| 臺大學術典藏 |
2020-02-27T06:39:54Z |
Power intensity patterns of an annular array ultrasound transducer used in intracavitary hyperthermia
|
Lin W.-L.;Cehn Y.-Y.;Yen J.-Y.;Ming-Jium Shieh;Chang C.-J.; Lin W.-L.; Cehn Y.-Y.; Yen J.-Y.; MING-JIUM SHIEH; Chang C.-J. |
| 臺大學術典藏 |
2020-02-27T06:39:54Z |
Control of intensity field for ultrasound hyperthermia
|
Lin W.-L.; Jin K.-W.; Chen Y.-Y.; MING-JIUM SHIEH; Yen J.-Y.; Yen J.-Y.;Ming-Jium Shieh;Jin K.-W.;Chen Y.-Y.;Lin W.-L. |
| 臺大學術典藏 |
2020-02-27T06:39:52Z |
Optimal configuration of multiple-focused ultrasound transducers for external hyperthermia
|
Lin W.-L.;Chen Y.-Y.;Lin S.-Y.;Yen J.-Y.;Ming-Jium Shieh;Kuo T.-S.; Lin W.-L.; Chen Y.-Y.; Lin S.-Y.; Yen J.-Y.; MING-JIUM SHIEH; Kuo T.-S. |
| 臺大學術典藏 |
2020-02-27T06:39:51Z |
Self-tuning fuzzy logic control for ultrasound hyperthermia with reference temperature based on objective functions
|
Chen Y.-Y.;Lin W.-L.;Liou H.-L.;Yen J.-Y.;Ming-Jium Shieh; Chen Y.-Y.; Lin W.-L.; Liou H.-L.; Yen J.-Y.; MING-JIUM SHIEH |
| 臺大學術典藏 |
2020-02-27T06:39:51Z |
Relationship between acoustic aperture size and tumor conditions for external ultrasound hyperthermia
|
Lin W.-L.;Yen J.-Y.;Chen Y.-Y.;Jin K.-W.;Ming-Jium Shieh; Lin W.-L.; Yen J.-Y.; Chen Y.-Y.; Jin K.-W.; MING-JIUM SHIEH |
| 臺大學術典藏 |
2020-02-27T06:39:50Z |
A theoretical study of cylindrical ultrasound transducers for intracavitary hyperthermia
|
Yen J.-Y.; Fan W.-C.; Lin W.-L.; Lin W.-L.;Fan W.-C.;Yen J.-Y.;Chen Y.-Y.;Ming-Jium Shieh; Chen Y.-Y.; MING-JIUM SHIEH |
| 臺大學術典藏 |
2020-02-26T09:15:56Z |
Inverse estimation of transducer parameters with artificial neural network for ultrasound hyperthermia
|
Chen Y.-Y.;Win-Li Lin;Lu D.-C.;Yen J.-Y.; Chen Y.-Y.; Win-Li Lin; Lu D.-C.; Yen J.-Y. |
| 臺大學術典藏 |
2020-02-26T09:15:56Z |
Power intensity patterns of an annular array ultrasound transducer used in intracavitary hyperthermia
|
Cehn Y.-Y.; Yen J.-Y.; Shieh M.-J.; Chang C.-J.; Win-Li Lin;Cehn Y.-Y.;Yen J.-Y.;Shieh M.-J.;Chang C.-J.; Win-Li Lin |
| 臺大學術典藏 |
2020-02-26T09:15:54Z |
Estimation of ultrasound transducer and tissue parameters with artificial neural network
|
Win-Li Lin; Chen Y.-Y.; Shieh M.-J.; Yen J.-Y.; Chen C.-H. |
| 臺大學術典藏 |
2020-02-26T09:15:54Z |
Control of intensity field for ultrasound hyperthermia
|
Yen J.-Y.;Shieh M.-J.;Jin K.-W.;Chen Y.-Y.;Win-Li Lin; Yen J.-Y.; Shieh M.-J.; Jin K.-W.; Chen Y.-Y.; Win-Li Lin |
| 臺大學術典藏 |
2020-02-26T09:15:54Z |
Modeling of ultrasound temperature distribution with artificial neural network
