Resonant converter and driving method thereof

What is claimed is: 1. A switch control circuit for a resonant converter, the switch control circuit comprising: a first driver circuit configured to drive a first switch on a primary side; a second driver circuit configured to drive a first synchronous rectification switch on a secondary side; and a below resonance detection circuit configured to determine that an operating region of the resonant converter is below resonance based on a result of a comparison between a conduction period of the first synchronous rectification switch and an on period of the first switch. 2. The switch control circuit of claim 1 , wherein the below resonance detection circuit is configured to determine that the operating region of the resonant converter is below resonance when a state in which the conduction period of the first synchronous rectification switch is shorter than the on period of the first switch is maintained during a first debounce time. 3. The switch control circuit of claim 1 , wherein the below resonance detection circuit is configured to determine that the operating region of the resonant converter is not below resonance when a state in which the conduction period of the first synchronous rectification switch is longer than the on period of the first switch is maintained during a second debounce time. 4. The switch control circuit of claim 1 , wherein the below resonance detection circuit is configured to generate a below detection signal indicative of below resonance operation based on a maximum on-period information corresponding to a period in which a first clock signal for controlling a switching operation of the first switch is enabled, dead time information of the first switch and a second switch on the primary side, and a conduction period information corresponding to the conduction period of the first synchronous rectification switch. 5. The switch control circuit of claim 4 , wherein the below resonance detection circuit comprises: a subtractor configured to generate on-period information about the on period of the first switch by subtracting the dead time information from the maximum on-period information; and a first comparison unit configured to generate a first reference information based on the on-period information and to compare the first reference information with the conduction period information to check whether the first reference information is smaller than the conduction period information, wherein the below resonance detection circuit is configured to enable the below detection signal when an output of the first comparison unit maintains a first level during a first debounce time. 6. The switch control circuit of claim 5 , wherein the below resonance detection circuit further comprises: a second comparison unit configured to generate a second reference information based on the on-period information and compare the conduction period information with the second reference information to check whether the conduction period information is greater than or equal to the second reference information; and the below resonance detection circuit is configured to disable the below detection signal when an output of the second comparison unit maintains the first level during a second debounce time. 7. The switch control circuit of claim 6 , wherein: the first comparison unit is configured to generate the first reference information based on a value obtained by multiplying the on-period information by a first ratio smaller than 1, and the second comparison unit is configured to generate the second reference information based on a value obtained by multiplying the on-period information by a second ratio which is smaller than 1 and which is greater than the first ratio. 8. The switch control circuit of claim 6 , wherein the below resonance detection circuit further comprises: a first debounce unit configured to count a period in which the output of the first comparison unit maintains the first level and to generate a first detection signal when the counted period is maintained during the first debounce time; and a second debounce configured to count a period in which the output of the second comparison unit maintains the first level and to generate a second detection signal when the counted period is maintained during the second debounce time, wherein the below resonance detection circuit is configured to enable the below detection signal in synchronization with the first detection signal and disable the below detection signal in synchronization with the second detection signal. 9. The switch control circuit of claim 8 , wherein the below resonance detection circuit further comprises: an SR latch comprising a set terminal to which the first detection signal is inputted and a reset terminal to which a signal corresponding to the second detection signal is inputted, wherein the SR latch is configured to enable the below detection signal in response to input to the set terminal and disable the below detection signal in response to input to the reset terminal. 10. The switch control circuit of claim 1 , wherein the switch control circuit is configured to increase a current limit level to maintain an output voltage of the resonant converter at least during a predetermined hold-up time when the resonant converter operates below resonance. 11. The switch control circuit of claim 10 , wherein the switch control circuit is configured to control the current limit level based on a feedback voltage corresponding to the output voltage. 12. The switch control circuit of claim 10 , wherein the switch control circuit is configured to clamp a current detection voltage corresponding to a load current to the current limit level when the current detection voltage is greater than or equal to the current limit level, and control switching operations of the first and a second switch on the primary side based on a result of a comparison between the clamped current limit level and a control voltage corresponding to the output voltage. 13. The switch control circuit of claim 1 , wherein the switch control circuit is configured to detect non-zero voltage switching when the resonant converter operates below resonance. 14. A switch control circuit for resonant converter, the switch control circuit comprising: a first driver configured to output a first drive signal through a first node to drive a first switch on a primary side and output a second drive signal through a second node to drive a second switch on the primary side; a second driver configured to output a third drive signal through a third node to a first synchronous rectification switch on a secondary side and output a fourth drive signal through a fourth node to a second synchronous rectification switch on the secondary side, wherein the switch control circuit is configured to determine that an operating region of the resonant converter is below resonance based on a result of a comparison between a conduction period of the first synchronous rectification switch and an on period of the first switch. 15. The switch control circuit of claim 14 , wherein the switch control circuit is configured to calculate the on period of the first switch, detect the conduction period of the first synchronization rectification switch, count a period in which the conduction period of the first synchronous rectification switch is shorter than the on period of the first switch, and determine that the operating region of the resonant converter is below resonance when a result of the count reaches a first debounce time. 16. The switch control circuit of claim 15 , wherein t