Patent Publication Number: US-2022217958-A1

Title: Fishing lure

Description:
RELATED APPLICATIONS 
     This application is a continuation-in-part application of U.S. patent application Ser. No. 16/334,958, which claims priority to PCT/AU2016/051057, the contents of which is hereby incorporated by reference. 
    
    
     TECHNICAL FIELD 
     This disclosure generally relates to a fishing lure. The lure finds particular application in sport and game fishing, but is in no way limited to this application. 
     BACKGROUND ART 
     Fishing lures are deployed at various depths to catch a variety of fish. Trolling, where a lure is deployed behind a boat and pulled through the water at a given speed, is often used, particularly to catch larger fish. Larger lures are used to catch larger fish, and larger fish are generally present at deeper water depths. Larger lures are also generally trolled at higher speeds compared to smaller lures. 
     The line used to connect the lure to the boat, usually fishing line, is attached generally towards a front portion of the lure at an attachment point. If the attachment point is not correctly aligned with the lure, then the lure may not track correctly through the water when being trolled. For example, in use, the lure may tend to drift to the left or right and then often returns to the surface and fails to swim naturally. 
     Incorrect tracking also tends to be magnified as the in-use depth of the lure increases when the trolling speed increases. For this reason, trolling is generally limited to speeds of below 8 knots. In addition, the maximum obtainable depth of a lure, in use, is at speeds of around 6-8 knots since speeds greater than 8 knots tend to increase the water resistance on the line causing the lure to swim shallower than intended, and also to not swim straight. 
     If a lure is deployed and it begins to track incorrectly, it is removed from the water and adjusted so that it tracks correctly. In some cases, it can take a few attempts of adjusting the attachment point to ensure that the lure tracks correctly, especially for larger lures. For some lures, it is not possible to adjust the attachment point, and this can render the lure useless. Further, the attachment point tends to be knocked out of alignment after a fish has been caught, meaning that the lure can require readjustment after every catch. In addition, manufacturing tolerances mean that most lures may even require adjustment before they can be used for the first time. Having to adjust a lure so as to provide correct tracking can decrease the lure lifetime, and increase lure setup time. Some anglers are also not skilled enough to properly adjust the lure to provide correct tracking. 
     It is to be understood that references herein to the prior art do not constitute an admission that such art forms a part of the common general knowledge of a person of ordinary skill in the art, in Australia or any other country. 
     SUMMARY OF THE DISCLOSURE 
     Disclosed herein is a fishing lure. The fishing lure as disclosed herein finds particular application in sport and game fishing, but is in no way limited to this application. In this regard, the lure can be readily resized for more general use in recreational (e.g., small fish) fishing, etc. 
     The fishing lure as disclosed herein comprises a body having a front end and a rear end. A cavity located towards the front end of the body. The term “towards” as used in relation to the location of the cavity should be interpreted broadly to mean located at the front end of the body, or located at an inset (set back) location from the body front end. The cavity extends in a longitudinal direction of the body. A connection member is located in the cavity at least partially in the cavity and retained therein by one or more retaining members, each retaining member able to extend into the cavity to retain the connection member in the cavity in use. The connection member is able to move, in use, in a direction transverse to the longitudinal direction. The term “substantially perpendicular” as used in relation to the direction of movement should be interpreted broadly to mean movement in a general perpendicular direction, such as in a direction in the range of about 60° to 120° relative to the longitudinal direction. 
     The transverse movement of the connection member in cavity may enable the lure to self-centre in use. In this regard, the connection member can move into a position that balances the relative forces applied to the lure such that it can track correctly. This may reduce lure setup time, since a tow point associated with the connection member may only need to be in approximately the correct position prior to use, whereby the remaining adjustment is performed by the lure itself in use. The need to adjust the tow point after each catch may also be eliminated. Further, allowing the lure to self-centre can allow the lure to be trolled at speeds greater than 10 knots, such as up to 14 knots, and potentially even faster speeds such as 15 knots or greater. 
     In an embodiment, the connection member movement in the transverse direction may comprise one or more of:
         a pivot/rotation laterally in the cavity in use;   a movement generally up and down with respect to a base of the cavity in use;   a laterally tilting movement from side to side within the cavity in use.       

     Each such movement may occur at the same time, thereby defining a vector of movement, which movement may again be generally transverse to the longitudinal direction. 
     For example, when the connection member is in the form of a plate, the plate may define a plane that, in use, extends generally vertically. The plate may be retained within the cavity such that the lateral pivot/rotation occurs at opposite ends of the connection member (e.g., one plate end pivots to one side of the cavity, and an opposite plate end pivots to the other side of the cavity, and vice versa). The plate may also be retained within the cavity such that the movement generally up and down with respect to the cavity base is a tilting up or rocking of the plate at one end, and a tilting or rocking down of the plate at the opposite end (and vice versa). The plate may further be retained within the cavity such that the tilting movement from side to side with respect to the cavity is a lateral tilting of the plate at an upper plate side, and an opposite lateral tilting of the plate at a lower plate side (and vice versa). 
     Thus, the configuration and retention of the connection member with respect to the lure can be such as to provide it with at least three degrees of freedom of movement with respect to the lure longitudinal direction (e.g., lure axis). 
     In each case, the pivoting/rotation back and forth and/or the tilting up and down, can generally be in a direction that is substantially perpendicular to the longitudinal direction. 
     An arm may be located in the cavity. The arm may be associated with the connection member such that, in use, the arm does not touch and/or transfer a force to the connection member. Preventing the arm from touching and/or transferring a force to the connection member may help the lure to self-centre in use. In some circumstances the retaining members may fail. In these circumstances, the connection member can then engage with the arm so that the connection member and the body do not separate from one another. This may be useful, for example, when the one or more retaining members fail when a size of a fish striking the lure is greater than the intended use of the lure. The arm may pass through a proximal aperture located in the connection member. A portion of the arm passing through the proximal aperture may define a loop. The proximal aperture may have an effective diameter about twice a diameter of the arm. This arrangement may help to prevent the arm from engaging the connection member in use, such as transferring a load from the connection member to the retaining member(s) during normal use of the lure. Minimising any contact and/or load transfer from the connection member to the arm in use may help to improve the self-centring ability of the lure. 
     The arm may extend from the cavity into the body. In another such embodiment, the arm may follow a labyrinthine path, extending through a series of passageways defined in the body, and optionally right through to the rear end of the body. When the arm extends through to the rear end of the body, the arm may be folded back onto itself to define an eyelet at the body rear end. 
     The body may also comprise one or more hook attachment points. The labyrinthine path of the arm through the body may be such as to define the one or more hook attachment points that e.g., each project from the body. Alternatively, the one or more hook attachment points may be separate from (i.e., separately defined to) the arm. The one or more hook attachment points may be separate from one another. Alternatively, each of the hook attachment points may be integral with one another. 
     In an embodiment, the one or more retaining members may pass through respective a respective aperture of the connection member. The respective aperture may have a diameter about 1.1 to 2.0 times greater than a diameter of the one or more retaining members. For example, the one or more retaining members may have a diameter of about 1.8 mm and the respective aperture may have a diameter of about 2.0 to 2.4 mm. In some embodiments, the connection member may be retained in the cavity with two retaining members. The retaining members may be pins. The pins may have a diameter of about 1.0 mm to 2.0 mm. In some embodiments, the pins may extend across the cavity in a direction substantially transverse to the longitudinal direction. The one or more retaining members may extend across an entire width of the cavity. For example, one or more of the one or more retaining members may engage both sides of the cavity, Alternatively, the one or more retaining members may extend across only a portion of the cavity so the one or more retaining members only engage with one sidewall of the cavity. The one or more retaining members may be stainless steel wire. The one or more retaining members may be a wear-resistant material. A ratio of a diameter of the one or more retaining members to the respective aperture in the connection member may range from about 1:1.45 to 1:1.65. Having ratios outside this range means that the ability of the lure to self-centre in use may be diminished, and the lure may start to track from side-to-side. This may mean that the lure may tend to blow out of the water. 
