Background Art Swordfish are primarily night feeders and leader lines, strung from long line fishing rigs, usually include some type of light, a bait such as squid and a hook. The typical longliner fisherman may use as many as 1200 lights per set or main line. A good example of the first type of lure used was to simply drop a battery light inside a sealed glass jar. Later, the favored art evolved into the use of a plastic incandescent light manufactured in Japan. It consisted of a clear two piece acrylic design, threaded or snapped together, containing a single 1.5 volt AA battery with a flashlight bulb mounted inside the top. Known as the Japanese light, when the top was screwed into the base the battery made contact activating the light thus becoming the on/off switch. A single 0-ring seal was used between the two halves to form a watertight seal when the light was activated. While this type of light was popular, it encountered several problems while in service. One of the first problems was the cost of replacement batteries. Due to the electric current draw of the incandescent bulb, battery life would only prove to be adequate for one night's use. Another problem was that while the 0-ring seal was effective once the light was activated, as soon as it was turned off pressure against the ring was released thereby allowing water and moisture to enter the light. The constant maintenance, replacement of batteries, and the ongoing need to ensure good electrical contacts made for an unreliable and labor-intensive product. These problems, along with the competition created by the expiration of patents for chemical lights, slowly eliminated the use of battery lights.

As fishermen experimented with other light sources, it was discovered that chemical lights proved effective when placed just above the bait. Chemical lights are described in the following patents: U. S. Patent No. 3,576,987 by Voight et al.; U. S. Patent No. 5,067,05 lby Ledyjensky; and U. S. Patent No. 5,213,405 by Giglia.

U. S. Patent No. 5,070,437 to Roberts discloses an LED light that is activated by flexing the lead of the LED to engage the battery and activate the light. It includes a threaded cap with an O- ring to seal water out and allow for the replacement of batteries. Since the Roberts'437 light only omits light directed forward of the battery compartment, it offers a very narrow light emission viewing angle from the LED itself. Light is emitted from the front end of the cap in a forward directed beam.

U. S. Patent No. 5,076,003 to Chen discloses a light device for an artificial fishing lure. The Chen'003 patent disclosure describes an LED mounted in a transparent tube having a reflector mounted opposite the LED in the tube. The battery is located behind the LED and hence does not reflect light emitted by the LED. Notches are formed in the transparent tube which refract LED light traveling through the tube. A reflector placed opposite the LED in the tube reflects light from the LED.

U. S. Patent No. 5,299,107 to Ratcliffe discloses an illuminating fishing lure having a non- transparent and light blocking rear housing. U. S. Patent No. 5,915,941 to Casey discloses a lighted fishing bobber which emits light only through a light pipe at the top end of the bobber. U. S. Patent No. 5,983,553 to Gordon discloses a lighted fishing lure having a generally cylindrical shape which emits light beams perpendicular to the axial center line of the lure but does not emit light forward and aft of the lure along the center line.

Disclosure of the Invention The present invention provides an underwater battery powered lighted fishing lure and a method therefor. The present invention, in one embodiment, also provides a lighted fishing lure that emits light, 360 degrees and in all three directions, along its x axis, y axis and z axis. Additionally in another embodiment, the present invention provides a lighted fishing lure which reflects, refracts and defuses light in order to emit light in all directions.

The underwater battery powered lighted fishing lure includes, in one embodiment, a transparent housing having at least one battery cavity and at least one light emitting device cavity, a battery disposed in the battery cavity and a light emitting device disposed in the device cavity.

