Comprehensive assessment of the two-flow model’s shape factors in aquatic environments

Manuel Gimond

doi:10.1364/AO.44.000966

Applied Optics
Vol. 44,
Issue 6,
pp. 966-975
(2005)
•https://doi.org/10.1364/AO.44.000966

Comprehensive assessment of the two-flow model’s shape factors in aquatic environments

Manuel Gimond

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Manuel Gimond, "Comprehensive assessment of the two-flow model’s shape factors in aquatic environments," Appl. Opt. 44, 966-975 (2005)

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Abstract

The applicability of the two-flow model to problems is dependent on assumptions that are used to reduce the model to two equations with two unknowns. Such a reduction requires proper parameterization of the shape factors. An extensive data set that reveals the relationships of shape factors to scattering-to-absorption ratios (0.1 ≤ b/a ≤ 30) and to the mean cosine of scattering (0.66 ≤ ${\bar{μ}}_{s}$ ≤ 0.95) as obtained with a Monte Carlo model is presented. The sensitivity of the computed irradiance reflectance to the shape factors is also addressed. Results show increasing sensitivity of irradiance reflectance to the shape factors with increasing scattering-to-absorption ratio and with increasing anisotropy of the scattering phase function. For waters with highly anisotropic scattering phase functions, high scattering-to-absorption ratios, or both, the proper parameterization of the shape factors must be considered. A lookup table of the shape factors’ depth-dependent values for various optical conditions is also presented.

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Symbol	Definition	Unit
a, b	Absorption and scattering coefficients	m⁻¹
a_u_,_d^d	Diffuse absorption coefficient for upwelling and downwelling light	m⁻¹
b_u_,_d^d	Diffuse backscattering coefficient for upwelling and downwelling light	m⁻¹
b_b	Backscattering coefficient	m⁻¹
B	Backscatter fraction
β	Volume scattering function	sr⁻¹ m⁻¹
c	Beam attenuation coefficient (sum of a and b)	m⁻¹
E_d, E_u	Downwelling and upwelling irradiance	Wm⁻²
E_od, E_ou	Downwelling and upwelling scalar irradiance	Wm⁻²
ζ	Optical depth, ζ = cz
θ	Zenith scattering angle
θ₀	Zenith angle of the Sun
ϑ	Vector specified by a zenith and an azimuth angle
L	Radiance	Wm⁻² sr⁻¹
${\bar{μ}}_{d}, {\bar{μ}}_{u}$	Downwelling and upwelling mean cosines of the zenith angle of downwelling and upwelling traveling photons, respectively
${\bar{μ}}_{s}$	Mean cosine of the scattering phase function
R	Irradiance reflectance
r_d, r_u	Downwelling and upwelling shape factors
z	Depth	m

Source	B	${\bar{μ}}_{s}$
Station 11 (Offshore California)	0.013	0.947
Station 5 (Offshore California)	0.014	0.947
Sea water	0.015	0.934
Sea water filtered for 40 min	0.017	0.931
Filtered fresh water + scattering agent	0.018	0.926
Average of San Diego Harbor measurements	0.019	0.922
(stations 2040, 2200, 2240)
Sea water filtered for 100 min	0.025	0.919
Station 7 (Bahamas Islands)	0.025	0.915
Station 9 (Bahamas Islands)	0.038	0.885
Station 8 (Bahamas Islands)	0.044	0.872
Filtered fresh water	0.119	0.727
Sea water filtered for 18 h	0.146	0.660

${\bar{μ}}_{s}$	r_d at Depth Where E_d = E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.0801	1.0860	1.0904	1.1006	1.1238	1.2354	1.3009	1.3381	1.3625	1.3796	1.3925
0.727	1.0691	1.0738	1.0772	1.0860	1.1059	1.2072	1.2721	1.3106	1.3364	1.3550	1.3691
0.872	1.1588	1.1643	1.1719	1.1843	1.2139	1.3991	1.5531	1.6603	1.7393	1.8005	1.8492
0.885	1.1767	1.1839	1.1896	1.2031	1.2330	1.4244	1.5886	1.7057	1.7933	1.8620	1.9173
0.915	1.2330	1.2369	1.2430	1.2569	1.2874	1.4874	1.6700	1.8067	1.9137	2.0003	2.0711
0.919	1.2002	1.2040	1.2096	1.2205	1.2510	1.4476	1.6308	1.7697	1.8792	1.9683	2.0421
0.922	1.3518	1.3586	1.3727	1.3892	1.4384	1.7453	2.0287	2.2438	2.4125	2.5500	2.6638
0.926	1.2935	1.2994	1.3130	1.3315	1.3805	1.7211	2.0495	2.3051	2.5094	2.6780	2.8191
0.931	1.3196	1.3205	1.3342	1.3510	1.3927	1.6764	1.9495	2.1608	2.3316	2.4716	2.5887
0.934	1.3746	1.3781	1.3933	1.4104	1.4586	1.7864	2.1014	2.3496	2.5482	2.7137	2.8525
0.947^a	1.2784	1.2848	1.2938	1.3096	1.3391	1.5702	1.8068	2.0020	2.1663	2.3059	2.4272
0.947^b	1.2797	1.2879	1.2933	1.3039	1.3341	1.5494	1.7689	1.9512	2.1031	2.2332	2.3447

