internal ID number 0552 transmission ID number 55fa IMEI 300125061790820 transmission type IRIDIUM positioning system GPS instrument type PROVOR_CTS5_1.09.002 WMO ID number 2902878 WMO instrument type (table 1770) 841 WMO recorder type (table 4770) 60 start time [dd mm yyyy hh mm (Z)] 01 07 2022 07 56 status of start time n/a launch time [dd mm yyyy hh mm (Z)] 01 07 2022 08 10 status of launch time n/a launch position [lat latm lon lonm] 39. 0.826 149. 59.858 status of launch position n/a delay of first down time [hours] 0 descent sampling period [seconds] 0 drift sampling period [hours] 12 ascent sampling period [seconds] 10 cycle time [days] 1. surface time [hours] 6 clock drift [hours/hours] 0 last cycle n/a ================================ calib eq 1 for oxygen TPHASE_DOXY=C1PHASE_DOXY-C2PHASE_DOXY; Phase_Pcorr=TPHASE_DOXY+Pcoef1*PRES/1000; CalPhase=PhaseCoef0+PhaseCoef1*Phase_Pcorr+PhaseCoef2*Phase_Pcorr^2+PhaseCoef3*Phase_Pcorr^3; MOLAR_DOXY=[((c3+c4*TEMP_DOXY)/(c5+c6*CalPhase))-1]/Ksv; Ksv=c0+c1*TEMP_DOXY+c2*TEMP_DOXY^2; O2=MOLAR_DOXY*Scorr*Pcorr; Scorr=A*exp[PSAL*(B0+B1*Ts+B2*Ts^2+B3*Ts^3)+C0*PSAL^2]; A=[(1013.25-pH2O(TEMP,Spreset))/(1013.25-pH2O(TEMP,PSAL))]; pH2O(TEMP,S)=1013.25*exp[D0+D1*(100/(TEMP+273.15))+D2*ln((TEMP+273.15)/100)+D3*S]; Pcorr=1+((Pcoef2*TEMP+Pcoef3)*PRES)/1000; Ts=ln[(298.15-TEMP)/(273.15+TEMP)]; DOXY=O2/rho, where rho is the potential density [kg/L] calculated from CTD data; PPOX_DOXY=MOLAR_DOXY*(0.20946*(1013.25-pH2Osat))/Tcorr*exp[0.317*PRES/(8.314*(TEMP+273.15))]. calib coef for oxygen Spreset=0;Pcoef1=0.1,Pcoef2=0.00022,Pcoef3=0.0419;B0=-6.24523e-3, B1=-7.37614e-3, B2=-1.03410e-2, B3=-8.17083e-3; C0=-4.88682e-7; PhaseCoef0=-1.232, PhaseCoef1=1, PhaseCoef2=0, PhaseCoef3=0; c0=2.62926E-03,c1=1.11339E-04,c2=2.32656E-06,c3=2.51575E02,c4=-3.20018E-01,c5=-5.36370E01,c6=5.14932E00;D0=24.4543,D1=-67.4509,D2=-4.8489,D3=-5.44e-4; calib eq 1 for temp_doxy temp_doxy=1/(ta0+(ta1*L)+(ta2*L^2)+(ta3*L^3))-273.15; calib coef for temp_doxy ta0=2.38849E01;ta1=-3.05620E-02;ta2=2.79367E-06;ta3=-4.19026E-09; calib eq 1 for chla CHLA=(FLUORESCENCE_CHLA-DARK_CHLA)*SCALE_CHLA; calib coef for chla SCALE_CHLA=0.0121;DARK_CHLA=46; calib comment for chla none calib eq 1 for bbp700 BBP700=2*pi*khi *((BETA_BACKSCATTERING700-DARK_BACKSCATTERING700)*SCALE_BACKSCATTERING700-BETASW700); calib coef for bbp700 DARK_BACKSCATTERING700=48;SCALE_BACKSCATTERING700=3.060e-06;khi=1.076;BETASW700 (contribution of pure sea water) is calculated at 124 deg; calib comment for bbp700 Sullivan et al., 2013, Zhang et al., 2009, BETASW700 is the contribution by the pure seawater at 700nm, requiring temperature, salinity and using a depolarization of 0.039, its default value. the script can be found at http://doi.org/10.17882/42916. Reprocessed from the file provided by Andrew Bernard (Seabird) following ADMT18. This file is accessible at http://doi.org/10.17882/54520 calib eq 1 for bbp532 BBP532=2*pi*khi *((BETA_BACKSCATTERING532-DARK_BACKSCATTERING532)*SCALE_BACKSCATTERING532-BETASW532); calib coef for bbp532 DARK_BACKSCATTERING532=50;SCALE_BACKSCATTERING532=6.793e-06;khi=1.076;BETASW532 (contribution of pure sea water) is calculated at 124 deg; calib comment for bbp532 Sullivan et al., 2013, Zhang et al., 2009, BETASW532 is the contribution by the pure seawater at 532nm, requiring temperature, salinity and using a depolarization of 0.039, its default value. the script can be found at http://doi.org/10.17882/42916. Reprocessed from the file provided by Andrew Bernard (Seabird) following ADMT18. This