Spot mode functionality for power saving in a sensor system

We claim: 1. A sensor signal processor that operates at a spot mode to conserve power consumption, comprising: a sensor readout circuit that generates a sensor output based on a sensing signal received from a sensor; an amplitude controller, coupled to the sensor readout circuit, the amplitude controller generating an amplitude control that controls a drive generator to drive a driving element in the sensor to oscillate with a controlled amplitude according to the sensing signal; a phase controller, coupled to the sensor readout circuit, the phase controller generating a phase control that is used to control the drive generator and the sensor readout circuit to operate in a synchronized manner; and wherein at the spot mode, a subset of functional blocks in the sensor signal processor are powered off during a plurality of active power saving durations and powered on during a respective inactive power saving duration subsequent to each of the plurality of active power saving durations, and the amplitude and phase controls are latched and refreshed during the plurality of active and inactive power saving durations, respectively. 2. The sensor signal processor according to claim 1 , wherein the sensor is a micromachined gyroscope that comprises the driving element electrostatically driven to oscillate along a first axis, and rotation with respect to a second axis is sensed based on a Coriolis force induced on the micromachined gyroscope. 3. The sensor signal processor according to claim 1 , further comprising: a clock generator, coupled to the phase controller, the clock generator generating a system clock that is used for synchronization; and a central processor, coupled to the clock generator, the central processor controlling the drive generator and the sensor readout circuit to operate in a synchronized manner. 4. The sensor signal processor according to claim 1 , wherein the subset of functional blocks includes at least one of the sensor readout circuit, the phase controller and the amplitude controller. 5. The sensor signal processor according to claim 1 , wherein the sensor readout circuit, the phase controller and the amplitude controller constitute a readout chain that is powered off during the active power saving durations. 6. The sensor signal processor according to claim 1 , wherein the plurality of active power saving durations and the plurality of inactive power saving durations alternate periodically, and each of the active power saving durations has a duty cycle. 7. The sensor signal processor according to claim 1 , wherein each of the plurality of active power saving durations is enabled as needed to conserve power consumption. 8. The sensor signal processor according to claim 1 , wherein each of the plurality of inactive power saving durations is enabled timely to avoid a driving signal and a system clock from drifting too much and causing a large mismatch with resonating mass movement of the driving element, and wherein the driving signal and the system clock are generated in the sensor signal processor to drive the driving element and synchronize the operation, respectively. 9. The sensor signal processor according to claim 1 , wherein the sensor readout circuit comprises a front-end amplifier, a sample-hold block, an analog-to-digital converter, a demodulator and a low-pass filter. 10. A method of conserving power consumption of a sensor system, comprising the steps of: determining a start and a length of an active power saving duration at a spot mode; selecting a subset of functional blocks in the sensor system during the active power saving duration; holding an amplitude control and a phase control, the amplitude control controlling generation of a driving signal that drives a driving element in a sensor to oscillate with a controlled amplitude based on a sensing signal received from the sensor, the phase control being used to control the sensor system to operate in a synchronized manner; powering off the subset of functional blocks for the length of the active power saving duration; and powering on the subset of functional blocks to refresh the amplitude and phase controls during a subsequent inactive power saving duration. 11. The method of conserving power consumption according to claim 10 , wherein the sensor is a micromachined gyroscope that comprises the driving element electrostatically driven to oscillate along a first axis, and rotation with respect to a second axis is sensed based on a Coriolis force induced on the micromachined gyroscope. 12. The method of conserving power consumption according to claim 10 , wherein the subset of functional blocks includes at least one of a sensor readout circuit, a phase controller and an amplitude controller that generate a sensor output, the amplitude controller, the amplitude control and the phase control based on the sensing signal received from the sensor, respectively. 13. The method of conserving power consumption according to claim 10 , wherein the active power saving duration and the inactive power saving duration repeat periodically, and the active power saving duration has a duty cycle. 14. The method of conserving power consumption according to claim 10 , wherein the active power saving duration is enabled as needed to conserve power consumption. 15. The method of conserving power consumption according to claim 10 , wherein the inactive power saving duration is enabled timely to avoid the driving signal and a system clock from drifting too much and causing a large mismatch with resonating mass movement of the driving element, and wherein the driving signal and the system clock are generated in the sensor system to drive the driving element and synchronize the sensor system, respectively. 16. The method of conserving power consumption according to claim 10 , wherein a sensing signal is received by a sensor readout circuit that generates a sensor output from the sensing signal, and wherein the sensor readout circuit comprises a front-end amplifier, a sample-hold block, an analog-to-digital converter, a demodulator and a low-pass filter. 17. A method of controlling a sensor system, comprising the steps of: determining a start and a length of an active power saving duration at a spot mode; selecting a subset of functional blocks in the sensor system during the active power saving duration; holding an amplitude control and a phase control, the amplitude control controlling generation of a driving signal that drives a sensor to oscillate with a controlled amplitude, the phase control being used to control the sensor system to operate in a synchronized manner; disabling the subset of functional blocks functionally for the length of the active power saving duration; and enabling the subset of functional blocks to refresh the amplitude and phase controls during a subsequent inactive power saving duration. 18. The method of controlling the sensor system according to claim 10 , wherein the sensor is a micromachined gyroscope that comprises the driving element electrostatically driven to oscillate along a first axis, and rotation with respect to a second axis is sensed based on a Coriolis force induced on the micromachined gyroscope. 19. The method of controlling the sensor system according to claim 10 , wherein the subset of functional blocks includes at least one of a sensor readout circuit, a phase controller and an amplitude controller that generate a sensor output, the amplitude controller, the amplitude control and the phase control based on the sensing signal