1. |
Field experiment using small MT equipment(1) : Ito Campus, Kyushu University. |
2. |
Field experiment using small MT equipment(2) : Kuju highland, Oita prefecture. |
3. |
Field experiment using small MT equipment(3) : Ebino highland, Miyazaki prefecture. |
4. |
Common sense and uncommon sense in magnetotelluric method. |
5. |
Magnetic Susceptibility Inversion and Magnetic Vector Inversion: A case Study for Polymetallic Prospecting in Panjshir, Afghanistan. |
6. |
Advanced of MT exploration techniques utilizing compact and lightweight equipment (1): Summary of the project. |
7. |
Advanced of MT exploration techniques utilizing compact and lightweight equipment (1): Hardware design and prototyping. |
8. |
Advanced of MT exploration techniques utilizing compact and lightweight equipment (1): Bibliographic and questionnaire surveys. |
9. |
Advanced of MT exploration techniques utilizing compact and lightweight equipment (1): Summary of the project. |
10. |
Advanced of MT exploration techniques utilizing compact and lightweight equipment (1): Hardware design and prototyping. |
11. |
Maryadi, Hideki Mizunaga , Subsurface resistivity imaging of geothermal field by means of impedance tensor and magnetovariational data analysis, International Symposium on Earth Science and Technology 2021, 2021.11. |
12. |
Hao Chen, Hideki Mizunaga, Toshiaki Tanaka, Gang Wang, Maik Neukirch , Application of a new robust impedance estimator based on Hilbert-Huang transform for magnetotelluric method, International Symposium on Earth Science and Technology 2021, 2021.11. |
13. |
Tamer Farag, Hideki Mizunaga, 3-D interpretation of airborne gravity data at Wadi El Assuity, Egypt, International Symposium on Earth Science and Technology 2021, 2021.11. |
14. |
Kazuto Inoue, Hao Chen, Toshiaki Tanaka, Hideki Mizunaga , Example of application of a new MT time series processing method, International Symposium on Earth Science and Technology 2021, 2021.11. |
15. |
Chuichi Inoue, Mizunaga Hideki, Toshiaki Tanaka , A study on visualization of underground roots using electrical techniques, International Symposium on Earth Science and Technology 2021, 2021.11. |
16. |
Hao Chen, Hideki Mizunaga, Toshiaki Tanaka, Gyan Wang, Comparison of the bound influence estimator and the maximum likelihood estimator for magnetotelluric response function, 物理探査学会 第144回学術講演会, 2021.06. |
17. |
Abebayehu Andarge Mengiste, Hideki Mizunaga, Toshiaki Tanaka, 1-D and 2-D Inversions of Magnetotelluric Data in Butajira Geothermal Field, Ethiopia
, International Symposium on Earth Science and Technology 2020, 2020.11. |
18. |
Soichiro Hashimoto, Toshiaki Tanaka, Hideki Mizunaga, A New Techniques of Resistivity Measurement for Drilling Cores
, International Symposium on Earth Science and Technology 2020, 2020.11. |
19. |
Yushin Higashi, Toshiaki Tanaka, Hideki Mizunaga, An Experimental Study on Quad-Loop EM Method
, International Symposium on Earth Science and Technology 2020, 2020.11. |
20. |
Hao Chen, Hideki Mizunaga, Toshiaki Tanaka, Gang Wang, New strategy to calculate robust impedance using RMHHT estimator for continuous and discontinuous broadband magnetotelluric time-series data
, International Symposium on Earth Science and Technology 2020, 2020.11. |
21. |
Casula Mel Anthony Asis, Hideki Mizunaga, Toshiaki Tanaka, Torres Aniano, Subsurface Characterization using Geophysical and Hydrochemical Data: An Application to Groundwater Resources Management in Pampanga, Philippines
, International Symposium on Earth Science and Technology 2020, 2020.11. |
22. |
#Hao Chen, Hideki Mizunaga, Toshiaki Tanaka, Robust impedance estimator based on Hilbert-Huang transformation to time-series magnetotelluric data, 物理探査学会 第143回学術講演会, 2020.11. |
