Patent Abstract:
The present invention is a pad for connecting a host device to a slave device through a slave adapter. The host may provide services to the slave, including power and data connections. Pins in the pad magnetically align the slave adapter. The host and slave may collaborate on which pins are assigned to connections. The system handles various usage modifications including, for example, dislocation of the slave adapter, and changes in pin assignments.

Full Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates to a pad for connecting electronic devices. More specifically, the present invention relates to a connection pad under control of a smart host. 
       BACKGROUND OF THE INVENTION 
       [0002]    By “storage” we mean tangible computer-accessible electronic storage. 
         [0003]    By a “communication system” we mean a combination of hardware devices and logic in software and/or hardware for electronically communicating data in digital form. A communication system might include, for example, a wide-area network such as the Internet; a local-area network (e.g., within a home, business, or school); and/or a personal-area network (e.g., a network implemented with Bluetooth or Infrared Data Association). The term “communication system” is hierarchical, and any combination of communication systems used to transmit data between two smart devices is a communication system. A communication system is assumed to include at least a hardware interface. 
         [0004]    By “logic”, we mean some combination that includes tangible electronic hardware, and may include software, whereby a processing system executes tasks and makes decisions. 
       SUMMARY OF THE INVENTION 
       [0005]    A universal smart connection pad allows a slave device, such as a mobile electronic device, to be conveniently connected to a host device, such as a computer. Orientation of a connector of the slave upon the pad may be assisted by magnetization. Through the pad, the host may provide services needed by the slave, such as power and communication. The host may adapt the connection to accommodate changing needs of the slave. The host may facilitate recovery and reconnection of a slave that becomes disconnected. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0006]      FIG. 1  is a conceptual diagram illustrating a host device and a slave device adapter connected e an exemplary universal smart connection pad (USCP), viewed from its connecting surface. 
           [0007]      FIG. 2  is a side view illustrating a host device that has an integrated USCP. 
           [0008]      FIG. 3  illustrates an arrangement of pins in a rectangular slave adapter. 
           [0009]      FIG. 4  illustrates an arrangement of pins in an elliptical slave adapter. 
           [0010]      FIG. 5  is a side view illustrating a slave device with an integrated slave adapter. 
           [0011]      FIG. 6  illustrates an arrangement of magnetic polarities of pins in a USCP. 
           [0012]      FIG. 7  illustrates an alternative configuration of magnetic polarities of pins in a USCP. 
           [0013]      FIG. 8  illustrates an exemplary cross section through a slave adapter mated with a USCP. 
           [0014]      FIG. 9  is a conceptual diagram illustrating a host device and multiple slave devices connected through an exemplary USCP. 
           [0015]      FIG. 10  is a block diagram illustrating exemplary types of connections whereby a host device or a slave device might access a USCP. 
           [0016]      FIG. 11  is a block diagram illustrating exemplary functions of host connection manager logic in an exemplary USCP. 
           [0017]      FIG. 12  is a block diagram illustrating exemplary components of a host connection manager in an exemplary USCP. 
           [0018]      FIG. 13  is a block diagram illustrating exemplary functions of slave connection manager logic for a slave that is compatible with a USCP. 
           [0019]      FIG. 14  is a block diagram illustrating exemplary components of a slave connection manager for a slave that is compatible with a USCP. 
           [0020]      FIG. 15  is a sequence diagram illustrating exemplary mating module logic in an exemplary USCP. 
           [0021]      FIG. 16  is a sequence diagram illustrating exemplary recovery module logic in an exemplary universal smart connection pad. 
           [0022]      FIG. 17  is a sequence diagram illustrating exemplary pin reassignment module logic in an exemplary universal smart connection pad. 
       
    
    
     DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS 
       [0023]    This description provides embodiments of the invention intended as exemplary applications. The reader of ordinary skill in the art will realize that the invention has broader scope than the particular examples described here. It should be noted from the outset that the drawings, and the elements depicted by the drawings, are intended to illustrate concepts, and may not be to scale. Generally, reference numbers are keyed to the drawing of first appearance. For example, reference number  220  would appear first in  FIG. 2 ; and  460 , in  FIG. 4 . Each such reference will be described at least once, ordinarily in connection with the figure of first appearance. For clarity, a given reference number that appears in a second figure will not necessarily be described a second time. 
