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"ABSTRAKPresenting seismic data in probability form is common practice in order to assess the uncertainty in hydrocarbon prospecting. It gives interpreters the ability to measure how sure they are about prospect they dealing with by looking at most probable value. In another side pre-stack data is now commonly available; it changes the paradigm about seismic inversion from just post-stack inversion turn into pre-stack inversion. The reason is obvious, by inverting pre-stack data will allow interpreter to obtain not only lithology information but fluid as well.The Bayes’ Rule is extension of conditional probability, it has been utilizes in many disciplines such us remote sensing, broadcasting, marketing and medical science to support in decision making. Bayes’ Rule is used to revise a probability value based on additional information that is later obtained. The same concept can also be applied to help decision making in hydrocarbon prospect evaluation where the output of pre-stack inversion can be transformed to probability volume supervised by well log data.This study uses P-Impedance and VP/VS as inputs because their combination is good indicator of lithology and hydrocarbon. Using Menampilkan data seismic dalam bentuk probabilitas merupakan cara yang umum dilakukan untuk mengikutsertakan informasi ketidak-pastian dari pekerjaan pemetaan prospek hidrokarbon. Hal tersebut memberikan interpreter peluang untuk mengukur seberapa yakin mereka terhadap prospek yang sudah dibuat dengan memanfaatkan informasi nilai “most-probable”. Pada sisi lain, ketersediaan pre-stack data sudah sangat umum dijumpai sehingga hal ini merubah cara pandang terhadap inversi seismic yang semula hanya dilakukan terhadap data post-stack menjadi inversi pre-stack. Hal tersebut memang beralasan karena dengan inversi pre-stack, interpreter tidak hanya dimungkinkan mendapatkan informasi litologi namun juga informasi tentang fluida.Aturan Bayes adalah merupakan bentuk lain dari probabilitas terkondisi, aturan ini telah banyak dimanfaatkan oleh berbagai disiplin ilmu seperti penginderaan jauh, peramalan cuaca, pemasaran dan ilmu medis untuk membantu dalam meminimalkan resiko saat pengambilan keputusan. Hal yang sama juga bias kita terapkan pada bidang ilmu bumi dimana keluaran dari proses inversi pre-stack dapat ditransformasi menjadi bentuk volum probabilitas dengan supervisi data sumuran.Penelitian ini menggunakan P-impedance dan VP/VS sebagai input karena kombinasi keduanya merupakan indikator yang baik untuk memisahkan litologi maupun hidrokarbon. Dengan menggunakan supervisi dari data sumuran kedua volume tersebut kemudian di transformasi menjadi bentuk kelas most-probable: (1) shale, (2) wet sand, (3) compacted sand, dan (4) hydrocarbon sand.

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ABSTRACTPresenting seismic data in probability form is common practice in order to assess the uncertainty in hydrocarbon prospecting. It gives interpreters the ability to measure how sure they are about prospect they dealing with by looking at most probable value. In another side pre-stack data is now commonly available; it changes the paradigm about seismic inversion from just post-stack inversion turn into pre-stack inversion. The reason is obvious, by inverting pre-stack data will allow interpreter to obtain not only lithology information but fluid as well.The Bayes’ Rule is extension of conditional probability, it has been utilizes in many disciplines such us remote sensing, broadcasting, marketing and medical science to support in decision making. Bayes’ Rule is used to revise a probability value based on additional information that is later obtained. The same concept can also be applied to help decision making in hydrocarbon prospect evaluation where the output of pre-stack inversion can be transformed to probability volume supervised by well log data.This study uses P-Impedance and VP/VS as inputs because their combination is good indicator of lithology and hydrocarbon. Using training set from well log the volumes then transformed into four most probable classes: (1) shale, (2) wet sand, (3) compacted sand, and (4) hydrocarbon sand."

