| 000 | 10631cam a2200433 i 4500 | ||
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| 008 | 060502s2006 enka b 001 0 eng d | ||
| 010 | _a2006926892 | ||
| 015 |
_aGBA639274 _2bnb |
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| 016 | 7 |
_a013443220 _2Uk |
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| 020 |
_a1846284589 _q(hardback) |
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| 020 |
_a1846284597 _qebook |
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| 024 | 3 |
_c9781846284588 _q(hardback) |
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| 024 | 3 | _c9781846284595 (ebook) | |
| 040 |
_aBAUN _beng _cBAUN _erda |
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| 042 | _alccopycat | ||
| 049 | _aBAUN_MERKEZ | ||
| 050 | 0 | 0 |
_aTJ225 _b.S457 2006 |
| 082 | 0 | 4 | _222 |
| 100 | 1 |
_aSira Ramírez, Hebertt J. _932 |
|
| 245 | 1 | 0 |
_aControl design techniques in power electronics devices / _cHebertt Sira-Ramírez and Ramón Silva-Ortigoza. |
| 264 | 1 |
_aLondon : _bSpringer, _cc2006. |
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| 300 |
_axvii, 423 pages : _billustrations ; _c24 cm. |
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| 336 | _2rdacontent | ||
| 337 | _2rdamedia | ||
| 338 | _2rdacarrier | ||
| 490 | 1 | _aPower systems | |
| 504 | _aIncludes bibliographical references (pages [415]-419) and index. | ||
| 505 | 0 | 0 |
_t1 Introduction _tPart I Modelling _t2 Modelling of DC-to-DC Power Converters _t2.1 Introduction _t2.2 The Buck Converter _t2.2.1 Model of the Converter _t2.2.2 Normalization _t2.2.3 Equilibrium Point and Static Transfer Function _t2.2.4 A Buck Converter Prototype _t2.3 The Boost Converter _t2.3.1 Model of the Converter _t2.3.2 Normalization _t2.3.3 Equilibrium Point and Static Transfer Function _t2.3.4 Alternative Model of the Boost Converter _t2.3.5 A Boost Converter Prototype _t2.4 The Buck-Boost Converter _t2.4.1 Model of the Converter _t2.4.2 Normalization _t2.4.3 Equilibrium Point and Static Transfer Function _t2.4.4 A Buck-Boost Converter Prototype _t2.5 The Non-inverting Buck-Boost Converter _t2.5.1 Model of the Converter _t2.5.2 Normalization _t2.5.3 Equilibrium Point and Static Transfer Function _t2.6 The Cúk Converter _t2.6.1 Model of the Converter _t2.6.2 Normalization _t2.6.3 Equilibrium Point and Static Transfer Function _t2.7 The Sepic Converter _t2.7.1 Model of the Converter _t2.7.2 Normalization _t2.7.3 Equilibrium Point and Static Transfer Function _t2.8 The Zeta Converter _t2.8.1 Model of the Converter _t2.8.2 Normalization _t2.8.3 Equilibrium Point and Static Transfer Function _t2.9 The Quadratic Buck Converter _t2.9.1 Model of the Converter _t2.9.2 Normalized Model _t2.9.3 Equilibrium Point _t2.9.4 Static Transfer Function _t2.10 The Boost-Boost Converter _t2.10.1 Model of the Boost-Boost Converter _t2.10.2 Average Normalized Model _t2.10.3 Equilibrium Point and Static Transfer Function _t2.10.4 Alternative Model of the Boost-Boost Converter _t2.10.5 A Boost-Boost Converter Experimental Prototype _t2.11 The Double Buck-Boost Converter _t2.11.1 Model of the Double Buck-Boost Converter _t2.11.2 Average Normalized Model _t2.11.3 Equilibrium Point and Static Transfer Function _t2.12 Power Converter Models with Non-ideal Components _t2.13 A General Mathematical Model for Power Electronics Devices _t2.13.1 Some Illustrative Examples of the General Model _tPart II Controller Design Methods _t3 Sliding Mode Control _t3.1 Introduction _t3.2 Variable Structure Systems _t3.2.1 Control of Single Switch Regulated Systems _t3.2.2 Sliding Surfaces _t3.2.3 Notation _t3.2.4 Equivalent Control and the Ideal Sliding Dynamics _t3.2.5 Accessibility of the Sliding Surface _t3.2.6 Invariance Conditions for Matched Perturbations _t3.3 Control of the Boost