The disclosure relates to electromagnetic navigation procedures, and more particularly to coil arrays for generating or receiving electromagnetic fields.
This section provides background information related to the present disclosure which is not necessarily prior art.
Electromagnetic-based navigation procedures include a surgeon using a navigation system to track a position of a surgical instrument in a three dimensional (3-D) space. In addition to the surgical instrument, the navigation system also includes a localizer and a processor. The localizer generates electromagnetic fields (or first signals), which are detected by the surgical instrument. The surgical instrument generates and/or outputs second signals in response to the first signals. The processor then determines a position of the surgical instrument based on the second signals.
The navigation system can assist in determining a location of a tracked device on a pointer probe and/or on a surgical instrument, such as a scalpel, a catheter, a suction device, or a deep brain stimulation probe. A pointer probe may be used to track a position of an instrument not having a tracking device. A tracked device may refer to the pointer probe, the surgical instrument or a device on the pointer probe or the surgical instrument. The position of the tracked device can be determined relative to a subject (e.g., a patient). The position of the tracked device can be illustrated on a display relative to the subject by superimposing an icon or image of the tracked device on an image of the subject.
Image data of the subject is often acquired for display prior to, during, and/or after a procedure on the subject. An image of the subject and the corresponding image data can be registered to the subject. The image data can define a first three-dimensional space (or image space). The subject can define a second three-dimensional space (or physical space) to which the image data is registered. Registration can be performed using multiple processes.
An electromagnetic (EM) navigation system can be used to acquire or determine navigation information, including tracked locations of various tracking devices and relative locations to registered image data. In an EM navigation system, EM fields are generated by a localizer and sensed by one or more tracking devices. The localizer can be positioned near or relative to the subject space. The tracking devices can be positioned on or in association with a surgical instrument. The EM fields can be affected by conductive or magnetic materials located in an area of the EM fields. Examples of conductive materials are metals, conductive polymers, and impregnated polymeric materials. An example of a magnetic material is soft ferromagnetic iron.
This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.
An electromagnetic device is provided and includes a jig and multiple wires. The jig includes a center member and coil-separating blocks. The coil-separating blocks protrude from the center member and are separated from each other to provide a coil channels. Each of the wires is wrapped on the jig, around the center member, and in one of the coil channels to form one of a multiple coils. Each of the coils is configured to connect to an electromagnetic navigation system and generate respective electromagnetic fields to be emitted relative to a subject.
In other features, another electromagnetic field device is provided and includes a jig and a wire. The jig includes a pair of end members and a center member. The center member is disposed between the pair of end members. The pair of end members and the center member together provide a coil channel. The coil channel includes dividers. The center member, the dividers, and the end member together provide wire channels. The wire is wrapped on the center member and in the wire channels to provide a coil. The coil is configured to connect to an electromagnetic navigation system and generate an electromagnetic field to be emitted relative to a subject.
In other features, a method is provided and includes forming a first jig to include a center member and coil-separating blocks. The coil-separating members protrude from the center member and provide coil channels. The coil channels are segregated by each other and include a first channel and a second channel. A first wire is wrapped on the first jig, around the center member, and in the first channel to form a first coil. A second wire is wrapped on the first jig, around the center member and the first coil, and in the second channel to form a second coil. The first wire and the second wire are configured to connect to an electromagnetic navigation system and generate respective electromagnetic fields to be emitted relative to a subject.
In other features, another method is provided and includes determining a number of jigs, including a first jig, to be included in a transmit coil array. The jigs are formed. Each of the jigs is formed to include a center member and a pair of end members. The center member is disposed between the pair of end members. The pair of end members and the center member together provide a coil channel. Wires are wrapped on the jigs. Each of the wires is wrapped on one of the center members and in one of the coil channels of a respective one of the jigs to provide a coil. The jigs are mounted on a base plate to form the transmit coil array. Each of the jigs is mounted in a respective location on the base plate. The coils are configured to connect to an electromagnetic navigation system and generate electromagnetic fields to be emitted relative to a subject.
Further areas of applicability will become apparent from the description provided herein. The description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.
Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.
Example embodiments will now be described more fully with reference to the accompanying drawings.
The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.