${\bar{μ}}_{s}$	r_d at Depth Where E_d = 50% E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.0797	1.0917	1.1003	1.1163	1.1518	1.2908	1.3527	1.3844	1.4008	1.4135	1.4221
0.727	1.0684	1.0782	1.0848	1.0982	1.1285	1.2583	1.3246	1.3578	1.3790	1.3918	1.4023
0.872	1.1571	1.1726	1.1881	1.2128	1.2737	1.5772	1.7637	1.8667	1.9315	1.9791	2.0127
0.885	1.1761	1.1939	1.2072	1.2312	1.2954	1.6236	1.8278	1.9436	2.0162	2.0745	2.1093
0.915	1.2299	1.2440	1.2589	1.2885	1.3553	1.7240	1.9750	2.1284	2.2271	2.2936	2.3533
0.919	1.1962	1.2077	1.2235	1.2515	1.3152	1.6818	1.9416	2.0965	2.2012	2.2791	2.3357
0.922	1.3532	1.3773	1.3993	1.4444	1.5531	2.1534	2.5546	2.7900	2.9386	3.0525	3.1328
0.926	1.2984	1.3131	1.3468	1.3948	1.5183	2.2182	2.7076	2.9895	3.1717	3.3148	3.4101
0.931	1.3208	1.3346	1.3598	1.4002	1.5015	2.0846	2.4852	2.7272	2.8866	3.0163	3.0974
0.934	1.3740	1.3914	1.4218	1.4714	1.5877	2.2715	2.7392	3.0241	3.2174	3.3629	3.4710
0.947^a	1.2822	1.2958	1.3078	1.3432	1.4230	1.9336	2.3269	2.5903	2.7705	2.9086	3.0132
0.947^b	1.2755	1.2879	1.3069	1.3313	1.4073	1.8756	2.2439	2.4893	2.6580	2.7877	2.8847

${\bar{μ}}_{s}$	r_d at Depth Where E_d = 10% E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.0787	1.0924	1.0991	1.1203	1.1598	1.3041	1.3620	1.3887	1.4047	1.4156	1.4233
0.727	1.0664	1.0749	1.0868	1.0995	1.1351	1.2718	1.3338	1.3645	1.3825	1.3956	1.4050
0.872	1.1537	1.1680	1.1848	1.2194	1.2918	1.6235	1.8005	1.8933	1.9527	1.9942	2.0266
0.885	1.1644	1.1836	1.2008	1.2375	1.3148	1.6748	1.8689	1.9753	2.0432	2.0917	2.1273
0.915	1.2045	1.2354	1.2548	1.2859	1.3721	1.7883	2.0374	2.1747	2.2630	2.3303	2.3793
0.919	1.1697	1.1988	1.2200	1.2534	1.3338	1.7473	1.9992	2.1449	2.2411	2.3105	2.3637
0.922	1.3368	1.3561	1.3870	1.4408	1.5852	2.2614	2.6408	2.8578	2.9928	3.0935	3.1699
0.926	1.2553	1.3086	1.3307	1.4005	1.5597	2.3480	2.8049	3.0683	3.2381	3.3593	3.4517
0.931	1.2730	1.3180	1.3396	1.3977	1.5283	2.1864	2.5859	2.8052	2.9550	3.0614	3.1428
0.934	1.3396	1.3747	1.4052	1.4753	1.6196	2.3917	2.8576	3.1200	3.2930	3.4237	3.5157
0.947^a	1.2556	1.2730	1.2977	1.3404	1.4437	2.0320	2.4366	2.6810	2.8496	2.9748	3.0679
0.947^b	1.2530	1.2765	1.3025	1.3309	1.4262	1.9710	2.3458	2.5749	2.733	2.8499	2.9391

