Patent Document

CROSS-REFERENCE TO RELATED 
     The present application is a divisional of U.S. patent application Ser. No. 13/603,986, filed Sep. 5, 2012, now U.S. Pat. No. 8,553,408, issued on Oct. 8, 2013, which claims priority from U.S. Patent Application No. 61/531,316, filed Sep. 6, 2011. The content of each of the aforementioned applications is hereby incorporated herein by reference in its entirety. Priority to each of the aforementioned applications is hereby expressly claimed in accordance with 35 U.S.C. §§119, 120, 365, 371 and any other applicable statutes. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present description relates generally to docking stations for mobile electronic devices, and in particular to methods and systems for docking and providing power mobile electronic devices. 
     2. Description of the Related Art 
     Many types of conventional docking stations and mounts exist for mobile electronic devices. Often, the docking station requires that the mobile electronic device be carefully plugged in to a mating connector each time the mobile electronic device is docked. Lack of care during the docking process can lead to damage to the docking station or mobile electronic device. To prevent this damage, the docking station may be constructed with a cavity or well to receive the mobile electronic device. The cavity or well of the docking station may help prevent damage due to lack of care during docking but do not prevent long time wear and tear on the docking station and the mobile electronic device mating connectors. 
     Recently, both conductive and inductive mats have been developed such as the WildCharge conductive charging mat the PowerMat inductive charging mat. The conductive and inductive charging mats often require that the mobile electronic device be inserted in a sleeve. The WildCharge mat is much larger than the WildCharge sleeve and the mobile electronic device. The PowerMat uses a slight well to receive the mobile electronic device and to position the mobile electronic device properly while charging. Charging mats are intended to be used on a relatively flat and horizontal surface and the mobile electronic device is not easily used while charging. Existing inductive chargers have been developed for low power devices that require 1 amp or less of charging current. Mobile electronic devices such as the Apple iPad require up to 2.1 amp of charging current so existing charging mats can&#39;t be used to charge the iPad. Certain inductive charging stations require that the device being charged be at a fixed orientation. 
     Non-charging mounts for mobile electronic devices have also been developed that allow the mobile electronic device to be held and operated in multiple orientations. The mounts require a cable from an external charger be plugged in to the mobile electronic device to charge or maintain a charge during use. The use of a charging cable in this type of mount restricts the movement or position of the mobile electronic device and will create the possibility of wear or damage to the mobile electronic devices charging connector and charging cable. 
     Semi-permanent mounts with integrated charging have also been developed such as the iPort CM-IW2000 that allow mobile electronic devices such as the iPad to be wall mounted and remain fully charged. The CM-IW2000 holding the iPad remains fixed in one position or orientation that is determined at the time the mounting hole for the CM-IW2000 is cut in a wall. The CM-IW2000 utilizes magnets to firmly secure the iPad in the mount and was not designed to allow the iPad to be removed easily and used as a mobile device. 
     SUMMARY OF THE INVENTION 
     The following presents a simplified summary of one or more aspects in order to provide a basic understanding of such aspects. This summary is not an extensive overview of all contemplated aspects, and is intended to neither identify key or critical elements of all aspects nor delineate the scope of any or all aspects. Its sole purpose is to present some concepts of one or more aspects in a simplified form as a prelude to the more detailed description that is presented later. 
     An example embodiment provides a mounting component for use in a docking system for a mobile electronic device, the mounting component comprising: a mounting portion removably coupleable to a mounting section of the docking system for coupling a mobile electronic device to the docking system, the mounting portion comprising: a coupling mechanism configured to removably couple the mounting portion to the mounting section, a mounting surface that extends along a plane generally parallel to a base surface of the mounting component, one or more indexing members disposed along at least a portion of the mounting surface of the mounting portion, said indexing members configured to removably engage one of a plurality of corresponding indexing elements on the mounting section to align the mounting section with the mounting portion in one or more rotational orientations on said plane, and a coil, wherein the coil is configured to inductively communicate power from a power source included in the docking system at a plurality of orientations in said plane. 
     Optionally, the mounting portion is pivotable relative to a horizontal plane to one or more angular positions that define a different angle between the mounting surface and the horizontal plane. Optionally, said mounting portion protrudes from said base surface, and a circumference of the mounting portion is circular in shape and defined about a central axis of symmetry. Optionally, the coupling mechanism comprises a magnet configured to exert a magnetic force between the mounting portion and the mounting section to maintain the mounting portion coupled to the mounting section, wherein the magnetic force on the mounting section is in an amount sufficient to maintain the mounting section coupled to the mounting portion while adjusting the rotational orientation of the mounting section relative to the mounting portion. Optionally, the coupling mechanism comprises a magnet configured to exert a magnetic force between the mounting portion and the mounting section to maintain the mounting portion coupled to the mounting section and the magnet is configured to exert a magnetic force on the mounting section in an amount sufficient to maintain the mounting section coupled to the mounting portion while adjusting the rotational orientation of the mounting section relative to the mounting portion, wherein the mounting portion is configured to attach to a wall and the magnet is configured to exert a magnetic force between the mounting portion and mounting section in an amount sufficient to maintain the mobile electronic device, including a display thereon, in a generally vertical orientation. Optionally, the coupling mechanism is configured to maintain the mounting section coupled to the mounting portion and to facilitate an electrical connection between the mounting portion and the mounting section. Optionally, the one or more indexing members comprise a plurality of protrusions on the mounting surface and the protrusions are spaced apart along at least a portion of a circumference of the mounting surface to align the mounting section with the mounting portion in one or more discrete rotational orientations on said plane. Optionally, the mounting portion is coupled to the mounting section of the docking system, the coil is configured to inductively communicate power from the power source included in the mounting section regardless of the mounting component&#39;s orientation in said plane. Optionally, the mounting component further comprises at least one exposed electrical contact configured to be in electrical communication with at least one exposed electrical contact on the mounting section. Optionally, the mounting component further comprises a sleeve configured to removably receive the mobile electronic device. 
