -3 ) α×Chl OC4 + β×Chl CI ( 0.25 mg m -3 < CHL CI ≤ 0.30 mg m -3 ) where α=(Chl CI -0.25)/(0.3-0.25) and β=(0.3- Chl CI )/(0.3-0.25)

8 VIIR-derived Chl-a data compared with those derived from the in situ MOBY data

9 Density Scatter plot for VIIRS-derived Chl-a using OC3V and OCI Chl-a algorithms -. Global (binned) VIIRS Level-3 daily data on March 29, 2015 -. Only pixels with water depths > 1 km are used

10 Scatter plot for VIIRS-derived Chl-a with OC3V vs CI values -. All the data in the plot were extracted from the density plot that requires density > 5000 pixels.

11 New OCI Chl-a Algorithm   New OCI Chl-a algorithm for VIIRS ocean color data: CI = R rs (551) – [R rs (443)+(B 2 -B 1 )/(B 3 -B 1 )(R rs (671)-R rs (443)] where B 1 =443, B 2 =551, B 3 =671 Chl CI = 10^[216.76 ∙ CI – 0.4093] Chl OCI = Chl OC3V (R ≤ 2.0 ) Chl OC3V ( R > 4.0 ) w×Chl CI + (1-w)×Chl OC3V ( 2.0 < R ≤ 4.0 ) where R=R rs (443)/R rs (551) & w =(R-2.0)/(4.0 – 2.0)

12 VIIRS-derived global Chl-a monthly composite images

13 Density scatter plots of global VIIRS Level-3 monthly composite Chl-a images

14 Histogram plots of VIIRS global Level-3 monthly composite Chl-a data

15 Global images of Chl-a difference between new OCI and OC3V Chl-a data

16 VIIR-derived Chl-a data compared with those derived from the in situ MOBY data

17 Conclusions   An implementation approach using the ocean color index (OCI)-based chlorophyll-a (Chl-a) algorithm for the VIIRS has been developed.   The CI-based Chl-a algorithm can improve VIIRS Chl-a data over oligotrophic waters with much reduced data noise from instrument calibration and the imperfect atmospheric correction.   We developed CI-based algorithm specifically for VIIRS and further improved the two Chl-a algorithm merging method using the blue-green reflectance ratio values.   New OCI Chl-a algorithm for VIIRS can produce consistent Chl-a data compared with those from the OC3V algorithm.   In particular, the data transition between CI-based and OC3V-based Chl-a algorithms is quite smooth and there are no obvious discontinuities in VIIRS- derived Chl-a data.   New OCI-based Chl-a algorithm has been implemented in the MSL12 for routine production of VIIRS global Chl-a data.   A paper has just been published: Wang, M. and S. Son, “VIIRS-derived chlorophyll-a using the ocean color index method,” Remote Sens. Environ., 182, 141–149, 2016.

18 Thank you!

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