Compressor and control method thereof

What is claimed is: 1. A method of controlling a compressor comprising a casing configured to accommodate refrigerant and oil while forming an accommodation space therein, a compressor part to compress refrigerant while being installed at an inside of the casing, a motor part installed at an inside of the casing to provide the compressing part with a driving force, and a sensor part having a first temperature sensor configured to sense temperature of the oil and a second temperature sensor configured to sense temperature of refrigerant being discharged from the casing, the method comprising: inputting an operation command; sensing temperature of the oil by the first temperature sensor; sensing temperature of the refrigerant being discharged from the casing by the second temperature sensor; determining a discharge temperature of the compressor, the discharge temperature of the compressor being a higher value between the temperature sensed by the first temperature sensor and the temperature sensed by the second temperature sensor; determining a discharge superheat (DSH), the DSH representing the discharge temperature of the compressor minus a high-pressure saturated temperature; performing a loss operation when the temperature of the oil is below a first reference temperature, the loss operation comprising increasing an amount of heat radiation of the motor part while operating the motor part at a low speed; and performing an efficiency operation when the temperature of the oil is equal to or higher than a second reference temperature and the DSH is equal to or higher than a third reference temperature. 2. The method of claim 1 , wherein the first temperature sensor is configured to sense temperature of the oil while being penetratively installed from an outside of the casing to an inside of the casing so as to make contact with the oil; and the second temperature sensor is configured to sense temperature of the refrigerant being discharged from the casing while being installed at an outlet port of the casing. 3. The method of claim 1 , wherein the first temperature sensor is configured to sense temperature of the oil by sensing the temperature of the casing while being installed at an outside of the casing; and the second temperature sensor is configured to sense temperature of refrigerant being discharged from the casing while being installed at an outlet side of the casing. 4. The method of claim 3 , wherein the sensing of the temperature of the oil further comprises compensating the sensed temperature of the casing to a value approximate to actual temperature of the oil. 5. The method of claim 1 , wherein the performing of the loss operation comprises when a present current command is within a current limit circle that represents a range of a magnetic flux current command and a torque current command that are controllable by a maximum stator current that is set to the motor part, supplying the motor part with a new current command having a value lamer than the present current command, and wherein when the current limit circle, a load curve and a maximum torque curve per unit current are represented on d and q axes current coordinate plane, the new current command comprises a magnetic flux current command and a torque current command of a point satisfying the load curve among current values belonging to the current limit circle. 6. The method of claim 3 , wherein the first reference temperature is equal to the second reference temperature. 7. The method of claim 3 , wherein the first reference temperature is different from the second reference temperature. 8. A compressor comprising: a casing configured to accommodate refrigerant and oil while forming an accommodation space therein; a compression part configured to compress the refrigerant while being installed at an inside of the casing; a motor part configured to provide the compressor part with a driving force while being installed at an inside of the casing; a first temperature sensor configured to sense temperature of the oil; a second temperature sensor configured to sense temperature of refrigerant being discharged from the casing; and a control part configured to determine a discharge temperature of the compressor, the discharge temperature of the compressor being a higher value between the temperature sensed by the first temperature sensor and the temperature sensed by the second temperature sensor, to determine a discharge superheat (DSH), the DSH representing the discharge temperature of the compressor minus a high-pressure saturated temperature, to perform a loss operation when the temperature of the oil is below a first reference temperature by increasing an amount of heat radiation of the motor part while operating the motor part at a low speed, and to perform an efficiency operation when the temperature of the oil is equal to or higher than a second reference temperature and the DSH is equal to or higher than a third reference temperature. 9. The compressor of claim 8 , wherein the first temperature sensor is configured to sense temperature of the oil while being penetratively installed from an outside of the casing to an inside of the casing so as to make contact with the oil; and the second temperature sensor is configured to sense temperature of the refrigerant being discharged from the casing while being installed at an outlet port of the casing. 10. The compressor of claim 8 , wherein the first temperature sensor is configured to sense temperature of the oil by sensing the temperature of the casing while being installed at an outside of the casing; and the second temperature sensor is configured to sense temperature of refrigerant being discharged from the casing while being installed at the outlet port of the casing. 11. The compressor of claim 10 , further comprising a compensation part configured to compensate the temperature of the casing sensed by the first temperature sensor to a value approximate to actual temperature of the oil. 12. The compressor of claim 8 , wherein the control part is configured to perform the loss operation by supplying the motor part with a new current command having a value larger than a present current command when the present current command is within a current limit circle that represents a range of a magnetic flux current command and a torque current command that are controllable by a maximum stator current that is set to the motor part, and wherein when the current limit circle, a load curve and a maximum torque curve per unit current are represented on a d-q axes current coordinate plane, the new current command comprises a magnetic flux current command and a torque current command of a point satisfying the load curve among current values belonging to the current limit circle. 13. The compressor of claim 9 , wherein the first reference temperature is equal to the second reference temperature. 14. The compressor of claim 9 , wherein the first reference temperature is different from the second reference temperature.