     An example embodiment includes a docking system for a mobile electronic device, comprising: a mounting portion removably attachable to a support surface, the mounting portion comprising a mounting surface that extends along a plane generally parallel to a base surface of the mounting portion; a mounting section on a rear surface of a mobile electronic device, the mounting section having a shape corresponding to a shape of the mounting portion and removably coupleable to the mounting portion via a coupling mechanism to support the mobile electronic device on the support surface, wherein one of the mounting portion and mounting section comprises one or more indexing members and the other of the mounting portion and mounting section comprises one or more indexing elements, the indexing members and elements configured to engage each other to align the mounting section with the mounting portion in one or more rotational orientations on said plane; and a detector configured to detect the presence of the mounting portion or the mobile electronic device; a driver circuit; a first device configured to control the sourcing of power to the mobile electronic device by the driver circuit at least partly in response to the detector detecting the presence of the mounting portion or the mobile device. 
     Optionally, the mounting section is disposed on a sleeve removably attachable to the mobile electronic device. Optionally, the mounting section is disposed on a sleeve removably attachable to the mobile electronic device and the sleeve comprises one or more heat sinks configured to dissipate heat generated by one or both of a charging circuit of the sleeve and the mobile electronic device. Optionally, the mounting portion is pivotable relative to a horizontal plane to one or more angular positions that define a different angle between the mounting surface and the horizontal plane. Optionally, one of the mounting portion and mounting section defines a male component and the other of the mounting portion and mounting section defines a female component, the female component configured to removably receive the male component to couple the mounting portion to the mounting section, and a circumference of the mounting portion and mounting section is circular in shape and extends about a central axis. Optionally, the coupling mechanism comprises a magnet on one of the mounting portion and mounting section, the magnet configured to exert a magnetic force between the mounting portion and mounting section to maintain the mounting portion coupled to the mounting section, wherein the magnetic force is in an amount sufficient to maintain the mounting section coupled to the mounting portion while adjusting the rotational orientation of the mounting section relative to the mounting portion. Optionally, the coupling mechanism comprises a magnet on one of the mounting portion and/or the mounting section, the magnet configured to exert a magnetic force between the mounting portion and mounting section to maintain the mounting portion coupled to the mounting section and the magnet is configured to exert a magnetic force in an amount sufficient to maintain the mounting section coupled to the mounting portion while adjusting the rotational orientation of the mounting section relative to the mounting portion, wherein the mounting portion is configured to attach to a wall and the magnet is configured to exert a magnetic force between the mounting portion and mounting section in an amount sufficient to maintain the mobile electronic device, and a display thereon, in a generally vertical orientation. Optionally, said indexing members and indexing elements align the mounting portion and mounting section so as to align an electrical connection between the mounting portion and mounting section. Optionally, one of the indexing members and indexing elements comprises a plurality of protrusions and the other of the indexing members and indexing elements comprises a plurality of indentations sized to engage the protrusions and the protrusions and indentations are spaced apart along at least a portion of a circumference of the mounting portion and mounting section so as to align the mounting section with the mounting portion in one or more discrete rotational orientations on said plane. Optionally, the mounting portion includes a first coil coupled to the driver circuit and the mounting section includes a second coil configured to inductively receive power from the first coil. Optionally, the mounting portion includes a first coil coupled to the driver circuit and the mounting section includes a second coil configured to inductively receive power from the first coil, wherein the second coil is configured to inductively receive power from the first coil regardless of the mounting section&#39;s orientation in said plane. 
     An example embodiment includes a mounting base comprising: a mounting component, the mounting component including a receiving area configured to removably receive a mating device at a plurality of orientations within a plane, wherein the mounting component comprises one or more indexing members and the mating device comprises one or more indexing elements, or the mating device comprises one or more indexing members and the mounting component comprises one or more indexing elements, the indexing members and elements configured to engage each other to align the mating device with the mounting component in one or more rotational orientations on said plane; and a detector configured to detect the presence of the mating device; a driver circuit; a first device configured to control the sourcing of power to the mating device by the driver circuit at least partly in response to the detector detecting the presence of the mating device. 
     Optionally, the mating device comprises a sleeve configured to receive a tablet computing device. Optionally, the mating device comprises a tablet computer or a phone. Optionally, the mounting base further comprises a driver coil coupled to the driver circuit, wherein the driver coil is configured to inductively provide power from the driver circuit to the mating device while the mating device is located at the receiving area. Optionally, the mounting base is configured to conductively provide power from the driver circuit to the mating device while the mating device is located at the receiving area. Optionally, the first device is configured to cause, at least in part, the driver circuit to operate in a low power mode when the detector fails to detect a proper positioning of the mating device with respect to the receiving area. Optionally, the detector magnetically senses the presence of the mating device. Optionally, a circumference of the receiving area is circular in shape and defined about a central axis of symmetry. Optionally, the mounting component comprises a magnet or a ferrous metal configured to magnetically couple the mounting base to the mating device. 
     An example embodiment includes a docking system including a sleeve and base. The sleeve may be a form fitted sleeve for a mobile electronic device. The base may be configured to hold the sleeve at multiple planes and/or multiple orientations within a single plane. The base may be a table top base. The sleeve is supported on the base using mechanical design features and or magnetic force. The docking system includes at least one indention and the at least one corresponding protrusion for locating the desired position of the sleeve on the base when docking and to allow rotation of the sleeve to alternative operating positions on axis after the sleeve is docked. The sleeve includes a connector port interface to the mobile electronic device. The base includes a connector port interface to an external power source. The docking system optionally includes an inductive charging function for the battery within the mobile electronic device. 
     An example embodiment includes a docking system including a sleeve and base. The docking system includes a sleeve and base. The sleeve may be a form fitted sleeve for a mobile electronic device. The base may be configured to hold the sleeve at multiple planes and/or multiple orientations within a single plane. The sleeve is supported on the base using mechanical design features and/or magnetic force. The base may be a table top base. The sleeve is supported on the base using mechanical design features and/or magnetic force. The docking system may include at least one indention and the at least one corresponding protrusion for locating the desired position of the sleeve on the base when docking and to allow rotation of the sleeve to alternative operating positions on axis after the sleeve is docked. The sleeve includes a connector port interface to the mobile electronic device. The base includes a connector port interface to an external power source. The docking system includes a conductive charging function for the battery within the mobile electronic device. 
     An example embodiment includes a docking system including a sleeve and base. The sleeve may be a form fitted sleeve for a mobile electronic device and the base may be configured to hold the sleeve at multiple orientations within a single plane. The sleeve is supported on the base using mechanical design features and/or magnetic force. The base may be an in-wall base. The sleeve is supported on the base using mechanical design features and/or magnetic force. The docking system includes at least one indention and the at least one corresponding protrusion for locating the desired position of the sleeve on the base when docking and to allow rotation of the sleeve to alternative operating positions on axis after the sleeve is docked. The sleeve includes a connector port interface to the mobile electronic device. The base includes a connector port interface to an external power source. The docking system optionally includes an inductive charging function for the battery within the mobile electronic device. 
