Indianapolis, Ind., : Wiley Technology Publishing, c2010

0-470-91718-0

1-282-70827-9

9786612708275

0-470-91716-4

1 online resource (482 p.)

658.4/04028553

Project management - Computer programs

Electronic books.

Inglese

Includes index.

Project 2010 Project Management; Praise; Acknowledgments; About the Author; Contents; Table of Exercises; Introduction; How to Contact the Author; Part I: Getting Started the Right Way; Chapter 1: Project 2010 as an Enabling Tool for Project Managers; Why Do People Think Project Is Hard to Use?; When to Use Project; Strategic Importance of Project 2010; Improving Results with a Proven, Effective Approach; Summary; Key Terms; Chapter 2: Mapping the Project-Management Process Groups to Microsoft Project 2010; Mapping Project to Your Methodology Will Increase Effectiveness

An Overview of the PM Process Groups Summary; Key Terms; Chapter 3: Overview of Enterprise Project Management; What Is EPM?; EPM as a Central Repository for Resources and Projects; Understanding Roles within EPM; Summary; Chapter 4: Getting Started and Setting Up the Microsoft Project Environment; Getting Started, and Moving Around Project; Key Options and Settings You Need to Know About; Working with Calendars; Summary; Hands-On Exercises; Part II: Planning Essentials; Chapter 5: Creating and Entering the Work Breakdown Structure and Task Arrangement; What Is a WBS, and Why Is It Important?

Entering Your WBS: Phases, Tasks, and Milestones Managing Your WBS; Summary; Hands-On Exercises; Chapter 6: Estimating and Entering Duration or Work; Estimating Duration vs. Estimating Work-What's the Difference?; Program Evaluation and Review Technique; Summary; Hands-On Exercises; Chapter 7: Setting Dependencies and the Critical Path; Setting Dependencies; Using Constraints and Deadlines; Understanding and Viewing the Critical Path; Summary; Hands-On Exercises; Chapter 8: Assigning Resources and Costs; Setting Up Your Resource Pool; Assigning Resources and Costs

Analyzing Resource Usage and Resource Leveling Summary; Hands-On Exercises; Chapter 9: Understanding the Calculation Engine for Automatic Scheduling; Six Factors that Drive the Calculation of Time (Dates and Duration) for Automatic Scheduling; Four Factors that Affect the Calculation of Cost; Switching from Manual Scheduling to Automatic Scheduling; Summary; Hands-On Exercises; Part III: Communicating and Reporting Essentials; Chapter 10: Understanding Views; Understanding Major View Components; Task Views; Resource Views; Summary; Hands-On Exercises; Chapter 11: Using Tables and Custom Fields

Creating Custom Fields Using Tables and Creating Custom Tables; Summary; Hands-On Exercises; Chapter 12: Using Filters, Groups, and Sorts; Using Filters and Highlights; Using Groups; Using Sorts and Auto-filters; Summary; Hands-On Exercises; Chapter 13: Creating Custom Views, Formatting, and Reporting; Creating Custom Views; Formatting Text and Bar Styles; Sharing and Sending Project Information and Reports; Summary; Hands-On Exercises; Chapter 14: Creating Master Schedules with Inserted Projects; Creating Master Schedules; Critical Path Across Projects; Reporting and Analyzing Across Projects

Summary

The ideal on-the-job reference guide for project managers who use Microsoft Project 2010 This must-have guide to using Microsoft Project 2010 is written from a real project manager's perspective and is packed with information you can use on the job. The book explores using Project 2010 during phases of project management, reveals best practices, and walks you through project flow from planning through tracking to closure. This valuable book follows the processes defined in the PMBOK Guide, Fourth Edition, and also provides exam prep for Microsoft's MCTS: Project 2010 certificate

Chichester ; ; Hoboken, N.J., : John Wiley, c2007

9786610856015

9781280856013

1280856017

9780470512098

0470512091

9781601195227

1601195222

9780470512081

0470512083

1 online resource (457 p.)

