1. Introduction

Ocean color satellites have provided an unprecedented view of the global ocean owing to their ability to detect spatio-temporal patterns of bio-optical properties from space [1]. However, a satellite sensor does not provide a direct measurement of biological or biogeochemical properties of the water, but top-of-atmosphere radiance (Lt, w/m²/nm/sr). Of this Lt, about 90% is a result of atmospheric scattering. Consequently, it is critical to accurately remove this atmospheric contribution before in-water properties could be adequately derived [2]. After this correction, because the resulted water-leaving radiance (or remote-sensing reflectance) is still a complex function of in-water properties, ocean-color inversion algorithms for those properties play an important role. Over more than three decades of practice, a variety of algorithms have been developed, including simple empirical regression techniques [3, 4], artificial neural networks (e.g. Doerffer & Schiller [5]), algebraic solutions [6, 7], and spectral optimization algorithms (SOA) [8–15].

The pioneering SOA was proposed in the 1990s [8]. Since then, various SOA schemes have been developed with different complexity in modeling the bio-optical properties that make up a reflectance spectrum [9–14]. For example, Devred et al. [11] incorporated more complicated components to model the spectral inherent optical properties (IOPs), while the Garver-Siegel-Maritorena (GSM) [13] and the Hyperspectral Optimization Process Exemplar (HOPE) schemes [12,15] employed simpler bio-optical models with a smaller number of variables for the spectral IOPs. Because an SOA searches for the optimal set of numerical combinations among numerous candidates for each measured reflectance spectrum to get a solution, a large computational burden is encountered. This limited its application in processing satellite-measured ocean color images until the past decade when the rapid advance of computer technology reduced the computational stress. Its potential advantages over empirical approaches have renewed interest in using an SOA as an operational tool to process satellite ocean-color data collected by modern sensors, such as the Sea-viewing Wide Field-of-view Sensor (SeaWiFS), the Moderate Resolution Imaging Spectroradiometer (MODIS), and the Medium Resolution Imaging Spectrometer (MERIS) [16,17]. A GIOP (stands for Generic Inherent Optical Properties) platform that offers freedom to specify various optimization approaches and parameterizations has been developed and implemented under SeaDAS [17]. Because an SOA solves for multiple variables simultaneously in an implicit fashion, it is necessary and useful to illustrate the details of SOA computation, in particular the association and impact of mathematical methods and spectral models.

Here in this study, the GSM, of which the retrieved products have been widely used by the ocean color and oceanography community (e.g. Behrenfeld et al. [18], Siegel et al. [19]), is selected as an example of SOA to gain the insights of the SOA scheme. Four commonly used computational methods that can find local and global minimums are evaluated for their effectiveness in achieving optimization by applying them to a widely used data set simulated by the IOCCG Algorithm Working Group (http://www.ioccg.org/groups/OCAG_data.html). These methods are: the Levenberg-Marquardt (LM), the Generalized Reduced Gradient (GRG), the Downhill Simplex Method (Amoeba), and the Simulated Annealing-Downhill Simplex (SAA). The impact of forward spectral models on the closure between measured and modeled spectral remote-sensing reflectance, and on retrievals of spectral optical properties, is also evaluated using both the IOCCG simulated data set and an in situ data set.

2. Spectral optimization algorithm (SOA)

2.1 Spectral models

For optically deep waters, the remote sensing reflectance above the surface (R_rs, sr⁻¹), which is defined as the ratio of water-leaving radiance to downwelling irradiance just above the surface [20], can be modeled as a function of the total absorption (a(λ), m⁻¹) and total backscattering coefficients (b_b(λ), m⁻¹) of the water column, i.e.

