PATENT DOCUMENT

Publication Number: US-9240700-B2
Application Number: US-201213607446-A
Country: US
Kind Code: B2

Title: Cascading power for accessories

Abstract:
Methods, systems, and apparatuses for charging a host device from a charging source through an accessory are described. Upon detecting an input power signal from the charging source, an accessory may send an identification request to the host device and authenticate the host device based on the identification information received from the host device. Upon authenticating the host device, the accessory may enable a power path between the charging source and the host device to supply a charging current to charge the host device.

Claims:
What is claimed is:  
     
       1. An accessory comprising:
 a power module; and 
 an identification (ID) module coupled to the power module, wherein the ID module is configured to:
 send a signal to the power module to supply a limited current to a downstream device in response to detecting an input power signal from an upstream device coupled to the accessory; 
 send an ID request to the downstream device; 
 receive ID information from the downstream device; 
 authenticate the downstream device based on the ID information; and 
 send a signal to the power module to enable a power path between the upstream device and the downstream device to supply a charging current greater than the limited current to the downstream device such that the downstream device can be operated in a normal mode and can provide a limited current to a downstream host connected to the downstream device. 
 
 
     
     
       2. The accessory of  claim 1 , wherein the ID information comprises a charge current indicator that is used by the accessory to determine an amount of charging current to provide to the downstream device. 
     
     
       3. The accessory of  claim 2 , wherein the charge current indicator comprises a value identifying a charge level of a battery of the downstream device. 
     
     
       4. The accessory of  claim 3 , wherein the ID module is configured to send, a command to the upstream device, wherein the command comprises the value identifying the charge level of the battery of the downstream device. 
     
     
       5. The accessory of  claim 2 , wherein the charge current indicator comprises a value representing an amount of current requested by the downstream device. 
     
     
       6. The accessory of  claim 5 , wherein the ID module is configured to send a command to the upstream device comprising a value representing at least the amount of current requested by the downstream device. 
     
     
       7. The accessory of  claim 2 , wherein the power path is maintained in a disabled state if the downstream device is not authenticated. 
     
     
       8. A method comprising:
 receiving, by an accessory, an input power signal from an upstream device; 
 sending a signal to a power module to supply a limited current to a downstream device; 
 sending, by the accessory, an identification (ID) request to the downstream device; 
 receiving, by the accessory, an ID response from the downstream device, wherein the ID response includes a charge current indicator; 
 authenticating, by the accessory, the downstream device based on the ID response; and 
 enabling, by the accessory, a power path between the upstream device and the downstream device to provide a charging current to the downstream device, wherein the charging current provided to the downstream device is based on the charge current indicator and the downstream device operates in a normal mode and can provide a limited current to a downstream host connected to the downstream device and temporarily incapable of authentication. 
 
     
     
       9. The method of  claim 8 , wherein the charge current indicator comprises a value identifying a charge level of a battery of the downstream device. 
     
     
       10. The method of  claim 8 , wherein the charge current indicator comprises a value representing an amount of current requested by the downstream device. 
     
     
       11. The method of  claim 8 , wherein the limited current to the downstream device enables the downstream device to send the ID response. 
     
     
       12. The method of  claim 8 , further comprising:
 maintaining the power path in a disabled state if the ID response from the downstream device is not recognized by the accessory. 
 
     
     
       13. The method of  claim 8 , further comprising:
 adjusting the charging current based on a subsequent charge current indicator received from the downstream device. 
 
     
     
       14. The method of  claim 13 , wherein the subsequent charge current indicator represents an updated charge level of the battery of the downstream device. 
     
     
       15. The method of  claim 13 , further comprising:
 polling the downstream device at a predetermined time interval to request the subsequent charge current indicator. 
 
     
     
       16. A method comprising:
 receiving, by an accessory, an input power signal from an upstream device; 
 supplying a limited current to a first downstream device; 
 sending, by the accessory, a first identification (ID) request to the first downstream device; 
 receiving, by the accessory, a first ID response from the first downstream device, wherein the first ID response includes a first charge current indicator; 
 authenticating, by the accessory, the first downstream device based on the first ID response; 
 sending, by the accessory, a second ID request to a second downstream device; 
 receiving, by the accessory, a second ID response from the second downstream device, wherein the second ID response includes a second charge current indicator; 
 authenticating, by the accessory, the second downstream device based on the second ID response; 
 distributing, by the accessory, a current from the upstream device to the first and second downstream devices based on the first and second charge current indicators such that the second downstream device can be operated in a normal mode and can provide a limited current to a downstream host connected to the second downstream device wherein the downstream host is temporarily incapable of authentication. 
 
     
     
       17. The method of  claim 16 , further comprising:
 receiving a subsequent charge current indicator from at least one of the first and second downstream devices; and 
 redistributing, by the accessory, the current from the upstream device to the first and second downstream devices based in part on the subsequent charge current indicator. 
 
     
     
       18. The method of  claim 16 , wherein at least one of the first and second charge current indicators represents a charge level of the battery of the respective downstream device. 
     
     
       19. The method of  claim 16 , wherein at least one of the first and second charge current indicators comprises a value representing an amount of current requested by the respective downstream device. 
     
     
       20. The method of  claim 19 , wherein a first charging current is provided to the first downstream device and a second charging current is provided to the second downstream device, wherein the first and second charging current are proportional to the values of the first and second charge current indicators, respectively. 
     
     
       21. The method of  claim 16 , wherein distributing the current from the upstream device comprises providing a first charging current to the first downstream device while a power path between the upstream device and the second downstream device is disabled.