"[ABSTRAKMenampilkan data seismic dalam bentuk probabilitas merupakan cara yang umum dilakukan untuk mengikutsertakan informasi ketidak-pastian dari pekerjaan pemetaan prospek hidrokarbon. Hal tersebut memberikan interpreter peluang untuk mengukur seberapa yakin mereka terhadap prospek yang sudah dibuat dengan memanfaatkan informasi nilai ?most-probable?. Pada sisi lain, ketersediaan pre-stack data sudah sangat umum dijumpai sehingga hal ini merubah cara pandang terhadap inversi seismic yang semula hanya dilakukan terhadap data post-stack menjadi inversi pre-stack. Hal tersebut memang beralasan karena dengan inversi pre-stack, interpreter tidak hanya dimungkinkan mendapatkan informasi litologi namun juga informasi tentang fluida.Aturan Bayes adalah merupakan bentuk lain dari probabilitas terkondisi, aturan ini telah banyak dimanfaatkan oleh berbagai disiplin ilmu seperti penginderaan jauh, peramalan cuaca, pemasaran dan ilmu medis untuk membantu dalam meminimalkan resiko saat pengambilan keputusan. Hal yang sama juga bias kita terapkan pada bidang ilmu bumi dimana keluaran dari proses inversi pre-stack dapat ditransformasi menjadi bentuk volum probabilitas dengan supervisi data sumuran.Penelitian ini menggunakan P-impedance dan VP/VS sebagai input karena kombinasi keduanya merupakan indikator yang baik untuk memisahkan litologi maupun hidrokarbon. Dengan menggunakan supervisi dari data sumuran kedua volume tersebut kemudian di transformasi menjadi bentuk kelas most-probable: (1) shale, (2) wet sand, (3) compacted sand, dan (4) hydrocarbon sand.

