Voltage detection circuit, switching converter and integrated circuit

What is claimed is: 1. A voltage detection circuit for a switching converter having a switch and a magnetic element connected in series, wherein a first terminal of the switch and a first terminal of the magnetic element are connected to a common node, the voltage detection circuit comprising: a) a low-pass filter configured to receive a first voltage across the switch, and to generate a second voltage representing an average value of the first voltage; b) wherein the second voltage represents a voltage between a second terminal of the switch and a second terminal of the magnetic element in a steady state of the switching converter; and c) wherein the switching converter is configured as a Boost converter, the switch is connected between the common node and a negative input terminal of the switching converter, the magnetic element is connected to a positive input terminal of the switching converter and the common node, and the second voltage represents an input voltage of the switching converter. 2. The voltage detection circuit of claim 1 , wherein the second voltage represents one of: an input voltage of the switching converter, an output voltage of the switching converter, and a difference between the input voltage and the output voltage. 3. The voltage detection circuit of claim 1 , wherein a reference ground of the low-pass filter and a reference ground of a control circuit of the switching converter are both connected to the second terminal of the switch. 4. The voltage detection circuit of claim 1 , wherein the magnetic element comprises an inductor or a winding of a transformer. 5. The voltage detection circuit of claim 1 , further comprising a control circuit configured to control a switching state of the switch according to the second voltage output by the voltage detection circuit. 6. An integrated circuit, comprising the voltage detection circuit of claim 1 , and the switch of the switching converter. 7. A voltage detection circuit for a switching converter having a switch and a magnetic element connected in series, wherein a first terminal of the switch and a first terminal of the magnetic element are connected to a common node, the voltage detection circuit comprising: a) a low-pass filter configured to receive a first voltage across the switch, and to generate a second voltage representing an average value of the first voltage; b) wherein the second voltage represents a voltage between a second terminal of the switch and a second terminal of the magnetic element in a steady state of the switching converter; and c) wherein the switching converter is configured as a Buck converter, the switch is connected between the common node and a positive input terminal of the switching converter, the magnetic element is connected to a positive output terminal of the switching converter and the common node, and the second voltage represents a difference between an input voltage and an output voltage of the switching converter. 8. The voltage detection circuit of claim 7 , wherein the second voltage represents one of: an input voltage of the switching converter, an output voltage of the switching converter, and a difference between the input voltage and the output voltage. 9. The voltage detection circuit of claim 7 , wherein a reference ground of the average circuit and a reference ground of a control circuit of the switching converter are both connected to the second terminal of the switch. 10. The voltage detection circuit of claim 7 , wherein the magnetic element comprises an inductor or a winding of a transformer. 11. A voltage detection circuit for a switching converter having a switch and a magnetic element connected in series, wherein a first terminal of the switch and a first terminal of the magnetic element are connected to a common node, the voltage detection circuit comprising: a) a low-pass filter configured to receive a first voltage across the switch, and to generate a second voltage representing an average value of the first voltage; b) wherein the second voltage represents a voltage between a second terminal of the switch and a second terminal of the magnetic element in a steady state of the switching converter; and c) wherein the switching converter is configured as a Buck converter, the switch is connected between the common node and a negative input terminal of the switching converter, the magnetic element is connected to a negative output terminal of the switching converter and the common node, and the second voltage represents a difference between an input voltage and an output voltage of the switching converter. 12. A voltage detection circuit for a switching converter having a switch and a magnetic element connected in series, wherein a first terminal of the switch and a first terminal of the magnetic element are connected to a common node, the voltage detection circuit comprising: a) a low-pass filter configured to receive a first voltage across the switch, and to generate a second voltage representing an average value of the first voltage; b) wherein the second voltage represents a voltage between a second terminal of the switch and a second terminal of the magnetic element in a steady state of the switching converter; and c) wherein the switching converter is configured as a Buck-Boost converter, the switch is connected between the common node and a positive input terminal of the switching converter, the magnetic element is connected to a negative output terminal of the switching converter and the common node, and the second voltage represents an input voltage of the switching converter. 13. A voltage detection circuit for a switching converter having a switch and a magnetic element connected in series, wherein a first terminal of the switch and a first terminal of the magnetic element are connected to a common node, the voltage detection circuit comprising: a) a low-pass filter configured to receive a first voltage across the switch, and to generate a second voltage representing an average value of the first voltage; b) wherein the second voltage represents a voltage between a second terminal of the switch and a second terminal of the magnetic element in a steady state of the switching converter; c) wherein the switching converter is configured as a Flyback converter; d) wherein when the low-pass filter is used to detect a voltage across the switch at a primary side, the second voltage is used to represent an input voltage of the switching converter, and e) wherein when the low-pass filter is used to detect a voltage across the switch at a secondary side, the second voltage is used to represent an output voltage of the switching converter. 14. The voltage detection circuit of claim 13 , wherein the magnetic element is a primary winding connected between a positive input terminal of the switching converter and the common node, and the switch at the primary side is connected between the common node and the negative input terminal of the switching converter. 15. The voltage detection circuit of claim 13 , wherein the magnetic element is a secondary winding connected between the common node and a negative terminal of the switching converter, and the switch at secondary side is connected between the common node and the positive output terminal of the switching converter. 16. The voltage detection circuit of claim 13 , wherein the magnetic element is a secondary winding connected between the common node and a positive output terminal of the switching converter, and the switch at the secondary side is connected between the common node and the negative output terminal of