Description:
BACKGROUND 
     The present disclosure generally relates to accessories that interoperate with portable computing devices, and in particular to the connection of multiple accessories to one or more portable computing devices. 
     In recent years, a number of portable computing devices (PCDs) have been developed. Examples of PCDs include portable media players, mobile phones, personal digital assistants (PDAs), portable e-mail devices, tablet computers, video game players, portable navigation units relying on Global Positioning System (GPS) satellite data, and multi-function devices that can integrate numerous functions such as media storage and playback, mobile phone, Internet access, e-mail, personal information management, game play, GPS/navigation capability, and the like. Examples of multi-function PCDs include various iPhone®, iPad® and iPod® models manufactured and sold by Apple Inc., assignee of the present application, as well as other portable electronic devices made and sold by other manufacturers and distributors under their respective brand names. 
     Along with the development of PCDs, accessories have also been created for use with the PCDs. Such accessories can communicate with a PCD using one or more connectors and/or communication interfaces. Accessories can be used to control features of a PCD or be used by a PCD to interact with users and/or the environment. In some instances, multiple accessories can be used concurrently with a PCD. For example, an accessory such as a speaker dock can be docked with a PCD to play audio from a media file such as a movie stored in the PCD, and another accessory such as an external display can be connected to the speaker dock or the PCD to play video from the same media file. In other instances, an accessory can be used concurrently with multiple PCDs. For example, an accessory such as a hub can be used to connect multiple PCDs together to share data and information among the PCDs. 
     SUMMARY 
     Certain embodiments of the present invention relate to connection of multiple accessories to one or more host devices such as portable computing devices (PCDs). In some embodiments, two or more accessories can be connected to a host device in a daisy chain topology, with the host device at one end of the daisy chain. In some embodiments, one or more host devices can be connected to an accessory in the daisy chain. At least one intermediary accessory (also referred to herein as a “relay” or “relay accessory”) provides a first connector or port that can be used to connect to another accessory (which may or may not also be a relay accessory), and a second connector or port that can be used to connect to a host device or an additional accessory (which may or may not also be a relay accessory). Thus, any number of accessories can be incorporated into a daisy chain. Each connected accessory (including the relay accessories) can interact with a host device. Thus, each connected accessory can invoke host device functionality, have its own functionality invoked by a host device, receive media content or other information from a host device, deliver media content or other information to a host device, and so on. Concurrently with its own interaction with a host device, each intermediary accessory can also act as a relay for other accessories in the daisy chain, directing commands, data and other signals between a host device and the other accessories, and thereby allowing the other accessories to interact with a host device through the intermediary accessory. In addition, in some embodiments, streaming signals (e.g., audio and/or video signals) can be routed from a host device to various accessories along the daisy chain. 
     In one embodiment, an accessory acting as a charging source for charging a host device can be connected to the host device through one or more intermediary accessories. For example, a host device may be a mobile phone, a tablet, a portable media player/reader, or a portable computing device. A charging source may be a power adapter, a power brick, a charger block, or a charging station that can be connected to a power source such as an electrical outlet or an external battery to charge a host device. One way to ensure compatibility between a host device and a charging source is to authenticate the power source by the host device before the charging source enables a power path to supply a charging current to charge the host device. For example, the charging source can be authenticated by sending identification (ID) information identifying the charging source to the host device. Alternatively, the host device can send ID information identifying the host device to the charging source. 
     In the instance where the battery of the host device is dead (i.e. the battery is completely drained, or the battery is drained to the extent that the circuitry of the host device responsible for sending the ID information cannot properly operate when using the battery as a power source), the host device may be incapable of authenticating the charging source. In such a scenario, the charging source can supply a limited current to the host device to enable circuitry in the host device to authenticate the charging source when the battery of the host device is dead. 
     However, if the host device is being used in a system with one or more intermediary accessories, such as a docketing station, a hub, or a speaker dock, that are coupled between the host device and the charging source in a daisy chain, the limited current provided by the charging source may be inadequate to enable the circuitry of the host device to send the ID information due to loses along the path through the intermediary accessories. As a result, a user would have to go through the inconvenience of physically disconnecting the host device from an accessory, and reconnecting the host device directly to the charging source to charge the host device. 
     Accordingly, in some embodiments of the invention, an accessory can be authenticated by a charging source such that the charging source would enable a power path to the accessory without first requiring authentication of a host device that is coupled downstream to that accessory. This allows the accessory to be powered through the power path such that the accessory can adequately provide a limited current to the next accessory to enable authentication of the next accessory. The accessory can authenticate the next accessory and enable a power path to power that next accessory. In this way, each accessory along the daisy chain towards the host device from the charging source can be authenticated and be powered in a cascading manner to enable each accessory to provide an adequate limited current to the next device along the chain. 
     The accessory that is directly connected to the host device can likewise be powered after being authenticated by the preceding accessory. As a result, instead of receiving a diminished limited current, the accessory directly connected to the host device can be sufficiently powered such that the accessory can provide an adequate limited current to the host device to enable authentication of the host device. Thus, even when the battery of the host device is dead, it is not necessary to disconnect the host device from the accessory and reconnect the host device directly to the charging source to charge the host device. 
     The following detailed description, together with the accompanying drawings will provide a better understanding of the nature and advantages of the present invention. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  illustrates a system with multiple accessories coupled to host devices according to one embodiment of the present invention. 
         FIG. 2  illustrates a block diagram of a system with multiple accessories coupled to host devices according to one embodiment of the present invention. 
         FIG. 3  illustrates a block diagram of an accessory that can be used as an intermediary accessory to connect to a host device according to one embodiment of the present invention. 
         FIG. 4  illustrates a block diagram of an accessory that can be used as an intermediary accessory to connect to a host device according to a different embodiment of the present invention. 
         FIG. 5  illustrates a block diagram of a host device that can be used to connect to multiple accessories according to one embodiment of the present invention. 
         FIG. 6  illustrates a flow diagram of charging a host device through an intermediary accessory according to an embodiment of the present invention. 
         FIG. 7  illustrates a flow diagram of updating a charging current during the charging of a host device through an intermediary accessory according to one embodiment of the present invention. 
         FIGS. 8A-B  illustrates a flow diagram of charging multiple host devices through an intermediary accessory according to one embodiment of the present invention. 
         FIG. 9  illustrates a perspective view of a plug connector according to an embodiment of the present invention. 
         FIG. 10A  illustrates a perspective view of a receptacle connector that is compatible with a plug connector according to an embodiment of the present invention. 
         FIG. 10B  illustrates a planar cross-section view of a receptacle connector that is compatible with a plug connector according to an embodiment of the present invention. 
         FIG. 11A  illustrates an exemplary pin-out of a connector according to an embodiment of the present invention. 
         FIG. 11B  illustrates an exemplary pin-out of a connector according to another embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     Embodiments of the present invention relate to connection of multiple accessories to one or more host devices. In some embodiments, a host device can be connected to one end of a daisy chain of accessories. In some embodiments, an accessory in the daisy chain can connect to one or more host devices. The daisy chain may have one or more intermediary accessories or relay accessories that each provides a connector or port for connecting to an accessory upstream from the intermediary accessory, and another connector or port for connecting to a host device or another accessory downstream from the intermediary accessory. Some accessories may provide additional connectors or ports to connect to one or more additional host devices and/or accessories. Each accessory in the daisy chain can interact with a host device and/or the other accessories. Thus, each accessory in the daisy chain can be used to control the features and functionality of a host device, be used by a host device to interact with users and/or the environment, and/or exchange data and other information with a host device and/or the other accessories. 
     To ensure each of the accessories in the daisy chain is a compatible and valid accessory that can be used with the host device, each accessory can authenticate or be authenticated by its adjacent device(s) which may include a host device and/or another accessory. An accessory or a host device can be authenticated by another device (which may be another accessory or another host device) by receiving an ID request from that device, and by sending ID information about the accessory to that device in response to the ID request. The ID information can be used by that device to determine if the accessory is a valid accessory that the device can interoperate with. Similarly, an accessory or a host device can authenticate another device (which may be another accessory or another host device) by sending an ID request to that device, receiving from that device ID information about the device, and determining if that device is a valid device based on the ID information received from that device. 
     A host device can be any type of computing and/or communication device such as a mobile phone, a tablet, a portable media player/reader, a laptop, a netbook, an ultrabook, a personal digital assistant (PDA), a portable gaming device, or any type of portable computing device (PCD). An accessory can be any type of device that can interoperate with a host device. Examples of an accessory may include a docking station, a hub, a cable, a dongle, a charger (e.g., a power adapter, a charging station, a charger block, a power brick, etc.), an external speaker dock/system, an external video device (e.g., a display monitor, a projector, etc.), an input device (e.g., a keyboard, a mouse, a microphone, a game controller, etc.), a multimedia device, a consumer electronic device (e.g., an alarm clock, etc.), a musical instrument (e.g., a digital piano), a home appliance (e.g., refrigerator, dishwasher, etc.), exercise equipment, a security system, a home or office automation system, a camera, a measurement device, a medical device (e.g., a glucose monitor, an insulin monitor, etc.), a point of sale device, an automobile, an automobile accessory (e.g., a car stereo system, car navigation system, etc.), a radio (e.g., FM, AM and/or satellite), an entertainment console on a transportation vehicle, or any combination of such devices. 
     Some embodiments of the present invention relate to connection of a host device to a power source through a daisy chain of accessories. The power source (e.g., an electrical outlet, an external battery, etc.) can provide power to each accessory along the daisy chain, and can also provide power to the host device through the daisy chain of accessories. In some embodiments, an accessory may include a power path in the accessory that provides a power connection between an upstream device and a downstream device. The accessory may include hardware and/or software operable to influence the power path between the upstream device and the downstream device. 
     The power source can also be used to charge a host device. An accessory acting as a charging source (e.g., a charger such as a power adapter, a charging station, a charger block, a power brick, etc.) can be connected to the power source to convert the electrical power from the power source into a suitable form for powering and/or charging the host device and/or accessories. For example, the charging source may have a AC-to-DC convert to convert alternating current (AC) into direct current (DC) that can be used by the host device and/or accessories. In some embodiments, the charging source may be included as part of another accessory. 
     According to some embodiments of the present invention, an accessory coupled between a host device and a charging source can be authenticated by the charging source to enable a power path from the charging source to the accessory. Upon the charging source authenticating the accessory and enabling a power path to supply power to the accessory, the accessory can proceed to authenticate the host device. In one embodiment, upon detecting an input power signal from the charging source, the accessory can supply a limited current to the host device to enable the host device to send identification (ID) information to the accessory. The accessory can authenticate the host device based on the ID information, and in response, enable a power path between the charging source and the host device to supply a charging current to charge the host device. In some embodiments, the power path may pass through the accessory. The charging current is sufficient to charge a battery of the host device according to the specification of the battery of the host device. 
     In a particular embodiment, the battery of the host device may be dead (i.e. the battery is completely drained, or the battery is drained to the extent that the circuitry of the host device responsible for sending ID information cannot properly operate when using the battery as a power source). The limited current supplied from the accessory to the host device can provide sufficient power to enable circuitry in the host device responsible for sending ID information to send the ID information to the accessory. Thus, a host device with a dead battery can still be authenticated according to embodiments of the invention. 
     In some embodiments, the ID information from the host device may include information, such as a device identifier that identifies the host device. The ID information may also include an indicator that identifies a charge level of the battery of the host device. The charging source may use the charge level indicator to determine the amount of current to be provided to the host device. The host device may send the charge level indicator several times during the charging process to periodically inform the charging source about the charge level of the battery. The charging source may adjust the output current based on this information. For example, the charging source may provide maximum current initially and as the host device battery charges above a certain level, e.g., 90%, the charging source may adjust the current to a lower value to provide a “trickle charge.” 
     In other embodiments, the ID information may include a charge current indicator that represents the amount of charging current requested by the host device. The charge current indicator can also be used by the accessory to determine the amount of charging current to provide to the host device. As the battery of the host device charges, the host device can send a subsequent charge current indicator to the accessory to change the amount of charging current being provided to the host device. The subsequent charge current indicator can be sent by the host device automatically, or the accessory can poll the host device periodically for the subsequent charge current indicator. 
     In other embodiments, multiple host devices can be coupled to a single charge source via one or more accessories. For example, two or more host devices can be connected through an accessory to a charging source. The accessory can distribute a charging current, received from the charging source, to each of the two host devices such that the charging current provided is based on the charge current indicator received from each host device. In some embodiments, if one host device charges up faster than the other host device, the host devices can send respective subsequent charge current indicators to the accessory such that the accessory can adjust the charging current provided to each host device based on the subsequent charge current indicators. 
     In other embodiments, an accessory can be coupled between an upstream device towards the direction of a power source and a downstream device towards the direction of a host device. The upstream device may be another accessory, or may be a charging source. The downstream device may be another accessory, or may be a host device. The accessory can be authenticated by the upstream device and can authenticate the downstream device in a similar manner as described above to enable a power path through the accessory. An example of such an embodiment will be described in more details with reference to  FIG. 2  below. 
     Turning now to the figures,  FIG. 1  illustrates a system  100  according to an embodiment of the present invention. In this embodiment, system  100  includes host devices  110  and  120 , accessories  150  and  160 , and a charging source  180 . Host devices  110  and  120  are coupled to accessory  150  through cables  132  and  134 , respectively. Accessory  150  is coupled to accessory  160  through cable  136 . Accessory  160  is coupled to charging source  180 , which can be plugged into power source  190  to provide power to charge host devices  110  and  120 . In system  100 , the upstream direction is the direction towards the power source  190 , and the downstream direction is the direction towards host devices  110  and  120 . It should be understood that the number of host devices and the number of accessories shown in  FIG. 1  are meant to be exemplary, and that other systems according to other embodiments may have a different number of accessories and/or different number of host devices. 