         [0024]      FIG. 1  is a conceptual diagram illustrating a host  110  device and a slave  120  device connected through an exemplary universal smart connection pad (USCP)  100  and an exemplary slave adapter  121 . The host  110  and slave  120  are both electronic devices. A host  110  might be, for example, a laptop computer or a tablet computer. A slave  120  might be, for example, a mobile device, a camera, a video recorder, or a computer. More generally, a host  110  might be any type of electronic device; similarly, for a slave  120 . The connection through the USCP  100  between the host  110  and the slave  120  facilitates transfers between them. A transfer might be power or “data”. By data, we mean anything that has information content, such as text, audio, video, instructions, signals, or software, whether in analog or digital form, alone or in combination. Data includes any handshaking done between host  110  and slave  120  regarding a transfer. Multiple transfers might be occurring over a given interval. Transfers are done between pins  104  of the pad  100  that are mated with slave pins  310  of the slave adapter  121 . 
         [0025]    In the type of embodiment shown in  FIG. 1 , pad  100  is in a separate housing from host  110 . In  FIG. 1 , host  110  connects to pad  100  with a cable  131 . This cable  131  might connect to the host  110  with a pair of mating connectors, making the cable  130  convenient for a user to disconnect from the host  110 ; alternatively, the end of the cable  131  might be integrated into the host  110 , designed to prevent separation. Similarly, the connection between the cable  131  and the pad  100  might be integrated into the pad  100  or be separable using a pair of mating connectors of the pad  100  and cable  131 . Mating-pair and integrated types of connectors are illustrated by  FIG. 8 , which is described in more detail below. 
         [0026]    The slave  120  connects to the pad  100  with a slave adapter  121 . Similar to connections between the cable  131  and the host  110 , connections between the cable  132  and the slave  120  might be integrated into the slave  120 , or use mating pairs of connectors; likewise, for connections between the cable  132  and the slave adapter  121 . 
         [0027]      FIG. 2  shows a side view of an embodiment, in which the pad  100  is integrated into the housing of a host  110 , exposed along a surface. In such embodiments, an external cable linking the host  110  and pad  100  is not required. Analogously, as illustrated by  FIG. 5 , a slave adapter  121  might be integrated into a slave  120 , eliminating the need for a slave external connecting cable. 
         [0028]    A slave adapter  121  makes physical contact with the pad  100  to electrically connect the slave  120  to the host  110 . As shown in  FIG. 1 , the pad  100  has pins  104  exposed on one of its surfaces. The pins  104  might protrude slightly beyond the surface of the pad  100 , as illustrated by  FIG. 2 . Alternatively, the exposed ends of the pins  104  might be recessed slightly, or flush with the surface. Preferably, all pins  104  will be uniform in their elevation relative to the connecting surface. Similarly, as illustrated by  FIG. 5 , the slave adapter  121  has slave pins  310  exposed on one of its surfaces; such slave pins  310  might be raised, lowered, or flush with respect to that connecting surface. Preferably, all slave pins  310  will be uniform in this regard. 
         [0029]    Preferably, the pad  100  will have a rectangular shape as illustrated by  FIG. 1 . In this case, the pins  104  are equally-spaced in two dimensions in a rectangular grid. With some pad  100  shape other than a rectangle, the grid is still rectangular, but will be truncated by the shape of the pad  100 . The pins  104  shown in  FIG. 1  are preferably circular when viewed from above the surface, but they might have other shapes, such as diamond, square, or hexagon. Like the pins  104 , the slave pins  310  are also arranged into a rectangular grid, with the same equal spacing as the  FIG. 1 .  FIG. 3  illustrates a view of a pin-surface grid of a rectangular slave adapter  121 ;  FIG. 4 , an elliptical slave adapter  121 , in which the rectangular grid is truncated by the overall shape of the slave adapter  121 . Preferably, the pad  100  will have at least  4  pins in each direction. 
         [0030]    Rows of pins  104  in the pad  100  in  FIG. 1  are labeled with letters; columns, with numerals. Labeled pin  104  ‘B 7 ’ exemplifies this system. Magnetism is used to automatically orient the slave adapter  121  into a functional position, as facilitated by the same equal spacing of slave pins  310  and pins  104 . Both pins  104  and the slave pins  310  are magnetized. Magnetism of the pins  104  might be either natural magnetism, or magnetism induced electronically by the host  110 . The slave pins  310  are preferably naturally magnetized, but in some embodiments, their magnetism might be induced by the slave  120 . 