23. |
Tumbu Lucas Boniface, Hideki MIZUNAGA, Multi-dimensional Resistivity Imaging from Magnetotelluric Data and its Geological Interpretation in Keijo-Mbaka Geothermal Field, South-West Tanzania, International Symposium on Earth Science and Technology 2019, 2019.12. |
24. |
Yusuke KIYOMOTO, Hideki MIZUNAGA, Toshiaki TANAKA, Development of Magnetotelluric 1-D Sparse Inversion, International Symposium on Earth Science and Technology 2019, 2019.12. |
25. |
Hao CHEN, Hideki MIZUNAGA, Toshiaki TANAKA, The research on the application of Hilbert-Huang transformation to time series magnetotelluric data, International Symposium on Earth Science and Technology 2019, 2019.12. |
26. |
Mohammad SHEHATA, Hideki MIZUNAGA, An Enhanced Edge Detection Technique for Potential Field Data; Case Study of Western USA, International Symposium on Earth Science and Technology 2019, 2019.12. |
27. |
Tamer FARAG, Nehal SOLIMAN, Atef El SHAYAT, Hideki MIZUNAGA, Landsat 8 and Airborne Geophysical Data Interpretations to Investigate the Radioactivity Hazards at El Gilf El Biber Area, South Western Desert, Egypt, International Symposium on Earth Science and Technology 2019, 2019.12. |
28. |
Soichiro HASHIMOTO, Toshiaki TANAKA, Hideki MIZUNAGA, Resistivity measurement technique using capacitor electrodes, International Symposium on Earth Science and Technology 2019, 2019.12. |
29. |
Estimation of deep subsurface temperature using electromagnetic geothermometry. |
30. |
1-D Inversion of TEM Data Considering IP Effect. |
31. |
Magnetotelluric 1-D Sparse Inversion. |
32. |
#Mohammad Shehata,Hideki Mizunaga, Three Dimensional Subsurface Resistivity Imaging of the Western USA Retrieved from Magnetotelluric Inversion, 物理探査学会 第141回学術講演会, 2019.10. |
33. |
#Tamer Farag, Mohammad Shehata,Hideki Mizunaga, The Present Scenario Controoling Groundwater Resources Using Magnetic Data at Wadi El Assuity, Egypt, 物理探査学会 第141回学術講演会, 2019.10. |
34. |
Shape Reconstruction of Tunnel Tombs Using GPR. |
35. |
清元 陽介, 水永 秀樹,田中 俊昭,岩本 鐘海, レイトレーシングを用いた地中レーダの波動伝播シミュレーション, 物理探査学会 第140回学術講演会, 2019.06. |
36. |
Tumbu LUCAS, Hideki MIZUNAGA, Dimensionality and Directionality Analysis of MT Data to Geothermal Systems in Kiejo-Mbaka Geothermal Field, South-West Tanzania, 物理探査学会 第140回学術講演会, 2019.06. |
37. |
Analysis of Gamma-ray Spectrum Using Sparce Modeling in Radioactive Method. |
38. |
Sparse Inversion of Geophysical Exploration Data. |
39. |
Monitoring of Geothermal Reservoir Using Fluid Flow Electromagnetic Method. |
40. |
Natural state and production-reinjection simulation in the Ogiri geothermal reservoir. |
41. |
Mohammad SHEHATA, Hideki MIZUNAGA, Directionality and Mimensionality Analysis of USArray Magnetotelluric Data from Weatern USA, International Symposium on Earth Science and Technology 2018, 2018.11. |
42. |
Tumbu Lucus BONIFACE, Hideki MIZUNAGA, Three-dimensional Inversion of MT Data to Geothermal Systems in Kisaki Geothermal Field, Eastern Tanzania, International Symposium on Earth Science and Technology 2018, 2018.11. |
43. |
Yosuke KIYOMOTO, Hideki MIZUNAGA, Toshiaki TANAKA, Archaeological Survey for Genko Borui Using Ground Penetrating Radar, International Symposium on Earth Science and Technology 2018, 2018.11. |
44. |
Gosuke HOSHINO, Hideki MIZUNAGA, Toshiaki TANAKA, Development of a Simulator for 3-D Long-offset TEM Method, International Symposium on Earth Science and Technology 2018, 2018.11. |
45. |
Hideaki EJIMA, Hideki MIZUNAGA, Toshiaki TANAKA, Detection and Classification of Anomalies in GPR B-scan Data, International Symposium on Earth Science and Technology 2018, 2018.11. |
46. |