     Host devices  110  and  120  may be any suitable electronic device that can perform the functionality discussed herein, and may include one or more hardware and or software components that can perform such functionality. For example, host device  110  can be a tablet as shown, or be another type of portable computing device (PCD) such as any of the PCD described above. Host device  120  can be a mobile phone as shown, or be another type of portable computing device (PCD) such as any of the PCD described above. 
     Each of host devices  110  or  120  may include any suitable components typically found in such electronic devices necessary to perform the operations discussed herein. For example, host device  110  may include a user interface  115  (e.g., a touchscreen) that may be operable to display information to the user or receive inputs from the user, and one or more buttons  118  for controlling the operation of host device  110  via a user input. Host device  110  may also include a connector  119  such as a plug connector or a receptacle connector for mechanically and electrically coupling host device  110  to other electronic components such as accessory  150 , where connector  119  may include one or more pins or conductive contacts for establishing electrical and/or optical communication with corresponding pins or contacts of a connector coupled to connector  119 . Furthermore, host device  110  may include other suitable components typically found in such systems for performing the operations discussed herein, such as a processor (not shown), a tangible non-transitory computer readable storage medium (not shown), and the like, all operably coupled to one another such that the processor may execute instructions stored on the computer readable storage medium so as to cause host device  110  to perform one or more of the operations discussed herein. 
     Host device  120  may include a user interface  125  that can display information to the user or receive inputs from the user (e.g., a touchscreen), a speaker  124  for providing an audio output to a user, a microphone for receiving audio inputs from a user, one or more buttons  128  for controlling the operation of host device  120  via a user input, a connector  129  such as a plug connector or a receptacle connector for mechanically and electrically coupling host device  220  to other electronic components such as accessory  150 , where connector  129  may include one or more pins or conductive contacts for establishing electrical and/or optical communication with corresponding pins or contacts of a connector coupled to connector  129 . Host device  120  may also include other suitable components typically found in such systems for performing the operations discussed herein, such as a processor (not shown), a tangible non-transitory computer readable storage medium (not shown), and the like, all operably coupled to one another such that the processor may execute instructions stored on the computer readable storage medium so as to cause host device  120  to perform one or more of the operations discussed herein. 
     Accessories  150  and  160  may be any suitable electronic device that can perform the functionality discussed herein, and may include one or more hardware and or software components that can perform such functionality. Accessory  150  can be a hub as shown, or be another type of accessory, such as any of the accessories describe above or a combination thereof. Accessory  160  can be a combination alarm clock/radio that includes speakers  162  and a clock  163  as shown, or be another type of accessory such as any of the accessories describe above or a combination thereof. 
     Each of accessories  150  or  160  may include any suitable components typically found in such electronic devices necessary to perform the operations discussed herein. For example, accessory  150  may include connectors  159 A,  159 B, and  159 C such as a plug connector or a receptacle connector for mechanically and electrically coupling accessory  150  to other electronic components such as accessory  160  and host devices  210  and  220 , where each of connectors  159 A,  159 B, and  159 C may include one or more pins or conductive contacts for establishing electrical and/or optical communication with corresponding pins or contacts of a connector coupled to connector  159 A,  159 B, or  159 C. Accessory  150  may also include other suitable components typically found in such systems for performing the operations discussed herein, such as a processor (not shown), a tangible non-transitory computer readable storage medium (not shown), and the like, all operably coupled to one another such that the processor may execute instructions stored on the computer readable storage medium so as to cause accessory  150  to perform one or more of the operations discussed herein. 
     Accessory  160  may include connectors  169 A and  169 B, such as a plug connector or a receptacle connector for mechanically and electrically coupling accessory  160  to other electronic components such as accessory  150  and a charging source  180 , where each of connectors  169 A and  169 B may include one or more pins or conductive contacts for establishing electrical and/or optical communication with corresponding pins or contacts of a connector coupled to connector  169 A or  169 B. Accessory  160  may also include other suitable components typically found in such systems for performing the operations discussed herein, such as a processor (not shown), a tangible non-transitory computer readable storage medium (not shown), and the like, all operably coupled to one another such that the processor may execute instructions stored on the computer readable storage medium so as to cause accessory  160  to perform one or more of the operations discussed herein. 
     It should be noted that in some embodiments, each of cables  132 ,  134 , or  136  may also be an accessory. Each of cables  132 ,  134 , or  136  may include any suitable components typically found in such electronic devices necessary to perform the operations discussed herein. For example, cable  132  may include connector  132 A that is compatible with connector  119  such that the two connectors  132 A and  119  can mate to provide an electrical, mechanical, or optical connection between cable  132  and host device  110 . Cable  132  may include connector  132 B that is compatible with connector  159 A such that the two connectors  132 B and  159 A can mate to provide an electrical, mechanical, or optical connection between cable  132  and accessory  150 . Cable  134  may include connector  134 A that is compatible with connector  129  such that the two connectors  134 A and  129  can mate to provide an electrical, mechanical, or optical connection between cable  134  and host device  120 . Cable  134  may include connector  134 B that is compatible with connector  159 B such that the two connectors  134 B and  159 B can mate to provide an electrical, mechanical, or optical connection between cable  134  and accessory  150 . Cable  136  may include connector  136 A that is compatible with connector  159 C such that the two connectors  136 A and  159 C can mate to provide an electrical, mechanical, or optical connection between cable  136  and accessory  150 . Cable  136  may include connector  136 B that is compatible with connector  169 A such that the two connectors  136 B and  169 A can mate to provide an electrical, mechanical, or optical connection between cable  136  and accessory  160 . 
     Charging source  180  may be a charger block as shown, a charging station, a power adapter, a power brick, or any type of device that can source power, voltage, and/or current from a power source  190 . Power source  190  can be an electrical outlet as shown, or an external battery, an AC/DC converter, a power supply, etc. In  FIG. 2 , charging source  180  is shown as being external to accessory  160 . Alternatively, charging source  180  can be internal to accessory  160 . 
     Charging source  180  may include any suitable components typically found in such electronic devices necessary to perform the operations discussed herein. For example, charging source  180  may include connector  189 , such as a plug connector or a receptacle connector for mechanically and electrically coupling charging source  180  to other electronic components such as accessory  160 , where connector  189  may include one or more pins or conductive contacts for establishing electrical and/or optical communication with corresponding pins or contacts of a connector coupled to connector  189 . Charging source  180  may also include other suitable components typically found in such systems for performing the operations discussed herein, such as a processor (not shown), a tangible non-transitory computer readable storage medium (not shown), and the like, all operably coupled to one another such that the processor may execute instructions stored on the computer readable storage medium so as to cause charging source  180  to perform one or more of the operations discussed herein. 
       FIG. 2  illustrates a block diagram of a system  200  according to one embodiment of the present invention. An accessory (e.g., accessories  250  and  260 ) may include one or more power modules (e.g., power modules  252 A,  252 B, and  262 ) and one or more identification (ID) modules (e.g., ID modules  253 A,  253 B, and  263 ). An accessory may be coupled between an upstream device and a downstream device. The upstream device may be a charging source  280  or may be another accessory that is coupled towards the direction of a power source  290 . The downstream device may be a host device  220  or may be another accessory that is coupled towards the direction of the host device. The power module of an accessory can be used to control a power path between the upstream device and the downstream device through the accessory. The ID module can be used to authenticate the accessory to the upstream device and can be used to authenticate a downstream device. 
     In  FIG. 2 , charging source  280  may include a power module  282 , an ID module  283 , and a connector  289  coupled to power module  282  and ID module  283 . Charging source  280  may also include an AC/DC converter (not shown) that can convert an AC current from power source  290  into a DC current that can be provided on a power pin of connector  289 . 
     In one embodiment, the power module  282  may include power control circuitry that can control a power path between a power source  290  and connector  289 . In other words, power module  282  can control a power path between devices, e.g., accessory  260 , that may be mechanically, electrically, and/or optically coupled to connector  289 . Power module  282  may control the power path between power source  290  and accessory  260  in a number of ways. For example, power module  282  can selectively alter a characteristic of the power path, such as an electrical impedance, a voltage capacity, a current capacity, and the like. Additionally or alternatively, power module  282  may impose power limits, voltage limits, and/or current limits on power, voltage, and/or current, respectively, supplied to accessory  260  through a power pin of connector  289 . In some embodiments, power module  282  may impose limits on amplitude, frequency, phase, and/or other characteristics of a signal, such as an electrical signal and/or an optical signal, communicated to accessory  260  through a data pin of connector  289 . 
     According to one embodiment of the present invention, ID module  283  can authenticate accessory  260  that is coupled to the charging source  280  through connector  289 , and influence power module  282  to control the power path between power source  290  and connector  289 . For example, ID module  283  may send an ID request to accessory  260 , and receive an ID response from accessory  260 . ID module  283  may authenticate accessory  260  if the ID information in the ID response received from accessory  260  matches a set of known or compatible devices. ID module  283  may then send a signal to power module  282  to enable the power path between power source  290  and connector  289  such that a charging current can be provided to accessory  260 . In some embodiments, in a default state, power module  282  presents a high resistance path to the incoming voltage from power source  290 . This results in the power pin of connector  289  having low to no available current, and thus charging source  280  is unable to provide sufficient power to the downstream accessory, e.g., accessory  260 . 
     According to some embodiments, accessory  260  may include a power module  262 , an ID module  263 , and connectors  269 A and  269 B coupled to power module  262  and ID module  263 . Connector  269 B is compatible with connector  289  such that the two connectors  269 B and  289  can mate to provide an electrical, mechanical, or optical connection between charging source  280  and accessory  260 . 
     In one embodiment, power module  262  may include power control circuitry that can control a power path between connector  269 B and connector  269 A. In other words, the power module  262  can control a power path between an upstream device that may be mechanically, electrically, and/or optically coupled to connector  269 B, e.g., charging source  280 , and a downstream device that may be mechanically, electrically, and/or optically coupled to connector  269 A, e.g., accessory  250 . Power module  262  may control the power path between charging source  280  and accessory  250  in any one or more of a number of ways. For example, power module  262  may can selectively alter a characteristic of the power path, such as an electrical impedance, a voltage capacity, a current capacity, and the like of the power path. Additionally or alternatively, power module  262  may impose power limits, voltage limits, and/or current limits on power, voltage, and/or current, respectively, supplied to accessory  250  through a power pin of connector  269 A. In some embodiments, power module  262  may impose limits on amplitude, frequency, phase, and/or other characteristics of a signal, such as an electrical signal and/or an optical signal, communicated to accessory  250  through a data pin of connector  269 A. 
     According to one embodiment, ID module  263  may can send ID information identifying accessory  260  to charging source  280  to authenticate accessory  260 . ID module  263  may also be operable to authenticate a downstream device, e.g., accessory  250 , that is coupled to accessory  260  through connector  269 A. For example, ID module  263  may send an ID request to accessory  250 , and receive an ID response containing ID information identifying accessory  250 . ID module  263  may authenticate accessory  250  if the ID information received from accessory  250  matches a set of known or compatible devices. ID module  263  may then send a signal to the power module  262  to enable the power path between connector  269 A and connector  269 B such that a charging current can be provided to accessory  250 . 
     According to some embodiments, accessory  250  may connect multiple host devices such as host device  210  and host device  220  to accessory  260 . Accessory  250  may include a connector  259 C that is compatible with connector  269 A such that connector  259 C and connector  269 A can mate to provide an electrical, mechanical, and/or optical connection between accessory  260  and accessory  250 . Accessory  250  may include a connector for each host device that accessory  250  can connect to, for example, connector  259 A for host device  210  and connector  259 B for host device  220 . Accessory  250  may also include one power module and one ID module per host device that accessory  250  can connect to, for example power module  252 A and ID module  253 A for host device  210 , and power module  252 B and ID module  253 B for host device  220 . In other embodiments, the functionalities of power modules  252 A and  252 B can be combined into a single power module, and the functionalities of ID module  253 A and  253 B can be combined into a single ID module. Accessory  250  may also include power distribution circuitry  255  that can distribute a current received on connector  259 C into a charging current provided to connector  259 A for host device  210 , and a charging current provided to connector  259 B for host device  220 . In some embodiments, each of the power modules and the ID modules of accessories  250 ,  260 , power source  280 , and host devices  210 ,  220  may be implemented as single integrated circuits. In other embodiments, a combined power and ID module can be implemented as a single integrated chip in each of the devices. 
     According to some embodiments, power module  252 A can control a power path between accessory  260  and host device  210 , and power module  252 B can control a power path between accessory  260  and host device  220 . The functionality and operation of power modules  252 A and  252 B are similar to the functionality and operation of power module  262  described above, and hence need not be repeated here. In some embodiments, ID module  253 A can authenticate host device  210 , and ID module  253 B can authenticate host device  220 . The functionality and operation of ID modules  253 A and  253 B are similar to the functionality and operation of ID module  263  described above, and hence need not be repeated here. In addition, as will be described below, according to some embodiments, power distribution circuitry  255  can distribute the current received on connector  259 C as a charging current to host device  210  through power module  252 A and a charging current to host device  220  through power module  252 B. The amount of charging current provided to host devices  210  and  220  can be based on a charge current indicator from each host device. In some embodiments, power distribution circuitry  255  can also adjust the amount of charging current provided to host devices  210  and  220  based on charge current indicators periodically received from each host device. 
     Still referring to  FIG. 2 , the operations of charging host devices  210  and  220  through accessories  250  and  260  will now be described. It should be understood that the principles and operations described herein are applicable to other systems that may have a different topology or include a different number of accessories and/or a different number of host devices. When charging source  280  is first plugged into power source  290 , the power module  282  of the charging source  280  is operated in a current limiting mode, that is the power path between power source  290  and connector  289  is in a disabled state as described above. In this current limiting mode, power module  282  provides a limited current to connector  289 . The limited current may be, for example, 20 milliamps (mA), 25 mA, 10 mA, or 5 mA. The small amount of current provided by the limited current is insufficient to damage most types of accessory or host device, even an accessory or a host device that may be incompatible with the charging source  280 . The limited current enables accessory  260  to send identification (ID) information to the charging source  280  to identify accessory  260 . Charging source  280  receives the ID information and can determine if accessory  260  is compatible with the charging source  280 . Alternatively, the limited current may enable accessory  260  to send an ID request to charging source  280 , and to authenticate charging source  280  based on ID information identifying charging source  280  received from charging source  280  in response to the ID request. In some embodiments, the limited current may be insufficient to power other circuitry in accessory  260  besides ID module  263 . This may not allow accessory  260  to operate in a normal mode of operation or to be put into an active state. For example, the limited current may provide sufficient power to ID module  263  of accessory  260  to send or receive ID information, but may be insufficient to turn on speakers  262  of accessory  260 . 
