Abstract:
A fishing lure imitating a bird has a body having a central long axis with equal longitudinal buoyancy, a set of two simulated eyes, groups of buoyant flexible strands each joined at one end to the body simulating extended bird wings, and a hook element disposed longitudinally through the cylindrical body with a shank extending rearward in the body along the long axis, the shank exiting the body in an upward-facing lengthwise recess, then bending forward to present a hook point.

Description:
CROSS-REFERENCE TO RELATED DOCUMENTS 
     The present application is a continuation application of and claims priority to U.S. Ser. No. 13/333,590, filed Dec. 21, 2011, which claims priority to provisional patent application No. 61/458,541, filed on Jan. 13, 2011 and provisional patent application No. 61/515,142 filed Aug. 4, 2011. All disclosure of the parent applications are incorporated herein at least by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention is in the field of fishing lures and accessories and pertains particularly to lures made to imitate winged prey. 
     2. Discussion of the State of the Art 
     In the art of fishing, more particularly cast fishing, many different types of top water lures have been developed for cast fishing near structure along the shoreline of any particular body of water. Top water lures include hard, solid body type and soft, hollow body type lures adapted to imitate some form of natural prey the fish typically or atypically feeds upon. 
     One problem with traditional top water lures is that they are difficult to fish in heavy brush, stumps, lily pads, or tulle areas typically prized by anglers due to the ambush nature of many fish species. Many lures with single, double, or treble hook attachments become snagged on such cover or drag pieces of grass, twigs, etc. when retrieved. 
     Current soft body floating lures such as frogs, rats, and mice for example, get snagged because the body is too soft enabling casual contact with an object to expose the hook points. Most of these soft body lures also sink after a short time in the water. 
     Another limitation to cast fishing in heavy cover is keeping the offering in a desired zone for an extended period required to entice a strike. Most top water lures are pulled, swum, or popped through cover, over lily pads, etc. requiring repeated casts to a same zone before a fish will finally strike. Many times such repeated commotion puts the fish down after the first few casts. 
     Therefore, what is clearly needed is a fishing lure and method for fishing that solves the problems mentioned above. 
     SUMMARY OF THE INVENTION 
     In one embodiment of the invention a fishing lure imitating a bird is provided, comprising a substantially cylindrical, flexible hollow body having a central long axis, the body shape tapering from a common larger diameter to a substantially smaller diameter at a front end and having a rounded rear end, the cylindrical body implemented to exhibit substantially equal longitudinal buoyancy, causing the body when floating on a water surface to float with the long axis substantially parallel with the surface in an orientation defining a body top, a body bottom, a height from top to bottom, a length, a left side facing front, and a right side facing front, the buoyancy providing a water line, a set of two simulated eyes, one eye positioned on the left side of the body toward the front end, another eye positioned on the right side of the body directly opposite the one eye, a first group of buoyant first flexible strands each joined at one end to the left side of the body at a common point rearward of the eyes, the first flexible strands extending outward from the body to the left side, such that with the body floating with the long axis parallel to the water surface, some of the first strands angle forward, some are substantially at a right angle to the long axis, and some angle rearward, and length of the first strands extending from the body are progressively shorter from front to back, such that the first strands floating next to the body simulate an extended bird wing to the left side, a second group of buoyant second flexible strands each joined at one end to the right side of the body at a common point rearward of the eyes, directly opposite the first group of first flexible strands, the second strands extending outward from the body to the right side, such that with the body floating with the long axis parallel to the water surface, some of the second strands angle forward, some are substantially at a right angle to the long axis, and some angle rearward, and length of the second strands extending from the body are progressively shorter from front to back, such that the second strands floating next to the body simulate an extended bird wing to the right side, as a mirror image of the simulated bird wing to the left side, and a hook element disposed longitudinally through the cylindrical body, the hook element having an eyelet extending outward through an opening from the front end of the body below the water line, a shank extending rearward in the body along the long axis, the shank exiting the body through an opening below the waterline in an upward facing lengthwise recess, then bending forward to present a hook point facing in a forward direction, the point concealed in the recess and positioned at a point along the length rearward of the simulated wings. 