Preferably, the light emitting device is an LED (light emitting diode). The battery in this embodiment has a substantially light reflective surface. An electrical circuit couples the battery and the LED. The transparent housing has light refraction surfaces therein and one or more light modifiers from the group of light diffusing optical elements dispersed in said housing and light reflecting material dispersed in the housing. As a result, the lighted fishing lure emits light in all three dimensions (x, y and z) due to light refraction, light reflection from at least the battery and light dispersion caused by one of the diffusing elements or reflecting material dispersed throughout the housing. Other embodiments include a battery with or without light reflective surface, light diffusing elements in the form of beads, rods or fibers (preferably glass) and light reflecting material such as glitter. The light diffracting elements may be bubbles or voids in the housing. The glass elements or voids have a different index of refraction as compared with the index of refraction of the transparent housing. Preferably, the lighted fishing lure includes two LEDs and two batteries which are all disposed at offset positions with respect to an axial centerline through the generally frusto-conical shape or generally cylindrical shape of the housing. The lighted fishing lure may further include a pressure sensitive switch. In a working embodiment, the lure has a three way or tri-modal control which enables the LED to be turned ON in one mode, OFF in a second mode and in a third mode, placed in a pressure sensitive switch condition such that the LED is turned ON when the ambient pressure exceeds a predetermined underwater pressure.

Brief Description of the Drawings FIG. 1 diagrammatically illustrates the underwater battery powered lighted fishing lure; FIG. 2 diagrammatically illustrates a partial, exploded view of the underwater battery powered fishing lure with the batteries extracted from one of the two body parts forming the housing; FIG. 3 diagrammatically illustrates a partial, exploded view of primary components of one embodiment of the lighted fishing lure; FIG. 4A diagrammatically illustrates a side view of the outside of one body part (the main body) forming the housing and FIG. 4B diagrammatically illustrates another cam control system; FIG. 5 diagrammatically illustrates the side arm of the other body part (the top) of the housing and shows a cam actuator member or finger; FIG. 6 diagrammatically illustrates an internal end view of the top body part of the housing; FIG. 7A diagrammatically illustrates a partial, cross-sectional view of the top body part; FIGS. 7B and 7C diagrammatically show switch pin cam follower positions on cam surfaces (plan views of arcuate cam surfaces which generally correspond to FIGS. 4A and 4B, respectively); FIG. 8 diagrammatically illustrates an internal end view of the FIG. 7 top body part; FIG. 9 diagrammatically illustrates a basic electrical schematic for a simple lighted fishing lure (one LED, a battery and two switches); FIG. 10 diagrammatically illustrates an electrical schematic for a lighted fishing lure having two LEDs wherein each LED has a different color; FIG. 11 diagrammatically illustrates a very simplistic representation of light refraction from the LED through the LED cavity, the battery cavity and the housing; FIGS. 12A, 12B, 12C and 12D diagrammatically illustrate reflection characteristics of the housing, a single LED and single battery, a single LED and a transversely disposed battery, and two LEDs and two batteries in accordance with the principles of the present invention; FIG. 13 diagrammatically illustrates light diffusion through the lighted fishing lure housing; FIGS. 14A and 14B diagrammatically illustrate dispersion of light with diffusing optical elements distributed in the housing and a simplistic light diffusion diagram, respectively; FIGS. 15A and 15B diagrammatically illustrate the use of light reflecting materials such as glitter dispersed through the housing and a simplified light diagram showing light reflection from the glitter; and, FIGS. 16A and 16B diagrammatically illustrate the emission of light 360 degrees in the x, y and z axes (FIG. 16B) from the lighted fishing lure.

Detailed Description of Features of the Invention The present invention relates to an underwater battery powered lighted fishing lure and method therefor.

FIG. 1 diagrammatically illustrates lighted fishing lure 10 having a first body part 12 which is removably attached to a second body part 14. Body parts 12,14 are plastic and are preferably clear plastic for cost, clarity and strength. First body part 12 has an end face 16 with an axially protruding member 18. Axially protruding member 18 includes a hole 19 therethrough which enables lighted fishing lure 10 to be attached to a longline fishing line. Lure 10 is generally cylindrical or frusto-conical end shape. From the side view illustrated in FIG. 1, lure 10 is cylindrical in shape but when viewed from another side, fishing lure 12 is frusto-conical in shape.

See FIG. 11. Axial center line 21 is shown in FIG. 1. Second body part 14 includes an end face 22 and an axially extending member 24 with an eyelet 25 to enable attachment to a longline fishing line. Body part 12 can rotate with respect to body part 14 as shown by double headed arrow 23.

