CROSS-REFERENCE TO RELATED APPLICATIONSThis application claims priority from and incorporates by reference in their entirety the following provisional applications:
U.S. Appl. No. 61/143,459, filed on Jan. 9, 2009;
U.S. Appl. No. 61/152,140, filed on Feb. 12, 2009;
U.S. Appl. No. 61/157,579, filed on Mar. 5, 2009;
U.S. Appl. No. 61/157,580, filed on Mar. 5, 2009;
U.S. Appl. No. 61/170,222, filed on Apr. 17, 2009;
U.S. Appl. No. 61/242,406, filed on Sep. 15, 2009; and
U.S. Appl. No. 61/252,770, filed on Oct. 19, 2009.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention generally relates to electro-active spectacles. More specifically, the present invention provides electronics for operating and synchronizing electro-active lenses compatible with any frame type, style or size, as well as associated charging devices.
2. Background Art
Electro-active lenses generally provide a region of adjustable optical power by changing the refractive index of an electro-active material (e.g., a liquid crystal material) by the application and removal of electrical power. Conventional electro-active lenses and spectacles fail to provide cosmetically acceptable and practical mechanisms for (a) controlling and synchronizing operation of the electro-active lenses, (b) providing electrical connectivity between controlling electronics and the electro-active lenses, and (c) recharging the electro-active lenses. Further, conventional devices and techniques for addressing these problems are limited in that they are not generally compatible with any frame size, type or style.
Accordingly, what is needed are electronics for controlling and synchronizing operation of electro-active lenses that can be housed in any type of frame in a cosmetically acceptable and easily implementable manner. Further, power charger devices for recharging electro-active lenses of any frame size, shape or style are also needed.
BRIEF DESCRIPTION OF THE DRAWINGS/FIGURESFIG. 1 illustrates electro-active spectacles in accordance with an aspect of the present invention.
FIG. 2 illustrates a side view of the electro-active spectacles depicted inFIG. 1 in accordance with an aspect of the present invention.
FIG. 3 illustrates an exemplary configuration of electrical components of the electro-active spectacles in accordance with an aspect of the present invention.
FIG. 4 illustrates an exemplary configuration of electrical connectivity between a battery and an electronic module depicted inFIG. 3 in accordance with an aspect of the present invention.
FIG. 5 illustrates an electronic module in accordance with an aspect of the present invention.
FIG. 6 illustrates an electro-active lens in accordance with an aspect of the present invention.
FIG. 7 illustrates a portion of a frame in accordance with an aspect of the present invention.
FIG. 8 illustrates an exploded view of the frame depicted inFIG. 7 in accordance with an aspect of the present invention.
FIG. 9 illustrates a portion of electro-active spectacles in accordance with an aspect of the present invention.
FIG. 10 illustrates a front a view of electro-active spectacles in accordance with an aspect of the present invention.
FIG. 11 illustrates a portion of a right temple of electro-active spectacles in accordance with an aspect of the present invention.
FIG. 12 illustrates a portion of a right temple of electro-active spectacles in accordance with an aspect of the present invention.
FIG. 13 illustrates a representative block diagram of electro-active spectacles in accordance with an aspect of the present invention.
FIG. 14 illustrates a slim line charger in accordance with an aspect of the present invention.
FIG. 15 illustrates a side view of the slim line charger depicted inFIG. 14 in accordance with an aspect of the present invention.
FIG. 16 illustrates the slim line charger ofFIGS. 14 and 15 in a closed positioned in accordance with an aspect of the present invention.
FIG. 17 illustrates an electro-active frame in accordance with an aspect of the present invention.
FIG. 18 illustrates electro-active spectacles in accordance with an aspect of the present invention.
DETAILED DESCRIPTION OF THE INVENTIONAspects of the present invention provide electronics for controlling and synchronizing operation of electro-active lenses. The controlling electronics can be positioned within a variety of frame types, sizes and styles and enable efficient user interaction. The controlling electronics, or a portion thereof, can be contained within an electronic module. The electronic module can be positioned within a frame temple and can be removable and reprogrammable and can include an inductive charge region. Electro-active spectacles of the present invention can use one or more electronic modules. When a single electronic module is used, the electronic module can activate and deactivate each electro-active lens at substantially the same time. If two electronic modules are used, then a first electronic module can synchronize operation of a second electronic module to ensure coordinated operation of both electro-active lenses.
Aspects of the present invention provide connectivity between one or more electronic modules and/or between a left-side portion and a right-side portion of electro-active spectacles. Connectivity can vary depending upon frame type. Aspects of the present invention allow electro-active spectacles to include one or more conductive links using left and right upper and lower rim portions of the frame that support the electro-active lenses, the bridge, conductive layers of the electro-active lenses, the upper and lower grooves of the electro-active lenses, wires or other conductive links embedded within any portion of the frame, and/or a wireless connection.
Aspects of the present invention provide chargers for recharging a power source of electro-active spectacles of any size, shape or style. A slim line charger of the present invention can include a base and arms to support electro-active spectacles of the present invention. The slim line charger can include one or more adjustable inductive charging cradles to inductively charge a power source (e.g., one or more batteries) of electro-active spectacles of the present invention.
FIG. 1 illustrates electro-active spectacles oreyeglasses100 in accordance with an aspect of the present invention. The electro-active spectacles100 shown inFIG. 1 are fully rimmed eyeglasses comprising left and right temples and a frame front (the frame front can comprise left and right eyewires or rims as will be appreciated by one skilled in the pertinent art). Electro-active spectacles and frames of the present invention can be fully rimmed, partially rimmed, or rimless. The electro-active spectacles100 can include aframe102, a first electro-active lens104, and a second electro-active lens106. Theframe102 can include left and right temple portions, a bridge, and rim portions (e.g., upper and/or lower rim portions) supporting the electro-active lenses104 and106. The first and second electro-active lenses104 and106 can each be an electro-active lens as described in U.S. patent application Ser. No. 12/408,973 (hereinafter the '973 application), filed Mar. 23, 2009, entitled “Electro-Active Diffractive Lens and Method for Making the Same,” which is hereby incorporated by reference in its entirety. In general, the first and second electro-active lenses104 and106 can be any lens or optic capable of changing, varying or tuning the optical power they each provide with the application of electricity.
The right temple portion can be considered to be a first temple portion that is positioned adjacent to the first electro-active lens104. The left temple portion can be considered to be a second temple portion that is positioned adjacent to the second electro-active lens106. The bridge can be considered to be part of the frame or to be a separate portion of the electro-active spectacles100 that connects, joins or supports the first and second electro-active lenses104 and106.
