Continuing with the RBRconcerto³ C.T.D.pH logger, the conductivity reading from Channel-1 without corrections is given by a simple linear function:
$Craw = c_0 + c_1 \cdot R$where R is the normalized voltage ratio from Channel-1 monitoring conductivity, c0,c1 are the core coefficients of the linear equation, and Craw is the uncorrected conductivity output, reported in mS/cm for RBR marine instruments.
The equation which corrects the output for the effects of both temperature and pressure on the conductivity cell is:
$Corr = \dfrac{Craw - Kc_1 \cdot (T - Tcal)}{1 + Kc_2 \cdot (T - Tcal) + Kc_3 \cdot (Pcorr - Pcal)}$Casting the equation into the style used by the logger would give:
where
- Craw is the uncorrected conductivity, c0 + c1 × R,
- x0, x1, x2 correspond directly to the constants "Kc1", "Kc2" and "Kc3",
- x3 is the calibration temperature "Tcal" in °C,
- x4 is the calibration pressure "Pcal" in dbar,
- n0 is the index of the temperature channel, in this example 2,
value(n0) is the final output value of the temperature channel in °C, - n1 is the index of the pressure channel, in this example 3,
value(n1) is the final output value of the pressure channel in dbar, - Ccorr is the corrected output in mS/cm.
It is quite common to have a logger monitoring conductivity and temperature without a pressure channel, typically deployed at a known, constant depth. In this case, n1 would be set to "value", and so value(n1) would be substituted by a default value (see the "settings pressure" command). Confirm the channel type. Set the core coefficients. Set the cross-channel correction coefficients. Request confirmation of all calibration coefficients.Examples
<< calibration 1 type = cond06
<< calibration 1 type = cond05, datetime = 20171201000000, c0 = 0.2346, c1 = 153.4873, x0 = 0.2003, x1 = 0.2943, x2 = 0.085, x3 = 15.028, x4 = 10.0025, n0 = 2, n1 = 3