Adaptive proximity detection system

1 . A proximity detection system for a mobile device, comprising: an infrared emitter to emit infrared light; an infrared detector to detect the infrared light after reflection from a target and to provide a detector signal; and a signal processing subsystem configured to control the proximity detection system into a first, detect mode for detecting proximity of the target as the target approaches the mobile device, and after detection of the target to control the proximity detection system into a second, release mode for detecting movement of the target out of proximity to the mobile device; and wherein the signal processing subsystem is configured to control the proximity detection system such that for a given proximity of the target the detector signal reduces when the mode switches from the detect mode to the release mode. 2 . The system of claim 1 wherein the signal processing subsystem is configured to control the infrared emitter to emit a first level of optical energy in the detect mode and a second, lower level of optical energy in the release mode. 3 . The system of claim 2 wherein the signal processing subsystem is programmable to control the optical energy by controlling one or more of a drive level, a number of pulses of the infrared light, a pulse length of the infrared light and, where the system comprises a plurality of the infrared emitters, a number of the infrared emitters used to emit the infrared light. 4 . The system of claim 1 wherein the signal processing subsystem is configured to generate a proximity detect signal for the mobile device on detection of proximity of the target to enable the mobile device to perform a post-detect action, and to switch back to the detect mode in response to a detect enable signal from software running on the mobile device that indicates that a post-release action has been performed by the mobile device. 5 . The system of claim 4 wherein the proximity detect signal is a detect interrupt signal generated by the signal processing system for the mobile device; and wherein the signal processing subsystem is configured to generate a release interrupt signal for the mobile device when the mode switches from the detect mode to the release mode. 6 . The system of claim 1 further comprising a programmable detect threshold register and a programmable release threshold register, wherein in the detect mode the a proximity detect signal for the mobile device on detection of proximity of the target to enable the mobile device to perform a post-detect action, and to switch back to the detect mode in response to a detect enable signal from software signal processing subsystem is configured to compare a value derived from the detector signal with a value in the detect threshold register, and in the release mode the signal processing subsystem is configured to compare a value derived from the detector signal with a value in the release threshold register. 7 . The system of claim 1 further configured to store a crosstalk calibration value for each of the detect mode and the release mode, wherein an analogue front end of the system or the signal processing subsystem is configured to apply the respective crosstalk calibration value in each of the detect mode and the release mode. 8 . A mobile device comprising the system of claim 1 . 9 . The mobile device of claim 8 wherein the mobile device has an OLED display, and wherein one or both of the infrared emitter and the infrared detector is located behind the OLED display. 10 . A method of detecting proximity of a target to a mobile device using a proximity detection system, comprising: illuminating the target with infrared light from an infrared emitter; detecting reflected light from the target to provide a detector signal; detecting proximity of the target to the mobile device using the detector signal; then controlling the proximity detection system to reduce the detector signal; and detecting movement of the target out of proximity to the mobile device. 11 . The method of claim 10 wherein controlling the proximity detection system to reduce the detector signal comprises reducing an optical energy output from the infrared emitter. 12 . The method of claim 10 wherein detecting proximity of the target to the mobile device using the detector signal comprises comparing a value derived from the detector signal with a detect threshold, and wherein detecting movement of the target out of proximity to the mobile device comparing a value derived from the detector signal with a release threshold different to the detect threshold. 13 . The method of claim 10 further comprising setting a difference between the detect threshold and the release threshold to define a false trigger rate of the proximity detection system. 14 . The method of claim 14 wherein the difference between the detect threshold and the release threshold defines a proximity ratio, P r , according to: P r = d e t e c t   t h r e s h o l d − r e l e a s e   t h r e s h o l d 6 σ where σ is the RMS noise level of the detector signal, and wherein setting the difference between the detect threshold and the release threshold to define the false trigger rate comprises selecting a value for P r according to P r = N C where N is a number of standard deviations of a distribution of the noise in the detector signal that defines a probability of false trigger corresponding to the false trigger rate, and C is a constant between 1 and 5. 15 . Computer-readable instructions, or one or more computer storage media storing computer-readable instructions, that when executed by one or more computers cause the one or more computers to implement the signal processing subsystem of any of claim 1 . 16 . Computer-readable instructions, or one or more computer storage media storing computer-readable instructions, that when executed by one or more computers cause the one or more computers to implement the method of claim 10 .