Calibration circuit and method

What is claimed is: 1. A circuit, comprising: a phase combiner, configured to: add an in-phase positive input and a quadrature positive input to obtain an in-phase positive output; add an in-phase negative input and a quadrature negative input to obtain an in-phase negative output; add the in-phase negative input and the quadrature positive input to obtain a quadrature positive output; add the in-phase positive input and the quadrature negative input to obtain a quadrature negative output; four output ports, respectively configured to output the in-phase positive output, the in-phase negative output, the quadrature positive output, and the quadrature negative output; a first power detector, configured to convert the in-phase positive output and the in-phase negative output to a first direct voltage; a second power detector, configured to convert the quadrature positive output and the quadrature negative output to a second direct voltage; and a comparator, configured to compare the first direct voltage and the second direct voltage, and feed comparison result back to the phase combiner; wherein the phase combiner further comprises a first NMOS, a second NMOS, a third NMOS, a fourth NMOS, a fifth NMOS, a sixth NMOS, a seventh NMOS and an eighth NMOS, a first impedance, a second impedance, a third impedance and a fourth impedance, wherein a gate of the first NMOS is configured to receive the in-phase positive input, a gate of the second NMOS receives the in-phase negative input, a gate of the third NMOS is configured to receive the quadrature positive input, a gate of the fourth NMOS is configured to receive the quadrature negative input, drains of both the first NMOS and third NMOS are connected to the first impedance, and the first impedance is connected to Vcc, drains of both the second NMOS and the fourth NMOS are connected to the second impedance, and the second impedance is connected to Vcc; and a gate of the fifth NMOS is configured to receive the quadrature positive input, a gate of the sixth NMOS is configured to receive the quadrature negative input, a gate of the seventh NMOS is configured to receive the in-phase negative input, a gate of the eighth NMOS is configured to receive the in-phase positive input, drains of both the fifth NMOS and seventh NMOS are connected to the third impedance, and the third impedance is connected to Vcc, drains of both the sixth NMOS and the eighth NMOS are connected to the fourth impedance, and the fourth impedance is connected to Vcc. 2. The circuit of claim 1 , wherein the first power detector is further configured to convert alternating voltage on the drains of both the first NMOS and the third NMOS and alternating voltage on the drains of both the second NMOS and the fourth NMOS, to the first direct voltage; and the second power detector, configured to convert alternating voltage on the drains of both the fifth NMOS and the seventh NMOS and alternating voltage on drains of both the sixth NMOS and the eighth NMOS to the second direct voltage. 3. The circuit of claim 2 , wherein each of the first power detector and the second power detector further comprises a ninth NMOS, a tenth NMOS, an eleventh NMOS, a twelfth NMOS, a first capacitor, a second capacitor, a third capacitor, a first resistor, a second resistor, a third resistor, and a current source, wherein one terminal of the first capacitor is configured to receive voltage on the drains of both the first NMOS and the third NMOS, the other terminal of the first capacitor is connected to a first bias voltage via the first resistor, the other terminal of the first capacitor is further connected to a gate of the ninth NMOS, a drain of the ninth NMOS is connected to Vdd, a source of the ninth NMOS is connected to a drain of the twelfth NMOS; one terminal of the second capacitor is configured to receive voltage on the drains of both the second NMOS and the fourth NMOS, the other terminal of the second capacitor is connected to the first bias voltage via the second resistor, the other terminal of the second capacitor is further connected to a gate of the tenth NMOS, a drain of the tenth NMOS is connected to Vdd, a source of the tenth NMOS is connected to the drain of the twelfth NMOS; the sources of the ninth NMOS and the tenth NMOS and the drain of the twelfth NMOS are further connected to one terminal of the third resistor, the other terminal of the third resistor is connected to one terminal of the third capacitor, the other terminal of the third capacitor is connected to ground, the source of the twelfth NMOS is connected to ground, output port of the power detector is connected to the other terminal of the third resistor; and a gate of the twelfth NMOS is connected to a gate and a drain of the eleventh NMOS, the drain of the eleventh NMOS is connected to the current source, and the source of the eleventh NMOS is connected to ground, the current source is connected to Vdd. 4. The circuit of claim 3 , further comprising a thirteenth NMOS, a fourteenth NMOS, and a fifteenth NMOS, wherein sources of the first NMOS, the second NMOS, the third NMOS and the fourth NMOS are all connected to a drain of the thirteenth NMOS, a gate of the thirteenth NMOS is connected to the output port of the comparator, a source of the thirteenth NMOS is connected to a drain of the fifteenth NMOS; sources of the fifth NMOS, the sixth NMOS, the seventh NMOS and the eighth NMOS are all connected to a drain of the fourteenth NMOS, a gate of the fourteenth NMOS receives a second bias voltage, a source of the fourteenth NMOS is also connected to the drain of the fifteenth NMOS; and a gate of the fifteenth NMOS is configured to receive a third bias voltage, and a source of the fifteenth NMOS is connected to ground (GND). 5. The circuit of claim 4 , wherein the second bias voltage and the third bias voltage are constant. 6. A method, comprising: adding an in-phase positive input and a quadrature positive input to obtain an in-phase positive output; adding an in-phase negative input and a quadrature negative input to obtain an in-phase negative output; adding the in-phase negative input and the quadrature positive input to obtain a quadrature positive output; adding the in-phase positive input and the quadrature negative input to obtain a quadrature negative output; respectively outputting the in-phase positive output, the in-phase negative output, the quadrature positive output, and the quadrature negative output; converting the in-phase positive output and the in-phase negative output to a first direct voltage; converting the quadrature positive output and the quadrature negative output to a second direct voltage; comparing the first direct voltage and the second direct voltage and generating a comparison result; and adjusting the in-phase positive output, the in-phase negative output, the quadrature positive output and the quadrature negative output according to the comparison result, such that the difference between the first direct voltage and second direct voltage reduces.