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AN ABSTRACT OF A DISSERTAION AN INV
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coupling and interaction terms are
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CERTIFICATE OF APPROVAL OF DISSERTA
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ACKNOWLEDGEMENTS I would like to ex
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vi Page 2.2 Machine Design I.......
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viii Page 4.2.3 Self Inductances of
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x Page 7.3.4 f = 30 Hz and f = 95 H
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xii Page 10.8 D-decomposition Metho
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LIST OF FIGURES xiv Page Figure 1.1
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Figure 3.10 The simulation of the s
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Figure 3.34 Measured flux densities
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xx Page Figure 4.8 Self-inductance
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Figure 5.2. Simulation results for
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Figure 6.8. The dynamic response of
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Figure 7.22. Copper losses of the m
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Figure 8.7. The dynamic response of
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Figure 9.4 Steady state analysis, (
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Figure 9.12. The steady state wavef
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xxxiv Page Figure 10.16 Pole-zero m
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Figure 11.2 Per phase equivalent ci
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CHAPTER 1 INTRODUCTION AND LITERATU
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The last is the recently developed
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It should be noted that at any time
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A. R. Munoz and T.A. Lipo are pione
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has to be modified to adapt to thes
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circuit model of an induction machi
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ωr stator rotor 13 ωr rotor (a) (
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1.2.4 Field Analysis Method In [5.1
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separated dc source, etc. From the
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in [8.14]. In [8.15-8.17], the stud
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[8.22] and the total losses of the
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proposed. The switching frequency i
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The actual rotor mechanical speed i
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1.2.9 Induction Machine Drive---Vec
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stator windings were used as flux s
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The rotor flux can be obtained by:
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The basic idea of a closed loop flu
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estimation. It has been claimed in
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{ k [ ˆ* ( i iˆ ) ] ( k) [ ˆ* Im
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integral and a new stretch-turn ope
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The most recent overview paper is g
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CHAPTER 2 DUAL STATOR WINDING INDUC
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Table 2.1 Parameters of machine des
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A C B 2.2.2 Air Gap Flux Density X
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where, ω s1 and s2 respectively.
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There are two unknown variables in
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Since small machines typically have
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N s E = (2.18) 4. 44 fK φ 1 m Flux
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conduct away the heat produced in t
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k cs τ s = 2 2b ⎪ ⎧ ⎡ ⎤⎪
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are: Fts = H ts( ave) d s ( ave) =
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1 2 1 = H o ( ) + H o ( ) + H cr 90
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The skew of the stator winding is n
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0 bs Figure 2.5. Detailed stator sl
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y: The pole pitch at the mid point
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L lsk = L m ( α 2) ⎪⎧ ⎡sin
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2.3.4 Rotor Bar Resistance r b The
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2.3.7 Rotor Resistance Referred to
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Substituting δ = π into (2.97) an
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atio also increases. The air gap fl
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From (2.105-2.108), the ratio of th
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2.5 Conclusions In this chapter, a
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A recently developed dual stator wi
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stator winding induction machine ba
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∫ H ⋅ dl = ∫ J ⋅ ds = N ⋅
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theory itself is correct. The inacc
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( θ ) ⋅ g( θ, θ ) − H ( 0)
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where ( θ ) n A is the average of
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Since the definition of the mutual
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3Cs1 Cs1 − Cs1 − 3Cs1 6Cs1 4Cs1
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3.4.2 Mutual Inductances of the ABC
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where, ( θ ) n is the average of t
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1 0 α 1 − r 2π α − r 2π Fig
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When the skewing factor of the roto
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3.6 Calculation of Stator-Rotor Mut
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dλ v = R ⋅ i + (3.58) dt where,
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3.7.1.3 Stator flux linkage in ABC