The electro-active spectacles100 can include one or more power sources for powering the first and second electro-active lenses104 and106. As an example, each power source can include one or more batteries (e.g., conventional rechargeable batteries and/or solar batteries). The electro-active spectacles100 can also include electronics that can govern operation of the electro-active lenses104 and106. The electronics can comprise one or more control units (e.g., a control unit matched to each electro-active lens) to determine when to activate and when to deactivate the electro-active lenses104 and106. The one or more power sources and the electronics of the electro-active spectacles100 can be housed or contained within any portion of theframe102. The one or more power sources and the one or more control units of the electro-active spectacles100 can be grouped together or distributed or dispersed in any manner within or throughout theframe102.
In accordance with an aspect of the present invention, the one or more power sources and the one or more control units of the electro-active spectacles100 can be arranged in a manner that can accommodate a wide variety of frame types and styles. Specifically, an aspect of the present invention enables the one or more power sources and the one or more control units of the electro-active spectacles100 to be arranged in a manner that can accommodate fully-rimmed, partially rimmed, and rimless frames.
In accordance with an aspect of the present invention, the operation of the electro-active lenses104 and106 can be synchronized. That is, the one or more control units housed in theframe102 can coordinate the activation and deactivation of the electro-active lenses104 and106 such that the electro-active lenses104 and106 are activated or deactivated at substantially the same time.
In accordance with an aspect of the present invention, the one or more control units housed in theframe102 can automatically operate (e.g., activate and deactivate) the electro-active lenses104 and106. As an example, the electro-active lenses104 and106 can be activated or deactivated based on a user's head tilt as sensed by the one or more control units. The one or more control units can also enable a user to interact with the electro-active lenses102 and104. As an example, a user can manually activate or deactivate the electro-active lenses104 and106, override automatic operation of the electro-active lenses104 and106, place the electro-active spectacles100 into a standby mode (in which the electro-active lenses104 and106 are neither automatically or manually activated or deactivated), or power off the electro-active spectacles100.
The electronics of the electro-active spectacles100 can include a processor, memory, a power source (e.g., a battery) and a gyroscope or accelerometer. As previously mentioned, these components can be grouped together or can be distributed within different portions of theframe102. As an example, all or a portion of these components can be grouped together to form a self-contained electronic module. The electro-active spectacles100 can comprise a single electronic module that governs synchronized operation of both the first and second electro-active lenses104 and106. Alternatively, operation of the first electro-active lens104 can be governed by a first electronic module and operation of the second electro-active lens106 can be governed by a second electronic module. Under this scenario, the first and second electronic modules can communicate using one or more conductive wires (e.g., embedded within a portion of the frame102), one or more conductive portions of the frame102 (e.g., conductive metal layers or conductive cores encapsulated by non-conductive material), one or more conductive layers of the electro-active lenses104 and106, an optical link, and/or via a wireless communications link. Communication between the first and second electronic modules can facilitate coordinated operation of the first and second electro-active lenses104 and106.
FIG. 2 illustrates a side view of the electro-active spectacles100 depicted inFIG. 1. As shown inFIG. 2, the electro-active spectacles100 can comprise an electronic module (or control unit)202. As described above, theelectronic module202 can include various electronics components. Theelectronic module202 can be positioned near the front temple of theframe102. Theelectronic module202 can be positioned within the frame102 (e.g., in an area or cavity of the frame102) and can be removable and replaceable. Alternatively, the electronic module can be built into theframe102 and form a part of theframe102. Theelectronic module202 can be located on an outer portion of a temple of the frame102 (further from a wearer) or can be located on an inner portion of the temple of the frame102 (closer to the wearer). Theelectronic module202 can be positioned on a left temple or a right temple of the frame102 (i.e., on either side of the frame102). Theelectronic module202, when inserted into the temple of theframe102, can be flush with the other portions of theframe102. All or a portion of the electronic components used to operate the electro-active lens104 can be contained within theelectronic module202.
Theelectronic module202 can also control operation (or at least ensure synchronized operation) of the electro-active lens106. Electrical connections between theelectronic module202 and one or more of the electro-active lenses104 and106 can be routed through theframe102 and/or the electro-active lenses104 and106 as will be described in more detail below. According to an aspect of the present invention, connectivity between theelectronic module202 and one or more of the electro-active lenses104 and106 can be accomplished by using a single conductive wire.
According to an aspect of the present invention, a first electrical connection (e.g., comprising one or more conductive links or wires) can be used to provide connectivity between one or more power sources of the electro-active spectacles100 and one or moreelectronic modules202 and a second electrical connection (e.g., comprising one or more conductive links or wires) can be used to provide connectivity between the one or moreelectronic modules202 and the one or more electro-active lenses (e.g., the electro-active lenses104 and106). For example, a battery positioned within theframe102 can be coupled to anelectronic module202 also positioned within theframe102 using a first conductive link. A second, distinct conductive link (e.g., electrically isolated from the first conductive link) can be used to couple theelectronic module202 to the electro-active lenses104 and106.
According to an aspect of the present invention, the same conductive link (e.g., comprising one or more electrical wires) can be used to couple the one or more power sources of the electro-active spectacles100, the one or moreelectronic modules202 and the electro-active lenses104 and106 as will be appreciated by one skilled in the pertinent art. This can enable a power source to be positioned on one side of the frame102 (e.g., in a first temple) and anelectronic module202 to be positioned on the other side of the frame102 (e.g., in a second temple) while using the same conductive link to simultaneously provide power to theelectronic module202 and controlling signals from theelectronic module202 to the electro-active lenses104 and106. As a result, the number of conductive links (e.g., embedded wires) positioned within theframe102 can be minimized.
FIG. 3 illustrates an exemplary configuration of electrical components of the electro-active spectacles100. Specifically,FIG. 3 shows abattery302 located near the end of theframe102 of the electro-active spectacles100. A portion of the end of theframe102 is removed for illustration purposes only. Thebattery302 can be a rechargeable battery and can provide power to the electrical components located within theelectronic module202. Thebattery302 can provide power to one or more electronic modules of the present invention.
FIG. 4 illustrates an exemplary configuration of electrical connectivity between thebattery302 depicted inFIG. 3 and theelectronic module202. A portion of theframe102 is removed for illustration purposes only. As shown inFIG. 4, conductingwires402 can couple thebattery302 to theelectronic module202. The conductingwires402 can be positioned within the frame102 (e.g., embedded within the frame102) of the electro-active spectacles100.
FIG. 5 illustrates theelectronic module202 in accordance with an aspect of the present invention. Theelectronic module202 can contain all or a portion of the electronic components that govern operation of one or more electro-active lenses including a power source (e.g., a rechargeable battery or a solar battery). As shown inFIG. 5, theelectronic module202 can comprise ahousing502,first contacts504 andsecond contacts506. Thehousing502 can contain the electrical components of theelectronic module202—e.g., a processor, memory, power source, and/or a gyroscope/accelerometer.
