DeBar; Michael J.

Patent Applications and Registrations

Patent applications and USPTO patent grants for DeBar; Michael J..The latest application filed is for "length-wise segmented slot contacts for improving performance in phase-change material (pcm) radio frequency (rf) switches".

Company Profile

27.39.31

DeBar; Michael J. - Tustin CA
DeBar; Michael J - Huntington Beach CA
DeBar; Michael J. - Huntington Beach CA
DeBar; Michael J. - Aliso Viejo CA
DeBar; Michael J. - Rochester NY

*profile and listings may contain filings by different individuals or companies with the same name. Review application materials to confirm ownership/assignment.

Patent Activity

Patent	Date
PCM RF switch with PCM contacts having slot lower portions Grant 11,031,552 - Rose , et al. June 8, 2	2021-06-08
Phase-change material RF switch Grant 10,892,411 - Rose , et al. January 12, 2	2021-01-12
Method of manufacturing PCM RF switch Grant 10,862,027 - Slovin , et al. December 8, 2	2020-12-08
Phase-change material (PCM) RF switch having contacts to PCM and heating element Grant 10,833,260 - Rose , et al. November 10, 2	2020-11-10
Phase-change material (PCM) RF switch with top metal contact to heating element Grant 10,833,261 - Rose , et al. November 10, 2	2020-11-10
Segmented slot contacts for improving performance in phase-change material (PCM) radio frequency (RF) switches Grant 10,811,605 - Howard , et al. October 20, 2	2020-10-20
Length-wise segmented slot contacts for improving performance in phase-change material (PCM) radio frequency (RF) switches Grant 10,811,606 - Howard , et al. October 20, 2	2020-10-20
Phase-change material (PCM) RF switch with contacts to PCM and heating element Grant 10,804,462 - Rose , et al. October 13, 2	2020-10-13
Method for fabricating contacts in a phase-change material (PCM) RF switch having a heating element Grant 10,804,108 - Rose , et al. October 13, 2	2020-10-13
High reliability RF switch based on phase-change material Grant 10,756,268 - Slovin , et al. A	2020-08-25
Width-wise segmented slot contacts for improving performance in phase-change material (PCM) radio frequency (RF) switches Grant 10,741,758 - Howard , et al. A	2020-08-11
Uniform plate slot contacts for improving performance in phase-change material (PCM) radio frequency (RF) switches Grant 10,707,414 - Howard , et al.	2020-07-07
Fabrication of contacts in an RF switch having a phase-change material (PCM) and a heating element Grant 10,707,125 - Rose , et al.	2020-07-07
Phase-change material (PCM) contact configurations for improving performance in PCM RF switches Grant 10,686,130 - Howard , et al.	2020-06-16
Length-Wise Segmented Slot Contacts for Improving Performance in Phase-Change Material (PCM) Radio Frequency (RF) Switches App 20200152868 - Howard; David J. ; et al.	2020-05-14
Width-Wise Segmented Slot Contacts for Improving Performance in Phase-Change Material (PCM) Radio Frequency (RF) Switches App 20200144497 - Howard; David J. ; et al.	2020-05-07
Segmented Slot Contacts for Improving Performance in Phase-Change Material (PCM) Radio Frequency (RF) Switches App 20200136042 - Howard; David J. ; et al.	2020-04-30
Phase-Change Material (PCM) RF Switch Having Contacts to PCM and Heating Element App 20200119265 - Rose; Jefferson E. ; et al.	2020-04-16
Phase-Change Material (PCM) RF Switch with Top Metal Contact to Heating Element App 20200119266 - Rose; Jefferson E. ; et al.	2020-04-16
Phase-Change Material (PCM) RF Switch with Contacts to PCM and Heating Element App 20200111953 - Rose; Jefferson E. ; et al.	2020-04-09
Method for Fabricating Contacts in a Phase-Change Material (PCM) RF Switch Having a Heating Element App 20200111952 - Rose; Jefferson E. ; et al.	2020-04-09
Phase-change material (PCM) contacts with slot lower portions and contact dielectric for reducing parasitic capacitance and improving manufacturability in PCM RF switches Grant 10,615,338 - Rose , et al.	2020-04-07
PCM RF Switch with PCM Contacts Having Slot Lower Portions App 20200091424 - Rose; Jefferson E. ; et al.	2020-03-19
Phase-Change Material (PCM) Contact Configurations for Improving Performance in PCM RF Switches App 20200058860 - Howard; David J. ; et al.	2020-02-20
High Reliability RF Switch Based on Phase-Change Material App 20200058869 - Slovin; Gregory P. ; et al.	2020-02-20
Phase-Change Material (PCM) Contacts with Slot Lower Portions and Contact Dielectric for Reducing Parasitic Capacitance and Impr App 20200058857 - Rose; Jefferson E. ; et al.	2020-02-20
Heating Element Designs For Phase-change Material (pcm) Radio Frequency (rf) Switches App 20200058863 - El-Hinnawy; Nabil ; et al.	2020-02-20
Phase-Change Material RF Switch App 20200058872 - Rose; Jefferson E. ; et al.	2020-02-20
Method of Manufacturing PCM RF Switch App 20200058855 - Slovin; Gregory P. ; et al.	2020-02-20
Fabrication of Contacts in an RF Switch Having a Phase-Change Material (PCM) and a Heating Element App 20200058854 - Rose; Jefferson E. ; et al.	2020-02-20