A localizer of an EM navigation system may include a transmit coil array (TCA). Although the localizers referred to and/or disclosed herein are primarily described as including TCAs (or coil arrays) for transmitting signals, the TCAs may be used for receiving signals. The TCA can include multiple sets of EM coils. Each set of the EM coils may include three orthogonally positioned coils that are used to generate EM fields. Other arrangements are disclosed below. The coil arrangements include singular coil arrangements and coil arrangements with coils that are not orthogonal to each other. Orthogonally positioned coils have respective center axes that are at right angles relative to each other. EM navigation is dependent on a precise and lengthy calibration process for calibrating the TCA. The calibration process can also cause a “bottleneck” in a manufacturing process of a navigation system.
The calibration process is primarily performed due to inconsistencies, irregularities, and varying differences in TCAs. This includes differences in coil placements, number of windings of each coil, lengths of coil wires, sizes of coils, spacing between coils, etc. The following disclosed implementations provide TCAs that can minimize calibration processes of TCAs and/or eliminate the need for calibrating TCAs. Examples of TCAs and corresponding manufacturing methods are shown in
Although the EM navigation system 20 is primarily described with respect to performing a procedure on a human patient, the EM navigation system 20 may be used to perform a procedure on other animate and/or inanimate subjects. Also, the implementations disclosed herein may be applied to other EM systems and for purposes other than for position tracking of devices. For example, the implementations may be used to generate EM fields in a transcranial magnetic stimulation system. Also, procedures disclosed herein can be performed relative to a volume, a mechanical device, and/or an enclosed structure. The volume may be of an animate or inanimate object. The subject can be an object that includes an enclosed mechanical device.
The EM navigation system 20 performs a guided procedure. The guided procedure can be, for example, a surgical procedure, a neural procedure, a spinal procedure, and an orthopedic procedure. The EM navigation system 20 allows a user, such as a surgeon 21, to view on a display 22 a position of an instrument 110 in a coordinate system. The coordinate system can be related to an image, such as in an image guided procedure, or can be related to an imageless procedure.
The EM navigation system 20 can operate as an image-based system or as an imageless system. While operating as an imageless system, the EM navigation system 20 can register the subject space to a graphical display representing an area of the subject 26, rather than to both the subject space and an image space. Image data of the subject 26 need not be acquired at any time, although image data can be acquired to confirm various locations of instruments or anatomical portions of the subject 26. Positions of the subject 26 can be tracked and positions of the instrument 110 relative to the subject 26 can be tracked.
While operating as an imageless system, a position of an anatomical structure can be determined relative to the instrument and the positions of the anatomical structure and the instrument can be tracked. For example, a plane of an acetabulum can be determined by touching several points with the instrument 110. As another example, a position of a femur can be determined in a similar manner. The position of the instrument 110 and the anatomical structure can be shown on a display with icons or graphics. The display, however, may not show actual image data captured of the subject 26. Other data can be provided, such as atlas data or morphed atlas data. The atlas data can be image data that is generated or generalized from the subject 26. For example, a brain atlas can be generated based on detail analysis of image data of a brain of a patient. Operation of the EM navigation system 20 as an image based system is further described below.
The EM navigation system 20 can be used to navigate or track rigid and flexible instruments. Examples of rigid instruments include drill motors, probes, awls, drill bits, large outer diameter (OD) needles, large or inflexible implants, etc. Examples of flexible instruments include catheters, probes, guide wires, small OD needles, small or flexible implants, deep brain stimulators, electrical leads, etc. The instrument 110 can be used in any region of a body of the subject 26. The EM navigation system 20 and instrument 110 can be used in various minimally invasive procedures, such as arthroscopic, percutaneous, stereotactic, or in an open procedure.
Although the EM navigation system 20 is described as acquiring image data using an imaging device 28, other data may be acquired and/or used, such as patient and non-patient specific data. The imaging device 28 acquires pre-, intra-, or post-operative image data and/or real-time image data of a subject 26. The imaging device 28 can be, for example, a fluoroscopic x-ray imaging device that may be configured as a C-arm having an x-ray source 30 and an x-ray receiving device 32. Other imaging devices may be included and mounted on the imaging device 28. Calibration and tracking targets and radiation sensors may be included. The imaging device 28 may be part of a fluoroscopic system, such as a bi-plane fluoroscopic system, a ceiling fluoroscopic system, a cath-lab fluoroscopic system, a fixed C-arm fluoroscopic system, an isocentric C-arm fluoroscopic system, a three dimensional fluoroscopic system, etc.