Thefirst contacts504 can provide electrical connectivity between the electrical components of thehousing502 and other portions of one or more associated electro-active lens (e.g., the first electro-active lens104). Thesecond contacts506 can provide electrical connectivity to a memory of theelectronic module506. Thesecond contacts506 can be used, for example, to program or reprogram theelectronic module202 directly. Additional contacts (not illustrated for simplicity), or the first and/orsecond contacts504 and506, can also provide connectivity to a remote battery (e.g., thebattery302 depicted inFIGS. 3 and 4) or to another electronic module or control unit. Alternative or additional contacts (e.g., an antenna) can allow wireless programming of theelectronic module202.
In general, theelectronic module202 can be positioned anywhere on the frame102 (e.g., in any portion of theframe102 having an area or cavity designed to accept insertion of the electronic module202). Theelectronic module202, as shown inFIG. 2, can be located near the front temple of a wide variety of frame types and styles. Specifically, theelectronic module202 can be located within a portion of a frame that is fully rimmed, partially-rimmed, or rimless. Theelectronic module202 can be removed and replaced with a new module or can be reprogrammed. As an example, theelectronic module202 can be initially programmed with a first mode of operation or a first prescription for a user. At a later time, theelectronic module202 can be removed and reprogrammed using thesecond contacts506 with a second mode of operation or a second prescription for a user.
As an alternative to thesecond contacts506, theelectronic module202 can be reprogrammed using a wireless communication link such that removal of theelectronic module202 from the frame is not necessary to enable reprogramming. Reprogramming can include changing a specified angle of head tilt for activating or deactivating an associated electro-active lens.
Theelectronic module202 can also include or be coupled to one or more light emitting diodes (LEDs). The one or more LEDs can be used to indicate operating conditions or states of the electro-active spectacles of the present invention including, but not limited to, the power level of the power source of the spectacles.
A wireless communication link between theelectronic module202 and a remote communication device can, as described above, provide a mechanism for reprogramming theelectronic module202 but can also provide a mechanism for collecting information on the operating status and history of operation of the electro-active spectacles of the present invention. Reprogramming verification (e.g., verifying successful uploaded controlling firmware) and other data collection can be enabled using such a communications link.
The one or more LEDs of theelectronic module202 can also be used to facilitate communication with a remote device. For example, the one or more LEDs can be opto-coupled to a receiving station to readoutelectronic module202 operating parameters and to aid in re-configuration or reprogramming (e.g., verifying uploaded firmware).
Additionally, a communication link between the electro-active spectacles of the present invention and a remote device can be established using the electro-active lenses themselves. For example, the electro-active lenses of the present invention can be used to transmit a signal to a receiving station by encoding data with lens “flicker” as will be apparent to one skilled in the pertinent art.
Theelectronic module202 can contain any number of mechanism by which a user can interact with theelectronic module202 to adjust operation of the electro-active spectacles of the present invention. For example, theelectronic module202 can include a switch or device to enable a user to interact with theelectronic module202. The switch or device can be a press button switch, a capacitive switch (e.g., comprising a capacitive sense pad), a toggle switch or other manual switch. The switch or device can enable a user to activate or deactivate the associated electro-active lens or lenses, to override or initiate automatic operation of the associated electro-active lens or lenses, and to select a mode of operation or prescription correction for a user. A capacitive switch can be located on a surface of theelectronic module202 that is exposed or accessible when positioned in theframe102. Alternatively, or in addition thereto, capacitive sense pads can be deposited or built into theframe102 that can be coupled to theelectronic module202.
Theelectronic module202 can also include an ability to toggle among modes or be activated or deactivated through voice activation or based on light sensitivity. For example, a user can activate or deactivate the lenses or otherwise adjust operation by issuing or speaking voice commands or instructions. Further, theelectronic module202 can be activated or deactivated or change operating modes based on the amount of light measured or sensed by electronics included in theelectronic module202. For example, in relatively low light, theelectronic module202 can be deactivated automatically (or placed into a standby, non-switchable mode) and can be activated (or switched out of a standby non-switchable mode) when in relatively bright light conditions. Lastly, theelectronic module202 can include electronics to allow remote activation or toggling of operational modes. For example, theelectronic module202 can include electronics to allow remote wireless activation or activation by a switch connected by a wired link from a position remote from the electro-active spectacles of the present invention. Remote activation may be particularly useful for individuals that are physically challenged (e.g., individuals that cannot move their arms to touch the frame temple with ease).
All of the mechanism described above can be used by a user to adjust the operation of the electro-active spectacles of the present invention. For example, a user can use one of the mechanisms described above to switch the lens from a first mode to a second mode of operation or between any number of different modes of operation. For example, a first mode of operation can be a standby mode of operation. In a standby mode of operation, the electro-active spectacles of the present invention can be placed into a non-switchable state (such that the electro-active lenses do not automatically activate or deactivate based on a sensed signal received from a tilt sensor, rangefinder or other activation/deactivation sensing device including manual control).
A second mode of operation can be an active mode of the electro-active spectacles. In the active mode of operation, the electro-active spectacles of the present invention can be placed into a switchable state (such that the electro-active lenses will automatically activate or deactivate based on a sensed signal received from a tilt sensor, rangefinder or other activation/deactivation sensing device or will respond to direct manual control to activate or deactivate).
The electro-active spectacles of the present invention can also include additional operational states or modes that the user can use (and toggle or transition between them using one of the interaction mechanism described above). For example, the electro-active spectacle of the present invention can include a manual operation state. In a manual operation state, the user can manually direct the electro-active lenses of the present invention to activate or deactivate. Manual direction can be though voice command or the touching or toggling of a switch as described above.
Another mode of operation can be an on mode. In the on mode or on state, the electro-active spectacles of the present invention can maintain the electro-active lenses of the present invention in an activate state. Accordingly, an off mode can maintain the electro-active lenses of the present invention in a deactivated state.
The ability to program or reprogram theelectronic module202 enables the electro-active spectacles of the present invention to be customized or re-customized for a particular user. Customizable features of the electro-active spectacles of the present invention include any of the following: head tilt angle at which to active one or more electro-active lenses of the present invention; head title angle at which to deactivate one or more electro-active lenses of the present invention; distance between an object viewed by the user and the user at which to activate or deactivate one or more electro-active lenses of the present invention; number of operational modes (e.g., inclusion or exclusion of operational modes such as standby mode or activation mode or off mode); method of toggling between selected operational modes (e.g., selection of which mechanism described above to use to allow a user to toggle between modes including the order of toggling or states); user prescription (e.g., the optical power provided by the electro-active area of the electro-active lenses of the present invention).
Any of the customizable features of the electro-active spectacles of the present invention can be programmed into theelectronic module202 directly (e.g., using a flash programmer or direct wired link) or indirectly (e.g., using a wireless link such as an infrared link or RF link).