When body parts 12,14 are rotated to a release position or an OPEN (described later in connection with FIG. 4) and body part 14 is axially withdrawn from body part 12, access to batteries 26,27 is provided. Other battery shapes may be utilized. Cylindrical, AA alkaline batteries are preferably used in the lure. Alkaline, lithium, nickel cadmium and POLA PULSE batteries may be used. Battery weight and the minimization of air space was utilized as a means to increase the negative buoyancy of the light.

FIG. 2 diagrammatically illustrates a partial, exploded view of the light wherein body part 14 is withdrawn from body part 12 and batteries 26,27 have been removed from cavities 28, 29.

LEDs 30,32 extend into LED cavities 34,36 formed in body part 12. The base of each LED is shaped to conform to a particular cavity in body part 12 thereby ensuring that the operator correctly matches the polarity of batteries 26,27 and the circuitry (described later) leading to LEDs 30,32.

LED 32 has a squared base which fits within square cavity 36 and body part 12. LED 30 has a cylindrical base which fits into cylindrical cavity 34.

The lighted fishing lure utilizes a light emitting device which, in a preferred embodiment, is a light emitting diode or LED. LEDs were selected because those devices emit light based upon electrical excitement of their elements, are low voltage level devices, are highly efficient light generators and do not generate heat. Further, LEDs are highly durable when used in the very adverse conditions of the present fishing lure. The light emitting devices subject to the present invention are not incandescent devices or fluorescent devices or devices which include tungsten filaments. Similar numerals designate similar items throughout the figures. FIG. 3 diagrammatically illustrates an exploded view of the light showing major components or parts of the lighted fishing lure of the present invention. An 0-ring 40 is disposed on one end region 42 of body part 12. Particularly, 0-ring 40 is placed in groove 44 near end 42. The 0-ring creates a watertight seal between body part 14 and body part 12. This 0-ring always seals the lighted lure during ON, AUTO (pressure sensitive mode) and OFF control modes.

Batteries 26,27 are placed in cavities 28,29 such that opposing battery terminal ends are adjacent each other. Contact plate 44 is disposed at the internal end (not shown) of cavities 28,29.

Contact 44 connects the positive terminal of battery 27 (not shown) and the negative terminal of battery 26 (not shown) together.

Body part or cap 14 retains LED circuit board elements 45 which transfer electrical power from batteries 26,27 to LEDs 30,32. This circuit includes an insulated base 46, battery terminal members 48,50 and circuit connectors 52,54. Battery terminal members 48,50 are placed on end regions 49,51 of plate base 46. Terminals 48,50 include U-shaped spring members which contact battery terminals 27a, 26a of batteries 26,27. These U-shaped spring terminals are diagrammatically illustrated as disposed in cap or body part 14 in FIG. 2.

Insulating platform 46 is spring loaded in the interior of cap 14 via coil spring 60. Coil spring 60 rides on post 62 extending above platform 46. Loosely retained pins 64,66 are mounted in through passages 68, 69 which limit the side to side or rocking movement of floating platform 46. Conductive elements 52,54 close the electrical circuit formed by batteries 26,27, conductive plate 44, battery terminals 48,50, conductive plates 52,54 and the electrical leads (one of which is lead 31) extending from LEDs 30,32 when the system is ON. Body part 12 includes cavities 70, 72 which hold hydrogen absorbing pellets. In a preferred embodiment, hydrogen absorbing pellets known as"getters,"are placed in cavities 70,72.

FIG. 4A diagrammatically illustrates body part 12 having plurality of cam surfaces thereon.

FIG. 5 illustrates side arm 80 having a cam actuator surface or finger 82. FIG. 6 is an internal end view of body part or top 14 showing side arms 82,83. FIG. 4B shows a different exterior cam system with AUTO or pressure sensitive switch region at flat land 89a, OFF at flat land 91 a and ON at the intermediate raised land 92 and end stop 94.

In order to place the body part 14 on main body part 12, side arm 80 and particularly cam actuator finger or surface 82 must be axially aligned with flat land area 84 (FIG. 4A) on the generally cylindrical end region 86 of main body part 12. By axially aligning side arm 80 and particularly cam actuator finger 82 with flat land 84 and axially moving body part 14 in the direction shown by arrow 87 in FIG. 4A, the axially alignment of cam actuator finger 82 and flat land 84 enables top body part 14 to be axially mounted onto main body part 12.