     An example embodiment includes a docking system including a sleeve and base. The sleeve may be a form fitted sleeve for a mobile electronic device and the base may be configured to hold the sleeve at multiple orientations within a single plane. The sleeve is supported on the base using mechanical design features and/or magnetic force. The base may be an in-wall base. The sleeve is supported on the base using mechanical design features and/or magnetic force. The docking system includes at least one indention and the at least one corresponding protrusion for locating the desired position of the sleeve on the base when docking and to allow rotation of the sleeve to alternative operating positions on axis after the sleeve is docked. The sleeve includes a connector port interface to the mobile electronic device. The base includes a connector port interface to an external power source. The docking system optionally includes a conductive charging function for the battery within the mobile electronic device. 
     An example embodiment includes a docking system including a sleeve and base. The sleeve may be a form fitted sleeve for a mobile electronic device and the base may be configured to hold the sleeve at multiple orientations within a single plane. The sleeve is supported on the base using mechanical design features and/or magnetic force. The base may be a flat surface base. The sleeve is supported on the base using mechanical design features and/or magnetic force. The docking system includes at least one indention and the at least one corresponding protrusion for locating the desired position of the sleeve on the base when docking and to allow rotation of the sleeve to alternative operating positions on axis after the sleeve is docked. The sleeve includes a connector port interface to the mobile electronic device. The base includes a connector port interface to an external power source. The docking system optionally includes an inductive charging function for the battery within the mobile electronic device. 
     An example embodiment includes a docking system including a sleeve and base. The sleeve may be a form fitted sleeve for a mobile electronic device and the base may be configured to hold the sleeve at multiple orientations within a single plane. The sleeve is supported on the base using mechanical design features and/or magnetic force. The base may be a flat surface base. The sleeve is supported on the base using mechanical design features and/or magnetic force. The docking system optionally includes at least one indention and the at least one corresponding protrusion for locating the desired position of the sleeve on the base when docking and to allow rotation of the sleeve to alternative operating positions on axis after the sleeve is docked. The sleeve includes a connector port interface to the mobile electronic device. The base includes a connector port interface to an external power source. The docking system includes a conductive charging function for the battery within the mobile electronic device. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The disclosed aspects will hereinafter be described in conjunction with the appended drawings, provided to illustrate and not to limit the disclosed aspects, wherein like designations denote the elements. 
         FIG. 1  is a block diagram of an example docking system inductive charging circuitry; 
         FIG. 2  is a front perspective view of an example docking system with table top base; 
         FIG. 3  is a side view of an example docking system with table top base; 
         FIG. 4  is a front perspective view of an example docking system table top base; 
         FIG. 5  is a front perspective view of an example docking system table top base without cover; 
         FIG. 6A  is a front perspective exploded view of an example docking system with in-wall base with sleeve in landscape position; 
         FIG. 6B  is a front perspective exploded view of an example docking system with in-wall base with sleeve in portrait position; 
         FIG. 7  is a front perspective view of an example docking system in-wall base; 
         FIG. 8  is a front perspective view of an example docking system sleeve and mobile electronic device; 
         FIG. 9  is a front perspective exploded view of an example docking system sleeve; 
         FIG. 10  is a rear perspective view of an example docking system sleeve; 
         FIG. 11  is a rear perspective view of an example docking system sleeve without cover; 
         FIG. 12  is a side view of an example docking system with an adjustable base; 
         FIG. 13  is a rear perspective view of an example docking system conductive charging sleeve; 
         FIG. 14  is a side perspective view of an example docking system conductive base; 
         FIG. 15  is a block diagram of an example docking system conductive charging electronics; 
         FIG. 16  is a simplified flow chart of an example process. 
     
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Disclosed herein are methods and systems of powering and/or charging mobile device. Certain embodiments provide a mobile device docking station that enables power to be provided to a mobile device at multiple orientations. Certain embodiments of the docking station are configured to charge a mobile device battery. Certain embodiments of the docking station are configured to supply power to the mobile device inductively and/or conductively. 
     In view of the deficits of conventional docking systems, such as those discussed above, there is a need for an improved docking system for mobile electronic devices that does not require plugging charging cables or docking connectors every time the mobile electronic device is charged, allows ease of use of the mobile electronic device during charging, permits multiple orientations of the device and allows the mobile electronic device to remain mobile and easily docked and unlocked without excessive care. 
     Embodiments of a docking system is disclosed. As described in greater detail below, in certain embodiments, the docking system may include a sleeve and base. The sleeve may be a form fitted sleeve for a mobile electronic device. The base may be configured to hold the sleeve at multiple planes and or multiple orientations within a single plane. The sleeve is supported on the base using mechanical design features and/or magnetic force. The docking system may include at least one indention and at least one corresponding protrusion for locating the desired position of the sleeve on the base when docking and to allow rotation of the sleeve to alternative operating positions on axis after the sleeve is docked. The sleeve may include a connector port interface to the mobile electronic device. The base may include a connector port interface to an external power source. The docking system may include a conductive and/or inductive charging function for the battery within the mobile electronic device. 
     Referring to the drawings  FIG. 1 , is a simplified block diagram of inductive charging electronics for a docking system. The use of an inductive charging circuit in a docking station provides improvement over docking stations that require that the mobile electronic device be plugged in to a connector or cable that provides charging. Inductive charging is an improved method of charging that does not require electrical conducting connectors between the base  10  and the sleeve  9 . 