Theelectronic module202 can include an inductive charge area. That is, theelectronic module202 can include electronics for enabling a power source of the electronic module202 (or a power source coupled to the electronic module202) to be recharged inductively by an inductive charging device. The inductive charge area can include inductive charge coils. According to an aspect of the present invention, the inductive charge coils can function as an antenna to communicate with a remote communication device. Communication with a remote communication device can enable remote wireless programming of theelectronic module202 or can enable communication between two or moreelectronic modules202 as described above. In general, the inductive charge area can be configured to serve these purposes.
A gyroscope or accelerometer of theelectronic module202 can be used to facilitate activation and deactivation of the associated electro-active lens or lenses based on a head tilt of a user. For example, the gyroscope or accelerometer can activate the associated electro-active lens or lenses when the user's head dips below a first predetermined threshold angle and can deactivate the associated electro-active lens or lenses when the user's head rises above a second predetermined threshold. Additionally, the gyroscope or accelerometer can power down or power off the associated electro-active lens or lenses when the electro-active spectacles housing theelectronic module202 are positioned upside down. For example, a user can power down or power off electro-active spectacles100 housing theelectronic module202 by simply placing the electro-active spectacles100 upside down on a relatively flat surface. Alternatively, positioning the electro-active spectacles100 upside down can place the electro-active spectacles100 in a standby mode (e.g., a mode where the electro-active spectacles100 will not switch between active and deactivate states but otherwise are turned on).
Theelectronic module202 can also include or can alternatively include a rangefinder. The rangefinder can be used to facilitate activation and deactivation of the associated electro-active lens or lenses based on the distance between a wearer of electro-active spectacles of the present invention and an object the wearer is looking at or observing.
FIG. 6 illustrates an electro-active lens600 in accordance with an aspect of the present invention. The electro-active lens600 can represent one of the electro-active lenses104 or106. The electro-active lens600 is depicted as a finished lens inFIG. 6. That is, the electro-active lens600 has been edged and grooved to fit into an eyeglass frame.
As shown inFIG. 6, the electro-active lens600 can comprise a first substrate (e.g., a top substrate)602 and a second substrate (e.g., a bottom substrate)604. During an edging process, agroove606 can be formed (e.g., near or between the interface of the first andsecond substrates602 and604). Thegroove606 can be used to position and stabilize the electro-active lens600 within an eyeglass frame as is done with conventional lenses.
The electro-active lens600 can comprise a first electrical lead orconnector608 and a second electrical lead orconnector610. The first and secondelectrical leads608 and610 can provide power (e.g., a drive signal or a control signal) to the electro-active region of the electro-active lens600. In particular, the first and secondelectrical leads608 and610 can link or connect the electro-active region of the electro-active lens600 to a power source and electronic components that can be housed within an associated eyeglass frame (e.g., the electronic module/control unit202 depicted inFIG. 5). The first and secondelectrical leads608 and610 can comprise any conductive material including, but not limited to, silver ink. The first and secondelectrical leads608 and610 can be painted, applied or otherwise deposited onto the transparent conductive layers placed on thesubstrates602 and604.
To ensure or improve connectivity, after edging and grooving the electro-active lens600, a small quantity of conductive material, paint or paste can be placed on top of the first and secondelectrical leads608 and610. Specifically, as shown inFIG. 6, a firstconductive material612 can be placed in thegroove604 on top of the firstelectrical lead608 and a secondconductive material614 can be placed in thegroove604 on top of the secondelectrical lead610. The first and secondconductive materials612 and614 can be substantially transparent and can comprise an indium tin oxide (ITO) paste or a paint containing silver particles (e.g., silver ink).
FIG. 7 illustrates a portion of aframe700 in accordance with an aspect of the present invention. Theframe700 can provide electrical connectivity between the electro-active lenses (not depicted inFIG. 7 for simplicity) and the electrical components used to operate electro-active lenses.
Theframe700 can include an upper portion of the right eye-wire orrim702 and a lower portion of the right eye-wire orrim704. For a fully rimmed frame, thelower portion704 can extend underneath an electro-active lens to abridge706. For a partially-rimmed frame, thelower portion704 generally does not extend to thebridge706.
Theframe700 can include anelectronic module202 and an area to accept anelectronic module202. Afirst conductor708 can be positioned within a groove of theupper rim portion702. Asecond conductor710 can be positioned within a groove of thelower rim portion704. The first andsecond conductors708 and710 can comprise flexible, compressible materials. When an electro-active lens—e.g., the electro-active lens600 depicted in FIG.6—is positioned within theframe700, the first andsecond conductors708 and710 can be compressed to fit in the groove of the upper andlower rim portions708 and710, respectively, and thegroove606 of the electro-active lens600. Thefirst conductor708 can be positioned to make contact with the firstconductive material612. Thesecond conductor710 can be positioned to make contact with the secondconductive material614.
Theframe700 can include anupper conducting member712, alower conducting member714 and an insulating orisolation member716. Theupper conducting member712, thelower conducting member714 and the insulatingmember716 can physically couple the temple of theframe700 to the eye-wire portion (i.e., the upper andlower rim portions702 and704).
Theupper conducting member712 can provide connectivity between theelectronic module202 and thefirst conductor708. Thefirst conductor708 can provide connectivity to the first conductive material612 (and, as a result, connectivity to the first electrical lead608) depicted inFIG. 6. The lower conducting member can provide connectivity between theelectronic module202 and thesecond conductor710. Thesecond conductor710 can provide connectivity to the second conductive material614 (and, as a result, connectivity to the second electrical lead610) depicted inFIG. 6. The insulatingmember716 can ensure that the connectivity path between theelectronic module202, the upper conductingmember712 and thefirst conductor708 remains insulated or electrically separated from the connectivity path between theelectronic module202, thelower conducting member714 and thesecond conductor710.
Any portion of the upper conductingmember712 and thelower conducting member714 can provide a conductive link. As an example, the entirety of the upper and lower conductingmembers712 and714 can be conductive (e.g., made of metal and coated with a non-conductive material) or a portion of the upper and lower conductingmembers712 and714 can be conductive (e.g., an internal portion that is encapsulated by non-conductive material).
FIG. 8 illustrates an exploded view of theframe700 depicted inFIG. 7. As shown inFIG. 8, theframe700 can be assembled by connecting the upper conductingmember712, the insulating member715 and thelower conducting member714 to theupper rim portion702 and thelower rim portion704. Thefirst conductor708 and thesecond conductor710 can then be positioned in the groove of theupper rim portion702 and thelower rim portion704, respectively. The first andsecond conductors708 and710 can be positioned in areas where they will make contact with the firstconductive material612 and the secondconductive material614, respectively.