The EM navigation system 20 further includes an imaging device controller 34. The imaging device controller 34 controls the imaging device 28 to (i) capture x-ray images received at the x-ray receiving section 32, and (ii) store the x-ray images. The imaging device controller 34 may be separate from the imaging device 28 and/or control the rotation of the imaging device 28. For example, the imaging device 28 can move in the direction of arrow 28a or rotate about a longitudinal axis 26a of the subject 26. This allows anterior or lateral views of the subject 26 to be imaged. Each of these movements involves rotation about a mechanical axis of the imaging device 28 via a member 36.
X-rays can be emitted from the x-ray source 30 and received at the x-ray receiving section 32. The x-ray receiving section 32 can include a camera that can create the image data from the received x-rays. Other suitable imaging devices and/or systems may be used to create or capture image data. For example, a magnetic resonance imaging system or a positron emission tomography system may be used. Further, an imager tracking device 38 may be included to track a position of the x-ray receiving section 32 of the imaging device 28 at selected times by, for example, the C-arm controller 34. The image data can then be forwarded from the C-arm controller 34 to a processing module of a navigation computer 40 wirelessly or via a link 41. The navigation computer 40 can include a processing module that is configured to execute instructions to perform a procedure.
A work station 42 can include the navigation computer 40, the display 22, a user interface 44, and an accessible memory system 46. The image data may be transmitted from the C-arm controller 34 to the work station 42 or to a tracking system 50. The navigation computer 40 may be a portable computer, such as a laptop computer or a tablet computer.
The work station 42 displays the image data as an image on the display 22. The user interface 44 may be a keyboard, a mouse, a touch pen, a touch screen, or other suitable interface. The user interface 44 allows the user 21 to provide inputs to control the imaging device 28, via the C-arm controller 34, or adjust display settings of the display 22. The work station 42 can also be used to control and receive data from a coil array controller (CAC) 54 having a navigation device interface (NDI) 56.
While the imaging device 28 is shown in
Image data sets from hybrid modalities, such as positron emission tomography (PET) combined with CT, or single photon emission computer tomography (SPECT) combined with CT, can also provide functional image data superimposed onto anatomical data to be used to reach target sites within the subject 26. The imaging device 28, as shown in
The EM navigation system 20 further includes a tracking system 50. The tracking system 50 includes a localizer 52, which may also be referred to as a transmit coil array (TCA), a tracking array, or a transmit coil assembly. Examples of localizers and corresponding components are shown in
The DRF 58 can include a DRF member 58a and a removable tracking device 58b. Alternatively, the DRF 58 can include the tracking device 58b that is formed integrally with the DRF member 58a. For example, the tracking device 58b can be connected directly to the subject 26. The tracking device 58b is a coil sensor that performs as an emitter or a receiver to sense one or more EM fields, or other appropriate device that can be tracked by the tracking system 50. Also, the tracking device 58b can be wired to other controllers, processors, modules, etc. of the EM navigation system 20.
The localizer 52 may be or include any of the TCAs shown and/or described with respect to
The tracking device 100 can be associated with the instrument 110 at a location that is generally positioned within the subject 26 during a procedure. The DRF 58 can then transmit and/or provide signals based upon the received/sensed signals of the generated fields from the localizer 52 and/or other localizers.
The tracking system 50 or components of the tracking system 50 may be incorporated into other systems or devices in the operating theatre. For example, one of the localizers can be incorporated into the imaging device 28. The transmitter coil arrays 52a can be attached to the x-ray receiving section 32 of the imaging device 28. The localizer 52 may be positioned at any location within the operating theatre. For example, the localizer 52 may be positioned at the x-ray source 30. Also, the localizer 52 can be positioned: within or on top of an operating room table 120; below the subject 26; on side rails associated with the table 120; or on the subject 26 and in proximity to a region being navigated within.
Also, the coil arrays 52a can include multiple coils (e.g., induction coils) that are each operable to generate distinct EM fields into the region being navigated, such as a region within the subject 26 (sometimes referred to as patient space). The coil arrays 52a are controlled or driven by the CAC 54. The CAC 54 can transmit a signal via a transmission line 112 to the localizer 52. The coil arrays 52a can have more than one coil that is driven by the CAC 54. The signal may be time division multiplexed or frequency division multiplexed. In one implementation, each of the coil arrays 52a includes at least three orthogonal coils that generate three orthogonal EM fields. The coil arrays 52a can include any number of coils. The localizer 52 can include any number of coil arrays. The coils can be oriented in various different positions and may not be in a position orthogonal to other coils. In this regard, each coil of the coil arrays 52a may be driven separately, at distinct times, simultaneously, and/or with respective current signals having predetermined frequencies.