     Referring more particularly to  FIG. 1 , AC power  1  may be used provide a source of power for a docking system, AC power  1  may range for example from 90 V AC to 240 V AC at 50 Hz to 60 Hz depending on where you are located in the world, other AC power voltages and frequencies may also be used. The external power supply  2  receives input AC power for example of 90 V AC to 240 V AC at 50 Hz to 60 Hz from AC power  1 . The external power supply can be a wall mounted unit that is plugged directly in to an AC power  1  outlet and may use country specific plug adapters to mate with the style of AC power  1  outlet. A power source such as an external power supply  2  provides input power for the driver board  3  of the docking system base  10 . A DC power input from a battery system in a vehicle such as an automobile could also be used in place of the AC power and external power supply to provide input to the driver board  3 . The driver board  3  is used to drive electrical current in to the driver coil  4  at a frequency range for example of 60 KHz to 130 KHz, other frequencies may be used. The driver board  3  may be implemented using a small programmable micro controller allowing use of various sensor inputs and allow various modes of operation. A sensor may be included on the driver board  3  or within the base  10  that senses when the sleeve  9  is docked on the base  10 . A magnetic sensor on the driver board  3  or base may be used to detect the magnetic field from a permanent magnet in the sleeve  9  as an indication that the sleeve  9  has been docked on the base  10 . A current sensor may be included on the driver board  3  and used to detect the change in driver board  3  current when the sleeve  9  is docked on the base  10 . The base  10  may use the detection of the sleeve  9  to change the operating mode of the driver board  3 . The driver board  3  may have several operating modes including a power saving low power sleep mode when the sleeve  9  is not docked on the base  10 . 
     The low power mode, for example, may draw less than 1 W of power from the AC power input when the sleeve  9  is not docked on the base  10 . The driver board  3  may also use a current sensor to determine when to change charging modes and also to monitor and control the charging of the mobile electronic device  7 . The mobile electronic device  7  may require much more current to recharge the mobile electronic device&#39;s batteries when the batteries are very low. The driver board  3  may sense the current need of the mobile electronic device  7  using a current sensor and vary the driver board  3  drive current as needed. 
     The driver board  3  may also include a temperature sensor. A temperature sensor may be used by the driver board  3  to change operating modes of the driver board  3  based on ambient temperatures. The driver board  3  may change operating modes to a low power mode if high ambient or driver board  3  temperature is detected. 
     The docking system may be designed to pass radiated emission and conducted emission FCC specifications. The driver board  3  may cause undesired excessive radiated and conducted emissions when driving current to a driver coil  4  during charging. To minimize or reduce radiated emissions and conducted emissions caused by driving current to a driver coil  4 , the frequency of the driver board  3  coil drivers may be varied within the optimum operating frequency range of the docking system reducing peak level of measured emissions. 
     The driver coil  4  may consist of multiple turns of wire. Multi-strand wire may be used for the driver coil  4 . The use of multi-strand wire for the driver coil  4  increases efficiency of the drive coil  4  and reduces heat generated by the drive coil  4 . The multi-strand wire used for the drive coil  4  may have individual strands of wire that are as thin as 40 A WG for example and may consist of 50 or more strands of wire. The drive coil  4  may further have multiple turns of wire forming the coil on the bobbin that held is by the ferrite pot core. The ferrite core helps focus the energy of the driver coil  4  to the receiver coil  5 . The use of a ferrite pot core with the drive coil  4  increases the power that may be transferred to the receiver coil  5  allowing the inductive charging circuit to achieve the higher current demands of devices such as an iPad for example a may need over 2 amps of charging current at 5 volts. 
     The receiver coil  5  may be located in the sleeve  9 . The receiver coil  5  may be implemented as a coil formed with etched copper using a printed circuit board. The use of a circuit board for the receiver coil  5  reduces the overall thickness of the receiver coil  5  and therefore reduces the space required for the receiver coil  5  within the sleeve  9 . The receiver coil  5  may use both outer surfaces of the receiver coil  5  printed circuit board when fabricated using double sided copper clad printed circuit board material. The receiver coil  5  may alternately be fabricated using multilayer printed circuit board material allowing the turns of the receiver coil  5  represented in etched copper be placed in series therefore increasing the turns of the receiver coil  5  and increasing the receiver coil  5  AC voltage level that is determined by the ratio of the receiver coil  5  windings to driver coil  4  windings or in parallel reducing the resistance of the receiver coil  5  therefore increasing the receiver coil  5  current carrying capability and reducing the receiver coil  5  heat caused by the current flow during charging the mobile electronic device  7  resulting in a voltage drop caused by resistance of the receiver coil  5 . A flat piece of ferrite material may be placed on the side of the receiver coil  5  printed circuit board that is most distant from the driver coil  4  when the sleeve  9  is docked on a base  10 . A flat ferrite piece on the back of the receiver coil  5  may be used to increase the efficiency of the transfer of power between the driver coil  4  and the receiver coil  5  over the space or gap between the two coils. The receiver coil  5  may also fabricated using copper wire wound to form a coil and backed with a flat piece of ferrite material. 
     The main board  6  may be located in a sleeve  9  receives the AC input from a receiver coil  5 . A capacitor may be used in parallel with the receiver coil  5  to for near to resonance operation of the receive circuit. At resonance the transfer function of energy to the receive coil may approach 1 and therefore increase the efficiency of the inductive charging circuit allowing the circuit to deliver the higher charging currents required by mobile electronic devices such as the iPad. The AC input from a receiver coil  5  may be rectified in to unregulated DC voltage by a full wave bridge on a main board  6 . The unregulated DC voltage from the bridge rectifier may be used as the input for a DC to DC switching power regulator circuit on the main board  6 . 
     The use of a switching power regulator on a main board  6  may improve the efficiency for example from 20% to nearly 90% of the conversion of unregulated DC voltage input to regulated voltage output over the use of conventional linear voltage regulators. The switching power regulator may be configured to output regulated +5 VDC output or other voltage for charging a mobile electronic device  7 . The output of a main board&#39;s  6  regulated DC output is used as the input to a connector board  8 . The connector board  8  may be located in the sleeve  9  and may include a mating connector  27  for the charging port on the mobile electronic device  7 . The connector board  8  may also include a connector that is accessible from the outside of the sleeve  9  that allows an alternate method to charge the mobile electronic device  7  using a conventional charger. 
     The mobile electronic device  7  charging port may plug in to a mating connector on the connector board  8  when a mobile electronic device  7  inserted in to the sleeve  9 . The sleeve  9  may be intended to remain in place on the mobile electronic device  7  semi-permanently and does not need to be removed for normal use of the mobile electronic device  7 . The sleeve  9  may be form fitting and also may provide a level of increased protection for the mobile electronic device  7 . The mobile electronic device  7  installed in the sleeve  9  may be placed on the base  10  to charge the mobile electronic device  7 . Optionally, no additional plugging of cables or connectors are required to charge the mobile electronic device  7  when installed in the sleeve  9  and placed on the base  10  that is receiving power from an external power supply  2 . The driver coil  4  of the base  10  may need to be aligned properly with the receiver coil  5  in the sleeve  9  to properly transfer power and allow charging of the mobile electronic device  7 . 