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ABSTRACTPresenting seismic data in probability form is common practice in order to assess the uncertainty in hydrocarbon prospecting. It gives interpreters the ability to measure how sure they are about prospect they dealing with by looking at most probable value. In another side pre-stack data is now commonly available; it changes the paradigm about seismic inversion from just post-stack inversion turn into pre-stack inversion. The reason is obvious, by inverting pre-stack data will allow interpreter to obtain not only lithology information but fluid as well.The Bayes? Rule is extension of conditional probability, it has been utilizes in many disciplines such us remote sensing, broadcasting, marketing and medical science to support in decision making. Bayes? Rule is used to revise a probability value based on additional information that is later obtained. The same concept can also be applied to help decision making in hydrocarbon prospect evaluation where the output of pre-stack inversion can be transformed to probability volume supervised by well log data.This study uses P-Impedance and VP/VS as inputs because their combination is good indicator of lithology and hydrocarbon. Using training set from well log the volumes then transformed into four most probable classes: (1) shale, (2) wet sand, (3) compacted sand, and (4) hydrocarbon sand.;Presenting seismic data in probability form is common practice in order to assess the uncertainty in hydrocarbon prospecting. It gives interpreters the ability to measure how sure they are about prospect they dealing with by looking at most probable value. In another side pre-stack data is now commonly available; it changes the paradigm about seismic inversion from just post-stack inversion turn into pre-stack inversion. The reason is obvious, by inverting pre-stack data will allow interpreter to obtain not only lithology information but fluid as well.The Bayes? Rule is extension of conditional probability, it has been utilizes in many disciplines such us remote sensing, broadcasting, marketing and medical science to support in decision making. Bayes? Rule is used to revise a probability value based on additional information that is later obtained. The same concept can also be applied to help decision making in hydrocarbon prospect evaluation where the output of pre-stack inversion can be transformed to probability volume supervised by well log data.This study uses P-Impedance and VP/VS as inputs because their combination is good indicator of lithology and hydrocarbon. Using training set from well log the volumes then transformed into four most probable classes: (1) shale, (2) wet sand, (3) compacted sand, and (4) hydrocarbon sand.;Presenting seismic data in probability form is common practice in order to assess the uncertainty in hydrocarbon prospecting. It gives interpreters the ability to measure how sure they are about prospect they dealing with by looking at most probable value. In another side pre-stack data is now commonly available; it changes the paradigm about seismic inversion from just post-stack inversion turn into pre-stack inversion. The reason is obvious, by inverting pre-stack data will allow interpreter to obtain not only lithology information but fluid as well.The Bayes? Rule is extension of conditional probability, it has been utilizes in many disciplines such us remote sensing, broadcasting, marketing and medical science to support in decision making. Bayes? Rule is used to revise a probability value based on additional information that is later obtained. The same concept can also be applied to help decision making in hydrocarbon prospect evaluation where the output of pre-stack inversion can be transformed to probability volume supervised by well log data.This study uses P-Impedance and VP/VS as inputs because their combination is good indicator of lithology and hydrocarbon. Using training set from well log the volumes then transformed into four most probable classes: (1) shale, (2) wet sand, (3) compacted sand, and (4) hydrocarbon sand.;Presenting seismic data in probability form is common practice in order to assess the uncertainty in hydrocarbon prospecting. It gives interpreters the ability to measure how sure they are about prospect they dealing with by looking at most probable value. In another side pre-stack data is now commonly available; it changes the paradigm about seismic inversion from just post-stack inversion turn into pre-stack inversion. The reason is obvious, by inverting pre-stack data will allow interpreter to obtain not only lithology information but fluid as well.The Bayes? Rule is extension of conditional probability, it has been utilizes in many disciplines such us remote sensing, broadcasting, marketing and medical science to support in decision making. Bayes? Rule is used to revise a probability value based on additional information that is later obtained. The same concept can also be applied to help decision making in hydrocarbon prospect evaluation where the output of pre-stack inversion can be transformed to probability volume supervised by well log data.This study uses P-Impedance and VP/VS as inputs because their combination is good indicator of lithology and hydrocarbon. Using training set from well log the volumes then transformed into four most probable classes: (1) shale, (2) wet sand, (3) compacted sand, and (4) hydrocarbon sand., Presenting seismic data in probability form is common practice in order to assess the uncertainty in hydrocarbon prospecting. It gives interpreters the ability to measure how sure they are about prospect they dealing with by looking at most probable value. In another side pre-stack data is now commonly available; it changes the paradigm about seismic inversion from just post-stack inversion turn into pre-stack inversion. The reason is obvious, by inverting pre-stack data will allow interpreter to obtain not only lithology information but fluid as well.The Bayes’ Rule is extension of conditional probability, it has been utilizes in many disciplines such us remote sensing, broadcasting, marketing and medical science to support in decision making. Bayes’ Rule is used to revise a probability value based on additional information that is later obtained. The same concept can also be applied to help decision making in hydrocarbon prospect evaluation where the output of pre-stack inversion can be transformed to probability volume supervised by well log data.This study uses P-Impedance and VP/VS as inputs because their combination is good indicator of lithology and hydrocarbon. Using training set from well log the volumes then transformed into four most probable classes: (1) shale, (2) wet sand, (3) compacted sand, and (4) hydrocarbon sand.]"

"ABSTRAKTarget utama dari pengembangan lapangan minyak di daerah X adalah untuk dapat meningkatkan produksi melalui penempatan lokasi sumur yang memiliki reservoir minyak yang besar. Untuk reservoir karbonat fracture metodologi analisis dilakukan secara terintegrasi dengan menggunakan data sumur dan data 3D seismik. Metoda prestack seismik anisotropi dilakukan untuk mengkarakterisasi fracture di daerah karbonat fracture. Analisa data sumur dilakukan untuk mendapatkan hubungan antara intensitas fracture dengan seismik anisotropi AVAZ (amplitude versus azimuth). Proses geofisika dilakukan untuk mendapatkan 3D cube AVAZ adalah meliputi pembuatan azimuthal stack dan perhitungan efek anisotropi.Batuan karbonat bersifat heterogen akan tetapi fracture pada batuan karbonat mempunyai arah tertentu, arah fracture dan intensitas fracture inilah yang akan diteliti dan kemudian dilokalisir untuk mendapatkan lokasi pemboran. Untuk batuan karbonat di sumur X, AVO response untuk penjalaran gelombang P yang sejajar dengan fracture akan berbeda dengan amplitude gelombang jika penjalaran tegak lurus pada arah fracture, perbandingan response amplitude inilah yang menentukan derajat anisotropi. Semakin besar anisotropi maka akan menunjukan semakin banyaknya fracture yang akan didapatkan. Pada penelitian ini akan lebih banyak melakukan integrasi umum data geologi, geofisika dan reservoir bersifat riset aplikasi dengan menggunakan software yang tersedia.