Body part 12 has slightly raised lands 88,90,92. Extreme rotational movement in the direction shown by arrow 85 is prohibited due to radially extending stop 94. A flat lands 89 and 91 are established between slightly raised lands 88,90 and 92. Cam actuator finger 82 (FIG. 5) is adapted to move over slightly raised lands 88,90 and 92 but the finger is configured to stop at rotational stop 94. In this manner, the operator by rotating body part or cap 14 with respect to main body 12, feels tactile responses when cam actuator finger 82 is located in flat land 89, intermediate raised lands 88 and 90, then enables a tactile response when cap 14 is rotated with respect to body 12 and cam actuator finger 82 passes over raised land 90 into flat land 91. Thereafter, the operator feels or obtains a tactile response by rotation of finger 82 over slightly raised land 92.

When finger 82 is in flat land 89, the lighted fishing lure is OFF. When finger 82 is in flat land 91, fishing lure is entering its AUTO or pressure sensitive control mode. When finger 82 is placed on slightly raised land 92, cap 14 is axially compressed and drawn to main body part 12.

This reduces the axial length of the battery chambers or cavities and rotates pin 64 (FIGS. 7A and 7B) from low cam surface 59 to intermediate cam surface 61. In an OFF position, the batteries "shake"or are loosely retained in the cavities and do not simultaneously contact upper contact 44 and battery terminals 48,50 because pins 64,66 (FIG. 7A) do not force contact plates 48, 50 into contact with the battery terminals. Therefore, there is no closed electrical circuit. However, when cam actuator finger 82 is placed on land 92, cap 14 and body part 12 are still permitted to axially compress thereby forming a pressure sensitive control surface or surfaces and establishing a pressure sensitive switch. Pins 64,66 are disposed on intermediate cam surfaces, e. g. pin 64 on surface 61 in FIG. 7B. The lighted fishing lure is designed such that, when the lure in the AUTO or pressure sensitive control mode, the system turns ON the LED or LEDs when the lure is approximately 10 feet or 3.0 m underwater. The pressure at this level compresses cap 14 and body part 12 together thereby reducing the axial size of battery cavities 28,29, causing the batteries to simultaneously contact upper and lower battery terminals due to pins 64,66 acting on contacts 48,50 and establishing a closed electrical circuit with the batteries, the LEDs, battery terminals 48,50 and conductor 44 when the water pressure exceeds the predetermined level. The lighted lure is constructed to withstand about 1,000 psi (about 2,300 feet below sea level).

Mechanically, a ridge or lip 96 (FIG. 4A) protrudes radially from main body part 12. A lower portion of rib 96 provides cam surfaces 97,98,99 which co-act with the cam actuator 82.

When cam actuator finger 82 is acting on cam surface 97, the fishing lure light is OFF. When cam actuator finger 82 is acting on axially sloped cam surface 98, the pressure sensitive switch of the fishing lure is set to AUTO and the LEDs are turned ON or OFF based upon the ambient pressure underwater. Rotation of cap 14 with respect to body 12 causes pins 64,66 to ride up o land 61 (FIG.

7B). In the third control mode (always ON), cam actuator finger 82 rides on cam surface 99 which establishes the maximum foreshortened position of top 14 with respect to body 12 and hence the maximum foreshortened position of the battery cavities 28,29 and pins 64,66 are raised by following cam surface 65 to their high up switch ON position. In this maximum foreshortened configuration and raised pin position, the LEDs are ON. The three way or tri-modal control of the lighted fishing lure is one of several important features of the present invention.

Another important feature of the present invention is to attach cap 14 onto body 12 in a bi- modal manner wherein, in the first mode when cam actuator finger 82 in is flat land 91 or raised land 92, the cap 14 is enabled to axially move with respect to body 12 based upon ambient pressure underwater. In a second mode of the removably attached, sealed, bi-modal configuration, axial movement of body part or cap 14 with respect to main body part 12 is prohibited. This mode is established when cam actuator finger 82 abuts and locks unto cam surface 99 which is axially inboard with respect to cam surface 97. When finger 82 abuts cam surface 99, no axial movement of cap 14 with respect to body 12 is permitted. As described above, in that second mechanical mode, the LEDs are ON. The cam actuator can be internal or external with respect to the housing.

