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Jason Christopher Soric

from North Andover, MA
Age ~48
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Also known as:
Jason C Soric
Related to:
Maryellen Ellen Lee, 70
Connected to:
Angelo T Sorice, 88Anne M Sorice, 64Cory J Sorice, 54Destiny L Sorice, 40John J Sorice, 66Michele Sorice, 109Molly A Sorice, 49Joseph L Soricelli, 66Barbara C Sorich, 94Irene Sorich, 70

Jason Soric Phones & Addresses

  • North Andover, MA
  • Andover, MA
  • Bedford, MA
  • 5624 Woodrow St, Austin, TX 78756 (512) 452-9328
  • 1002 Neans Dr, Austin, TX 78758
  • Cedar Park, TX
  • San Antonio, TX
  • Pflugerville, TX
  • 5624 Woodrow Ave, Austin, TX 78756 (512) 786-1140

Work

Company: Raytheon Sep 2018 Position: Senior electrical engineer ii

Education

Degree: Doctorates, Doctor of Philosophy School / High School: The University of Texas at Austin 2017 to 2021

Skills

Electromagnetics • Simulations • Testing • Characterization • Matlab • Sensors • Cst Microwave Studio • Antenna Design • Signal Processing • Circuit Design • Teaching • Comsol • Mathematica • Ads • Latex • Labview • Fanuc Robotics • Hfss • Additive Manufacturing

Interests

Health

Emails

j***[email protected]

Industries

Defense & Space

Resumes

Resumes

Jason Soric Photo 1

Senior Electrical Engineer Ii

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Location:
Andover, MA
Industry:
Defense & Space
Work:
Raytheon
Senior Electrical Engineer Ii
The University of Texas at Austin Dec 2010 - Aug 2015
Phd Candidate
The University of Texas at Austin Jun 2008 - Aug 2014
Teaching Assistant
Ets-Lindgren Jun 2013 - Aug 2013
Graduate Intern
Harris Corporation May 2006 - Aug 2007
Manufacturing Engineer
Education:
The University of Texas at Austin 2017 - 2021
Doctorates, Doctor of Philosophy The University of Texas at Austin 2011 - 2015
Doctorates, Doctor of Philosophy The University of Texas at Austin 2010 - 2015
Doctorates, Doctor of Philosophy The University of Texas at Austin 2008 - 2010
Masters, Master of Science In Electrical Engineering, Design The University of Texas at Austin 2003 - 2006
Bachelors, Bachelor of Science
Skills:
Electromagnetics
Simulations
Testing
Characterization
Matlab
Sensors
Cst Microwave Studio
Antenna Design
Signal Processing
Circuit Design
Teaching
Comsol
Mathematica
Ads
Latex
Labview
Fanuc Robotics
Hfss
Additive Manufacturing
Interests:
Health

Publications

Us Patents

Reconfigurable Wideband High-Frequency Circuits Using Non-Reciprocal Circulators

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US Patent:
20210384598, Dec 9, 2021
Filed:
May 4, 2021
Appl. No.:
17/307237
Inventors:
- Waltham MA, US
Zhaoyang C. Wang - Carlisle MA, US
Jason C. Soric - North Andover MA, US
Matthew A. Morton - Lynnfield MA, US
International Classification:
H01P 1/38
H01P 1/18
Abstract:
A method includes receiving a radio frequency (RF) input signal using at least one non-reciprocal circulator. The method also includes generating an RF output signal using at least one of one or more reflective circuit elements. Each reflective circuit element is configured to receive an RF signal from the at least one non-reciprocal circulator and to provide a modified RF signal to the at least one non-reciprocal circulator. The RF output signal represents the RF input signal as modified by the at least one of the one or more reflective circuit elements.

Reconfigurable Wideband High-Frequency Filter Using Non-Reciprocal Circulator

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US Patent:
20210384599, Dec 9, 2021
Filed:
May 4, 2021
Appl. No.:
17/307261
Inventors:
- Waltham MA, US
Ajay Subramanian - Nashua NH, US
Jason C. Soric - North Andover MA, US
Matthew A. Morton - Lynnfield MA, US
International Classification:
H01P 1/38
H03H 11/04
Abstract:
A method includes receiving a radio frequency (RF) input signal using at least one non-reciprocal circulator. The method also includes generating an RF output signal using at least one of multiple reflective filter elements. Each reflective filter element is configured to receive an RF signal from the at least one non-reciprocal circulator and to provide a filtered RF signal to the at least one non-reciprocal circulator. The reflective filter elements include amplitude change reflectors configured to modify amplitudes of the RF signal at different frequencies. The RF output signal represents the RF input signal as modified by the at least one of the reflective filter elements.