Upon driving the coils in the coil arrays 52a with the coil array controller (or control module) 54, EM fields are generated within the subject 26 in the area where the medical procedure is being performed. The EM fields can induce currents in the tracking devices 58b, 100. In response to the induced currents, the tracking devices 58b, 100 generate signals, which are provided to the NDI 56 and can be forwarded to the CAC 54 and/or the navigation computer 40. The NDI 56 may provide electrical isolation for the EM navigation system 20. The NDI 56 can include amplifiers, filters and buffers to directly interface with the tracking devices 58b, 100. Alternatively, the tracking devices 58b, 100 may communicate wirelessly or via wires with the NDI 56.
The tracking device 100 can be in a handle or inserter that interconnects with an attachment and may assist in placing an implant. The instrument 110 can include a graspable or manipulable element at a proximal end and a sensor that can be fixed near the manipulable element or at a distal working end. The tracking device 100 can include an EM sensor to sense the EM fields generated by the localizer 52 and induce a current in the tracking device 100. As illustrated in
The DRF 58 can be connected to the NDI 56 to forward the information to the CAC 54 and/or the navigation computer 40. The DRF 58 may include a magnetic and/or EM field detector (e.g., the tracking device 58b). The DRF 58 may be fixed to the subject 26 and adjacent to the region where navigation is occurring such that any movement of the subject 26 is detected as relative motion between the localizer 52 and the DRF 58. The DRF 58 can be interconnected with the subject 26. Any relative motion is indicated to the CAC 54, which updates registration correlation and maintains accurate navigation. The DRF 58 may include a selected number of coils. For example, the coils may be mutually orthogonal with each other and share a center axis around which the coils are wound. The coils may be configured in various non-coaxial or co-axial coil configurations.
The DRF 58 may be affixed externally to the subject 26 and/or adjacent to a region of navigation (e.g., affixed on a skull of the subject 26, to a bone of the subject 26, or to skin of the subject 26). The DRF 58 may be affixed using an adhesive patch and/or a tensioning system. The DRF 58 may also be removably attachable to a fiducial marker. Fiducial markers can be anatomical landmarks and/or artificial members attached or positioned on the subject 26.
In operation, the EM navigation system 20 creates a map between points in image data or an image space and corresponding points in a subject space (e.g., points in an anatomy of a patient or in a patient space). After the map is created, the image space and subject space are registered to each other. This includes correlating position (location and orientations) in an image space with corresponding positions in a subject space (or real space). Based on the registration, the EM navigation system 20 may illustrate a position of the instrument 110 relative to an image of the subject 26 in a super-imposed image. For example, the instrument 110 can be illustrated relative to a proposed trajectory and/or a determined anatomical target. The work station 42 alone and/or in combination with the CAC 54 and/or the C-arm controller (or control module) 34 can: identify the corresponding point on the pre-acquired image or atlas model relative to the tracked instrument 110; and display the position on display 22 and relative to an image 134. This identification is known as navigation or localization. An icon representing a localized point or an instrument is shown on the display 22 within two-dimensional image planes, as well as on three and four dimensional images and models. The work station 42, the CAC 54, and the C-arm controller 34 and/or selected portions thereof can be incorporated into a single system or implemented as a single processor or control module.
To register the subject 26 to the image 134, the user 21 may use point registration by selecting and storing particular points from the pre-acquired images and then touching the corresponding points on the subject 26 with a pointer probe or any appropriate tracked device. The EM navigation system 20 analyzes the relationship between the two sets of points that are selected and computes a match, which allows for a correlation of every point in the image data or image space with its corresponding point on the subject 26 or the subject space.
The points that are selected to perform registration or form a map are the fiducial markers, such as anatomical or artificial landmarks. Again, the fiducial markers are identifiable on the images and identifiable and accessible on the subject 26. The fiducial markers can be artificial landmarks that are positioned on the subject 26 or anatomical landmarks that can be easily identified in the image data. The artificial fiducial markers can also form part of the DRF 58. Any appropriate number of the fiducial markers can be provided with and/or separate from the DRF 58.
The EM navigation system 20 may also perform registration using anatomic surface information or path information (referred to as auto-registration). The EM navigation system 20 may also perform 2D to 3D registration by utilizing the acquired 2D images to register 3D volume images by use of contour algorithms, point algorithms or density comparison algorithms.