For an SOA, an error function is defined and minimized to derive the optimal model variables (a(λ) and b_b(λ)), and it generally takes a form as

The bio-optical models to calculate a(λ) and b_b(λ) used in the GSM are detailed in Maritorena et al. [13]. For easier understanding of the results in this study, they are briefly described as below,

_{${\tilde{a}}_{ph}(\lambda )$}, ${\tilde{a}}_{dg}(\lambda )$ and ${\tilde{b}}_{bp}(\lambda )$ are spectral shapes (eigen vectors or eigen functions) determined based on either field measurements [10, 14, 24, 25] or “optimized” from a database [13]. ${\tilde{a}}_{dg}(\lambda )$and ${\tilde{b}}_{bp}(\lambda )$ are generally described as [26, 27]

It is much more difficult to model ${\tilde{a}}_{ph}(\lambda )$ precisely (e.g. Devred et al. [11], Bricaud et al. [24], Ciotti et al. [30]), although better fits could be achieved by increasing the number of free variables. In GSM, ${\tilde{a}}_{ph}(\lambda )$ is also optimized as a fixed spectrum for global waters, i.e.

Therefore, the three eigen functions imbedded in GSM are all fixed globally. Although simple linear-matrix inversion schemes could be used to solve such a system of equations [31], here and as in Maritorena et al. [13], the SOA is used and the impact of other factors such as computational methods are investigated.

2.2 Initial guesses and constrained conditions

For all numerical solutions, a set of initial values (first guess) is required to start the process. In GSM, the initial values for the three variables are kept constant, i.e. X₁ = 0.002, X₂ = 0.01, and X₃ = 0.0029.

To produce physically meaningful properties, boundaries of the three variables have to be defined. Retrievals from an R_rs(λ) spectrum via GSM are considered valid if all three variables satisfy:

0.01 ≤ X₁ ≤ 64 mg m⁻³; 0.0001 ≤ X₂ ≤ 2 m⁻¹; 0.0001 ≤ X₃ ≤ 0.1 m⁻¹.

These constrains are either applied during the solution phase or used to filter out retrievals considered invalid after the completion of an optimization (see details in Section 3).

All these numbers (for initial guesses and boundaries) were obtained from the IOCCG website (http://www.ioccg.org/groups/software.html).

3. Computation methods for optimization

There are various computational methods to reach, numerically, an optimization (minimum) status of the error function. Widely used methods include the Levenberg-Marquardt (LM), Generalized Reduced Gradient (GRG), Downhill Simplex Method (Amoeba), and Simulated Annealing-Downhill Simplex (SAA). The LM employs the partial derivative of the objective function to search for the set of variables where the objective function reaches a minimum. This is based on the theorem that the partial derivative of a function is zero when this function reaches an extreme (either maximum or minimum) [32,33]. The GRG is similar as LM in searching for minimization, but uses difference to calculate the gradient. What differs GRG from LM the most is the handling of boundary constraints. While LM assumes open boundary (or no boundary) in the solution phase, GRG uses both the gradient and the boundary conditions to determine the direction of the search for minimization and thus constrains the search within pre-determined boundaries [34]. The Amoeba, also known as Nelder-Mead algorithm, uses the downhill simplex concept to search for optimization, and thus evaluates the error function only, not its derivatives [35]. It operates by constructing a simplex between searching points and manipulating this simplex [35]. The SAA, on the other hand, is a combination of the Amoeba and simulated annealing approaches for optimization [36]. In particular, it uses stochastic transition to avoid local minimums [37]. While the LM, GRG and Amoeba belong to the category of local optimization schemes (locate a local minimum), SAA is a global optimization scheme, thus SAA is capable to overcome local minimums and achieve global optimization of an objective function.

Under their default computational architectures, constrains can be applied during the solution phase for GRG (a unique feature of GRG [34]), but not for the other three methods. In order to examine if this difference have any impacts on the solutions, in addition to the default GRG, we also implemented a modified GRG (MGRG) by widening the constraints to −500 < X < 500. After optimization is reached, the same validating constraints described in Section 2.2 are applied to results from LM, Amoeba, SAA and MGRG. Therefore, for these four methods, retrievals considered valid are those that each variable satisfies the same predefined boundaries. For GRG, the same validating constraints were applied during the solution phase.

Finally, the Interactive Data Language (ver.7.0) was used to implement the five optimization methods. Codes of the LM were downloaded from http://www.ioccg.org/groups/software.html, because the LM has been used by the GSM to solve the inversion equation numerically, likely due to its simplicity and effectiveness.