The components illustrated in FIGS.7 and8—namely, the upper conductingmember712, thelower conducting member714, the insulatingmember716, theupper rim portion702, thelower rim portion704, thefirst conductor708 and thesecond conductor710—can be used to form a portion of theframe700 as a partially-rimmed frame or a fully-rimmed frame and to provide connectivity between an electronic module of the present invention and an electro-active lens of the present invention for each type of frame (and a variety of styles therein).
For a fully-rimmed frame, both theupper rim portion702 and thelower rim portion704 can extend from the upper conductingmember712 and thelower conducting member714, respectively, to thebridge706. For a partially-rimmed frame, generally only theupper rim portion702 extends from the upper conductingmember712 to thebridge706 while thelower rim portion704 does not extend to thebridge706.
When theframe700 is implemented as a fully-rimmed frame or a partially-rimmed, thefirst conductor708 can be of any size or length. That is, thefirst conductor708 can extend along any portion of theupper rim702 to make electrical connectivity with a desired lead of the electro-active lens104. When theframe700 is implemented as a fully-rimmed frame, thesecond conductor710 can similarly be of any size or length to make electrical connectivity with a separate or second desired lead of the electro-active lens104. However, when theframe700 is implemented as a partially-rimmed frame, thesecond conductor710 will be of the same length or shorter than thelower rim portion704.
FIG. 9 illustrates a portion of electro-active spectacles900 in accordance with an aspect of the present invention. The electro-active spectacles900 are implemented as rimless spectacles. That is, no upper or lower rim supports the electro-active lens104.
As shown inFIG. 9, the electro-active spectacles900 can include anelectronic module202 and an area to accept anelectronic module202. Theelectronic module202 can be electrically coupled to the electro-active lens104 using upper conductingmember902 and lower conducting member904 (similar to upper conductingmember712 andlower conducting member714 depicted inFIGS. 7 and 8). Both the upper and lower conductingmembers902 and904 can be isolated or insulated conductors having a protected, internal conductive routes (e.g., a conductive wire) enclosed by a non-conductive material (e.g., a plastic). Alternatively, the upper and lower conductingmembers902 and904 can entirely comprise conductive material and can be coated with non-conductive material.
The frame of the electro-active spectacles900 can support the electro-active lens104 usingupper support member910 andlower support member912. As an alternative, one of the upper andlower support members910 and912 can be used. Both the upper and lower supportingmembers910 and912 can be positioned through holes residing in the electro-active lens104. The frame of the electro-active spectacles900 can also be supported byupper contact906 andlower contact908. Both the upper andlower contacts906 and908 can be positioned through holes residing in the electro-active lens104. The upper andlower contacts906 and908 can be compression pin connectors having a portion that can make electrical contact with appropriate elements of the electro-active lens104.
While simultaneously supporting the electro-active lens104, theupper contact906 can make electrical contact with a first electrical lead of the electro-active lens (e.g., the firstelectrical lead608 depicted inFIG. 6). Similarly, thelower contact908 can support the electro-active lens104 while also providing electrical contact to a second electrical lead of the electro-active lens (e.g., the secondelectrical lead610 depicted inFIG. 6).
Both theupper contact906 and theupper support member910 can form part of an arm or extension of the upper conductingmember902. Theupper contact906 and theupper support member910 can comprise one or more conductors (e.g., a wire) insulated or contained by an insulating material (e.g., plastic). Theupper contact906 and theupper support member910 can be positioned in front of the electro-active lens104 (and connect through to the back of the electro-active lens104—as shown inFIG. 9) or can be positioned behind the electro-active lens104 (and connect through to the front of the electro-active lens104—not shown inFIG. 9). Thelower contact908 and thelower support member912 can be positioned in a manner similar to theupper contact906 and theupper support member910 pairing (and can form part of an arm or extension of the upper conducting member904).
FIG. 10 illustrates a front a view of electro-active spectacles1000 in accordance with an aspect of the present invention. The electro-active spectacles1000 are implemented as partially-rimmed spectacles. Electrical connectivity between a right side of the electro-active spectacles (e.g., from a right-side portion of a frame1002) to a left side of the electro-active spectacles (e.g., from a left-side portion of a frame1004) can be provided in a variety of ways and is not limited to partially-rimmed designs. Electrical connectivity between the right-side portion1002 and the left-hand portion1004 can enable a single electronic module (e.g., the electronic module202) located on either side to govern operation of both electro-active lenses104 and106. Further, this connectivity can ensure synchronized operation of the electro-active lenses104 and106 even if each of the electro-active lenses104 and106 is driven by separate electronic modules.
One or more conducting elements (e.g., conducting wires) can be embedded in a right-side upper frame orrim member1006, a left-side upper frame orrim member1008 and a bridge1010 (as well as a left-side lower frame or rim member and a right-side lower frame or rim member for some frame designs). The conducting elements can be embedded and surrounded by insulating material. Embedding one or more conducting elements in the right-sideupper frame member1006, thebridge1010 and the left-sideupper frame member1008 can enable an electronic module on either side of the electro-active spectacles1000 to control and/or synchronize operation of both electro-active lenses104 and106.
Rimless frames generally do not include the right-sideupper frame member1006 or the left-sideupper frame member1008. Rimless frames, however, do generally include abridge1010. Electrical connectively between the right-side portion1002 and the left-hand portion1004 of a rimless frame can be accomplished by using conductive elements incorporated into the manufacture of the electro-active lenses104 and106. Specifically, thebridge1010 can electrically connect (e.g., using an embedded conductive link or a conductive link adjacent to or connected to the bridge) one or more conducting elements of the electro-active lenses104 and106 (e.g., using one or more ITO layers) which are themselves coupled to the right-side portion1002 and the left-hand portion1004, respectively, of a spectacles lens. Electrical connectively between the right-side portion1002 and the left-hand portion1004 of a rimless frame can also be accomplished by using conductive wires positioned within the grooves an electro-active lens (e.g., thegroove606 depicted inFIG. 6) to couple the right-side portion1002 to the left-hand portion1004. Portions of the groove on the top part of the electro-active lens or on the bottom part of the electro-active lens can be used to house or contain one or more conductive wires. The conductive wires positioned within such a groove can be insulated.
According to an aspect of the present invention, one or more conductive wires can be embedded in the upper rim connectors, the bridge and/or the lower rim connectors of electro-active spectacles and frames of the present invention during a mold casting process. That is, when the upper rim connectors, the bridge and/or the lower rim connectors are formed using a casting process, one or more conductive wires can be cast over when the upper rim connectors, the bridge and/or the lower rim connectors are prepared. Generally, thicker conductive wires can be used during such a process. Nylon is an example material that can be used to mold over one or more conductive wires to from the upper rim connectors, the bridge and/or the lower rim connectors.
