Abstract
Data telemetry is a critical element of successful unconventional well drilling operations, involving the transmission of information about the well-surrounding geology to the surface in real-time to serve as the basis for geosteering and well planning. However, the data extraction and code recovery (demodulation) process can be a complicated system due to the non-linear and time-varying characteristics of high amplitude surface noise. In this work, a novel model fuzzy wavelet neural network (FWNN) that combines the advantages of the sigmoidal logistic function, fuzzy logic, a neural network, and wavelet transform was established for the prediction of the transmitted signal code from borehole to surface with effluent quality. Moreover, the complete workflow involved the pre-processing of the dataset via an adaptive processing technique before training the network and a logistic response algorithm for acquiring the optimal parameters for the prediction of signal codes. A data reduction and subtractive scheme are employed as a pre-processing technique to better characterize the signals as eight attributes and, ultimately, reduce the computation cost. Furthermore, the frequency-time characteristics of the predicted signal are controlled by selecting an appropriate number of wavelet bases “N” and the pre-selected range for pij3 to be used prior to the training of the FWNN system. The results, leading to the prediction of the BPSK characteristics, indicate that the pre-selection of the N value and pij3 range provides a significantly accurate prediction. We validate its prediction on both synthetic and pseudo-synthetic datasets. The results indicated that the fuzzy wavelet neural network with logistic response had a high operation speed and good quality prediction, and the correspondingly trained model was more advantageous than the traditional backward propagation network in prediction accuracy. The proposed model can be used for analyzing signals with a signal-to-noise ratio lower than 1 dB effectively, which plays an important role in the electromagnetic telemetry system.
Highlights
Over the past decade, the bi-directional transmission of data from bottom hole assembly (BHA) to the rig floor through electromagnetic signals has been identified as an effective tool for real-time data transmission with an increasing focus on the horizontal drilling of unconventional reservoirs
New developments in EM telemetry have been more focused on increasing the telemetry signal strength via improvements in technology and modes of acquisition/acquisition design, with fewer reports on data processing and transmitted signal demodulation
Working out an effective method of removing the extremely low-frequency electromagnetic (ELF-EM) in-band noise has become key to the transmission of electromagnetic telemetry measurement while drilling (EM MWD)
Summary
The bi-directional transmission of data from bottom hole assembly (BHA) to the rig floor through electromagnetic signals has been identified as an effective tool for real-time data transmission with an increasing focus on the horizontal drilling of unconventional reservoirs. Telluric and near-surface noise interference from field operations are of major concern and, affects decoding accuracy To solve this challenge, new developments in EM telemetry have been more focused on increasing the telemetry signal strength via improvements in technology and modes of acquisition/acquisition design, with fewer reports on data processing and transmitted signal demodulation. White [11] focused primarily on adapting the characteristics of the transmitted signal to improve the bit error rate This is done by adaptively changing the transmission frequency of the BPSK-coded signals to address the problem of EM detection in the presence of non-stationary noise. With the aim of increasing the effective operational depth of EM telemetry, we introduce fuzzy wavelet neural network (FWNN) techniques as a highly effective tool to develop an ANN model that can be used for the best prediction in EMT signal demodulation.
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