Calibration jig for a catheter comprising a position sensor

The invention claimed is: 1. An apparatus, comprising: (a) a calibration fixture, sized and shaped to fit over a distal-end of a medical probe, such that the distal-end makes physical contact with a wall of the calibration fixture; (b) a calibration position sensor, fixed in the calibration fixture at a known position relative to the wall, and configured, in response to sensing a magnetic field, to produce position signals indicative of a given position of the calibration position sensor; (c) interface circuitry, which is electrically coupled to the calibration position sensor, and is configured to output the position signals; and (d) a processor, which is configured to: (i) receive electrical signals indicative of a measured position of a probe position sensor attached to the medical probe, (ii) receive the position signals produced by the calibration position sensor, and (iii) estimate, based on the electrical signals and the position signals, a distance between the probe position sensor and a tip of the distal-end by subtracting a predetermined distance between the wall and the calibration position sensor from an estimated distance between the calibration position sensor and the probe position sensor. 2. The apparatus according to claim 1 , and comprising an additional calibration position sensor, fixed in the calibration fixture at a predefined position relative to the calibration position sensor, and configured, in response to sensing the magnetic field, to produce additional position signals indicative of an additional position of the additional calibration position sensor, wherein the processor is configured to produce, based on the predefined position, the position signals and the additional position signals, a scaling factor for estimating the distance. 3. The apparatus according to claim 1 , wherein the interface circuitry is configured to transmit the position signals wirelessly or via an electrical cable coupled to the interface circuitry. 4. The apparatus according to claim 1 , and comprising a calibration appliance, which is fixed to the calibration fixture and is configured to produce the magnetic field. 5. The apparatus according to claim 4 , wherein the calibration appliance comprises multiple Helmholtz coils, which are configured to produce the magnetic field. 6. The apparatus according to claim 1 , wherein the calibration fixture comprises a non-magnetic material and an opening that extends as a hole into the non-magnetic material for receiving the distal-end of the medical probe, wherein the wall is presented by the hole. 7. The apparatus according to claim 6 , wherein the hole defines a diameter slightly larger than a diameter of the distal-end of the medical probe. 8. A method for producing a calibration apparatus, the method comprising: (a) producing a calibration fixture, sized and shaped to fit over a distal-end of a medical probe, such that the distal-end makes physical contact with a wall of the calibration fixture; (b) fixing in the calibration fixture, at a known position relative to the wall, a calibration position sensor for producing position signals indicative of a given position of the calibration position sensor in response to sensing a magnetic field; (c) electrically coupling to the calibration position sensor, interface circuitry for outputting the position signals; and (d) coupling to the interface circuitry a processor for: (i) receiving electrical signals indicative of a measured position of a probe position sensor attached to the medical probe, (ii) receiving the position signals produced by the calibration position sensor, and (iii) estimating, based on the electrical signals and the position signals, a distance between the probe position sensor and a tip of the distal-end by subtracting a predetermined distance between the wall and the calibration position sensor from an estimated distance between the calibration position sensor and the probe position sensor. 9. The method according to claim 8 , and comprising fixing in the calibration fixture, at a predefined position relative to the calibration position sensor, an additional calibration position sensor, for producing, in response to sensing the magnetic field, additional position signals indicative of an additional position of the additional calibration position sensor, such that the processor produces, based on (i) the predefined position, (ii) the position signals, and (iii) the additional position signals, a scaling factor for estimating the distance. 10. The method according to claim 8 , and comprising fixing the calibration fixture to a calibration appliance that produces the magnetic field. 11. The method according to claim 8 , and comprising coupling to the interface circuitry at least one of an electrical cable and a wireless communication device for transmitting the position signals. 12. The method according to claim 8 , wherein the calibration fixture comprises a non-magnetic material and an opening that extends as a hole into the non-magnetic material for receiving the distal-end of the medical probe, wherein the wall is presented by the hole. 13. The method according to claim 12 , wherein the hole defines a diameter slightly larger than a diameter of the distal-end of the medical probe. 14. A method, comprising: (a) receiving via a processor, position signals indicative of a given position of a calibration position sensor fixed in a calibration fixture at a known position relative to a wall of the calibration fixture, wherein the calibration fixture is sized and shaped to fit over a distal-end of a medical probe, such that the distal-end makes physical contact with the wall of the calibration fixture; (b) receiving via the processor, electrical signals indicative of a measured position of a probe position sensor attached to the medical probe, wherein a tip of the distal-end makes physical contact with the wall; and (c) estimating via the processor, based on the electrical signals and the position signals, a distance between the probe position sensor and the tip of the distal-end, wherein the act of estimating a distance between the probe position sensor and the tip of the distal-end includes subtracting via the processor, a predetermined distance between the wall and the calibration position sensor from an estimated distance between the calibration position sensor and the probe position sensor. 15. The method according to claim 14 , further comprising: (a) receiving via the processor, additional position signals indicative of an additional position of an additional calibration position sensor fixed in the calibration fixture at a predefined position relative to the calibration position sensor; and (b) producing via the processor, based on the predefined position, the position signals and the additional position signals, a scaling factor for estimating the distance. 16. The method according to claim 14 , further comprising selectively inserting the distal-end of the medical probe into the calibration fixture such that the tip of the distal-end makes physical contact with the wall of the calibration fixture. 17. The method according to claim 14 , wherein the act of estimating a distance between the probe position sensor and the tip of the distal-end includes: (a) estimating via the processor, based on the electrical signals and the position signals, the estimated distance between the calibration position sensor and the probe position sensor. 18. The method according to claim 14 , further comprising producing a magnetic field, wherein the