In order to maintain registration accuracy, the EM navigation system 20 tracks the position of the subject 26 during registration and navigation with the DRF 58. This is because the subject 26, DRF 58, and localizer 52 may all move during the procedure. Alternatively the subject 26 may be held immobile once the registration has occurred, such as with a head holder. Therefore, if the EM navigation system 20 does not track the position of the subject 26 or an area of an anatomy of the subject 26, any subject movement after registration would result in inaccurate navigation within the corresponding image. The DRF 58 allows the tracking system 50 to track the anatomy and can be used during registration. Because the DRF 58 is rigidly fixed to the subject 26, any movement of the anatomy or the localizer 52 is detected as the relative motion between the localizer 52 and the DRF 58. This relative motion is communicated to the CAC 54 and/or the processor 48, via the NDI 56, which updates the registration correlation to thereby maintain accurate navigation.
The DRF 58 can be affixed to any portion of the subject 26, and can be used to register the subject 26 to the image data, as discussed above. For example, when a procedure is being performed relative to a skull or cranium 26s, the DRF 58 can be interconnected with the cranium 26s.
The tracking system 50 can position the localizer 52 adjacent to the patient space to generate an EM field (referred to as a navigation field). Because points in the navigation field or patient space is associated with a unique field strength and direction, the tracking system 50 can determine the position (which can include location and orientation) of the instrument 110 by measuring the field strength and direction or components of the EM field at the tracking device 100. The DRF 58 is fixed to the subject 26 to identify the location of the subject 26 in the navigation field. The tracking system 50 continuously determines the relative position of the DRF 58 and the instrument 110 during localization and relates this spatial information to subject registration data. This enables image guidance of the instrument 110 within and/or relative to the subject 26.
To obtain a maximum accuracy it can be selected to fix the DRF 58 in each of at least 6 degrees of freedom. Thus, the DRF 58 or any tracking device, such as the tracking device 100, can be fixed relative to axial motion X, translational motion Y, rotational motion Z, yaw, pitch, and roll relative to a portion of the subject 26 to which the tracking device 58b is attached. Any appropriate coordinate system can be used to describe the various degrees of freedom. Fixing the DRF 58 relative to the subject 26 in this manner can assist in maintaining maximum accuracy of the EM navigation system 20.
The instrument 110 can be any appropriate instrument (e.g., a catheter, a probe, a guide, etc.) and can be used for various mechanisms and methods, such as delivering a material to a selected portion of the subject 26, such as within the cranium 26s. The material can be any appropriate material such as a bioactive material, a pharmacological material, a contrast agent, or any appropriate material. As discussed further herein, the instrument 110 can be precisely positioned (including location and orientation) via the EM navigation system 20 and otherwise used to achieve a protocol for positioning the material relative to the subject 26 in any appropriate manner, such as within the cranium 26s. The instrument 110 may also include a brain probe to perform deep brain stimulation.
As discussed above, an EM field can be generated by the localizer 52. The EM field is generated to define a navigation field. The navigation field can, however, be distorted by various distorting objects including the operating table 120, the imaging device 28, various instruments, etc.
In
In the example shown, the jig 170 includes a center member 178 and eight coil-separating blocks 180. The term “block” as used herein may refer to an object having a predetermined shape. Although the coil-separating blocks 180 are shown as having a generally cubular shaped geometry, the coil-separating blocks 180 may have various shaped geometries. The coil-separating blocks 180 protrude away from the center member 178 and form wire wrapping (or coil) channels 182, 184, 186. The coil channels 182, 184, 186 may be externally accessible for wrapping of respective wires to form the coils 172, 174, 176. A single coil channel is provided for each of the coils 172, 174, 176. Each of the coils 172, 174, 176 is wound around the center member 178 and/or a common center point 190 of the jig 170 and in a respective one of the coil channels 182, 184, 186. Each of the coils 172, 174, 176 may have a predetermined number of windings. In one implementation, each of the coils 172, 174, 176 has the same number of windings. In another implementation, the coils 172, 174, 176 have different numbers of windings. Coils on a jig may have the same or a different number of windings than corresponding coils on another jig. The diameter of each of the coil channels 182, 184, 186 of the jig 170 is different and is predetermined such that each of the coils 172, 174, 176 are wrapped on the jig 170 without contacting other ones of the coils 172, 174, 176.