Note that there are many computational details, such as the use of partial derivatives or differences, etc., are associated with these optimization methodologies. Discussions of these computational details are beyond the scope of the study here, as our focus is to evaluate the performance of the four search schemes on the SOA, and eventually identify an optimal method for processing satellite ocean-color images.

4. Data

Both numerically simulated and field-measured data are used for this study. The simulated data set came from the IOCCG Algorithm Working Group, and details of the data simulation can be found at http://www.ioccg.org/groups/OCAG_data.html. Basically the data set contains 500 spectral R_rs simulated by Hydrolight [38] along with their corresponding spectral IOP components, which cover optical properties from clear oceanic waters to turbid coastal waters, which generally follow the increase of the order of the data points. The wavelengths range from 400 nm to 800 nm with a 10 nm spectral resolution, which was sub-sampled to wavelengths at 410, 440, 490, 510, 550, and 670 nm, spectral bands closely matching the settings of SeaWiFS. Such a data set is considered measurement-error free, thus ideal for sensitivity analysis.

The NASA Bio-Optical Marine Algorithm Data set (NOMAD [39],), where all data came from field measurements, was downloaded from SeaBASS website (http://seabass.gsfc.nasa.gov). NOMAD provides optical properties that include IOPs and R_rs at bands of 411, 443, 489, 510, 555, 670 nm. Note that the slight band center difference, such as 410 nm vs 411 nm and 490 nm vs 489 nm, is considered negligible on the SOA solution so no fine adjustment of the eigen functions was made to accommodate the slight band shift [40]. Between 550 and 555 nm, however, the absorption and backscattering coefficients of pure seawater were adjusted accordingly.

5. Result of computational methods

The results of computational methods on the SOA calculation and retrievals are presented in Fig. 1 , Fig. 2 , and Fig. 3 . In addition to the total number of valid retrievals (N) from each method, a few more measures are included after optimization is achieved. They are: computing cost (T, seconds, with an Intel Core2 Duo E8400 CPU), ${\delta }_{R_{rs}}$(the value when optimization is achieved), ${\delta }_{IOP}$, and root mean square error in log scale (RMSE). ${\delta }_{IOP}$ is the error between the derived and known spectral IOPs, which is calculated using Eq. (4), except that the R_rs(λ) spectrum is replaced by the corresponding spectral IOPs and ${\delta }_{R_{rs}}$ is replaced by ${\delta }_{IOP}$ with the spectral IOPs that formed the optimized ${\delta }_{R_{rs}}$. Further, the calculation of ${\delta }_{IOP}$ is focused on the first five bands as the longer wavelength (670 nm here) has limited information on the active optical components for most oceanic waters. Thus ${\delta }_{IOP}$ provides a goodness of match between known and retrieved IOPs spectra, instead of products at a single wavelength. On the other hand, RMSE provides a goodness of match between known and retrieved IOPs at a single band. Range, average, median and standard deviation (std) of ${\delta }_{R_{rs}}$,${\delta }_{IOP}$and RMSE for valid retrievals are summarized in Table 1 .

 

Fig. 1 Distribution of ${\delta }_{R_{rs}}^{}$ obtained with the IOCCG simulated R_rs using GSM; (a) ${\delta }_{R_{rs}}^{}$ of each input (with X axis representing the sample number and lower for clearer waters and higher number for more turbid waters); (b) frequency distribution of ${\delta }_{R_{rs}}^{}$.

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Fig. 2 Distribution of ${\delta }_{IOP}$ obtained with the IOCCG simulated R_rs using GSM; the left column shows values for each input and the right column shows frequency distribution; (a) ${\delta }_{a_{ph}}$; (b) ${\delta }_{a_{dg}}$; (c) ${\delta }_{b_{bp}}$

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Fig. 3 Scatter plot of derived IOPs versus known values using the IOCCG simulated data set; (left) 410 nm; (right) 440 nm; (a) a_ph; (b) a_dg; (c) b_bp.

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Table 1. Results of Different Optimization Schemes for the IOCCG Simulated Data set (n = 500)

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A few findings can be drawn from these results:

For the NOMAD data set, a comparison of derived products with measured values at two bands is shown in Fig. 4 . Note that the N on the figure represents the number of valid data pairs (i.e. both retrieval and in situ data are valid), which was used for the calculation of RMSE. These results suggest consistent conclusions with that based on the IOCCG simulated data set.

 

Fig. 4 Scatter plot of derived IOPs versus known values for the NOMAD data set; (left) 412 nm; (right) 443 nm; (a) a_ph; (b) a_dg; (c) b_bp.

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In summary, three local optimization methods, i.e. LM, MGRG, and Amoeba, can achieve an optimized solution quickly and with similar precision (in terms of ${\delta }_{R_{rs}}$, ${\delta }_{IOP}$, and RMSE), while LM is the quickest one. GRG can achieve 100% retrieval but those that landed on the boundary constraints are not reliable, as it is dependent on the definition of the boundary. The global optimization method, SAA, on the other hand, achieved the largest number of valid and not-hitting-boundary retrievals, but at a much higher computing cost. Applying the GSM optimization scheme to NOMAD, the NASA Ocean Biology Processing Group (http://oceancolor.gsfc.nasa.gov/MEETINGS/OOXIX/IOP/inversion_methods.html) also evaluated LM and Amoeba, and reached similar results as we shown here with both simulate and field-measured data, i.e. Amoeba is slower compared to LM. However, the results here suggest that SAA is a good candidate for retrieval performance through an SOA scheme, as long as the computational cost is tolerable.

6. Effects of spectral models on error functions and solutions

As shown in the IOCCG Report 5 [40], different bio-optical models will impact the retrievals. The results there, however, show the cumulative effects of all the eigen functions. To highlight the impact of individual eigen function once a time, below we modify some of the eigen functions used in the GSM and to characterize the impacts on error functions and variable solutions. Both the IOCCG simulated data set and the NOMAD data set were used in the experiment.

For easier illustration, we simply change or adjust the three eigen functions in the GSM.

Modification 1 (m01_GSM): In this modification, the eigen function of ${\tilde{a}}_{ph}(\lambda )$(used in Eq. (12) was changed to the following:

Modification 2 (m02_GSM): In this modification, the above change of ${\tilde{a}}_{ph}(\lambda )$maintained, and the Y value used in Eq. (11) was changed from a constant (1.03373) to dynamic (Eq. (14),

Modification 3 (m03_GSM): The above changes of ${\tilde{a}}_{ph}(\lambda )$and ${\tilde{b}}_{bp}(\lambda )$ maintained, as in Modification 2, and further the a_dg spectral slope was changed from 0.0206 nm⁻¹ to 0.015 nm⁻¹, a forward bio-optical design matching that of HOPE [15].

Here for easier implementation, MGRG was used to achieve optimization. Figure 5 shows the ${\delta }_{R_{rs}}$ and ${\delta }_{IOP}$ values from the GSM and the modified models for the IOCCG simulated data set, respectively, along with the distribution of the ${\delta }_{R_{rs}}$ and ${\delta }_{IOP}$ values. It is found that ${\delta }_{R_{rs}}$ from the m01_GSM, m02_GSM and m03_GSM is smaller than that from the GSM model (for m01_GSM, m02_GSM and m03_GSM, more than 70% of the data set has ${\delta }_{R_{rs}}$ ≤ 0.02; ${\delta }_{R_{rs}}$ from the original GSM spans a range between 0.04 and 0.10). And they also showed discernible improvement over the original GSM in terms of ${\delta }_{IOP}$. Among the three variables, ${\delta }_{a_{ph}}$differs the most between the original GSM and m01_GSM, m02_GSM and m03_GSM. ${\delta }_{a_{ph}}$of the original GSM has ~25% of the data centered at 0.6, while ${\delta }_{a_{ph}}$of the three modified models have ~20% data centered at 0.1 (see Fig. 5).

