Delta sigma modulator for shaping noise and audio codec having the same

What is claimed is: 1. A delta-sigma modulator comprising: a loop filter; a quantizer configured to convert an analog signal into a digital signal; and a digital-to-analog converter (DAC) configured to receive the digital signal, and including a first capacitor and a second capacitor, wherein in a first sampling period, the first capacitor is discharged, and at the same time, the second capacitor is charged with a reference voltage, in a second sampling period, the digital signal includes a noise caused by a clock jitter, the first capacitor is charged with the reference voltage, and the second capacitor is discharged and generates a charge corresponding to the noise, and in a subsequent first sampling period that is after the second sampling period, the first capacitor is discharged, and at the same time, the second capacitor generates a noise current corresponding to the noise using the charge and is charged with the reference voltage. 2. The delta-sigma modulator of claim 1 , wherein the DAC supplies a reference current having a constant magnitude to the loop filter for the first sampling period and the second sampling period. 3. The delta-sigma modulator of claim 2 , wherein the DAC supplies the reference current to the loop filter, and supplies the noise current to the loop filter, and a direction of each of the noise current and the reference current is determined based on the noise. 4. The delta-sigma modulator of claim 1 , wherein the DAC comprises: a first current source connected between a first node and a third node; a first switch connected between a second node and a fourth node, and activated in response to a first control signal for the second sampling period; a second switch connected between the third node and the fourth node, and activated for the first sampling period; the first capacitor connected between the fourth node and a fifth node; a third switch connected between the fourth node and a sixth node, and activated in response to the first control signal for the second sampling period; a fourth switch connected between the fifth node and the sixth node, and activated in response to the first control signal for the second sampling period; a fifth switch connected between a seventh node and an eighth node, and activated in response to the first control signal for the second sampling period; a sixth switch connected between the third node and the eighth node, and activated for the second sampling period; the second capacitor connected between the eighth node and a ninth node; a seventh switch connected between the eighth node and a tenth node, and activated in response to the first control signal for the first sampling period; an eighth switch connected between the tenth node and an eleventh node, and activated in response to the first control signal for the first sampling period; a ninth switch connected between the ninth node and the tenth node, and activated in response to the second control signal for the first sampling period; a tenth switch connected between the tenth node and a twelfth node, and activated in response to the second control signal for the first sampling period; an eleventh switch connected between the eleventh node and a thirteenth node, and activated for the second sampling period; a third capacitor connected between the eleventh node and the twelfth node; a twelfth switch connected between the eleventh node and a fourteenth node, and activated in response to the second control signal for the first sampling period; a thirteenth switch connected between a fifteenth node and a sixteenth node, and activated in response to the first control signal for the second sampling period; a fourteenth switch connected between the fifteenth node and a seventeenth node, and activated in response to the second control signal for the second sampling period; a fifteenth switch connected between the thirteenth node and the sixteenth node, and activated for the first sampling period; a fourth capacitor connected between the sixteenth node and the seventeenth node; a sixteenth switch connected between the sixteenth node and a nineteenth node, and activated in response to the second control signal for the second sampling period; and a second current source connected between the thirteenth node and an eighteenth node. 5. The delta-sigma modulator of claim 4 , wherein the DAC further comprises: a seventeenth switch connected between the fifth node and a twentieth node, and activated when a current digital data signal is in a high state for the first sampling period or when a previous digital data signal is in the high state for the second sampling period, and the first control signal is activated; an eighteenth switch connected between the seventeenth node and the twentieth node, and activated when the current digital data signal is in a low state for the first sampling period or when the previous digital data signal is in the low state for the second sampling period, and the first control signal is activated; a nineteenth switch connected between the ninth node and the twentieth node, and activated when the current digital data signal is in the high state for the second sampling period or when the previous digital data signal is in the high state for the first sampling period, and the first control signal is activated; a twentieth switch connected between the twelfth node and the twentieth node, and activated when the current digital data signal is in the low state for the second sampling period or when the previous digital data signal is in the low state for the first sampling period, and the first control signal is activated; a 21st switch connected between the ninth node and a 21st node, and activated when the current digital data signal is in the low state for the second sampling period or when the previous digital data signal is in the low state for the first sampling period, and the first control signal is activated; a 22nd switch connected between the twelfth node and the 21st node, and activated when the current digital data signal is in the high state for the second sampling period or when the previous digital data signal is in the high state for the first sampling period, and the first control signal is activated; a 23rd switch connected between the fifth node and the 21st node, and activated when the current digital data signal is in the low state for the first sampling period or when the previous digital data signal is in the low state for the second sampling period, and the first control signal is activated; and a 24th switch connected between the seventeenth node and the 21st node, and activated when the current digital data signal is in the high state for the first sampling period or when the previous digital data signal is in the high state for the second sampling period, and the first control signal is activated. 6. The delta-sigma modulator of claim 5 , wherein each of the twentieth node and the 21st node is connected to virtual ground nodes of an operational amplifier in the loop filter, and the virtual ground nodes are connected to an inverting input port and a non-inverting input port, respectively. 7. The delta-sigma modulator of claim 5 , further comprising a two-phase clock generator configured to generate the first sampling period, the second sampling period, the first control signal, and the second control signal. 8. The delta-sigma modulator of claim 5 , wherein the quantizer transmits the current digital data signal and the previous digital data signal to the DAC. 9. The delta-sigma modulator of claim 4 , wherein the DAC has a differential structure, and the first current source and the second current source are implemented with one current so