621.38133

Microwave transistors

Radio frequency oscillators

Oscillators, Transistor

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Contents; About the Author; Preface; Acknowledgements; 1 Nonlinear circuit design methods; 1.1 SPECTRAL-DOMAIN ANALYSIS; 1.1.1 Trigonometric identities; 1.1.2 Piecewise-linear approximation; 1.1.3 Bessel functions; 1.2 TIME-DOMAIN ANALYSIS; 1.3 NEWTON-RAPHSON ALGORITHM; 1.4 QUASILINEAR METHOD; 1.5 VAN DER POL METHOD; 1.6 COMPUTER-AIDED ANALYSIS AND DESIGN; REFERENCES; 2 Oscillator operation and design principles; 2.1 STEADY-STATE OPERATION MODE; 2.2 START-UP CONDITIONS; 2.3 OSCILLATOR CONFIGURATIONS AND HISTORICAL ASPECTS; 2.4 SELF-BIAS CONDITION

2.5 OSCILLATOR ANALYSIS USING MATRIX TECHNIQUES2.5.1 Parallel feedback oscillator; 2.5.2 Series feedback oscillator; 2.6 DUAL TRANSISTOR OSCILLATORS; 2.7 TRANSMISSION-LINE OSCILLATOR; 2.8 PUSH-PUSH OSCILLATOR; 2.9 TRIPLE-PUSH OSCILLATOR; 2.10

OSCILLATOR WITH DELAY LINE; REFERENCES; 3 Stability of self-oscillations; 3.1 NEGATIVE-RESISTANCE OSCILLATOR CIRCUITS; 3.2 GENERAL SINGLE-FREQUENCY STABILITY CONDITION; 3.3 SINGLE-RESONANT CIRCUIT OSCILLATORS; 3.3.1 Series resonant circuit oscillator with constant load; 3.3.2 Parallel resonant circuit oscillator with nonlinear load

3.4 DOUBLE-RESONANT CIRCUIT OSCILLATOR3.5 STABILITY OF MULTI-RESONANT CIRCUITS; 3.5.1 General multi-frequency stability criterion; 3.5.2 Two-frequency oscillation mode and its stability; 3.5.3 Single-frequency stability of oscillator with two coupled resonant circuits; 3.5.4 Transistor oscillators with two coupled resonant circuits; 3.6 PHASE PLANE METHOD; 3.6.1 Free-running oscillations in lossless resonant LC circuits; 3.6.2 Oscillations in lossy resonant LC circuits; 3.6.3 Aperiodic process in lossy resonant LC circuits; 3.6.4 Transformer-coupled MOSFET oscillator

3.7 NYQUIST STABILITY CRITERION3.8 START-UP AND STABILITY; REFERENCES; 4 Optimum design and circuit technique; 4.1 EMPIRICAL OPTIMUM DESIGN APPROACH; 4.2 ANALYTIC OPTIMUM DESIGN APPROACH; 4.3 PARALLEL FEEDBACK OSCILLATORS; 4.3.1 Optimum oscillation condition; 4.3.2 Optimum MOSFET oscillator; 4.4 SERIES FEEDBACK BIPOLAR OSCILLATORS; 4.4.1 Optimum oscillation condition; 4.4.2 Optimum common base oscillator; 4.4.3 Quasilinear approach [23]; 4.4.4 Computer-aided design [24]; 4.5 SERIES FEEDBACK MESFET OSCILLATORS; 4.5.1 Optimum common gate oscillator; 4.5.2 Quasilinear approach [15]

4.5.3 Computer-aided design [28]4.6 HIGH-EFFICIENCY DESIGN TECHNIQUE; 4.6.1 Class C operation mode; 4.6.2 Class E power oscillators; 4.6.3 Class DE power oscillators; 4.6.4 Class F mode and harmonic tuning; 4.7 PRACTICAL OSCILLATOR SCHEMATICS; REFERENCES; 5 Noise in oscillators; 5.1 NOISE FIGURE; 5.2 FLICKER NOISE; 5.3 ACTIVE DEVICE NOISE MODELLING; 5.3.1 MOSFET devices; 5.3.2 MESFET devices; 5.3.3 Bipolar transistors; 5.4 OSCILLATOR NOISE SPECTRUM: LINEAR MODEL; 5.4.1 Parallel feedback oscillator; 5.4.2 Negative resistance oscillator; 5.4.3 Colpitts oscillator

5.5 OSCILLATOR NOISE SPECTRUM: NONLINEAR MODEL

The increase of consumer electronics and communications applications using Radio Frequency (RF) and microwave circuits has implications for oscillator design. Applications working at higher frequencies and using novel technologies have led to a demand for more robust circuits with higher performance and functionality, but decreased costs, size and power consumption. As a result, there is also a need for more efficient oscillators. This book presents up to date information on all aspects of oscillator design, enabling a selection of the best oscillator topologies with optimized noise reductio