Shokai IWAMOTO, Hideki MIZUNAGA, Toshiaki TANAKA, GPR Survey at Kuratsukasa Erea in Dazaifu Historical Site, Fukuoka Prefecture, Japan, International Symposium on Earth Science and Technology 2018, 2018.11. |
47. |
Kazuki YAMADA, Hideki MIZUNAGA, Toshiaki TANAKA, Spectrum Analysis of Gamma Ray Data to Extract Spectrum Peaks, International Symposium on Earth Science and Technology 2018, 2018.11. |
48. |
Yusuke EGUSA, Hideki MIZUNAGA, Toshiaki TANAKA, 3-D Simulation of Square Array Resistivity Method Considering the Effects of Mixture of Soil-Cement, International Symposium on Earth Science and Technology 2018, 2018.11. |
49. |
3-D Sparse Inversion of Fluid Flow Electromagnetic Method. |
50. |
Improvement of the measurement system for fluid flow electromagnetic method. |
51. |
Ground penetrating radar for Genko Borui. |
52. |
Development of equipment for fluid flow electromagnetic method and monitoring survey of water injection. |
53. |
Effects of construction of soil-cement columns on resistivity measurement by square array resistivity method. |
54. |
GPR survey to detect Genko Borui at Hakozaki campus of Kyushu University. |
55. |
Processing of time series MT data using empirical mode decomposition. |
56. |
Ground penetrating radar survey at Dazaifu Kuratsukasa area (2). |
57. |
Removing coherent noise from magnetotelluric data using cepstrum. |
58. |
Development of an inversion program of marine TEM method using PSO. |
59. |
1D simulation of marine TEM for developing marine TEM equipment. |
60. |
Shafiqullah WAHAB, 水永 秀樹, 2-D inversion of electrical resistivity data from Aynal copper deposits, Aynak, Afghanistan, 物理探査学会 第137回学術講演会, 2017.11. |
61. |
Geothermal Reservoir Exploration in Okushiri Island Using a Mise-a-la-masse Method. |
62. |
Numerical Simulation of Fluid Flow Electromagnetic Method at Geothermal Area. |
63. |
Ground penetrating radar survey at Dazaifu Kuratsukasa area. |
64. |
Time series analysys for magnetotelluric data using cepstrum. |
65. |
Maryadi, Hideki Mizunaga, Application of artificial neural network on vertical and lateral temperature estimation based on magnetotelluric data, 物理探査学会 第136回学術講演会, 2017.06. |
66. |
Yosef Kebede, Hideki Mizunaga, Magnetotelluric exploration at Tendaho high temperature geothermal field in north east Ethiopia, 物理探査学会 第136回学術講演会, 2017.06. |
67. |
Daniel Gallagher, Hideki Mizunaga, Archaeological prospecting at Dazaifu by FDEM, 物理探査学会 第136回学術講演会, 2017.06. |
68. |
Development of a ray tracing program for seismic refraction analysis. |
69. |
Simulkation of square array resistivity method to detect subsurface layer boundaries. |
70. |
An injection monitoring test by fluid flow electromagnetic method. |
71. |
Cherkose Biruk Abera, Hideki Mizunaga, Exploration og high-enthalpy geothermal resources using magnetotelluric method - a case study of Alto-Langano geothermal field, Ethiopia, 物理探査学会 第136回学術講演会, 2017.06. |
72. |
Development of the equipment for marine MT method. |
73. |
Archaeological Prospecting in Kyusu University. |
74. |
GPR survey at Onigaura tunnel tombs and 2-D simulation. |
75. |
Development of small measurement equipment for fluid flow electromagnetic method. |
76. |
1-D modeling of TEM method in consideration of IP effect. |
77. |
Numerical simulation of fluid flow electromagnetic method for hydrothermal convection system. |
78. |
Jean d'Amour UWIDUHAYE, 水永 秀樹, SAIBI HAKIM, 2-D gravity modeling, a case study of Kinigi geothermal field, Rwanda, 物理探査学会第135回学術講演会, 2016.10. |
79. |
Sparse inversion of geophysical data using L1 norm minimization. |
80. |
GPR survey at Onigaura tunnel tombs. |
81. |
Reduction of coherent noise from MT data using independent component analysis. |
82. |
Apparent resistivity of airborne and marine TEM methods using coincident loop. |
83. |