     In one embodiment the cylindrical body is hollow and molded from a polyvinyl chloride (PVC)-based or rubber-based compound to form a soft but resilient lure body. Also in one embodiment the tapered front end is reinforced to secure the front end of the hook assembly. Also in one embodiment the first and second flexible strands have a rigidity low enough that with the body suspended in air the strands droop downward, and high enough that with the body floating on the surface the strands fan out straight on the surface from the joining point. Still in one embodiment the buoyant flexible strands are annular, hollow, silicon rubber strands or rectangular, hollow, silicon rubber strands. 
     In one embodiment the hook element separates to two second shanks from the single shank, each second shank exiting the body in parallel lengthwise recesses ending in points facing forward and concealed in the parallel recesses. In one embodiment the lure further comprises simulated bird legs and feet extending from beneath the body. Also in one embodiment the groupings of buoyant flexible strands each pass through an opening in the body at points below the water line, and are secured within the body by knots or clamping elements larger than the openings through which the groupings of strands pass at each joining point to the body. 
     In one embodiment the lure further comprises a third and a fourth group of buoyant flexible strands joined to the body at opposite points on the left and right sides of the body rearward of the joining points of the first and second groups of flexible strands, wherein the flexible strands in each of the third and fourth groups extend outward from the body on each side, such that with the body floating with the long axis parallel to the water surface, some of the third and fourth strands angle forward, some are substantially at a right angle to the long axis, and some angle rearward, and length of the third and fourth strands extending from the body are progressively shorter from front to rear, and the average length of the strands in the third and fourth groups is less than the average length of strands in the first and second groups. 
     In one embodiment the lure further comprises a fifth and sixth group of buoyant flexible strands joined to the body at opposite points on the left and right sides of the body rearward of the joining points of the third and fourth groups of flexible strands, wherein the flexible strands in each of the fifth and sixth groups extend outward from the body on each side, such that with the body floating with the long axis parallel to the water surface, some of the fifth and sixth strands angle forward, some are substantially at a right angle to the long axis, and some angle rearward, and length of the fifth and sixth strands extending from the body are progressively shorter from front to rear, and the average length of the strands in the fifth and sixth groups is less than the average length of strands in the third and fourth groups. 
     Also in one embodiment the lure further comprises a seventh and eighth group of buoyant flexible strands joined to the body at opposite points on the left and right sides of the body rearward of the joining points of the fifth and sixth groups of flexible strands, wherein the flexible strands in each of the seventh and eighth groups extend outward from the body on each side, such that with the body floating with the long axis parallel to the water surface, some of the seventh and eighth strands angle forward, some are substantially at a right angle to the long axis, and some angle rearward, and length of the seventh and eighth strands extending from the body are progressively shorter from front to rear, and the average length of the strands in the seventh and eighth groups is less than the average length of strands in the fifth and sixth groups. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWING FIGURES 
         FIG. 1  is an elevation view of a fishing lure according to an embodiment of the present invention. 
         FIG. 2  is a top view of the fishing lure of  FIG. 1 . 
         FIG. 3  is a section view of the fishing lure of  FIG. 1  viewed along the section line AA in  FIG. 1  according to an embodiment of the present invention. 
         FIG. 4  is an elevation view of the fishing lure according to a further embodiment of the present invention. 
         FIG. 5  is an overhead view of the fishing lure of  FIG. 1  depicting motion on the surface of water. 
         FIG. 6  is a process flow chart illustrating steps for fishing the lure of  FIG. 1 . 
         FIG. 7  is a top view of a fishing lure with a right-side profile of the lure body according to another embodiment of the present invention. 
         FIG. 8  is a bottom view of the fishing lure of  FIG. 7  with a left-side profile of the lure body. 
         FIG. 9  is a plan view of the lure body of the fishing lure of  FIG. 7  showing a hook adapted to increase the unobstructed strike length of the lure according to an embodiment of the present invention. 