Sides of the jig 170 may include, for example, tabs and/or holes 192, as shown. The tabs and/or holes 192 may be located in the coil-separating blocks 180 and accessible from external surfaces of the coil-separating blocks 180. The coil-separating blocks 180 may each have any number of external surfaces at various angles and/or positions relative to the center member 178 and the center point 190. The tabs and/or holes 192 may be used to attach the jig 170 to corresponding mounting (or end) plates, as shown in
Ends 194 of the wires on the jig 170 may be received into corresponding connectors. Example connectors are shown in
Each of the coil channels 202, 204, 206 has a set of dividers (respective ones of the dividers 212) and a set of wire channels (respective ones of the wire channels 214). Each of the sets of dividers may have a respective diameter. Each of the sets of wire channels may have a respective inner diameter and outer diameter, where the outer diameter matches the diameter of the corresponding dividers.
The dividers 212 extend radially outward from the center member 208 and are segregated by the coil channels 202, 204, 206 such that the dividers 212 are non-contiguous annularly and/or toroidally-shaped discs. The dividers 212 and wire channels 214 can provide stacked layers of alternating coil windings and dividers. The elements of the jig 200 including the protruding coil-separating blocks 210, the center member 208 and the dividers 212 may be separate elements or may be implemented as a unitary structure, as shown. Although the jig 200 is shown as being generally cube-shaped, the jig 200 may have a different shape.
Each of the wire channels 214 is configured to receive a wire of a coil. A wire may be wrapped one or more times around the center member 208 and in each of the wire channels 214. In this implementation, the dividers 212 separate each winding of a coil or sets of windings of a coil for precise wrapping of the wire of the coil on the jig 200. Each set may have the same number of windings or may have a respective number of windings. This provides accurate, predictive, consistent placement of each winding of the coil.
The jigs of
Although the three jigs 222 shown have the same orientation on the base plate 224, the jigs of the TCA 220 may have different orientations. An example of jigs having different orientations is shown in
Although the jigs of
The jig 260 may have a crossover section 280 between the end members 266 and separating each of the dividers 268, such that the dividers 268 are non-contiguous annularly and/or toroidally-shaped discs. The wire, when wrapped on the jig 260, may be wrapped around the center member 272, around a center axis 282, in the wire channels 270 and in a first direction parallel (indicated by arrow 284) to the center axis 282. The wire may then be wrapped in a second direction (indicated by arrow 286) opposite the first direction. To facilitate wrapping in the first direction and second direction the wire may switch between wire channels in the crossover section 280. First portions 288 of the wire extend through the crossover section 280 while wrapping the wire in the first direction. Second portions 290 of the wire extend through the crossover section 280 while wrapping the wire in the second direction. The second portions 290 may crossover the first portions 288 in the crossover section 280. Portions of the EM field generated by the portions 288, 290 of the coil in the crossover section 280 may cancel each other.
The crossover section 280 may be wedge-shaped with a narrow end 292 extending through one of the end members 266. This allows ends 276 of the wire to (i) extend through the end member and, for example, a base plate, and (ii) be received by the connector 278. The crossover section 280 allows for accurate positioning of crossover locations. Crossover locations refer to locations in the crossover section 280 in which the wire transitions between two of the wire channels 270.
Although not shown, one or more of the wires of the coils on the jigs of
The orienting blocks 312, 314 have jig mounting surfaces 322. Directional placement of the orienting blocks 312, 314 and angles of the jig mounting surfaces 322 relative to the base plate 310 may be predetermined to set the orientation of the jigs 302, 304 and corresponding coils 306, 308. End members 324 of the jigs 302, 304 may be at the same angles relative to the base plate 310 as the corresponding jig mounting surfaces 322. This allows coils to not be wrapped around the same center member of the same jig and be placed in various positions and/or orientations relative to each other. As an example, the coils 306, 308 may be orthogonally positioned relative to each other and/or be used to generate orthogonal EM fields. Any number of jigs and coils may be included in the TCA. The jigs 302, 304 and coils 306, 308 may have the same or different orientations. In one implementation, more than two jigs and coils have the same orientation and more than two jigs and coils have different orientations.
In one implementation, twelve jigs and corresponding coils are included. The twelve jigs and twelve coils include three sets. Each of the sets includes four jigs and four coils. The jigs and coils of a single set are orientated in the same direction (e.g., have center axes that are in parallel with each other). A center axis being an axis around which a coil is wrapped. The jigs and coils of different sets are oriented differently (e.g., have center axes that are not in parallel with each other).
