초록 ▼

Disclosed is a method and system for navigating an instrument relative to a patient that can be near a field distorting feature. A localizer can generate an electromagnetic field that is sensed by a tracking device to determine a location of the tracking device with the sensed electromagnetic field.

Disclosed is a method and system for navigating an instrument relative to a patient that can be near a field distorting feature. A localizer can generate an electromagnetic field that is sensed by a tracking device to determine a location of the tracking device with the sensed electromagnetic field. The system and related method can assist in determining whether a navigation field is distorted near a tracking device of the instrument.

대표청구항 ▼

1. A method to determine proper navigation of an instrument in a navigation field, comprising: receiving a first signal from a first tracking device fixed to the instrument at a first instrument position;receiving a second signal from a second tracking device fixed to the instrument at a second inst

1. A method to determine proper navigation of an instrument in a navigation field, comprising: receiving a first signal from a first tracking device fixed to the instrument at a first instrument position;receiving a second signal from a second tracking device fixed to the instrument at a second instrument position that is spaced a distance along the instrument from the first instrument position, wherein the instrument is able to flex to change at least one of a relative distance or orientation between the first instrument position and the second instrument position;determining a first three-dimensional location and a first three-dimensional orientation of the first tracking device based on the first received signal;determining a second three-dimensional location and a second three-dimensional orientation of the second tracking device based on the second received signal;determining a relative location and orientation of the first tracking device and the second tracking device based on the determined first three-dimensional location and orientation and the determined second three-dimensional location and orientation;recalling at least one instrument constraint based on a physical characteristic of the instrument at least between the first instrument position and the second instrument position from a memory system;determining whether the determined relative location and orientation of the first tracking device and the second tracking device is probable based on the recalled at least one instrument constraint;determining a parameterized energy of the instrument between the first tracking device and the second tracking device; anddetermining a minimization of an energy functional based on the parameterized energy of the instrument between the first tracking device and the second tracking device;wherein the determined minimization of the energy functional is operable to determine a probable location and orientation of the instrument;wherein the navigation is able to be deemed improper if the relative location and orientation of the first tracking device and the second device is determined to be improbable based on the recalled at least one instrument constraint. 2. The method of claim 1, wherein the energy functional is built starting with a bending energy that depends upon a curvature of the instrument between at least the first tracking device and the second tracking device. 3. The method of claim 1, further comprising: a third tracking device;wherein the energy functional is calculated between the first tracking device, second tracking device, and third tracking device. 4. The method of claim 1, further comprising: placing the instrument within a volume;wherein the energy functional has a maximum energy value that is related to a physical constraint on the instrument based on the volume in which the instrument is placed when the first signal is received and the second signal is received. 5. The method of claim 1, wherein receiving the first signal occurs substantially simultaneously with receiving the second signal. 6. The method of claim 1, further comprising: navigating the instrument with a navigation system within a subject space based at least on the determined first three-dimensional location and orientation and the determined second three-dimensional location and orientation. 7. The method of claim 6, further comprising: stopping a user display of a system navigation, including at least one of removing a presentation of the instrument from the user display or removing an image from the user display, while continuing the system navigation if it is determined that the determined relative location and orientation of the first tracking device and the second tracking device is improbable based on the determined relative location and orientation of the first tracking device and the second tracking device;restarting the user display of the system navigation after stopping the user display of the system navigation when the navigation system determines that the determined relative location and orientation of the first tracking device and the second tracking device is probable. 8. The method of claim 7, further comprising: mitigating an interference caused by an interfering object that interferes with receiving the first signal from the first tracking device and receiving the second signal from the second tracking device. 9. The method of claim 1, further comprising: determining the location and orientation of the instrument relative to a subject space; andillustrating an icon representing a model of at least a portion of the instrument based on the determined energy functional of the instrument between the first tracking device and the second tracking device superimposed on an image of a subject that defines the subject space. 