         FIG. 10A  is a perspective view of the hook of  FIG. 9 . 
         FIG. 10B  is a perspective view of a cam configuration hook. 
         FIG. 11  is a plan view of the lure body of the fishing lure of  FIG. 7  showing a straight shank treble hook implementation. 
         FIG. 12  is a perspective view of a single shank hook of the same design as the hook of  FIG. 9 . 
     
    
    
     DETAILED DESCRIPTION 
     The inventor provides a fishing lure adapted in a preferred embodiment to imitate a bird, and that allows for snag-less operation in heavy cover fishing and more presentation time in a desired strike zone. The present invention is described in enabling detail using following examples, which may describe more than one relevant embodiment falling within the scope of the present invention. 
       FIG. 1  is an elevation view of a fishing lure  100  according to an embodiment of the present invention. Fishing lure  100  is adapted in this example to imitate a live bird that has fallen in water. However the example of a bird imitation should not be construed as a limitation of the invention. Other characterizations for lure  100  are possible and may be considered according to one or more embodiments of the present invention. The inventor chooses to represent a bird in a preferred embodiment because of its position as a natural prey for certain predator species of game fish. In one embodiment of the invention, a dragonfly, bat, mosquito or any other flying prey which a fish eats may be imitated without departing from the spirit and scope of the present invention. 
     Fishing lure  100  includes a cylindrical body  101  having a conical front end and a rounded rear end. Body  101  may be injection molded from a flexible but resilient rubber or polymer-based compound or composite like Neoprene, Polyvinyl Chloride (PVC) based material, or a similar composite. Body  101  in one embodiment is molded in the form of a bird body wherein the conical end represents the bird&#39;s beak and the rounded end, the bird&#39;s rear parts. In one embodiment, the molding process used is a Rotoblast™ process used in rotational molding known to and available to the inventor. 
     In a preferred embodiment, body  101  is a hollow body whereby certain portions are reinforced by allowing greater material thickness to form in the specified areas. In one embodiment, thickening the mold materials immediately around the conical shape that represents the bird&#39;s beak reinforces the conical end of cylindrical body  101 . Body  101  may also be reinforced in other areas supporting various features of the lure. In one embodiment, cylindrical body  101  is a solid body (not hollow). In this embodiment, the body might be formed of a porous buoyant material such as foam that cures and can be used in a molding process as an injection molding material. 
     In one embodiment, Body  101  is textured on the outer surface  108  of body  101 . Texturing  108  may be achieved in part by indentations and or protrusions made in the surface of the mold cavity used to form body  101 . In one embodiment, the material used to mold body  101  is impregnated with fibrous polymer or other heat resistant fibrous materials to improve resiliency and to simulate texture such as bird feathers or down. In this example, fishing lure  100  includes a pair of bird&#39;s eyes  109 . Bird&#39;s eyes  109  may include eyelids and a false eyeball. These features may be molded into the body or applied after the body is molded without departing from the spirit and scope of the present invention. In one embodiment, lure body  101  includes colored sections and or patterns that mimic a bird&#39;s variation in natural color pattern. One such section is illustrated herein by under section  104  representing the bird&#39;s typically lighter underside. Stripes, bars, and other colored sections may also be incorporated to mimic natural color variations in a bird without departing from the spirit and scope of the present invention. 
     In a preferred embodiment, lure  100  floats indefinitely and buoyancy is controlled along cylindrical body  101  in the molding process to provide substantially equal buoyancy at both the conical and rear ends of body  101  so that the lure does not list while afloat and so that it moves laterally across the water when pulled without diving beneath or rising up out of the water. Equilateral buoyancy across the length of body  101  is accomplished through an empirical method of calculating weights of various features of the lure and hook assembly and refining the mold cavity to enable appropriate distribution of materials accordingly, so that air pockets residing within the lure body in the hollow embodiment are sized to result in the equilateral buoyancy. 
