The present invention concerns apparatuses and systems for imparting vibrational movement to a bobble toy. More specifically, some embodiments of the present invention pertain to electromagnetically operated apparatuses and systems for vibrating a platform upon which a bobble toy rests.
Conventional bobble toys, such as bobblehead dolls, nodders, and wobblers, include two or more rigid portions which are operatively engaged to another with one or more springs. This permits a first rigid portion (e.g., a head) to move in relative independence from a second rigid portion (e.g., a body) such that an impact to the first body portion (e.g., a tap) will cause the second body portion to “bobble” or swing back and forth. Typical bobble toys have a base portion and a top portion, where the base has a flat surface for resting on a table or other supporting device and the top, operatively engaged to the base with a spring, is free to bobble when an impact force is applied to the base or top.
In some conventional applications, the base of a bobble toy may be mounted on an automobile dashboard causing the top of the toy to bobble when the car is in motion. In some other conventional applications, the base of a bobble toy may be placed on a stationary surface and a user may impart an impact force to the top of the bobble toy causing the top of the toy to exhibit pendulum motion.
Some conventional bobble toys further include mechanical means for applying an impact force to one of the rigid body portions, giving the toy the appearance of autonomous movement. There also exist some conventional mechanical devices having a vibrating table upon which the bobble toy can be placed. The conventional mechanical devices can be placed on a solid surface and activated, permitting the bobble toy to be operated without interaction from the user. However, conventional approaches utilize motors, gears, actuators, pendulums, and similar mechanical devices which require a physical connection between the motion imparting means (such as a motor) and the rigid body portion of the bobble toy and/or the vibrating table. Such conventional approaches suffer from mechanical or contact wear and tear. Noise, caused by the mechanical implements, may also be present when using such devices. In addition the range of movement that can be imparted to the bobble toy is limited by the specific mechanical construction (i.e., it can move front to back, side to side, or up and down), and customization of the movement is not possible.
It is therefore desirable for apparatuses and systems for imparting motion to a bobble toy which are contactless and programmable.
Several embodiments of the present invention relate to electromagnetically operated apparatuses and systems for vibrating a platform upon which a bobble toy rests. More specifically, disclosed are devices which include one or more electromagnetic devices each for imparting magnetic attractive and repulsive force on a platform upon which the bobble toy may rest.
In some aspects, the invention concerns a vibratory device for imparting motion to a bobble toy which may include a base having one or more base magnetic members therein; a platform for supporting the bobble toy having one or more platform magnetic member(s) engaged therewith; and one or more support spring(s) for supporting the platform. The platform magnetic members may be disposed adjacent to the at least one base magnetic member. The support springs may be between the base and a bottom surface of the platform.
In some embodiments, the base magnetic member(s) may include at least one electromagnet operable to displace the platform magnetic member(s). The platform magnetic member(s) may include a rare earth magnet, a permanent magnet, or a ferromagnetic material, or the platform magnetic member(s) may include at least one electromagnet. In some other embodiments, the base magnetic member(s) may include a rare earth magnet, a permanent magnet, or a ferromagnetic material, and the platform magnetic member(s) may include at least one electromagnet operable to displace the platform magnetic member(s).
In some embodiments, apparatuses can include at least two base magnetic members and at least two platform magnetic members. The base magnetic members and the platform magnetic members may be adjacent and/or aligned with one another.
In some embodiments, apparatuses can include control circuitry adapted to activate and deactivate the electromagnet(s). The control circuitry may activate and deactivate the electromagnet in one or more patterns. In some embodiments, a configuration device (for example, and without limitation, a button, switch, or dial) can be coupled to the control circuit. In some embodiments, a port (for example, and without limitation, a USB port or a wireless transceiver) can be coupled to the control circuit. In some implementations, an external stimuli sensor (for example, and without limitation, an audio sensor or a light sensor) can be coupled to the control circuit. The configuration device, port, and/or sensor may operate with the control circuitry to activate and deactivate the electromagnet, in some embodiments, according to one or more pattern(s).