Each of the jigs and corresponding coils of
The jigs, end plates, and base plates of
The control module 354 may control operations in the production printer 356, supply area 358 and/or production system 360 and/or may be in communication with modules in the production printer 356, supply area 358 and/or production system 360. The production printer 356, supply area 358 and/or production system 360 may have respective control modules or may share a single control module, as shown.
The production printer 356 may be, for example, a stereolithography printer or other type of production printer or production machine. The production printer 356 may include, for example, a resin bath 362 in which plates, jigs and/or orienting blocks may be formed via a laser 364 and scanner system 366. The plates, jigs and/or orienting blocks may be stored in the supply area 358.
The supply area may store plates 370, jigs 372, orienting blocks 374 and wires 376 and include motors, grippers, and/or other machinery to move the plates 370, jigs 372, orienting blocks 374 and/or wires 376 from the production printer 356 to the supply area 358 or from the supply area 358 to the production system 360. The wires 376 may be pre-cut to predetermined lengths or may be cut as used in the production system 360.
The production system 360 may include a wire wrapping station 380 and a TCA assembly station 382 and corresponding grippers and/or motors to move, wire wrap and connect the jigs 372 to the plates 370. The jigs 372 may be wrapped in the wire wrapping station 380 and mounted between end plates, on a base plate and/or in housing in the TCA assembly station 382. The production system 360 may include wire cutters for cutting wires to predetermined lengths.
At 402, coil characteristics are determined. The coil characteristics may include, for example, lengths of wires, number of windings per coil, number of windings per wire channel, etc.
At 404, a number of jigs to be included in a TCA and corresponding dimensions of the jigs are determined. This may be based on the coil characteristics, a number of jigs per EM field to be generated, a number of EM fields to be generated, a maximum current level or current ranges of corresponding coils, and characteristics of EM fields to be generated.
At 406, the jigs (e.g., the jigs of
At 408, a first wire is wrapped on one of the jigs (referred to in the below tasks 410, 412 as “the jig”), in a first coil channel, and around a center member and a center point of the jig to form a first coil. The first wire is wrapped according to corresponding and predetermined coil characteristics.
At 410, a second wire is wrapped on the jig, in a second coil channel, and around (i) the center member, (ii) the center point, and (iii) the first coil. The second wire may be wrapped, such that the second coil is at a predetermined position relative to the first coil. The second wire is wrapped according to corresponding and predetermined coil characteristics.
At 412, a third wire is wrapped on the jig, in a third coil channel, and around (i) the center member, (ii) the center point, (iii) the first coil, and (iv) the second coil. The third wire may be wrapped, such that the third coil is at a predetermined position relative to the first coil and the second coil. The third wire is wrapped according to corresponding and predetermined coil characteristics.
Although the above tasks include three wire wrapping tasks, any number of wire wrapping tasks may be included.
At 414, the control module determines whether there is another jig to be wrapped. If there is another jig to be wrapped, task 408 is performed, otherwise task 416 is performed.
At 415, the end plates are formed. At 416, the one or more jigs may be installed between end plates (e.g., the end plates) and/or mounted within a housing to form the TCA. The jigs may be press-fitted, adhesively attached and/or connected to the end plates.
At 418, the TCA may be installed in an EM navigation system (e.g., the EM navigation system 20). At 420, the TCA may be calibrated via the navigation computer 40 or other controller, processor and/or control module of the EM navigation system. In one implementation, task 420 is not performed. The TCA is then used in a procedure with having been calibrated. The EM navigation system may perform the procedure based on predetermined characteristics of the TCA, components of the TCA (coils, jigs, plates, etc.), and EM field characteristics (e.g., electric and magnetic field vector values). The characteristics of the TCA may include any of the TCA characteristics disclosed herein including dimensions and characteristics of the components in the TCA. The method may end at 422.
At 452, coil characteristics are determined. The coil characteristics may include, for example, lengths of wires, number of windings per coil, number of windings per wire channel, etc.
At 454, a number of jigs to be included in a TCA and corresponding dimensions of the jigs are determined. This may be based on the coil characteristics, a number of jigs per EM field to be generated, a number of EM fields to be generated, a maximum current level or current ranges of corresponding coils, and characteristics of EM fields to be generated.
At 456, the jigs (e.g., the jigs of
At 458, wrapping respective wires on each of the jigs formed at 454. The wires may be wrapped in respective coil channels and/or wire channels of the jigs. Each of the wires is wrapped according to corresponding and predetermined coil characteristics.