     In one embodiment, ID module  283  of charging source  280  may send an ID request on a data pin of connector  289  to accessory  260 . The ID request may ask accessory  260  (i.e. the downstream device) to send identification information for the accessory. In some embodiments, the ID request may be sent by charging source  280  in response to detecting an input power signal from the power source  290 . In response to the ID request, accessory  260  may send back an ID response that includes the ID information identifying accessory  260 . The ID module  283  may authenticate accessory  260  if the ID information received from accessory  260  is recognized as a known or compatible accessory. If accessory  260  fails to respond to the ID request or if the ID information received from accessory  260  indicates an unknown or incompatible device, power module  282  may maintain the power path in a disabled state (i.e. the power module remains in current limiting mode). 
     If accessory  260  is authenticated by ID module  283 , ID module  283  may send a signal to power module  282  to put power module  282  in a bypass mode that enables the power path between power source  290  and connector  289  such that a charging current can be provided to the accessory  260 . In this bypass mode of operation, the charging current provided to the accessory  260  through connector  289  may be 5 amps (A), 3 A, 2 A, 1 A, 800 milliamps (mA), 500 mA, 200 mA, or 100 mA. In some embodiments, the charging current may be 10 times or 100 times the limited current. In some embodiments, the charging current may provide sufficient power to enable accessory  260  to operate in a normal mode of operation or to be put into an active state. For example, the charging current provided to accessory  260  may be sufficient to turn on the speakers of accessory  260 . 
     In other embodiments, ID module  283  of charging source  280  may not be required to send an ID request on a data pin of connector  289 . Instead, the limited current that is provided to accessory  260  may serve as the ID request itself. In other words, when accessory  260  detects the limited current from the charging source  280 , ID module  263  of accessory  260  may interpret this as an ID request and send ID information to charging source  280  in response to detecting the limited current. 
     In some embodiments, the ID information sent from ID module  263  of accessory  260  may include a charge current indicator. The charge current indicator may be used by charging source  280  to determine the amount of charging current to provide to accessory  260 . For example, in one embodiment, the charge current indicator may be a value identifying a charge level of a battery of accessory  260 , e.g., 50%, 30%, etc., if accessory  260  has such a battery. Charging source  280  may then provide an amount of charging current based on the charge level of the battery of accessory  260 . In some embodiments, the value identifying the charge level may be represented in form of a percentage value such as between 0% and 100%. In other embodiments, the value may be represented as a relative level such as low, med, and full. For example, if the charge level of the battery of accessory  260  is low (or e.g., below 20%), charging source  280  may provide to accessory  260  a maximum amount of charging current allowable for accessory  260  based on the battery and/or accessory specification of accessory  260 . If the charge level of the battery of accessory  260  is high (or e.g., about 90%), charging source  280  may provide a small amount of charging current to accessory  260 . 
     In another embodiment, the charge current indicator may include a value representing the amount of current being requested by accessory  260 . In one embodiment, accessory  260  may request a predetermined nominal amount of current, e.g., 2 Amps (A). In another embodiment, accessory  260  may request at least the amount of current required to operate accessory  260  in a normal mode of operation, e.g., 5 A, i.e. to turn on accessory  260  and to put accessory  260  into an active state. Charging source  280  may use the charge current indicator to provide a charging current to accessory  260  corresponding to the amount of current being requested by accessory  260 . In another embodiment, charging source  280  may provide a different amount of charging current to accessory  260  than the amount of current being requested by accessory  260 , for example, if charging source  280  cannot provide the amount of current being requested by accessory  260 . 
     After authenticating accessory  260 , charging source  280  may enable the power path from power source  290  to accessory  260 . Thus, it is not necessary to first authenticate host device  210  or host device  220  before power is provided to accessory  260 . With accessory  260  powered, accessory  260  may then provide an adequate limited current to accessory  250  to enable accessory  250  to be authenticated by accessory  260 , e.g., using the techniques described above. 
     Initially, power module  262  of accessory  260  is operated in a current limiting mode when power module  262  first detects an input power signal provided on connector  269 B by the charging source  280 . The power signal can be, for example, the charging current provided by charging source  280 . In this current limiting mode, the power path between connector  269 A and connector  269 B is in a disabled state, but power module  262  still provides a limited current to connector  269 A. The limited current may be, for example, 20 milliamps (mA), 25 mA, 10 mA, or 5 mA. The small amount of current provided by the limited current is insufficient to damage most types of accessory or host device, even an accessory or a host device that may be incompatible with accessory  260  and/or charging source  280 . The limited current enables a downstream device that is connected to connector  269 A, such as accessory  250 , to send identification (ID) information identifying the downstream device to accessory  260 . ID module  263  of the accessory  260  can then determine if the downstream device is compatible with accessory  260  and/or the charging source  280  and authenticate the downstream device. In some embodiments, the limited current may be insufficient to power other circuitry besides ID module  253 A or  253 B in accessory  250 . For example, the limited current may provide sufficient power to ID module  253 A or ID module  253 B of accessory  250  to send ID information identifying the accessory  250  to accessory  260 , but may be insufficient to turn on other circuitry of accessory  250 . It should be noted that in accessory  250 , according to one embodiment, either ID module  253 A or ID module  253 B can be configured as a master ID module that is responsible for sending ID information identifying accessory  250 . 
     In one embodiment, ID module  263  of accessory  260  may send an ID request on a data pin of connector  269 A to request ID information from accessory  250  (i.e. the downstream device) in response to detecting the input power signal from charging source  280  (i.e. the upstream device). In response to the ID request, accessory  250  may send back an ID response that includes ID information identifying accessory  250 . ID module  263  may authenticate accessory  250  if the ID information received from accessory  250  is recognized as a known or compatible accessory. If accessory  250  fails to respond to the ID request or if the ID information received from accessory  250  indicates an unknown or incompatible device, power module  262  may maintain the power path between connector  269 A and connector  269 B in a disabled state (i.e. the power module  262  remains in a current limiting mode). 
     If the accessory  250  is authenticated by ID module  263  of accessory  260 , ID module  263  may then send a signal to the power module  262  to put the power module  262  in a bypass mode that enables the power path between connector  269 A and connector  269 B such that a charging current can be provided to the accessory  250 . In this bypass mode of operation, the charging current provided to the accessory  250  through connector  269 A may be 5 Amps (A), 3 A, 2 A, 1 A, 800 milliamps (mA), 500 mA, 200 mA, or 100 mA. In some embodiments, the charging current may be at least 10 times or 100 times the limited current. In some embodiments, the charging current may provide sufficient power to enable accessory  250  to operate in a normal mode of operation. For example, the charging current provided to accessory  250  may be sufficient to put accessory  250  into an active state. 
     In other embodiments, ID module  263  of accessory  260  may not be required to send an ID request on a data pin of connector  269 A to request ID information from accessory  250 . Instead, the limited current that is provided to accessory  250  may serve as the ID request itself. In other words, when accessory  250  detects the limited current from accessory  260 , the ID module  253 A or ID module  253 B of accessory  250  would interpret this as an ID request and send ID information to accessory  260  in response to detecting the limited current. 
     In some embodiments, the ID information sent from the ID module  253 A or ID module  253 B of accessory  250  may include a charge current indicator that is used by accessory  260  to determine the amount of charging current to provide to accessory  250 . For example, in one embodiment, the charge current indicator may be a value identifying a charge level of a battery of accessory  250 , e.g., 50%, 30%, etc., if accessory  250  has such a battery. Accessory  260  may then provide an amount of charging current based on the charge level of the battery of accessory  250 . In some embodiments, the value identifying the charge level may be represented in form of a percentage value such as between 0% and 100%. In other embodiments, the value may be represented as a relative level such as low, med, and full. For example, if the charge level of the battery of accessory  250  is low (or e.g., below 20%), accessory  260  may provide to accessory  250  a maximum amount of charging current allowable for accessory  250  based on the battery and/or accessory specification of accessory  250 . If the charge level of the battery of accessory  250  is high (or e.g., about 90%), accessory  260  may provide a small amount of charging current to accessory  250 . 
     In another embodiment, the charge current indicator may include a value representing the amount of current being requested by accessory  250 . In one embodiment, accessory  250  may request a predetermined nominal amount of current, e.g., 2 Amps (A). In another embodiment, accessory  250  may request at least the amount of current required to operate accessory  250  in a normal mode of operation, e.g., 5 A, i.e. to turn on accessory  250  and to put accessory  250  into an active state. Accessory  260  may use the charge current indicator to provide a charging current to accessory  250  corresponding to the amount of current being requested by accessory  250 . In another embodiment, accessory  260  may provide a different amount of charging current to accessory  250  than the amount of current being requested by accessory  250 , for example, if accessory  260  cannot provide the amount of current being requested by accessory  250 . 
     In some embodiments, the amount of charging current provided to accessory  260  by charging source  280  that was previously requested by accessory  260  may be insufficient to compensate for the amount of current being requested by accessory  250 . For example, accessory  260  may have requested 50 mA from charging source  280  when accessory  260  was first authenticated. At that time, accessory  260  was unaware of the amount of current that accessory  250  may request because accessory  250  has not yet been authenticated by accessory  260 . In an exemplary embodiment, upon authenticating accessory  250 , accessory  250  may request 200 mA from accessory  260 . Thus, the 50 mA that is being provided to accessory  260  from charging source  280  may be insufficient to supply the 200 mA that is being requested by accessory  250 . Accordingly, in some embodiments, accessory  260  may, in response to authenticating accessory  250 , send a command that includes an updated charge current indicator to charging source  280  to request an updated amount of current. The updated charge current indicator may include a value representing at least the amount of current being requested by accessory  250 . In other words, in the above example, accessory  260  may send an updated charge current indicator to charging source  280  that includes a value representing at least 200 mA. In other embodiments, the updated charge current indicator may include a value representing a sum of the amount of current being requested by accessory  250  and accessory  260 . In other words, in the example above, the updated charge current indicator may include a value representing 250 mA. 
     Having authenticated accessory  250 , accessory  260  may enable the power path from charging source  280  to accessory  250 . Thus, it is not necessary to first authenticate host device  210  or host device  220  before providing power to accessory  250 . With accessory  250  being powered, accessory  250  may then provide an adequate limited current to host devices  210  and  220  to enable the host devices  210  and  220  to be authenticated by accessory  250 , even when the respective battery of host devices  210  and  220  are dead, and even when charging source  280  is coupled to host devices  210  and  220  through one or more accessories, for example, accessories  250  and  260 . 
     Initially, power modules  252 A and  252 B of accessory  250  are in a current limiting mode when power modules  252 A and  252 B first detect an input power signal provided on connector  259 C by accessory  260 . The power signal can be, for example, the charging current provided by accessory  260 . In this current limiting mode, the power path between connector  259 A and connector  259 C, and the power path between connector  259 B and connector  259 C are in a disabled state, but power modules  252 A and  252 B still provides a limited current to connector  259 A and  259 B, respectively. The limited current may be, for example, 20 mA, 25 mA, 10 mA, or 5 mA. The small amount of current provided by the limited current is insufficient to damage most types of accessory or host device, even an accessory or a host device that may be incompatible with accessory  250  or charging source  280 . The limited current enables host device  210  that is connected to connector  259 A and/or host device  220  that is connected to connector  259 B to send identification (ID) information to accessory  250  to identify the respective host devices such that ID modules  253 A and  253 B of the accessory  250  can determine if the respective host devices are compatible with accessory  250  and/or charging source  280 . In some embodiments, the limited current may be insufficient to provide power to the other circuitry in the host device to enable the host device to operate in a normal mode of operation. For example, the limited current may provide sufficient power to control circuitry  211  of host device  210  and/or control circuitry  221  of host device  220  to send ID information identifying the respective host device to accessory  250 , but may be insufficient to power or turn on other circuitry (e.g., a display) of the respective host device to enable the host device to be in an active state. 
     The operations of authenticating and enabling a power path to host device  210  by accessory  250  will now be described with reference to power module  252 A and ID module  253 A. In one embodiment, ID module  253 A of accessory  250  may send an ID request on a data pin of connector  259 A to request ID information from host device  210  upon detecting the input power signal from accessory  260 . In response to the ID request, control circuitry  211  of host device  210  may send back an ID response that includes ID information identifying host device  210 . ID module  253 A may authenticate host device  210  if the ID information received from host device  210  is recognized as a known or compatible host device. If host device  210  fails to respond to the ID request, or if the ID information received from host device  210  indicates an unknown or incompatible device, power module  252 A may maintain the power path between connector  259 A and connector  259 C in a disabled state (i.e. power module  252 A remains in a current limiting mode). 
     If host device  210  is authenticated by ID module  253 A of accessory  250 , ID module  253 A may then send a signal to power module  252 A to put power module  252 A in a bypass mode that enables the power path between connector  259 A and connector  259 C such that a charging current can be provided to host device  210 . In this bypass mode of operation, the charging current provided to the host device  210  through connector  259 A may be 5 amps (A), 3 A, 2 A, 1 A, 800 milliamps (mA), 500 mA, 200 mA, or 100 mA, or the charging current may be at least 10 times or 100 times the limited current. In some embodiments, the charging current may provide sufficient power to enable host device  210  to operate in a normal mode of operation. For example, the charging current provided to host device  210  may be sufficient to put host device  210  into an active state. 
     In other embodiments, the ID module  253 A of accessory  250  may not be required to send an ID request on a data pin of connector  259 A to request ID information from the host device  210 . Instead, the limited current that is provided to host device  210  may serve as the ID request itself. In other words, when host device  210  detects the limited current from the accessory  250 , the control circuitry  211  of the host device  210  would interpret this as an ID request and send ID information to accessory  250  in response to detecting the limited current. 
     In some embodiments, the ID information sent from control circuitry  211  of host device  210  may include a charge current indicator that is used by accessory  250  to determine the amount of charging current to provide to host device  210 . For example, in one embodiment, the charge current indicator may be a value identifying a charge level of a battery of host device  210 , e.g., 50%, 30%, etc. Accessory  250  may then provide an amount of charging current based on the charge level of the battery of host device  210 . In some embodiments, the value identifying the charge level may be represented in form of a percentage value such as between 0% and 100%. In other embodiments, the value may be represented as a relative level such as low, med, and full. For example, if the charge level of the battery of host device  210  is low (or e.g., below 20%), accessory  250  may provide to host device  210  a maximum amount of charging current allowable for host device  210  based on the battery and/or specification of host device  210 . If the charge level of the battery of host device  210  is high (or e.g., about 90%), accessory  250  may provide a small amount of charging current to host device  210 . 
     In another embodiment, the charge current indicator may include a value representing the amount of current being requested by host device  210 . In another embodiment, the charge current indicator may include a value representing the amount of current being requested by host device  210 . In one embodiment, host device  210  may request a predetermined nominal amount of current, e.g., 2 Amps (A). In another embodiment, host device  210  may request at least the amount of current required to operate host device  210  in a normal mode of operation, e.g., 5 A, i.e. to turn on host device  210  and to put host device  210  into an active state. Accessory  250  may use the charge current indicator to provide a charging current to host device  210  corresponding to the amount of current being requested by host device  210 . In another embodiment, accessory  250  may provide a different amount of charging current to host device  210  than the amount of current being requested by host device  210 , for example, if accessory  250  cannot provide the amount of current being requested by host device  210 . 