In some embodiments, the bobble toy may be detatchably engaged to the platform. In some other embodiments, the bobble toy may include the platform (i.e., the platform may be integrally formed with the base of the bobble toy), and the platform magnetic member may be included in the bobble toy.
In some embodiments, apparatuses can include bearing(s) and/or spring(s) for supporting the platform. The bearing(s) and/or spring(s) may be between the base and a bottom surface of the platform. In some implementations, the bearing may be positioned in about the center of the base, and the spring(s) may be positioned at distal ends of the base. The bearing may be about equidistant from each of the base magnetic member(s) and about equidistant from each of the support spring(s).
In some aspects, the invention concerns a vibratory device for imparting motion to a bobble toy that may include: a platform for supporting the bobble toy; a base supporting the platform; a first plurality of magnetic members engaged with the platform; a second plurality of magnetic members in the base; a plurality of support springs supporting the platform; and a bearing for supporting the platform. The second plurality of magnetic members may include at least one electromagnet. First ends of the support springs may engage the base and second ends of the support springs may engage the platform. The bearing may be between the base and a bottom surface of the platform. The apparatus may include a fastener for securing the bobble toy to the platform. In some embodiments, each of the first plurality of magnetic members may be aligned with one of the second plurality of magnetic members.
In some embodiments, the bearing may be positioned in about the center of the base. The bearing may be about equidistant from each of the second plurality of magnetic members and may be about equidistant from each of the plurality of support springs.
In some embodiments, the apparatus may further include control circuitry adapted to selectively activate and deactivate the at least one electromagnet. One or more configuration device(s) (for example, and without limitation, a button, switch, or dial) may be coupled to the control circuitry for selecting a pattern in which the electromagnet(s) are selectively activated and deactivated. One or more speaker(s) may be coupled to the control circuitry, and the configuration device(s) may further select a pattern of sound emitted from the speaker(s). One or more light source(s) may be coupled to the control circuitry, and the configuration device(s) may further select a pattern of light emitted from the light source(s). The platform and/or the base may include openings, reflective materials, and/or translucent materials for reflecting or passing light emitted from the light source(s). In some embodiments, the apparatus can include one or more sensor(s) (for example, and without limitation, audio or light sensors) for detecting external stimuli that may be coupled to the control circuitry.
In some embodiments, the apparatus can include one or more port(s) (for example, and without limitation, a USB port or a wireless transceiver) coupled to the control circuitry. The port may provide electronic communication between the control circuitry and an external electronic device (for example, and without limitation, a computer, a mobile phone, or a remote control). The control circuitry may include a processor and a memory element. The memory element may store instructions for the processor to selectively activate and deactivate the electromagnet(s) according to at least one pattern.
In some aspects, a system for automating vibration of a bobble toy may include at least one vibratory device. Each vibratory device may include: a platform for supporting the bobble toy; a base supporting the platform; and control circuitry. In some embodiments, the platform may have a magnetic member engaged therewith, and the base may have an electromagnet therein. The electromagnet may be adjacent to the magnetic member of the platform. The control circuitry may selectively activate and deactivate the electromagnet to induce a pattern of vibration of the platform relative to the base.
In some embodiments, the vibration pattern of the platform may be selected from a plurality of vibration patterns by operation of a configuration device (for example, and without limitation, a button, switch, or dial) coupled to the control circuitry. In some embodiments, the vibration pattern of the platform may be selected from a plurality of vibration patterns through a port (for example, and without limitation, a USB port or a wireless transceiver) coupled to the control circuitry.
In some embodiments, a system can have two or more vibratory devices, and the control circuitry of a first vibratory device may be coupled to the control circuitry of the second vibratory device. In some implementations, the control circuitry of the first vibratory device may select a vibration pattern of the second vibratory device.
