Geomagnetic sensor

What is claimed is: 1. A geomagnetic sensor, comprising: a core that constitutes a closed magnetic circuit; two coils that are wound around the core in positions facing each other and that are connected in series to generate magnetic flux in a same circumferential direction in the core; an excitation power supply that applies an alternating current with a superimposed direct current to the two coils; and a detection circuit that is connected to a connection point of the two coils, wherein the detection circuit includes a synchronous detector that synchronously detects a voltage at the connection point using an alternating current excitation voltage of the excitation power supply, and a low pass filter that smooths an output of the synchronous detector. 2. The geomagnetic sensor according to claim 1 , further comprising: a feedback coil; a feedback circuit; and a current sense resistor, wherein the feedback coil is wound around the core to make the core magnetically equilibrated, the feedback circuit includes a reference voltage source to generate a reference voltage, an adder to add an output of the low pass filter and the reference voltage, and an amplifier to amplify an output of the adder and flow a feedback current to the feedback coil, and the feedback current is converted to a voltage by the current sense resistor and then the voltage is output. 3. A geomagnetic sensor, comprising: a core that constitutes a closed magnetic circuit; two coils that are wound around the core in positions facing each other and that are connected in series to generate magnetic flux in a same circumferential direction in the core; an excitation power supply that applies an alternating current with a superimposed direct current to the two coils; and a detection circuit that is connected to a connection point of the two coils, wherein the detection circuit includes a direct current eliminator that removes a direct current component of a voltage at the connection point, a full wave rectifier that rectifies full wave of an output of the direct current eliminator, and a low pass filter that smooths an output of the full wave rectifier. 4. The geomagnetic sensor according to claim 3 , further comprising: a feedback coil; a feedback circuit; and a current sense resistor, wherein the feedback coil is wound around the core to make the core magnetically equilibrated, the feedback circuit includes a reference voltage source to generate a reference voltage, an adder to add an output of the low pass filter and the reference voltage, and an amplifier to amplify an output of the adder and flow a feedback current to the feedback coil, and the feedback current is converted to a voltage by the current sense resistor and then the voltage is output. 5. A geomagnetic sensor, comprising: a core that constitutes a closed magnetic circuit; two coils that are wound around the core in positions facing each other and that are connected in series to generate magnetic flux in a same circumferential direction in the core; an excitation power supply that applies an alternating current with a superimposed direct current to the two coils; and a detection circuit that is connected to a connection point of the two coils, wherein the detection circuit includes a direct current eliminator that removes a direct current component of a voltage at the connection point, a half wave rectifier that rectifies half wave of an output of the direct current eliminator, and a low pass filter that smooths an output of the half wave rectifier. 6. The geomagnetic sensor according to claim 5 , further comprising: a feedback coil; a feedback circuit; and a current sense resistor, wherein the feedback coil is wound around the core to make the core magnetically equilibrated, the feedback circuit includes a reference voltage source to generate a reference voltage, an adder to add an output of the low pass filter and the reference voltage, and an amplifier to amplify an output of the adder and flow a feedback current to the feedback coil, and the feedback current is converted to a voltage by the current sense resistor and then the voltage is output. 7. A geomagnetic sensor, comprising: a core that constitutes a closed magnetic circuit; two coils that are wound around the core in positions facing each other and that are connected in series to generate magnetic flux in a same circumferential direction in the core; an excitation power supply that applies an alternating current with a superimposed direct current to the two coils; and a detection circuit that is connected to a connection point of the two coils, wherein the excitation power supply applies the alternating current with the superimposed direct current to the two coils in a manner such that the core is not magnetically saturated. 8. The geomagnetic sensor according to claim 7 , wherein the superimposed direct current is set so as to generate a magnetic field corresponding to a midpoint of a range in which relative permeability changes linearly with response to a magnetic field. 9. A geomagnetic sensor, comprising: a core that constitutes a closed magnetic circuit; two coils that are wound around the core in positions facing each other and that are connected in series to generate magnetic flux in a same circumferential direction in the core; an excitation power supply that applies an alternating current with a superimposed direct current to the two coils; and a detection circuit that is connected to a connection point of the two coils, wherein the superimposed direct current is set so as to generate a magnetic field corresponding to a midpoint of a range in which relative permeability changes linearly with response to a magnetic field.