         [0031]    Magnets in the pad  100  orient the slave adapter  121  into an optimal position for transfer of power and/or data between the host  110  and the slave  120 .  FIG. 6  shows an illustrative arrangement of polarities of a grid of pins  104  in a USCP  100 . Filled pins  104  have positive polarity; empty ones, negative. Polarities alternate between adjacent pins  104 .  FIG. 7  shows a reversed arrangement of the same pad  100 . In  FIG. 6 , pin B 7   604  is positive; in  FIG. 7  the same pin, pin B 7   604 , is negative. As shown in  FIG. 8 , which is a cross-section through a pad  100  and a slave adapter  121 , positive slave pins  310  will be attracted to and align with negative pins  104 , and conversely. The cross-sectional view of  FIG. 8  illustrates how positively-charged pins  104  connect with negatively-charged slave pins  310 . 
         [0032]    In both  FIG. 1  and  FIG. 8 , pins  104  either connected to corresponding slave pins  310  or not. Preferably, all the slave pins  310  are connected slave pins  106 , but in some embodiments, the slave adapter  121  might straddle a boundary of the pad  100  and still have enough connected slave pins  106  for the connection to work. Preferably, the pin grid of the pad  100  is sufficiently large so that a slave adapter  121  might be attached to the pad  100  at a variety of locations, as shown in  FIG. 1  and  FIG. 8 . In other words, the pin-dimensions of the pad  100  should as a minimum be larger than those of the largest slave adapter  121  that the pad  100  is intended to accommodate. The locations unused by a first slave  120  can be used so that the host  110  can mate with other slave  120  devices.  FIG. 9  shows a second slave  920 , connected to the pad  100  by cable  922  and adapter  921 . 
         [0033]    The connected slave pins  106  fall into two categories--they are either mated slave pins  107  or reserved slave pins  108 . The mated slave pins  107  (shown as filled in  FIG. 1 ) are actively participating in the connection, exchanging power or data. The reserved slave pins  108  (shown as hollow) are inactive, either because they are presently unneeded to transfer data, or because they are defective or have failed. During a given interaction or exchange between a host  110  and a slave  120 , host connection management logic  1100  and/or slave connection management logic  1300  might change the role of a given slave pin  310  from mated to reserved, or conversely. Moreover, the position of the slave adapter  121  on the pad  100  can change during an interaction. 
         [0034]    In the embodiment illustrated by  FIG. 1 , the pad  100  is in a hardware housing separate from both the host  110  and the slave  120 . The host  110  is connected to the pad  100  by a cable  130 ; specifically, cable  131 . The slave  120  is connected to the slave adapter  121  by a cable  130 ; specifically, cable  132 . In other embodiments, the pad  100  may be integrated into the host  110 ; and/or the slave adapter  121  may be integrated into the slave  120 .  FIG. 10 , which is a block diagram illustrating exemplary types of connections whereby a host  110  device or a slave  120  device might access a USCP  100 . The host  110  may be either connected with an integrated connection  1010 , or through an external port  1020  of the host  110  and a corresponding cable; similarly, for the slave  120 . Such an external port  1020  might be, for example, a USB port  1021 , a SD port  1022 , a SATA port  1023 , or an eSATA port  1024 . Other examples include Ethernet, HDMI, analog audio/video, digital audio/video, COAX, Lightening, Thunderbolt, and FireWire. 
         [0035]    The smart connection between the host  110  and the slave  120  through the pad  100  is managed for the host  110  by host connection management logic  1100 , illustrated by  FIG. 11 . For the slave  120 , the connection is managed by slave connection management logic  1300 , illustrated by  FIG. 13 . Functionality, and corresponding hardware/software, of host connection management logic  1100  may be split in any combination between the host  110  and the pad  100 . Placing more functionality in the pad  100  means that one pad  100  might be compatible with many hosts. On the other hand, a host  110  with a processing system may be able to easily accommodate a relatively passive and unintelligent pad  100 , possibly with a simple software application installation on the host  110 . Analogously, functionality, and corresponding hardware/software, of slave connection management logic  1300  may be split in any combination between the slave  120  and the slave adapter  121 ; in this case, placing as much functionality on the slave adapter  121  as possible is preferable. 
         [0036]    In the illustrative embodiment of  FIG. 8 , the pad  100  has module  860  where some or all of the host connection management logic  1100  might be housed. Similarly, the slave adapter  121  has module  840  where some or all of the slave connection management logic  1300  might be housed. As a minimum, module  860  provides electrical connections between the pins  104  and the cable  131 ; similarly, module  840  provides electrical connections between the slave pins  310  and the cable  132 . 
         [0037]    The host connection management logic  1100  may include an action selection module  1110 . The action selection module  1110  considers, given the current state of the pad  100 , whether each of the possible other action modules should be executed, and if so, initiates execution of that module. The host connection management logic  1100  may include a pin orientation module  1115  that manages magnetization of pins  104 , causing an attached slave  120  device to assume a workable orientation. The host connection management logic  1100  may include a mating module  1120 , a power module  1130 , a pin assignment module  1140 , a function expansion module  1150 , a function reduction module  1160 , a recovery module  1170 , and/or a handshaking module  1180 . Exemplary logic of a mating module  1120  and a pin assignment module  1140  is illustrated by  FIG. 15 . Exemplary logic of a pin assignment module  1140 , a handshaking module  1180 , and a recovery module  1170  is illustrated by  FIG. 16 . Exemplary logic of a pin assignment module  1140 , a function expansion module  1150 , a function reduction module  1160 , and a  17  is illustrated by  FIG. 17 . 
         [0038]    The modules of the slave connection management logic  1300  are required to collaborate with their counterparts to facilitate the transfers. The slave connection management logic  1300  may include an action selection module  1310 , a mating module  1320 , a power module  1330 , a pin assignment module  1340 , a function expansion module  1350 , a function reduction module  1360 , a recovery module  1370 , and/or a handshaking module  1380 .  15 - FIG. 17  illustrate applications of these modules in initiating interactions with the host  110 , and responding to interactions initiated by the host  110 . 
         [0039]      FIG. 12  is a block diagram illustrating exemplary components of a host connection manager  1200  in an exemplary USCP  100 . The host connection manager  1200  executes the host connection management logic  1100 . The processing system  1210  includes at least one processor, housed in either the host  110 , the pad  100 , or one or more in each. Similarly, storage  1220  may be housed in either the host  110 , the pad  100 , or in each. The processing system  1210 , storage  1220 , and the four interfaces all include hardware electronic components; the host connection management logic  1100  may include hardware components and may include software instructions, some or all of which might be accessed from the storage  1220 . The host communication interface  1230  is an interface between the host  110  and the pad  100  through which the host  110  may communicate electronically with the slaves  120  and with the pad  100  itself. The host power interface  1240  is an interface through which the host  110  may provide power to the pad  100 , and in some embodiments, to slaves  120 . The host transfer-control interface  1250  is an interface through which the host  110  communicates with the slave  120 , through the pad  100  and slave adapter  121 , to coordinate and monitor transfers of power and/or data, including handshaking. 
         [0040]      FIG. 14  is a block diagram illustrating exemplary components of a slave connection manager  1400  in an exemplary USCP  100 . The slave connection manager  1400  executes the slave connection management logic  1300 . The processing system  1410  includes at least one processor, housed in either the host  110 , the pad  100 , or one or more in each. Similarly, storage  1420  may be housed in either the host  110 , the pad  100 , or in each. The processing system  1410 , storage  1420 , and the four interfaces all include hardware electronic components; the slave connection management logic  1300  may include hardware components and may include software instructions, some or all of which might be accessed from the storage  1420 . The slave communication interface  1430  is an interface between the host  110  and the pad  100  through which the host  110  may communicate electronically with the slaves  120  and with the pad  100  itself. The slave power interface  1440  is an interface through which the host  110  may provide power to the pad  100 , and in some embodiments, to slaves  120 . The slave communication interface  1430  is an interface through which slaves  120  may communicate electronically with the host  110  and with the pad  100  itself. The slave power interface  1440  is an interface through which slaves  120  may receive power from the pad  100 , and in some embodiments, ultimately from the host  110 . The slave transfer-control interface  1450  is an interface through which the slave  120  communicates with the host  110 , through the slave adapter  121  and pad  100 , to coordinate and monitor transfers of power and/or data, including handshaking. Preferably, as much of the slave connection manager  1400  as possible is housed in the slave adapter  121 , and as much of the slave connection management logic  1300  as possible is executed by the slave adapter  121 . Preferably, the slave  120  itself is unaware of the details of the connection. 