In some embodiments, the vibratory device may include one or more light source(s), and the control circuitry may activate and deactivate the light source(s) according to at least one pattern. In some embodiments, the vibratory device may include one or more speaker(s), and the control circuitry may activate and deactivate the speaker(s) according to at least one pattern. In some embodiments, the vibratory device may further include one or more sensor(s) (for example, and without limitation, audio sensors or light sensors) coupled to the control circuitry for detecting external stimuli.
These and other objects, advantages and features of the invention, together with the organization and manner of operation thereof, will become apparent from the following detailed description when taken in conjunction with the accompanying drawings, wherein like elements have like numerals throughout the several drawings described herein.
The invention, in its various aspects, will be explained in greater detail below. While the invention will be described in conjunction with several exemplary embodiments, the exemplary embodiments themselves do not limit the scope of the invention. Similarly, the exemplary illustrations in the accompanying drawings, where like elements have like numerals, do not limit the scope of the exemplary embodiments and/or invention. Rather the invention, as defined by the exemplary claims, may cover alternatives, modifications, and/or equivalents of the exemplary embodiments.
Referring generally to
The platform may be a rigid structure that rests horizontally over the base. For example, and without limiting the invention,
It is to be appreciated that platform 30 may have dimensions that are less than dimensions of the opening of base 20 in which platform 30 is positioned such that platform 30 is flushly mounted to base 20. In some implementations, there may be a void between outside peripheral edges of platform 30 and inside edges of base 20. As an example and without limiting the invention,
In some implementations, and without limitation, the base may have a square or rectangular shape (see, e.g., base 20 in
In some embodiments, the top surface of the platform may have features for securing the bobble toy. For example and without limiting the invention, the top surface of the platform may have gripping (for example, and without limitation gripping 39 on top surface 31 as shown in the illustration of
It is to be appreciated that, in accordance with some embodiments of the present invention, the vibration platform may move in relative independence from the base. For example, and without limitation, platform 30 may tilt side-to-side or front-to-back relative to base 20. In some other examples, platform 30 may rotate relative to base 20. In some embodiments, the vibratory device may include one or more controls or ports located on a top and/or side surface of the base. In some embodiments, the vibratory device may include wired, wireless, and optical communication ports for connection to computers, mobile phones, remote controls, other vibratory devices, optical and/or acoustical accessories, or other devices. For example, and without limitation, a vibratory device may include one or more USB ports, network ports, audio jacks, serial ports, parallel ports, transceivers for wireless data exchange over short distances using short wavelength radio transmissions (e.g., Bluetooth®), wireless local area network transceivers, and infrared ports. In some non-limiting implementations, the vibratory device may also include audio speakers, microphones, sensors, or display lighting.
It is to be appreciated that vibratory devices in accordance with several preferred embodiments of the present invention enable vibration that can be programmable, customizable, responsive to external input, and/or synchronized with other vibratory devices and accessories. In some embodiments, a multifunction button can cycle the vibration table through various patterns. As a non-limiting example,
In some embodiments, the vibratory device may be responsive to ambient sound or light. For example, and without limitation, the vibratory device may include a microphone or optical sensor for detecting sound, motion, and/or light and may cause the platform to vibrate in response thereto.
Vibratory devices in accordance with some embodiments of the present invention may also communicate with other nearby vibratory devices. For example, and without limitation, a plurality of vibratory devices can be placed near each other and may communicate with each other to synchronize pattern of platform vibrations and thus the bobble toy movement. In some non-limiting implementations, multiple vibratory devices can be physically and/or electrically connected to each other and/or a computer or remote device.