file is accessible at http://doi.org/10.17882/54520 calib eq 1 for irrad DOWN_IRRADIANCE380=0.01*A1_380*(RAW_DOWNWELLING_IRRADIANCE380-A0_380)*lm_380; calib coef 1 for irrad A0_380=2147876151.2;A1_380=1.65479310138e-007;lm_380=1.161; calib eq 2 for irrad DOWN_IRRADIANCE412=0.01*A1_412*(RAW_DOWNWELLING_IRRADIANCE412-A0_412)*lm_412; calib coef 2 for irrad A0_412=2147587102.7;A1_412=2.01634370668e-07;lm_412=1.368; calib eq 3 for irrad DOWN_IRRADIANCE490=0.01*A1_490*(RAW_DOWNWELLING_IRRADIANCE490-A0_490)*lm_490; calib coef 3 for irrad A0_490=2147985906.6;A1_490=2.04527998424e-07;lm_490=1.365; calib eq 1 for par DOWNWELLING_PAR=A1_PAR*(RAW_DOWNWELLING_PAR-A0_PAR)*lm_PAR; calib coef for par A0_PAR=2147383679.2;A1_PAR=3.47604142638e-06;lm_PAR=1.359; calib eq 1 for nitrate The sensor returns UV_INTENSITY_DARK_NITRATE and UV_INTENSITY_NITRATE(Ntrans), a subset of continuous pixels of UV_INTENSITY_NITRATE(N), N = 1 to 256. The Ntrans indices span the interval [PIXEL_START, PIXEL_END] subset of the original array (1 to 256). Thus Ntrans(i) refers to pixel N = (PIXEL_START+i-1). PIXEL_START and PIXEL_END are defined from calibration data so that the [PIXEL_START, PIXEL_END] interval is the smallest interval of pixels that correspond to the [217 nm, 250 nm] interval of wavelengths. Only a subset of the [PIXEL_START, PIXEL_END] interval is processed to compute nitrate concentration. This subset is defined as the [PIXEL_FIT_START, PIXEL_FIT_END] interval which is the smallest interval of pixels that correspond to the [217 nm, 240 nm] interval of wavelengths (thus PIXEL_FIT_START = PIXEL_START). In the following equations the data are computed for each pixel R = PIXEL_FIT_START to PIXEL_FIT_END; ABSORBANCE_SW(R)=-log10[(UV_INTENSITY_NITRATE(R)-UV_INTENSITY_DARK_NITRATE)/UV_INTENSITY_REF_NITRATE(R)]; F(R,T)=(A+B*T)*exp[(C+D*T)*(OPTICAL_WAVELENGTH_UV(R)-OPTICAL_WAVELENGTH_OFFSET)]; E_SWA_INSITU(R)=E_SWA_NITRATE(R)*F(R,TEMP)/F(R,TEMP_CAL_NITRATE); ABSORBANCE_COR_NITRATE(R)=ABSORBANCE_SW(R)-(E_SWA_INSITU(R)*PSAL)*[1-(0.026*PRES/1000)]; Perform a multilinear regression to get MOLAR_NITRATE with estimated ABSORBANCE_COR_NITRATE(R) with ABSORBANCE_COR_NITRATE(R)=BASELINE_INTERCEPT+BASELINE_SLOPE*OPTICAL_WAVELENGTH_UV(R)+MOLAR_NITRATE*E_NITRATE(R); NITRATE=MOLAR_NITRATE/rho, where rho is the potential density [kg/L] calculated from CTD data. calib coef for nitrate n/a calib eq 1 for ph k0T=k0+k2*TEMP; pcorr=f1*PRES+f2*PRES^2+f3*PRES^3+f4*PRES^4+f5*PRES^5+f6*PRES^6; k0TP=k0T+pcorr; Tk=273.15+TEMP; Cltotal=(0.99889/35.453*PSAL/1.80655)/(1-0.001005*PSAL); ADH=3.4286e-6*TEMP^2+6.7524e-4*TEMP+0.49172143; IonS=19.924*PSAL/(1000-1.005*PSAL); log10gammaHCl=[-ADH*sqrt(IonS)/(1+1.394*sqrt(IonS))]+[(0.08885-0.000111*TEMP)*IonS]; deltaVHCl=17.85+0.1044*TEMP-0.001316*TEMP^2; log10gammaHCLtP=log10gammaHCl+[deltaVHCl*(PRES/10)/(R*Tk*ln(10))/2/10]; PH_IN_SITU_FREE=[(VRS_PH-k0TP)/(R*Tk/F*ln(10))]+[ln(Cltotal)/ln(10)]+2*log10gammaHCLtP-log10(1-0.001005*PSAL); Stotal=(0.14/96.062)*(PSAL/1.80655); Khso4=exp{[-4276.1/Tk+141.328-23.093*ln(Tk)]+[(-13856/Tk+324.57-47.986*ln(Tk))*IonS^0.5]+[(35474/Tk-771.54+114.723*ln(Tk))*IonS]-[2698/Tk*IonS^1.5]+[1776/Tk*IonS^2]+ln(1-0.001005*PSAL)}; deltaVHSO4=-18.03+0.0466*TEMP+0.000316*TEMP^2; KappaHSO4=(-4.53+0.09*TEMP)/1000; lnKhso4fac=(-deltaVHSO4+0.5*KappaHSO4*(PRES/10))*(PRES/10)/(R*10*Tk); Khso4TPS=Khso4*exp(lnKhso4fac); PH_IN_SITU_TOTAL=PH_IN_SITU_FREE-log10(1+Stotal/Khso4TPS) calib coef for ph