     The operations of authenticating and enabling a power path to host device  220  with power module  252 B and ID module  253 B are similar to those described above, and hence need not be repeated here. 
     Upon authenticating host devices  210  and  220 , accessory  250  may supply both a charging current to charge or operate host device  210  and a charging current to charge or operate host device  220 . In one embodiment, the amount of current provided to accessory  250  by accessory  260  may be less than the total amount of charging current being requested by host devices  210  and  220 . For example, accessory  250  may have requested 200 mA from accessory  260  when accessory  250  was first authenticated. At that time, accessory  250  was unaware of the amount of current that host devices  210  and  220  may request, because host devices  210  and  220  had not yet been authenticated. Upon authenticating host devices  210  and  220 , host device  210  may request, for example, 2 Amps (A), while host device  220  may request, for example, 500 milliamps (mA). The 200 mA provided to accessory  250  is less than the total requested current of 2.5 A that is now being requested by host devices  210  and  220 . Accordingly, in some embodiments, accessory  250  may, in response to authenticating host devices  210  and  220 , send a command to accessory  260  that includes an updated charge current indicator to request an updated amount of charging current. Accessory  260  may propagate the updated charge current indicator to charging source  280  to request an updated amount of charging current. 
     In some embodiments, charging source  280  may be incapable of supplying the total amount of current request by both host devices  210  and  220 . Accordingly, accessory  250  may request the maximum amount of current that charging source  280  can supply and distribute the current into respective charging currents for host devices  210  and  220 . The charging current provided to each host device would be in the same proportion as the charge current indicator provided by each host device. For example, continuing with the example given above, host device  210  may request 2 Amps (A), and host device  220  may request 1 A. As an example, charging source  280  may be only capable of supply 600 mA. In such a scenario, the power distribution circuitry  255  of accessory  250  may take the 600 mA provided from charging source  280  and distribute 400 mA to host device  210  and 200 mA to host device  220 . In other words, the charging current provided to each host device may have the same proportion as the amount of current requested by each host device as indicated by the respective charge current indicators. 
     Furthermore, as the battery of each host device charges, each host device may send a command with a subsequent charge current indicator to accessory  250  to request a change in the amount of charging current provided to the host device. For example, host device  210  or host device  220  may send a subsequent charge current indicator to adjust the charging current when the battery of the respective host device reaches 20%, 25%, 50%, 80%, 90% of full charge and when the battery is fully charged. Because the battery capacity of host device  210  may be different than the battery capacity of host device  220 , each battery may charge up at a different rate. As a result, as accessory  250  receives the subsequent charge current indicator from each host device, the power distribution circuitry  255  adjusts and redistributes the amount of charging current provided to each host device accordingly. In some embodiments, accessory  250  may periodically send a command with an updated charge current indicator to accessory  260  to reduce or increase the amount charging current being provided to accessory  250  as the battery of respective host device charges up. 
     In some embodiments, instead of distributing the current from charging source  280  in a proportional manner as described above when charging source  280  is incapable of supplying the total amount of current request by both host devices  210  and  220 , accessory  250  may provide a charging current to only one of the host devices  210  and  220 . For example, suppose host device  210  requests 500 mA, and host device  220  also requests 500 mA. Charging source  280  may be only capable of supply 600 mA. Distributing the current in a proportional manner may result in 300 mA being provided to both host devices  210  and  220 . However, if 300 mA is below the minimum current requirement for charging the battery of each host device according to the specification of the battery and/or host device, distributing the current in a proportional manner may result in a scenario where neither of the host device may charge. In such a scenario where distributing the current in a proportional manner may result in at least one of the host devices to not charge, power distribution circuitry  255  of accessory  250  may provide a charging current to only one of the host device (e.g., by disabling the power path to the other host devices). For example, power distribution circuitry  255  of accessory  250  may provide no current to host device  210 , and a charging current of 500 mA to host device  220  such that the battery of host device  220  can charge. When the battery of host device  220  charges up to a certain level (e.g., 50%, 90%, etc.) or is fully charged, power distribution circuitry  255  of accessory  250  may switch from providing a charging current to host device  220  to providing a charging current to host device  210 . In other words, in some embodiments, power distribution circuitry  255  of accessory  250  may provide a charging current to one host device at a time to charge the host devices in a serial manner. 
       FIG. 3  illustrates the circuitry of an accessory  300 , which can be, for example, accessory  260 , according to one embodiment. The accessory  300  includes a connector  309 B for coupling to an upstream device such as charging source  280  of  FIG. 2  and a connector  309 A for coupling to a downstream device such as accessory  250  of  FIG. 2 . Accessory  300  includes a power module  302  with power control circuitry for controlling a power path (e.g., power path through line  351  and line  352 ) between connector  309 A and connector  309 B. Accessory  300  also includes ID module  303  that can send ID information identifying accessory  300  to an upstream device in order to receive power from the upstream device. Also, ID module  303  can receive ID information from a downstream device prior to enabling the power path between connector  309 A and connector  309 B. 
     ID module  303 , which may be implemented at least partially in hardware or software as a processor (either single core or multi-core) or other type of logic (e.g., an ASIC), may be operable to receive power and data via connector  309 B or connector  309 A and respond to the received data. For example, ID module  303  may have stored therein ID information such as an accessory identifier, and may be operable to communicate the accessory identifier to an upstream device in response to receiving a request for the ID information. ID module  303  may also be operable to send instructions to power module  302  instructing power module  302  to alter an impedance of the power path between connector  309 A and connector  309 B and hence enable or disable the power path between lines  351  and  352 . 
     Power module  302 , which may be implemented at least partially in hardware or software as a processor (either single core or multi-core) or other type of logic, (e.g., an ASIC), may be operable to alter an impedance of the power path between connector  309 A and connector  309 B. This may be in response to an instruction from ID module  303  or, in some embodiments, in response to an instruction sent directly from a device coupled through connector  309 A or connector  309 B. There are various ways that power module  302  may alter the impedance of the power path, as further described herein. 
     Referring to  FIG. 3 , power module  302  according to this embodiment includes a resistive element  321  coupled in parallel with a switch  322 . Resistive element  321  and switch  322  are arranged along or in-line with a power path between connector  309 A and connector  309 B. Resistive element  321  may provide any suitable resistance for measurably altering an impedance characteristic of accessory  300 . For example, resistive element  321  may have a resistance of 1 Ohm, 2 Ohm, 3 Ohm, 100 Ohm, 200 Ohm, 300 Ohm, 1 kOhm, 2 kOhm, 3 kOhm, 1 MOhm, 2 MOhm, 3 MOhm, be in a range from 1 to 3 Ohm, 100 Ohm to 300 Ohm, 1 kOhm to 3 kOhm, 1 MOhm to 3 MOhm, or less than 1 Ohm or greater than 3 MOhm. Resistive element  321  may be coupled to a power pin of connector  309 B on one end and a power pin of connector  309 A on the other end, such that resistive element  321  is disposed along a power path between connector  309 A and connector  309 B. 
     Switch  322  may be any suitable switching element that allows current provided from connector  309 B to selectively bypass resistive element  321 . For example, switch  322  may be a MOSFET, JFET, or other type of transistor or other semiconductor device that can switch electronic signals and power. Switch  322  is coupled in parallel to resistive element  321  and includes a first terminal (e.g., a source) coupled to one end of resistive element  321 , a second terminal (e.g., a drain) coupled to second end of resistive element  321 , and a third terminal (e.g., a gate) for controlling the operation of switch  322 . In an OFF state, switch  322  has a resistance significantly higher than the resistance of resistive element  321 . In an ON state, switch  322  has a resistance that is significantly lower than the resistance of resistive element  321 . 
     As described above, power module  302  may operate to alter an impedance of a power path between connector  309 A and connector  309 B. In some embodiments, power module  302  may operate in different modes, e.g., a bypass mode and a current limiting mode. Such modes may be entered in response to instructions from ID module  303  and, in some embodiments, power module  302  may operate in some modes (e.g., the current limiting mode) by default. 
     In one embodiment, the bypass mode may result from switch  322  being in the ON state. As a result of the relatively low resistance of switch  322  as compared to resistive element  321 , current provided from connector  309 B may pass through the accessory  300  substantially unaltered. Power module  302  may also operate in a current limiting mode. While in the current limiting mode of operation, power module  302  may operate to limit an amount of current provided from connector  309 B to connector  309 A. In one embodiment, this may be achieved by placing switch  322  into the OFF state. As a result of the relatively high resistance of switch  322  as compared to resistive element  321 , current provided from connector  309 B may pass through resistive element  321 . Since resistive element  321  has a resistance that is greater than a nominal amount such as 0 Ohm, the amount of current passing through to connector  309 A available at the output end of resistive element  322  depends on the value of resistive element  321 . Hence, when power module  302  is operated in the bypass mode, the incoming current received on connector  309 B can be provided to connector  309 A through switch  322 . When power module  302  is operated in the current limiting mode, a limited current can be provided to connector  309 A from connector  309 B through resistive element  321 . 
     In accordance with the embodiment depicted in  FIG. 3 , ID module  303  may include circuitry to facilitate single-wire open-drain communication. In some embodiments, the functionality provided by such circuitry may be performed by a processor (single core or multi-core), multiple processors or other suitable circuitry. In the embodiment described with reference to  FIG. 3 , the circuitry for providing the single-wire open-drain communication interface may include an internal power line  336 , an internal transmit line  337 , and an internal receive line  338 , each coupled to a controller  331  and data pins  361  and  362 . 
     In accordance with this embodiment, a single-wire open-drain communication interface may be used to allow an external device coupled to connector  309 A (e.g., a downstream device) to communicate with accessory  300  on data pin  362 , and an external device coupled to connector  309 B (e.g., an upstream device) to communicate with accessory  300  on data pin  361 . In such a case, an active or passive pull-up resistance (not shown) may be used to pull data pin  361  to a high state when neither accessory  300  nor an external device coupled to connector  309 B communicate information over data pin  361 . To communicate information between one another, an external device coupled to connector  309 B and/or accessory  300  may pull data pin  361  low. Similarly, an active or passive pull-up resistance (not shown) may be used to pull data pin  362  to a high state when neither accessory  300  nor an external device coupled to connector  309 A communicate information over data pin  362 . To communicate information between one another, an external device coupled to connector  309 A and/or accessory  300  may pull data pin  362  low. 
     Internal power line  336  may be used to power the ID module  303 . Internal power line  336  may be coupled to one end of a capacitor  332  or other type of charge storage element, where the other end of capacitor  332  is coupled to ground. Internal power line  336  may be coupled to data pin  362  via a diode  335 , which may be used to prevent capacitor  332  from discharging through data pin  362 . In operation, a high voltage state at data pin  362  may cause capacitor  332  to charge and provide power to internal circuitry of accessory  300 , e.g., controller  331 . Similarly, a high voltage state at data pin  361  may cause controller  331  to provide a signal to charge capacitor  332 . When information is communicated between an external device and accessory  300 , by way of pulling down the voltage of data pin  361  or data pin  362 , capacitor  332  may have enough stored charge to facilitate at least temporary operation of accessory  300 . Accordingly, in some embodiments, power provided via internal power line  336  may be sufficient to fully power all components of accessory  300 . In other embodiments, however, power provided via internal power line  336  may be sufficient to only power a subset of the components of accessory  300 . For example, power provided via internal power line  336  may be sufficient to only power operation of ID module  303 . In some embodiments, accessory  300  may receive additional or alternative power for operating one or more of its components via a power source other than the power provided via internal power line  336 , such as via a power pin on connector  309 A or connector  309 B. 
     Returning to  FIG. 3 , internal transmit line  337  may be used to communicate information from accessory  300  to an external device, for example to send an ID request or to send ID information. Internal transmit line  337  may be coupled to data pin  362  via a transmission switch  333 , and may be coupled to internal circuitry such as controller  331  that can communicate information to the external device via changes in voltage levels. Transmission switch  333  may be a MOSFET, JFET, or other type of transistor or other semiconductor device that can switch electronic signals and power. Transmission switch  333  may include multiple terminals, such as a gate coupled to internal transmit line  337 , a source coupled to data pin  362  and, in some embodiments, to diode  335 , and a drain coupled to ground. Controller  331  or other internal circuitry of accessory  300  can change a state of transmission switch  333 , where changing a state of transmission switch  333  may cause a change in voltage at data pin  362 . For example, by placing transmission switch  333  into an ON state, the voltage at data pin  362  may be pulled to ground or some other low voltage. By placing transmission switch  333  into an OFF state, the voltage at data pin  362  may return to a higher voltage than ground, e.g., 5V. 
     It should be recognized that in some embodiments, accessory  300  may also or alternatively transmit information to an external device via some other means other than internal transmit line  337 . For example, accessory  300  may transmit information to an external device via a pin other than data pins  361  or  362 . For another example, accessory  300  may transmit information wirelessly to the external device. 
     Internal receive line  338  may be used to receive information such as an ID request or ID information from an external device via data pins  361  or  362 . Internal receive line  338  may be coupled to some internal circuitry such as controller  331  that can interpret changes in voltage levels provided at internal receive line  338 , and may also be coupled to data pin  362  via an amplifier element  334  that can amplify the voltage received at data pin  362 . In operation, controller  331  or other internal circuitry coupled to internal receive line  338  may be operable to receive and interpret information communicated to accessory  300  from an external device. 
     It should be recognized that in some embodiments, accessory  300  may also or alternatively receive information from an external device via some means other than internal receive line  338 . For example, accessory  300  may receive information from an external device via a pin other than data pins  361  or  362 . For another example, accessory  300  may receive information wirelessly from an external device. 
     While single-wire open-drain communication circuitry is disclosed in detail with reference to  FIG. 3 , it should be recognized that embodiments of the present invention are not limited to communication between accessory  300  and an external device (e.g., an upstream device or a downstream device) using such circuitry. Rather, accessory  300  may include any suitable circuitry for establishing communication with an external device over any suitable communication protocol. For example, accessory  300  may include suitable circuitry for establishing serial communication such as that defined by the RS-232 standard and/or that using a UART transceiver, parallel communication such as that defined by the IEEE-488 protocol, USB communication, PCI communication, etc. 
       FIG. 4  illustrates an accessory  400  that includes power distribution circuitry  455  according to one embodiment. Accessory  400  can be implemented, e.g., as accessory  250  of  FIG. 2 . According to this embodiment, accessory  400  can provide a charging current to two downstream devices that may be coupled to connector  409 A and connector  409 B, respectively. In other embodiments, accessory  400  can provide a charging current to a different number of downstream devices. Accessory  400  may include a power module  402 A that can control a power path between an upstream device coupled to connector  409 C and a downstream device coupled to connector  409 A, and an ID module  403 A that can communicate with an upstream device coupled to connector  409 C and a downstream device coupled to connector  409 A. Accessory  400  may also include a power module  402 B that can control a power path between an upstream device coupled to connector  409 C and a downstream device coupled to connector  409 B, and an ID module  403 B that can communicate with an upstream device coupled to connector  409 C and a downstream device coupled to connector  409 B. In an alternative embodiment, there may be only one power module and one ID module, and the functionalities and operations of the two sets of modules are combined into one set of modules. 