It is to be appreciated that any number of features of the vibratory devices in accordance with some embodiments of the present invention may be programmable. For example, and without limitation, a vibratory device can be programmed with a sequence of different lights, sounds, and vibratory patterns. The vibrational pattern of the platform may be synchronized with the pattern of lights and/or sounds emitted by the vibratory device. For example, and without limiting the invention, one or more electromagnets in a base of the vibratory device may be activated and/or deactivated by a control circuitry each time a light source is turned on by the control circuitry. In a further example, and without limitation, the control circuitry may activate one or more speakers to play a particular song or musical melody, and synchronize the vibration of the platform with the melody or another aspect or pattern of the song. In some other examples, a plurality of vibratory devices can be arranged in a line, and the group of vibratory devices can be programmed to exhibit chasing lights and synchronized vibratory patterns. In one non-limiting example, multiple vibratory devices can be arranged so that they appear to each be dancing in a group to a melody played through the speakers. It is to be appreciated that other variations of patterns and synchronizations are contemplated in accordance with some embodiments of the present invention.
It is to be appreciated that any number of features of vibratory devices in accordance with some embodiments of the present invention may be responsive to external stimuli, such as sounds, motion, and light. For example, and without limiting the invention, the vibratory device may include a motion sensor that initiates a vibrational pattern in the platform when nearby motion is detected. In another example, and without limiting the invention, the vibratory device may include a microphone or other sound sensor that can trigger the control circuitry to initiate vibration of the platform when it detects a specific ambient sound, such as a specific word (e.g., “go”) or the sound of hands clapping.
It is to be further appreciated that any number of features of vibratory devices in accordance with some embodiments of the present invention may include an alarm clock or timer feature as part of said control circuitry that can be set to activate the vibration of the platform at one or more set times. In such embodiments, speakers may be activated to emit music or other sounds (e.g., a buzzer), and/or light sources may activated to emit a light pattern with the vibrations of the platform in a synchronized manner at the one or more set times.
Referring now specifically to the non-limiting exemplary illustration of
Although the vibratory device illustrated in
In some non-limiting implementations, and as discussed herein, the magnetic members in the base and/or platform may comprise electromagnets, each of which may generate magnetic fields having magnitudes controlled by circuitry. The electromagnets may be activated in different patterns by a control circuitry to cause the platform and the bobble head thereon to undergo different patterns of motion. Additionally, the polarity of the electromagnets may be changed, allowing the bobble toy to be cyclically attracted and repelled by the electromagnets in the base. In such embodiments, each electromagnet may have positive and negative leads from a control circuitry on each side or end of the magnet through which current can be supplied in an alternating pattern. For example, and without limiting the invention, side to side motion may be induced in the platform 30 shown in
It is to be appreciated that various numbering and arrangements of magnetic members in the base and/or platform may enable vibratory devices having any number of rotational/vibrational axes, and in varying resolutions. In some embodiments, the base and the platform may have the same number of magnetic elements which are aligned with each other. For example, and without limitation, the base may include for magnets and the platform may include four corresponding magnets engaged therewith in a pattern similar to that of the base magnets (e.g., base 20 and platform 30 of
It is to be understood that other arrangements of magnets in both the base and the platform are included in the present invention. For example, and without limiting the invention, magnets may be arranged in rows, shapes (e.g., triangle, rectangle, oval, etc.). There may be differing numbers of magnets in the base of the vibratory device and the platform. Also, the arrangements of magnets in the base may be either aligned or offset with regard to the magnets in the platform. Furthermore, control circuitry may be operable to activate electromagnets in the base and/or the platform in various patterns, allowing the platform to move in various patterns, including vertical shaking, circular movements, swaying, tilting, popping, depressing, twisting, rotating, and various other motions.
The circuitry may comprise hardware and/or software and may be responsive to one or more inputs. For example, and without limitation, the vibratory device may include switch 53 (which in some implementations may be used to turn the vibratory device on and off), button 55 (which in some implementations may be used as a mode select or program button, e.g., to change a pattern of activating electromagnets in the base and/or platform, and a consequent vibrational pattern), and/or dial 57 (which in some implementations may be used to control the vibrational speed and/or intensity). The vibratory device may also have one or more power ports, for example and without limitation, power port 51. As discussed above, the vibratory devices may also include one or more communication ports for programming, customizing, or synchronizing the vibratory devices (not illustrated).
