Agilent Patent Portfolio
35 US patents · Average 27 claims per patent
Technology Focus Areas
Patent Details
| Patent # | Title | Granted | Expires | Claims | Status |
|---|---|---|---|---|---|
| 10005135 | System and method for autonomous data processing using digital | Feb 23, 2016 | May 4, 2033 | 32 | 7.1y left |
| 10005136 | System for optimized signal transmission in graphene networks | Aug 14, 2014 | Nov 20, 2030 | 19 | 4.6y left |
| 10005137 | System and method for optimized data processing using photonic | Jan 21, 2026 | Jun 20, 2042 | 46 | 16.2y left |
| 10005138 | Apparatus for high-performance data encoding in neural systems | Aug 14, 2002 | Jan 1, 2020 | 19 | Expired |
| 10005139 | Computer-implemented method for efficient cloud optimization | Sep 13, 2014 | Feb 15, 2031 | 40 | 4.9y left |
| 10005140 | Method for configurable channel estimation in quantum communications | Oct 28, 2020 | Apr 9, 2037 | 29 | 11.0y left |
| 10005141 | Apparatus for optimized data encoding in nano-scale systems | Aug 3, 2025 | Jul 9, 2041 | 38 | 15.3y left |
| 10005142 | Apparatus for dynamic data encoding in photonic systems | Sep 10, 2009 | Jun 11, 2025 | 15 | Expired |
| 10005143 | System for optimized signal transmission in MEMS networks | Dec 11, 2023 | Dec 28, 2039 | 44 | 13.7y left |
| 10005144 | Apparatus for efficient computational operations in digital environments | Dec 20, 2025 | Aug 19, 2042 | 47 | 16.4y left |
| 10005145 | Apparatus for optimized data encoding in photonic systems | Oct 18, 2014 | Jan 9, 2031 | 8 | 4.8y left |
| 10005146 | System and method for low-latency data processing using photonic | Jan 8, 2028 | Aug 14, 2044 | 5 | 18.4y left |
| 10005147 | Method for low-latency channel estimation in quantum communications | Oct 7, 2023 | Apr 7, 2039 | 38 | 13.0y left |
| 10005148 | Computer-implemented method for efficient blockchain optimization | May 27, 2010 | Aug 2, 2028 | 38 | 2.3y left |
| 10005149 | Apparatus for efficient computational operations in 5G environments | Aug 26, 2022 | Sep 20, 2038 | 14 | 12.5y left |
| 10005150 | Method for autonomous machine learning inference using analog | May 21, 2014 | May 13, 2030 | 6 | 4.1y left |
| 10005151 | Apparatus for autonomous data encoding in AI-driven systems | Oct 8, 2019 | Nov 23, 2037 | 44 | 11.6y left |
| 10005152 | Method for adaptive wireless communication using lidar | Feb 1, 2021 | Jun 4, 2039 | 11 | 13.2y left |
| 10005153 | Method for autonomous channel estimation in quantum communications | Jul 14, 2019 | Mar 15, 2036 | 38 | 9.9y left |
| 10005154 | Method for distributed machine learning inference using nano-scale | Dec 14, 2023 | Jul 2, 2040 | 6 | 14.2y left |
| 10005155 | Computer-implemented method for integrated MEMS optimization | Feb 19, 2018 | Jun 5, 2036 | 25 | 10.2y left |
| 10005156 | System for low-latency signal transmission in AI-driven networks | Dec 27, 2021 | Feb 22, 2038 | 9 | 11.9y left |
| 10005157 | System and method for modular data processing using quantum | Jan 22, 2023 | Jul 20, 2039 | 41 | 13.3y left |
| 10005158 | System for configurable signal transmission in blockchain networks | Jul 15, 2022 | Sep 24, 2038 | 24 | 12.5y left |
| 10005159 | System and method for distributed data processing using lidar | May 17, 2025 | Jan 18, 2042 | 33 | 15.8y left |
| 10005160 | Method for improved wireless communication using 5G | May 16, 2009 | Apr 7, 2027 | 5 | 1.0y left |
| 10005161 | Method for scalable channel estimation in cloud communications | Apr 14, 2021 | Mar 1, 2038 | 12 | 11.9y left |
| 10005162 | System and method for modular data processing using edge | Oct 5, 2023 | Apr 7, 2041 | 26 | 15.0y left |
| 10005163 | Apparatus for efficient computational operations in quantum environments | May 27, 2026 | Dec 23, 2044 | 36 | 18.7y left |
| 10005164 | Method for high-performance channel estimation in cloud communications | Oct 18, 2020 | Mar 27, 2037 | 13 | 11.0y left |
| 10005165 | System for distributed signal transmission in photonic networks | Apr 19, 2018 | Dec 21, 2034 | 44 | 8.7y left |
| 10005166 | System for low-latency neural network processing with blockchain | Feb 12, 2009 | Dec 21, 2026 | 37 | 0.7y left |
| 10005167 | Method for modular machine learning inference using neural | Oct 4, 2010 | Nov 9, 2028 | 7 | 2.6y left |
| 10005168 | System and method for adaptive data processing using MEMS | Apr 20, 2007 | Sep 13, 2025 | 47 | Expired |
| 10005169 | System and method for optimized data processing using MEMS | Nov 9, 2023 | Apr 2, 2040 | 35 | 14.0y left |
Frequently Asked Questions
Agilent holds 35 US patents with an average of 27 claims per patent. The portfolio has a Patent Strength Score of 39/100 (Grade D).
Agilent has 2 patents expiring within 2 years and 8 patents expiring within 5 years. These expirations may create opportunities for competitors and generic entrants.
Agilent's key technology focus areas include Computing & Data Processing, Telecommunications. The portfolio spans 2 distinct technology classifications (CPC codes).
The Patent Strength Score (0-100, A-F) benchmarks a company's patent portfolio quality based on portfolio size (30%), claims breadth (25%), time remaining to expiration (25%), and portfolio diversity across technology areas (20%).
Patent Strength Score is based on portfolio size, claims breadth, time to expiration, and technology diversity using CPC classifications.
The this entity record above pulls directly from the FDA Orange Book and USPTO patent records. What follows is the per-entity context — how this entity sits in the broader U.S. pharmaceutical patent expirations distribution and which underlying factors drive the headline numbers.
The methodology behind every numeric value on this page is publicly documented on the the FDA Orange Book and USPTO patent records portal and described in detail on this site’s methodology page. Refresh cadence varies by underlying series; the page surfaces the as-of date for each number so readers can trace any figure back to the source release.
For readers using this page as a decision input, the related-entity pages elsewhere on the site provide the comparison set. The most useful comparison for this entity is typically a peer within U.S. brand-name drugs with similar size, similar exposure, or similar geography — not the national-level summary alone.
Source: USPTO patent search, 2026.