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Graduate School of Information Science and technology, Hokkaido University | 論文
- A Merged SET-MOSFET Logic for Interface and Multiple-Valued Functions
- A behavioral model of unipolar resistive RAMs and its application to HSPICE integration
- VLSI Implementation of a Scalable Pipeline MMSE MIMO Detector for a 4×4 MIMO-OFDM Receiver
- Error-Resilient 3-D Wavelet Video Coding with Duplicated Lowest Sub-Band Coefficients and Two-Step Error Concealment Method
- Fundamental Characteristics of Localized Acoustic Modes in Photonic Crystal Fibers(Optical Fibers, Cables and Fiber Devices, Recent Progress in Optoelectronics and Communications)
- Detailed theoretical investigation of bending properties in solid-core photonic bandgap fibers
- CMOS Image Sensor Using Negative-Feedback Resetting to Obtain Variably Smoothed Images(Novel Device Architectures and System Integration Technologies)
- Establishment of in silico systems to predict the effects of genetic polymorphism on the enzymatic activity of cytochrome P450
- Voltage Gain of Si Single-Electron Transistor and Analysis of Performance of n-Metal-Oxide-Semiconductor Type Inverter with Resistive Load
- Single-Electron Detection in Si-Wire Transistors at Room Temperature
- Realistic Design of Large-Hollow-Core Photonic Band-Gap Fibers With Suppressed Higher Order Modes and Surface Modes
- Design of effectively single-mode air-core photonic bandgap fiber with improved transmission characteristics for the realization of ultimate low loss waveguide
- Design of photonic band gap fibers with suppressed higher-order modes: Towards the development of effectively single mode large hollow-core fiber platforms
- Full-vectorial coupled mode theory for the evaluation of macro-bending loss in multimode fibers. application to the hollow-core photonic bandgap fibers
- Numerical Modeling of Cryogenic Temperature Sensors Based on Plasmonic Oscillations in Metallic Nanoparticles Embedded Into Photonic Crystal Fibers
- Coupling Characteristics of Multicore Photonic Crystal Fiber-Based 1 × 4 Power Splitters
- Thermooptical Sensitivity Analysis of Highly Birefringent Polarimetric Sensing Photonic Crystal Fibers With Elliptically Elongated Veins
- C-3-87 Multi-Core Photonic Band Gap Fiber Splitters Based on Highly-Selective Non-Proximity Resonant Coupling
- C-3-82 Thermo-Optical Sensitivity of Polarimetric-Sensing Photonic Crystal Fibers
- C-3-136 Modeling of Realistic Air-Core Photonic Band-Gap Fibers