Author_Institution :
Honeywell Marine Syst. Oper., Northwest Seattle, WA, USA
Abstract :
Requirements for control and data acquisition from remote subsea wellheads are expected to grow during the 1980s. In this paper, the implementation of an \´underwater acoustic approach is developed, together with the companion problems-achieving hardware reliability and low power consumption. A companion paper, "MFSK-The Basis for Robust Acoustical Communications," outlines a technique for achieving reliable acoustical communications. The goals that were set included long-range communications, up to 10 kiloyards; dependable communications, 99-percent correct messages under worst-case noise and multipath; secure communications, probability of an undetected error of less than 1 by 10 ; high reliability, 95-percent probability of successful operation for 5 years; and operation from a practical-sized battery pack. Using acoustical communications hardware together with a microprocessor, a theme of total subsea control capability is developed. Practical examples include sequential hydraulic control with acoustical data acquisition and backup control, as well as electro-hydraulic multiplex BOP control with acoustic backup.
Keywords :
data acquisition; frequency shift keying; microprocessor chips; underwater acoustic communication; MFSK acoustical communication system; acoustic backup; acoustical communication hardware; acoustical data acquisition; backup control; electrohydraulic multiplex BOP control; long-range communication; microprocessor; problems-achieving hardware reliability; reliable acoustical communications; remote subsea wellheads; secure communication; sequential hydraulic control; subsea control capability; underwater acoustic; Acoustic applications; Batteries; Communication system control; Data acquisition; Energy consumption; Error correction; Hardware; Noise robustness; Power system reliability; Underwater acoustics;
