Overview of key competing variable-frequency drive control platforms: While the analysis of AC drive controls can be technically quite involved ("See also" section), such analysis invariably starts with modeling of the drive-motor circuit involved along the lines of accompanying
signal flow graph and equations. :
Induction motor model equations :: \begin{align} &\tau_\sigma'\frac{di_s}{d\tau}+i_s - \omega_k\tau_\sigma'i_s+\frac{k_r}{\tau_r r_\sigma}(1-jr_\tau\omega_m)\psi_r+\frac{1}{r_\sigma}u_s && (1) \\&\tau_r\frac{d\psi_r}{d\tau}+\psi_r=-j(\omega_k-\omega_m)\tau_r\psi_r+l_mi_s && (2) \end{align} :where :: \begin{align} \sigma_r'=\frac{\sigma l_s}{r_\sigma} && r_\sigma=r_s+k_r^2r_r && k_r=\frac{l_m}{l_r} && \tau=\omega_{sR} \end{align} :: \begin{align} &\sigma=1-\frac{l_m^2}{l_rl_s}=\text{total leakage coefficient} \\ &\omega_{sR}=\text{nominal stator frequency} \end{align} : : (SFG) for induction motor and
armature flux linkage created by the respective field and armature (or torque component) currents are
orthogonally aligned such that, when torque is controlled, the field flux linkage is not affected, hence enabling dynamic torque response. Vector control accordingly generates a three-phase
PWM motor voltage output derived from a
complex voltage vector to control a complex current vector derived from motor's three-phase stator current input through
projections or
rotations back and forth between the three-phase speed and time dependent system and these vectors' rotating reference-frame two-
coordinate time invariant system. Such complex
stator current space vector can be defined in a (d,q) coordinate system with orthogonal components along d (direct) and q (quadrature) axes such that field flux linkage component of current is aligned along the d axis and torque component of current is aligned along the q axis. • Forward projection from instantaneous currents to (a,b,c) complex
stator current space vector representation of the three-phase
sinusoidal system. • Forward three-to-two phase, (a,b,c)-to-(\alpha,\beta) projection using the
Clarke transformation. Vector control implementations usually assume ungrounded motor with balanced three-phase currents such that only two motor current phases need to be sensed. Also, backward two-to-three phase, (\alpha,\beta)-to-(a,b,c) projection uses space vector PWM modulator or inverse Clarke transformation and one of the other PWM modulators. • Forward and backward two-to-two phase,(\alpha,\beta)-to-(d,q) and (d,q)-to-(\alpha,\beta) projections using the Park and inverse Park transformations, respectively. The idea of using the park transform is to convert the system of three phase currents and voltages into a two coordinate linear time-invariant system. By making the system LTI is what enables the use of simple and easy to implement PI controllers, and also simplifies the control of flux and torque producing currents. However, it is not uncommon for sources to use combined transform three-to-two, (a,b,c)-to-(d,q) and inverse projections. While (d,q) coordinate system rotation can arbitrarily be set to any speed, there are three preferred speeds or reference frames: Whereas magnetic field and torque components in DC motors can be operated relatively simply by separately controlling the respective field and armature currents, economical control of AC motors in variable speed application has required development of microprocessor-based controls Inverters can be implemented as either
open-loop sensorless or closed-loop FOC, the key limitation of open-loop operation being minimum speed possible at 100% torque, namely, about 0.8 Hz compared to standstill for closed-loop operation. In DFOC, flux magnitude and angle feedback signals are directly calculated using so-called voltage or current models. In IFOC, flux space angle feedforward and flux magnitude signals first measure stator currents and
rotor speed for then deriving flux space angle proper by summing the rotor angle corresponding to the rotor speed and the calculated reference value of
slip angle corresponding to the slip frequency. Sensorless control (see the Sensorless FOC block diagram) of AC drives is attractive for cost and reliability considerations. Sensorless control requires derivation of rotor speed information from measured stator voltage and currents in combination with open-loop estimators or closed-loop observers. ==Application ==