Also, the cam surfaces can be disposed on part 12 or part 14.

FIG. 7A shows a partial, cross-sectional view of end cap 14 and the electrical circuit 45 of LEDs 30,32. Insulating platform 46 rides on spring 60 in the interior of cap 14. A spring loaded ride is caused by spring 60 loosely mounted on post 63 in the interior of cap 14 and post 62 depending from platform 46. A screw or other attachment 112 adjusts the degree of spring loading or float of platform 46. Platform 46 rotates on spring 60 due to keys 30a, 32b, and keyways 11 a and 13a in main body housing 12 (see FIG. 3). Loosely retained cam follower pins 64,66 are disposed axially beneath the U-shaped battery terminals 48,50 to ensure that when pins rotate over cam surface 67 (see FIG. 7B), the pins force contacts 48,50 upward to close the switch. Pins 64,66 are loosely retained in holes 68,69. See FIG. 3. The distal ends of floating pins 64,66 are slightly flared such that the pins rotate over arcuate cam surface 67 as the platform 46 rotates with respect to end cap 14 and surface 67.

An additional 0-ring 110 is disposed in an appropriate channel or groove in the internal end face of top 14. 0-ring 110 is compressed by edge 112 (See FIG. 2) of the main body part.

Accordingly, two watertight seals are provided for the lighted fishing lure. 0-ring 110 is primarily effective in the ON control mode when the pressure exceeds the predetermined level underwater or when the system is manually turned ON.

FIG. 8 diagrammatically illustrates an interior end view of top cap 14, battery terminals 48, 50 and LEDs 30, 32. The radial, outboard flare or U-shape of terminals 48,50 is shown. Bases 30a, 32a of the LED are keyed to internal keyways 1 la, 13a (FIG. 3) such that (i) platform 46 (FIGS. 7A and 8) is interlocked with main housing 12 (FIG. 3) in only one position; (ii) the electronic circuit is established in a singular manner (if two LEDs of different color are used, resistors are typically required to balance light output from the LEDs); and (iii) platform 46 rotates based upon rotation of housing 12 with respect to cap 14.

FIGS. 7A and 7B are plan representations of arcuate cam surfaces on interior surface 67 of end cap 14. As pin 64 rotates due to linkage between platform 46 and housing 12 (see key and keyway sets 30a-lla and 32a-13a), the pins 64,66 move over cam surface regions 59,61 and 65 which move pins 64,66 upward to strike contacts 48,50 and close the electrical circuit with batteries 26,27. At low level 59, the pin 64 does not force contact 48 into an electrical connection with the battery. The system is OFF. At intermediate cam surface 61, the pin 64 forces contact 48 to connect with the battery if pressure on the system compresses the battery cavity, foreshortens the cavity and closes the switch system. At high cam surface 65, the switch is closed due to pin 64 contacting element 48 and making an electrical connection. FIG. 7C shows the complementary switch cam surface with high cam surface 65 (ON), low cam surface 59 (OFF) and intermediate cam surface 61 (AUTO or pressure sensitive).

It should be noted that various switch cam systems may be utilized within the scope and spirit of the present invention. For example, cam surface may be defined on the outboard side or underside of contacts 48,50, the contacts could be arcuate and a cam actuator (e. g., rod) could be fixed on end cap 14 protruding from inboard surface 67 to the underside of contacts 48,50. The height of the cam surfaces on the underside of arcuate contacts 48,50 may determine switch control ON, OFF or AUTO. The key and keyways, e. g., 30a-l la, may be any shape, e. g., oval.

