@article { author = {Irani Mehr, Mohammad and Riahi, Mohammad Ali and Goudarzi, Ali Reza}, title = {The effects of oscillatory behavior of the mother wavelet in the discrete wavelet transform in order to suppress seismic random noise}, journal = {Journal of the Earth and Space Physics}, volume = {45}, number = {1}, pages = {63-79}, year = {2019}, publisher = {Institute of Geophysics, University of Tehran}, issn = {2538-371X}, eissn = {2538-3906}, doi = {10.22059/jesphys.2019.263998.1007031}, abstract = {  Seismic data have a variable characteristic. Overlooking this important characteristic will reduce the effectiveness of any signal processing tool. Wavelet transform is a useful tool in seismic data processing and in recent years it has been the subject of attention of geophysicists. In this study we investigate the role of the resolution of the wavelet transform and the Q-factor (Q-factor in band-pass filters is the ratio of central frequency to the bandwidth) of the mother-wavelet on the filter performance with the goal of reducing the random noise and examining the effects of the mother wavelet Q-factor and its oscillatory behavior on the filter performance. We use Rational-Dilation Wavelet Transform (RADWT) and Dual-tree RADWT. These methods have the capability to achieve variable frequency resolution that can also provide a variety of Q-factors. To evaluate the effect of Q-factor of mother wavelet on filter function, the DT-RADWT with different Q-factors is applied on a Ricker Wavelet and synthetic shot gathers and the results are discussed in the manuscript. In the following, we investigate the relationship between seismic signal Q-factor and suitable Q-factor for seismic data processing. The method is applied to high-frequency shallow Sub-Bottom Profiler data and land data. In this study, a new wavelet transform called Rational Dilation Wavelet Transform (RADWT) and its Dual Tree analytical version DT-RADWT is used to attenuate random noise in seismic data. These transforms can achieve a limited range of Q-factor by selecting appropriate parameters p, q and s. The advantage of this transform over the common discrete wavelet transforms is that its rational sampling which provides higher time-frequency resolution. We also investigate the effect of Q-factor of mother wavelet on the performance of wavelet transform filters, and the relation between seismic signal Q-factor and Wavelet transform filter Q-factor. Increasing the Q-factor can reduce the bandwidth of wavelet in each scale. We test the effect of random noise on Q-factor of Ricker wavelet, with different noise levels. The results showed that by changing the level of random noise, the range of Q-factor remains constant. Next, we added the constant noise to Ricker wavelet, and we analyzed the noise-infected wavelet by RADWT and DT-RADWT with different Q-factors, here the soft threshold was used. The result of denoising is presented in Table 2. In last part of manuscript high Q-factor Dual Tree Rational wavelet transform was used to attenuate random noise from synthetic shot gather and marine and land seismic data (figures 9 & 11& 14& 15). Suitable parameters for random noise attenuation, p, q, and s was selected respectively 7, 8, 1 that made WT Q-factor 7.48. This research investigated the role of Q-factor value in suppressing random noise from reflection seismic data. Many Q-factors were tested to evaluate the effect of wavelet transform Q-factor on random noise denoising, and it was observed that with an increase in the Q-factor of the wavelet transform, the signal-to-ratio of filtered trace was improved. The data Q-factor was also calculated, but there was no significant correlation between the appropriate Q-factor of WT for noise reduction and the signal Q-factor. DT-RADWT was better than RADWT in distinguish was the random noise from the signal, due to the use of two parallel filter banks. DT-RADWT with high Q-factor was applied to synthetic data with a variable level of random noise and results are summarized in table4. In addition, the method was also applied to real shallow marine data from sub-bottom profiler with a wide frequency content. Results confirm the effectiveness of WT filter which is increased with the increase of wavelet transform Q-factor.}, keywords = {Random Noise,Discrete Wavelet Transform,Time-Frequency Domain,Wavelet Q-factor,Offshore Data,Rational Dilation,Dual-Tree Wavelet Transform}, title_fa = {اثر رفتار نوسانی موجک مادر در تبدیل موجک گسسته به‌منظور تضعیف نوفه لرزه‌ای تصادفی}, abstract_fa = {ابزارهای پردازش داده لرزه‌ای ویژگی‌های متنوعی دارند و چشم‌پوشی از این ویژگی‌ها اثرگذاری ابزارهای پردازش سیگنال را کاهش می‌دهد. در این تحقیق نقش تفکیک‌پذیری در تبدیل موجک و نسبت فرکانس مرکزی به پهنای باند موجک (WQ-factor) موجک مادر بر عملکرد تضعیف نوفه اتفاقی بررسی خواهد شد. در این تحقیق از نسخه دوشاخه تحلیلی تبدیل موجک اتساع گویا (DT-RADWT) به‌منظور بررسی نقش نسبت فرکانس مرکزی به پهنای باند موجک (WQ-factor) در تبدیل موجک استفاده شده است. این تبدیل‌ها می‌تواند بازه متنوعی از WQ-factor ها را فراهم کنند. برای بررسی تأثیر WQ-factor موجک مادر بر روی عملکرد تبدیل موجک DT-RADWT با WQ-factor های مختلف بر روی داده مصنوعی اعمال می‌شود، در ادامه تحقیق ارتباط بین نسبت فرکانس مرکزی به پهنای باند موجک داده و نسبت فرکانس مرکزی به پهنای باند موجک مناسب برای پردازش داده‌های لرزه‌ای بررسی می‌شود، نتایج نشان داد که نسبت فرکانس مرکزی به پهنای باند موجک نگاشت لرزه‌ای ارتباط معناداری با نسبت فرکانس مرکزی به پهنای باند موجک مناسب برای تجزیه سیگنال ندارد و ضمناً با افزایش نسبت فرکانس مرکزی به پهنای باند موجک تبدیل موجک، پردازش سیگنال بهتر صورت می‌گیرد. در قسمت بعد، این روش بر داده‌های Sub-Bottom Profiler و همچنین داده‌های خشکی استفاده شده است. نتایج DT-RADWT نشان داد که انتخاب WQ-factor بالا در تبدیل موجک، موجب کاهش بهتر نوفه تصادفی از داده لرزه‌ای خواهد شد.}, keywords_fa = {Random Noise,Discrete Wavelet Transform,Time-Frequency Domain,Wavelet Q-factor,Offshore Data,Rational Dilation,Dual-Tree Wavelet Transform}, url = {https://jesphys.ut.ac.ir/article_69152.html}, eprint = {https://jesphys.ut.ac.ir/article_69152_6aa620baed70b9c3f08c23f5c8d78745.pdf} }