Biplanar Tapered Line Frequency Selective Limiter

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US Patent:
20190393578, Dec 26, 2019
Filed:
Jun 26, 2018
Appl. No.:
16/018768
Inventors:
- Waltham MA, US
Gerhard Sollner - Winchester MA, US
Jason C. Soric - Bedford MA, US
Assignee:
Raytheon Company - Waltham MA
International Classification:
H01P 1/23
H01P 3/08
H01P 11/00
Abstract:
A frequency selective limiter (FSL) is provided having a transmission line structure with a tapered width. The FSL includes a magnetic material having first and second opposing surfaces. A first conductor is disposed on the first surface of the magnetic material, where a width of the first conductor decreases from a first end of the FSL to a second end of the FSL along a length of the FSL. Two second conductors are disposed on the second surface of the magnetic material, where a width of a gap between the two second conductors decreases from the first end of the FSL to the second end of the FSL along a length of the FSL. The first conductor and two second conductors form a biplanar waveguide transmission line.

Transmission Line Transformers

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US Patent:
20180191325, Jul 5, 2018
Filed:
Jan 3, 2017
Appl. No.:
15/397194
Inventors:
- Waltham MA, US
Thomas B. Reed - North Reading MA, US
Jason C. Soric - Bedford MA, US
Assignee:
Raytheon Company - Waltham MA
International Classification:
H03H 7/42
H01F 27/29
H01P 3/06
Abstract:
A transmission line transformer having a time delay network having a signal terminal and a pair of output terminals connected to the signal terminal through a corresponding one of a pair of time delay elements, the delay line elements having different time delays. A pair of transmission lines, each one having a pair of electrically coupled elements. A first one of the elements in one of the transmission lines has a first end connected to one of the pair of output terminals. A second one of the elements in such one of the transmission lines has a second end connected to a second end of one of the pair of elements in the other one of the transmission lines. The first one of the pair of elements in the other one of the pair of transmission lines is coupled to a second one of the pair of output terminals.

Dielectric-Core Antennas Surrounded By Patterned Metallic Metasurfaces To Realize Radio-Transparent Antennas

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US Patent:
20170373385, Dec 28, 2017
Filed:
Sep 22, 2015
Appl. No.:
15/524222
Inventors:
- Austin TX, US
Jason Soric - Austin TX, US
Scott Michaelis - Allen TX, US
Igor Timofeev - Richardson TX, US
Nikolay Chistyakov - Plano TX, US
International Classification:
H01Q 1/38
H01Q 15/00
H01Q 9/28
H01Q 1/42
H01Q 9/02
Abstract:
A transparent dielectric-core antenna surrounded by patterned metallic metasurfaces. The patterned metallic metasurface acts as a conductive medium for surface current to flow and efficiently radiate fields driven by a power source. Furthermore, the patterned metallic metasurface can strongly reduce the electrical presence of the dielectric-core to realize a radio-transparent antenna to nearby systems at any desired frequency band while still maintaining good radiation and matching properties. Such an antenna concept may be applied to a variety of geometries.

Eliminating Reciprocity Constraints In Radiating And Scattering Systems With Spatio-Temporal Modulation

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US Patent:
20170237175, Aug 17, 2017
Filed:
Jul 15, 2016
Appl. No.:
15/212023
Inventors:
- Austin TX, US
Yakir Hadad - Austin TX, US
Jason Christopher Soric - Austin TX, US
International Classification:
H01Q 13/10
H01Q 21/00
H01P 3/00
Abstract:
A non-reciprocal device using a space-time modulation scheme. By applying the space-time modulation scheme, reciprocity in radiation and scattering scenarios is prevented. Such a scheme utilizes a linear system with simple, compact and inexpensive electronic components compared to the current use of bulky duplexers and non-reciprocal magnet based phase shifters to provide non-reciprocity. One such linear system involves traveling-wave antennas loaded with voltage dependent capacitors that are modulated in space and time thereby allowing the antenna to transmit with high directivity in a certain direction and not receive from that direction. Another linear system involves a resonant metasurface characterized by transverse spatiotemporal gradients, where the spatiotemporal gradients include periodically modulated impedances thereby causing a non-reciprocal transmission response. In this manner, a signal that propagates and impinges on the surface at a given direction will be fully transmitted while a signal propagating from the complementary direction will be fully reflected.

Dual-Polarized, Broadband Metasurface Cloaks For Antenna Applications

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US Patent:
20160111782, Apr 21, 2016
Filed:
Sep 3, 2015
Appl. No.:
14/844243
Inventors:
- Austin TX, US
Jason Soric - Austin TX, US
International Classification:
H01Q 5/20
H01Q 9/04
H01Q 15/00
H01Q 5/48
Abstract:
A communication system that reduces the mutual influence of antennas operating in similar or different frequency bands. The communication system includes a first and a second antenna operating in a first and a second frequency band, respectively, and placed in close proximity to each other. The first antenna is covered by a conformal mantle metasurface with anti-phase scattering properties thereby cancelling the scattering in the second frequency band. The conformal mantle metasurface consists of a patterned metallic sheet comprising slits both in an azimuthal and a vertical direction to reduce both vertical and horizontal polarization scattering. When the first antenna is a low-band dipole antenna and when the second antenna is a high-band dipole antenna, the conformal mantle metasurface reduces the low-band blockage without disrupting the performance of both antennas in terms of radiation pattern and impedance matching.
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Jason Christopher Soric from North Andover, MA, age ~48 Get Report