초록 ▼

A combined passive and active object sensing system (30; 50; 70) employing electric field sensing is described. An electric field sensing transmission electrode (2) generates a first electric field (11, 12, 13) that induces a current in an electric field sensing reception electrode (4). A passive ob

A combined passive and active object sensing system (30; 50; 70) employing electric field sensing is described. An electric field sensing transmission electrode (2) generates a first electric field (11, 12, 13) that induces a current in an electric field sensing reception electrode (4). A passive object (10) is sensed from variation in this current. An active object (31; 51; 71) comprises a further electric field sensing transmission electrode (33; 53; 73) and generates a second electric field (35, 36, 37; 55, 56, 57; 75, 76, 77). This may be generated by the active object (31) coupling with and applying a phase shift to the first electric field (11, 12, 13). Alternatively the second electric field (55, 56, 57) may be generated at a different frequency to the first electric field (11, 12, 13). Alternatively the second electric field (75, 76, 77) may be generated by the active object (71) coupling with an alternating magnetic field generated by a coil (172). The second electric field (35, 36, 37; 55, 56, 57; 75, 76, 77) induces a current in the electric field sensing reception electrode (4) that varies with the position of the active object (31; 51; 71). The separate currents are distinguished by virtue of their different phase or frequency.

대표청구항 ▼

What is claimed is: 1. An object sensing system, comprising: a first electric field sensing transmission electrode; an electric field sensing reception electrode; a driving circuit for driving the first electric field sensing transmission electrode so as to generate a first electric field; an el

