Ji Won Kim
109Patents
8h-index
235Co-inventors
83Inventor score
Filing activity: Aug 13, 2001 → Jun 11, 2024
Most-cited inventions
| Patent | Title | Area | Cited by | Status |
|---|---|---|---|---|
| US7952252B2 | Inner rotor type permanent magnet excited transverse flux motor | Electricity | 43 | Active |
| US7626308B2 | Permanent magnet excited transverse flux motor with outer rotor | Electricity | 35 | Active |
| US6764298B2 | Method for controlling air fuel ratio in gas furnace | Mechanical Engineering; Lighting; Heating | 24 | Expired |
| US10411327B2 | Antenna device and electronic device including same | Electricity | 15 | Active |
| US7474019B2 | Permanent magnet excited transverse flux linear motor with normal force compensation structure | Electricity | 13 | Active |
| US10261615B2 | Method and electronic device for outputting screen | Physics | 11 | Active |
| US10517980B2 | Compact air cleaner using UV LED and photocatalytic filter | Performing Operations; Transporting | 9 | Active |
| US7554254B2 | Flat fluorescent lamp | Electricity | 8 | Active |
| US8380444B2 | Methods of measuring concentration of component in biochemical sample and estimating reliability of test result | Physics | 7 | Active |
| US8593019B2 | Structure for linear and rotary electric machines | Electricity | 6 | Active |
| US10804728B2 | Device for adjusting path of power and method for operating the same | Electricity | 6 | Active |
| US8553972B2 | Apparatus, method and computer-readable medium generating depth map | Physics | 5 | Active |
| US8367398B2 | Centrifugal-based microfluidic apparatus, method of fabricating the same, and method of testing samples using the microfluidic apparatus | Performing Operations; Transporting | 5 | Active |
| US7928612B2 | Low-noise, high-speed, high precision and high-thrust flux reversal motor for linear or rotary motion system | Electricity | 5 | Active |
| US10010635B2 | Detergent pourer sterilizer and sterilizing method thereby | Textiles; Paper | 5 | Active |
| US8253733B2 | 3D image generation apparatus and method | Electricity | 5 | Active |
| US9137512B2 | Method and apparatus for estimating depth, and method and apparatus for converting 2D video to 3D video | Electricity | 4 | Active |
| US9616424B2 | Centrifugal-based microfluidic apparatus, method of fabricating the same, and method of testing samples using the microfluidic apparatus | Performing Operations; Transporting | 3 | Active |
| US8624446B2 | Doubly salient permanent magnet electric machine | Electricity | 3 | Active |
| US8884995B2 | System for compensating for gamma data, display device including the same and method of compensating for gamma data | Physics | 3 | Active |
| US10425568B2 | Display device and system and method for controlling power of the same | Electricity | 3 | Active |
| US10713294B2 | Method for learning cross-domain relations based on generative adversarial networks | Physics | 3 | Active |
| US10649534B2 | Apparatus and method for providing haptic feedback through wearable device | Electricity | 3 | Active |
| US8013970B2 | Array substrate for in-plane switching mode liquid crystal display device and method of fabricating the same | Physics | 3 | Active |
| US9082176B2 | Method and apparatus for temporally-consistent disparity estimation using detection of texture and motion | Physics | 2 | Active |
Source: USPTO / EPO open patent data. Inventor disambiguation is heuristic; counts are objective bibliographic measures.