     Fishing lure  100  includes, in this example, a pair of bird wings  105  (one each side) and a bird tail  106 . Bird wings  105  are characterized by one or more grouping of flexible, yet resilient strands of rubber or similar buoyant material. In this example, there are four groupings of strands on each side of lure body  101 . Each grouping of strands is held to a unique protrusion length from the lure body so that simulation of an outstretched wing is achieved when the lure is floating on water. 
     In one example, the strands are annular and hollow to aid buoyancy. In another example, the strands are rectangular and hollow to aid buoyancy. In a preferred embodiment, each strand is geometrically similar to other strands in the grouping; however geometric mixes may be used without departing from the spirit and scope of the present invention. Tail  106  in one embodiment is a single grouping of flexible but resilient strands that may be of the same likeness including geometry as those making up wings  105 . In this view, the hook assembly is not entirely visible and is described in more detail later in this specification relative to  FIG. 3  in section view. However, the assembly includes at least one hook  107  and eyelet  103  adapted to accept fishing line. Further the tail  106  could be comprised of yarn, string, feathers, or any other synthetic material that floats and is formulated to be flexible and rigid enough to return to the original shape. 
     In this elevation view, wings  105  and tail  106  are flexible enough to hang down when lure  100  is not floating on water, but resilient enough to assume a lateral position when the lure is floating on water. The weights of wings  105  are held consistent on either side of lure body  101  to prevent listing and to prevent any unwanted drift during casting or pitching into heavy cover, which requires considerable accuracy. The flexibility of the wing strands is controlled such that the strands will form close to the lure body during casting, eliminating drag from the wings. The wings could be comprised of yarn, string, feathers, or any other synthetic material that floats and is formulated to be flexible and rigid enough to return to the original shape. 
       FIG. 2  is a top view of fishing lure  100  of  FIG. 1 . Fishing lure  100  is viewed from overhead in this example and outstretched wings  105  and tail  106  are illustrated in at rest position as if the lure body were floating on a body of water. Tail  106  fans out and is buoyant simulating a V-shape bird&#39;s tail. Wings  105  fan out and are buoyant simulating outstretched bird wings. The overall lengths of each grouping of strands are ordered in such a manner that grouping of strands provide the silhouette of outstretched wings in a realistic manner. 
     Cylindrical body  101  includes hook recesses  200  formed into the body during the molding process. Recesses  200  are symmetrically disposed on top of and toward the rear of lure body  101  and are adapted to conceal hook points  201  of hook  107 . In this example, hook  107  is a double hook featuring two hook points  201  requiring two recesses  200 . Hook points  201  may be barbed or barbless. In an embodiment where hook points  201  are barbed the barbs may reside on the outside of the hook bend or on the inside of the hook bend. 
     In a preferred embodiment, the hook bends of the double hook protrude from the underside of the cylindrical body near the rear thereof, the bends substantially conforming about the rear end of the cylindrical body toward the upper surface, the hook points thereof pointing toward the front of the cylindrical body and resting in recesses provided in the upper surface of the cylindrical body 
     In another example, hook  107  may be a single hook with one hook point and one recess disposed centrally on top of body  101 . The resiliency of lure body  101  is such that it is stiff enough to prevent exposure of the hook points from recesses  200  unless suitable force from a striking fish is applied. In this way, hook point exposure is greatly reduced during lure movement and retrieval from typical soft-body imitations that float or sink. In one embodiment, wire or stiff fiber snag guards may be incorporated into the hook design, however such apparatus may reduce the potential number of hook-ups with fish while using lure  100 . 
       FIG. 3  is a section view of fishing lure  100  of  FIG. 1  viewed along the section line AA in  FIG. 1  according to an embodiment of the present invention. Lure  100  includes a hook assembly as mentioned further above and that is visible in this sectioned overhead view. The hook assembly includes a shank  300  with a gapped eyelet  301  disposed at the rear of the shank. Eyelet  103  is disposed at the end opposite eyelet  301 . Shank  300  connects to hook  107  at a hook eyelet  302 . 