FIG. 9 diagrammatically illustrates an electrical schematic. The electrical components are mounted in a housing shown by dashed-dot-dashed line 120. Housing 120 seals the entire electrical system except pressure sensitive surface 122 associated with switch 124. Another switch, typically a manual switch 126, is a three position switch which turns the LED 128 ON (the system condition shown in FIG. 9) or enables the pressure sensitive switch 124 to control the LED (AUTO) or turns the system OFF. Battery 130 completes the electrical circuit. In a preferred embodiment, two batteries are utilized and two blue Nichia LEDs 30, 32 are utilized with no other resistive elements in the circuit. Green Nichia LEDs are also preferred. However, the system can be configured with a single LED 128 and a single battery 130. The system may include resistors to match the voltage to the LED. Other power conditioning circuit elements may be used. However, additional electrical components reduce power available to the LEDs.

The tri-state switch with ON, OFF and pressure sensitive ON states is an additional feature of the present invention. The pressure sensitive switch 124 must have a pressure sensitive control surface exposed to the ambient environment of housing 120. In a working embodiment, manual switch 126 is provided by the rotational movement of top 14 with respect to body 12 as described above in connection with FIGS. 4A, 5 and 6, among others. The pressure sensitive switch 124 is provided by cam actuator finger 82 placed on or near land 92 and axially inboard sloped cam surface 98 which enables the pressure in the ambient underwater environment to axially compress cap 14 with respect to body 12 and foreshorten battery cavities 28,29, and the switch cam system (in FIG.

7B) moves contacts 48,50 close to the batteries until batteries 26,27 make electrical contact with both conductor plate 44 and battery terminals 48,50. In the full ON position, the pins force contacts toward the batteries 26,27 such that the batteries make electrical contact with plate 44 and terminals 48,50.

FIG. 9 shows a simple electrical schematic with battery 130, three position switch 126, pressure sensitive switch 124 with pressure sensitive surface 122 and LED 128.

It should be noted that other types of switches may be utilized rather than the simple combined ON/OFF switch and pressure sensitive switch (AUTO) described in the current embodiment. Specifically, the OFF control may be completely eliminated such that the lighted lure only operates full ON and in the AUTO ON or pressure sensitive mode. A mechanical slide switch (properly sealed) could be placed on the housing 10 (FIG. 1) thereby providing the function of switch 126 in FIG. 9. Many pressure sensitive switches 124 can be utilized to enable the pressure sensitive control for LED 128. One example is a bladder actuated pressure switch. Singular or multiple LEDs may be incorporated into the present invention.

FIG. 10 is an electrical schematic showing battery 130, a three-way switch 132 and LEDs 134,136. Three way switch 132 represents the ON, AUTO and OFF switch. LED 136 emits alight of one color or frequency fi and LED 134 emits a different color light having a different frequency f2. A resistor 13 8 is disposed between LED 134 and 136 in order to reduce the voltage and equalize the light output from LED 136. A series of tests using different colored LEDs have established that different colored LEDs produce intensities of light. The intensity of light is measured as a Lux factor. Resistor 138 is required in order to somewhat equalize the light output of LED 136 as compared with LED 134. In a one preferred embodiment, two LEDs are utilized, each having the same color and hence frequency, and no resistors are utilized in the circuit. See FIG. 9. Market demands may require two lights of different color or other resistors.

A lighted fishing lure in accordance with one important principle and one embodiment of the present invention emits light with refraction, reflection and either diffusion or a multitude of reflection points in the housing.

FIG. 11 diagrammatically shows lighted fishing lure 12 having an LED 32 and batteries 26, 27. Housing 10, consisting of body 12 and body or cap 14 is clear plastic. However, body 12 has an LED cavity 140 which enables refraction of an LED light beam 142 at the interface between cavity 140 and the transparent plastic of body 12. Refraction occurs when light travels through two media each having a different index of refraction. When the light passes through battery cavity 28, the LED light beam 142 is again refracted at the cavity wall. When LED light beam 142 exits body 12, the beam is again refracted at the housing wall. Accordingly, the single illustrated beam 142 is refracted at points a, b and c in FIG. 11. Accordingly, the shape of lighted fishing lure 10 is designed to refract the multitude of generally forward directed light beams from LED 32. Hence, the frusto-conical shape of body 12 and the LED cavities and the battery cavities increase light refraction, among other things. Of course, there is a plurality of LED light beams in addition to light beam 142 emanating from LED 32 in FIG. 11.