|
Chen Y.-Y.;Shieh M.-J.;Yen J.-Y.;Chen C.-H.;Win-Li Lin; Chen Y.-Y.; Shieh M.-J.; Yen J.-Y.; Chen C.-H.; Win-Li Lin |
| 臺大學術典藏 |
2020-02-26T09:07:57Z |
Optimal configuration of multiple-focused ultrasound transducers for external hyperthermia
|
Win-Li Lin;Chen Y.-Y.;Lin S.-Y.;Yen J.-Y.;Shieh M.-J.;Kuo T.-S.; Win-Li Lin; Chen Y.-Y.; Lin S.-Y.; Yen J.-Y.; Shieh M.-J.; Kuo T.-S. |
| 臺大學術典藏 |
2020-02-26T09:07:57Z |
Self-tuning fuzzy logic control for ultrasound hyperthermia with reference temperature based on objective functions
|
Chen Y.-Y.;Win-Li Lin;Liou H.-L.;Yen J.-Y.;Shieh M.-J.; Chen Y.-Y.; Win-Li Lin; Liou H.-L.; Yen J.-Y.; Shieh M.-J. |
| 臺大學術典藏 |
2020-02-26T09:07:57Z |
Relationship between acoustic aperture size and tumor conditions for external ultrasound hyperthermia
|
Win-Li Lin;Yen J.-Y.;Chen Y.-Y.;Jin K.-W.;Shieh M.-J.; Win-Li Lin; Yen J.-Y.; Chen Y.-Y.; Jin K.-W.; Shieh M.-J. |
| 臺大學術典藏 |
2020-02-26T09:01:14Z |
Treatable domain and optimal frequency for brain tumors during ultrasound hyperthermia
|
Win-Li Lin;Liauh C.-T.;Yen J.-Y.;Chen Y.-Y.;Shieh M.-J.; Win-Li Lin; Liauh C.-T.; Yen J.-Y.; Chen Y.-Y.; Shieh M.-J. |
| 臺大學術典藏 |
2020-02-26T09:01:13Z |
Optimization of power deposition and a heating strategy for external ultrasound thermal therapy
|
Win-Li Lin;Liang T.-C.;Yen J.-Y.;Liu H.-L.;Chen Y.-Y.; Win-Li Lin; Liang T.-C.; Yen J.-Y.; Liu H.-L.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-26T09:01:13Z |
A theoretical study of cylindrical ultrasound transducers for intracavitary hyperthermia
|
Win-Li Lin;Fan W.-C.;Yen J.-Y.;Chen Y.-Y.;Shieh M.-J.; Win-Li Lin; Fan W.-C.; Yen J.-Y.; Chen Y.-Y.; Shieh M.-J. |
| 臺大學術典藏 |
2020-02-26T09:01:13Z |
An investigation of power deposition patterns for scanned ultrasound arrays
|
Win-Li Lin;Chen Y.-Y.;Ju K.-C.;Yen J.-Y.;Shieh M.-J.; Win-Li Lin; Chen Y.-Y.; Ju K.-C.; Yen J.-Y.; Shieh M.-J. |
| 臺大學術典藏 |
2020-02-26T09:01:12Z |
Treatment time reduction for large thermal lesions by using a multiple 1D ultrasound phased array system
|
Liu H.-L.;Chen Y.-Y.;Yen J.-Y.;Win-Li Lin; Liu H.-L.; Chen Y.-Y.; Yen J.-Y.; Win-Li Lin |
| 臺大學術典藏 |
2020-02-26T09:01:12Z |
Interrelationship between control parameters and tumor/bone conditions for external ultrasound hyperthermia
|
Win-Li Lin; Chen Y.-Y.; Yen J.-Y.; Liauh C.-T.; Liauh C.-T.;Win-Li Lin;Chen Y.-Y.;Yen J.-Y. |
| 臺大學術典藏 |
2020-02-26T09:01:11Z |
Pilot point temperature regulation for thermal lesion control during ultrasound thermal therapy
|