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where, r R is the resistance matrix
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Only terms in equation (3.77) which
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119 ( ) ⎥ ⎥ ⎥ ⎥ ⎥ ⎥ ⎥
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−1 −1 −1 where, λ qdr = Tr L
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3.16 and Figure 3.17. It is found f
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Figure 3.11 The simulation of the d
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Figure 3.14 The simulation of the s
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Figure 3.16 Rotor bar currents duri
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Phase Y Figure 3.20 Air gap flux de
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Figure 3.24 Total air gap flux dens
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Figure 3.27 The air gap flux densit
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Figure 3.29 Air gap flux density co
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Figure 3.33 Air gap flux density in
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All the waveforms shown above are t
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Figure 3.39 Air gap flux density pr
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Figure 3.42 Normalized spectrum of
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Figure 3.46 Normalized spectrum of
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Figure 3.49 Normalized spectrum of
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Figure 3.53 Normalized spectrum of
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CHAPTER 4 FULL MODEL SIMULATION OF
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Substituting (3.28) and (3.29) into
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Figure 4.3 Self-inductance under 20
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Figure 4.4 Mutual inductance under
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that L AB = L BA , L BC = L CB and
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Figure 4.8 Self-inductance under 10
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Figure 4.10 Mutual inductance under
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the assumption that the rotor skew
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Figure 4.15 Self-inductance under 2
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Figure 4.17 Mutual inductance under
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Figure 4.19 Mutual inductance under
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4.4 Mutual Inductances Calculation
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Figure 4.24 Stator rotor mutual ind
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Figure 4.25 Stator rotor mutual ind
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varying inductances excited by four
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Equations similar to (4.15-4.16) we
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the number of poles for the winding
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Figure 4.29 Dynamic response of dua
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(a) (b) (c) (d) Figure 4.32. Normal
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CHAPTER 5 FIELD ANALYSIS OF DUAL ST
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In the analysis that follows the fu
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where, C s1 is the number of series
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θ , ∂B1 µ 0r = ⋅ J1 θ ∂θ
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C C = k π ⋅ d s2 s2 s2 199 (5.19
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the XYZ winding set is obtained by
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u rpi 2π ' k − jk θ −( i−1)
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The corresponding flux densities in
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The first term in equation (5.55) i
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The second term in (5.64) is zero u
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5.2.2 Torque Equation The calculati
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Re j( ω ) ⎧ 1t− P1θ µ 0r j(
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* ( ) ( ) ( ) ⎛ P1 ⋅ ⋅ ⎞ j
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- Page 259 and 260: (A) Induced voltage in the ABC wind
- Page 261 and 262: 5.3.3 Equation of Torque Contribute
- Page 263 and 264: winding set works as a generator, w
- Page 265 and 266: possible for the brushless doubly-f
- Page 267 and 268: Since the number of rotor bar is n,
- Page 269 and 270: 5.6 Computer Simulation and Experim
- Page 271 and 272: Figure 5.2. Simulation results for
- Page 273 and 274: 5.7. Conclusions In this chapter, u
- Page 275 and 276: good steady-state predictions and c
- Page 277 and 278: which are superimposed some space h
- Page 279 and 280: (a) (b) (c) Figure 6.1: Main flux s
- Page 281 and 282: (a) (b) (c) (d) (e) Figure 6.3: Fin
- Page 283 and 284: (a) (b) Figure 6.5: Induced air-gap
- Page 285 and 286: Substituting (6.7) into (6.4-6.6),
- Page 287 and 288: L L L L L L L λ + lr1 m1 ls1 m1 lr
- Page 289 and 290: 6.4 Simulation and Experimental Res
- Page 291 and 292: Figure 6.7 . Simulation results for
- Page 293 and 294: Figure 6.9 Experimental results for
- Page 295 and 296: diminish the contribution of the 6-
- Page 297 and 298: CHAPTER 7 STEADY STATE ANALYSIS OF
- Page 299 and 300: where, L L = (7.11) si mi iqdri λq
- Page 301 and 302: Overall efficiency of the dual stat
- Page 303 and 304: Figure 7.2 Stator current speed cha
- Page 305 and 306: Figure 7.6 Power factor speed chara
- Page 307: Figure 7.9 Power factor speed chara
- Page 311 and 312: Figure 7.16 Torque speed characteri
- Page 313 and 314: this conclusion is based on the ass
- Page 315 and 316: Figure 7.21. ω s1 vs s2 ω when to
- Page 317 and 318: Figure 7.25 ω s1 vs s2 ω when the
- Page 319 and 320: Figure 7.28. Copper losses of the m
- Page 321 and 322: 7.4 Conclusions Based on the steady
- Page 323 and 324: applications and possible use as st
- Page 325 and 326: L pλ + λ = I − = σ (8.3) ( ω
- Page 327 and 328: espectively. The stator q and d axi
- Page 329 and 330: * 3 * ( V I ) V Re( M I ) 3 P p = R
- Page 331 and 332: the modulation index of the rectifi
- Page 333 and 334: Lie derivative and relative order d
- Page 335 and 336: The above algorithm requires that t
- Page 337 and 338: σ = 3 1+ K ( Vqs1iqs1 + Vds1 ds1)
- Page 339 and 340: Butterworth polynomial with the den
- Page 341 and 342: Table 8.1 Parameters of controllers
- Page 343 and 344: generally the case to get a good pe