In some embodiments, the control circuitry may be configured to selectively activate and deactivate the electromagnets according to at least one vibration pattern. For example, and without limitation, the control circuitry may include a first pattern for sequentially activating each electromagnet at a first cycle timing (e.g., sequentially pulse electromagnets 43a-d) to impart a circular wobbling effect on the bobble toy. The control circuitry may also include additional patterns for sequentially activating each electromagnet at longer or shorter cycle timings to impart faster or slower wobbling. In some other examples, the control circuitry may include a first pattern for cyclically activating first and second groups of electromagnets (e.g. sequentially pulse electromagnets 43b and 43d for a one second interval to achieve side to side rocking and then sequentially pulse electromagnets 43a and 43c for a one second interval to achieve front to back rocking). In some embodiments, the multiple patterns may correspond to order of activation/deactivation amongst the electromagnets. In some embodiments, one or more switches, dials, buttons, or other configuration devices may be coupled to the control circuitry for adjusting the cyclical speed.
In some embodiments, the control circuitry may be responsive to one or more external stimuli sensors (for example and without limitation, audio sensors or light sensors) for selecting the pattern of rotation. For example and without limitation, a light sensor coupled to the control circuitry may detect low light conditions and cause the control circuitry to selectively activate and deactivate the electromagnets at a slow speed, whereas in bright light conditions the control circuitry may activate and deactivate the electromagnets at a fast speed. In some other embodiments, the control circuitry can be responsive to one or more audio ports (such as a headphone jack) such that a user may connect a conventional stereo or media player to the vibratory device and the bobble toy may vibrate in response thereto.
In some embodiments, the speakers and/or lighting devices (for example and without limitation, bulbs, LEDs, lasers, mirrors, and/or fiber optics) may be responsive to the control circuitry, which may play sounds, music, or other melodies, and activate and deactivate light sources. It is to be appreciated that in some examples, without limitation, the vibratory device may cause the bobble toy to vibrate at fast speeds, quickly activate one or more light sources, and play fast music to give the bobble toy the appearance of dancing to, for example, disco music, while alternatively causing the bobble toy to vibrate or rock at slow speeds, with a fixed light source, and play slow music to give the bobble toy the appearance of dancing to slow rhythm and blues music. Of course, other programs and patterns of the electromagnets, speakers, and/or lighting devices are contemplated in accordance with some embodiments of the present invention.
In some embodiments, the control circuitry of the vibration device may communicate with a computer, mobile phone, or other programming device to allow a user to customize the pattern of electromagnetic activation/deactivation, and optionally if such features are provided, the speakers and/or lighting devices. The programming device may communicate through a port provided in the vibration device and store in a memory element in the vibratory device a set of programs or instructions operable by a processor or controller of the control circuitry. In some implementations, the port can be USB port(s), network port(s), audio jack(s), serial port(s), parallel port(s), transceiver(s) for wireless data exchange over short distances using short wavelength radio transmissions, wireless local area network transceiver(s), and/or infrared port(s), however other ports are contemplated herein. In some other examples, the programs may be included in portable storage disks such as USB memory drives, memory sticks, multimedia cards, secure digital cards, smart media cards, picture cards, or any other type of storage drives.