     In some embodiments the connection member may have a thickness about 50-80% of a width of the cavity. In some embodiments, the connection member may have a thickness that is about 66% of the width of the cavity. For example, the connection member may have a thickness of about 1.0 mm to 2.0 mm, such as 1.0 mm, 1.2 mm, 1.5 mm and 1.8 mm, and the cavity may have a width of about 1.5 mm to 2.0 mm, such as about 1.5 mm, 1.8 mm, 2.2 mm and 2.9 mm. In some embodiments, the cavity may be defined by sidewalls. The sidewalls may each have an upper portion and a lower portion. The upper portions of the sidewalls may have lips extending towards one another such that a width of the cavity between the lips is less than a width of the cavity between the lower portion. The lips may help to strength the cavity. In some embodiments, the width between the lower portion may be about 1.1 to 2.0 times greater than the width between the lips. For example, a width between the lips may be about 2.2 mm and a width between the lower portion may be about 3.5 mm. The lips may have a thickness of about 1.0 mm to 2.0 mm, such as 1.2 mm. In use the connection member may pivot about the one or more retaining members. The one or more retaining members may be spaced along the longitudinal direction. In some embodiment, the cavity may have no lips at the upper portion of the sidewall. In these embodiments, the sidewall may be straight walls. 
     A front end of the body may be configured to define a bib. The cavity may be defined to open out onto an in-use upper face of the bib (e.g., at a location that is set back from a distal front end of the bib). The size and shape of the cavity may be designed in accordance with the design and shape of the bib. A remainder of the body extending rearwardly from the bib may be configured to have a profile similar to that of a fish body. 
     The body may comprise an interior, a weighted portion, and a skin covering the interior and weighted portion. The interior may comprise foam. The interior may be hollow. The interior may have ribs arranged perpendicular to one another. The weighted portion may be provided by lead weights. The body may have one or more weighted portions. The weighted portions may be positioned proximate the one or more hook attachment points. The skin may have additional features, such as artificial fins or soft flexible regions, so as to attract fish. The skin may form the covering that defines the interior. The body may be painted to resemble a fish. Reflective surfaces may be applied to the skin so as to attract fish. The skin may be toughened to resist e.g., teeth from fish. The skin may be formed of ABS plastic. 
     In an embodiment, the connection member may have an eyelet for connection to a fishing line. The eyelet may be located towards a distal end of the connection member. The eyelet may be in the form of an aperture passing through the connection member. A ring may be fitted to the eyelet. Fishing line may be attached to the eyelet and/or ring. 
     The lure may be adapted to be trolled at a water speed of up to 15 knots. Generally, the larger the lure, the higher the troll speeds. For example, a lure with a length of approximately 200 mm may be trolled at a speed of 15 knots, whereas a lure with a length of approximately 165 mm may be trolled at a speed of 13 knots. Larger lures tend to attract larger fish which move at higher speeds. To attract and catch these larger fish, the lure tends to be deployed at deeper depths, such as &gt;12 m, compared to smaller lures. The lure may have a body size ranging from approximately 40-250 mm, such as 85 mm, 100 mm, 120 mm, 140 mm, 165 mm, 200 mm or 250 mm. 
     Also disclosed is a fishing lure, comprising a body; and a connection member for attaching the body to line. The connection member is connected to the body by at least two connectors in a manner such that the connection member is moveable, in use, relative to the body. 
     In some embodiments the connection member may be moveable in a transverse direction relative to a longitudinal direction of the body. In some embodiments, the connection member may be moveable relative to the at least two connectors. This fishing lure may be otherwise as set forth above. 
     The disclosure also provides a fishing lure having a body having a front end and a rear end. A cavity may be disposed towards the front end of the body. The term “towards” as used in relation to the location of the cavity should be interpreted broadly to mean located at the front end of the body, or located at an inset (set back) location from the body front end. The fishing lure as disclosed herein may also comprise an arm extending in the cavity. The arm may have a first end rigidly affixed to the body at one end of the cavity and a second end having a tow point for attachment to a fishing line. When the lure is not in use (e.g., rest position) the arm may be aligned with a stationary longitudinal axis. This stationary longitudinal axis may extend centrally through the cavity. However, in use, the arm may be adapted to flex about the first end such that the second end of the arm can move laterally away from the stationary longitudinal axis, with arm movement in the cavity being possible in a multitude of directions. 
     The fishing lure as disclosed herein may further comprise an abutment portion extending into the cavity. The abutment portion may be arranged to locate at the arm when the arm is aligned with the stationary longitudinal axis. In use, when the arm moves away from the stationary longitudinal axis, the abutment portion may be able to act as a pivot point. For example, when the arm flexes in a direction that is generally towards the abutment portion, a distal part of the arm can pivot around the abutment portion. 
     The abutment portion may extend into the cavity from an in-use upper side thereof. Thus, when the arm flexes generally upwards in use, it can pivot around the abutment portion. However, the arm may flex laterally and down without pivoting around the abutment portion. The abutment portion may be positioned to locate at the arm at a distance that is approximately 40-50%, optionally 47%, of the arm length taken from the first end. Adjusting the position of the abutment portion can be used to alter the diving and tracking characteristics of the lure. 
     The tow point of the arm second end may be defined as an eyelet. The eyelet may be formed by folding the arm back onto itself at a distal part of the arm. The folded back part of the arm may be fastened to that part of the arm that extends between the first and second ends. This fastening may be provided by welding at one or more points, such as spot welding. This fastening may alternatively be provided by adhesive, or by a lashing (such as fine metal wire or yarn) around the folded back distal part of the arm. The tow point may alternatively be provided by a ring secured to the second end of the arm. The ring may be attached by welding and/or adhesive. 
     The cavity may be elongate. The stationary longitudinal axis may generally correspond to an elongate, central (i.e., longitudinal) axis of the cavity. The stiffness of the arm and the size of the cavity may be such as to allow the arm to move (flex) in the multitude of directions in the cavity in use, without the arm touching a wall of the cavity. For example, at a distal portion of the arm beyond the abutment portion, the multitude of directions may be any direction in an x/y plane perpendicular to the stationary longitudinal axis. The arm stiffness and cavity dimensions, such as width and breadth, may be adjusted to adjust the characteristics of the lure. Lures for smaller fish may have different arm and cavity properties compared to lures for larger fish. For example, lures for larger fish tend to have a stiffer arm to compensate for the larger forces experienced in use, e.g., during trolling at high speeds, during a fish strike, etc. 
     The cavity can be any shape or size that allows the arm to appropriately flex. For example, the cavity may have a generally square or rectangular cross-sectional profile. The cavity may alternatively have a circular, elliptical, etc. cross-section that allows a combination of movement of the arm. The square or rectangular profile may be provided with a breadth and height that is approximately three times or greater than a thickness/diameter of the arm, although for some applications the breadth and height may be less than three times the thickness/diameter of the arm. The arm may be provided by a metal wire. The wire may be steel, such as stainless steel. The steel wire may have a diameter of approximately 0.3-4 mm, such as 0.6 mm, 1.0 mm, 1.8 mm or 2 mm. 
     The abutment portion may be provided by a pin, optionally of metal. The metal pin may have a diameter in the range of 2-3 mm, such as approximately 2.5 mm. The pin may have a length of up to 18 mm. The abutment portion may be provided by a wear-resistant material, such as surface treated metal, hardened/toughened plastics, etc. A combination of a metal pin and wear-resistant material can be used as the abutment portion. The pin may be arranged to extend laterally of the body, and transversely with respect to the cavity at a side (e.g., upper side) thereof. This arrangement can help to distribute loads applied to the pin in use into the body. In a variation, the abutment portion may be formed integrally with the body, and may be provided by a region in the body having increased wear resistance. 