 

Fig. 5 Distribution of ${\delta }_{R_{rs}}$ and ${\delta }_{IOP}$ derived from the IOCCG simulated R_rs using GSM and modified models, computed by applying MGRG; the left column shows values for each input and the right column shows frequency distribution; (a) ${\delta }_{R_{rs}}$; (b) ${\delta }_{a_{ph}}$; (c) ${\delta }_{a_{dg}}$; (d) ${\delta }_{b_{bp}}$.

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Figure 6 compares derived IOPs with known IOPs of the first five bands (except 667 nm) of the IOCCG data set (for convenience, Fig. 6 only shows the result at 440 nm as an example, see Table 2 for more details). It was found that the modification of the eigen functions changed the retrievals of a_ph, a_dg and b_bp spectra significantly, and this impact is not uniform among the properties. One modification may reduce the RMSE of one property, but may at the same time increase the RMSE of another property. For example, between the original GSM and m01_GSM, the RMSE for a_ph(440) reduced from 0.295 to 0.155, but the RMSE for a_dg(440) increased from 0.114 to 0.185. It is the application of m03_GSM reduced almost the RMSE of all three IOPs. In addition, although m01_GSM returned the lowest RMSE for a_ph, this may partially due to the much smaller number of valid retrievals (N = 228 with m01_GSM; but it is 420 with the original GSM). On the other hand, the valid number of retrievals with m03_GSM is a lot more than that of m01_GSM. All these results regarding the number of valid retrievals and their qualities suggest that because R_rs is a function of at least three active IOPs (a_ph, a_dg, b_bp), simply modifying one component may not achieve optimal results of the three properties, although specific tuning may produce promising results of targeted property (such as chlorophyll-a concentration and diffused attenuation coefficient).

 

Fig. 6 Scatter plot of derived 440nm IOPs versus known values for the IOCCG simulated data set; GSM and three modified models were used, computed by applying MGRG; (a) a_ph, (b) a_dg, (c) b_bp.

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Table 2. Compare Derived IOPs with Known IOPs of the First Five Bands (Except 667 nm) of the IOCCG Data set

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A further test of the NOMAD in situ data also provided consistent results (see Fig. 7 ). Accuracy of retrievals in terms of absorption was much higher when all modifications were applied. For example, the RMSE for a_ph decreased from 0.504 using the original GSM to 0.281 using m03_GSM. Here the RMSE value is calculated for a_ph of the five bands to provide a measure of the quality of the retrieved a_ph spectrum, instead of the quality of a_ph at one specific band.

 

Fig. 7 Scatter plot of derived IOPs versus known values for the NOMAD data set; GSM and three modified models were used, computed by applying MGRG; while measured Rrs at six SeaWiFS bands were used as model input, output IOPs at five bands (without 670 nm) were put together and compared with measured data; (a) a_ph; (b) a_dg; (c) b_bp

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These results echo that spectral models have strong impact on the error function and final solutions of SOA [40], and also suggest that simply changing one eigen function is probably insufficient to improve remote sensing retrievals through an SOA scheme. Of course, we did not consider all possibilities of forward model modification, and this study is just to demonstrate how significant the results will be when changing an eigen function. In addition, the ${\tilde{a}}_{ph}(\lambda )$ used in GSM is not likely to be the sole factor leading to relatively larger ${\delta }_{R_{rs}}$ and ${\delta }_{IOP}$value, although this eigen function does not necessarily represent the spectral shape observed from sample measurements [24], as indicated in Maritorena et al [13].

7. Conclusions

Our analysis shows that the minimized value of the target function appears slightly different when different computational methods for optimization are used. For the five computational methods tested here, all of them can find numerical solutions for each R_rs spectrum, but the computing time and the number of valid retrievals are subject to the method used and the application of boundary constraints. Further, our results echo that the minimized values of the error function and the resulted retrievals depend on the details of the forward bio-optical models. It also suggested that for the implementation of an SOA scheme in ocean color remote sensing, it is desired to employee dynamic eigen functions to reduce errors in retrievals. These detailed illustrations regarding the impacts of computational methods and eigen functions on ocean color retrievals provide more insights associated with the spectral optimization scheme. These findings will lend helps to identify an optimal computational method and eigen functions if an SOA scheme be used to process ocean color images.