Magnetic sensor and an integrated circuit

We claim: 1. A magnetic sensor, comprising: an input port to be connected to an external power supply; a magnetic field detecting circuit configured to generate a magnet detection signal; an output control circuit configured to control operation of the magnetic sensor in response to the magnet detection signal; and an output port, wherein the magnetic field detecting circuit includes: a magnetic sensing element configured to detect an external magnetic field and output a detection signal, a signal processing element configured to amplify the detection signal and removing interference from the detection signal to generate processed detection signal, and a conversion element configured to convert the processed detection signal into the magnet detection signal, which is used to control the magnetic sensor to operate in at least one of a first state and a second state responsive to at least the magnet detection signal, wherein in the first state, a load current flows from the output port to outside of the magnetic sensor, and in the second state, a load current flows from the outside into the output port of the magnetic sensor, wherein the signal processing element comprises an amplifier and a filter circuit, and gain of the amplifier is greater than gain of the filter circuit. 2. The magnetic sensor of claim 1 , wherein the detection signal includes a magnetic field signal and a deviation signal, the amplifier is a chopper amplifier, and the filter circuit is a low-pass filter, wherein the signal processing element comprises: a first chopper switch configured to separate the detection signal into the deviation signal and the magnetic field signal corresponding to a chopper frequency and a baseband frequency, respectively, wherein the chopper amplifier is configured to amplify the deviation signal and the magnetic field signal and to switch the amplified deviation signal and the amplified magnetic field signal onto the chopper frequency and the baseband frequency, respectively, and the filter circuit is configured to filter out the deviation signal at the chopper frequency. 3. The magnetic sensor of claim 2 , wherein the chopper amplifier comprises a first amplifier; and a second chopper switch, wherein the first amplifier is configured to perform first-stage amplification on the deviation signal and the magnetic field signal from the first chopper switch to generate the amplified deviation signal and the amplified magnetic field signal, respectively, and the second chopper switch is configured to switch the amplified deviation signal and the amplified magnetic field signal onto the chopper frequency and the baseband frequency, respectively. 4. The magnetic sensor of claim 3 , wherein the chopper amplifier further comprises a second amplifier disposed between the second chopper switch and the filter circuit, wherein the second amplifier is configured to perform second-stage amplification on the amplified deviation signal switched onto the chopper frequency and the amplified magnetic field signal switched onto the baseband frequency. 5. The magnetic sensor of claim 4 , wherein gain of the first amplifier is greater than gain of the second amplifier. 6. The magnetic sensor of claim 5 , wherein the filter circuit further comprises a first filter configured to compute a second pair of differential signals based on the two pairs of sampled differential signals. 7. The magnetic sensor of claim 2 , wherein the chopper frequency is greater than 100 K Hertz and/or the baseband frequency is less than 200 Hertz. 8. The magnetic sensor of claim 2 , wherein the signal processing element further comprises a sample-and-hold circuit coupled between the chopper amplifier and the filter circuit, wherein the sample-and-hold circuit is configured to sample a first pair of differential signals during a first half and a second half of a clock cycle, respectively and output two pairs of sampled differential signals during the clock cycle. 9. The magnetic sensor of claim 8 , wherein the filter circuit further comprises a second filter configured to further amplify the second pair of differential signals, remove the deviation signal, and generate a third pair of differential signals. 10. The magnetic sensor of claim 9 , wherein gain of the first filter is less than gain of the second filter. 11. The magnetic sensor of claim 1 , further comprising: an output control circuit configured to control the magnetic sensor to operate in at least one of the first state and the second state based on the magnet detection signal, wherein the output control circuit comprises: a first switch coupled with the output port to form a first current path allowing the load current flows from the output port to outside of the magnetic sensor in the first state; and a second switch coupled with the output port to form a second current path allowing the load current flows from outside of the magnetic sensor to the output port in the second state, wherein the first and second switches operate based on the magnet detection signal to selectively turn on the first and second current paths. 12. The magnetic sensor of claim 11 , wherein the external power supply is an alternating current (AC) power supply, and the magnet detection signal is a switching detection signal, wherein a switching frequency of the magnetic detection signal is proportional to a frequency of the AC power supply or is twice the frequency of the AC power supply.