     The arm may extend beyond its first end into the body. In one such embodiment, the arm may terminate a short distance into the body but sufficiently to enable the rigid affixing at the arm first end. 
     Also disclosed herein is a fishing lure, comprising: a body having a front end and a rear end; an elongate cavity towards the front end of the body; and an arm rigidly affixed to the body and extending through the cavity to terminate at a tow point for attachment to a fishing line. The cavity surrounds the arm to be spaced therefrom. 
     The lure may further comprise an abutment portion extending into the cavity. When the lure is not in use the abutment portion may be arranged to locate at the arm when the arm is aligned with a stationary longitudinal axis. In use, when the arm is caused to move away from the stationary longitudinal axis, the abutment portion may act as a pivot point. 
     A further embodiment relates to a self-centering fishing lure, comprising:
         a body being at least partially fish-shaped having a top, a bottom, a first side, a second side, a front end and a rear end and extending in a longitudinal direction, the body further extending in a vertical direction and a width direction, the vertical direction extending from the top to the bottom of the body and the width direction extending from the first side to the second side and a medial line extending along the longitudinal direction, the medial line defining an axis of symmetry of the body;   a cavity located towards the front end of the body, the cavity having an opening defined on a surface of the body, the opening having an opening length and an opening width where the opening length is greater than the opening width and wherein the opening length extends along the medial line; and   a connection member configured for attaching the body to a line, the connection member being located at least partially in the cavity and retained therein by one or more retaining members, each of the one or more retaining members configured to extend into the cavity substantially in the width direction to retain the connection member in the cavity in use of the lure,   wherein the connection member, in use of the lure, is configured to move relative to the body in:   a pivot movement in the cavity, wherein the pivot movement is a movement about an axis substantially parallel to the vertical direction;   a movement along the vertical direction; and   a lateral tilting movement within the cavity, wherein the lateral tilting movement is a movement about the longitudinal direction, and   wherein the lure is configured so that the line exerts a force on the connection member substantially in the longitudinal and vertical directions to cause the connection member to move relative to the body.       

     The connection member may be in the form of a plate that has a plane that, in use, extends generally vertically and longitudinally. 
     The medial line may define a plane of symmetry. The plane of symmetry may lie in the vertical and longitudinal directions. 
     The connection member may have a thickness that is about 50-80% of a width of the cavity. 
     The connection member may have a thickness that is about 66% of the width of the cavity. 
     The one or more retaining members may each be arranged to pass through a respective aperture of the connection member. Each respective aperture may have a diameter about 1.1 to 2.0 times greater than a diameter of the one or more retaining members. 
     The connection member may be retained in the cavity by two retaining members. 
     The one or more retaining members may be in the form of a pin that extends across the cavity in the width direction. 
     The fishing lure may further comprise an arm located in the cavity, the arm being associated with the connection member such that, in use, the arm does not apply a load to the connection member. 
     The arm may pass through a proximal aperture located at a proximal end of the connection member. 
     The proximal aperture has an effective diameter about twice a diameter of the arm. 
     The arm may extend from the cavity into the body and follow a labyrinthine path to extend through a series of passageways defined in the body, through to the rear end of the body. 
     The body may comprise one or more hook attachment points and the labyrinthine path of the arm through the rear end of the body may define the one or more hook attachment points that project from the body. 
     The fishing lure may further comprise a bib connected to the body and the cavity may be located in the bib. 
     The body may have a head portion and a tail portion and the cavity may be located at a tip of the head. 
     A further embodiment extends to a self-centering fishing lure comprising:
         a body being at least partially fish-shaped having a top, a bottom, a first side, a second side, a front end and a rear end and extending in a longitudinal direction, the body further extending in a vertical direction and a width direction, the vertical direction extending from the top to the bottom of the body and the width direction extending from the first side to the second side and a medial line extending along the longitudinal direction, the medial line defining an axis of symmetry of the body;   a cavity formed in the body, the cavity having an opening defined on a surface of the body, the opening having an opening length and an opening width where the opening length is greater than the opening width and wherein the opening length extends along the medial line; and   a connection member configured for attaching the body to a line, the connection member being vertically oriented and located at least partially in the cavity and retained therein by one or more retaining members, each of the one or more retaining members configured to extend into the cavity substantially in the width direction to retain the connection member in the cavity in use of the lure,   wherein the connection member, in use of the lure, is configured to move relative to the body with six degrees of freedom and wherein the cavity is at least partially defined by sidewalls, the connection member being retained within the cavity by the one or more retaining members to allow restricted movement in each of the six degrees of freedom.       

     The body may have a head portion and a tail portion, the head portion defining a tip and the cavity may be formed in the body at the tip. 
     The connection member may be in the form of a plate that has a plane that, in use, extends generally vertically and longitudinally. 
     The connection member may retained in the cavity by two retaining members, each of the retaining members being in the form of a pin that extends across the cavity in the width direction. 
     The connection member is retained in the cavity by a single retaining member. Each connection member may be in the form of a pin. 
     The connection member may be formed with two apertures so that each retaining member passes through a respective aperture and wherein each aperture is greater than a portion of the respective connection member passing through the pin to allow said movement of the connection member relative to the body. 
     A further embodiment extends to a self-centering rod fishing lure, comprising:
         a body being at least partially fish-shaped having a top, a bottom, a first side, a second side, a front end and a rear end and extending in a longitudinal direction, the body further extending in a vertical direction and a width direction, the vertical direction extending from the top to the bottom of the body and the width direction extending from the first side to the second side and a medial line extending along the longitudinal direction, the medial line defining an axis of symmetry of the body;   wherein the body has a tail portion and a head portion with a cavity formed at a tip of the body, the cavity having an opening defined on a surface of the body, the opening having an opening length and an opening width where the opening length is greater than the opening width and wherein the opening length extends along the medial line; and   a plate shaped connection member configured for attaching the body to a line, the connection member being vertically oriented and located at least partially in the cavity and retained therein by one or more retaining members, each of the one or more retaining members configured to extend into the cavity substantially in the width direction to retain the connection member in the cavity in use of the lure;   wherein the connection member, in use of the lure, is configured to move relative to the body with six degrees of freedom and wherein the cavity is at least partially defined by sidewalls, the connection member being retained within the cavity by the one or more retaining members to allow restricted movement in each of the six degrees of freedom;   and wherein the plate shaped connection member defines a plane that, in use, extends generally vertically and longitudinally.       

     The movement of the connection member may be restricted by one or more of: sidewalls forming the cavity and one or more abutments formed on the sidewalls in addition to, or instead of, the one or more retaining members. The connection member may be retained in the cavity by a single connection member and the single connection member may constrain movement of the connection member in the cavity. 
     This fishing lure may be otherwise as set forth above. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Non-limiting embodiments will now be described, by way of example only, with reference to the accompanying drawings, in which: 
         FIG. 1  shows an elevation view of an embodiment of a fishing lure as disclosed herein. 
         FIG. 2  shows a cross-section along line A-A in  FIG. 1 . 
         FIG. 3  shows a plan view of the fishing lure of  FIG. 1  in which only some internal features depicted. 
         FIG. 4  shows an internal arrangement of the lure from  FIG. 1 . 
         FIG. 5  shows a cross-section along line B-B in  FIG. 4 . 
         FIG. 6  shows an embodiment of a connection member. 
         FIG. 7  shows a cross-section along line C-C from  FIG. 4 . 
