Security marker

We claim: 1. A method of making a marker, comprising: disposing a resonator with a flat planar cross-sectional profile in a cavity formed in a first substrate partially defining a marker housing; sealing an opening of the cavity using a second substrate; placing a first bias element adjacent to the second substrate so that the resonator will be biased by the first bias element when the marker is in use to oscillate at a frequency of a received transmit burst; and using a physical structure in the cavity to reduce frictional forces between the resonator and at least the second substrate, where the physical structure comprises at least one of (a) a portion of the first or second substrate that is located at an interface of the first and second substrates, protrudes out and into the cavity, and physically supports only edges of the resonator, (b) a textured sidewall of the cavity defined by the second substrate having a plurality of protruding textured shapes; and (c) a non-conductive mesh material, screen material, or perforated sheet material forming the second substrate. 2. The method according to claim 1 , wherein the portion of the first or second structure in (a) comprises a narrow strip of material formed at the interface of the first and second substrate during a heat sealing process. 3. The method according to claim 2 , wherein the narrow strip of material physically lifts the resonator off of the second substrate. 4. The method according to claim 1 , wherein the plurality of protruding textured shapes extend from at least the second substrate in a direction towards the resonator. 5. The method according to claim 1 , wherein the textured sidewall further comprises a plurality of depressions extending from at least the second substrate in a direction away from resonator. 6. The method according to claim 1 , wherein the frictional forces are further reduced by a magnetic field that is produced by a second bias element disposed on a side of the resonator that is opposite to the side of the resonator where the first bias element resides. 7. The method according to claim 1 , wherein frictional forces are further reduced by a magnetic field that is produced by the first bias element that is longer than the resonator. 8. The method according to claim 7 , wherein the magnetic field lines of the magnetic field enter the resonator at opposing ends of its elongate body. 9. A marker, comprising: a marker housing; a resonator with a flat planar cross-sectional profile disposed in a cavity formed in a first substrate partially defining the marker housing; a second substrate sealing an opening of the cavity; a first bias element placed adjacent to the second substrate so that the resonator will be biased by the first bias element when the marker is in use to oscillate at a frequency of a received transmit burst; and a physical structure configured to reduce frictional forces between the resonator and at least the second substrate, where the physical structure comprises at least one of (a) a portion of the first or second substrate that is located at an interface of the first and second substrates, protrudes out and into the cavity, and physically supports only edges of the resonator, (b) a textured sidewall of the cavity defined by the second substrate having a plurality of protruding textured shapes; and (c) a non-conductive mesh material, screen material, or perforated sheet material forming the second substrate. 10. The marker according to claim 9 , wherein the portion for the first or second structure in (a) comprises a narrow strip of material formed at the interface of the first and second substrate during a heat sealing process. 11. The marker according to claim 9 , wherein the narrow strip of material physically lifts the resonator off of the second substrate. 12. The marker according to claim 9 , wherein the plurality of textured shape extend from at least the second substrate in a direction towards the resonator. 13. The marker according to claim 9 , wherein the textured sidewall further comprises a plurality of depressions extending from at least the second substrate in a direction away from resonator. 14. The marker according to claim 9 , wherein the frictional forces are further reduced by a magnetic field that is produced by a second bias element disposed on a side of the resonator that is opposite to the side of the resonator where the first bias element resides. 15. The marker according to claim 9 , wherein the frictional forces are further reduced by a magnetic field that is produced by the first bias element that is longer than the resonator. 16. The marker according to claim 15 , wherein the magnetic field lines of the magnetic field enter the resonator at opposing ends of its elongate body.