     In this example, hook  107  exits or protrudes from lure body  101  at a general egress area  303  on the bottom surface of the lure body forward from tail feature  106 . The hook bends and points are cut off in this sectioned view and are not visible in this view. The portions of hook  107  that are on the outside of lure body  101  are illustrated with a broken boundary. In this example, hook  107  and shank  300  form a jointed hook assembly that may be inserted or assembled into lure body  101  after the molding process. Egress area  303  may or may not be reinforced with thicker material during the molding process. Reinforcement for specific areas of lure body  101  may be provided in ways other than thickening the material at the targeted area. Other ways to reinforce portions of the cylindrical body include adding reinforcing materials to the lure after the molding process using glue or other attachment methods. 
     Wings  105  are disposed transversely through openings in the walls of lure body  105  and are secured in place by knots  304  tied in the individual groupings of flexible strands. In this example the strands are grouped into eight groupings. Knots  304  serve as stops preventing unintended pullout of the wing components from the lure body, thereby reinforcing the wing feature of lure  100 . The openings within the lure body are kept much smaller than the diameter of the knots, but can stretch according to material properties to accommodate the knots when the lure is assembled. 
     In one embodiment, wings  105  may further be secured by knots tied into the strand groupings that are strategically disposed to abut against the outer surface of the bird lure as an extra positioning measure to prevent wings  105  from encroaching into the interior of body  101  in the hollow embodiment. In one embodiment, wings  105  are contiguous with wing tips formed at both ends of a grouping of strands. In this embodiment, the strands are disposed contiguously through the lure body, each single strand forming two opposing wing tips. 
     Tail  106  is secured to body  101  via a knot  305  disposed strategically near one end of the tail strands. An opening is provided through body  101  where tail  106  is installed, the opening held much smaller than the knot but able to accommodate insertion of the knot through the wall of the body via the stretch property of the lure body. Once the knot is inserted, the opening encloses around the knot preventing pull out of the tail feature. In a preferred embodiment, wings  105  do not connect through the cylindrical body, and are installed in similar fashion as tail  106 . In this embodiment, there may also be knots disposed externally to the lure body to prevent the wing from encroaching into the interior of the lure body. 
     Section line AA of  FIG. 1  may generally represent a water line when lure  100  is floating. It is important to note herein that in a preferred embodiment, there are no protrusions or openings on the lure body that sit at or above the waterline when the lure is floating. In this way, the lure retains trapped air and floats indefinitely. 
       FIG. 4  is an elevation view of fishing lure  100  according to a further embodiment of the present invention. In this example, fishing lure  100  further includes a feature  401  that simulates bird legs. Bird legs  401  may be fashioned with stiff fibers grouped and tied for insertion through the underside of cylindrical body  101 . In other embodiments, other simulation methods may be employed to simulate bird legs and feet. In one embodiment, bird legs are simply painted, drawn, or otherwise depicted on the outer surface of body  101  at an area on the underside of lure  100  where it would be expected to see bird legs. 
       FIG. 5  is an overhead view of fishing lure  100  of  FIG. 1  depicting motion on the surface of water. Fishing lure  100  may float in one position on a body of water for an indefinite period once cast or pitched into a target strike zone. The silhouette of wings  105  provides an underwater view of outstretched wings. Similarly, tail  106  provides an underwater view of an outstretched bird tail fanned out in the water. 
     A slight twitch of fishing lure  100  while at rest on water produces a flux in wings  105  simulating that the bird is alive, but incapacitated and unable to fly or escape. Another feature of operation of lure  100  is that when a fisherman pulls or “twitches” fishing lure  100  forward by a pull in the direction of the arrow labeled pull, wings  105  flex rearward with the force of the pull as illustrated by the broken directional arrows immediately behind wings  105 . The wings resume their original position in the water when the pull force is terminated followed by slack in the fishing line, creating a drag force represented herein by a directional arrow labeled drag. This motion follows the principal that for every action there is an equal and opposite reaction. The drag created by the resiliency of the flexible strands of the wings helps to keep fishing lure  100  in the same general location of the original targeted strike zone that the lure was tossed into on the first cast. In this way, the lure may be fished extensively in heavy cover with a provision of more time in the strike zone. 