     Smaller magnets  35  in the sleeve  9  may be used to attract to ferrous metal in the base  10 . A combination of magnetic force and mechanical design features of a base  10  and a sleeve  9  may be used to enable the sleeve  9  to be easily docked properly aligning the receiver coil  5  and the driver coil  4  on the base  10  without excessive care from the intended user. The mechanical design features of the base  10  and the sleeve  9  also allow the sleeve  9  to be rotated to any position within a single plane while a sleeve  9  is installed on the base  10 . The magnetic force may be used to hold the base  10  and sleeve  9  together with enough force to allow the mobile electronic device  7  to be used normally while docked. The magnetic force between the sleeve  9  and base  10  may be such that it is not strong enough to prevent the mobile electronic device  7  held in the sleeve  9  from easily being undocked by a user and used as a mobile device. 
     Referring to the drawing  FIG. 2 , is a front perspective view of a docking system with table top base. 
       FIG. 2  shows the docking system when the sleeve  9  and the mobile electronic device  7  is docked on the base  10 . The base  10  may be constructed to hold the sleeve  9  and the mobile electronic device at any angle that allows the mobile electronic device  7  to be easily used while docked on a base  10 . The base  10  may have weight added for stability of the docking system. The sleeve  9  holding the mobile electronic device  7  may be rotated to any position within a single plane while the sleeve  9  is docked on the base  10 . The base  10  may alternately be constructed as a free standing module with a mating surface for the sleeve  9  at any useful angle or with a mating surface for the sleeve  9  that allows the mating surface angle or plane to be adjustable. 
     Referring to the drawing  FIG. 3 , is a side view of a docking system with table top base.  FIG. 3  shows a docking system when a sleeve  9  is docked on a base  10 . 
     Referring to the drawing  FIG. 4 , is a front perspective view of a docking system table top base. The base  10  may have protrusion  11 . The protrusion  11  may be circular or other shapes may be used. The base  10  may have a protrusion  11  that may be used to mate with an indention  31  on the sleeve  9  when the sleeve  9  is docked on the base  10 . The base  10  may also have smaller protrusions  12  that mate with smaller indentions  32  on the sleeve  9 . The smaller protrusions  12  may be circular or other shapes may be used. Mobile electronic devices  7  may have user displays that may be orientated in portrait or landscape positions. Mobile electronic devices  7  may automatically change the orientation of the user screen based on how the mobile electronic device  7  is being held. The smaller protrusions  12  on a base  10  may be used to easily locate desired operating positions of the mobile electronic device  7  when docked on the base  10 . The protrusion  11  may include a driver coil  4  cover  13 . The driver coil cover  13  may be made of durable material and thin allowing the driver coil  4  of the base  10  to be located near the surface that will mate with the indention  31  of the sleeve  9 . The base  10  housing may be made of aluminum and fabricated using an extrusion process. 
     The base  10  housing may be made of plastic. The base  10  may have side panels  14  made of plastic. In this example, the base  10  has protrusions and the sleeve  9  has indentations. In other embodiments, the base  10  may have indentations and the sleeve  9  may have protrusions. In other embodiments, the base  10  may have both protrusions and indentations and the sleeve  9  may have both protrusions and indentations. 
     Referring to the drawing  FIG. 5 , is a front perspective view of a docking system table top base with the driver coil cover  13  shown in  FIG. 4  removed. When the driver coil cover  13  is removed the driver coil  4  pot core  15  and bobbin  16  are exposed. Ferrous material in the base  10  is used to attract and hold the sleeve  9  when docked. Metal screws  17  may serve two purposes, the first purpose may be to secure the components making up the protrusion  11  assembly to the base  10 , the second purpose may be the ferrous material of the screws  17  are attracted to the smaller magnets  34  in the sleeve  9  and hold the sleeve  9  to the base  10  while the sleeve  9  is docked. 
     Referring to the drawings  FIGS. 6A and 613 , are front perspective exploded views of a docking system in-wall base with the sleeve in landscape position  FIG. 6A  and portrait position  FIG. 6B . The sleeve  9  may be docked to the base  10  in multiple positions within a single plane.  FIG. 6A  show a sleeve  9  in the portrait position. The mobile electronic device  7  held in the sleeve  9  may automatically change the orientation of its user touch screen to the landscape position when rotated as shown in  FIG. 6A  or to the portrait position as shown in  FIG. 6B . The in-wall base  19  may be very similar to the table top base  10  described in  FIG. 1  through  FIG. 5 . The in-wall base  19  may have a protrusion  11  that may be used to mate with the indention  31  on the sleeve  9  when a sleeve  9  is docked on a base  19 . The protrusion  11  may be circular or other shapes may be used. The base  19  may also have smaller protrusions  12  that mate with indentions  32  on the sleeve  9 . The smaller protrusions  12  may be circular or other shapes may be used. 
     Mobile electronic devices  7  may have user displays that may be orientated in portrait or landscape positions. Mobile electronic devices  7  may automatically change the orientation of the user screen based on how the mobile electronic device  7  is being held. The smaller protrusions  12  on the base  19  may be used to easily locate typical operating positions of the mobile electronic device  7  when docked on the base  19 . The protrusion  11  may include the driver coil cover  13 . The driver coil cover may be made of durable material and thin allowing a driver coil  4  of the base  19  to be located near the surface that will mate with the indention  31  of the sleeve  9 . The base  19  housing may be made of ferrous material. The base  19  housing may be made of plastic. Ferrous material may be used to fabricate the base  19  outer ring  18 . The outer ring when made of ferrous material may be used to attract larger magnets  34  in the sleeve  9  to the base  19  and hold the sleeve  9  and mobile device securely. A simplified representation of a wall is shown. Standard wall material such as drywall may be used for  20  and  21 . Wood or metal studs  21  may be used to support sheets of drywall forming wall in a home or building. The in-wall base  19  may be mounted in a wall and occupying space created by the studs  21  separating the sheets of drywall  20  and  21 . 
