Low-power activation circuit with motion sensor

What is claimed is: 1. An activation circuit, comprising: a magnetic sensor configured to output a signal proportional to a measured magnetic quantity; a digital difference detection circuit configured to convert the measured magnetic quantity to a digital signal, wherein the digital difference detection circuit is configured to operate according to a low power phase and an operating phase; wherein in the operating phase the digital difference detection circuit compares a current digital signal to selected ones of previous digital signals stored in a digital storage element, to detect at least one difference in digital signals; wherein if the at least one difference in the digital signals is larger than a digital reference level, the digital difference detection circuit causes an activation signal generator to generate an activation signal that activates a system from the low power phase; and wherein the digital difference detection circuit is configured to detect an upward change or a downward change for a time, and if the time is greater than the digital reference level the activation signal generator generates the activation signal. 2. The activation circuit of claim 1 , wherein the digital difference detection circuit, comprises: an analog-to-digital converter configured to track the measured magnetic quantity by converting the signal to the digital signal which corresponds to the measured magnetic quantity; a difference detector configured to measure the at least one difference in the digital signals and to output a difference signal comprising information concerning a magnitude of the at least one difference in the digital signals. 3. The activation circuit of claim 2 , wherein after the system is activated, the digital signal output from the analog-to-digital converter or the difference signal output of the difference detector is outputable to the system. 4. The activation circuit of claim 2 , wherein after the system is activated, the analog-to-digital converter is configured to change from a step-by-step tracking mode to a successive operation mode or an adaptive tracking mode. 5. The activation circuit of claim 1 , wherein the digital difference detection circuit comprises: a comparator configured to receive a differential input voltage output from the magnetic sensor and to generate a comparator signal; a digital logic element coupled to an output of the comparator; and a current steering digital to analog converter coupled to the comparator and configured to compensate the differential input voltage of the comparator. 6. The activation circuit of claim 2 , further comprising: an offset compensation circuit located between the analog-to-digital converter and the difference detector, and configured to remove an offset of the signal such that the difference detector compares a first offset compensated signal with at least a second offset compensated signal. 7. The activation circuit of claim 6 , further comprising: one or more switches disposed between the magnetic sensor and the analog-to-digital converter, the one or more switches configured to be selectively operated at a chopping frequency that enables a current spinning method to provide a first chopping signal comprising an offset and a second chopping signal comprising the offset, wherein the digital difference detection circuit is configured to cancel the offset by building a modulated digital signal from the first and second chopping signals. 8. The activation circuit of claim 6 , further comprising: a low power oscillator configured to operate as a clock for the activation circuit in the low power phase; and a fast oscillator configured to drive the analog-to-digital converter, the offset compensation circuit or the difference detector in the operating phase. 9. The activation circuit of claim 1 , further comprising one or more high voltage protection circuits configured to reject high voltages or reverse battery voltages. 10. The activation circuit of claim 9 , wherein the one or more high voltage protection circuits respectively comprise a depletion-MOS transistor or a JFET transistor that provides a low-voltage supply voltage at minimum supply current for a low power oscillator, a latch or the digital storage element. 11. The activation circuit of claim 1 , wherein the digital reference level is provided to the activation circuit from an apparatus external to the activation circuit. 12. The activation circuit according to claim 1 , wherein the activation signal is adapted to awaken a system receiving the activation signal from a sleep mode, or wherein in the low power phase, digital signals are stored. 13. The activation circuit of claim 1 , further comprising: an analog-to-digital converter configured to track the signal by converting the signal to a digital signal which corresponds to the measured magnetic quantity; wherein during the operating phase, which has a first current consumption, the analog-to-digital converter tracks the signal and the digital difference detection circuit measures the difference between the current digital signal and the selected ones of the previous digital signals; and wherein during the low power phase the analog-to-digital converter or the digital difference detection circuit have a second current consumption lower than the first current consumption.