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ABSTRACT

The main purpose of the expanded ground oil in area X is to increase the production through the allocation of the well that contains massive amount of oil reservoir. In order to analyze the carbonate Fracture reservoir, an analysis of methodology is applied collectively by using the well data and 3D seismic data. Pre-Stack Seismic Anisotropy method is used to determine the characterization of fracture in the carbonate fracture areas. The analysis of well data is calculated to get the relations between fracture intensity and seismic anisotropy AVAZ (amplitude vs. azimuth). Geophysics process is done to get 3D cube AVAZ, which involved the construction of azimuthal stack and the calculation effect of anisotropi. Naturally carbonate rock is said to be heterogeneous, however, fracture in carbonate rock has its own direction, fracture direction and fracture intensity will be observed and localized to get the drilling‟s location. For the carbonate rock in well X, AVO response for the spreading of P wave that is parallel with the fracture will be different with the amplitude wave when the spreading is vertical at the directions of fracture, this comparison of amplitude response will observed the scale or level of anisotropy . The greater scale of anisotropy will show more fracture being found. In this research will focus more on doing the general integration data on geology, geophysics and reservoir, having the quality of application research by using available software."

"Metode P-Z Summation merupakan salah satu metode yang baik untuk meminimalisir ghost dan multiple reflection pada perekaman data seismik di zona Ocean Bottom Cable (OBC). Cara kerja metode ini dengan mengkombinasikan data P dari hydrophone dengan data Z dari geophone untuk menghilangkan multiple yang memiliki sifat polaritas berlawanan pada wavelet seismik P dan Z. Penggabungan data tersebut juga akan meningkatan resolusi penampang seismik pada zona target seiring dengan hilangnya ghost serta multiple pada data. Untuk studi lebih lanjut, maka dilakukanlah pengamatan mengenai metode P-Z Summation pada data pre-stack serta data post stack untuk mengetahui hasil dan proses yang lebih optimal pada pengolahan data seismik OBC. Dimana data pre-stack merupakan data yang belum mengalami Zero Offset dan data post stack merupakan data yang sudah mengalami Zero Offset serta penggabungan trace. Dari hasil studi dengam menggunakan 2 metode tersebut digunakan nilai ACF (Auto Correlation Function) sebagai pembanding, yakni ACF 250 dengan ACF 1000 pada data pre-stack dan post stack yang digunakan, didapat hasil deghosting yang berbeda pada resolusi penampang akhirnya. Pada hasil akhir pre-stack ACF 250 masih terlihat multiple reflection pada Two Way Time (TWT) 1500-2000 ms, sedangkan pada hasil akhir pre stack ACF 1000 multiple sudah mulai menghilang pada TWT 1500-2000 ms. Kemudian, pada hasil akhir penampang seismik post stack ACF 250 terdapat multiple yang masih telihat pada TWT 500-1000 ms. Dan seismik post stack ACF 1000 mengalami pelemahan multiple pada TWT 500-1000 ms dan mengalami peningkatan resolusi pada zona target di TWT 1000-1500ms.

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PZ summation method is a good method to minimize multiple reflections in the seismic data recording in the zone of Ocean Bottom Cable (OBC). This method works by combining the P data from the hydrophones with the Z data from the geophones to eliminate ghost and multiple properties that have opposite polarity on P and Z seismic wavelet. The incorporation of these data will also increase seismic resolution on the target zone due to the loss of multiple. For further study, we conducted extensive observations of P-Z summation method on the pre-stack and post-stack data to determine and enhance the outcome of OBC seismic data processing. As we know, the pre-stack data is the data that has not been changed to the Zero Offset and post stack data is the data that has undergone to the Zero Offset.