According to an aspect of the present invention, one or more conductive wires can be embedded in the upper rim connectors, the bridge and/or the lower rim connectors of electro-active spectacles and frames of the present invention as each frame component is assembled. More specifically, any of the upper rim connectors, the bridge and/or the lower rim connectors that will be used to embed one or more conductive wires can be fabricated by two or more individual or separate pieces. For example, the upper rim connectors can be formed from two substantially symmetrical pieces of substantially the same shape—a front piece and a back piece which individually may appear to be a portion of the upper rim connector split in half lengthwise. Prior to assembling the front and back pieces to form a complete upper rim connector, one or more wires can be embedded (e.g., in a groove formed by mold or machined into the front and/or back pieces) between the front and back pieces (i.e., at the interface between the front and back pieces). The front and back pieces used to form the complete upper rim connector can subsequently be combined, for example, using an adhesive.
According to an aspect of the present invention, one or more conductive wires can be embedded in the upper rim connectors, the bridge and/or the lower rim connectors of electro-active spectacles and frames of the present invention after the frame is assembled. Specifically, one or more grooves can be machined into the upper rim connectors, the bridge and/or the lower rim connectors that can be used to contain one or more conductive wires. The machined grooves can then be filled or covered with material to cosmetically hide the conductive wires. The assembled frame can then be polished to hide or mask the area in which the wires are embedded. Acetate is an example material that can be manipulated in this fashion to embed one or more conductive wires.
FIG. 17 illustrates electro-active frame1700 in accordance with an aspect of the present invention. Electro-active lenses can be mounted within the electro-active frame1700. For simplicity, a portion ofelectronics1702 that can be used to govern operation of the electro-active lenses are shown. Theelectronics1702 can represent a portion of anelectronic module202 described above and/or can represent conductive elements positioned to provide electrical connectivity between a temple of the electro-active frame1700 and a front portion of the electro-active frame1700. The electro-active frame1700 is shown as includingelectronics1702 on only one side of the electro-frame1700 but is not so limited.
As further shown inFIG. 17, the electro-active frame1700 can includeconductive leads1704 and1706 andconductive link1708.Conductive link1708 can provide electrical connectivity from one side of the electro-active frame1700 to the other side of the electro-active frame1700. Conductive leads1704 can provide electrical connectivity betweenelectronics1702 and a first electro-active lens mounted within the electro-active frame1700. Conductive leads1706 can provide electrical connectivity between theconductive link1708 and a second electro-active lens mounted within the electro-active frame1700.
As shown inFIG. 17, theconductive link1708 can be embedded or positioned within the electro-active frame1700. Theconductive link1708 can include any number of conductive elements (e.g., wires) that can be insulated not insulated. If the electro-active frame1700 uses driver electronics on each side of the frame1700 (e.g., a master and slave driver electronics or electronic modules202) then as few as only one single wire can comprise the conductive link1708). If the electro-active frame1700 has driver electronics on only one side of the electro-active frame1700, then at least two wires or conductive elements can be used. Theconductive link1708 can be positioned inside the electro-active frame1700 in accordance with any of the methods described above for embedding conductive links including, but not limited to, (1) embedding during a mold casting process; (2) embedding during an assembly process of the front frame portion of the electro-active frames1700; and (3) embedding after assembly of the electro-active frames by providing a groove or route for theconductive link1708. Theconductive link1708 can also use or can alternatively comprise the conductive layers of the electro-active lenses of the present invention that can be positioned into theframes1700 as described above.
FIG. 18 illustrates electro-active spectacles1800 in accordance with an aspect of the present invention. The electro-active spectacles1800 can include anelectronic module202. The electro-active spectacles1800 can also includeconductive link1802.Conductive link1802 can include any number of conductive elements (e.g., wires) that can be insulated or not insulated.Conductive link1802 can provide electrical connectivity between theelectronic module202 and the electro-active lens104 and the electro-active lens106.
As shown inFIG. 18, a portion of theconductive link1802 can be positioned or embedded within a portion of the frame of the electro-active spectacles1800. For rimless spectacles, theconductive link1802 can be routed through a groove in an electro-active lens (e.g., thegroove606 depicted inFIG. 6). As further shown inFIG. 18, theconductive link1802 can be routed adjacent to abridge1804 of the electro-active spectacles1800. For example, the conductive link can be routed throughtubing1806 that is positioned adjacent to thebridge1804.
FIG. 11 illustrates a portion of aright temple1100 of electro-active spectacles in accordance with an aspect of the present invention. The portion of theright temple1100 depicted inFIG. 11 shows aright temple area1102 that can be coupled to an electro-active lens (not depicted inFIG. 11 for simplicity). Theright temple area1102 can include an electro-active module of the present invention. Theright temple area1102 can be coupled to thefirst conductor708 throughfirst conductor link1104. Theright temple area1102 can further be coupled to thesecond conductor710 through asecond conductor link1106.
The first andsecond link conductors1104 and1106 can be shaped and constructed to tolerate bending of the frame (not depicted inFIG. 11 for simplicity) when the electro-active spectacles are opened and closed. The first andsecond link conductors1104 and1106 can contain one or more conducting elements (e.g., conducting wires) and can enclose them with insulating or non-conductive material or can themselves be entirely conductive. The first andsecond link conductors1104 and1106 can be considered to be continuous conductive links since they provide an uninterruptable physical connection between theright temple area1102 and the conductive elements of the electro-active lenses (e.g., toconductive elements708 and710).
FIG. 12 illustrates a portion of aright temple1200 of electro-active spectacles (implemented as rimless spectacles) in accordance with an aspect of the present invention. The portion of theright temple1200 depicted inFIG. 12 shows aright temple area1102 that can be coupled to an electro-active lens (not depicted inFIG. 11 for simplicity). Theright temple area1102 can include an electro-active module of the present invention. Theright temple area1102 can be coupled to the upper conductingmember712 through afirst spring conductor1202. Theright temple area1102 can further be coupled to the lower conducting714 through asecond spring conductor1204. The first andsecond spring conductors1202 and1204 can contain one or more conducting elements (e.g., conducting wires) and can enclose them with insulating or non-conductive material or can themselves be entirely conductive. The first andsecond spring conductors1202 and1204 can be considered to be discontinuous conductive links since they can provide an interruptible physical connection between theright temple area1102 and the conductive elements of the electro-active lenses (to upper and lower conductingmembers712 and714).
The first andsecond spring conductors1202 and1204 can extend proud of theright temple portion1102 when the spectacles are in use (i.e., when they are opened). The first andsecond spring conductors1202 and1204 can retract inside theright temple portion1102 when the spectacles are not in use (i.e., when they are closed). When opened, the first andsecond spring conductors1202 and1204 can extend to make contact with the upper and lower conductingmembers712 and714, respectively.
