Fluxgate magnetic sensor readout apparatus

What is claimed is: 1. A sensor readout apparatus for providing an output signal from a fluxgate magnetic sensor, comprising: a demodulator circuit, including: a first demodulator input coupled to a first end of a sense coil of the fluxgate magnetic sensor, a second demodulator input coupled to a second end of the sense coil, a first demodulator output, a second demodulator output, and a demodulator switching circuit operative according to at least one demodulator switching control signal in a first state to electrically couple the first demodulator input to the first demodulator output and to electrically couple the second demodulator input to the second demodulator output, and in a second state to electrically couple the first demodulator input to the second demodulator output and to electrically couple the second demodulator input to the first demodulator output; a control circuit providing the at least one demodulator switching control signal to alternate operation of the demodulator switching circuit between the first and second states; and an amplifier circuit, including: an amplifier with a first amplifier input connected to the first demodulator output, a second amplifier input connected to the second demodulator output, and an amplifier output, and at least one feedback capacitance connected between the amplifier output and one of the amplifier inputs to integrate output current provided by the amplifier output and provide a voltage output signal at the amplifier output indicating a magnetic field sensed by the fluxgate magnetic sensor. 2. The sensor readout apparatus of claim 1 , wherein the amplifier output is a differential output with a first amplifier output and a second amplifier output, and wherein the at least one feedback capacitance includes a first feedback capacitor connected between the first amplifier output and the first amplifier input, and a second feedback capacitor connected between the second amplifier output and the second amplifier input. 3. The sensor readout apparatus of claim 2 , further comprising a reset circuit operative according to at least one reset signal from the control circuit to selectively discharge the first and second feedback capacitors. 4. The sensor readout apparatus of claim 3 , wherein the control circuit is configured to provide the at least one demodulator switching control signal to operate the demodulator switching circuit sequentially in the first and second states in each of a plurality of sensing cycles, and wherein the control circuit is configured to selectively provide the reset signal to discharge the first and second feedback capacitors every integer number N sensing cycles, wherein N is greater than or equal to 1. 5. The sensor readout apparatus of claim 4 , wherein the integer number N is configurable according to a gain input signal provided to the control circuit. 6. The sensor readout apparatus of claim 2 , wherein the amplifier is a transconductance amplifier. 7. The sensor readout apparatus of claim 3 , further comprising a disable circuit operative according to at least one disable signal from the control circuit to selectively connect the first and second demodulator inputs together to disable the sensor readout apparatus. 8. The sensor readout apparatus of claim 1 , further comprising a reset circuit operative according to at least one reset signal from the control circuit to selectively discharge the at least one feedback capacitance. 9. The sensor readout apparatus of claim 8 , wherein the control circuit is configured to provide the at least one demodulator switching control signal to operate the demodulator switching circuit sequentially in the first and second states in each of a plurality of sensing cycles, and wherein the control circuit is configured to selectively provide the reset signal to discharge the at least one feedback capacitance every integer number N sensing cycles, wherein N is greater than or equal to 1. 10. The sensor readout apparatus of claim 9 , wherein the integer number N is configurable according to a gain input signal provided to the control circuit. 11. The sensor readout apparatus of claim 1 , further comprising a disable circuit operative according to at least one disable signal from the control circuit to selectively connect the first and second demodulator inputs together to disable the sensor readout apparatus. 12. The sensor readout apparatus of claim 1 , wherein the amplifier is a transconductance amplifier. 13. A magnetic sensing apparatus, comprising: a fluxgate sensor structure, including a core structure, at least one excitation coil wound around at least a portion of the core structure, and a sense coil; an excitation circuit configured to provide a periodic bidirectional excitation current waveform to the excitation coil; a control circuit controlling timing of the periodic bidirectional excitation current waveform; and a sensor readout circuit, comprising: a demodulator circuit operatively synchronized with the excitation circuit according to at least one demodulator switching control signal from the control circuit to demodulate a sense signal from the sense coil, and an amplifier circuit, including: an amplifier with a first amplifier input connected to a first demodulator output, a second amplifier input connected to a second demodulator output, and an amplifier output, and at least one feedback capacitance connected between the amplifier output and one of the first and second amplifier inputs to integrate output current provided by the amplifier output and provide a voltage output signal at the amplifier output indicating a magnetic field sensed by the fluxgate magnetic sensor structure. 14. The magnetic sensing apparatus of claim 13 , wherein the demodulator circuit comprises: a first demodulator input coupled to a first end of a sense coil of the fluxgate magnetic sensor; a second demodulator input coupled to a second end of the sense coil; and a demodulator switching circuit operative according to the at least one demodulator switching control signal in a first state to electrically couple the first demodulator input to the first demodulator output and to electrically couple the second demodulator input to the second demodulator output, and in a second state to electrically couple the first demodulator input to the second demodulator output and to electrically couple the second demodulator input to the first demodulator output; and wherein the control circuit provides the at least one demodulator switching control signal to alternate operation of the demodulator switching circuit between the first and second states. 15. The magnetic sensing apparatus of claim 14 , wherein the amplifier output is a differential output with a first amplifier output and a second amplifier output, and wherein the at least one feedback capacitance includes a first feedback capacitor connected between the first amplifier output and the first amplifier input, and a second feedback capacitor connected between the second amplifier output and the second amplifier input. 16. The magnetic sensing apparatus of claim 13 , further comprising a reset circuit operative according to at least one reset signal from the control circuit to selectively discharge the at least one feedback capacitance; wherein the control circuit is configured to operate the excitation circuit and the demodulator circuit in each of a plurality of sensing cycles individually corresponding to one period of the periodic bidirectional excitation signal; and wherein the control circuit is configured to selectiv