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Philip Ray Stetson

from Archdale, NC
Age ~65
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Also known as:
Philip R Stetson, Philip Hermina Stetson, Phil Stetson, Phillip R Stetson
Related to:
Herminia StetsonPhillip Stetson
Connected to:
Brian W Stetson, 41Butch Stetson, 56Charles N Stetson, 93Heidi M Stetson, 38Karla M Stetson, 52Marian A Stetson, 79Matthew J Stetson, 48Melissa A Stetson, 44Peter B Stetson, 40Tamera O Stetson, 61

Philip Stetson Phones & Addresses

  • Archdale, NC
  • 102 Apolla Dr, Morgantown, WV 26501
  • 465 Civitan St, Morgantown, WV 26505
  • 1113 Wild Cherry Dr, Carrollton, TX 75010 (469) 878-3488
  • 4901 93Rd Ave, Westminster, CO 80031
  • 452 Buckskin Ct, Winter Springs, FL 32708
  • Denton, TX

Resumes

Resumes

Philip Stetson Photo 1

Parts Manager

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Location:
Houston, TX
Industry:
Automotive
Work:
Vann York Toyota Inc
Parts Manager
Lone Star Ford Feb 2015 - Mar 2016
Parts Manager
Randall Reed's Prestige Ford Jan 2013 - Sep 2014
Parts Director
Vandergriff Toyota Nov 2010 - Sep 2013
Parts Director
Toyota of Dallas Sep 2003 - May 2010
Parts Director
Education:
University of Toyota 1990 - 2012
Masters, Management University of Toyota 1997 - 1998
Usaf School of Aviation Electronics 1980 - 1981
Pungo Christian Academy
Skills:
Automotive Aftermarket
Automotive
Parts
Vehicles
Dealers
Customer Retention
Customer Satisfaction
Dealer Management
Inventory Management
Automobile
Operations Management
Profit
Team Building
Sales
Sales Management
Warranty
Sales Operations
Automotive Repair
Automotive Parts
Reynolds
Purchasing
Management
New Business Development
Automotive Products
Sales Process
Dealer Operations
Collision
Customer Service
Negotiation
Tires
Powertrain
Spare Parts
Nissan
Process Improvement
Chassis
Motorsports
Gross Profit
Automotive Sales Training
Automotive Electronics
Advertising
Start Ups
Aftersales
Suspension
Fleet Management
Service Parts
Account Management
Brake
Ase Certified
Forecasting
Supply Chain
Interests:
Off Road Overland Travel
Boating
Automotive
Camping
Woodworking
Fishing
Philip Stetson Photo 2

Director Of Oversight And Resource

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Work:
Usda
Director of Oversight and Resource Management

Director of Oversight and Resource

Publications

Us Patents

Data Acquisition System Using Predictive Conversion

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US Patent:
6590513, Jul 8, 2003
Filed:
May 8, 2002
Appl. No.:
10/141394
Inventors:
Philip S. Stetson - Garland TX
Teddy D. Thomas - Dallas TX
Assignee:
Texas Instruments Incorporated - Dallas TX
International Classification:
H03M 300
US Classification:
341143, 341155
Abstract:
A data acquisition system uses an analog-to-digital converter (ADC) that includes a prediction feedback element. Using the computing power of a digital signal processor, the system predicts the next sample of the target signal based on pre-defined rules and previous samples. This digital prediction is converted to an analog signal using a digital-to-analog converter (DAC). An analog error summer compares the predicted signal with the target signal and creates an error signal. The digital signal processor uses the prediction error to more accurately predict the next sample. A negative feedback loop is thus formed by this system to drive the prediction error toward zero. Operating on the relatively small error signal in the forward and feedback paths enhances the conversion performance and data transfer efficiency.

Ultra-Low Distortion, Wide-Bandwidth Amplifier Architecture Using Actively Phase-Matched Feed-Forward Linearization

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US Patent:
6788140, Sep 7, 2004
Filed:
Jan 21, 2003
Appl. No.:
10/348147
Inventors:
Jay K. Cameron - Dallas TX
Philip S. Stetson - Garland TX
Assignee:
Texas Instruments Incorporated - Dallas TX
International Classification:
H03F 126
US Classification:
330149, 330151
Abstract:
An amplifier architecture using actively phase-matched feed-forward linearization includes: a first signal path having a scaling amplifier in series with a main amplifier ; a second signal path having a replica amplifier in series with a correction amplifier ; and a combining node that combines the first signal path and the second signal path. This topology places the scaling amplifier in the main signal path. By inverting the scaling factor from to 1/, this topology retains the distortion cancellation property while balancing the two signal paths. In this case the scaling amplifier attenuates the input signal rather than amplifying it. The end result remains the same. The main amplifier output signal is lower than the replica amplifiers by a factor of. This results in a third-order distortion component that is times bigger at the replica amplifier output. By correcting this level down to that at the main amplifier , the fundamental component in the feed-forward path is significantly attenuated.

Tunable Filter To Facilitate Communications

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US Patent:
7457258, Nov 25, 2008
Filed:
Dec 31, 2003
Appl. No.:
10/749201
Inventors:
Philip Sean Stetson - Garland TX, US
Richard Knight Hester - McKinney TX, US
Assignee:
Texas Instruments Incorporated - Dallas TX
International Classification:
H04B 3/20
US Classification:
370286
Abstract:
Systems and methods are described herein for changing the frequency response of a filter, such as a hybrid circuit. One or more tunable components are adjustable to provide the hybrid circuit with a frequency response corresponding to the characteristics of an associated communications network, such as a digital subscriber link.

Method And Apparatus For Effecting Programmable Gain Amplification

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US Patent:
20020011897, Jan 31, 2002
Filed:
Jun 22, 2001
Appl. No.:
09/887795
Inventors:
Neil Gibson - Richardson TX, US
Marco Corsi - Parker TX, US
Philip Stetson - Garland TX, US
James Quarfoot - Richardson TX, US
International Classification:
H03F003/45
US Classification:
330/051000, 330/254000
Abstract:
A programmable gain amplifier () has a differential input (-), a differential output (-), and a plurality of enable inputs (-). The amplifier includes a plurality of transconductor sections (-), which each have input nodes coupled to the differential input, output nodes coupled to the differential output, and an enable node coupled to a respective enable signal. The transconductor sections have different gains, which are respective powers of two. Each transconductor section includes a transconductor circuit () which is coupled in series with at least one current mirror circuit (--). Each transconductor circuit has a transistor () with a class A quiescent current that is proportional to the corresponding gain, the transistor being sized to achieve an optimum current density for its quiescent current. Each such transistor has two terminals coupled to other circuitry within the transconductor circuit, and a third terminal coupled only to the associated current mirror circuit.
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Philip Ray Stetson from Archdale, NC, age ~65 Get Report