Preliminary research of fluid flow electromagnetic method. |
84. |
Hassan MOHAMED, Hideki Mizunaga, Hakim SAIBI, Ali ABDELAZIZ, Three-dimensional Forward Modeling of Geomagnetic Data Using Hexahedral Element with an Application to Zeit Basin Area, Gulf of Suez, Egypt, International Symposium on Earth Science and Technology 2015, 2015.12. |
85. |
Kyosuke TANNO, Hideki Mizunaga, 3-D Inversion of Gravity Method Using Quantum Annealing, International Symposium on Earth Science and Technology 2015, 2015.12. |
86. |
Satoshi TANIMURA, Hideki Mizunaga, Development of One-Dimensional Inversion Program of Marine Controlled Source Electromagnetic (MCSEM) Method with Particle Swarm Optimization, International Symposium on Earth Science and Technology 2015, 2015.12. |
87. |
Keisuke IKEDA, Hideki Mizunaga, GPR survey at Funabaru Ruins in Koga City, Fukuoka Prefecture, Japan, International Symposium on Earth Science and Technology 2015, 2015.12. |
88. |
Shogo HAMADA, Hideki MIZUNAGA, Toshiaki TANAKA, Research about Measurement of Marine MT Probe's Posture, International Symposium on Earth Science and Technology 2015, 2015.12. |
89. |
Jean d'Amour UWIDUHAYE, Hideki MIZUNAGA, 3-D Simulation of Gravity Method Using Gauss-Legendre Integration, International Symposium on Earth Science and Technology 2015, 2015.12. |
90. |
Akitaka NAKAMURA, Hideki MIZUNAGA, Saline Contamination Research in Motooka Using TEM method, International Symposium on Earth Science and Technology 2015, 2015.12. |
91. |
Long-distance directional drilling technology in chemical grouting method - development of wireless orbit measurement system -. |
92. |
Development of measurement system for drilling bit position of non-open cut method. |
93. |
Three-dimensional Modeling of Airborne TEM Method. |
94. |
3-D simulation of fluid flow electromagnetic method considering subsurface fluid flow. |
95. |
3-D simulation of radiometric method. |
96. |
GPR survey at Funabaru ruins in Koga city, Fukuoka prefecture. |
97. |
3-D inversion of gravity method usingquantum annealing. |
98. |
Ground water survey for saline contamination by using TEM method. |
99. |
Ground Penetrating Radar Survey at Funabaru Tumulus. |
100. |
Weighted correlation tomography for fluid flow electromagnetic method. |
101. |
Kyoshke Tanno, Hideki Mizunaga, Three-dimensional Forward Modeling of the Gravity Exploration Using the Hexahedral Element, International Symposium on Earth Science and Technology 2014, 2014.12. |
102. |
Satoshi Tanimura, Hideki Mizunaga, Yutaka SASAKI, One-dimensional Modeling of Marine Controlled Source Electromagnetic (MCSEM) Method, International Symposium on Earth Science and Technology 2014, 2014.12. |
103. |
Kenta Kuma, Hideki Mizunaga, Toshiaki TANAKA, Three-dimensional Modeling and Inversion of Fluid Flow Electromagnetic Method, International Symposium on Earth Science and Technology 2014, 2014.12. |
104. |
Shota Kukita, Hideki Mizunaga, Three-dimensional Forward Modeling of Airborne TEM Method, International Symposium on Earth Science and Technology 2014, 2014.12. |
105. |
Measurement System of Drilling Position for MWD. |
106. |
Wireless data transmission experiments in vegetation environment for a measurement system of fluid flow electromagnetic method. |
107. |
Development of Measurement System to Detect Drilling Position. |
108. |
Three-dimensional Forward Modeling of Airborne TEM Method. |
109. |
The numerical Modeling of Fluid Flow Electromagnetic Method in 3-D Heterogeneous Structure. |
110. |
1-D Modeling of Marine CSEM Method for Methane Hydrate Exploration. |
111. |
3-D Modelig of Gravity Method Using Hexahedral Element. |
112. |
Shota Kukita, Hideki Mizunaga, Toshiaki TANAKA, 3-D Forward Modeling of Airborne TEM Method for Wide Geothermal Area, Grand renewable Energy 2014 International Conference, 2014.07. |
