Sensorless vector control apparatus for induction motor

What is claimed is: 1. A sensor-less vector control apparatus for induction motor, the apparatus comprising: a current controller configured to output d and q-axis voltages in a synchronous reference frame, using d and q-axis current references in the synchronous reference frame; a first phase converting unit configured to convert output voltages from the current controller into voltages in a stationary reference frame; an inverter configured to apply voltages to an induction motor by receiving the output of the first phase converting unit; a second phase converting unit configured to convert phase currents measured based on the voltages applied to the induction motor from the inverter into d and q-axis currents in the synchronous reference frame; a rotor speed and position estimator configured to measure a rotor speed and a rotor magnetic flux of the induction motor and estimate a rotor position by using the phase currents and an output value of the first phase converting unit and to estimate a rotor position using the output value; and a stator resistance and angle error estimator configured to calculate a stator resistance and an angle error of the induction motor by receiving d, q axis current commands on the synchronous reference frame inputted from the current controller and d, q voltages on the synchronous reference frame outputted from the current controller, and to provide the stator resistance to the rotor speed and position estimator. 2. The apparatus of claim 1 , further comprising a current measurer for each phase configured to measure phase currents applied to the induction motor using an output voltage of the inverter. 3. The apparatus of claim 1 , further comprising a first magnetic flux angle compensator configured to compensate a rotor magnetic flux angle used by the first phase converting unit by using each error provided by the stator resistance and angle error estimator. 4. The apparatus of claim 1 , further comprising a second magnetic flux angle compensator configured to compensate a rotor magnetic flux angle used by the second phase converting unit by using each error provided by the stator resistance and angle error estimator. 5. The apparatus of claim 1 , wherein the stator resistance and angle error estimator includes: an angle speed error estimator configured to estimate angle speed error of the induction motor using an output voltage of the current controller and a feedback current applied from the second phase converting unit to the current controller, and a stator resistance estimator configured to estimate in real time a stator resistance value using an output voltage of the current controller and a feedback current applied from the second phase converting unit to the current controller. 6. The apparatus of claim 5 , wherein the stator resistance and angle error estimator further includes: a first switch configured to selectively provide an angular speed error estimated by the angle speed error estimator, a compensator configured to determine an angular speed compensation amount determined by the angular speed error provided by the first switch, an integrator configured to calculate an angular error from the angular speed compensation amount which is an output of the compensator, and a second switch configured to selectively provide a stator resistance value provided by the stator resistance estimator to the rotor speed and position estimator. 7. The apparatus of claim 1 , further comprising a speed controller configured to output a q axis current command on the synchronous reference frame to the current controller by inputting a rotor speed command and rotor speed of the induction motor.