     The in-wall base  19  when installed in a wall is nearly flush with the surface of the drywall  20 . The base  19  may be installed in a vertical wall or a horizontal surface. Horizontal and vertical surfaces where the base  19  may be mounted maybe found in homes, buildings and vehicles such as automobiles, motor homes, boats and aircraft. The base  19  may be constructed as a free standing module with a mating surface for the sleeve  9  at any useful angle or with a mating surface for the sleeve  9  that allows the mating surface angle or plane to be adjustable. In this example, the base  19  has protrusions and the sleeve  9  has indentations. In other embodiments, the base  19  may have indentations and the sleeve  9  may have protrusions. In other embodiments, the base  19  may have both protrusions and indentations and the sleeve  9  may have both protrusions and indentations. 
     Referring to the drawing  FIG. 7 , is a front perspective view of a docking system in-wall base. The in-wall base  19  may be very similar to the table top base  10  described in  FIG. 1  through  FIG. 5 . The in-wall base  19  may have a protrusion  11  that may be used to mate with an indention  31  on the sleeve  9  when the sleeve  9  is docked on the base  19 . The protrusion  11  may be circular or other shapes may be used. The base  19  may also have smaller protrusions  12  that mate with indentions  32  on the sleeve  9 . The smaller protrusions  12  may be circular or other shapes may be used. Mobile electronic devices  7  may have user displays that may be orientated in portrait or landscape positions. Mobile electronic devices  7  may automatically change the orientation of the user screen based on how the mobile electronic device  7  is being held. The smaller protrusions  12  on the base may be used to easily locate typical operating positions of the mobile electronic device  7  when docked on the base  19 . The protrusion  11  may include the driver coil cover  13 . The driver coil cover  13  may be made of durable material and thin allowing the driver coil  4  of the base  19  to be located near the surface that will mate with the indention  31  of the sleeve  9 . 
     The base  19  housing may be made of ferrous material. The base  19  housing may be made of plastic. Ferrous material may be used to fabricate the base  19  outer ring  18 . The outer ring  18  when made of ferrous material may be used to attract larger magnets  34  in the sleeve  9  to the base  19  and hold the sleeve  9  and mobile electronic device securely. A simplified representation of a wall is shown. Standard wall material such as drywall may be used for  20  and  21 . The in-wall base may be mounted in a wall and occupying space created by the studs  21  separating the sheets of drywall  20  and  21 . The in-wall base  19  when installed in a wall may be nearly flush with the surface of the drywall  20 . In this example, the base  19  has protrusions and the sleeve  9  has indentations. In other embodiments, the base  19  may have indentations and the sleeve  9  may have protrusions. In other embodiments, the base  19  may have both protrusions and indentations and the sleeve  9  may have both protrusions and indentations. 
     Referring to the drawing  FIG. 8 , is a front perspective view of a docking system sleeve and mobile electronic device. The sleeve  9  is used to hold a mobile electronic device  7 . The sleeve  9  may be made one or more parts. A sleeve  9  may have a longer part  24  that the mobile electronic device is placed into followed by the shorter part  23  that may be installed next completing the sleeve  9 . The sleeve  9  shorter part may have mechanical design feature that allow it to snap together with the larger part  24  of the sleeve  9 . The longer part  24  and shorter part  23  of the sleeve  9  may be made with plastic material and fabricated using a molding process. The sleeve  9  may have openings  26  that allow access to ports on the mobile electronic device  7  allowing accessories such as cables to be plugged in to the mobile electronic device  7  while it is held by the sleeve  9 . The sleeve  9  may have openings  25  that may be used to allow audio from speakers of the mobile electronic device  7  to exit the sleeve  9 . The openings  25  may also be used for ventilation of the mobile electronic device  7  while it is held in the sleeve  9 . The sleeve  9  may have an outer coating of soft touch paint or similar material. The use of soft touch paint or similar material may be used improve the users grip when holding the sleeve  9 . 
     Referring to the drawing  FIG. 9 , is a front exploded perspective view of a docking system sleeve. The sleeve  9  may be made one or more parts. The sleeve  9  may have a longer part  24  that the mobile electronic device is placed into followed by the shorter part  23  that may be installed next completing the sleeve  9 . The sleeve  9  shorter part may have mechanical design feature that allow it to snap together with the larger part  24  of the sleeve  9 . The mechanical snapping feature may be implemented using a ramped shaped part  28  and a hook shaped part  30 . The ramp shape part  28  may snap together with hook shaped part  30  when the sleeve  9  longer part  24  is mated with the sleeve  9  shorter part  23  mechanically holding the two parts together. The sleeve  9  may include an electrical connector port  27  that mates with the charging port on mobile electrical device  7  when the mobile electrical device  7  is installed in the sleeve  9 . The sleeve longer part may have a cover  29 . The cover  29  provides a cover for the receiver coil  5 , the main board  6  and connector board  8  shown in  FIG. 1 . 
     Referring to the drawing  FIG. 10 , is a rear perspective view of a docking system sleeve. The sleeve  9  may have one or more parts. A sleeve  9  may have a longer part  24  and a shorter part  23 . The sleeve  9  may have  31  an indentation that may mate with the corresponding protrusion  11  on the base  10 . The indentation  31  may be circular or other shapes may be used. A sleeve  9  may have multiple smaller indentations  32  that may mate with the corresponding protrusions on the base  10  and may be used to locate useful positions of the mobile electronic device  7  when the mobile electronic device  7  is in the sleeve  9  and docked on the base  10 . The smaller indentations  32  may be circular or other shapes may be used. The sleeve  9  may have a magnet cover  33  that covers larger magnets  34  in the sleeve  9 . The magnet cover  33  is made of thin material that allows the larger magnets  34  in the sleeve  9  to be close to the ferrous material in the base  10 . The sleeve  9  may have a receiver coil cover  37  that covers the receive coil and smaller magnets  35  in the sleeve  9 . The receiver coil cover  37  may be made of thin material so the receiver coil  5  is near to the driver coil  4  of the base  10  and the sleeve  9  smaller magnets  35  are near to the ferrous material in the base  10 . A sleeve  9  may have a connection port that serves as an alternate method to charge the mobile electronic device  7  using a conventional charger and cable. 
     Referring to the drawing  FIG. 11 , is a rear perspective view of a docking system sleeve without cover. 
