Resonant converter and driving method thereof

What is claimed is: 1. A resonant converter, comprising: a first switch on a primary side and a second switch coupled to the first switch; a first synchronous rectification switch on a secondary side configured to conduct according to a switching operation of the first switch; a second synchronous rectification switch on the secondary side configured to conduct according to a switching operation of the second switch; and a switch control circuit configured to detect a waveform of one end voltage of at least one of the first synchronous rectification switch and the second synchronous rectification switch, determine one of a below region and an above region of the detected waveform, and differently control conduction duration of the first and second synchronous rectification switches according to a result of the determination, wherein the switch control circuit comprises a mode selector configured to count changes in output detected by comparing the at least one end voltage with a predetermined threshold voltage and select a mode according to a counted result. 2. The converter of claim 1 , wherein the switch control circuit is configured to determine an operation region of the resonant converter to be the below region when ringing of the at least one end voltage occurs, and determine the operation region of the resonant converter to be the above region when the ringing does not occur. 3. The converter of claim 1 , wherein in the above region, the switch control circuit extends the conduction duration of the first and second synchronous rectification switches to a time later than an off time of the first and second switches, respectively. 4. The converter of claim 1 , wherein the mode selector comprises: a level detector configured to detect a waveform level of the at least one end voltage and output a result of comparing the detected waveform level with the threshold voltage; and a level counter configured to select a first mode when it is determined that ringing has not occurred when the result of counting changes in output of the level detector is smaller than a predetermined value, and to select a second mode when it is determined that the ringing has occurred when the result of counting is equal to, or greater than the predetermined value. 5. The converter of claim 1 , wherein the switch control circuit is configured to turn on the first synchronous rectification switch for a duration spanning from a conduction time of the first synchronous rectification switch to a time delayed from turn-off time of the first switch by a first extended duration calculated in an immediately preceding switching cycle, and turn on the second synchronous rectification switch for a duration spanning from a conduction time of the second synchronous rectification switch to a time delayed from turn-off time of the second switch by a second extended duration calculated in the immediately preceding switching cycle, when an operation region of the resonant converter is the above region. 6. The converter of claim 5 , wherein the switch control circuit is configured to calculate the first extended duration by subtracting a first duration and a dead time between the first and second synchronous rectification switches from a duration spanning from a turn-on time of the first switch to a conduction end time of the first synchronous rectification switch, in which the first duration is calculated by subtracting a dead time of the first switch and a dead time of the second switch from a maximum on-time of the first switch. 7. The converter of claim 6 , wherein the switch control circuit counts enabled duration of a clock signal to determine a switching frequency of the first and second switches, and the enabled duration of the clock signal corresponds to the maximum on-time of the first switch. 8. The converter of claim 5 , wherein the switch control circuit is configured to calculate the second extended duration by subtracting a first duration and a dead time between the first and second synchronous rectification switches from a duration spanning from turn-on time of the second switch to a conduction end time of the second synchronous rectification switch, in which the first duration is calculated by subtracting dead time of the first and second switches from maximum on-time of the second switch. 9. The converter of claim 8 , wherein the switch control circuit counts enabled duration of a clock signal which determines a switching frequency of the first and second switches, and the enabled duration of the clock signal corresponds to the maximum on-time of the second switch. 10. The converter of claim 1 , wherein the switch control circuit comprises: an SR on-time determiner configured to detect an end voltage of the first synchronous rectification switch and an end voltage of the second synchronous rectification switch, detect first conduction duration of the first synchronous rectification switch and second conduction duration of the second synchronous rectification switch in an immediately preceding switching cycle, and set an on-time of each of the first and second synchronous rectification switches in a next switching cycle based on a duration obtained as a result of subtracting second dead time between the first and second synchronous rectification switches from the detected first and second conduction duration; and an SR on-time compensator configured to calculate a first extended duration by subtracting a first duration of the first synchronous rectification switch and the second dead time from a duration spanning from turn-on time of the first switch to a conduction end time of the first synchronous rectification switch, and calculate second extended duration in the immediately preceding switching cycle by subtracting a first duration of the second synchronous rectification switch and the second dead time from a duration spanning from turn-on time of the second switch to a conduction end time of the second synchronous rectification switch. 11. The converter of claim 10 , wherein the SR on-time compensator is configured to calculate the first duration of the first synchronous rectification switch based on a duration obtained as a result of subtracting a first dead time of the first and second switches from a maximum on-time of the first switch in the immediately preceding switching cycle, and calculate the first duration of the second synchronous rectification switch based on a duration obtained as a result of subtracting the first dead time from maximum on-time of the second switch in the immediately preceding switching cycle. 12. The converter of claim 10 , wherein the switch control circuit further comprises an SR control signal generator configured so that when the resonant converter operates in the above region, the SR control signal generator turns on the first synchronous rectification switch for a duration spanning from the conduction time of the first synchronous rectification switch until a time that is delayed from the turn-off time of the first switch by the first extended duration, and turns on the second synchronous rectification switch for a duration spanning from the conduction time of the second synchronous rectification switch until a time delayed from the turn-off time of the second switch by the second extended duration. 13. The converter of claim 12 , wherein when the resonant converter operates in the below region, the SR control signal generator is configured to turn on the first synchronous rectification switch for a duration spanning from the conduction time of the first synchronous rectification switch to a time when the on-time of the first synchronous rectification s