     The operations of ID modules  403 A and  403 B are similar to those discussed above with reference to ID module  303  of  FIG. 3 , and the operations of power modules  402 A and  402 B are similar to those discussed above with reference to power module  302  of  FIG. 3 , and hence need not be repeated here. 
     Power distribution circuitry  455  includes a controller  456  and one or more current control circuits  458 A and  458 B which collectively function as current divider circuitry. Current control circuit  458 A is placed in a power path between the upstream device that is connected to connector  409 C and power module  402 A. Current control circuit  458 B is placed in a power path between the upstream device that is connected to connector  409 C and power module  402 B. In one embodiment, the current control circuits  458 A and  458 B may be impedance altering circuits as shown, where the impedance of the circuits can be adjusted to control the current passing through the current control circuits  458 A and  458 B. It should be understood that in alternative embodiments, other current dividing mechanism or control can be used by power distribution circuitry  455 . 
     In one embodiment, upon connection of a downstream device, e.g., host device  210  or  220  of  FIG. 2 , to each of connectors  409 A and  409 B, the downstream devices can send their identification information and a charge current indicator to accessory  400 . Accessory  400  can receive the charge current indicators, e.g., at ID modules  403 A and  403 B. Upon authenticating the downstream devices, ID modules  403 A and  403 B may send the received charge current indicators to the controller  456  of the power distribution circuitry  455 . In one embodiment, controller  456  can sum up the charge current indicators to determine the total amount of charging current being requested by all downstream devices that are coupled to accessory  400  and determine the percentage of the total amount of charging current that each downstream device is requesting based on the charge current indicator provided by each of the downstream devices. Controller  456  can adjust the impedance of the current control circuits  458 A and  458 B such that the charging current provided to each of the downstream devices corresponds to the charging current requested by each downstream device. 
     For example, suppose controller  456  determines that the amount of current being requested by a downstream device coupled to connector  409 A is 25% of the total amount of current being requested of accessory  400  from all host devices coupled to accessory  400 , and that the amount of current being requested by a downstream device coupled to connector  409 B is 75% of the total amount of current being requested of accessory  400  from all host devices coupled to accessory  400 . In some embodiments, controller  456  may adjust the impedance of current control circuit  458 A to be 75% of the total impedance of current control circuits  458 A and  458 B, and adjust the impedance of current control circuit  458 B to be 25% of the total impedance of current control circuits  458 A and  458 B to distribute 25% of the current received on connector  409 C to a downstream device coupled to connector  409 A, and 75% of the current received on connector  409 C to a downstream device coupled to connector  409 B. In other embodiments, controller  456  may also take into account the input impedance of the downstream devices when adjusting the current control circuits  458 A and  458 B, because the input impedance of the downstream devices may affect the amount of current being distributed through the current divider circuitry (e.g., current control circuits  458 A and  458 B). 
     In some embodiments, controller  456  may determine that distributing the current received on connector  409 C to both a downstream device coupled to connector  409 A and a downstream device coupled to connector  409 B may cause at least one of the downstream devices to not charge, for example, if the amount of current provided to the downstream device is below the minimum requirement for charging the battery of that downstream device. In such an embodiment, controller  456  may disable a power path between connector  409 C and connector  409 A to provide the current received on connector  409 C to only the downstream device coupled to connector  409 B, or alternatively disable a power path between connector  409 C and connector  409 B to provide the current received on connector  409 C to only the downstream device coupled to connector  409 A. This way, one of the downstream devices can be charged if the current received on connector  409 C is insufficient to charge both downstream devices. When the one downstream device charges up, controller  456  may disable the power path to that downstream device and enable the power path to the other downstream device to charge the other downstream device. In other words, controller  456  may alternately enable and disable the power path to each downstream device to charge the downstream devices in a serial manner. 
       FIG. 5  illustrates a host device  500 , which can be, for example, host device  210  or  220 , according to one embodiment. Host device  500  can include processor  511 , memory  512 , user interface (UI)  513 , network interface  514 , and connector  519 . Processor  511 , which can be implemented as one or more integrated circuits (including, e.g., one or more microprocessors and/or microcontrollers and/or a multi-core processor), may control the operation of host device  500 . For example, in response to user input signals provided by user interface  513 , processor  511  can perform various tasks such as selecting and playing media assets that may be stored in memory  512 , accessing various networks (e.g., a mobile telephone network, the Internet, local area network, or the like) to send and/or retrieve data using network interface  514 , executing software residing in memory  512 , and so on. Processor  511  can also manage communication and exchange data with accessories via connector  519 . 
     Memory  512  may be implemented using disk, non-volatile memory such as flash memory, ROM, PROM, EPROM or other non-volatile storage medium, or a combination thereof. Memory  512  may also include random access memory (RAM). Memory  512  can store application programs that are executable by processor  511 , system programs and other program code (not explicitly shown), and various data and/or information that can be used in managing communication with various accessories. In some embodiments, memory  512  can also store media assets such as audio, video, still images, or the like, that can be played by host device  500 , along with metadata describing the media assets (e.g., asset name, artist, title, genre, etc.), playlists (lists of assets that can be played sequentially or in random order), and the like. Memory  512  can also store any other type of information such as information about a user&#39;s contacts (names, addresses, phone numbers, etc.); scheduled appointments and events; notes; and/or other personal information. 
     In some embodiments, the control circuitry in host device  500  responsible for sending ID information to an accessory coupled to connector  519  (e.g., control circuitry  211  and  221  in  FIG. 2 ) may be implemented using a combination of processor  511  and memory  512 . For example, the ID information identifying host device  500  may be stored in memory  512 , and processor  511  can be configured to send the ID information on connector  519  in response to receiving an ID request. In other embodiments, the control circuitry (e.g., control circuitry  211  and  221  in  FIG. 2 ) in host device  500  responsible for sending ID information to an accessory coupled to connector  519  may be implemented with circuitry similar to ID module  303  as described with reference to  FIG. 3 . 
     Network interface  514  can provide an interface to one or more communication networks. For example, network interface  514  can incorporate a radio frequency (RF) transceiver and suitable components for communicating via a mobile communication network such as a mobile telephone network. Additionally or instead, network interface  514  can incorporate a wireless connection to the Internet (e.g., a WiFi transceiver, 3G/4G transceiver or the like), to a personal area network (e.g., a Bluetooth network), or any other network. In still other embodiments, a wired network connection (e.g., Ethernet) may be provided. In some embodiments, the same hardware can be used to support connections to multiple networks; thus, network interface  514  can include analog to digital and/or digital to analog circuitry, baseband processing components (e.g., codecs, channel estimators, and the like), modulators, demodulators, oscillators, amplifiers, transmitters, receivers, transceivers, internal and/or external antennas, and so on. In some embodiments, some operations associated with network connectivity can be implemented entirely or in part as programs executed on processor  511  (e.g., encoding, decoding, and/or other processing in the digital domain), or a dedicated digital signal processor can be provided. 
     User interface  513  can include input controls such as a touch pad, touch screen, scroll wheel, click wheel, dial, button, keypad, microphone, etc., as well as output devices such as a display screen, indicator lights, speakers, headphone jacks, etc., together with supporting electronics (e.g., digital-to-analog or analog-to-digital converters, signal processors or the like). A user can operate the various input controls of user interface  513  to invoke the functionalities of host device  500  and can also view and/or hear output from host device  500  via user interface  513 . 
       FIG. 6  illustrates a flow chart  600  for charging a host device through an accessory according to some embodiments. At block  602 , the accessory may receive an ID request from an upstream device coupled to the accessory. The upstream device can be a charging source or another accessory. At block  604 , in response to receiving the ID request from the upstream device, the accessory may sends an ID response to the upstream device. The ID response may include ID information identifying the accessory and may also include a charge current indicator. The upstream device may authenticate the accessory and provide a charging current to the accessory based on the charge current indicator in the ID response. At block  606 , the accessory may receive an input power signal from the upstream device. In one embodiment, the input power signal may be the presence of a voltage or a current detected on a power pin of the accessory. In another embodiment, the input power signal may be a change in a voltage level or a current on a power pin of the accessory, for example, an increase from a nominal voltage to a supply voltage on an input power pin, or an increase from a limited current to the charging current being received on an input power pin. 
     Upon detecting the input power signal from the upstream device, at block  608 , the accessory may provide a limited current to a downstream device. The downstream device can be a host device or another accessory. The limited current provided to the downstream device enables the downstream device to send identification (ID) information to the accessory. Thus, in some embodiments, even when if the battery of the downstream device is dead (i.e. the battery is completely drained, or the battery is drained to the extent that the circuitry of the downstream device responsible for sending the ID information cannot properly operate when using the battery as a power source), the downstream device can still be authenticated by the accessory. 
     At block  610 , the accessory may send an identification (ID) request to the downstream device to request the downstream device to send ID information identifying the downstream device to the accessory. In one embodiment, the ID request can be sent as a command on a data pin. In an alternative embodiment, the limited current provided in block  608  can serve as the ID request. 
     At block  612 , the accessory may receive an ID response that include ID information identifying the downstream device. The ID response may also include a charge current indicator from the downstream device. The charge current indicator can be used by the accessory to determine the amount of charging current to provide to the downstream device upon authenticating the downstream device. In one embodiment, the charge current indicator may represent a charge level of the battery of the downstream device. In a different embodiment, the charge current indicator may represent the amount of charging current requested by the downstream device. 
     At block  614 , the accessory may determine if the downstream device is authenticated, that is, if the downstream device is a known or compatible device that can interoperate with the accessory or the upstream device. If the ID information in the ID response sent from the downstream device is recognized or known to the accessory, then the downstream device can be authenticated, and the process continues at block  616 . If the downstream device fails to send ID information to the accessory, for example, after a predetermined period of time such as 2 second, 5, seconds, or 20 seconds, or after a time-out timer expires in the accessory, the downstream device may not be authenticated. Or if the downstream device sends ID information that is not recognized by the accessory or is otherwise determined to be an incompatible device, the downstream device may not be authenticated. In some embodiments, the accessory may send a predetermined number of ID request, for example 5 times, 10 times, or 20 times, in an attempt to request ID information from the downstream device (not shown). If a recognizable or compatible ID information is not received from the downstream device after the predetermined number of ID requests are sent, the process may terminate. 
     If the downstream device is authenticated at block  614 , then at block  616 , the accessory enables a power path between the upstream device and the downstream device to provide a charging current to the downstream device. The amount of charging current provided by the accessory may be dependent on the charge current indicator that the downstream device sent to the accessory. In one embodiment, if the current provided to the accessory by the upstream device is insufficient to meet the amount of charging current requested by the downstream device, the accessory may send a command that includes an updated charge current indicator to the upstream device to ask the upstream device to provide the appropriate amount of charging current such that the accessory can provide the amount of charging current requested by the downstream device. 
     In some embodiments, as the downstream device charges up, the downstream device may adjust the amount of charging current the downstream device requests by sending a subsequent charge current indicator to the accessory. In such embodiments, the charging process continues with flow chart  700  of  FIG. 7 . 
       FIG. 7  illustrates a flow chart  700  for updating the amount of charging current provided to a downstream device by an accessory according to some embodiments. As the battery of the downstream device charges up, the downstream device may send a command that includes a subsequent charge current indicator to the accessory to request the accessory to alter or adjust the amount of charging current being provided to the downstream device. In some embodiments, the subsequent charge current indicator received at the accessory from the downstream device may include a value representing an updated amount of current being requested by the downstream device, or the subsequent charge current indicator may represent an updated charge level of the battery of the downstream device. At block  702 , the accessory receives a subsequent charge current indicator from the downstream device. In one embodiment, the downstream device may send the subsequent charge current indicator automatically as the battery of the downstream device charges up to a certain level, or as a predetermined length of charging time has elapsed. In another embodiment, the downstream device may send the subsequent charge current indicator in response to the accessory polling the downstream device for the subsequent charge current indicator. In some embodiments, the accessory may poll the downstream device for the subsequent charge current indicator by sending an ID request to the downstream device at a predetermined time interval 
     Upon receiving the subsequent charge current indicator, at block  704 , the accessory determines if the accessory is capable of adjusting, on its own, the charging current provided to the downstream device. For example, if the accessory includes current control circuitry that can control how much charging current is provided to the downstream device, the accessory may determine that it is capable of adjust the charging current provided to the downstream device. In this case, the process continues at block  606  where the accessory adjusts the charging current that is provided to the downstream device according to the subsequent charge current indicator received from the downstream device. 
     If the accessory lacks current control circuitry, the accessory may determine that it cannot adjust, on its own, the charging current provide to the downstream device. In this case, then at block  708 , the accessory may send a command that includes an updated charge current indicator to the upstream device to request the charging source to adjust the amount of current being provided to the accessory. According to some embodiments, the updated charge current indicator being sent to the upstream device may be based on the subsequent charge current indicator received from the downstream device. For example, in one embodiment, the updated charge current indicator may have a value that is the same as the subsequent charge current indicator. In another embodiment, the updated charge current indicator may have a value that is greater than the subsequent charge current indicator received from the downstream device. For example, the updated charge current indicator may take into account the amount of current required to operate the accessory. In one embodiment, the updated current indicator being sent to the upstream device may be a sum of a value representing the amount of current required to operate the accessory and the subsequent charge current indicator sent from the downstream device. 
       FIG. 8A-B  illustrate a flow chart  800  for charging multiple host devices (e.g., two host devices) through an accessory according to some embodiments. Referring to  FIG. 8A , at block  802 , the accessory may receive an ID request from an upstream device coupled to the accessory. The upstream device can be a charging source or another accessory. At block  804 , in response to receiving the ID request from the upstream device, the accessory may sends an ID response to the upstream device. The ID response may include ID information identifying the accessory and may also include a charge current indicator. The upstream device may authenticate the accessory and provide a charging current to the accessory based on the charge current indicator in the ID response. At block  806 , the accessory may receive an input power signal from the upstream device. In one embodiment, the input power signal may be the presence of a voltage or a current detected on a power pin of the accessory. In another embodiment, the input power signal may be a change in a voltage level or a current on a power pin of the accessory, for example, an increase from a nominal voltage to a supply voltage on an input power pin, or an increase from a limited current to the charging current being received on an input power pin. 