What is claimed is: 1. An object sensing system, comprising: a first electric field sensing transmission electrode; an electric field sensing reception electrode; a driving circuit for driving the first electric field sensing transmission electrode so as to generate a first electric field; an electric field generating object including a second electric field sensing transmission electrode and means for driving the second electric field sensing transmission electrode so as to generate a second electric field; and a current sensing circuit for distinguishably sensing currents induced in the electric field sensing reception electrode by the first electric field and the second electric field, wherein the first electric field sensing transmission electrode and the electric field sensing reception electrode are arranged such that a first object placed in the vicinity of the first electric field sensing transmission electrode and the electric field sensing reception electrode causes a variation in the current induced in the electric field sensing reception electrode by the first electric field, and wherein the current sensing circuit is adapted to sense the first object from the variation in the current induced in the electric field sensing reception electrode by the first electric field and to sense the electric field generating object from a variation in the current induced in the electric field sensing reception electrode by the second electric field. 2. The system of claim 1, wherein the means for driving the second electric field sensing transmission electrode so as to generate a second electric field comprises: a reception electrode for coupling with the first electric field to generate a received signal; means for applying a phase shift to the received signal; and means for delivering the phase shifted signal to the second electric field sensing transmission electrode; wherein the current sensing circuit is adapted to distinguish the current induced from the first electric field from the current induced from the second electric field by virtue of the different phases of the two fields. 3. The system of claim 2, including a plurality of electric field generating objects, the driving circuit of each being adapted to drive each to generate a respective second electric field distinguishable from the other second electric fields on a time-modulated basis; wherein the current sensing circuit is adapted to distinguish the current induced from each of the plural electric field generating objects by virtue of the different time-modulated form of the fields from each of the electric field generating objects. 4. The system of claim 1, wherein the means for driving the second electric field sensing transmission electrode so as to generate a second electric field comprises: a driving circuit for driving the second electric field sensing transmission electrode so as to generate the second electric field at a frequency different to the frequency of the first electric field; and wherein the current sensing circuit is adapted to distinguish the current induced from the first electric field from the current induced from the second electric field by virtue of the different frequencies of the two fields. 5. The system of claim 4, comprising a plurality of electric field generating objects, the driving circuit of each being adapted to drive each to generate a respective second electric field of different frequency; wherein the current sensing circuit is adapted to distinguish the current induced from each of the plural electric field generating objects by virtue of the different frequencies of the fields from each of the electric field generating objects. 6. The system of claim 4, including a plurality of electric field generating objects, the driving circuit of each being adapted to drive each to generate a respective second electric field distinguishable from the other second electric fields on a time-modulated basis; wherein the current sensing circuit is adapted to distinguish the current induced from each of the plural electric field generating objects by virtue of the different time-modulated form of the fields from each of the electric field generating objects. 7. The system of claim 1,comprising a plurality of electric field generating objects, the driving circuit of each being adapted to drive each to generate a respective second electric field distinguishable from the other second electric fields on a time-modulated basis; wherein the current sensing circuit is adapted to distinguish the current induced from each of the plural electric field generating objects by virtue of the different time-modulated form of the fields from each of the electric field generating objects. 8. The system of claim 1, further comprising means for generating an alternating magnetic field; and wherein the means for driving the second electric field sensing transmission electrode so as to generate a second electric field comprises: an inductor for coupling with the alternating magnetic field to generate a received signal; and means for delivering the signal to the second electric field sensing transmission electrode; wherein the current sensing circuit is adapted to distinguish the current induced from the first electric field from the current induced from the second electric field by virtue of different phases of the two fields. 9. The system of claim 8, wherein shielding is provided to substantially block any electric field generated by the means for generating an alternating magnetic field and substantially allow to pass the magnetic field generated by the means for generating an alternating magnetic field. 10. The system of claim 8, wherein the current sensing circuit is adapted to substantially filter out currents produced in the electric field sensing reception electrode by electric fields generated by the means for generating an alternating magnetic field. 11. The system of claim 10, wherein the filtering out is performed using a difference in phase between the electric field generated by the means for generating an alternating magnetic field and the second electric field generated by the second electric field sensing transmission electrode. 12. The system of claim 11, wherein shielding is provided to substantially block any electric field generated by the means for generating an alternating magnetic field and substantially allow to pass the magnetic field generated by the means for generating an alternating magnetic field. 13. The system of claim 10, wherein shielding is provided to substantially block any electric field generated by the means for generating an alternating magnetic field and substantially allow to pass the magnetic field generated by the means for generating an alternating magnetic field. 14. A current sensing circuit for an electric field sensing arrangement; the current sensing circuit comprising: means for sensing variation in a current induced in an electric field sensing reception electrode by a first electric field; and means for separately sensing variation in a current induced in the electric field sensing reception electrode by a second electric field. 15. The circuit of claim 14, wherein the current sensing circuit is adapted to distinguish between the respective currents induced by the first and second electric fields by virtue of different respective phases of the two fields. 16. The circuit of claim 15, including means for separately sensing variation in respective currents induced in the electric field sensing reception electrode by a plurality of further electric fields; wherein the current sensing circuit is adapted to distinguish the respective induced currents by virtue of different respective time-modulated forms of the further electric fields. 17. The circuit of claim 14, wherein the current sensing circuit is adapted to distinguish between the respective currents induced by the first and second electric fields by virtue of different respective frequencies of the two fields. 18. The circuit of claim 17, further comprising means for separately sensing variation in respective currents induced in the electric field sensing reception electrode by a plurality of further electric fields; wherein the current sensing circuit is adapted to distinguish the respective induced currents by virtue of different respective frequencies of the further electric fields. 19. The circuit of claim 17, including means for separately sensing variation in respective currents induced in the electric field sensing reception electrode by a plurality of further electric fields; wherein the current sensing circuit is adapted to distinguish the respective induced currents by virtue of different respective time-modulated forms of the further electric fields. 20. The circuit of claim 14, further comprising means for separately sensing variation in respective currents induced in the electric field sensing reception electrode by a plurality of further electric fields; wherein the current sensing circuit is adapted to distinguish the respective induced currents by virtue of different respective time-modulated forms of the further electric fields. 21. A method of sensing objects, comprising: generating a first electric field using a first electric field sensing transmission electrode; sensing a first current induced in an electric field sensing reception electrode by the first electric field; sensing a first object by detecting variation in the current induced by the first electric field, the variation being caused by the first object being placed in the vicinity of the first electric field sensing transmission electrode and the electric field sensing reception electrode; generating a second electric field using an electric field sensing transmission electrode located in a second object; sensing the second object by sensing, in distinction from the first current, a second current induced in the electric field sensing reception electrode by the second electric field when the second object is placed in the vicinity of the electric field sensing reception electrode.