     Retrieval of fishing lure  100  may be necessary only to redeploy the lure to another possible strike zone identified in heavy cover. Another feature enabled by the flexibility of wings  105  is further protection against snags during lure retrieval. Lure retrieval induces a rearward flex in wings  105  in the direction of the broken arrows. While wings  105  are in a rearward flexed position, they provide further “weed” guard against snagging the lure against floating debris or grounded cover. This same flexibility also offers a straight and unwavering pitch or cast of lure  100  into a strike zone. 
       FIG. 6  is a process flow chart  600  illustrating steps for fishing lure  100  of  FIG. 1 . At step  601 , a fisherman ties the fishing lure analogous to lure  100  of  FIG. 1  to a fishing line. In one embodiment, the fishing line is connected to a fishing reel on a fishing rod. In an alternate embodiment, the fishing line may be connected to a still fishing cane pole. At step  602 , the lure is cast or pitched into a target strike zone. A strike zone may be a hole in a blanket of lily pads or a spot of water under a shade tree where the fisherman expects a strike is possible. 
     At step  603 , the fisherman attempts to elicit a strike by twitching the lure in place. This is done to simulate a bird that has fallen into the water. At step  604 , the fisherman pauses to provide a window for a strike that might result from the twitching action. At step  605 , the fisherman makes a determination of whether there has been a strike on the lure. 
     At step  605 , if a strike is detected, the fisherman sets the hook at step  606  and reels in the fish. The process may then resolve back to step  602  where the fisherman casts or pitches the lure into another targeted strike zone, typically along heavy cover. If the fisherman does not detect a strike at step  605 , the process resolves back to step  603  where the fisherman resumes twitching the lure. Step  603  and step  604  may be repeated in succession many times before the fisherman ultimately catches a fish decides to retrieve the lure for another cast. 
       FIG. 7  is a top view of a fishing lure  700  with a right-side profile of the lure body according to another embodiment of the present invention.  FIG. 8  is a bottom view of fishing lure  700  of  FIG. 7  with a left-side profile of the lure body. Referring now to  FIG. 7 , fishing lure  700  is adapted to imitate a bird as described further above with respect to fishing lure  100 . In this example, the wings and tail are represented by broken boundaries in the general displayed shapes of those appendages while the lure is floating on a body of water. 
     Lure  700  includes a buoyant lure body  701  that may be manufactured in the same fashion as described for lure  100 . In this example however, lure body  701  is formed in a symmetrical manner with respect to the molding process in such a way as to provide the same body profile for the top, bottom and side views of the lure. In this top view, the eyes are visible. Also in this example, lure  700  includes a hook  801 . Hook  801  is a single wire hook formed about the eye with equal lengths of remaining wire to form the rest of the hook. In this view (top) the hook points are visible. A representative right side view of lure  700  (reduced in size to save drawing space) is depicted to communicate that the profile of the side of the lure is identical in shape to the profile of the top of the lure. 
     Referring now to  FIG. 8 , the bottom view of lure  700  is depicted. As described further above, the wings and tail are represented by broken boundaries in the general shape of those appendages when the lure is floating on a body of water. Body  701  as seen from underneath the lure has an identical profile as the top of the lure. Hook  801  is visible at the split and bends of the hook. The eyes are not visible and are represented here by broken boundaries. In one embodiment, the eyes may be placed both on the top of lure  700  and on the bottom of lure  700  so that there are two pairs of eyes symmetrically opposed. A representative left side view of lure  700  (reduced in size to save drawing space) is depicted to communicate that the profile of the left side of the lure (upside down) is identical in shape to the profile of the bottom, top, and right side profile of the lure. Maintaining a consistent symmetry with respect to shape at  360  degree views about the lure body orientation provides the same view to a predator fish regardless of how the lure lands in a body of water when cast. 
