acs processing tao-cruise august 2006. 1. total vs 0.2 m signal total signal 0.2 m signal the 0.2 ...
TRANSCRIPT
ACs processing
TAO-cruise August 2006
1. Total vs 0.2m signal
total signal
0.2 m signal
The 0.2 m signal is removed from the total signal using the 0.2 m interpolated values
0.2 m interpolated values
2. Spectral discontinuity correction
Present also in 0.2 m measurements
2. Spectral discontinuity correction
Longer Portion of the Spectrum
Shorter Portion of
the Spectrum
Q: Which is the correct one, LPS or SPS?
A: For ap we don’t care because we know that ap(NIR)≈0.
2. Spectral discontinuity correction
Correction methoda) assume that the LPS is
the correct one
Longer Portion of the Spectrum
2. Spectral discontinuity correction
Correction methoda) assume that the LPS is
the correct oneb) using the first 2 s of
the LPS, predict the value of ap at the last of the SPS
2. Spectral discontinuity correction
Correction methoda) assume that the LPS is
the correct oneb) using the first 2 s of
the LPS, predict the value of ap at the last of the SPS
c) compute the difference between the predicted and observed values of ap at the last of the SPS
d) subtract such difference from the SPS
2. Spectral discontinuity correction
Case of cp
a) There is no at which we a-priori know the value of cp
b) Arbitrarily assume that LSP is correct
c) Apply correction as for ap
d) Evaluate the bias introduced by such arbitrary assumption
2. Spectral discontinuity correction
Bias evaluation (cp)
a) NOTE: For this data set, cp(750) (minimal values) ranges from 0.02 to 0.08 m-1
b) For most of the cp data the discontinuity is not important
c) When it is important, our arbitrary assumption introduces biases of the order of 0.0007/0.02=4% (conservative estimate)
d) There is no preferential direction for the shift
2. Spectral discontinuity correction
Importance of this correction for ap
a) NOTE: For this data set, ap(676) ranges from 0.001 to 0.005 m-1
b) For most of the ap data the discontinuity is not important
c) When it is important, the discontinuity can be of the order of 0.0003/0.005=6% to 0.0003/0.001=30% of ap(676)
d) There is no preferential direction for the shift
3. Interpolation to common • Because the ACs produces ap and cp
spectra with different wavelength centers, we interpolated each spectrum to have equally spaced values every 2 nm from 400 to 750 nm
4. Correction for residual T-dependence
• In theory by subtracting the 0.2 m interpolated signal from the total signal, we should not need any TS-correction of our ap spectra
• However, because the ap that we are measuring have really low values in the red region (0.001-0.005 m-1), even small Ts between two consecutive 0.2 m filtrations could introduce relatively large biases in ap
• What ranges of T and S are we observing between 1-hr distant data points?
4. Correction for residual T-dependence
from Sullivan et al. 2006
4. Correction for residual T-dependence
• What ranges of T and S are we observing between 1-hr distant data points?
ignore S
4. Correction for residual T-dependence
1. b() is independent of T (and S)
)()(
),()(),()()( b
NIRb
TNIRaNIRaTaaa wp
wpTbp
)(Tpa
scattering correction
note that part of the b-corr depends on T)(NIRaTp
2. look at Zaneveld’s scattering correction #3:
4. Correction for residual T-dependence
ref
)()(
),()(),()( refrefref
bNIRb
TNIRaNIRaTaa wp
wp
How to get T?a) Assume that there exists a spectral region (ref) where:
0)()(
),()(),()( refrefref
b
NIRb
TNIRaNIRaTaa wp
wp
b) Set ref=710:740 nm and NIR=730 nm
c) For each spectrum, find T that minimizes:
TTa Sw )(),( refref where:
d) Apply T-correction to ap using the derived T
)()(
)(b
NIRb
NIRap
)()(
)()( b
NIRb
NIRaa pp
)(Tbpa
)(pa
4. Correction for residual T-dependence
4. Correction for residual T-dependence
no correction
4. Correction for residual T-dependence
b-correction
4. Correction for residual T-dependence
Tb-correction
4. Correction for residual T-dependence
4. Correction for residual T-dependence
5. Compute cpT
• The temperature-corrected cp is finally calculated as:
pTbp
Tp bac
6. Biofouling
6. Biofouling
7. CD content
• processed ACs data merged with PAR, lat, long, SST and salinity data
• Sullivan et al. 2006 table interpolated every 2 nm (instrument specific)
Some highlights
-125ºW -140ºW
125º 140º
biofouling