Heating element designs for phase-change material (PCM) radio frequency (RF) switches Grant 10,566,528 - El-Hinnawy , et al. Feb	2020-02-18
PCM RF switch fabrication with subtractively formed heater Grant 10,475,993 - Slovin , et al. Nov	2019-11-12
Manufacturing RF switch based on phase-change material Grant 10,476,001 - Rose , et al. Nov	2019-11-12
High reliability RF switch based on phase-change material Grant 10,461,253 - Slovin , et al. Oc	2019-10-29
Reduced substrate effects in monolithically integrated RF circuits Grant 9,966,301 - Howard , et al. May 8, 2	2018-05-08
Reduced Substrate Effects in Monolithically Integrated RF Circuits App 20170372945 - Howard; David J. ; et al.	2017-12-28
RF SOI switches including low dielectric constant features between metal line structures Grant 9,755,063 - Howard , et al. September 5, 2	2017-09-05
Integration of active devices with passive components and MEMS devices Grant 9,751,753 - DeBar , et al. September 5, 2	2017-09-05
MEMS device with sealed cavity and method for fabricating same Grant 9,725,306 - DeBar , et al. August 8, 2	2017-08-08
Integration Of Active Devices With Passive Components And MEMS Devices App 20160368764 - DeBar; Michael J. ; et al.	2016-12-22
Integration of active devices with passive components and MEMS devices Grant 9,481,568 - DeBar , et al. November 1, 2	2016-11-01
Integration of Active Devices with Passive Components and MEMS Devices App 20160289065 - DeBar; Michael J. ; et al.	2016-10-06
Scalable self-supported MEMS structure and related method Grant 9,458,011 - Howard , et al. October 4, 2	2016-10-04
Light sensor with chemically resistant and robust reflector stack Grant 9,377,350 - Howard , et al. June 28, 2	2016-06-28
Robust MEMS structure with via cap and related method Grant 9,346,669 - Howard , et al. May 24, 2	2016-05-24
Light Sensor with Chemically Resistant and Robust Reflector Stack App 20160069739 - Howard; David J. ; et al.	2016-03-10
MEMS device with sealed cavity and release chamber and related double release method Grant 9,272,901 - DeBar , et al. March 1, 2	2016-03-01
Scalable Self-Supported MEMS Structure and Related Method App 20150368092 - Howard; David J. ; et al.	2015-12-24
Robust MEMS Structure with Via Cap and Related Method App 20150368094 - Howard; David J. ; et al.	2015-12-24
MEMS Device with Sealed Cavity and Release Chamber and Related Double Release Method App 20150158721 - DeBar; Michael J. ; et al.	2015-06-11
MEMS Device with Sealed Cavity and Method for Fabricating Same App 20150158719 - DeBar; Michael J. ; et al.	2015-06-11
Method for encapsulating microelectronic devices Grant 8,513,063 - DeBar , et al. August 20, 2	2013-08-20
Method for Encapsulating Microelectronic Devices App 20120270371 - DeBar; Michael J. ; et al.	2012-10-25
Method of strengthening a microscale chamber formed over a sacrificial layer App 20070020794 - DeBar; Michael J.	2007-01-25
Providing an improved organic vertical cavity laser array device Grant 6,996,146 - Kahen , et al. February 7, 2	2006-02-07
Fabrication of liquid emission device with symmetrical electrostatic mandrel Grant 6,966,110 - DeBar , et al. November 22, 2	2005-11-22
Method of making a multi-layer micro-electromechanical electrostatic actuator for producing drop-on-demand liquid emission devices Grant 6,938,310 - Hawkins , et al. September 6, 2	2005-09-06
Electrostatically actuated drop ejector Grant 6,874,867 - DeBar , et al. April 5, 2	2005-04-05
Measuring absolute static pressure at one or more positions along a microfluidic device Grant 6,843,121 - DeBar , et al. January 18, 2	2005-01-18
Method for fabricating microelectromechanical structures for liquid emission devices Grant 6,830,701 - DeBar , et al. December 14, 2	2004-12-14
Fabrication of liquid emission device with asymmetrical electrostatic mandrel Grant 6,770,211 - DeBar , et al. August 3, 2	2004-08-03
Electrostatically actuated drop ejector App 20040119782 - DeBar, Michael J. ; et al.	2004-06-24
Fabrication of liquid emission device with symmetrical electrostatic mandrel App 20040055126 - DeBar, Michael J. ; et al.	2004-03-25
Electrostatic fluid ejector with dynamic valve control Grant 6,702,209 - Furlani , et al. March 9, 2	2004-03-09
Fabrication of liquid emission device with asymmetrical electrostatic mandrel App 20040041884 - DeBar, Michael J. ; et al.	2004-03-04
Fabricating liquid emission electrostatic device using symmetrical mandrel App 20040036740 - Hawkins, Gilbert A. ; et al.	2004-02-26
Method for fabricating microelectromechanical structures for liquid emission devices App 20040008238 - DeBar, Michael J. ; et al.	2004-01-15
Electrostatic fluid ejector with dynamic valve control App 20030205630 - Furlani, Edward P. ; et al.	2003-11-06
Measuring absolute static pressure at one or more positions along a microfluidic device Grant 6,575,026 - DeBar , et al. June 10, 2	2003-06-10

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