Referring now specifically to the illustration of
It is to be appreciated that magnet recesses 23a-d may have a shape and size situated for receiving and securing the magnetic members of various shapes and sizes therein. In some embodiments, the top cavity of the vibratory device may have a different number and arrangements of recesses. As an example, and without limiting the invention,
In some embodiments, a vibratory device can include a bearing for hingedly supporting the platform during vibration. Referring back to the exemplary illustrations of
Other recesses for receiving platform supporting elements may be provided in the top cavity of the base in accordance with some embodiments of the present invention. In some implementations, spring recesses 27a-d for receiving supporting springs (for example, and without limitation, springs 47a-d as illustrated in
It is to be appreciated that any number of magnet recesses, sockets, or spring recesses, and other locations, sizes, and combinations thereof are contemplated in accordance with some embodiments of the present invention. For example, and without limitation, a vibratory device may comprise only two magnet recesses for receiving two magnetic members therein. In some other examples, a vibratory device may be standardized and include four magnet recesses but only two of such magnet recesses may be populated with magnetic members therein. Thus, it is to be appreciated that the same base may be used for different vibratory device models, some of which may include one degree of movement and some of which may include two degrees of movement. In other non-limiting examples, magnet recesses may be provided in each of four corners of the top cavity of the base and spring recesses may be provided along the edges of the top cavity of the base. In some other non-limiting examples, a single magnet recess may be centrally provided, and a single magnetic member may be placed therein for enabling up and down vibratory motion to the platform.
Referring now specifically to the illustration of
In some implementations, and referring back to the example of
Referring now specifically to the exemplary illustration of
In some embodiments of the present invention, vibratory motion may be imparted to the platform by attractive and/or repulsive magnetic forces applied between a plurality of magnetic members engaged with the base and platform. In some embodiments, one or more of the magnetic members engaged with the base and one or more of the magnetic members engaged with the platform may comprise rare earth magnets, permanent magnets, ferromagnetic material, or electromagnets. In some preferred implementations, one or more of magnetic members 43a-d in the base may comprise electromagnets each of which may be selectively activated and deactivated to induce a magnetic field upon which one or more of magnetic members 44a-d of the platform may react. In some implementations, all of the magnetic members in the base and/or platform may comprise the same type of magnetic members (for example, and without limitation, all of the base magnetic members may include electromagnets while all of the platform magnetic members may comprise rare earth magnets). However in other implementations, multiple types may be provided. For example, and without limitation, magnetic members 43a and 43b may comprise electromagnets and magnetic members 43c and 43d may comprise permanent magnets. It is further to be appreciated that one or more of magnetic members 43a-d may comprise a ferromagnetic material that may attract or repel one or more of magnetic members 44a-d. It is to be appreciated that other combinations of magnetic members in the base and/or platform are contemplated in accordance with some embodiments of the present invention.
As illustrated in the non-limiting examples of
Springs 47a-d may have first ends positioned and secured in spring recesses 27a-d of base 20, respectively, and second ends positioned in spring recesses 37a-d of platform 30, respectively. Bearing 45 may be positioned between socket 25 of base 20 and socket 35 of platform 30. It is to be appreciated that, in some embodiments as illustrated in the examples of
In some embodiments, one or more preventative dampeners (for example, and without limitation, foam or rubber pads) may be provided between the magnetic members engaged with the base and the magnetic members engaged with the platform for preventing unintended direct contact of the magnetic members during operation. As an example and without limiting the invention,
In preferred implementations, each of magnetic members 43a-d may comprise an electromagnetic and each of magnetic members 44a-d may comprise rare earth magnets, permanent magnets, or ferromagnetic material. It is to be appreciated that alternating activation of electromagnetic members 43a and 43c may induce alternating magnetic fields on magnetic members 44a and 44c, respectively, which may impart a front-to-back vibration of platform 30. Similarly, it is to be appreciated that alternating activation of electromagnetic members 43b and 43d may induce alternating magnetic fields on magnetic members 44b and 44d, respectively, which may impart a side-to-side vibration of platform 30. Further, it is to be appreciated that sequential activation of electromagnetic members 43a-d may induce magnetic fields on magnetic members 44a-d, respectively, which may impart a circular vibration of platform 30. It is further to be appreciated that alternating activation of (i) two adjacent electromagnet members (e.g., 43a and 43b) and (ii) the other two adjacent electromagnetic members (e.g., 43c and 43d) may impart a corner-to-corner vibration of platform 30.