R=8.31446;F=96485;k0=-1.2813;k2=-0.00092084;f0=-0.0017554;f1=8.7373e-06;f2=-1.1362e-08;f3=8.9705e-12;f4=-3.8505e-15;f5=8.3605e-19;f6=-7.1269e-23; ==================================== conductivity calibration date 17 03 2022 temperature calibration date 17 03 2022 pressure calibration date 14 03 2022 flbbcd calibration date 25 03 2022 oxygen calibration date 10 02 2022 nitrate calibration date 20 04 2022 ocr calibration date 24 03 2022 ph calibration date 15 02 2022 float manufacturer NKE float serial number P53357-22CH001 PI MEIXUN ZHAO program name CHINA ARGO EQUIVALENT principal investigator address OUC, QINGDAO originating country CHINA float deployer CHAO CUI float deployer address OUC, QINGDAO deployment type R/V deployment platform DONG FANG HONG 3 deployment cruise id n/a profile at deployment n/a nominal drift pressure [dbar] 1000 cycles for drift pressure 1 nominal profile pressure [dbar] 2000 cycles for profile pressure 1 pump type n/a conductivity sensor type SBE41CP_V7.2.5 conductivity sensor manufacturer SBE conductivity sensor serial number 17099 conductivity sensor accuracy 0.005 conductivity sensor resolution 0.001 Profile Sampling Method continuous temperature sensor type SBE41CP_V7.2.5 temperature sensor manufacturer SBE temperature sensor serial number 17099 temperature sensor accuracy 0.002 temperature sensor resolution 0.001 pressure sensor type DRUCK_2900PSIA pressure sensor manufacturer DRUCK pressure sensor serial number 12050286 pressure sensor accuracy 2.4 pressure sensor resolution 0.1 oxygen sensor type AANDERAA_OPTODE_4330 oxygen sensor manufacturer AANDERAA oxygen sensor serial number 3910 oxygen sensor accuracy 8 oxygen sensor resolution 1 oxygen sensor pressure offset -0.3 oxygen sampling in air 1 chlorophyll sensor type ECO_FLBB2 chlorophyll sensor manufacturer WETLABS chlorophyll sensor serial number 7466 chlorophyll sensor accuracy 0.08 chlorophyll sensor resolution 0.025 chlorophyll sensor excit wavelength 470 chlorophyll sensor emission wavelength 695 backscattering sensor type ECO_FLBB2 backscattering sensor manufacturer WETLABS backscattering sensor serial number 7466 backscattering sensor accuracy -999.9 backscattering sensor resolution -999.9 backscattering sensor wavelength 700 backscattering sensor angle 124 backscattering sensor pressure offset 0.1 backscattering sensor type ECO_FLBB2 backscattering sensor manufacturer WETLABS backscattering sensor serial number 7466 backscattering sensor accuracy -999.9 backscattering sensor resolution -999.9 backscattering sensor wavelength 532 backscattering sensor angle 124 backscattering sensor pressure offset 0.1 ocr sensor type SATLANTIC_OCR504_ICSW ocr sensor manufacturer SATLANTIC ocr sensor serial number 2279 ocr sensor accuracy -999.9 ocr sensor resolution -999.9 ocr sensor bandwidth 10,10,10 ocr sensor wavelength 380,412,490 ocr sensor pressure offset -0.08 nitrate sensor type SUNA_V2 nitrate sensor manufacturer SATLANTIC nitrate sensor serial number 1881 nitrate sensor accuracy 2 nitrate sensor resolution 0.01 nitrate sensor pressure offset 1.5 nitrate calibration file SNA1881C.CAL nitrate pixel start 36 nitrate pixel end 76 nitrate pixel fit start 36 nitrate pixel fit end 64 ph sensor type SEAFET ph sensor manufacturer SBE ph sensor serial number 11386 ph sensor accuracy 0.005 ph sensor resolution 0.0004 battery type Lithium initial battery voltage [volt] 10.8 primary control board type APMT primary board serial number C210618-0019 secondary control board type USEA secondary control board serial number C21010700011 ROM version 1.09.002 manual version 33-16-051_APMT comment n/a