From the results of studies using two method, the comparison of those two types of data is using ACF (Auto Correlation Function) values, ACF 250 with ACF 1000 using pre - stack and post- stack data, the different results obtained in the deghosting eventually cross section resolution. At the end of the pre - stack results ACF 250 still seen multiple reflection on Two Way Time ( TWT ) from 1500 to 2000 ms, while the end result of pre stack multiple ACF 1000 have started to disappear in the 1500-2000 ms TWT. Then, on the final results of post stack seismic ACF 250 there are still multiple seemingly at 500-1000 ms TWT. And post-stack seismic weakened multiple ACF 1000 at 500-1000 ms TWT and increase the resolution of the target zone at 1000- 1500ms TWT."

"ABSTRAK

Integrasi pemodelan isi fluida dan analisis seismik AVO untuk memetakan reservoar gas Globigerina limestone melalui simultaneous pre stack inversion telah dilakukan pada Cekungan Jawa Timur, Selat Madura. Penelitian ini memanfaatkan pemodelan ke belakang atau lebih dikenal sebagai inversion modelling. Tujuan dari penelitian ini adalah untuk menggambarkan penyebaran reservoar gas dari Globigerina limestone sehingga hasil analisis kuantitatifnya dapat dijadikan sebagai rujukan didalam pemboran sumur berikutnya. Penelitian diawali dengan pembuatan low frequency model yang optimum yaitu dengan mengintegrasikan pemodelan isi fluida dan analisis seismik AVO. Integrasi keduanya diperlukan mengingat target penelitian banyak terpengaruh oleh zona gas dangkal yang mengakibatkan terdistorsinya puncak dan dasar dari struktur reservoar targetnya. Data penelitian terdiri dari data seismik tiga dimensi (3D) seluas 320km² dengan kerapatan bin size 18.75m x 12.5m disertai dengan dua data sumur. Hasil dari crossplot menunjukan bahwa litologi target reservoar dapat dibedakan dengan litologi non reservoar melalui log Vp dan Vs. Hasil dari crossplot antara impedansi P dan Vp/Vs dapat menunjukkan bagaimana kualitas reservoar gas pada struktur F dan struktur H. Nilai cut-off pada crossplot utama yaitu antara impedansi P dan Vp/Vs adalah sebesar 2.400 - 5.500 gr/cc*m/s dan 2,0 - 2,1 pada rasio cepat rambat gelombang. Hasil dari optimasi low frequency model menunjukkan bahwa pada struktur G, yang merupakan target pemboran berikutnya, respon impedansi P dan Vp/Vs nya analog terhadap kedua struktur F dan H. Hal ini menunjukkan bahwa melalui integrasi pemodelan isi fluida dan analisis seismik AVO, low frequency model dapat dioptimasikan sehingga metode simultaneous seismic inversion mampu memetakan zona-zona reservoar gas lainnya.

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ABSTRACT

Integration of fluid replacement modelling and seismic AVO analysis towards simultaneous seismic inversion had been done to delineate the distribution of Globigerina limestone gas reservoir in Madura Strait, East Java Basin. This study was using backward modelling or well known as inversion modelling to finish the quantitative analysis. The purpose of the study is to map the distribution of Globigerina limestone gas reservoir so that in the end the final result will be used as a guidance to drill the next exploration well. It started with an optimized low frequency model building by integrating fluid replacement modelling and seismic AVO analysis. By integrating these two methods, the distorted reservoir top structure and bottom can be compensated and the low frequency model will be optimized. The availability of the data includes 3D seismic data with acquisition bin size 18.75m x 12.5m, area of 320km², with two well logs. The crossplot result showed that the reservoir and non-reservoir lithology can be distinguished by Vp and Vs log. By analysing the acoustic impedance together with Vp/Vs, the character of gas reservoir at surrounding F and H structures can also be delineated. The main cutoff for acoustic impedance and Vp/Vs were 2,400 - 5,500 gr/cc*m/s and 2.0 - 2.1. The final optimizing result of low frequency model showed that the target G structure, which will be the next exploration target, showed an analogue response with its neighbour F and H structures. It is concluded that by integrating both two methods, fluid replacement modelling and AVO seismic analysis, the optimizing of low frequency model can be achieved and the simultaneous seismic inversion can successfully map other gas reservoir.

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