Liu H.-L.;Chen Y.-Y.;Yen J.-Y.;Win-Li Lin; Liu H.-L.; Chen Y.-Y.; Yen J.-Y.; Win-Li Lin |
| 臺大學術典藏 |
2020-02-26T09:00:55Z |
Effectiveness of external respiratory surrogates for in vivo liver motion estimation
|
Chang K.-H.; Ho M.-C.; Yeh C.-C.; Chen Y.-C.; Lian F.-L.; Win-Li Lin; Yen J.-Y.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-26T09:00:52Z |
Preliminary study of intracorporeal localization for endoscopy tracking
|
Ke M.-C.;Tseng Y.-H.;Chen C.-W.;Ho M.-C.;Lian F.-L.;Yen J.-Y.;Win-Li Lin;Chen Y.-Y.; Ke M.-C.; Tseng Y.-H.; Chen C.-W.; Ho M.-C.; Lian F.-L.; Yen J.-Y.; Win-Li Lin; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-26T09:00:50Z |
Computation of liver deformations for minimally invasive surgery
|
Chen Y.-Y.; Hsu W.-J.; Ho M.-C.; Lian F.-L.; Yen J.-Y.; Win-Li Lin |
| 臺大學術典藏 |
2020-02-26T01:36:46Z |
A method of measuring corneal young’s modulus
|
Cao, H.-J.; Huang, C.-J.; Shih, P.-J.; Wang, I.-J.; Yen, J.-Y.; PO-JEN SHIH |
| 臺大學術典藏 |
2020-02-26T01:36:46Z |
A corneal elastic dynamic model derived from Scheimpflug imaging technology
|
Shih, P.-J.; Cao, H.-J.; Huang, C.-J.; Wang, I.-J.; Shih, W.-P.; Yen, J.-Y.; PO-JEN SHIH |
| 臺大學術典藏 |
2020-02-26T01:36:45Z |
Estimation of the Corneal Young's Modulus in Vivo Based on a Fluid-Filled Spherical-Shell Model with Scheimpflug Imaging
|
Po-Jen Shih Shih, P.-J.;Huang, C.-J.;Huang, T.-H.;Lin, H.-C.;Yen, J.-Y.;Wang, I.-J.;Cao, H.-J.;Shih, W.-P.;Dai, C.-A.; Shih, P.-J.; Huang, C.-J.; Huang, T.-H.; Lin, H.-C.; Yen, J.-Y.; Wang, I.-J.; Cao, H.-J.; Shih, W.-P.; Dai, C.-A.; PO-JEN SHIH |
| 臺大學術典藏 |
2020-02-26T01:36:44Z |
Facile fabrication of superporous and biocompatible hydrogel scaffolds for artificial corneal periphery
|
Lee, Y.-P.;Liu, H.-Y.;Lin, P.-C.;Lee, Y.-H.;Yu, L.-R.;Hsieh, C.-C.;Shih, P.-J.;Shih, W.-P.;Wang, I.-J.;Yen, J.-Y.;Dai, C.-A.Po-Jen Shih; Lee, Y.-P.; Liu, H.-Y.; Lin, P.-C.; Lee, Y.-H.; Yu, L.-R.; Hsieh, C.-C.; Shih, P.-J.; Shih, W.-P.; Wang, I.-J.; Yen, J.-Y.; Dai, C.-A.; PO-JEN SHIH |
| 臺大學術典藏 |
2020-02-26T01:36:44Z |
Biomechanical Simulation of Stress Concentration and Intraocular Pressure in Corneas Subjected to Myopic Refractive Surgical Procedures
|
Po-Jen Shih Shih, P.-J.;Wang, I.-J.;Cai, W.-F.;Yen, J.-Y.; Shih, P.-J.; Wang, I.-J.; Cai, W.-F.; Yen, J.-Y.; PO-JEN SHIH |
| 臺大學術典藏 |
2020-02-26T01:33:59Z |
In-vivo wireless bio-diagnosis system for long-term bioactivity monitoring network
|
Fu-Shan JawChen, C.-K.;Wu, W.-J.;Yu, S.-A.;Huang, J.-G.;Lin, Y.-H.;Chen, Y.-F.;Jin, M.-H.;Wen, C.-M.;Kao, C.-Y.;Lin, S.-M.;Lu, S.-S.;Lin, C.-W.;Yen, J.-Y.;Jaw, F.-S.;Chen, C.-A.;Liao, F.-J.;Chiu, N.-F.;Chien, C.-N.;Lee, C.-K.; Chen, C.-K.; Wu, W.-J.; Yu, S.-A.; Huang, J.-G.; Lin, Y.-H.; Chen, Y.-F.; Jin, M.-H.; Wen, C.-M.; Kao, C.-Y.; Lin, S.-M.; Lu, S.-S.; Lin, C.-W.; Yen, J.-Y.; Jaw, F.-S.; Chen, C.-A.; Liao, F.-J.; Chiu, N.-F.; Chien, C.-N.; Lee, C.-K.; FU-SHAN JAW |
| 臺大學術典藏 |
2020-02-19T09:33:58Z |
Minimizing abdominal wall damage during high-intensity focused ultrasound ablation by inducing artificial ascites
|
Wu C.-C.;Chen W.-S.;Ming-Chih Ho;Huang K.-W.;Chen C.-N.;Yen J.-Y.;Lee P.-H.; Wu C.-C.; Chen W.-S.; MING-CHIH HO; Huang K.-W.; Chen C.-N.; Yen J.-Y.; Lee P.-H. |
| 臺大學術典藏 |
2020-02-19T09:33:51Z |
Effectiveness of external respiratory surrogates for in vivo liver motion estimation
|
Chang K.-H.; MING-CHIH HO; Yeh C.-C.; Chen Y.-C.; Lian F.-L.; Lin W.-L.; Yen J.-Y.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:51Z |
Ultrasound image-guided tracking algorithm for moving-tumor treatment
|
Chang K.-H.; MING-CHIH HO; Yeh C.-C.; Lian F.-L.; Yen J.-Y.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:50Z |
Ultrasound image-guided algorithms for tracking liver motion
|
Lin C.-K.; Lin F.-C.; Lian F.-L.; Chang K.-H.; MING-CHIH HO; Yen J.-Y.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:48Z |
A novel design of high intensity focus ultrasound (HIFU) for enlarged focus area application
|
Chao Y.-T.; Yu Y.-L.; Yen J.-Y.; Hsu C.-J.; Kam M.; Liu S.T.; MING-CHIH HO; Chen Y.-Y.; Lian F.-L. |
| 臺大學術典藏 |
2020-02-19T09:33:48Z |
Dynamics stress analysis for a minimal invasive scalpel design
|
Chao Y.-T.; Yu Y.-L.; Yen J.-Y.; Hsu C.-J.; Kam M.; MING-CHIH HO; Chen Y.-Y.; Fang J.; Lian F.-L. |
| 臺大學術典藏 |
2020-02-19T09:33:47Z |
Dynamics stress analysis for a high rigidity bendable Minimal Invasive surgical (MIS) instrument design
|
Chao Y.T.; Yu Y.L.; Yen J.Y.; Kam M.; Hsu C.J.; Liu S.T.; MING-CHIH HO; Chen Y.Y.; Lian F.L. |
| 臺大學術典藏 |
2020-02-19T09:33:47Z |
Preliminary study of intracorporeal localization for endoscopy tracking
|
Ke M.-C.; Tseng Y.-H.; Chen C.-W.; MING-CHIH HO; Lian F.-L.; Yen J.-Y.; Lin W.-L.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:46Z |
A novel application for enlarge focus area based on High Intensity Focused Ultrasound (HIFU) probe with a high directivity structure design
|
Yu Y.L.; Chao Y.T.; Yen J.Y.; Hsu C.J.; Kam M.; MING-CHIH HO; Chen Y.Y.; Lian F.L. |
| 臺大學術典藏 |
2020-02-19T09:33:44Z |
A novel sound-blocking structure based on the muffler principle for rib-sparing transcostal high-intensity focused ultrasound treatment