         FIGS. 8 a  and 8 b    show a close-up schematic plan view of the front of  FIG. 4 . 
         FIGS. 9 a  and 9 b    show a close-up schematic cross-section view of a front of  FIG. 4 . 
         FIGS. 10 a  and 10 b    show a schematic elevation view of the front of  FIG. 4 . 
         FIG. 11  shows another embodiment of a fishing lure having an alternative cavity arrangement of the lure. 
         FIG. 12  shows a cross-sectional elevation view of an another embodiment of a fishing lure as disclosed herein. 
         FIG. 13  shows a cross-sectional elevation view of yet another embodiment of a fishing lure as disclosed herein. 
         FIG. 14  shows an exploded view of an embodiment of a fishing lure as disclosed herein. 
         FIG. 15  shows a front view of the fishing lure of  FIG. 14 . 
         FIG. 16  shows a section view of the fishing lure of  FIG. 14 ; 
         FIG. 17  shows a detail of a portion of  FIG. 16 . 
         FIG. 18  shows a connection member for use with the fishing lure of  FIG. 14 . 
         FIG. 19  shows the connection member of  FIG. 18  installed in the portion of  FIG. 17 . 
         FIG. 20  shows another view of the connection member of  FIG. 18  and shows potential movement of the connection member. 
         FIG. 21  is a further view of installation of the connection. 
     
    
    
     DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS 
     Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Any relative terms such as “about” and “approximately” should be understood to be within normal engineering tolerances for the field of art, or in some cases, preferably within 10% of a stated value, or more preferably within 5% of a stated value, or even more preferably within 1% of a stated value. Other terms such as “near” or “close” should be understood as meaning a particular component is closer to or nearer to another element than other elements of the assembly. 
       FIG. 1  shows a first embodiment of a fishing lure  10 . The lure  10  can be employed for catching a variety of fish and may, for example, be suitable for game fishing. Fishing lure  10  has a body  12  having a front end in the form of a nose  11  and a rear end in the form of a tail  13 . The body  12  has a profile similar to that of a fish. However, the body can have any other profile suitable for attracting fish. 
     An eyelet in the form of ring  22  is positioned at the tail  13 . Ring  22  allows a fishing hook to be attached to the tail  13  of the body  12 . The body  12  also has two fishing hook attachment points, in the form of first U-shaped projection  18  and second U-shaped projection  20 , which are positioned approximately in the middle of the body  12 . Ring  22  and U-shaped projections  18  and  20  have an inner radius of about 4.0 mm to 4.9 mm. Other inner radii can be used, and the radii size can be determined, in part, by target fish size for the lure and the size of any associated fishing hooks. In the embodiment of  FIG. 1 , ring  22  and U-shaped projections  18  and  20  are integrally formed from a rod  16 , as best shown in  FIG. 4 . To form the ring  22  and projections  18  and  20 , rod  16  follows a labyrinthine path. In other embodiments, ring  22  and U-shaped projections  18  and  20  are not integrally formed from a rod  16  and instead are formed from two or more sections of rod (not shown). In an embodiment, rod  16  is stainless steel wire having a diameter about 1.0 to 2.0 mm, such as about 1.8 mm, 1.6 mm or 1.2 mm. 
     The body  12  has a generally elongate body shape ( FIG. 3 ), with a cross-section similar to that of a fish ( FIG. 2 ). In the embodiment of  FIGS. 1 to 3 , the width of the body at cross-section A-A in  FIG. 2  is 25.2 mm, and the height is 40.2 mm. These cross-sectional dimensions are for a body  12  (i.e., from nose  11  to tail  13 ) having a length of 165 mm. Therefore, if the size of the body is increased, say up to 200 mm, the width at cross-section A-A is approximately 30 mm and the height is approximately 48 mm. The size of the body ranges from 85 mm to 200 mm from nose  11  to tail  13 . The proportions of the features are generally scaled accordingly. 
     The body  12  has a bib in the form of a generally elliptical plate  14  extending from the nose  11 . In the embodiment of  FIG. 1 , the elliptical plate  14  is integrally formed with the body  12 . However, the elliptical plate  14  may be formed separately to the body  12  and then be affixed thereto e.g., with adhesives. The elliptical plate  14  in  FIG. 1  has a length of about 68 mm and a width of about 43 mm. For a body size of 200 mm, the elliptical plate  14  has a length of about 82 mm and a width of about 53 mm. However, for smaller lure sizes e.g., less than 165 mm, the plate is scaled accordingly smaller. While the elliptical plate  14  is shown as extending from the nose  11  in the Figures, in some embodiments the elliptical plate  14  can extend forwardly from a region between the nose  11  and tail  13 . In the embodiment of  FIG. 1 , the plate extends downwards at an angle of about 15° to 30°, such as 20°, relative to a longitudinal direction of the body  12 , as shown by arrow  60 . 
     Referring to  FIG. 2  is a cross-sectional view of the lure  10  of  FIG. 1  along the line A-A. In  FIG. 2 , the body  12  has an outer skin in the form of covering  24  which surrounds an interior in the form of core  26 . The covering  24  can be made of plastic, such as ABS plastic, or other plastics typically employed in injection moulding. The covering  24  has a thickness of about 2.0 to 3.0 mm, however, other thicknesses can be used. For example, smaller lures can have a thinner covering  24  compared to larger lures. For lures that are intended to attract fish with sharp and/or abrasive teeth, the covering can be thicker than 3.0 mm. 
     The core  26  is a hollow region within the body  12 . Protruding from the inner surface of the covering  24  are ribs  17  which help to stiffen covering  24 . In the embodiment of  FIG. 2 , the ribs  17  are integrally formed with the covering  24 . The arrangement of ribs  17  can be better viewed with reference to  FIGS. 4 and 5 . The ribs  17  form a lattice arrangement on the interior of the body.  FIG. 5  is a cross-sectional view of  FIG. 4  along line B-B showing how the ribs  17  project from the inner surface of the body towards the interior. In some embodiments, core  26  is formed of foam, such as expanded polystyrene, expanded ABS or expanded polyurethane. In some embodiments, the core is a honeycomb structure defined by walls and voids. The honeycomb structure can comprise tessellated squares. The honeycomb structure can be formed from the same material as the covering e.g., ABS plastic. 
     The body  12  also has a weighted portion in the form of first weight  30  and second weight  32  ( FIG. 4 ). The first and second weights  30  and  32  are positioned adjacent to the first and second U-shaped projections  18  and  20 . The weights  30  and  32  are generally lead-based, but any suitable material that is denser than the covering  24 , core  26  and/or water can be used. Since the weights  30  and  32  are generally positioned in a lower half of the body, the weights  30  and  32  act as ballast to keep the lure  10  in an upright position when being trolled in the water. The position of the weights  30  and  32  determines the centre of gravity for the lure  10 . Depending on the application of the lure i.e., the type of fish that the lure is intended to catch, the weights  30  and  32  can be positioned closer to the nose  11  or tail  13 . 
     In the embodiment of  FIGS. 1 to 4 , the elliptical plate  14  is made from the same material as the covering  24 . However, when the elliptical plate  14  is not integrally formed with the covering  24 , the elliptical plate  14  can be made from a different material (e.g., a reinforced polymer or polymer composite to provide increased stiffness). While the elliptical plate  14  is shown as generally being planar, in some embodiments the elliptical plate  14  can have a contoured surface with e.g., projections and cavities to alter the in use hydrodynamics of the lure  10 . This can help to provide a lure with desirable trolling characteristics, such as diving profiles and/or tracking profiles that help to mimic bait fish, so as to attract target fish. 
