Magnetic sensor

What is claimed is: 1. A magnetic sensor for discriminating between high and low coercivity magnets, the sensor comprising: (i) a first magnetic field operable to orient high and low coercivity magnets in a first magnetic orientation; (ii) a second magnetic field, lower in strength than the first magnetic field, and operable to orient only the low coercivity magnets in a second magnetic orientation opposite to the first magnetic orientation; and (iii) a sensor for ascertaining the magnetic orientation of each of the magnets and thereby identifying if a magnet is a high coercivity magnet or a low coercivity magnet and the sensor including a microcontroller for outputting an indication of a magnetic field strength for the magnet and a polarity for the magnet, wherein the sensor further includes pairs of channel detectors, each pair configured to provide a pair of sensing outputs simultaneously to the microcontroller, each pair of sensing outputs includes one positive signal and one negative signal for electrical currents in an analogue format, the microcontroller configured to convert the positive and negative signals to a digital format and subtract the positive and negative signals in the digital format from one another to reduce noise and output a result from the subtraction as the indication in the digital format. 2. A magnetic sensor according to claim wherein the sensor for ascertaining the magnetic orientation of each of the magnets comprises a fluxgate sensor. 3. A magnetic sensor according to claim 2 , wherein the fluxgate sensor comprises a printed circuit board (pcb) having a plurality of track layers. 4. A magnetic sensor according to claim 3 , wherein the pcb also defines a plurality of vias extending therethrough, and a plurality of tracks, each track spiraling around a via to provide a coil. 5. A magnetic according to claim 4 , wherein the fluxgate sensor also comprises a plurality of microwires, each microwire located in a via and oriented normal to pcb track layers. 6. A magnetic sensor according to claim 5 , wherein the microwires comprise glass coated bistable microwires. 7. A magnetic sensor according to claim 6 , wherein the fluxgate sensor comprises a linear array of vias, adjacent vias being spaced by a fixed distance. 8. A magnetic sensor according to claim 2 , wherein the magnetic sensor further comprises (iv) a second fluxgate sensor spaced from and aligned with the first fluxgate sensor to define a gap between the two fluxgate sensors through which media items may be moved. 9. A method of discriminating between high and low coercivity magnets, the method comprising: using a first magnetic field to orient high and low coercivity magnets in a first magnetic orientation; using a second magnetic field, lower in strength than the first magnetic field, to orient only the low coercivity magnets in a second magnetic orientation opposite to the first magnetic orientation; ascertaining the magnetic orientation of each of the magnets; outputting a magnetic field strength for the magnet and a polarity for the magnet, herein outputting further includes sensing pairs of outputs simultaneously, each pair of sensing outputs includes one positive signal and one negative signal for electrical currents in an analogue format, converting the positive and negative signals to a digital format and subtracting the positive and negative signals in the digital format from one another to reduce noise and outputting a result from the subtracting as the indication in the digital format; and identifying if a magnet is a high coercivity magnet or a low coercivity magnet based on the ascertained magnetic orientation.