Hall switch with adaptive threshold

What is claimed is: 1. A position sensor, comprising: a Hall-effect sensor; an adaptation electronic stage coupled to the Hall-effect sensor that outputs a comparison threshold signal based on peak detecting an output of the Hall-effect sensor using a long term adjustment and resetting the long term adjustment to a current output of the Hall-effect sensor in response to a short term adjustment, wherein the adaptation electronic stage comprises: a rapid adaptation stage comprising: a first comparator; a counter operatively coupled to the first comparator; and, a reset signal generation stage operatively coupled to the counter; and, a peak and hold stage comprising: a peak-and-hold and decrement register operatively coupled to the reset signal generation stage; and, a switch electronic stage coupled to the Hall-effect sensor and to the adaptation electronic stage that switches to output a logic active value in response to the output of the Hall-effect sensor exceeding the comparison threshold output, wherein an input of the first comparator is operatively coupled to the output of the Hall-effect sensor and an output of the peak and hold stage, such that the first comparator is configured to output a switch output signal indicative of a comparison between the output of the Hall-effect sensor and a fraction of the output of the peak and hold/decrement register, wherein the counter is configured to increment on each transition of the switch output signal, wherein the reset signal generation stage is configured to generate the short term adjustment to reset the peak and hold/decrement register in response to the counter exceeding a predefined value. 2. The position sensor of claim 1 , wherein the position sensor is configured to detect the presence of a permanent magnet whose position is moved with reference to the position of the position sensor; wherein the long term adjustment is configured to allow the adaptation electronic stage to follow an increase in a peak value of the output of the Hall-effect sensor. 3. The position sensor of claim 2 , wherein the short term adjustment is triggered by an abrupt change in the peak output of the Hall-effect sensor in response to the permanent magnet being located close to the position of the position sensor; wherein the adaptation electronic stage is configured to decrease its output over time to continue to track the peak value of the output of the Hall-effect sensor if that peak value decreases. 4. The position sensor of claim 1 , wherein the switch electronic stage provides hysteresis in switching. 5. The position sensor of claim 1 , wherein the adaptation electronic stage resets the long term adjustment in response to a plurality of minimum-to-peak-to-minimum cycles of the Hall-effect sensor that do not cause the switch electronic stage to output a logic active value. 6. The position sensor of claim 1 , wherein the position sensor is configured for use in detecting when a laptop is closed. 7. The position sensor of claim 1 , wherein the position sensor is configured for use in detecting when a cover is opened. 8. A method of determining a position of a device using a Hall-effect sensor, comprising: receiving a magnetic input by a Hall-effect sensor; outputting a signal by the Hall-effect sensor that represents the magnetic input; receiving the signal output by the Hall-effect sensor by an adaptation component; storing a peak value of the received signal by a peak-and-hold stage of the adaptation component; outputting, by a first comparator operatively coupled to the output of the Hall-effect sensor and an output of the peak and hold stage, a switch output signal; incrementing a counter operatively coupled to the first comparator on each transition of the switch output signal; generating, by a reset signal generation stage operatively coupled to the counter, a reset pattern to effectuate resetting a peak-and-hold and decrement register of the peak and hold stage in response to the counter exceeding a predefined value; detecting the reset pattern in the received signal by the adaptation component; resetting the peak value stored by the peak-and-hold stage of the adaptation component in response to detection of the reset pattern by the peak-and-hold stage of the adaptation component; outputting the stored peak value by the peak-and-hold stage of the adaptation component; generating a threshold output that is less than but proportional to the stored peak value output by the peak-and-hold stage of the adaptation component; receiving the threshold output by a switch component; receiving the signal output by the Hall-effect sensor by the switch component; and switching to output a logic active value by the switch component on the event of the received signal output by the Hall-effect sensor exceeding the received threshold output, wherein the peak-and-hold and decrement register is operatively coupled to the reset signal generation stage, wherein the switch output signal is indicative of a comparison between the output of the Hall-effect sensor and a fraction of the output of the peak and hold/decrement register. 9. The method of claim 8 , where the magnetic input is received by the Hall-effect sensor from a permanent magnet whose position moves with reference to the position of the Hall-effect sensor. 10. The method of claim 8 , wherein the reset pattern comprises a plurality of minimum-to-peak-to-minimum cycles of signal output by the Hall-effect sensor. 11. The method of claim 10 , wherein the reset pattern further comprises that the switch component does not switch to output a logic active during the plurality of minimum-to-peak-to-minimum cycles of the signal output by the Hall-effect sensor. 12. The method of claim 8 , wherein the signal output by the Hall-effect sensor is conditioned by an amplifier before it is provided to the adaptation component and to the switch component. 13. The method of claim 8 , wherein the switch component is a comparator. 14. The method of claim 13 , wherein the comparator is a hysteresis comparator. 15. An electronic device comprising: a permanent magnet mechanically coupled to a first portion of the electronic device; a Hall-effect sensor coupled to a second portion of the electronic device where the first portion and the second portion are moveable with reference to each other and where the Hall-effect sensor receives a magnetic field of the permanent magnet in at least some working configurations of the electronic device; an adaptation electronic stage coupled to the Hall-effect sensor that outputs a comparison threshold signal based on peak detecting an output of the Hall-effect sensor using a long term adjustment and resetting the long term adjustment to a current output of the Hall-effect sensor in response to a short term adjustment, wherein the adaptation electronic stage comprises: a rapid adaptation stage comprising: a first comparator; a counter operatively coupled to the first comparator; and, a reset signal generation stage operatively coupled to the counter; and, a peak and hold stage comprising: a peak-and-hold and decrement register operatively coupled to the reset signal generation stage; and, a switch electronic stage coupled to the Hall-effect sensor and to the adaptation electronic stage that switches to output a logic active value in response to the output of the Hall-effect sensor exceeding the comparison threshold output, wherein an input of the first comparator is operatively coupled to the output of the Hall-effect sensor and an output of the peak and hold stage, such tha