     The sleeve  9  may have one or more parts. A sleeve  9  may have a longer part  24  and a shorter part  23 . A receiver coil  36  may be fabricated as a printed circuit board as shown in  FIG. 11 . The receiver coil  36  may be thin when fabricated as a printed circuit board. Multiple smaller magnets  35  may be used to hold the sleeve  9  to the base  10 . Multiple larger magnets  34  may be used to hold the sleeve  9  to the base  10 . The larger magnets  34  may be used to provide magnetic force to hold the sleeve securely to the in-wall base housing  19  which may require more force than the table top base  10 . A sleeve  9  may have a connection port  26  that permits and alternate method to charge the mobile electronic device  7  using a conventional charger and cable. 
     Referring to the drawing  FIG. 12 , is a side view of a docking system with an adjustable base. The docking system may have a mechanical feature that allows the angle at which the sleeve  9  is supported to be adjustable to multiple angles or planes. For example, a hinge  50  or similar mechanical feature could be used to allow docking surface supporting the sleeve  9  to be adjustable to multiple angles. The hinge  50  may have enough mechanical resistance to motion, after adjusted to the desired angle by the user, so the mobile electronic device  7  held in the sleeve  9  can be used while docked on the base  51 . The mechanical resistance may be accomplished with the hinge  50  mechanical design and optionally include a locking feature that locks the angle of the docking surface  53  in place at multiple angles. The user could adjust the angle that the mobile electronic device  7  is held to an angle of their choice either before docking the sleeve  9  or after the sleeve  9  was docked. Ferrous material may be used in the base  51  and covered by the docking cover  52 . Magnets may be included in the sleeve  9 . The magnets in the sleeve  9  may be attracted to the ferrous material in the base  51  and hold the sleeve  9  to the base  51  while the sleeve  9  is docked on the base  51 . The sleeve  9  may rotate to multiple positions on axis within a single plane while docked on the base  51 . The docking surface  53  of the base  51  may be adjustable to multiple angles or planes. The docking cover  52  can be used to cover the method of charging the mobile electronic device  7 . Inductive or conductive charging may be included in the docking system. The docking system be used to just hold the sleeve  9  in some configurations and may not include charging in those configurations. 
     Referring to the drawing  FIG. 13 , is a rear perspective view of a docking system conductive charging sleeve. The docking system may use a conductive method to charge the mobile electronic device  7 . Conductive charging may include electrical receiver contacts  55  to provide a method to transfer electrical power used for charging the mobile electronic device  7  from the base  45  to the sleeve  38 . For example, the conductive charging sleeve  38  may have a receiver contact  40  located in the center of surface that mates with the base  45  when docked. The sleeve  38  may have a receiver contact that may be implemented as a conductive ring  42 . The receiver contacts  55  of the sleeve  38  may be made of conductive material and or plated with conductive material. 
     The conductive ring  42  may include small indentations  41 . The sleeve  38  may have an indentation  43  that may mate with the corresponding protrusion  48  on the base  45 . The indentation  38  may be circular or other shapes may be used. A sleeve  9  may have multiple smaller indentations  41  that may mate with the corresponding protrusions  47  on the base  45  and may be used to locate useful positions of the mobile electronic device  7  when the mobile electronic device  7  is rotated on axis while docked on the base  45 . The smaller indentations  41  may be circular or other shapes may be used. The sleeve  38  may have a magnet cover  33  that covers larger magnets  34  in the sleeve  38 . The magnet cover  33  is made of thin material that allows the larger magnets  34  in the sleeve  38  to be close to the ferrous material in the base  45  when the sleeve  38  is docked on the base  45 . The sleeve  38  may have a cover  39  that covers smaller magnets  35  in the sleeve  38 . The cover  39  may be made of thin material so the smaller magnets  35  in the sleeve  38  are near to the ferrous material in the base  45 . A sleeve  38  may have a connection port  26  that serves as an alternate method to charge the mobile electronic device  7  using a conventional charger and cable. In this example, the base  45  has protrusions and the sleeve  38  has indentations. In other embodiments, the base  45  may have indentations and the sleeve  38  may have protrusions. In other embodiments, the base  45  may have both protrusions and indentations and the sleeve  38  may have both protrusions and indentations. 
     Referring to the drawing  FIG. 14 , is a side perspective view of a docking system conductive base. The base  45  may have a protrusion  48  that may be used to mate with an indention  43  on the sleeve  38  when the sleeve  38  is docked on the base  45 . The protrusion  48  may be circular or other shapes may be used. 
     The base  45  may also have smaller protrusions  47  that mate with indentions  47  on the sleeve  38 . The smaller protrusions  47  may be circular or other shapes may be used. Mobile electronic devices  7  may have user displays that may be orientated in portrait or landscape positions. Mobile electronic devices  7  may automatically change the orientation of the user screen based on how the mobile electronic device  7  is being held. The smaller protrusions  47  on a base  45  may be used to easily locate desired operating positions of the mobile electronic device  7  when docked on the base  45 . The protrusion  48  may include a cover  49 . The cover  49  may be made of durable material and thin allowing ferrous material of the base  45  to be located near the surface that will mate with the indention  43  of the sleeve  38 . The sleeve  38  may have magnets in the indention  43  and be attracted to the ferrous material in the base  45 . The magnetic force of the magnets in the sleeve  38  may hold the sleeve  38  to the base  45  while docked. 
     The small protrusions  47  may be conductive. The small protrusions  47  may be plated with conductive material. The small protrusions may be spring loaded contact points that allow charging current to be transferred to contact points on the sleeve  38 . The base  45  may have a small protrusion  46  in the center of the large protrusion  48 . The small protrusion  46  may be conductive. The small protrusion  46  may be plated with conductive material. The small protrusion  46  may be a spring loaded contact point that allows charging current to be transferred to a contact point on the sleeve  38 . The base  45  housing may be made of aluminum and fabricated using an extrusion process. In this example, the base  45  has protrusions and the sleeve  38  has indentations. In other embodiments, the base  45  may have indentations and the sleeve  38  may have protrusions. In other embodiments, the base  45  may have both protrusions and indentations and the sleeve  38  may have both protrusions and indentations. 
     Referring to the drawing  FIG. 15 , is a simplified block diagram of conductive charging electronics for a docking system. The use of driver contacts and receiver contacts and a conductive charging circuit in a docking station provides improvement over docking stations that require that the mobile electronic device be plugged in to a connector or cable that provides charging. 