113. |
Kenta Kuma, Hideki Mizunaga, Toshiaki TANAKA, Three-dimensional Numerical Simulation of Fluif Flow Electromagnetic Method for Geothermal Fluid, Grand renewable Energy 2014 International Conference, 2014.07. |
114. |
Ground Penetrating Radar Survey at Ikisan-Chosizuka Tomb. |
115. |
Inversion of MT Data Using Ensemble Kalman Filter. |
116. |
Fundamental Experiments of Time-domain IP Method Considering Rectifying Characteristics. |
117. |
3-D Modeling of Gravity Gradient Using Hexahedral Element. |
118. |
Takeru Okuzawa, Hideki Mizunaga, New Algorithm to Calculate Transient Response of Time-domain IP Method, International Symposium on Earth Science and Technology 2013, 2013.12. |
119. |
Takeru Okuzawa, Toshiaki Tanaka, Hideki Mizunaga, Development of a Practical Measurement Equipment for Time-domain IP Method, International Symposium on Earth Science and Technology 2013, 2013.12. |
120. |
Kenta Kuma, Hideki Mizunaga, Three-dimensional Forward Modeling Program of Fluid Flow Electromagnetic Method, International Symposium on Earth Science and Technology 2013, 2013.12. |
121. |
Shota Kukita, Hideki Mizunaga, Field Experiment and 3-D Numerical Modeling of UXO Detection by TEM Method, International Symposium on Earth Science and Technology 2013, 2013.12. |
122. |
Shota KUKITA, Hideki Mizunaga, UXO detection using small loop TEM method, The 11th SEGJ International Symposium, 2013.11. |
123. |
Tateyuki NEGI, Hideki MIZUNAGA, Yuji MITSUHATA, Quality improvement in the magnetotelluric spectrum using multiple far remote references, The 11th SEGJ International Symposium, 2013.11. |
124. |
Development of a measurement system for time-domain IP method. |
125. |
New Calculation Method for Transient Response of Time Domain IP Method. |
126. |
1-D inversion of MT method considering IP effect. |
127. |
Development of measurement system for the fluid flow electromagnetic method using a low-power wireless sensor network. |
128. |
Three-Dimensional Inversion of Fluid Flow Electromagnetic Method. |
129. |
UXO detection by small loop TEM method. |
130. |
Ryosuke OKUMOTO, Hideki MIZUNAGA, Toshiaki TANAKA, Development of 2.5-D Modeling Software for Time-Domain IP Method, The Kick-off Seminar on ASEAN-Japan BUILD-UP Coorporative Education Program for Grobal Resource Developmentin Earth Resources Engineering, Bankog, Thailand, 11th 2013, 2013.01. |
131. |
Takeru Okuzawa, Toshiaki Tanaka, Hideki Mizunaga, Development of Measurement Equipment for Time-domain IP Method, The Kick-off Seminar on ASEAN-Japan BUILD-UP Coorporative Education Program for Grobal Resource Developmentin Earth Resources Engineering, Bankog, Thailand, 11th 2013, 2013.01. |
132. |
Development of simultaneously multipoint measurement system using wireless sensor networks for fluid flow electromagnetic method. |
133. |
Jacobian-free inversion of geophysical data. |
134. |
Tree-dimensional inversion of fluid flow electromagnetic method. |
135. |
Ground penetrating radar survey at Shinmachi megalithic dolmens. |
136. |
High-resolution cumputation of Jacobian using hyperreal number. |
137. |
Development of 2.5-D modeling program for time-domain IP method. |
138. |
Basic experiment for development of the measurement equipment for time-domain IP method. |
139. |
The Calculation Technique for Magnetotelluric Impedance Considering the Existence of Noise. |
140. |
Three dimensional magnetotelluric imaging of the source area of the 2000 Western Tottori earthquake using heterogeneous smoothness-constraint least-squares method. |
141. |
Numerical modeling of ground penetrating radar using FDTD method. |
142. |