     The covering  24  is painted to so that the lure  10  resembles bait fish. Other distinctive markings that attract fish to lure  10  can also be used. In some embodiments, a top portion of the covering  24  has a reflective surface that resembles fish scales (not shown). The colours and design of the painted covering are selected to target specific fish. The covering  24  in some embodiments is fitted with additional features that extend from the covering, such as soft rubber fins that wave about when the lure  10  is trolled through water. These additional features can make the lure  10  further resemble bait fish. The elliptical plate  14  as shown in the Figures is not painted, and is instead formed of transparent plastic. Keeping the elliptical plate  14  transparent ensures that only the body  12  resembles a bait fish. However, in some embodiments, it can be beneficial to provide distinctive markings on elliptical plate  14  to attract fish. In a specific embodiment, the elliptical plate  14  is clear ABS plastic and the covering  24  is painted ABS plastic. 
     The body  12  has a recess  21  near second U-shaped projection  20 . The recess  21  allows a hook attached to second U-shaped projection  20  to sit closer to the body  12  so as to provide a streamlined profile. This can help to increase lure stability when the lure  10  is being trolled at speed, such as 12 knots. Alternatively, a hook can be connected to the first U-shaped projection  18  by a tether, such as wire or Kevlar rope or cable. The hook and/or tether can then be temporarily secured with a tie, for example using a small cable tie, to temporarily secure them to the second U-shaped projection  20 . Once a fish strikes and is engaged with the hook, the tie breaks allowing the hook to be tethered only to U-shaped projection  18 . This arrangement helps to improve lure stability when catching a fish, whilst then allowing the lure  10  to still be securely engaged with a fish when a fish is being reeled in. Using a flexible tether can reduce the ability of the fish, through its use of violent shaking movements, to form a lever against the lure body and so come free when being reeled in. 
     Now referring to  FIG. 4  and  FIGS. 6 to 10 , the body  12  has a cavity in the form of elongate channel  40  located towards the nose  11  of the body  12 . The channel  40  extends to define an opening at an upper surface  43  of the elliptical plate  14 . Located within channel  40  is a connection member in the form of plate  28 . A major plane of the plate  28  extends vertically in use of the lure  10  (see  FIG. 7 ). Plate  28  is retained in the channel by retaining members/connectors in the form of pins  42  and  44 . Pins  42  and  44  pass through apertures  50  and  52 , respectively, located in plate  28 . In the embodiments of  FIGS. 4 and 6 , apertures  50  and  52  have a diameter of about 1.5 mm to 2.5 mm such as about 2.4 mm, 2.0 mm or 1.5 mm, and the pins  42  and  44  have a diameter of about 1.0 to 2.0 mm, such as about 2.0 mm, 1.8 mm, 1.5 mm, 1.2 mm or 1.0 mm. Since apertures  50  and  52  are about 35% to 75% larger than the diameter of pins  42  and  44 , such as about 65%, plate  28  is able to move along and up and down with reference to the pins  42  and  44 , as described in more detail with reference to  FIGS. 7 to 10 . The ratio of the diameter of pins  42 / 44  to aperture  50 / 52  range from about 1:1.45 to 1:1.65. Having ratios outside this range means that the ability of the lure to self-centre in use can be diminished, and the lure may start to track from side-to-side. This means that the lure will generally tend to blow out of the water. 
     While pins have been described in  FIG. 4 , retaining members having different cross-sections, such as rectangular, square and/or oval, can be used in some embodiments. In some embodiments, the diameter and cross-section of pin  42  and aperture  50  can differ to that of pin  44  and aperture  52 . 
     An in-use distal end of the plate  28  has a distal aperture in the form of an eyelet or connection aperture  38  for connecting the plate  28  to fishing line ( FIG. 6 ). The connection aperture  38  has a semi-oval shape. In the embodiment of  FIG. 6 , connection aperture  38  has a length of about 5.6 mm and a width of about 3.3 mm. However, other dimensions can be used for the connection aperture in alternative embodiments. The design of plate  28  means that it can be scaled up and down depending on the size of the lure  10 . As shown in  FIG. 4 , a connection (e.g., split) ring  39  is secured to aperture  38 . 
     The positioning of connection aperture  38  relative to the elliptical plate  14  and the nose  11  of the body  12  affects the diving characteristics of the lure  10 . As the position of the connection aperture  38  is moved away from the nose  11  and closer to the tip (i.e., front) of elliptical plate  14 , the lure  10  tends to remain close to the surface of the water in use. Conversely, moving the connection aperture  38  towards the nose  11  away from the tip of the elliptical plate  14  causes the lure  10  to dive deeper in use. Placing the connection aperture  38  too close or too far from the nose causes the lure to not track correctly when being trolled in use. For example, the lure  10  may cavitate underwater. Alternatively, the lure may jump out of the water. Therefore, the positioning of the connection aperture  38  affects the ability of the lure  10  to self-centre. In the embodiment of  FIG. 1  to  FIG. 4 , the distance between the nose  11  and tail  13  is 165 mm, and the connection aperture  38  is about 34 mm in front of the nose  11 . Since the elliptical plate  14  is about 68 mm long, the connection aperture  38  is about 35% along the length of the elliptical plate  14  when measured from the nose  11 . Generally, the connection aperture  38  is about 25% to 40% along the length of the elliptical plate  14  when measured from the nose  11 . 
     The size of connection aperture  38  is not critical, but rather the location of a centre point of the top of the connection aperture  38  in relation to the size of the elliptical plate  14  is important to a desired lure performance. Generally, each size of the lure  10  has to be tested for the optimal position of connection aperture  38 . Whilst it can be proportionally scaled down or up once a relative position is known on one size of lure, and it can be shown that the lure will then swim with this scaling, it is often the case that the best action is not achieved by just scaling this position. The exact position of connection aperture  38  relative to elliptical plate  14  has to be tested on each size to determine an optimal position that allows maximum depth and speed. 
     Pins  42  and  44  are fixed into the elliptical plate  14  in a direction approximately transverse to a longitudinal direction (i.e., the direction of arrow  60 ) of channel  40 . In the embodiment of  FIGS. 5 and 7 , pins  42  and  44  are received in bores formed in elliptical plate  14 . The bores are formed during manufacture of the plate. In use, plate  28  contacts pins  42  and/or  44 . Therefore, any forces applied to plate  28  are transferred to pins  42  and  44  and into elliptical plate  14 . The load distribution between pins  42  and  44  varies depending on an angle of the load acting on the plate  28  from fishing line attached to connection aperture  38 . 
     The strength of pins  42  and  44  and elliptical plate  14  help to retain plate  28  in the channel  40  in use (i.e., normal use) of lure  10 . However, in some circumstances, pins  42  and/or  44  may fail. For example, if a fish that is larger than the intended use of the lure strikes lure  10 , pins  42  and/or  44  may be pulled from their respective bores and out of the channel  40 . This would normally result in the plate  28  being disconnected from body  12 . To ensure that such circumstances do not result in the plate  28  being disconnected from body  12 , a proximal end of plate  28  is provided with a proximal aperture in the form of auxiliary aperture  54 . An arm in the form of loop  41  is able to pass through auxiliary aperture  54  (loop  41  is also represented as dashed lines in  FIG. 3 ). Loop  41  is formed at a terminal portion of rod  16  by folding a portion of rod  16  back on itself. In the embodiment of  FIG. 3 , the loop  41  is positioned in a flared region of the elongate channel  40 , as represented by dashed box  31 . Flared region  31  accommodates the total width of the loop  41 . In some embodiments, the loop  41  can be partially embedded in sidewalls of the channel. 