${\bar{μ}}_{s}$	r_d at Depth Where E_d = 1% E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.0746	1.0803	1.0968	1.1214	1.1595	1.3045	1.3614	1.3877	1.4055	1.4139	1.4232
0.727	1.0568	1.0813	1.0791	1.0998	1.1360	1.2709	1.3345	1.3653	1.3826	1.3956	1.4054
0.872	1.1415	1.1518	1.1645	1.1994	1.2782	1.6273	1.8014	1.8938	1.9520	1.9946	2.0273
0.885	1.1495	1.1743	1.1976	1.2194	1.3092	1.6733	1.8728	1.9779	2.0443	2.0910	2.1273
0.915	1.2011	1.2222	1.2349	1.2531	1.3657	1.7912	2.0444	2.1772	2.2670	2.3236	2.3794
0.919	1.1759	1.1958	1.2116	1.2384	1.3252	1.7453	2.0071	2.1468	2.2481	2.3097	2.3655
0.922	1.2846	1.3284	1.3309	1.4186	1.5529	2.2579	2.6483	2.8583	2.9986	3.1007	3.1682
0.926	1.2648	1.2832	1.3334	1.3701	1.5285	2.3408	2.8178	3.0802	3.2327	3.3604	3.4585
0.931	1.2822	1.2647	1.3139	1.3771	1.5055	2.1767	2.5941	2.8112	2.9663	3.0572	3.1428
0.934	1.3837	1.3258	1.3779	1.4218	1.5829	2.3951	2.8579	3.1224	3.2942	3.4188	3.5176
0.947^a	1.2232	1.2273	1.2934	1.3290	1.4240	2.0283	2.4337	2.7015	2.8539	2.9793	3.0694
0.947^b	1.2426	1.2691	1.2521	1.3013	1.4107	1.9621	2.3531	2.5820	2.7347	2.8579	2.9435

${\bar{μ}}_{s}$	r_u at Depth Where E_d = E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.5879	1.5867	1.6041	1.6046	1.5965	1.5816	1.5731	1.5672	1.5631	1.5597	1.5569
0.727	1.6077	1.6023	1.6054	1.5998	1.5961	1.5814	1.5729	1.5672	1.5631	1.5595	1.5568
0.872	2.8757	2.8204	2.8666	2.8464	2.8175	2.7087	2.6537	2.6244	2.6062	2.5924	2.5815
0.885	3.1206	3.1058	3.1293	3.0957	3.0619	2.9295	2.8626	2.8281	2.8061	2.7893	2.7764
0.915	3.9515	3.9219	3.9009	3.8794	3.8228	3.5914	3.4710	3.4069	3.3649	3.3365	3.3132
0.919	3.8965	3.8625	3.9134	3.9047	3.8361	3.6239	3.5059	3.4432	3.4032	3.3771	3.3543
0.922	5.9156	6.2127	6.1407	6.0840	5.9229	5.3470	5.0617	4.9204	4.8327	4.7743	4.7286
0.926	6.7762	6.8868	6.8586	6.8002	6.6929	6.0347	5.7227	5.5667	5.4746	5.4136	5.3680
0.931	5.9927	6.0746	6.1022	6.1859	6.0222	5.4585	5.1790	5.0269	4.9380	4.8762	4.8280
0.934	7.5502	7.2947	7.3642	7.3356	7.1586	6.3784	5.9997	5.8127	5.6939	5.6139	5.5533
0.947^a	6.4272	6.1879	6.1739	6.1856	6.0787	5.6395	5.3761	5.2379	5.1487	5.0860	5.0386
0.947^b	5.7655	6.0074	5.8956	5.8173	5.7496	5.3436	5.1023	4.9703	4.8873	4.8279	4.7823

${\bar{μ}}_{s}$	r_u at Depth Where E_d = 50% E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.6393	1.6080	1.6090	1.6136	1.6195	1.6141	1.6000	1.5908	1.5824	1.5768	1.5719
0.727	1.6187	1.6247	1.6059	1.6083	1.6178	1.6165	1.6046	1.5950	1.5873	1.5805	1.5756
0.872	2.8334	2.8799	2.8759	2.8904	2.9217	2.8714	2.8113	2.7661	2.7300	2.7049	2.6817
0.885	3.1090	3.1169	3.1869	3.1608	3.1706	3.1259	3.0512	2.9970	2.9539	2.9259	2.8969
0.915	4.0813	3.9226	3.9247	3.9336	3.9477	3.8445	3.7236	3.6442	3.5817	3.5302	3.4943
0.919	4.0370	3.9533	3.9030	3.9495	3.9696	3.9174	3.8051	3.7212	3.6579	3.6088	3.5682
0.922	6.3389	6.1638	6.2274	6.2171	6.1639	5.8069	5.5302	5.3527	5.2203	5.1283	5.0490
0.926	7.1246	7.0856	6.9480	7.0908	7.0790	6.7954	6.4674	6.2427	6.0725	5.9590	5.8524
0.931	6.2404	6.5357	6.3435	6.3082	6.3048	5.9839	5.6993	5.5103	5.3786	5.2855	5.1985
0.934	7.3766	7.5562	7.6813	7.4843	7.4445	7.0285	6.6514	6.4110	6.2464	6.1224	6.0217
0.947^a	5.7012	6.3710	6.2704	6.4025	6.4061	6.3004	6.0704	5.8929	5.7557	5.6460	5.5595
0.947^b	5.8290	5.6943	5.9204	5.8507	5.9712	5.9125	5.7119	5.5588	5.4315	5.3348	5.2531

