Sample Template Example of Beautiful Excellent Professional Curriculum Vitae / Resume / CV Format with Career Objective, Job Description, Skills & Work Experience for Freshers & Experienced in Word / Doc / Pdf Free Download
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Objective: A full-time mechanical engineering job utilizing my experience
in nanotechnology, MEMS, and product development to contribute to an innovative
technology company.
Education: University of Colorado at Boulder, Boulder CO
PhD
Candidate in Mechanical Engineering with Emphasis in Micro Electromechanical
Systems (MEMS), August 2002 – August 2004, GPA 3.55/4.0
Rose-Hulman Institute of
Technology, Terre Haute IN
Bachelor
of Science Mechanical Engineering with Certification in Semiconductors,
February 2002, GPA 3.56/4.0
Technical Skills:
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Knowledge of Windows 2000/XP/7, MS Office, VBASIC, C++, FORTRAN
90/95, SAP, MatLab, Maple, ANSYS, Working Model 2D, Solid Works, ProEngineer,
PDM Works, WildFire, AutoCAD, Coventorware, SEM, Wet Lab, Cleanroom, Statistical
Process Control, Technical Writing/Editing, Public Speaking,
Multi-Disciplinary Design, Team Leader/Member, Prototyping, ASME Y14.5-1995,
GD&T
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Work Experience:
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Medical Device Mechanical Engineer, FlexMedical, Plano, TX
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Re-designed and
improved high vacuum gas chromatograph mass spectrometer system for client,
including chamber sealing, high voltage detector tolerance analysis,
materials recommendations and thermal isolation
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Optical Air In-Line
sensor design, testing, and prototyping, utilizing Fresnel and Snell equations
and design of custom X-Y-Theta precision test fixture
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High speed motor noise
reduction including innovative integral gear damping design, drive train
analysis, acoustic measurements and statistical data analysis
Low Voltage Switchgear Mechanical Engineer, Siemens Industry, Grand Prairie, TX
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Sep. ’10 - Present
Oct.
’08 – Sep. ‘10
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Developed and implemented numerous productivity
enhancing process automations for Engineering and other departments to assist
in interfacing with logistics data, BOM verification, design methodology and
results reporting
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Designed industrial and critical power
distribution systems meeting multiple safety codes and standards, customer
specifications, and internal design protocol with emphasis on lowering costs,
reducing errors, and balancing standard designs with the necessity for custom
solutions
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Six months of shop-floor experience doing full
system Quality Assurance testing on Switchboards, Switchgear, and Power
Panels, including verification of design, code compliance, and functionality
for interrelated electromechanical products
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Created process
improvement plans and trained Engineering groups as member of a three person,
50% for one year assignment to an Engineering error reduction team, utilizing
data collection and analysis, and corrective action implementation and
tracking across a 40 person department, interacting with Production,
Purchasing, Management, and Quality Assurance
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Product Development and
Applications Engineer, Zyvex Instruments,
Richardson, TX
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Aug. ‘04 – Oct. ‘08
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Designed numerous
components for high precision, vacuum compatible robotics systems including
electrical and mechanical feedthroughs, nanometer resolution positioner
components, and various test fixtures
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Integral in total design
cycle including creation of site survey documents, solution conception and
design for cost and manufacturability, final design verification, and drawing
release to internal/external machine shops
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Lead design reviews for
entire product development team including project managers, electrical and software engineers, mechanical
designers, machinists, and applications scientists
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Performed detailed
nanoscale electrical and mechanical investigations of semiconductor, nano
material, and nano-mechanical devices resulting in comprehensive technical
reports to potential customers worldwide
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Developed and
implemented improved process for electrochemically etched nano probes
resulting in a 20% yield increase to 95% passing
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Trained customers and
new employees on SEM, nanomanipulation, electrochemical etching, electrical
test equipment and data analysis
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Co-inventor on core
technology patent, US Patent #7,319,336, Charged
particle beam device probe operation
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MEMS Graduate
Researcher, PhD Candidate, Univ. of
Colorado, Boulder CO
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Aug. ‘02 – Aug. ‘04
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Designed and developed in-situ
MEMS-based mechanical measurement of individual carbon nanotubes
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Investigated electron
beam deposited material with FTIR spectroscopy
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Collaborated with NIST
researchers on AFM analysis of nanotubes
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Packaged MEMS for
actuation in both SEM and optical microscopes, including flip-chip and wire
bonding
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Managed simulation lab
with 30 users and 20 networked PCs
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MEMS Engineer, Zyvex Corporation, Richardson TX
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Mar. ‘02 – Aug. ‘02
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Designed 50 MEMS devices for surface and bulk
micromachining (MUMPs and DRIE)
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Contributed
to design reviews as part of the engineering group
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Specified
and designed micro optics system for 5 DOF precision robotics
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Characterized and
released MEMS in class 100 clean room
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Professional Achievements and Interests:
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Device
Design and Modeling Including Finite Element and Analytical Modeling of
Multiphysics Systems
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Interests in finite element analysis for device
design and characterization, topology optimization for mechanical systems,
and atomistic modeling of nano structures
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Custom code developed for ANSYS to analyze non
linear, mechanical, electrostatic, thermal, and electrothermal systems
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Parametric optimization of piezo based flexure
actuator for next generation replacement in encoded, nanometer step size,
millimeter travel nanopositioning system
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Integration and calibration of a strain-gauge
based AFM sensor as part of a custom force characterization package including
both custom and off-the-shelf electronics packaging and user manual
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High fidelity modeling of complex MEMS geometries
coupled to fully 3D finite element analysis and experimental measurements to
determine mechanical effect of non-ideal anchors in MEMS resonators
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Coventorware MEMS simulation software used to
design surface and bulk micromachined devices
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Mechanical test device for CNTs designed and
simulated in MEMS II class
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Learned and applied Rayleigh-Ritz methods, both
analytically and numerically, in Advanced Mechanics for Microsystem Design
class
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In-situ Manipulation, Attachment, and Mechanical
Measurement of Single CNTs
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A. Hartman, et al.,
Force-Deflection Characterization of Individual Carbon Nanotubes Attached to
MEMS Devices, IEEE MEMS 2004 Conference, Jan. 2004.
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Nanotechnology, 18, 2007.
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Surface micromachined devices fabricated to apply
tensile loads to individual nanotubes and measure the resulting tube strain
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Additional devices produced for thermal and
electrical conductivity measurement of carbon nanotubes
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Bulk micromachined devices created to strain tubes
over a through-wafer hole, allowing investigation of nanotube lattice
deformation and defect movement in real time inside a TEM
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Devices also made to apply torsional loads to CNTs
in order to characterize their rotational spring properties
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Electron beam induced deposition (EBID) applied to
permanently attach single CNTs to MEMS structures and micro manipulator
probes
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Work on EBID materials characterization included
in NIST Boulder, Materials Reliability Division annual report to US Congress
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In-situ nano-manipulation using both piezo stack
and stick-slip systems to remove CNTs from a prepared sample, position them
at a desired location, and apply mechanical loads
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Multidisciplinary topics integrating molecular
biological, nano scale, and micro scale systems studied in a class taught
jointly by Mechanical Engineering and Molecular Biology professors
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Interests in mechanical
testing of single bio-molecules, DNA, cells, and nano structures
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