The efficacy of SIP parameterical analysis using modefied Cole-Cole equations. |
143. |
Three dimensional magnetotelluric inversion using heterogeneous smoothness-constraint least-squares method. |
144. |
Development of multipoint measurment system for monitoring geothermal fuluid-flow behavior by fluid flow electromagnetic method. |
145. |
Basic study on numerical Hankel transform in electric and electromagnetic methods. |
146. |
Three-dimensional modeling of time-domain IP method. |
147. |
Archaeological prospecting at Antokudai ruins using ground penetrating radar. |
148. |
Ground penetrating radar survey at Iwara-Yarimizo ruin. |
149. |
2.5-D inversion of time-domain IP method. |
150. |
Improvement of the numerical Hankel transform in marine CSEM method. |
151. |
Joint Analysis of Marine MT and CSEM Data. |
152. |
2.5-D Modeling of Time-domain IP Method. |
153. |
Simulation of Fluid Flow Electromagnetic Method. |
154. |
Development of Measurement System for Geothermal Fluid Flow Monitoring by Fluid Flow Electromagnetic Method. |
155. |
Measurement and management techniques for sustainable use of geothermal development, The present and future of geophysical exploration . |
156. |
Study on hydrogeological structure around the Mizunami Underground Research Laboratory (MIU) site using self-potential method. |
157. |
GPR survey at Antokudai ruins. |
158. |
New method to estimate IP parameters using modified Cole-Cole equation. |
159. |
2.5-D modeling of time-domain IP method. |
160. |
Improvement of a small MT equipment for monitoring survey. |
161. |
Development of Measurement System for Fluid Flow Electromagnetic Method. |
162. |
Development of Measurement System for Fluid Flow Electromagnetic Method. |
163. |
High-precision Computation of Hankel Transform Using Continuous Euler Transformation. |
164. |
Development of a Small MT Equipment for Monitoring Survey . |
165. |
Development of Analysis Program for TEM Method . |
166. |
Development of Small Measuring Equipment for Electromagnetic Method. |
167. |
Forward and Inverse Modelings of SIP Data for Mineral Discrimination. |
168. |
Three-dimensional FDTD analysis of Ground Penetrating Radar. |
169. |
An oil leak detection system for marine hose using electrical resistivity method . |
170. |
Sensitivity study of marine MT method . |
171. |
Three-dimensional modeling of electromagnetic method . |
172. |
Estimation of Cole-Cole parameters from time-domain IP data . |
173. |
Archaeological prospecting at Iwara-Yarimizo site using GPR (2). |
174. |
Simulation of methane hydrate using marine resistivity method. |
175. |
Fluid flow tomography survey at Yamakawa geothermal area. |
176. |
Experimental study of UXO detection using electromagnetic method. |
177. |
Archaeological prospecting at Iwara-Yarimizo site using GPR. |
178. |
The education and human resource development for earth resources in Kyushu university. |
179. |
Development of measurement system for Fluid Flow Electromagnetic method - Vevelopment of dynamic active filter -. |
180. |
Development of measurement system for Fluid Flow Electromagnetic method - Experimantal production of portable triaxial megnetometer -. |
181. |
Characteristics of small-loop EM. |
182. |
Forward modeling of SIP ddata for mineral discrimination. |
183. |
Test Experiment of Fluid Flow Electromagnetic Method. |
184. |
Development of high accuracy marine electrical prospecting system. |
185. |
Archaeological Prospecting at Ito Campus of Kyushu University. |
186. |
Numerical analysis of SP data using immune algorithm. |
187. |
Study on Quantative Relationship between Injected Fluid and Streaming Potential Using Rock Core Samples. |
188. |
Modeling of streaming potentials using TOUGHT2 output. |
189. |