     The folded back portion of loop  41  is secured to rod  16 , for example by spot welds as shown as dots  29  in  FIG. 3 . Optionally, the folded back portion may be secured by lashing with yarn and/or adhesives. The inner diameter of loop  41  is about 3.0 mm. In another embodiment, the inner diameter of loop  41  is about 2.5 mm. In an embodiment, the diameter of the loop is determined by the space available within the elliptical plate. While the embodiment of  FIG. 4  shows rod  16  being integrally formed with loop  41 , as well as ring  22  and U-shaped projections  18  and  20 , this is not always necessary and each feature may be formed from its own section of rod. The loop  41  is generally used for lures when a size of the body  12  is about 200 mm to 140 mm, such as 165 mm. The actual size of the loop  41  is not important so long as it does not engage with the plate  28  in normal use of the lure  10 . 
     The term “engage” as used herein in relation to the engagement of the loop  41  and plate  28  is to be interpreted broadly to mean not touching and/or not transferring any substantial load(s) from the plate  28  to the loop  41  during normal use of the lure. For example, the proximal portion of plate  28  may come into contact with loop  41 , but the dimensions of the loop  41 , auxiliary aperture  54 , channel  40  pins  42  and  44 , and/or apertures  50  and  52  may mean that substantial loads exerted onto plate  28  during normal use of the lure  10  are transferred through pins  42  and  44 . Minimising or eliminating any loads transferred from the loop  41  to the plate  28  through auxiliary aperture  54  can help the lure  10  to self-centre during normal use of the lure. 
     If pins  42  and/or  44  fail, the load(s) acting upon lure  10  are transferred from the plate  28  to loop  41  via auxiliary aperture  54 . Because loop  41  is only required in the event that pins  42  and/or  44  fail, it does not always need to be in contact or otherwise engaged with auxiliary aperture  54 . Therefore, in some embodiments, loop  41  does not touch and/or engage with plate  28  during normal use i.e., when pins  42  and/or  44  have not failed. As described with reference to  FIG. 7  to  FIG. 10 , the plate  28  tends to only engage with the pins and not the loop  41  during normal use of the lure  10 . To ensure loop  41  does not touch plate  28 , auxiliary aperture  54  has dimensions about twice that of the diameter of the wire forming the loop  41 . For example, when the auxiliary aperture  54  is an oval, the width of the aperture may be twice that of a diameter for the wire used to form loop  41 , and the length may be about three times the diameter of the wire used to form loop  41 . In an embodiment, the wire forming the loop  41  has a diameter of about 1.6 mm and the auxiliary aperture is in the form of a rounded rectangle having a width of about 3.0 mm and a length of about 5.6 mm. In normal use, the loop  41  is positioned to be approximately in the centre of auxiliary aperture  54 . For example, if auxiliary aperture  54  has a length of about 5.6 mm, loop  41  is positioned about 2.0 mm from an end of auxiliary aperture  45 . 
     Specific features of the lure  10  are now described with reference to  FIGS. 7 to 10 . However, certain features have been omitted for clarity. 
       FIG. 7  shows a cross-section along line C-C from  FIG. 4 . Channel  40  is formed of side walls having a lower portion  58  and an upper portion. In the embodiment of  FIG. 7 , upper portion has lips in the form of flanges  56  extending towards each other. This arrangement means that the width W 1  of the channel at the lower portion  58  is greater than a width W 2  between flanges  56 . Generally, the ratio of W 1 :W 2  is about 1:0.6 to about 1:0.71. For example, the ratio of W 1 :W 2  may be about 1:0.66. Some embodiments have a ratio of W 1 :W 2  outside of about 1:0.6 to 1:0.71. In an embodiment, W 1  is about 3.5 mm and W 2  is about 2.2 mm. In other embodiments, W 1  is about 4.0 mm, 3.5 mm, 3.0 mm, 2.5 mm or 2.0 mm. In some embodiments, W 2  is about 2.9 mm, 2.2 mm, 1.8 mm or 1.5 mm. Flanges  56  help to increase of the strength of the bores that house pin  42  and  44  so that it is less likely that the bores will fail in use of lure  10 . Flange  56  has a thickness of about 0.7 mm to about 1.3 mm, such as 0.8 mm to 1.1 mm. Because W 1 &gt;W 2 , the portion of the plate  28  that is proximate the lower portion of the channel is able to pivot about pin  42  and  44  without coming into contact with the lower portion of the sidewall  58 , as will be explained in greater detail with reference to  FIGS. 8 and 9 . 
     Plate  28  has a thickness T 1  that is less than W 2 . In an embodiment W 2  is about 2.2 mm and T 1  is about 1.5 mm. In other embodiments, T 1  is about 2.0 mm, 1.8 mm, 1.5 mm, 1.2 mm or 1.0 mm. T 1  is generally about 50% to 80% W 2 . Because apertures  50  and  52  are larger than the diameter of pins  42  and  44 , plate  28  is able to move along and pivot side to side relative the pins  42  and  44 . Therefore, plate  28  is able to pivot from side to side in use in a direction approximately transverse to the longitudinal direction of channel  40 . However, the plate  28  in its entirety does not necessarily need to move in the transverse direction. Pin  42  has a length of about 15.0 mm to about 2 mm, such as about 12.0 mm, 11.0 mm, 10.6 mm, 8.0 mm, 7.0 mm, 5.0 mm, 6.0 mm, 4.0 mm or 3.0 mm. 
       FIG. 8 a    and  FIG. 8 b    is a schematic top view of the lure  10 , omitting most of the lure  10  for clarity. As shown in  FIG. 8 a    and  FIG. 8 b   , the oversized apertures  50  and  52  allow the distal and proximal ends of plate  28  to move along and pivot about relative pin  42  so that the connection aperture  38  moves in a generally transverse direction to the longitudinal direction of the channel, as depicted by arrow  60 , towards the sides of channel  40 . Put another way, one end of plate  28  pivots to one side of the channel, and an opposite end of the plate  28  pivots to the other side of the channel, and vice versa. Therefore, the transverse movement means generally towards the sidewalls of channel  40 . In the embodiment of  FIG. 8 a    and  FIG. 8 b   , arrow  60  is pointing from the front  11  of the body towards an in use front end of elliptical plate  14 . Such movement of plate  28  can occur when the lure  10  is not correctly aligned and begins to track off course when being trolled in use. During the movement of plate  28  from side to side as shown in  FIG. 8 a    and  FIG. 8 b   , the auxiliary aperture  54  does not engage with the loop  41  e.g., no load is transferred from the plate  28  to loop  41 . 
     Movement of plate  28  to either sidewall allows the forces acting upon lure  10  to equilibrate so that the lure  10  tracks in a straight line when being trolled i.e., to become centred. Once the lure  10  begins to equilibrate, the plate  28  is then able to align itself generally with the longitudinal direction  60 . Depending on the trolling conditions, the plate  28  may be centrally located or may be located closer to one of the sidewalls once it is aligned generally with the longitudinal direction. The term “generally aligned” is to be broadly interpreted to mean approximately parallel to the longitudinal direction. In some circumstances, the plate pivots about pin  44  so that connection aperture  38  moves generally up and down with respect to a base of channel  40 . In the embodiment of  FIG. 8 a    and  FIG. 8 b   , the up and down movement is into and out of the page. The pin upon which the plate  28  pivots in generally an up and down movement will be determined by the forces acting through plate  28  and pins  42  and  44 . Given plate  28  can pivot about pin  42  and/or  44 , plate  28  can move in a direction that is generally perpendicular to the longitudinal direction  60 , that is to say in a direction in a range from about 60° to 120° relative to the longitudinal direction  60 . 
     Since the plate  28  is able to move into a position that balances the relative forces applied to the lure, the lure  10  can track correctly in use. This arrangement can reduce lure setup time, since connection aperture  38  may only need to be in approximately the correct position prior to use, where the remaining adjustment is performed by the lure itself in use. The need to adjust the connection aperture  38  after each catch can also be eliminated. Further, allowing the lure to self-centre can allow the lure to be trolled at speeds greater than 10 knots, such as up to 12 knots, and potentially even faster speeds. In an embodiment, the lure  10  can be trolled at speeds of up to 15 knots. The actual speed that the lure  10  is trolled will be determined by the type of target fish. 