         [0041]    The handshaking module  1180  and the handshaking module  1380  may communicate regularly to monitor the status of any transfers of power or data, and to initiate any appropriate corrective action. Such handshaking might be done using one or more otherwise unassigned slave pins  310 , a dedicated slave pin  310 , or might be piggybacked on a data or power transfer pin. 
         [0042]      FIG. 15-17  are sequence diagrams (also known as swim lane diagrams) that illustrate exemplary host connection management logic  1100  of an exemplary USCP  100 .  FIG. 15  is typical of these swim-lane diagrams. Across the top of the diagram, system components are depicted in boxes; in  FIG. 15 , the components are the host  110 , the pad  100 , and the slave  120 . As indicated by notation  1500 , time increases down the page. Under each box representing a respective component is a timeline; in  FIG. 15 , the timelines are host timeline  1501 , pad timeline  1502 , and slave timeline  1503 . An arrow between two timelines indicate interactions between the corresponding system components, where the component transfers something to, communicates with, or senses something from other component. A single-headed arrow indicates a one-way interaction; a double-headed arrow, two-way. An arrow from a timeline to itself indicates an action taken by the corresponding system component at that point in the sequence. 
         [0043]      FIG. 15  is a sequence diagram illustrating exemplary mating module  1120  logic in an exemplary USCP  100 . In  FIG. 15 , when the pad  100  has no active connections, host  110  still provides  1510   a  low level of power to the pad  100 . This power might be required for a slave adapter  121  to respond to contact, or for the host  110  to detect presence of a slave adapter  121 . Magnetic attraction of the pins  104  to the slave pins  310  causes  1520  the slave adapter  121  of the slave  120  to attain a workable orientation. The host  110  detects  1530  contact with the slave adapter  121 , and establishes  1540  with the slave  120  through the slave adapter  121 . The slave  120  then identifies  1550  itself to the host  110 . Such identification may include type of the slave  120 , the type of the slave adapter  121 , and the number of connections available. The slave  120  then requests  1555  what it needs from the host  110 , such as the types of connections, the power requirements, assignments of slave pins  310  and their duties, which pins are reserved, and how handshaking will occur. The host  110  responds  1565 , choosing pin assignments. The slave  120  complies  1565  by assigning slave pins  310  as directed. The host  110  places  1570  unused slave pins  310  on standby. The host  110  establishes  1575  the power connection. The host  110  establishes  1580  the data connection. At this point, interaction begins  1585  between the host  110  and the slave  120 . 
         [0044]      FIG. 16  is a sequence diagram illustrating recovery from a connection failure. Initially, the host  110  and slave  120  are interacting  17 , as in the last step of  FIG. 15 . Something disturbs the system; for example, a user  150  might bump  1603  the slave adapter  121 . The host  110  detects  1607  the connection failure at the pad  100 . The remaining steps ( 1625 - 1685 ) follow their counterparts ( 1520 - 1585 ) in  FIG. 15 , except that here there is an additional step of recovery  1675  from interruption of the data transfer. 
         [0045]      FIG. 17  is a sequence diagram that deals with changes to the system once interaction  1585  between the host  110  and slave  120  has already been taking place. In the embodiment shown, the slave  120  determines for itself  1704  that a change in the interaction is needed. (In other embodiments, a needs change might be initiated by the pad  100 , by the host  110 , or by the slave adapter  121 .) The slave  120  requests  1712  a change. The remainder steps ( 1560 - 1585 ) follows their counterparts ( 1660 - 1685 ) in  FIG. 16 . The optional recovery step  1782  might or might not be needed, depending upon circumstances of the change. 
         [0046]    Of course, many variations of the above method are possible within the scope of the invention. The present invention is, therefore, not limited to all the above details, as modifications and variations may be made without departing from the intent or scope of the invention. Consequently, the invention should be limited only by the following claims and equivalent constructions.

Technology Classification (CPC): 6