Converter _t3.3.1 Direct Control _t3.3.2 Indirect Control _t3.3.3 Simulations _t3.3.4 Experimental Implementation _t3.4 Control of the Buck-Boost Converter _t3.4.1 Direct Control _t3.4.2 Indirect Control _t3.4.3 Simulations _t3.5 Control of the Cúk Converter _t3.5.1 Direct Control _t3.5.2 Indirect Control _t3.5.3 Simulations _t3.6 Control of the Zeta Converter _t3.6.1 Direct Control _t3.6.2 Indirect Control _t3.6.3 Simulations _t3.7 Control of the Quadratic Buck Converter _t3.7.1 Direct Control _t3.7.2 Indirect Control _t3.7.3 Simulations _t3.8 Multi-variable Case _t3.8.1 Sliding Surfaces _t3.8.2 Equivalent Control and Ideal Sliding Dynamics _t3.8.3 Invariance with Respect to Matched Perturbations _t3.8.4 Accessibility of the Sliding Surface _t3.9 Control of the Boost-Boost Converter _t3.9.1 Direct Control _t3.9.2 Indirect Control _t3.9.3 Simulations _t3.9.4 Experimental Sliding Mode Control Implementation _t3.10 Control of the Double Buck-Boost Converter _t3.10.1 Direct Control _t3.10.2 Indirect Control _t3.10.3 Simulations _t3.11 Σ – Δ Modulation _t3.11.1 Σ – Δ-Modulators _t3.11.2 Average Feedbacks and Σ – Δ-Modulation _t3.11.3 A Hardware Realization of a Σ – Δ-Modulator _t4 Approximate Linearization in the Control of Power Electronics Devices _t4.1 Introduction _t4.2 Linear Feedback Control _t4.2.1 Pole Placement by Full State Feedback _t4.2.2 Pole Placement Based on Observer Design _t4.2.3 Reduced Order Observers _t4.2.4 Flatness _t4.2.5 Generalized Proportional Integral Controllers _t4.2.6 Passivity Based Control _t4.2.7 A Hamiltonian Systems Viewpoint _t4.3 The Buck Converter _t4.3.1 Generalities about the Average Normalized Model _t4.3.2 Controller Design by Pole Placement _t4.3.3 Proportional-Derivative Control via State Feedback _t4.3.4 Trajectory Tracking _t4.3.5 Fliess' Generalized Canonical Forms _t4.3.6 State Feedback Control via Observer Design _t4.3.7 GPI Controller Design _t4.3.8 Passivity Based Control _t4.3.9 The Hamiltonian Systems Viewpoint _t4.3.10 Implementation of the Linear Passivity Based Control for the Buck Converter _t4.4 The Boost Converter _t4.4.1 Generalities about the Average Normalized Model _t4.4.2 Control via State Feedback _t4.4.3 Proportional-Derivative State Feedback Control _t4.4.4 Trajectory Tracking _t4.4.5 Fliess' Generalized Canonical Form _t4.4.6 State Feedback Control via Observer Design _t4.4.7 GPI Controller Design _t4.4.8 Passivity Based Control _t4.4.9 The Hamiltonian Systems Viewpoint _t4.5 The Buck-Boost Converter _t4.5.1 Generalities about the Model _t4.5.2 State Feedback Controller Design _t4.5.3 Dynamic Proportional-Derivative State Feedback Control _t4.5.4 Trajectory Tracking _t4.5.5 Fliess' Generalized Canonical Forms _t4.5.6 Control via Observer Design _t4.5.7 GPI Controller Design _t4.5.8 Passivity Based Control _t4.5.9 The Hamiltonian Systems Viewpoint _t4.5.10 Experimental Passivity based Control of the Buck-Boost Converter _t4.6 The Cúk Converter _t4.6.1 Generalities about the Model _t4.6.2 The Hamiltonian System Approach _t4.7 The Zeta Converter _t4.7.1 Generalities about the Model _t4.7.2 The Hamiltonian System Approach _t4.8 The Quadratic Buck Converter _t4.8.1 Generalities about the Model _t4.8.2 State Feedback Controller Design _t4.8.3 The Hamiltonian System Approach _t4.9 The Boost-Boost Converter _t4.9.1 Generalities about the Model _t4.9.2 The Hamiltonian System Approach _t5 Nonlinear Methods in the Control of Power Electronics Devices _t5.1 Introduction _t5.2 Feedback Linearization _t5.2.1 Isidori's Canonical Form _t5.2.2 Input-Output Feedback Linearization _t5.2.3 State Feedback Linearization _t5.2.4 The Boost Converter _t5.2.5 The Buck-Boost Converter _t5.2.6 The Cúk Converter _t5.2.7 The Sepic Converter _t5.2.8 The Zeta Converter _t5.2.9 The Quadratic Buck Converter _t5.3 Passivity Based