Leolabs has a total of 48 patents globally, out of which 6 have been granted. Of these 48 patents, more than 95% patents are active. United States of America is where Leolabs has filed the maximum number of patents, followed by Canada and Australia. Parallelly, United States of America seems to be the main focused R&D centre and also is the origin country of Leolabs.
Leolabs was founded in the year 2016. The Company is an aerospace company that supplies and provides low Earth orbit mapping and space situational awareness services.
Do read about some of the most popular patents of Leolabs which have been covered by us in this article and also you can find Leolabs patents information, the worldwide patent filing activity and its patent filing trend over the years, and many other stats over Leolabs patent portfolio.
How many patents does the founder and the CEO of Leolabs have?
The founder Edward T. Lu has 1 patent, John Buonocore has 2 patents, Michael Nicolls has 7 patents and CEO Daniel Ceperley has 1 patent.
How many patents does Leolabs have?
Leolabs has a total of 48 patents globally. These patents belong to 13 unique patent families. Out of 48 patents, 12 patents are active.
How Many Patents did Leolabs File Every Year?
Are you wondering why there is a drop in patent filing for the last two years? It is because a patent application can take up to 18 months to get published. Certainly, it doesn’t suggest a decrease in the patent filing.
| Year of Patents Filing or Grant | Leolabs Applications Filed | Leolabs Patents Granted |
| 2023 | 2 | 2 |
| 2022 | 6 | 2 |
| 2021 | 15 | 1 |
| 2020 | 16 | 1 |
| 2019 | 1 | – |
| 2018 | 7 | – |
| 2017 | 1 | – |
How many Leolabs patents are Alive/Dead?
How Many Patents did Leolabs File in Different Countries?
Countries in which Leolabs Filed Patents
| Country | Patents |
| United States Of America | 8 |
| Canada | 6 |
| Australia | 6 |
| Europe | 6 |
| Korea (South) | 5 |
| India | 5 |
| Argentina | 3 |
| Japan | 1 |
| United Kingdom | 1 |
Where are Research Centres of Leolabs Patents Located?
What Percentage of Leolabs US Patent Applications were Granted?
Leolabs (Excluding its subsidiaries) has filed 9 patent applications at USPTO so far (Excluding Design and PCT applications). Out of these 6 have been granted leading to a grant rate of 100.0%.
Below are the key stats of Leolabs patent prosecution at the USPTO.
Which Law Firms Filed Most US Patents for Leolabs?
| Law Firm | Total Applications | Success Rate |
| Dentons | 9 | 100.00% |
List of Leolabs Patents
| LeoLabs Patents | Title |
| US10921427B2 | Drone-Based Calibration Of A Phased Array Radar |
| US11592549B2 | Calibrating Radars And Tracking Space Objects |
| US10698099B2 | Randomized Phase And Amplitude Radar Codes For Space Object Tracking |
| US11378685B2 | Systems, Devices, And Methods For Determining Space Object Attitude Stabilities From Radar Cross-Section Statistics |
| US11327168B2 | Randomized Phase And Amplitude Radar Codes For Space Object Tracking |
| US20220376389A1 | Calibrating Radars And Tracking Space Objects |
| US20220065990A1 | Method And System For Detecting The Tumbling Characteristics Of Space Objects |
| US20210405187A1 | System And Method For Orbital Collision Screening |
| EP4204846A2 | A Method And System For Detecting The Tumbling Characteristics Of Space Objects |
| EP4172710A1 | A System And Method For Orbital Collision Screening |
| EP3931592A2 | Determining Space Object Attitude Stabilities From Radar Cross-Section Statistics |
| EP3698165A1 | Randomized Phase And Amplitude Radar Codes For Space Object Tracking |
| EP4042198A1 | Calibrating Radars And Tracking Space Objects |
| EP4042183A1 | Calibrating Radars And Tracking Space Objects |
| WO2021072348A1 | Calibrating Radars And Tracking Space Objects |
| WO2021072347A1 | Calibrating Radars And Tracking Space Objects |
| WO2022240892A1 | Computing Technologies For Detecting And Tracking Space Objects Via Combinations Of Incoherent Processing, Dynamic Detection, And Coherent And/Or Correlator Processing |
| WO2022076095A3 | A Method And System For Detecting The Tumbling Characteristics Of Space Objects |
| WO2021262867A1 | A System And Method For Orbital Collision Screening |
| GB202210287D0 | A System And Method For Satellite Identification |
| AU2020364169A1 | Calibrating Radars And Tracking Space Objects |
| AU2020361695A1 | Calibrating Radars And Tracking Space Objects |
| AU2020259110A1 | Determining Space Object Attitude Stabilities From Radar Cross-Section Statistics |
| CA3179817A1 | A System And Method For Orbital Collision Screening |
| CA3151077A1 | Calibrating Radars And Tracking Space Objects |
| CA3151079A1 | Calibrating Radars And Tracking Space Objects |
| CA3131519A1 | Determining Space Object Attitude Stabilities From Radar Cross-Section Statistics |
| AU2018350835A1 | Randomized Phase And Amplitude Radar Codes For Space Object Tracking |
| CA3185975A1 | A Method And System For Detecting The Tumbling Characteristics Of Space Objects |
| AU2021358654A1 | A Method And System For Detecting The Tumbling Characteristics Of Space Objects |
| AU2021296857A1 | A System And Method For Orbital Collision Screening |
| CA3073753A1 | Randomized Phase And Amplitude Radar Codes For Space Object Tracking |
| KR2023028296A | Systems And Methods For Orbital Collision Screening |
| KR2022076471A | Radar Calibration And Space Object Tracking |
| KR2022076469A | Radar Calibration And Space Object Tracking |
| IN202327016893A | A Method And System For Detecting The Tumbling Characteristics Of Space Objects |
| IN202327002698A | A System And Method For Orbital Collision Screening |
| IN202227026326A | Calibrating Radars And Tracking Space Objects |
| IN202227026314A | Calibrating Radars And Tracking Space Objects |
| IN202127043626A | Determining Space Object Attitude Stabilities From Radar Cross-Section Statistics |
| KR2022008800A | Determination Of Space Object Attitude Stability From Radar Cross-Section Statistics |
| KR2023054833A | Method And System For Detecting Tumbling Characteristics Of Space Objects |
| AR123335A1 | A Method And System To Detect The Rollover Characteristics Of Spatial Objects |
| AR124474A2 | Method For Tracking A Spatial Object Through A Network Radar In Phase And Radar System Of Disposition In Phase |
| AR113366A1 | Random Phase And Amplitude Radar Codes For Space Object Tracking |
| JP07285849B2 | The Random Phase And The Radar Code Of An Amplitude For Space Object Tracking |
| WO2020214242A3 | Determining Space Object Attitude Stabilities From Radar Cross-Section Statistics |
| WO2019079151A1 | Randomized Phase And Amplitude Radar Codes For Space Object Tracking |
What are Leolabs key innovation segments?
What Technologies are Covered by Leolabs?
The chart below distributes patents filed by Leolabs