- Page 345 and 346: Table 8.2 Machine parameters for si
- Page 347 and 348: (a) (b) (c) (d) (e) (f) (g) Figure
- Page 349 and 350: (a) (b) (c) (d) (e) (f) (g) (h) (i)
- Page 351 and 352: (a) (b) (c) (d) (e) (f) (g) (h) (i)
- Page 353 and 354: CHAPTER 9 HIGH PERFORMANCE CONTROL
- Page 355 and 356: The qd0 voltage equations of a dual
- Page 357 and 358: 317 ( ) ( ) ( ) ( ) ( ) ⎥ ⎥ ⎥
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If the rotor speed and the rotor fl
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Infeasible region (a) Vdc1 and Vdc2
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The influences of the saturation of
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Figure 9.5(a), by varying the q-axi
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Figure 9.5 Steady state analysis, (
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L1 L3 2 ( 1− K ) Vdc1 3 = ( Vqs1i
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If the PI controllers are used and
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egulation capabilities of the contr
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(a) (b) (c) (d) (e) (f) (g) (h) (k)
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(a) (b) Figure 9.11. The starting p
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9.6 Conclusions The high performanc
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induction machine are applicable to
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In section 10.2, the fundamentals o
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The vector control of an induction
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possibilities for fault conditions,
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where, where, − r r L = (10.18) (
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qsi qsi * ( I I ) σ = K ⋅ − (1
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In the proposed control scheme, rot
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* ωr * ωr + + − ωr k p + ki s
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The value of ω 0 determines the dy
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10.4.4 Stator D-axis Current Contro
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(a) (b) (c) (d) (e) (f) Figure 10.4
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The proposed control scheme has als
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(a) (b) (c) (d) (e) (f) (g) Figure
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10.6 Full-order Flux Observer The c
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while the second three-phase windin
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L r L p ˆ λ ˆ ˆ (10.66) ri si r
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373 [ ] ( ) ( ) ( ) ( ) ( ) ( ) ( )
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t 2bi ⎛ rsiLri K iL ⎞ ⎛ ri K
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ri D i si ri ri si mi ri 2 ( K )
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esults show that the selected obser
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Figure 10.12 The poles of the 6-pol
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383 ( ) ( ) ( ) ( ) ( ) ( ) ( ) ( )
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⎧t s ⎨ ⎩ts 1 2 = t = t 1 2 Th
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Figure 10.15 The poles of the machi
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X i i = X Y = Y i i ( σ , ω) ( σ
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this error is used as the feedback.
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ˆ ω rm The output error is expres
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The expressions of t1 i and t2 i ar
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397 ( ) ( ) ( ) bi ei i bi ei i ai
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The transfer function of rotor spee
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(a) (b) (c) (d) Figure 10.16 Pole-z
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Figure 10.19 Pole-zero maps with di
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Figure 10.22 Pole-zero maps with di
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should ensure the stability under a
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The boundary of the speed controlle
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10.11 Simulation Results for Sensor
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Figure 10.28 Speed estimation for 2
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(a) (b) Figure 10.31 Speed estimati
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(a) (b) (c) (d) (e) (f) Figure 10.3
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Figure 10.34 Actual and estimated v
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CHAPTER 11 HARDWARE IMPLEMENTATION
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esistance for two phase windings. T
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11.2.3 Short Circuit Test The short
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When the input voltages of 2-pole A
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winding set is generating and the o
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11.4 Per Unit Model For the fixed p
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1 = 12 2 0. 0024414 The transformat
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ase values of voltage/current. The
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Start System configuration Initiali
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CHAPTER 12 CONCLUSIONS AND FUTURE W
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Using the rotating-field theory and
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each winding have been clearly show
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voltages of different frequencies,
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REFERENCES 447
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[2.2]. P. C. Roberts, "A Study of B
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[5.3]. R. A. McMahon, P. C. Roberts
- Page 493 and 494:
[8.17]. O. Ojo, “Performance of s
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[10.5]. J. C. Moreira, K. T. Hung,
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[10.27]. M. Hinkkanen, “Analysis
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[10.48]. K. Lee and F. Blaabjerg,
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VITA Zhiqiao Wu was born in Shashi,
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3. Zhiqiao Wu and O. Ojo, "High Per