     Upon detecting the input power signal from the upstream device, the accessory may provide a limited current to the downstream devices (e.g., two host devices) that are coupled downstream to the accessory. Each downstream device can be a host device or another accessory. It should be understood that in other embodiments, more than two downstream devices can be coupled to the accessory. The limited current provided to each downstream device enables each downstream device to send identification (ID) information to the accessory. Thus, in some embodiments, even when if the battery of a downstream device is dead (i.e. the battery is completely drained, or the battery is drained to the extent that the circuitry of the downstream device responsible for sending the ID information cannot properly operate when using the battery as a power source), that downstream device can still be authenticated by the accessory. 
     At block  808 , the accessory may send an identification (ID) request to the first downstream device to request the first downstream device to send ID information identifying the first downstream device to the accessory. At block  810 , the accessory may receive an ID response that includes ID information identifying the first downstream device. The ID response may also include a charge current indicator from the first downstream device. The charge current indicator can be used by the accessory to determine the amount of charging current to provide to the first downstream device upon authenticating the first downstream device. 
     At block  812 , the accessory may send an identification (ID) request to the second downstream device to request the second downstream device to send ID information identifying the second downstream device to the accessory. At block  814 , the accessory may receive an ID response that includes ID information identifying the second downstream device. The ID response may also include a charge current indicator from the second downstream device. The charge current indicator can be used by the accessory to determine the amount of charging current to provide to the second downstream device upon authenticating the second downstream device. 
     Referring now to  FIG. 8B , if the downstream devices are authenticated, at block  816 , the accessory determines if the current received from the upstream device is sufficient to charge both downstream devices concurrently at the same time in a parallel manner. For example, the accessory may determine that the current received from the upstream device is sufficient, if the current received from the upstream device is greater than or equal to the sum of the current being requested from both downstream devices, or if the current received from the upstream device is greater than the sum of the minimum current requirement to charge the battery of each downstream device according to the specification of the battery and/or downstream device. If the accessory determines that the current received from the upstream device is sufficient, at block  818 , the accessory may distribute the current from upstream device into a charging current for the first downstream device and a charging current for the second downstream device. In some embodiments, the respective charging current provided to each downstream device can be proportional to the respective charge current indicators of the downstream devices. In some embodiments, the accessory may receive a subsequent charge current indicator from at least one of the downstream devices. In response, the accessory may adjust and redistribute the current from the upstream device to the downstream devices based on the subsequent charge current indicator. 
     If the accessory determines that the current received from the upstream device is insufficient to charge both downstream devices concurrently, the accessory may provide only one charging current to one downstream device to charge the downstream devices one at a time in a serial manner. At block  820 , the accessory may provide a charging current to the first downstream device while the power path between the upstream device and the second downstream device is disabled. Then at a later time, at block  822 , the accessory may provide a charging current to the second downstream device while the power path between the upstream device and the first downstream device is disabled. The accessory may perform this change, for example, when the battery of the first downstream device is charged to a certain level or is fully charged as indicated by a subsequent charge current indicator from the first downstream device, or when the battery of the first downstream device have been charging for a predetermined amount of time. Similarly, the accessory may switch from proving a charging current to the second downstream device back to providing a charging current to the first downstream device. The process may continue back to block  820  (as indicated by the dotted arrow) and be repeated until both downstream devices are fully charged. Switching the charging current back and forth between the two downstream devices before one of the downstream devices is fully charged may allow both downstream devices to have some charge in their respective batteries such that both downstream devices can be turned on sooner (e.g., to exchange data between the two downstream devices) than if the accessory waits until one downstream device is fully charged before performing the switch. 
     It should be understood that although the flow charts and methods of  FIGS. 7-8  have been described with reference to a host device and a charging source, similar steps and operations can be performed by an accessory that is coupled between an upstream device that may be another accessory and a downstream device that may also be another accessory. 
       FIG. 9  illustrates a simplified perspective view of one embodiment of a plug connector  1000  that can be used to implement some of the connectors described above. As shown in  FIG. 9 , plug connector  1000  includes a body  1003  and a tab portion  1004  that extends longitudinally away from body  1003  in a direction parallel to the length of the connector. Tab portion  1004  is sized to be inserted into a corresponding receptacle connector during a mating event. Tab portion  1004  includes a first contact region  1006   a  formed on a first major surface  1004   a  and a second contact region  1006   b  formed at a second major surface  1004   b  opposite of surface  1004   a . Surfaces  1004   a  and  1004   b  extend from a distal tip of tab portion  1004  to a spine  1009 . When tab portion  1004  is inserted into a corresponding host receptacle connector, spine  1009  abuts the housing of the host receptacle connector or the host device. Tab portion  1004  also includes first and second opposing side surfaces  1004   c  and  1004   d  that extend between the first and second major surfaces  1004   a  and  1004   b . In one particular embodiment, tab portion  1004  is 6.6 mm wide, 1.5 mm thick and has an insertion depth (the distance from the tip of tab portion  1004  to spine  1009 ) of 7.9 mm. 
     The structure and shape of tab portion  1004  is defined by a ground ring  1005  that can be made from stainless steel or another hard conductive material. Plug connector  1000  includes retention features  1002   a  and  1002   b  formed as curved pockets in the sides of ground ring  1005  that can also be used as ground contacts. Body  1003  is shown in  FIG. 9  in transparent form (via dotted lines) so that certain components inside body  1003  are visible. As shown, within body  1003  is a printed circuit board (PCB)  1007  that extends into ground ring  1005  between contact regions  1006   a  and  1006   b  towards the distal tip of plug connector  1000 . One or more integrated circuits (ICs), such as Application Specific Integrated Circuit (ASIC) chips  1008   a  and  1008   b , can be coupled to PCB  1007  to provide information about the device associated with connector  1000  and/or to perform specific functions, such as authentication, identification, contact configuration, current or power regulation, and/or signal and/or power conversion. 
     Bonding pads  1010  can also be formed within body  1003  near the end of PCB  1007 . Each bonding pad can be connected to a contact or contact pair within contact regions  1006   a  and  1006   b . Wires (not shown) can then be soldered to the bonding pads to provide an electrical connection from the contacts to circuitry within the device associated with connector  1000 . In some embodiments, however, bonding pads are not necessary and instead all electrical connections between the contacts and components of plug connector  1000  and other circuitry within the device associated with connector  1000  are made through traces on a PCB that the circuitry is coupled to and/or by interconnects between multiple PCBs within the device associated with connector  1000 . 
     As shown in  FIG. 9 , up to eight external contacts  1006 ( 1 ) . . .  1006 ( 8 ) can be spaced apart along a single row in contact region  1006   a . A similar set of eight contacts (not shown) can be spaced apart along a single row in contact region  1006   b . The two rows of contacts are directly opposite each other and each contact in contact region  1006   a  is electrically connected to a corresponding contact in contact region  1006   b  on the opposite side of the connector. Contacts  1006 ( 1 ) . . .  1006 ( 8 ) can be used to carry a wide variety of signals including digital signals and analog signals as well as power and ground. When plug connector  1000  is properly engaged with a receptacle connector, each of contacts  1006 ( 1 )- 1006 ( 8 ) is in electrical connection with a corresponding contact of the receptacle connector. 
       FIG. 10A  illustrates a simplified perspective view of one embodiment of a receptacle connector  1040  that plug connector  1000  can be coupled with. Receptacle connector  1040  includes a housing  1042  that defines a cavity  1047  and houses up to eight contacts  1046 ( 1 )- 1046 ( 8 ) within cavity  1047 . Housing  1042  can be integrated into a housing of a host device. In operation, a connector plug, such as plug connector  1000  can be inserted into cavity  1047  to electrically couple the contacts  1006 ( 1 )- 1006 ( 8 ) to respective contacts  1046 ( 1 )- 1046 ( 8 ). Each of the receptacle contacts  1046 ( 1 )- 1046 ( 8 ) electrically connects its respective plug contact to circuitry associated with the electrical device (e.g., a host device) in which receptacle connector  1040  is housed. Note that receptacle connector  1040  includes contacts on a single side so it can be made thinner. In other embodiments, receptacle connector  1040  may have contacts on each side while plug connector  1000  may only have contacts on a single side. 
       FIG. 10B  illustrates a planar cross-section view of receptacle connector  1040 . As shown in  FIG. 10B , contacts  1046 ( 1 )- 1046 ( 8 ) in receptacle connector  1040  are spaced apart in a single row. The contacts are positioned within a cavity  1047  that is defined by a housing  1042 . Receptacle connector  1040  also includes side retention mechanisms  1046   a  and  1046   b  (not shown) that engage with retention features  1002   a  and  1002   b  in plug connector  1000  to secure plug connector  1000  within cavity  1047  once the connectors are mated. Receptacle connector  1040  also includes two contacts  1048 ( 1 ) and  1048 ( 2 ) that are positioned slightly behind the row of signal contacts and can be used to detect when plug connector  1000  is inserted within cavity  1047  and detect when plug connector  1000  exits cavity  1047  when the connectors are disengaged from each other. 
     When tab portion  1004  of plug connector  1000  is fully inserted within cavity  1047  of receptacle connector  1040  during a mating event, each of contacts  1006 ( 1 ) . . .  1006 ( 8 ) from contact region  1006   a  or contacts from  1006   b  are physically and electrically coupled to one of contacts  1046 ( 1 ) . . .  1046 ( 8 ) depending on the insertion orientation of plug connector  1000  with respect to receptacle connector  1040 . Thus, contact  1046 ( 1 ) will be physically connected to either contact  1006 ( 1 ) or  1006 ( 8 ) depending on the insertion orientation; data contacts  1046 ( 2 ) and  1046 ( 3 ) will connect with either data contacts  1006 ( 2 ) and  1006 ( 3 ) or with data contacts  1006 ( 7 ) and  1006 ( 6 ) depending on the insertion orientation, etc. 
       FIG. 11A  illustrates one particular implementation of a pin-out  1101  for plug connector  1000  (or a pin-out for a compatible receptacle connector  1040 ), according to one embodiment of the invention. On one side of plug connector  1000  for contact region  1006   a , pin-out  1101  shown in  FIG. 11A  includes two host power contacts  1006 ( 4 ) and  1006 ( 5 ) that are electrically coupled together to function as a single contact dedicated to carrying power; an accessory ID contact  1006 ( 8 ); an accessory power contact  1006 ( 1 ); and four data contacts  1006 ( 2 ),  1006 ( 3 ),  1006 ( 6 ) and  1006 ( 7 ). Host power contacts  1006 ( 4 ) and  1006 ( 5 ) can be sized to handle any reasonable power requirement for a host device, and for example, can be designed to carry between 3-20 Volts from an accessory to charge a host device connected to plug connector  1000 . Host power contacts  1006 ( 4 ) and  1006 ( 5 ) are positioned in the center of contact regions  1006   a  and  1006   b  to improve signal integrity by keeping power as far away as possible from the sides of ground ring  1005 . 
     Accessory power contact  1006 ( 1 ) can be used for an accessory power signal that provides power from the host to an accessory. The accessory power signal is typically a lower voltage signal than the power in signal received over host power contacts  1006 ( 4 ) and  1006 ( 5 ), for example, 3.3 Volts as compared to 5 Volts or higher. The accessory ID contact  1006 ( 8 ) provides a communication channel that enables a host device to authenticate an accessory and enables an accessory to communicate information to the host device about the accessory&#39;s capabilities. 
     Data contacts  1006 ( 2 ),  1006 ( 3 ),  1006 ( 6 ) and  1006 ( 7 ) can be used for data communication between the host device and accessory using one or more communication protocols. Data contacts  1006 ( 2 ) and  1006 ( 3 ) are positioned adjacent to and on one side of the host power contacts  1006 ( 4 ) and  1006 ( 5 ), while data contacts  1006 ( 6 ) and  1006 ( 7 ) are positioned adjacent to but on the other side of the host power contacts  1006 ( 4 ) and  1006 ( 5 ). The accessory power contact  1006 ( 1 ) and accessory ID contact  1006 ( 8 ) are positioned at each end of the connector. The data contacts can be high speed data contacts that operate at rate that is two or three orders of magnitude faster than any signals sent over the accessory ID contact  1006 ( 8 ) which causes the accessory ID signal to appear essentially as a DC signal to the high speed data lines. Thus, positioning the data contacts  1006 ( 2 ) and  1006 ( 3 ) between accessory power contact  1006 ( 1 ) and host power contact  1006 ( 4 ), and positioning the data contacts  1006 ( 6 ) and  1006 ( 7 ) between host power contact  1006 ( 5 ) and accessory ID contact  1006 ( 8 ), improve signal integrity by sandwiching the data signals between contacts designated for DC signals or essentially DC signals 
       FIG. 11B  illustrates another particular implementation of a pin-out  1151  for plug connector  1000  (or a pin-out for a compatible receptacle connector  1040 ) according to another embodiment of the invention. Similar to pin-out  1101 , the plug connector having pin-out  1151  is a reversible connector. In other words, based on the orientation in which the plug connector is mated with a corresponding host connector of a host device, either the contacts on the contact region  1006   a  or  1006   b  are in physical and electrical contact with the contacts in the corresponding host connector of the host device. As illustrated in  FIG. 11B , there are eight contacts arranged within contact region  1006   a  and eight contacts arranged within contact region  1006   b.    
     Pin-out  1151  shown in  FIG. 11B  includes two contacts  1006 ( 1 ) and  1006 ( 12 ) that can function as accessory ID contacts to carry the adapter identification signals between adapter  40  and the host device. Contacts  1006 ( 1 ) and  1006 ( 12 ) are electrically connected to each other. The pin-out shown in  FIG. 11B  can have four pairs of data contacts: (a)  1006 ( 2 ) and  1006 ( 3 ); (b)  1006 ( 6 ) and  1006 ( 7 ); (c)  1006 ( 10 ) and  1006  ( 12 ); and (d)  1006 ( 14 ) and  1006 ( 15 ). In this particular embodiment, opposing data contacts, e.g.,  1006 ( 2 ) and  1006 ( 10 ), are electrically connected to each other. Pin-out  1151  further includes host power contacts  1006 ( 4 ) or  1006 ( 13 ) that may be electrically connected to each other. Host power contacts  1006 ( 4 ) or  1006 ( 13 ) carry power to the host device that is mated with plug connector  1000 . For example, plug connector  1000  may be part of a power supply system designed to provide power to the host device. In this instance, either host power contact  1006 ( 4 ) or  1006 ( 13 ) may carry power from the power supply to the host device, e.g., to charge a battery in the host device. 
     Pin-out  1151  of  FIG. 11B  may further include accessory power contacts  1006 ( 5 ) and  1006 ( 16 ) that may be electrically connected to each other. Accessory power contacts carry power from the host device to a connected accessory. For example, in some instances, an accessory connected to the host device may not be self-powered and may derive its power from the host device. In this instance, the host device can supply power to the accessory over either of the accessory contacts, depending on the orientation of plug connector  1000 . Pin-out  1151  of  FIG. 11B  may further include two ground contacts  1006 ( 8 ) and  1006 ( 9 ) electrically connected to each other. The ground contacts provide a ground path for plug connector  1000 . 
     Circuits, logic modules, processors, and/or other components can be described herein as being “configured” to perform various operations. Those skilled in the art will recognize that, depending on implementation, such configuration can be accomplished through design, setup, interconnection, and/or programming of the particular components and that, again depending on implementation, a configured component might or might not be reconfigurable for a different operation. For example, a programmable processor can be configured by providing suitable executable code; a dedicated logic circuit can be configured by suitably connecting logic gates and other circuit elements; and so on. 
     While the embodiments described above can make reference to specific hardware and software components, those skilled in the art will appreciate that different combinations of hardware and/or software components can also be used and that particular operations described as being implemented in hardware might also be implemented in software or vice versa. 
     Computer programs incorporating various features of the present invention can be encoded on various non-transitory computer readable storage media; suitable media include magnetic disk or tape, optical storage media, such as compact disk (CD) or DVD (digital versatile disk), flash memory, and the like. Computer readable storage media encoded with the program code can be packaged with a compatible device or provided separately from other devices. In addition program code can be encoded and transmitted via wired optical, and/or wireless networks conforming to a variety of protocols, including the Internet, thereby allowing distribution, e.g., via Internet download. 
     Thus, although the invention has been described with respect to specific embodiments, it will be appreciated that the invention is intended to cover all modifications and equivalents within the scope of the following claims.