Study on quantative relationship between injected fluid and streaming potential using rock core samples. |
190. |
Tree-dimensional inversion of mise-a-la-masse method using correlation tomography. |
191. |
A new approach to extract electrical responces from measured potential waveform (Part 2). |
192. |
Detection of buried pipes using pole-dipole mrthod. |
193. |
Groundwater exploration by GPR using low-frequency antenna. |
194. |
Identification of buried object by electromagnetic method. |
195. |
Three-dimensional resistivity imaging of keyhole shaped mounded tomb. |
196. |
Development of a real-time monitoring sustem by 4-D geoelectrical techniques Part 5: Field experiment of ER tomography using current sources in a cased borehole. |
197. |
Development of a real-time monitoring sustem by 4-D geoelectrical techniques Part 4: Real-scale experiment of the FFM measurment system. |
198. |
Reservoir Monitoring by 4-D Geophysics. |
199. |
Reservoir Monitoring by 4-D Geophysics. |
200. |
Development of a real-time monitoring sustem by 4-D geoelectrical techniques Part 3: Measurment of current density along a casing electrode. |
201. |
Development of a real-time monitoring sustem by 4-D geoelectrical techniques Part 2: Software development of mise-a-la-masse method. |
202. |
Development of a real-time monitoring sustem by 4-D geoelectrical techniques Part 1: Hardware (FFM-logger) development. |
203. |
Mine exploration by electrical resistivity survey. |
204. |
3D survey of underground water by TEM method. |
205. |
Development of magnetometer using magneto-impedance sensor. |
206. |
Simulation of IP effect for the mise-a-la-masse method. |
207. |
Archaeological exploration of Imajuku-Otsuka Kofun by seismic tomography. |
208. |
Electromagnetic exploration of buried object using GEM=3. |
209. |
Self-potential data Analysis by Charge Occurrence Probability Tomography. |
210. |
Three-dimensional Inversion of Self Potential Method. |
211. |
Imaging Fluid-Flow by 4-D Geoelectrical Techniques. |
212. |
TEM survey for soil and groundwater contamination. |
213. |
Study on detecting buried objects using airborne TEM. |
214. |
Archaelogical Survey at Muromachi Ruin using GPR. |
215. |
3-D imaging of Mounded Tomb using seismic Tomography. |
216. |
Electrical Resistivity Survey at Waste Disposal Site. |
217. |
Magnetotelluric Survey in Takigami Geothermal Field. |
218. |
Data analysis of apparent resistivity profile using dconvolution filter . |
219. |
Experimental research of detecting buried objects using airborne TEM. |
220. |
Three-dimensional imaging of shallow subsurface imaging using electrical resisitivity method. |
221. |
Reservoir Monitoring by a 4-D Geoelectrical Prospecting. |
222. |
Three-dimensional analysis of Fluid Flow Tomography data. |
223. |
Three-dimensional imaging of internal structure of ancient mounded tomb. |
224. |
UXO detection system using blimps and removal of mines. |
225. |
Three-dimensonal resistivity inversion using Schlumberger data. |
226. |
Three-dimensonal inversion of the mise-a-la-masse method. |
227. |
Groundwater survey at Motooka area in Fukuoka. |
228. |
Data analysis of three-dimensional resistivity survey. |
229. |
Seismic refraction survey at Iwabaru-Furagozuka Kofun. |
230. |
Archaeological survey at Mizukiato in Dazaifu. |
231. |
Ground penetrating radar survey for keyhole-shaped mounded tomb. |
232. |
Development of mine and UXO detecting system using blimps. |
233. |
Fluid flow tomography at Onuma geothermal field. |
234. |
Fluid flow tomography survey in Mori geothermal field. |
235. |
Fluid flow tomography survey for geothermal reservoirs in Sumikawa geothermal field, Akita, Japan. |
236. |