${\bar{μ}}_{s}$	r_u at Depth Where E_d = 10% E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.6069	1.6095	1.6113	1.6208	1.6303	1.6215	1.6061	1.5938	1.5846	1.5782	1.5727
0.727	1.6455	1.5846	1.6026	1.6173	1.6303	1.6264	1.6119	1.5990	1.5900	1.5833	1.5775
0.872	2.8228	2.8268	2.8861	2.9009	2.9238	2.9173	2.8381	2.7845	2.7449	2.7131	2.6898
0.885	2.8862	3.0072	3.2103	3.1589	3.2152	3.1729	3.0817	3.0175	2.9724	2.9364	2.9084
0.915	3.5981	3.8719	3.9713	3.8964	3.9717	3.8985	3.7717	3.6781	3.6075	3.5559	3.5133
0.919	3.1638	3.9192	3.9741	3.9760	4.0250	3.9894	3.8635	3.7653	3.6902	3.6326	3.5863
0.922	6.2344	6.2522	6.1870	6.1858	6.1849	5.9201	5.6004	5.4014	5.2580	5.1537	5.0753
0.926	7.1407	6.7614	7.2974	7.1035	7.1552	6.9728	6.5695	6.3258	6.1324	5.9922	5.8818
0.931	5.4425	6.3119	6.4198	6.3164	6.2236	6.0816	5.7867	5.5848	5.4258	5.3116	5.2295
0.934	7.9650	7.2656	7.3673	7.6344	7.3930	7.1833	6.7676	6.5004	6.3105	6.1689	6.0575
0.947^a	6.5651	7.0223	6.2543	6.2431	6.4534	6.4771	6.1926	5.9826	5.8271	5.7061	5.6078
0.947^b	6.3453	6.0751	6.0794	5.9779	6.1362	6.0759	5.8241	5.6488	5.4992	5.3928	5.2993

${\bar{μ}}_{s}$	r_u at Depth Where E_d = 1% E_d(z = 0)

	0.1	0.2	0.3	0.5	1	5	10	15	20	25	30
0.66	1.6185	1.5291	1.6171	1.6166	1.6280	1.6233	1.6089	1.5947	1.5846	1.5773	1.5726
0.727	1.4828	1.5631	1.6744	1.5827	1.6379	1.6255	1.6125	1.5984	1.5899	1.5829	1.5757
0.872	2.3766	2.8209	2.8815	2.9845	2.9089	2.9200	2.8380	2.7838	2.7407	2.7092	2.6889
0.885	3.4174	2.8773	3.1711	3.1118	3.2176	3.1710	3.0835	3.0196	2.9720	2.9352	2.9050
0.915	2.7345	4.3381	4.0629	3.6915	4.0786	3.9134	3.7775	3.6830	3.6080	3.5521	3.5143
0.919	6.5086	3.8669	3.7187	3.7309	4.0271	3.9473	3.8758	3.7651	3.6955	3.6268	3.5929
0.922	5.2944	6.3842	5.9976	6.1493	5.8994	5.8880	5.5931	5.3899	5.2731	5.1600	5.0730
0.926	4.5542	6.8715	7.5339	7.0769	7.2332	6.9364	6.6071	6.3205	6.1239	5.9838	5.8972
0.931	3.7619	3.5290	7.0930	6.9480	6.5340	6.1089	5.8010	5.6036	5.4438	5.3106	5.2188
0.934	6.0178	7.3894	5.4892	7.8775	7.4017	7.2355	6.7606	6.5073	6.3060	6.1743	6.0490
0.947^a	3.5764	6.4152	5.7277	5.6224	6.2528	6.4215	6.1670	6.0085	5.8334	5.6917	5.5996
0.947^b	3.6821	6.2724	5.8746	5.6193	6.3723	6.0198	5.8328	5.6535	5.5027	5.3910	5.2966

Abstract

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Figures (4)

Tables (10)

Equations (12)

Applied Optics