Control _t5.3.1 The Boost Converter _t5.3.2 The Buck-Boost Converter _t5.3.3 The Cúk Converter _t5.3.4 The Sepic Converter _t5.3.5 The Zeta Converter _t5.3.6 The Quadratic Buck Converter _t5.4 Exact Error Dynamics Passive Output Feedback Control _t5.4.1 A General Result _t5.4.2 The Boost Converter _t5.4.3 Experimental Implementation _t5.4.4 The Buck-Boost Converter _t5.4.5 The Cúk Converter _t5.4.6 The Sepic Converter _t5.4.7 The Zeta Converter _t5.4.8 The Quadratic Buck Converter _t5.4.9 The Boost-Boost Converter _t5.4.10 The Double Buck-Boost Converter _t5.5 Error Dynamics Passive Output Feedback _t5.5.1 The Boost Converter _t5.5.2 Experimental Results _t5.6 Control via Fliess' Generalized Canonical Form _t5.6.1 The Boost Converter _t5.6.2 The Buck-Boost Converter _t5.6.3 The Quadratic Buck Converter _t5.7 Nonlinear Observers for Power Converters _t5.7.1 Full Order Observers _t5.7.2 The Boost Converter _t5.7.3 The Buck-Boost Converter _t5.8 Reduced Order Observers _t5.8.1 The Boost Converter _t5.8.2 The Buck-Boost Converter _t5.9 GPI Sliding Mode Control _t5.9.1 The Buck Converter _t5.9.2 The Boost Converter _t5.9.3 The Buck-Boost Converter _tPart III Applications _t6 DC-to-AC Power Conversion _t6.1 Introduction _t6.2 Nominal Trajectories in DC-to-AC Power Conversion _t6.2.1 The Buck Converter _t6.2.2 Two-Sided Σ – Δ Modulation _t6.2.3 The Boost Converter _t6.2.4 The Buck-Boost Converter _t6.3 An Approximate Linearization Approach _t6.3.1 The Boost Converter _t6.3.2 The Buck-Boost Converter _t6.4 A Flatness Based Approach _t6.4.1 The Double Bridge Buck Converter _t6.4.2 The Boost Converter _t6.4.3 The Buck-Boost Converter _t6.5 A Sliding Mode Control Approach _t6.5.1 The Boost Converter _t6.5.2 A Feasible Indirect Input Current Tracking Approach _t6.6 Exact Tracking. |
| 505 | 0 | 0 |
_tError Dynamics Passive Output Feedback Control _t6.6.1 The Double Bridge Buck Converter _t6.6.2 The Boost Converter _t6.6.3 The Buck-Boost Converter _t7 AC Rectifiers _t7.1 Introduction _t7.2 Boost Unit Power Factor Rectifier _t7.2.1 Model of the Monophasic Boost Rectifier _t7.2.2 The Control Objectives _t7.2.3 Steady State Considerations _t7.2.4 Exact Open Loop Tracking Error Dynamics and Controller Design _t7.2.5 Simulations _t7.2.6 The Use of the Differential Flatness Property in the Passive Controller Design _t7.2.7 Simulations _t7.3 Three Phase Boost Rectifier _t7.3.1 The Three Phase Boost Rectifier Average Model _t7.3.2 A Static Passivity Based Controller _t7.3.3 Trajectory Planning _t7.3.4 Switched Implementation of the Average Design _t7.3.5 Simulations _t7.4 A Unit Power Factor Rectifier-DC Motor System _t7.4.1 The Combined Rectifier-DC Motor Model _t7.4.2 The Exact Tracking Error Dynamics Passive Output Feedback Controller _t7.4.3 Trajectory Generation _t7.4.4 Simulations _t7.5 A Three Phase Rectifier-DC Motor System _t7.5.1 The Combined Three Phase Rectifier DC Motor Model _t7.5.2 The Exact Tracking Error Dynamics Passive Output Feedback Controller _t7.5.3 Trajectory Generation _t7.5.4 Simulations _tReferences _tIndex |
| 650 | 0 | _aElectronic control. | |
| 650 | 0 |
_aElectronic controllers _xDesign and construction. |
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| 700 | 1 | _aSilva-Ortigoza, Ramón. | |
| 830 | 0 |
_9108464 _aPower systems. |
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| 856 | 4 | 1 |
_3Table of contents only _uhttp://www.loc.gov/catdir/enhancements/fy0824/2006926892-t.html |
| 856 | 4 | 2 |
_3Contributor biographical information _uhttp://www.loc.gov/catdir/enhancements/fy0824/2006926892-b.html |
| 856 | 4 | 2 |
_3Publisher description _uhttp://www.loc.gov/catdir/enhancements/fy0824/2006926892-d.html |
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_c19139 _d19139 |
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