Fluid Flow Tomography Survey for Geothermal Reservoirs in Sumikawa Geothermal Field, Akita, Japan. |
237. |
3D modeling of magnetotelluric soundings. |
238. |
Monitoring of groundwater contamination by transient electromagnetic method. |
239. |
Three-dimensional inversion of vertical electric soundings. |
240. |
Analysis of Fluid Flow Tomography Data. |
241. |
Mine detection system using blimps. |
242. |
Three-dimensional inversion of Schlumberger VES data. |
243. |
Joint inversion of TEM and MT data. |
244. |
Study on SP Tomography. |
245. |
Probability tomography od SP method. |
246. |
Geophysical explorations for archaeological ruins. |
247. |
Electrical prospecting for a keyhole-shaped mounded tomb. |
248. |
Monitoring of groundwater aquifer by vertical electric soundings. |
249. |
Three-dimensional EM modeling in the Laplace domain. |
250. |
Fluid Flow Imaging by Fluid Flow Tomography Method. |
251. |
Imaging of Gold Deposit by Vertical Electric Sounding Method . |
252. |
Imaging of fractures by electrical methods. |
253. |
Three Dimensional Electromagnetic Methods for the Deep Structure Exploration. |
254. |
A Study on Electroseismic Prospecting. |
255. |
Keisuke USHIJIMA, Hideki MIZUNAGA, Chika SAKAMOTO, 3D Imaging of Monumental Tombs Buried in Keyhole-shaped Tumuli by Electrical Prospecting, Second International Conference on Archaeological Prospection 1997, 1997.09. |
256. |
Archaeological prospecting using electrical resistivity method - Case history of Kaibukiyama ancient tomb -. |
257. |
Groundwater exploration by self-potential method. |
258. |
Data processing for the fluid flow tomography method. |
259. |
2D inversion of MT data. |
260. |
Fluid Flow Monitoring by Electrical Prospecting. |
261. |
Fracuture Detection by Spontaneous Polarization Logs. |
262. |
Ogachi project for Hot Dry Rock Geothermal Power (6) - Reservoir Evaluation by AE and VEP Measurements -. |
263. |
Tree-dimensional inversion of the Mise-a-la-masse Data. |
264. |
Monitoring of EOR operations by electrical prospecting (II). |
265. |
Monitoring of EOR・IOR operations by electrical prospecting. |
266. |
Data processing for the mise-a-la-masse survey. |
267. |
Three-dimensional mise-a-la-masse modeling using horizontal well. |
268. |
Inversion interpretation of the mise-a-la-masse data. |
269. |
Archaeological prospecting by DEF method. |
270. |
Erectrical resistivity survey for archaeological tombs. |
271. |
Monitoring of EPR operations by electrical prospecting. |
272. |
Ogachi Project for Hot Dry Rock Geothermal Power (5) - AE and VEP measurements During Water Injection and Fracturing Tests -. |
273. |
Monitoring of EOR Operations by Electrical Prospecting. |
274. |
Three-dimensional Analysis of the Mise-a-la-masse Data. |
275. |
Interpretation of Schlumberger VES Data in Hatchobaru Area. |
276. |
Groundwater exploration in MK area. |
277. |
Three-dimensional inversion of self potensial data. |
278. |
Electrical prospecting in Iwatoyama ancient tomb, Yame, Fukuoka. |
279. |
Fracture evaluation by electrical prospecting. |
280. |
Hideshi KAIEDA, Yasuhiro Fujimitsu, Takeshi YAMAMOTO, Hideki MIZUNAGA, Keisuke USHIJIMA, Shunji SASAKI, AE and Mise-a-la-masse Measurements during a 22-day Water Circulation Test at Ogachi HDR site, Japan, World Geothermal Congress, 1995, 1995.05. |
281. |
3D numerical modeling for mise-a-la-masse method. |
282. |
Fluid flow imaging of the Earth's interior by electrical prospecting - Three dimensional modeling of SP data - . |
283. |
Vertical erectric sounding at Motooka and Kuwabara areas in Fukuoka city. |
284. |
Archaeometry by Electrical Prospecting - Measurements of Electrical Fields -. |
285. |
Fluid Flow Monitoring by Electrical Prospecting - Three Dimensional Inversion of SP Data -. |