David J. Carter
26Patents
8h-index
48Co-inventors
75Inventor score
Filing activity: Nov 25, 1983 → Jul 30, 2019
Most-cited inventions
| Patent | Title | Area | Cited by | Status |
|---|---|---|---|---|
| US7005946B2 | MEMS piezoelectric longitudinal mode resonator | Emerging Cross-Sectional Technologies | 60 | Expired |
| US7312674B2 | Resonator system with a plurality of individual mechanically coupled resonators and method of making same | Emerging Cross-Sectional Technologies | 32 | Expired |
| US6367403B1 | Boating accessory container | Performing Operations; Transporting | 25 | Expired |
| US5842329A | Adjustable lawn mower handle mount | Emerging Cross-Sectional Technologies | 13 | Expired |
| US9060842B2 | Adhesive articles | Chemistry; Metallurgy | 12 | Active |
| US6960773B2 | System and method for maskless lithography using an array of improved diffractive focusing elements | Physics | 9 | Expired |
| USD700498S1 | Woodturning handle | General | 8 | Active |
| US6894292B2 | System and method for maskless lithography using an array of sources and an array of focusing elements | Physics | 8 | Expired |
| US7137262B2 | Supplemental heat control apparatus and method for freezer/refrigeration equipment | Mechanical Engineering; Lighting; Heating | 6 | Expired |
| US9150405B2 | Rotary nanotube bearing structure and methods for manufacturing and using the same | Emerging Cross-Sectional Technologies | 4 | Active |
| US7031144B2 | Reversible display apparatus and method for appliances | Chemistry; Metallurgy | 3 | Expired |
| US4497671A | Processed ferrous metal and process of production | Emerging Cross-Sectional Technologies | 3 | Expired |
| US7160673B2 | System and method for holographic fabrication and replication of diffractive optical elements for maskless lithography | Physics | 2 | Expired |
| US8337141B2 | Rotary nanotube bearing structure and methods for manufacturing and using the same | Emerging Cross-Sectional Technologies | 2 | Active |
| US7348104B2 | System and method for fabrication and replication of diffractive optical elements for maskless lithography | Physics | 1 | Expired |
| US10020219B2 | Method for realizing ultra-thin sensors and electronics with enhanced fragility | Electricity | 1 | Active |
| US10857427B2 | Hard-point fixture and system for attaching the fixture to a target surface | Performing Operations; Transporting | 1 | Active |
| US11159262B2 | Decoder | Electricity | 0 | Active |
| US10933282B2 | Hard-point fixture for attaching to a target surface | Performing Operations; Transporting | 0 | Active |
| US10130846B2 | Hybrid adhesion system and method | Human Necessities | 0 | Active |
| US10791779B2 | Polymer microwedges and methods of manufacturing same | Performing Operations; Transporting | 0 | Active |
| US8771525B2 | Rotary nanotube bearing structure and methods for manufacturing and using the same | Emerging Cross-Sectional Technologies | 0 | Active |
| US8728602B2 | Multi-component adhesive system | Emerging Cross-Sectional Technologies | 0 | Active |
| US10014204B2 | Method for realizing ultra-thin sensors and electronics with enhanced fragility | Electricity | 0 | Active |
| US7304318B2 | System and method for maskless lithography using an array of sources and an array of focusing elements | Physics | 0 | Expired |
Source: USPTO / EPO open patent data. Inventor disambiguation is heuristic; counts are objective bibliographic measures.