FIG. 12A diagrammatically shows light reflection from battery 27. In this figure, LED 32 emits a light beam 150. Light beam 150 is reflected from battery 27 due to a light reflective surface on the battery. The light reflective surface is silver or mirror or mirrored film or white. Coating the battery cavity achieves the same result. That light beam after reflection from battery 27 ultimately exits body 12 as beam 150. LED 32 also emits a light beam 152 which is reflected off a different part of battery 27. In this sense, battery 27 acts as a convex mirror surface to achieve reflection of LED light from the lighted fishing lure 10. A reflective sleeve may be placed about the battery. The sleeve acts as a coating to reflect the light. The sleeve defines a reflective light surface of the battery as does a reflective coating over the battery cavity.

FIG. 12B shows LED 32 emitting reflected light beams 154,156 and 158. The reflected light is reflected 360 degrees except for the shadow of the battery opposite LED 32. FIG. 12C shows a battery 27 transversely disposed with respect to the LED and reflected light 153 and non- reflected light 151.

In FIG. 12D, LEDs 30, 32 emit light beams 162,164 and 166 (from LED 30) and beams 168,170 (from LED 32). In this manner, two LEDs and a single battery can generate reflective light in a substantially 360 degree manner about the lighted fishing lure housing. Although two batteries are shown in the preferred embodiment, a single battery may be sufficient. When the reflective principle is combined with the refraction shown in FIG. 11, light emission from all directions (to all three dimensions, the x axis, y axis and z axis) is achieved by the fishing lure of the present invention.

FIG. 13 shows LED 32 emitting light beam 172 that is diffused on six (6) different occasions by striking an element embedded in housing 12 or bubbles or voids formed in the housing.

Diffracted light beams h, i, j, k, 1, m are also generated by light beam 172. Diffraction occurs when a light beam travels from one medium having a certain index of refraction into another medium having a different index of refraction or it strikes a diffractive optical element. FIG. 14A shows a cross-section of housing 12 from the perspective of section line a'-a"in FIG. 13. A plurality of light diffusing optical elements, one of which is element 174 is disbursed throughout housing 12. In one embodiment, the housing has a first index of refraction and the light diffusing element has a second or different index of refraction.

Diffraction is caused by typically one, but possibly two or more of the following: glass beads ; glass fiber ; glass rods ; glass particles ; small amounts of translucent color (e. g., Ti02) ; and voids or bubbles in the housing (caused by blowing agents). Although the light diffusing bubble is not, in a purse sense, a structural member, the void or bubble is an optical element that diffuses light. The translucent color is also a light diffusing optical element.

FIG. 14B shows LED 32 emitting light ray 174. Light ray 174 strikes an interface between transparent housing body 12 and a light diffusing element 174. This light diffusing element splits the beam into sub-beams a and b. Beam a strikes another light diffusing element and splits into beams al, a2. Beam b strikes another light diffusing element and splits into beams b'and b2, In this manner, the diffusing element scatters or disburses the light in a multitude of directions.

FIG. 15A shows body 12 having plurality of light reflective optical material disbursed throughout. One light reflective optical material is material, particle or chip 180. In a preferred embodiment, material 180 is glitter. Glitter is a small element or discrete component having a reflective surface thereon (e. g. plastic or metal flakes). In FIG. 15B, LED 32 emits beams 182 and 184. Beam 182 is reflected by light reflective material or glitter 180 three times before it exits the housing. In contrast, LED light beam 184 proceeds directly through the housing without being reflected.

FIG. 16A shows lighted fishing lure 10 emitting light in substantially all directions, that is, forward and aft (see FIG. 16B, over the positive and negative x axis) and 360 degrees around central axis 21 (in the y axis and the z axis which fall in a plane perpendicular to the x axis). An important feature of the present invention is to refract, reflect and diffuse the light through the housing thereby causing the emission of light in all directions, forward, aft and 360 degrees about the lighted fishing lure.

Industrial Applicability The lighted fishing lure is used in the fishing industry.

The claims appended hereto are meant to cover modifications and changes within the scope and spirit of the present invention.

What is claimed is: