Ramon Montano

 Ramon Montano

Ramon M. Montano

  • Courses5
  • Reviews6

Biography

San Jacinto College Central - Electrical Technology


Resume

  • 10963243

    LEED AP BD+C

    USGBC-Central Texas Balcones Chapter

    SKM PowerTools

    SKM Systems Analysis

    Inc

    Engineer in Training

    Texas Board of Professional Engineers

    Project Management Bootcamp

    PSMJ Resources

    Inc.

    OSHA 30 Hour

    Occupational Safety and Health Administration

  • 241771

    Master Electrician

    Texas Department of Licensing and Regulation

  • 2014

    Master's degree

    Electrical engineering

    University of Houston

  • 2009

    Bachelor of Science - BS (Honors)

    Electrical Engineering

    MAES SHPE IEEE Omega Delta Phi

    Inc.

    University of Houston

    Minor in Mathematics

    Electrical Engineering - Electromagnetics

    University of Houston

  • 2007

    AS

    Engineering

    San Jacinto College

  • ECE Senior Wins Outstanding Honors Thesis Award

    Ramon Montano's parents moved his family from Mexico to the United States in the early 1990's because \"they wanted us to have a good education

    \" he says. Fast forward to May 2014

    and Montano

    now an alumnus of the UH Cullen College of Engineering with a degree in electrical engineering

    was honored with the Outstanding Honors Thesis award by Dean Joseph Tedesco for his work with transparent antennas for cube satellites.

    ECE Senior Wins Outstanding Honors Thesis Award

    The new face of Odphi

    UH IEEE | Come as a student

    leave as a leader.

    UH IEEE | Come as a student

    leave as a leader.

    ACE Mentor

    C++

    BIM

    PowerPoint

    AutoCAD

    Microsoft Word

    Programming

    SKM PowerTools

    Windows

    Access

    Matlab

    Electricians

    Revit

    Microsoft Office

    HTML

    Java

    Teamwork

    Troubleshooting

    Electrical Engineering

    C

    Microsoft Excel

    Analysis of Transparent Antennas

    Analysis of Transparent Antennas

    Development of Low-Profile Antennas for CubeSats

    DC-DC converters are used in many electronics to convert a DC voltage to another DC voltage that is useable by the product

    be it a laptop

    cell phone chargers

    or in power electronics. This project was built with discrete components using the op-amp as its main device. Using feedback

    the DC voltage was stepped down and selected by the user to be within the range of 3.5 [V] - 7.5 [V]. a current of 1 [A] was maintained for a wide range of resistance from under 100 to over 1000 [Ohms]. The system began with a square AC voltage at a frequency of 50 [kHz]

    which was converted to a triangle wave via an integrator

    and used to establish a reference voltage that would be determined by the user. Filters were created to convert the AC source to a DC source

    andother factors such as the ripple voltage

    load regulation were measured. The project was 70% efficient at maintaining a [A] current through the loads with a load regulation factor of less than 10%.

    michelle gale

    Development of Low Profile Antennas for the Cube Satellite

    Senior design (capstone) project sponsored by NASA; \n\nThe objective of this project was to design low profile

    cost efficient antennas to replace the standard monopole antenna currently employed by the satellites. These monopole antennas are fragile and often break as they \"whip\" into place. Due to their mechanical dependency

    the antennas would either break during the launch process due to the excessive vibration or during deployment. Our team designed antennas for two frequency bands

    434 MHz and 2.4 GHz

    both for downlink (satellite to earth) communication. The antennas of choice were the microstrip

    commonly known as the patch antenna

    and are to be placed on the faces of the 3U CubeSat

    thereby eliminating the mechanical dependency of their predecessor and ensuring stability. Patch antennas are also superior to their monopole antennas with the only drawback of a narrow bandwidth. The antennas were successfully designed

    modeled

    and simulated using ANSYS HFSS

    providing a near ideal impedance match

    resonance at the appropriate frequency

    and sized to fit on the faces of the CubeSat.

    Karen

    Testing of Low Profile Antennas for the CubeSat

    The antenna I was responsible for during my senior design project was the 434 MHz. This specific design was fabricated and is in the process of being tested at the anechoic chamber at UH

    which will then be verified at the anechoic chamber at NASA JSC. Due to its low frequency

    the original size of the antenna would not fit on the face of the CubeSat. This issue was overcome by designing a PIFA style antenna which drastically reduced the size by nearly cutting its length in half and allowing it to fit on the long face of the Cubesat. To improve its bandwidth

    a C-notch was introduced.

    Professional Engineer Licensed in TX & Ohio. \nMaster Electrician in TX\nMasters degree in Electrical Engineering (UH) \nProfessor of Engineering at San Jacinto Community College. \nSkilled in Bluebeam

    Revit

    SKM

    AutoCAD

    Matlab

    C++.

    Ramón M.

    Montaño P.E.

    Collaborative Engineering Group

    Pieper-Houston Electric

    San Jacinto College

    Trio Electric

    Bury

    Inc.

    Integral Group

    Use AutoCAD 2016 and Revit 2016 to design systems for high end commercial/residential. \nApply NEC

    IBC

    ASHRAE

    and other applicable codes as needed. \nElectrical load calculations: power distribution

    short circuit analysis

    voltage drop

    conduit/wire sizing. \nPhotometric Analysis\nGen set sizing

    Bury

    Inc.

    Electrical Foreman

    Trio Electric

    Electrical Foreman

    Pieper-Houston Electric

    Integral Group

    Austin

    Texas

    Electrical Engineer

    Introduction of engineering disciplines

    design process

    flow charts

    technical writing and research

    and coding. \n\nTeach basic electrical theory and critical thinking for problem solving skills as applicable to the fundamentals of solving basic AC and DC circuits. \nEducate on the proper use of lab equipment

    including voltmeters

    ammeters

    ohmmeters

    oscilloscope

    frequency generators

    etc.

    San Jacinto College

    Collaborative Engineering Group

    Houston

    Texas

    Electrical Engineer

    IEEE

    Spanish

    English

    Dean's List

    Cullen College of Engineering

    University of Houston - Honors College

    University of Houston

    President - IEEE UH Student Chapter

    IEEE - UH Student Branch

    Outstanding Senior Honor's Thesis Award

ELECTRICAL

1(1)

ELPT 131110

5(1)