10. The method of claim 1, wherein the parameterized energy includes at least one of a torsion energy, a compression energy, extension energy, or a rotation energy; wherein determining the parameterized energy includes determining a parameterizable physical constraint of the instrument related to the parameterizable energy. 11. The method of claim 1, further comprising: determining a calibrated location and orientation of the first tracking device relative to the second tracking device when the instrument is at-rest including an at rest location and orientation of the first tracking device relative to the second tracking device;wherein determining whether the determined relative location and orientation of the first tracking device and the second tracking device is probable includes comparing the calibrated location and orientation of the first tracking device relative to the second tracking device when the instrument is at-rest and the determined relative location and orientation of the first tracking device and the second tracking device based on the determined first three-dimensional location and orientation and the determined second three-dimensional location and orientation; andceasing a navigation of the instrument if the determined relative location and orientation of the first tracking device and the second tracking device is improbable;wherein the determination of the relative location and orientation of the first tracking device and the second tracking device is improbable based on a selected value of the minimization of the energy functional including evaluation of a curve parameter and a curve tangent. 12. The method of claim 1, wherein determining the first three-dimensional location and orientation of the first tracking device based on the first received signal and determining the second three-dimensional location and orientation of the second tracking device based on the second received signal includes accounting for at least one known error in at least one of the first received signal or the second received signal. 13. The method of claim 12, wherein accounting for at least one known error includes accounting for an error in a tracked three dimensional location and orientation of at least one of the first tracking device or the second tracking device. 14. The method of claim 1, comprising: storing with a first storage device the at least one instrument constraint of the instrument that is a flexible instrument;storing with a second storage device a calibrated position of the first tracking device and the second tracking device fixed to the flexible instrument; andaccessing with a processor: the received first signal regarding a current tracked location and orientation of the first tracking device;the received second signal regarding a current tracked location and orientation of the second tracking device; andthe accessed stored at least one instrument constraint from the first storage device and the stored calibrated position from the second storage device to execute an algorithm to determine a probability of a determined position of the first tracking device and the second tracking device fixed to the flexible instrument based on the accessed stored at least one instrument constraint, accessed stored calibrated position, the current tracked location and orientation of the first tracking device, and the current tracked location and orientation of the second tracking device;outputting from the processor a determination of a distortion of the navigation field when the determined probability of the determined position of the first tracking device and the second tracking device is outside of a selected range. 15. The method of claim 14, providing a single storage device as the first storage device and the second storage device. 16. The method of claim 14, further comprising: determining a shape of the flexible instrument at least by minimizing the energy functional of the flexible instrument at least between the first tracking device and the second tracking device based on the current tracked location and orientation of the first tracking device and the second tracking device and the saved physical constraints and the determined calibrated position of the first tracking device and the second tracking device; andbased on the determined shape, determine whether the determined shape is probable based on the accessed stored at least one instrument constraint and the determined calibrated position of the first tracking device and the second tracking device. 17. The method of claim 16, further comprising: creating a user defined physical constraint on the flexible instrument after and different from the stored at least one instrument constraint;wherein determining the energy functional is further based on the user defined physical constraint of the flexible instrument. 18. The method of claim 16, further comprising: executing the algorithm with the processor to determine the energy functional based on at least one of (i) a distance between the current tracked location of the first tracking device and the second tracking device or (ii) determining an estimated arc length of the flexible instrument between the first tracking device and the second tracking device or (iii) a relative orientation between the current tracked orientation of the first tracking device and the second tracking device. 19. The method of claim 18, further comprising: positioning the instrument within a subject during a procedure;determining an intra-procedure physical constraint of the flexible instrument based at least on a physical feature dimension of the subject;determining a maximum value of the energy functional based on the accessed determined intra-procedure physical constraint; andcomparing the maximum value of the energy functional to the determined value of the energy functional. 20. The method of claim 18, wherein the energy functional is further based at least on a curvature of the instrument as evaluated with a curve parameter and a curve tangent derivative. 