Metadata:
Filing Date: 20120907
Publication Date: 20160119
Grant Date: 20160119
Priority Date: 20120907
Inventors: TERLIZZI JEFFREY J.
ANDREWS JONATHAN J.
KOSUT ALEXEI
HOLLABAUGH JAMES M.
RICH ZACHARY C.
FRITCHMAN DANIEL J.
Assignee: APPLE INC
CPC Classifications: [{"code": "H02J7/00045", "inventive": false, "first": false, "tree": "[]"}, {"code": "H01M10/4257", "inventive": false, "first": false, "tree": "[]"}, {"code": "H02J7/00036", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J7/00036", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J7/00045", "inventive": false, "first": false, "tree": "[]"}, {"code": "H02J7/0048", "inventive": false, "first": false, "tree": "[]"}, {"code": "H01M10/4257", "inventive": false, "first": false, "tree": "[]"}, {"code": "H02J7/00", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J7/00034", "inventive": false, "first": false, "tree": "[]"}, {"code": "H02J7/007", "inventive": true, "first": true, "tree": "[]"}, {"code": "H02J7/0004", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J2007/0001", "inventive": false, "first": false, "tree": "[]"}, {"code": "H02J7/007", "inventive": true, "first": true, "tree": "[]"}, {"code": "H02J2007/0098", "inventive": false, "first": false, "tree": "[]"}, {"code": "H02J7/00047", "inventive": true, "first": true, "tree": "[]"}, {"code": "H01M10/4257", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J7/00045", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J7/0047", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J7/00036", "inventive": true, "first": false, "tree": "[]"}, {"code": "H02J7/00034", "inventive": true, "first": false, "tree": "[]"}, {"code": "Y02E60/10", "inventive": false, "first": false, "tree": "[]"}, {"code": "H02J7/00047", "inventive": true, "first": true, "tree": "[]"}]
Family ID: 48141738