Resonant power converter and frequency tracking method for resonant power converter

What is claimed is: 1. A resonant power converter, comprising: an inverter circuit, a resonant circuit connected to the inverter circuit, a transformer connected to the resonant circuit, a rectification and filtering circuit connected to the transformer, a detection circuit, a sampling circuit, a determining circuit, and a control circuit, wherein: a first side of the transformer is connected to the resonant circuit, a second side of the transformer is connected to the rectification and filtering circuit, the detection circuit is connected to both the second side of the transformer and the rectification and filtering circuit, the determining circuit is connected to the detection circuit, and the control circuit is connected to both the determining circuit and the inverter circuit, the detection circuit is configured to: obtain a secondary current of the transformer, generate, according to the secondary current, a pulse signal corresponding to the secondary current, and send the pulse signal corresponding to the secondary current to the determining circuit, the control circuit is configured to generate a drive signal and send the drive signal to the inverter circuit and to the determining circuit, wherein the drive signal is used to drive the inverter circuit, the determining circuit is configured to: receive the pulse signal that is corresponding to the secondary current and sent by the detection circuit and receive the drive signal that is sent by the control circuit, generate first information based on the pulse signal and the drive signal, and send the first information to the control circuit, wherein the first information is used to indicate a resonant status of the resonant power converter, the control circuit is further configured to: receive the first information sent by the determining circuit, and control frequency of the drive signal according to the first information, and the sampling circuit is connected to each of the detection circuit, the second side of the transformer, and the rectification and filtering circuit, wherein the sampling circuit is configured to sample the secondary current, wherein the sampling circuit comprises: a comparator, a first resistor, a second resistor, a third resistor, and a capacitor, wherein: an output end of the comparator is connected to one end of the third resistor, one end of the capacitor is connected to the other end of the third resistor, the other end of the third resistor is connected to the detection circuit, a positive input end of the comparator is connected to one end of the first resistor, a negative input end of the comparator is connected to one end of the second resistor, the other end of the first resistor is connected to both the transformer and the rectification and filtering circuit, and the other end of the second resistor and the other end of the capacitor are grounded. 2. The resonant power converter according to claim 1 , wherein: the inverter circuit is of any one of a half-bridge inverter circuit structure, a full-bridge inverter circuit structure, or a three-level inverter circuit structure. 3. The resonant power converter according to claim 2 , wherein: the resonant circuit is of a resonant circuit structure that is formed by connecting an excitation inductor, a resonant inductor, and a resonant capacitor in series. 4. The resonant power converter according to claim 3 , wherein: the rectification and filtering circuit is of a half-wave rectification and filtering circuit structure or a full-wave rectification and filtering circuit structure. 5. The resonant power converter according to claim 2 , wherein: the rectification and filtering circuit is of a half-wave rectification and filtering circuit structure or a full-wave rectification and filtering circuit structure. 6. The resonant power converter according to claim 1 , wherein: the resonant circuit is of a resonant circuit structure that is formed by connecting an excitation inductor, a resonant inductor, and a resonant capacitor in series. 7. The resonant power converter according to claim 1 , wherein: the rectification and filtering circuit is of a half-wave rectification and filtering circuit structure or a full-wave rectification and filtering circuit structure. 8. A frequency tracking method, comprising: obtaining, by a resonant power converter, a pulse signal corresponding to a secondary current and a drive signal; generating, by the resonant power converter, first information according to the pulse signal corresponding to the secondary current and the drive signal, wherein the first information indicates a resonant status of the resonant power converter; and controlling, by the resonant power converter, frequency of the drive signal according to the first information, wherein the generating the first information according to the pulse signal corresponding to the secondary current and the drive signal comprises: determining that a rising edge of the pulse signal corresponding to the secondary current and a rising edge of the drive signal are synchronous; determining that a falling edge of the pulse signal corresponding to the secondary current and a falling edge of the drive signal are synchronous; and generating the first information, wherein the first information indicates that the resonant power converter works at a resonant frequency point; wherein the controlling the frequency of the drive signal according to the first information comprises keeping the frequency of the drive signal unchanged according to the first information. 9. The frequency tracking method according to claim 8 , wherein the obtaining the pulse signal corresponding to the secondary current comprises: obtaining the secondary current; and generating, according to the secondary current, the pulse signal corresponding to the secondary current. 10. A frequency tracking method, comprising: obtaining, by a resonant power converter, a pulse signal corresponding to a secondary current and a drive signal; generating, by the resonant power converter, first information according to the pulse signal corresponding to the secondary current and the drive signal, wherein the first information indicates a resonant status of the resonant power converter; and controlling, by the resonant power converter, frequency of the drive signal according to the first information, wherein the generating the first information according to the pulse signal corresponding to the secondary current and the drive signal comprises: determining that a rising edge of the pulse signal corresponding to the secondary current and a rising edge of the drive signal are synchronous; determining that a falling edge of the pulse signal corresponding to the secondary current lags behind a falling edge of the drive signal; and generating the first information, wherein the first information indicates that the resonant power converter works in a first area; wherein the controlling the frequency of the drive signal according to the first information comprises decreasing the frequency of the drive signal according to the first information. 11. The frequency tracking method according to claim 10 , wherein the obtaining the pulse signal corresponding to the secondary current comprises: obtaining the secondary current; and generating, according to the secondary current, the pulse signal corresponding to the secondary current. 12. A frequency tracking method, comprising: obtaining, by a resonant power converter, a pulse signal corresponding to a secondary current and a drive signal; generating, by the resonant power converter, first information accor