Titan atmosphere profiles from Huygens engineering (temperature and acceleration) sensors

Data from several Huygens probe housekeeping sensors (an engineering accelerometer and housekeeping temperature sensors) are studied to determine how effectively such nonideal instruments may characterize the density or temperature structure of the atmosphere. While only confirming the results of the dedicated atmospheric structure instrument, this exercise is of relevance to possible future missions to various bodies which might not be equipped with such science-grade sensors able to accurately profile the atmosphere top-to-bottom. It is found that for typical engineering accelerometers with 8-bit resolution, the atmosphere density for ∼4 scale heights above the peak deceleration altitude may be recovered. If, as with Huygens, the peak deceleration exceeds the range of the accelerometers, recovery of an additional scale height or so below the peak is still possible, but relies on accurate total velocity knowledge. Engineering temperature sensors can, with care, be analyzed to recover the temperature structure of at least the lowest ∼30 km of Titanʹs atmosphere. Fortunately, in the case of Huygens, data from the surface after landing were available to constrain models of heat leaks which offset the observed temperature from that of the ambient air during descent; data from before and during the entry phase on other missions would be similarly useful. When corrections are made for the estimated heat transfer processes, the atmospheric temperature can be recovered to within about 3 K.