The connectivity mechanisms illustrated inFIGS. 11 and 12 and described above can be used for any type of frame style—that is, for fully rimmed, partially-rimmed and rimless frames of the present invention. Further, according to an aspect of the present invention, the first andsecond spring conductors1202 and1204 can be used to activate, deactivate, or place electro-active spectacles of the present invention into a standby mode or off mode of operation. For example, when thespring conductors1202 and1204 are not coupled or in contact with the upper and lower conductingmembers712 and714, the electro-active spectacles of the present invention can be powered-off or placed into a standby mode. When thespring conductors1202 and1204 are coupled or in contact with the upper and lower conductingmembers712 and714, the electro-active spectacles of the present invention can be powered-on and placed into an active mode (e.g., a switchable mode based on sensed input) or can immediately activate the electro-active lenses.
As will be apparent to one skilled in the pertinent art, electronics housed within the frame can sense such a lens disconnect condition by observing a reduction in capacitance or change in drive signal waveform that can occur when thespring conductors1202 and1204 are not coupled or in contact with the upper and lower conductingmembers712 and714. Once in the lens disconnect state, the electronics of the electro-active spectacles of the present invention can transition into a low power, standby or off mode. When in a low power or standby mode, the electronics of the electro-active spectacles of the present invention can periodically or randomly observe sensed capacitance or changes in the drive signal waveform to detect when the frame is re-opened for use.
FIG. 13 illustrates a representative block diagram of electro-active spectacles1300 in accordance with an aspect of the present invention. The electro-active spectacles1300 can represent the electro-active spectacles of the present invention described above (e.g., the electro-active spectacles100). The electro-active spectacles1300 can include a right electro-active lens1302 and a left electro-active lens1304. The right and left electro-active lenses1302 and1304 can represent the first and second electro-active lenses104 and106 described earlier. The electro-active spectacles1300 can include aright control unit1306 and aleft control unit1308. The left andright control units1306 and1308 can each represent anelectronic module202, or a portion thereof, described above.
Theright control unit1306 can include anisolation switch1310,driver circuits1312, andtransmitter circuits1314. Thedriver circuits1312 can generate a driver signal for operating (e.g., activating) the right electro-active lens1302. For example, to activate the right electro-active lens1302, thedriver circuits1312 can provide, generate or transmit a driver signal or activation signal. Further, to deactivate the right electro-active lens1302, thedriver circuits1312 can simply stop providing, generating or transmitting the driver signal.
Thetransmitter circuits1314 can generate a synchronization signal for coordinating operation of the right and left electro-active lenses1302 and1304. Specifically, thetransmitter circuits1314 can transmit a synchronization signal instructing the left electro-active lens1304 to activate or deactivate. As an example, the left electro-active lens1304 can be activated based on receipt of the synchronization signal or a synchronization signal of a first type instructing activation. Further, the left electro-active lens can be deactivated based on the absence of the synchronization signal or receipt of a synchronization signal of a second type instructing deactivation. As a result, the right and left electro-active lenses1302 and1304 can be activated and deactivated at substantially the same time.
Theisolation switch1310 can determine when thedriver circuits1312 and thetransmitter circuits1314 can access aconductive link1316 coupling the right electro-active lens1302 to thecontrol unit1306. Theconductive link1316 can comprise one or more conductive wires. Theconductive link1316 can represent one or more of the connectivity mechanisms depicted and described above (e.g., the routing and connectivity features illustrated inFIGS. 11 and 12 and described above).
When the electro-active spectacles are implemented with only a single control unit (e.g., the control unit1306), then thecontrol unit1306 can control operation of both the right and the left electro-active lenses1302 and1304. Under such a scenario, theisolation switch1310 andtransmitter circuits1314 can be optional. Further, the left and right electro-active lenses1302 and1304 can be activated at substantially the same time by a driver signal provided by thedriver circuits1312.
A communications link between the right and leftcontrol units1306 and1308 can comprise any portion of theconducive link1316, conductive elements within the right electro-active lens1302, a bridgeconductive link1318 contained within or adjacent to a bridge of the electro-active spectacles1300, conductive elements within the left electro-active lens1304, and aconductive link1320. Theconductive link1320 can comprise one or more conductive wires and can represent one or more of the connectivity mechanism depicted and described above (e.g., the routing and connectivity features illustrated inFIGS. 11 and 12 and described above). The communications link between the right and leftcontrol units1306 and1308 can also include or alternatively include a frame conductive link1222 (shown in phantom inFIG. 13).
The frameconductive link1322 can include one or more conductive wires wrapped over the right and left electro-active lens1302 and1304—e.g., either embedded within a portion of the frame and/or contained in a groove of the right and left electro-active lenses1302 and1304 as described above. The frameconductive link1322 can also include conductive elements of the right and left electro-active lenses1302 and1304 (e.g., one or more layers of ITO or other transparent conductive layers of the right and left electro-active lenses1302 and1304). For example, the frameconductive link1322 can be a wireless link that uses conductive layers of the right and left electro-active lenses1302 and1304 as antennas to facilitate communication and/or synchronization between the right and left electro-active lenses1302 and1304. Alternatively, other conductive elements can be embedded within the electro-active spectacles of the present invention to facilitate communication and/or synchronization between the right and left electro-active lenses1302 and1304. One or more of these embedded antennas could also provide a wireless communication link between the electro-active spectacles of the present invention and a remote communication device.
Overall, theright control unit1306 can communicate with theleft control unit1308 and/or can operate the left electro-active lens1304 using a single conductive wire or link. The single conductive wire can also be used to operate the right electro-active lens1302. The single conductive wire or link can be embedded within a portion of a frame and can include conductive elements of the electro-active lenses.
Theleft control unit1308 can include anisolation switch1324,driver circuits1326, andreceiver circuits1328. Thedriver circuits1326 can generate a driver signal for operating (e.g., activating) the left electro-active lens1302. Thereceiver circuits1326 can receive and process a synchronization signal transmitted by the right electro-active module1306. Theisolation switch1324 can determine when thedriver circuits1312 and thereceiver circuits1328 can access theconductive link1320 coupling the left electro-active lens1304 to thecontrol unit1308.
Thereceiver circuits1326 can listen for a synchronization signal transmitted overconductive link1320. Thereceiver circuits1326 can listen periodically or randomly for a specific or random amount of time. Once a synchronization signal is received, thecontrol unit1308 can operate accordingly—i.e., either activate or deactivate the left electro-active lens1304 using a driver signal transmitted by thedriver circuits1328.
Thetransmitter circuits1314 can transmit a synchronization signal in response to detection of a head tilt change of the user (e.g., detected by a gyroscope or accelerometer included in theright control unit1306—not illustrated for clarity) or manual command issued by the user. The synchronization signal transmitted by thetransmitter circuits1314 can be coded to distinguish it from noise and to prevent false triggering.
FIG. 14 illustrates an electro-active spectacles charger1400 in accordance with an aspect of the present invention. The charger1400 (as a slim line charger) can be used to charge/re-charge electro-active spectacles (e.g., the electro-active eyeglasses100) of the present invention.