21. The method of claim 18, wherein the accessed stored at least one instrument constraint includes at least one of a wire constant, a modulus of elasticity, a dimension of the instrument, or combinations thereof. 22. The method of claim 21, wherein the probable value of the energy functional is at or below a threshold value. 23. The method of claim 22, further comprising: determining a probability value of the energy functional based on whether the value of the energy functional is greater than the threshold energy functional value. 24. The method of claim 23, further comprising: stopping a current user display of a system tracking of the first tracking device and the second tracking device if the determined energy functional is determined to have a determined probability value less than a selected threshold probability value while maintaining the system tracking to determine if the determined energy functional changes to have a determined probability value greater than the selected threshold probability value. 25. The method of claim 24, further comprising: providing an output to a user that the current user display of the system tracking is stopped, wherein the output includes at least one of a visual display, a tactile output, or an audible output. 26. The method of claim 24, further comprising: generating an electromagnetic field as the navigation field; andtracking the first tracking device and the second tracking device by sensing the generated electromagnetic field in a navigation space. 27. The method of claim 26, further comprising: determining that a distortion is present in the generated electromagnetic field if the probability value of the energy functional based on the determined value of the energy functional is greater than the threshold energy functional value;wherein outputting from the processor the determination of the distortion of the navigation field is based on the determined that the distortion is present in the generated electromagnetic field. 28. A system to determine proper navigation of an instrument in a navigation field, comprising: a localizer configured to generate an electromagnetic field as the navigation field;a flexible instrument configured to be moved relative to the navigation field;a first tracking device fixed to the flexible instrument at a first location;a second tracking device fixed to the flexible instrument at a second location spaced apart from the first location; anda navigation processor configured for: receiving a first signal from the first tracking device;receiving a second signal from the second tracking device;determining a relative location and orientation of the first tracking device and the second tracking device based on the respective received first signal and second signal;recalling from a memory system at least one instrument constraint based on a physical feature of the instrument between the first tracking device at the first location and the second tracking device at the second location;determining a minimization of an energy functional based on the parameterized energy of the instrument between the first tracking device and the second tracking device; anddetermining whether the determined relative location and orientation of the first tracking device and the second tracking device is probable based on the recalled at least one instrument constraint to determine whether navigation of the instrument should be stopped if the relative location and orientation is improbable;wherein determining whether the determined relative location and orientation of the first tracking device and the second tracking device is probable to determine whether distortion exists in the navigation field includes determining a parameterized energy of the instrument between the first tracking device and the second tracking device;wherein the determined minimization of the energy functional is operable to determine a probable location and orientation of the instrument;wherein the navigation is able to be deemed improper if the relative location and orientation of the first tracking device and the second device is determined to be improbable based on the recalled at least one instrument constraint. 29. The system of claim 28, wherein the navigation processor is further configured for determining whether the determined relative location and orientation of the first tracking device and the second tracking device is probable by: determining a geometry of the flexible instrument based on the determined relative location and orientation of the first tracking device and the second tracking device; anddetermining a physical parameterizable energy of the flexible instrument based on the geometry of the flexible instrument;wherein the first tracking device and the second tracking device are both configured to sense the navigation field. 30. The system of claim 29, further comprising: a signaling system configured to signal a user via at least one of a tactile signal, a visual signal, or an audible signal that the determined physical parameterizable energy is improbable. 31. The system of claim 30, further comprising: a display device configured to illustrate a model of the flexible instrument representing the determined geometry of the flexible instrument and the physical parameterizable energy. 32. The system of claim 29, wherein the flexible instrument is configured to change geometry based on the at least one instrument constraint during a procedure. 33. The system of claim 29, wherein the physical parameterizable energy includes at least one of an energy functional value, a torsion energy, a compression energy, extending energy, or a rotation energy. 34. The system of claim 33, wherein the physical parameterizable energy further includes at least one associated physical parameterizable constraint.