Abstract: A circuit for measurement of the conductance of an electrolyte cell is disclosed which features compensation for non-linearities produced by resistance in series with the resistance of the cell and for non-linearities caused by polarization of the cell due to chemical, kinetic or other effects within the cell. The cell is driven by an AC signal, and the circuit features a feedback loop in which a portion of the AC output signal is fed back for compensation of the series resistance and in which an op-amp generates a compensating DC voltage, both of which are summed with the AC excitation signal prior to its being supplied to the cell.

Abstract: Apparatus and methods for measurement of total organic carbon content of water, particularly of low relative organic content, are described which feature a single sample cell for exposure of a static sample to ultraviolet radiation comprising electrodes for measuring the conductivity of the water. The conductivity is monitored as a function of time and the second time derivative of the conductivity signal is monitored to indicate when the oxidation reaction has been completed. Compensation for the contribution to conductivity of the water sample made by the instrument is achieved by subtracting a quantity proportional to the first time derivative of the conductivity at a time when the second time derivative reaches zero, indicating that the oxidation reaction is complete, from the change in the total conductivity measurement, the remainder being equal to the contribution to conductivity made by oxidation of the organic content of the water.

Abstract: Apparatus and methods for measurements of total organic carbon content of water, particularly of low relative organic content, is described which features a single sample cell for exposure of a sample to ultraviolet radiation comprising electrodes for measuring the resistivity of the water. The conductivity is monitored as a function of time and the second time derivative of the conductivity signal is monitored to indicate when the oxidation reaction has been completed. Compensation for the contribution to conductivity of the water sample made by the instrument is achieved by subtracting a quantity porportional to the first time derivative of the resistivity at a time when the second time derivative reaches zero, indicating that the oxidation reaction is complete, from the overall conductivity measurement, the remainder being equal to the contribution of conductivity made by the organic content to the water.