As shown inFIG. 14, theslim line charger1400 comprises a front member orbase member1402, a firstmovable arm1404, and a secondmovable arm1406. Thefront member1402 can include a raisedsupport member1408 and a chargingstate indicator1410. The chargingstate indicator1410 can be a light emitting diode (LED). Thefirst arm1404 can include a first adjustable charging area1412 (or first adjustable inductive charging cradle) and thesecond arm1406 can include a second adjustable charging area1414 (or second adjustable inductive charging cradle).
Thebase member1402 can support a front portion of the electro-active spectacles100 (e.g., the first and second electro-active lenses104 and106 and any surrounding frame rim portions). The raisedsupport member1408 can support a bridge area of the electro-active spectacles100. Alternatively, or in addition thereto, the raisedsupport member1408 can support one or more electro-active lenses or rim portions of the electro-active spectacles100.
Thefirst arm1404 can be moveable. Specifically, thefirst arm1404 can rotate to an open position from a closed positioned about a point where thefirst arm1404 is attached to thefront member1402. Thefirst arm1404 is depicted in an open position inFIG. 14. In a closed position, thefirst arm1404 can be adjacent and parallel to thefirst member1402. Similar to thefirst arm1404, thesecond arm1406 can also be moveable. Specifically, thesecond arm1406 can rotate to an open position from a closed positioned about a point where thesecond arm1406 is attached to thefront member1402. Thesecond arm1406 is depicted in an open position inFIG. 14. In a closed position, thesecond arm1406 can be adjacent and parallel to thefirst member1402.
The firstadjustable charging cradle1412 can be moved along thefirst arm1404. As an example, the firstadjustable charging cradle1412 can be held into position using a set screw and can be moved along a groove positioned in thefirst arm1404. Thefirst charging area1412 can be adjusted to be located near or next to a charging area of the electro-active spectacles100. Thefirst charging area1412 can include an indicative charger to inductively charge an inductive charging region of the electro-active spectacles100. As an example, the electro-active spectacles100 can include an inductive charger region within an electronic module as described above. To recharge the electro-active spectacles100, the firstadjustable charging area1412 can be positioned to be in close proximity with the inductive charging region of the electro-active spectacles100.
Correspondingly, the secondadjustable charging cradle1414 can be moved along thesecond arm1406. As an example, the secondadjustable charging cradle1414 can be held into position using a set screw and can be moved along a groove positioned in thesecond arm1406. Thesecond charging area1414 can be adjusted to be located near or next to a charging area of the electro-active spectacles100. Thesecond charging area1414 can include an inductive charger to inductively charge an inductive charging region of the electro-active spectacles100. To recharge the electro-active spectacles100, the secondadjustable charging area1414 can be positioned to be in close proximity with the inductive charging region of the electro-active spectacles100.
As shown inFIG. 14, theslim line charger1400 can be used to recharge two electronic modules. Theslim line charger1400 can also be used to charge electro-active spectacles100 having a single electronic module. By allowing the first and secondadjustable charging areas1412 and1414 to move, theslim line charger1400 can be used to recharge a wide variety of frame sizes and styles. That is, since frames sizes may vary for different users, the recharging area of the frames may be located in different positions relative to thefront member1402. Accordingly, the first and secondadjustable charging areas1412 and1414 can be moved to line up or be close to these charging areas. Overall, theslim line charger1400 can support any frame type—fully-rimmed, partially-rimmed and rimless—and any frame size or shape.
As an alternative to inductive charging, thecharger1400 can be used to charge electro-active spectacles directly. That is, thecharger1400 can include a conductive link that can be used to plug into electro-active spectacles to transfer power directly rather than inductively.
The chargingstate indicator1410 can change states to indicate a change in the charging status of the electro-active spectacles100. For example, the chargingstate indicator1410 can have a first state to indicate thecharger1400 is not charging (e.g., an off state), a second state to indicate thecharger1400 is recharging the electro-active spectacles100 (e.g., a charging state), and a third state to indicate thecharger1400 has completed or fully recharged the electro-active spectacles100 (e.g., a charged or completed state). Theslim line charger1400 can include a rechargeable power supply to enable charging of electro-active spectacles100 when the charger is not connected to a power supply source (e.g., a wall outlet) directly. Theslim line charger1400 can include a port to connect thecharger1400 to a power supply (e.g., a wall outlet). Theslim line charger1400 can therefore charge the electro-active spectacles100 when either plugged into or not plugged into a power source.
FIG. 15 illustrates a side view of theslim line charger1400. As shown inFIG. 15, the electro-active spectacles can be stabilized or supported by thecharger1400 at three locations—a front portion of the spectacles100 (at or near the lenses of the electro-active spectacles100), a right side temple area of the frame of the electro-active spectacles100 (shown inFIG. 15), and a left side temple area of the frame of the electro-active spectacles100 (not shown inFIG. 15). The secondadjustable charging area1414 can be moved laterally to be in close proximity with any portion of the front temple area of the electro-active spectacles100 (i.e., to place the secondadjustable charging area1414 in close proximity to an inductive charging area of the electro-active spectacles100).
FIG. 16 illustrates theslim line charger1400 in a closed positioned. Specifically, the first andsecond arms104 and1406 have been rotated and positioned adjacent and parallel to thebase member1402. A hinge or lock or other device can be used to lock each of the first andsecond arms1404 and1406 in place. Thecharger1400 can include a button, knob or other device to release the first andsecond arms1404 and1406 from their closed, locked positions.
Aspects of the present invention also include a charger case for electro-active spectacles having a top cover and a bottom cover as is found with conventional eyeglass cases. The charger case of the present invention can include one or more inductive charge regions and a power source. The power source of the charger case of the present invention can be rechargeable.
CONCLUSIONWhile various embodiments of the present invention have been described above, it should be understood that they have been presented by way of example and not limitation. Any conductive element described above (e.g., the upper or lower portions of the frame) can be entirely conductive (and possibly coated with non-conductive material) or can contain an embedded or buried conductive element (e.g., a conductive core) and a non-conductive outer or surrounding layer. Further, any conductive link—e.g., described or referred to as an electrical wire or connection—could alternatively, or in addition thereto, be or include an optical conductive link as will be apparent to one skilled in the pertinent art. The exemplary techniques for coupling or connecting the electrical elements of the electro-active spectacles of the present invention (e.g., the controlling electronics and power supplies and electro-active lenses) using embedded conductive links can be used to embed one or more conductive optical links (e.g., one or more optical fibers) as will be apparent to one skilled in the pertinent art.
Overall, it will be apparent to one skilled in the pertinent art that various changes in form and detail can be made therein without departing from the spirit and scope of the invention. Therefore, the present invention should only be defined in accordance with the following claims and their equivalents.