|
Chao Y.-T.;Hsu C.-J.;Yu Y.-L.;Yen J.-Y.;Ming-Chih Ho;Chen Y.-Y.;Chang H.-C.;Lian F.-L.; Chao Y.-T.; Hsu C.-J.; Yu Y.-L.; Yen J.-Y.; MING-CHIH HO; Chen Y.-Y.; Chang H.-C.; Lian F.-L. |
| 臺大學術典藏 |
2020-02-19T09:33:43Z |
Improvement of harmonic dissector for minimal invasive surgery, modeling and the stiffness identification of the clipped object
|
Liu S.T.; Liao Y.T.; Yen J.Y.; Chen Y.Y.; Lian F.L.; MING-CHIH HO |
| 臺大學術典藏 |
2020-02-19T09:33:43Z |
Computation of liver deformations for minimally invasive surgery
|
Hsu W.-J.; MING-CHIH HO; Lian F.-L.; Yen J.-Y.; Lin W.-L.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:42Z |
Long range gaze estimation with multiple near-infrared emitters
|
Ma Z.-H.;Liu Z.-X.;Ming-Chih Ho;Yen J.-Y.;Chen Y.-Y.; Ma Z.-H.; Liu Z.-X.; MING-CHIH HO; Yen J.-Y.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:42Z |
Computation of liver deformations with finite element model
|
Chien C.-C.;Chang Y.-F.;Ming-Chih Ho;Yen J.-Y.;Chen Y.-Y.; Chien C.-C.; Chang Y.-F.; MING-CHIH HO; Yen J.-Y.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:41Z |
Comparison of the Control Designs of an Human Co-Working Endoscope Holder
|
Liao Y.-T.;Chen C.-Y.;Yen J.-Y.;Ming-Chih Ho;Chen Y.-Y.; Liao Y.-T.; Chen C.-Y.; Yen J.-Y.; MING-CHIH HO; Chen Y.-Y. |
| 臺大學術典藏 |
2020-02-19T09:33:38Z |
Liver image registration by finite element model for deriving tumour and vessel locations
|
Ming-Chih Ho;Su S.-T.;Hsu W.-J.;Yen J.-Y.;Chen Y.-Y.; MING-CHIH HO; Su S.-T.; Hsu W.-J.; Yen J.-Y.; Chen Y.-Y. |
| 臺大學術典藏 |
2020-01-17T07:48:46Z |
In-vivo wireless bio-diagnosis system for long-term bioactivity monitoring network
|
Chen, C.-K.; Wu, W.-J.; Yu, S.-A.; Huang, J.-G.; Lin, Y.-H.; Chen, Y.-F.; Jin, M.-H.; Wen, C.-M.; Kao, C.-Y.; Lin, S.-M.; Lu, S.-S.; Lin, C.-W.; Yen, J.-Y.; Jaw, F.-S.; Chen, C.-A.; Liao, F.-J.; Chiu, N.-F.; Chien, C.-N.; Lee, C.-K.; WEN-JONG WU |
| 臺大學術典藏 |
2020-01-17T07:47:38Z |
Solution-refined method for electrostatic potential distribution of large-scale electron optics
|
Lee, Y.-M.; Li, J.-H.; Sheu, T.-W.-H.; Tsai, K.-Y.; Yen, J.-Y.; TONY W. H. SHEU |
| 臺大學術典藏 |
2020-01-13T08:20:48Z |
Stress effect on the kinetics of silicon thermal oxidation
|
Yen, J. Y.;Hwu, J. G.Jia-Yush Yen; Yen, J. Y.; Hwu, J. G.; JIA-YUSH YEN |
| 臺大學術典藏 |
2020-01-13T08:20:48Z |
Enhancement of silicon oxidation rate due to tensile mechanical stress
|
Jia-Yush YenYen, J. Y.;Hwu, J. G.; Yen, J. Y.; Hwu, J. G.; JIA-YUSH YEN |