In some other examples, two adjacent magnetic members (e.g., 43a and 43b) may comprise an electromagnet and two other adjacent magnetic members (e.g., 43c and 43d) may comprise permanent magnets. It can be appreciated that pulsing of electromagnetic member in a front of the base (e.g., 43a) may impart a front-to-back vibration on the platform (e.g., platform 30) and pulsing of an electromagnetic member (e.g., 43b) located on a lateral side of the base (e.g., base 20) may impart a side-to-side vibration on the platform. In some other non-limiting examples, magnetic members in the base (e.g., magnetic members 43a-d) may comprise permanent magnets and magnetic members in the platform (e.g., magnetic members 44a-d) may comprise electromagnets. In some other non-limiting examples, at least one of the magnetic members in the base (e.g., 43a-d) may comprise an electromagnet and at least one of magnetic members in the platform (e.g., 44a-d) may comprise an electromagnet. It is to be appreciated that other combinations of electromagnets, permanent magnets, rare earth magnets, and ferromagnetic material are contemplated in accordance with some embodiments of the present invention.
It is to be appreciated that a bearing (e.g., bearing 45) can be centrally located in the top cavity of the base that permits hinged movement about the center of the magnetic members (e.g., magnets 43a-d) and/or platform (e.g., platform 30). As such, a bobble toy positioned on the platform may appear to bobble or wobble. In some embodiments, a vibratory device can instead have a centrally located spring in a spring recess in the center of a top cavity (e.g., top cavity 28) of the base. In such non-limiting embodiments, and in those where magnetic members (e.g., magnets 43a-d) in the base comprise electromagnets, simultaneous activation of the electromagnetic members may induce upward and downward vibration on the platform (e.g., platform 30).
In some embodiments, the supporting springs (e.g., springs 47a-d) may be interchangeable. For example, and without limitation, springs having heavier weights may be used when heavier bobble toys are placed on the platform and springs having lighter weights may be used when lighter bobble toys are placed on the platform. It is to be appreciated that providing springs having different weights enable different platform vibration characteristics.
It is to be appreciated that vibratory devices in accordance with embodiments of the present invention may comprise any number, location, and type of magnetic members, springs, and bearings. Those skilled in the art can appreciate that the number and positioning of magnetic members, relative to each other and to a central bearing (if present) may enable a multitude of different vibration patterns.
In some embodiments, the base may have a bottom cavity for housing circuitry, power sources, control devices, ports, inputs, audio speakers, microphones, display lighting, and other elements. Referring now specifically to the illustration of
In some non-limiting implementations, the main body (e.g., body 21) can have one or more openings on side or top walls for receiving user inputs therein. For example, and without limitation,
In some non-limiting embodiments, the vibratory device may include one or more aesthetic display lights for increasing the enjoyment of the user during operation. Vibratory devices may include multiple lights having multiple different colors. In some non-limiting implementations, lights may be positioned on an outside surface of the vibratory device on walls of the base and/or the platform. In some non-limiting implementations, lights may be internally positioned and configured to shine light through one or more openings in, or translucent surfaces of, the base or housing. For example, and without limitation,
The present invention thusly provides apparatuses and systems for enabling silent and maintenance free autonomous motion on bobble toys. In embodiments comprising electromagnets, programmable and/or customizable vibration patterns may be provided allowing the user to create their own vibration program or pattern.
The foregoing descriptions of specific embodiments of the present invention have been presented for purposes of illustration and description. They are not intended to be exhaustive or to limit the invention to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical application, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated. It is to be understood that variations, modifications, and permutations of embodiments of the present invention may be made without departing from the scope thereof. Thus, although reference has been made to the accompanying figures, it is to be appreciated that these figures are exemplary and are not meant to limit the scope of the invention. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.
This application claims the benefit of U.S. Provisional Patent Application No. 61/649,239, filed May 19, 2012, incorporated herein by reference in its entirety.
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