       FIG. 9  is an elevation view of lure body  701  of the fishing lure of  FIG. 7  depicting hook  801  adapted to increase the unobstructed strike length of the lure according to an embodiment of the present invention. Lure body  701  is seen in right side elevation in this example. The shape profile of body  701  is consistent regardless of view angle. Hook  801  is a double hook in this example. Hook  801  may be manufactured of suitable wire available in hook manufacturing. Hook  801  may be formed using hand operated tools such as a jig and press. Hook  801  is made of a single length of contiguous hook wire formed about a dowel to make the hook eye with relatively equal lengths of the wire reserved for forming the hook shank, bends, and points. 
     In this example, hook  801  (side profile) has a bend  802  located at or about the eye of fishing lure  701  when properly positioned therein. Bend  802  follows a relative straight portion from the hook eye and progresses downward toward the bottom inside surface of lure body  701 , the bend beginning just past the bird eye in this example. 
     The purpose of bending the hook closer to the hook eye is to allow the contoured portion of the hook to lie along the natural contour of the bottom inside surface of the lure body and anterior portion of lure body  701 . This unique adaptation enables a much longer unobstructed strike space for a predator fish to bite down on the soft body without being obstructed by any part of the hook including the hook shank. The estimated obstruction free bite or strike length is dimension A and is roughly measured from the hook points out to a point along the hook shank behind bend  802  where it may be considered that a bite at the stated point might be obstructed by the fish contacting the hook shank behind the bend before being hooked. The maximum hook gap B becomes gradually less along length A to the point where the probability of inconsistent hookup because of a smaller hook gap increases significantly. Additionally it is known to the inventor that if a large bass or other predator fish bites and feels the hard material of the hook shank the bass will typically spit the lure out. The bending of the lure shank to follow the contour of the bottom of the lure significantly increases the sweet spot bite area of the lure. 
       FIG. 10A  is a perspective view of the hook of  FIG. 9 . Hook  801  is fashioned from a single contiguous piece of hook wire. Bend  802  significantly lengthens the strike distance represented above by distance A where the hook gap is still large enough to provide consistent hookup. Hook  801  may be formed about pin, dowel, or any other method of hook manufacture, forming hook eye  803 . The wire is bent around the eye and directed downward adjacently toward the split in hook  801  that forms the adjacent hook bends  804 . To keep the hook from separating, the wire may be brazed together along the shank. 
       FIG. 10B  is a perspective view of a cam action hook. In this embodiment when eyelet  903  is pulled, interconnecting member  901  causes movement through the connections in the hook which causes hook points  902  to move in an upward direction because of the bend in member  901 . In this embodiment the movement of the hook points in an upward direction when pulled increases the likelihood of hooking a fish. 
     The contour of the hook past bend  802  is adapted to conform significantly to the contour of the lure body until the hook egresses the body of the lure where the hook tangs arc about the rear portion of the lure body, the hook points facing forward and protected, in some embodiments, by recesses formed in the soft lure body. In one embodiment where recesses are provided to protect the hook from hook point exposure, the recesses are the only feature, except perhaps the bird eyes and coloring or markings, if any, that distinguishes the top of the lure from the bottom of the lure. 
       FIG. 11  is a plan view of lure body  700  of  FIG. 7  showing a straight-shank treble hook implementation. In this view, lure body  700  hosts a treble hook  1101  having a straight shank. 
       FIG. 12  is a perspective view of a single shank hook  1201  in the same design as double-shank hook  801  of  FIG. 9 . Hook  1201  has the same shape of hook  801  but is a single hook implementation. When implemented in the lure body, the hook may face up with the barb out of water, or down with the barb under the water line. 
     It will be apparent to one with skill in the art that the fishing lure and method of the invention may be provided using some or all of the mentioned features and components without departing from the spirit and scope of the present invention. It will also be apparent to the skilled artisan that the embodiments described above are specific examples of a single broader invention that may have greater scope than any of the singular descriptions taught. There may be many alterations made in the descriptions without departing from the spirit and scope of the present invention.