At 460, a base plate and/or orienting blocks are formed. The orienting blocks may be formed at 460 as part of the base plate or may be formed at 454 as part of the jigs. The orienting blocks are formed with jig mounting surfaces at predetermined angles.
At 462, the orienting blocks may be mounted on the base plate at predetermined positions. At 464, the jigs may be mounted on the orienting blocks and/or mounted within a housing to form the TCA. The jigs are mounted on the orienting blocks in predetermined positions and to place the jigs and wires in predetermined orientations relative to the base plate.
At 466, the TCA may be installed in an EM navigation system (e.g., the EM navigation system 20). At 468, the TCA may be calibrated via the navigation computer 40 or other controller, processor and/or control module of the EM navigation system. In one implementation task 468 is not performed. The EM navigation system may perform the procedure based on predetermined characteristics of the TCA, components of the TCA (coils, jigs, plates, orienting blocks, etc.), and EM field characteristics (e.g., electric and magnetic field vector values). The characteristics of the TCA may include any of the TCA characteristics disclosed herein including dimensions and characteristics of the components in the TCA. The method may end at 470.
The above-described tasks of
The above-described implementations, allow for coils to be wound on jigs in a consistent and repeatable manner. This allows for a reduction in calibration time of TCAs and/or elimination of a calibration process due to the predictable physical and operating characteristics of the TCAs.
The wireless communications described in the present disclosure can be conducted in full or partial compliance with IEEE standard 802.11-2012, IEEE standard 802.16-2009, IEEE standard 802.20-2008, and/or Bluetooth Core Specification v4.0. In various implementations, Bluetooth Core Specification v4.0 may be modified by one or more of Bluetooth Core Specification Addendums 2, 3, or 4. In various implementations, IEEE 802.11-2012 may be supplemented by draft IEEE standard 802.11ac, draft IEEE standard 802.11ad, and/or draft IEEE standard 802.11ah.
It should be understood that one or more steps within a method may be executed in different order (or concurrently) without altering the principles of the present disclosure.
In this application, including the definitions below, the term module may be replaced with the term circuit. The term module may refer to, be part of, or include an Application Specific Integrated Circuit (ASIC); a digital, analog, or mixed analog/digital discrete circuit; a digital, analog, or mixed analog/digital integrated circuit; a combinational logic circuit; a field programmable gate array (FPGA); a processor (shared, dedicated, or group) that executes code; memory (shared, dedicated, or group) that stores code executed by a processor; other suitable hardware components that provide the described functionality; or a combination of some or all of the above, such as in a system-on-chip.
The term code, as used above, may include software, firmware, and/or microcode, and may refer to programs, routines, functions, classes, and/or objects. The term shared processor encompasses a single processor that executes some or all code from multiple modules. The term group processor encompasses a processor that, in combination with additional processors, executes some or all code from one or more modules. The term shared memory encompasses a single memory that stores some or all code from multiple modules. The term group memory encompasses a memory that, in combination with additional memories, stores some or all code from one or more modules. The term memory may be a subset of the term computer-readable medium. The term computer-readable medium does not encompass transitory electrical and electromagnetic signals propagating through a medium, and may therefore be considered tangible and non-transitory. Non-limiting examples of a non-transitory tangible computer readable medium include nonvolatile memory, volatile memory, magnetic storage, and optical storage.
The apparatuses and methods described in this application may be partially or fully implemented by one or more computer programs executed by one or more processors. The computer programs include processor-executable instructions that are stored on at least one non-transitory tangible computer readable medium. The computer programs may also include and/or rely on stored data.
Example embodiments are provided so that this disclosure will be thorough, and will fully convey the scope to those who are skilled in the art. Numerous specific details are set forth such as examples of specific components, devices, and methods, to provide a thorough understanding of embodiments of the present disclosure. It will be apparent to those skilled in the art that specific details need not be employed, that example embodiments may be embodied in many different forms and that neither should be construed to limit the scope of the disclosure. In some example embodiments, well-known processes, well-known device structures, and well-known technologies are not described in detail.
The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting. As used herein, the singular forms “a,” “an,” and “the” may be intended to include the plural forms as well, unless the context clearly indicates otherwise.
Terms such as “first,” “second,” and other numerical terms when used herein do not imply a sequence or order unless clearly indicated by the context. Thus, a first element, component, region, layer or section discussed herein could be termed a second element, component, region, layer or section without departing from the teachings of the example embodiments.
The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are not to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure.
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