       FIG. 9 a    and  FIG. 9 b    is a schematic representation of the lure  10  across a cross-section through pin  44 . As shown in  FIG. 9 a    and  FIG. 9 b   , plate  28  is able to literally tilt back and forth about pin  42  in a sideways direction towards and away from the sidewalls of the channel  40  so that the connection aperture  38  can move in a general perpendicular direction to the longitudinal direction. In  FIG. 9 a    and  FIG. 9 b   , the longitudinal direction extends out of the page. Much in the same way the plate  28  moves in response to forces exerted on the lure  10 , as described in reference to  FIG. 8 a    and  FIG. 8 b   , plate  28  will tilt laterally when the lure  10  is not centred when being trolled. As the lure  10  begins to self-centre, plate  28  will then begin to position itself to be more vertically aligned i.e., be in a position that is approximately perpendicular to the plane of the top surface  43  of elliptical plate  14 . While only pin  42  is shown in  FIG. 9 a    and  FIG. 9 b   , the plate  28  also moves in a similar way relative to pin  44  as that for pin  42 . 
     In  FIG. 9  and  FIG. 10  the pins  42  and  44  are illustrated as extending across the entire width of cavity  40 . However, in some embodiments the pins may only extend across a portion of the width of the cavity. For example, in  FIG. 11 , pin  66  is embedded in a first sidewall  68 . Pin  66  extends from the first sidewall  68  into the channel  40  and towards a second sidewall  70 , but the pin  66  terminates before engaging the second sidewall  70  so as to extend across a portion of the cavity. Such an arrangement may be beneficial during manufacture since less tolerance is required during manufacture since the pin(s) do not need to match up with opposite facing bores. 
     In reference to  FIG. 10 a    and  FIG. 10 b   , a side view of the plate  28  in different orientations in the channel  40  in shown. For clarity, many features of lure  10  are omitted from  FIG. 10 a    and  FIG. 10 b   . Because apertures  50  and  52  are larger than the diameter of the pins  42  and  44 , the plate  28  is able to move towards and away from base  51  of channel  40  depending on the forces being applied to the plate  28  (i.e., tilt or rock up and down). In  FIG. 10 a   , force  62 , such as tension being applied in use from a fishing line, is directed generally perpendicular to the base  51  of the channel  40 . The force  62  pulls the plate  28  out of the channel until a lower region of aperture  52  contacts a lower region of pin  44 , and an upper region of aperture  50  contacts an upper region of pin  42 . The terms “upper” and “lower” are with respect to the base  51  of the channel  40  and are not intended to limit the lure  10  to any particular orientation. The plate  28  moves relative the channel when the direction of the force changes. For example, in  FIG. 10 b   , force  64  is directed generally parallel to the base  51  of the channel  40 . In  FIG. 10 b   , the force  64  pulls the plate  28  towards a distal end of the channel  40  so that the proximal sides of apertures  50  and  52  contact pins  42  and  44 . Put another way, the plate  28  moves generally up and down with respect to the base  51  such that a tilting up or rocking of the plate  28  at one end, and a tilting or rocking down of the plate  28  at the opposite end (and vice versa). 
     The amount the plate  28  can move in and out of channel  40  is determined by the diameter of apertures  50  and  52  and the diameter of pins  42  and  44 . As the size of the apertures  50  and  52  increases relative to the diameter of the pins  42  and  44 , the plate  28  able to move in and out of channel more compared to when the size of the apertures  50  and  52  decreases relative to the diameter of the pins  42  and  44 . During the movement of plate  28  in and out of the channel  40 , as shown in  FIG. 10 a    and  FIG. 10 b   , the auxiliary aperture  54  does not engage with the loop  41 . 
     Since the plate  28  can move, in use, in a multitude of directions (i.e., multiple degrees of freedom), as shown in  FIGS. 8 to 10 , the plate  28  is allowed to function as a floating anchor point, which means that the plate  28  is able to move to balance out the forces acting on the lure  10  so that the lure is able to self-centre. Adjusting the relative sizes of the diameters of apertures  50  and  52  and pins  42  and  44 , the plate thickness T 1 , and the width of the channel W 1  and W 2 , helps to control how much the plate  28  is able to move relative to the channel. These features can be adjusted to provide lures with specific self-centring abilities. For example, if a ratio of W 2 :T 1  is too large, the channel  40  allows the plate  28  to “wander” from side to side on the pins away from a centre point of the channel  40  centre point, and the lure cannot self-centre to find its own centre point. This means that the lure will tend to swim from left to right, which means that a top speed of the lure may not be achieved and the lure may tend to easily break out of the water. The presence of the sidewalls, for example lips  56 , inhibits the “wander” of the plate  28  and instead allows the plate  28  to wiggle. Conversely, if the ratio of W 2 :T 1  is too small, the lure  10  cannot self-centre in use to find its own centre point, and the sidewalls walls of the channel, for example the lips  56 , inhibit the wiggle in the plate  28 . Similarly, if the apertures  50  and  50  are too small and/or the pins  42  and  44  are too large, the plate  28  cannot get enough “wiggle” room to self-centre in use. Effectively, what happens in normal use of the lure  10  is that the plate  28  stays in position (i.e., in a straight generally uprights orientation) and the lure  10  moves (i.e., “wiggles”) relative to the plate. 
     In some embodiments, however, there are situations where a larger ratio of W 2 :T 1  is used to provide a lure that in use has the “wandering” action, that is to say a lure that moves in use in a left to right direction. These embodiments may have a W 1 :W 2  ratio outside of about 1:0.6 to 1:0.71. The lures of embodiments with the “wandering” action tend to have a shallower elliptical plate  14 . For some lures, such as shallow diving “Square bib” design that are designed to dive to around 4-5 ft, this wandering action can be useful for attracting target fish. 
       FIG. 12  shows another embodiment of a lure  100 . Lure  100  shares similar features to lure  10 , in that lure  100  has a body  110  having a front end in the form of a nose  112  and a rear end in the form of a tail  114 . An eyelet in the form of ring  116  is positioned at the tail  114 . The body  110  also has two hook attachment points, in the form of first oval-shaped projection  118  and second oval-shaped projection  120 , which are positioned approximately in the middle of the body  110 . Ring  116  is formed of a single piece of wire, for example stainless steel wire having a diameter of about 1.0 mm and a length of about 11.0 mm. Similar, oval-shaped projections  118  and  120  are each formed of a single piece of wire, such as stainless steel wire having a diameter of about 1.0 mm and a length of about 9.0 mm. The body  112  has a length of about 100 mm. A weighted portion provided as two adjacently positioned weights  122  is also provided adjacent oval-shaped projections  118  and  120 . Weights  122  may be positioned anywhere between the nose  112  and the tail  114  to give the lure  100  a desired centre of gravity. 
     Body  112  also has a bib in the form of elliptical plate  124 . A longitudinal direction  160  extends alone the body from the tail  113  to the nose  111 . A cavity in the form of channel  128  opens up to an in use upper surface  126  of the elliptical plate. The channel  128  extends generally along the longitudinal direction  160  to define an opening at an upper surface  126  of the elliptical plate  124 . A connection member in the form of a plate  130  is retained in the channel  128  by retaining members in the form of pins  134  and  136 . A major plane of plate  130  extends vertically in use of the lure, similar to that shown in  FIG. 7 . Unlike plate  28 , plate  130  does not have an auxiliary aperture located at a proximal end of the plate  130  that is configured to engage with an arm. Because lure  100  is designed for use with smaller fish, the strength of pins  134  and  136  means that it tends to be unlikely that the pins  134  and  136  and/or the bores in the elliptical plate  124  in which the pins are housed will fail in use. However, lure  100  can be used to catch larger fish, such as sport fish, provided the strength of the elliptical plate  124  and the pins  134  and  136  are strong enough to withstand the forces generated in use of the lure  100 . Therefore, not all embodiments of lure  10  require the use of auxiliary aperture  54  and loop  41 . 