     Referring more particularly to  FIG. 15 , AC power  1  may be used provide a source of power for a docking system. AC power  1  may range from 90 V AC to 240 V AC at 50 Hz to 60 Hz depending on where you are located in the world and other AC power voltages and frequencies may be used. The external power supply  2  receives input AC power 90 V AC to 240 V AC at 50 to 60 from AC power  1 . The external power supply can be a wall mounted unit that is plugged directly in to an AC power  1  outlet and may use country specific plug adapters to mate with the style of AC power  1  outlet. A power source such as an external power supply  2  provides input power for the driver contacts  54  of the docking system base  45 . A DC power input from a battery system in a vehicle such as an automobile for example may also be used in place of the AC power  1  and external power supply  2  to provide input to the driver contacts. The driver contacts  54  are used to transfer power the sleeve  38  when the sleeve  38  is docked on the base  45 . The driver contacts  54  may be spring loaded insuring a good electrical contact with the receiver contacts  55  on the sleeve  38 . The driver contacts  54  and receiver contacts  55  may be made of conductive material and further may be plated with gold or other highly conductive material improved conduction and reduce contact resistance. The receive contacts  55  are used to receive the power transferred from the driver contacts  54 . 
     The regulator board  56  receives the power input from the receiver contacts  55 . The regulator board  56  may be located in a sleeve  38 . The power input from the receiver contacts  55  may be rectified in to DC voltage by a full wave bridge or half wave bridge on the regulator board  56 . Alternately, if a DC voltage source is used for the driver contact  54  power then a full wave bridge or half wave bridge is not needed to create DC voltage. The DC voltage from the full or half wave bridge rectifier or DC power input from the receiver contacts  55  may be used as the input for a DC to DC switching power regulator circuit on the regulator board  56 . The use of a switching power regulator on the regulator board  56  may improve the efficiency from 20% to nearly 90% of the conversion of unregulated DC voltage input to regulated voltage output over the use of conventional linear voltage regulators. The switching power regulator may be configured to output regulated +5 VDC output or other voltage for charging a mobile electronic device  7 . The output of a regulator board&#39;s  56  regulated DC output is used as the input to a connector board  57 . 
     The connector board  57  may be located in the sleeve  38  and may include a mating connector for the charging port on the mobile electronic device  7 . The connector board  57  may also include a connector that is accessible from the outside of the sleeve  38  that allows an alternate method to charge the mobile electronic device  7  using a conventional charger. The mobile electronic device  7  charging port may plug in to a mating connector  27  on the connector board  57  when a mobile electronic device  7  inserted in to the sleeve  38 . The sleeve  38  may be intended to remain in place on the mobile electronic device  7  semi-permanently and does not need to be removed for normal use of the mobile electronic device  7 . The sleeve  38  may be form fitting and also may provide a level of increased protection for the mobile electronic device  7 . The mobile electronic device  7  installed in the sleeve  38  may be placed on the base  45  to charge the mobile electronic device  7 . Optionally, no additional plugging of cables or connectors are required to charge the mobile electronic device  7  when installed in the sleeve  38  and placed on the base  45  that is receiving power from an external power supply  2 . The driver contacts  54  of the base  45  may need to be aligned properly with the receiver contacts  55  in the sleeve  38  to properly transfer power and allow charging of the mobile electronic device  7 . 
     Smaller magnets  35  in the sleeve  38  may be used to attract to ferrous metal in the base  45 . A combination of magnetic force and mechanical design features of a base  45  and a sleeve  38  may be used to enable the sleeve  38  to be easily docked properly aligning the receiver contacts  55  and the driver contacts  54  on the base  45  without excessive care from the intended user. The mechanical design features of the base  45  and the sleeve  38  also allow the sleeve  38  to be rotated to any position on axis within a single plane while a sleeve  38  is installed on the base  45 . The magnetic force may be used to hold the base  45  and sleeve  38  together with enough force to allow the mobile electronic device  7  to be used normally while docked. The magnetic force between the sleeve  38  and base  45  may be such that it is not strong enough to prevent the mobile device  7  held in the sleeve  38  from easily being undocked by a user and used as a mobile electronic device  7 . 
     Referring to  FIG. 16 ,  FIG. 16  is a simplified flow chart of the operation of the docking system microcontroller firmware. 
     The microcontroller is initialized when the docking system has power applied from the external power supply. This is the POWER ON state of the docking system. The microcontroller next initializes the internal registers that control the input and output pin configurations and timers that may be used. After initialization is complete the system enters LOW POWER MODE. In LOW POWER MODE the charging function is disabled or OFF. The docking system may stay LOW POWER MODE and loop checking if a sleeve has been docked. When the docking system detects that a sleeve has been docked it will exit LOW POWER MODE and enter CHARGE MODE. The charging function is enabled or turned ON in CHARGE MODE. The firmware will remain in CHAR MODE and loop checking that a sleeve is still docked. If the sleeve remains docked on the docking system then CHARGE MODE will remain ON. If the sleeve is removed from the dock the docking system will return to LOW POWER MODE and the charge function will be turned OFF. The docking system will remain in LOW POWER MODE until a sleeve is docked and the process describe above will repeat indefinitely until power to the docking system is removed. 
     Certain systems and methods disclosed herein can be implemented in hardware, software, firmware, or a combination thereof. Software can include computer readable instructions stored in memory (e.g., non-transitory, tangible memory, such as solid state memory (e.g., ROM, EEPROM, FLASH, RAM), optical memory (e.g., a CD, DVD, Blu-ray disc, etc.), magnetic memory (e.g., a hard disc drive), etc., configured to implement the algorithms on a general purpose computer, special purpose processors, or combinations thereof. For example, one or more computing devices, such as a processor, may execute program instructions stored in computer readable memory to carry out processed disclosed herein. Hardware may include state machines, one or more general purpose computers, and/or one or more special purpose processors. 
     Although this invention has been disclosed in the context of certain embodiments and examples, it will be understood by those skilled in the art that the present invention extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses of the invention and obvious modifications and equivalents thereof in addition, while a number of variations of the invention have been shown and described in detail, other modifications, which are within the scope of this invention, will be readily apparent to those of skill in the art based upon this disclosure. It is also contemplated that various combinations or subcombinations of the specific features and aspects of the embodiments may be made and still fall within the scope of the invention. Accordingly, it should be understood that various features and aspects of the disclosed embodiments can be combined with or substituted for one another in order to form varying modes of the disclosed invention. Thus, it is intended that the scope of the present invention herein disclosed should not be limited by the particular disclosed embodiments described above.

Technology Category: 5