       FIG. 13  shows yet another embodiment of a lure. Lure  200  is similar to lure  100 , e.g., has nose  212 , tail  214 , ring  216 , elliptical plate  224 , channel  228 , plate  230  having a major plane extending vertically in use of the lure, and pins  234  and  236 . However, only one oval-shaped projection  218  is provided. This is because lure  200  is intended to catch small fish. A body length from the nose  212  to tail  214  of lure  200  is about 80 mm. 
     In both  FIG. 12  and  FIG. 13 , channel  128 / 238  is formed of side walls having a lower portion and an upper portion having lips, similar to that shown in  FIG. 7 . A width between the lips for lure  100 / 200  is about 1.5 mm and a width between a lower portion of channel  128 / 238  is about 2.0 mm. Plate  130 / 230  has a thickness of about 1.0 mm. Pins  134 / 234  and  136 / 236  have a diameter of about 1.0 mm and the corresponding apertures in plate  130 / 230  though which pins  134 / 234  and  136 / 236  pass is about 1.5 mm. 
     The embodiments described above use two pins to retain the plate  28 / 130 / 230  into channel  40 / 128 / 228 . However, other embodiments may have more or less than two pins. For example, three pins, four pins, or more than four pins may be provided. Some embodiments may only use one pin. In embodiments with only one pin, the channel may be provided with additional features, such as abutment members to control the degrees of freedom of the plate with respect to the lure longitudinal direction. In another embodiment, the pins are replaced with a single bar having a generally rectangular or oval cross-section, and the plate  28  is provided with a similarly shaped aperture having dimensions larger than the respective cross-section. In these embodiments, one side of the bar will contact a top portion of the aperture and the other side of the bar will contact a bottom portion of the aperture when the plate  28  moves in and out of the channel  40 . The contact of the top portion and/or bottom portion can help to limit the degrees of movement. 
       FIG. 14  shows a further embodiment of a fishing lure  300 . The lure  300  can be employed for catching a variety of fish and may, for example, be suitable for game fishing. Although the lure  300  may be used for either trolling or rod fishing, it has particular application to rod fishing. 
     Fishing lure  300  has a body  302  having a front end in the form of a head portion  304  and a rear end in the form of a tail portion  306 . The body  302  has a profile similar to that of a fish and the head portion  304  has a tip  310 . In certain embodiments, the tip  310  may be the foremost part of the head portion or the part of the head portion where a surface has the largest curvature. The body defines a longitudinal direction   generally along a length, a height   from a top to bottom and a width w from one side to the other, as shown in  FIGS. 15 and 16 . 
     In the embodiment illustrated (and as shown in the exploded view of  FIG. 14 ), the body comprises two lateral sides  330  and  332  which are attached to one another during a manufacturing process. As shown in  FIG. 15 , when the lateral side  330  is attached to lateral side  332 , this forms a seam  334  which is here designated as a medial line. Since the side  330  is a mirror-image of side  332 , in this embodiment, the medial line forms a plane of symmetry. 
     It is to be realised that in other embodiments, the two sides may not be symmetrical and the medial line may then designate a plane mid-way in a width direction w. 
       FIG. 16  illustrates the side  330  and, as illustrated, a cavity  340  is formed at the tip of the head region. Although the cavity  340  extends into the body  302  ( FIGS. 16 and 17 ), the cavity has an opening  342  defined at the surface of the body. As shown in  FIG. 15 , the opening is elongate having a length O L  and a width O W . The opening length O L  is greater than the opening width O W . In this embodiment, the opening length O L  and the opening width O W  are measured along the outer surface of the body. 
     In this embodiment, the medial line runs the length of the cavity O L . In this embodiment, the cavity is symmetrically disposed about the medial line, but it is be realised that in other embodiments a certain degree of asymmetry may be permitted without deleteriously affecting the performance of the lure. 
     Referring to  FIGS. 17 and 21 , the cavity  340  is formed by a sidewalls  344  (towards the back) and  356  and  358  (top and bottom) which extend from the opening back into the side  330 . Although portions of the body side  330  are hollow, the cavity  340  is delimited within the body by the sidewalls  344 ,  356  and  358  which form the top, bottom and back of the cavity. A further sidewall  346  forms a portion of a side of the cavity  340 . As shown, the sidewall  346  describes a circular member  348 . A hollow core  352  is formed in the circular member  346 . An abutment  350  is formed on the sidewall  346 . 
     The lure  300  further comprises a connection member  380 , shown in  FIG. 18 . The connection member  380  is formed with two apertures  382  and  384 . In use the connection member is situated in the cavity  340  and is retained in place by a retaining member in the form of a pin  392  which is situated in the hollow core  352  formed by the side wall  346  and which passes through aperture  382  in the connection member  380 . 
     It is to be realised that the other side  332  is formed in the same way as side  330  illustrated and described above. Therefore, the opposite end of the pin is retained in a similar circular hollow formed in that side. 
     The various sidewalls and the pin act to retain the connection member  380  in the cavity whilst allowing movement of the connection member relative to the cavity. The cavity is larger than the connection member  380  and the aperture  382  is larger than the pin  392  as illustrated in  FIG. 19 , thereby allowing movement of the connection member. The movement of the connection member is as described above with reference to the embodiments of  FIGS. 1 to 13 . 
     The movement of the connection member may be described with reference to  FIG. 20 .  FIG. 20  shows the connection member  380  and the three Cartesian coordinates in dashed lines X, Y and Z. Here, the length of the lure  300  lies in the Y coordinate; the height of the lure  300  lies in the X co-ordinate and the width of the lure  300  lies in the Z coordinate. The connection member  380  is able to move with six degrees of freedom: it is able to translate (move back and forth) in each of the X, Y and Z directions as well as rotate about each of the X, Y and Z axes. 
     However, the movement of the connection plate in each of these six directions is constrained by either or both of the pin and the sidewalls of the cavity. In this embodiment, the abutment  350  on sidewall  346  ( FIG. 21 ) helps to constrain the movement of the connection member relative to the body. 
     As illustrated, the connection member is in the form of a plate which extends in the X and Y directions more than in the Z direction when the connection member has been installed in the body  302  of the lure  300 . 
     As illustrated in  FIGS. 14, 15 and 16 , the lure includes two eyelets  322  and  308  to which a hook or similar apparel may be attached. Similarly, aperture  384  of connection member  380  forms an attachment for a line or other apparel. Three weights  390  provide ballast, as known in the art. 
     As illustrated in  FIGS. 1, 4   8 ,  12 ,  13 ,  15 ,  16  etc. the connection member  28 ,  380  generally lies in a plane which extends generally vertically and longitudinally. Although movement of the connection member in the cavity is permitted, as discussed, the movement is restrained so that the orientation of the connection member is closer to a plane lying in the longitudinal and vertical directions than in other directions. It has been found that exerting the force required to pull the lure through the water on a connection member with this orientation may improve the seemingly life-like swimming motion of the lure and improve the tracking characteristics as described above. 
     In the claims which follow and in the preceding description of the fishing lure, except where the context requires otherwise due to express language or necessary implication, the word “comprise” or variations such as “comprises” or “comprising” is used in an inclusive sense, i.e., to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the lure. 
     It will be understood to persons skilled in the art of the invention that many modifications may be made without departing from the spirit and scope of the invention.