JP2015061332A - System and method for charger performance discrimination, mobile router and cradle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a USB charger performance discrimination system, achieving the discrimination of power supply capability of a charger and Ethernet (R) communication through a USB connector without a dedicated cradle connector.SOLUTION: The USB charger performance discrimination system includes a mobile router, having an Ethernet communication function, and a cradle connected to the mobile router through a first USB connector. The cradle includes: a USB charger detector, connectable through a second USB connector to the charger for charging the mobile router, for discriminating the power supply capability of the charger; and a USB-Ethernet converter, disposed on the cradle, capable of converting a signal conforming to the USB standard into a signal conforming to the Ethernet standard, and vise versa. A connection between the USB-Ethernet converter and the first USB connector becomes valid after the discrimination of the power supply capability by the USB charger detector, so that the mobile router is capable of Ethernet communication.

Description

  The present invention relates to a charger performance discrimination system, a charger performance discrimination method, a mobile router, and a cradle.

  A mobile router is known as a portable wireless LAN (Local Area Network) router device. FIG. 9 is an image diagram when mobile devices such as a smartphone, a mobile phone, and a portable game machine having a wireless LAN communication function perform data communication via the mobile router. The mobile router 101 connects the mobile device 100 to the Internet 103 through a wireless WAN (Wide Area Network) line such as WiMAX (Worldwide Interoperability for Microwave Access) (registered trademark) or LTE (Long Term Evolution) with the base station 102. Can be made. The mobile router 101 can be operated by a built-in battery. Unlike the conventional stationary wireless LAN router device, the WAN line and the power source are wireless. Therefore, it can be carried and used in various scenes.

  As shown in FIG. 10, some mobile routers can be connected to a dedicated cradle. By connecting the mobile router 200 to the cradle 201, communication and charging via a wired LAN are possible. As a result, for example, a PC (Personal Computer) 203 can be connected to the Internet via a wireless LAN when going out and a wired LAN at home. As a result, communication costs can be reduced.

  FIG. 11 is a diagram illustrating a configuration of the USB charging system 30 according to the related art. The charging system 30 includes a mobile router (main body) 31 and a cradle 32.

  The mobile router 31 includes a main control unit 300, a USB (Universal Serial Bus) charger detector 301, a dedicated cradle connector 302, a charge control unit 303, a battery 304, a power supply unit 305, a wireless communication unit 306, a storage unit 307, and a USB connector 308. It is comprised including.

  The main control unit 300 controls the mobile router 31 as a whole and performs various communication controls, routing operations necessary for Internet connection, and the like. The main control unit 300 uses a CPU (Central Processing Unit).

  When charging using a USB connector, it is preferable to follow the standard of Battery Charging Specification, which is the standard of USB. The USB charger detector 301 determines the state of D + / D− that is the data line of the USB device connected to the cradle 32, and determines the power supply capability of the device according to the Battery Charging Specification (for example, 500 mA for a PC or the like). The dedicated charger is 1.5A).

  The dedicated cradle connector 302 is a connector on the mobile router 31 side for connection with the cradle 32, and at least the signal line for Ethernet (registered trademark) communication and the power supply capability of the USB charger determined on the mobile router 31 side are cradle. It has a function of passing a signal line transmitted to the 32 side and a power supply line from the cradle 32 side.

  The charging control unit 303 performs control for charging the battery 304 with power supplied from the dedicated cradle connector 302 and control for supplying power to the power source unit 305.

  The power supply unit 305 has a function of supplying power to each functional block.

  The wireless communication unit 306 has a function of performing wireless WAN communication for connecting to the Internet line and wireless LAN communication with the connected external device.

  The storage unit 307 has a function of storing an OS (Operating System), settings necessary for operation, and the like.

  The USB connector 308 is provided separately from the dedicated cradle connector 302 so that the mobile router 31 can be charged alone.

  The cradle 32 includes a dedicated cradle connector 309, a USB connector 310, a wired LAN connector 311, and a USB-Ether converter 312.

  The dedicated cradle connector 309 is a cradle-side connector for connecting to the mobile router 31.

  The USB connector 310 is a connector for connecting a USB charger when the battery 304 is charged.

  The wired LAN connector 311 is a connector for communicating with a PC or the like connected to the outside via a wired LAN.

  The USB-Ethernet conversion unit 312 has a function of performing USB communication with the main control unit 300 of the mobile router 31 and converting a USB signal into an Ethernet signal.

  As described above, when the wired LAN function is installed in the cradle, a signal line for Ethernet communication is required in addition to the signal line for determining the power supply capability of the charger. That is, it is necessary to provide a dedicated cradle connector with an increased number of pins, leading to an increase in the size and cost of the main body.

  Here, if the mobile router and the cradle can be connected using a more general-purpose USB connector without using a dedicated cradle connector, there are advantages in convenience, design, and cost.

  Patent Document 1 discloses charge control of a radiation image detection system using a cradle. Specifically, the charging control unit of the cradle detects a battery voltage change ΔV1 accompanying a current change when the charging current is raised from 0 to Is at the start of constant current charging, and detects the initial target voltage V1. The constant current charging is performed with the new target voltage V2 corrected by adding the voltage change ΔV1 to the value of. For this reason, when shifting from constant current charging to constant voltage charging, the battery can be pulled up to a state as close as possible to the target voltage V1, and redundancy of constant voltage charging can be avoided and charging can be completed quickly. .

  Patent Document 2 discloses a power feeding device that can improve the reliability of a non-contact power feeding operation by confirming a power feeding object via non-contact communication. Specifically, when it is detected by the detection switch provided in the cradle that the mobile terminal is installed in the cradle, the non-contact power supply module (primary side) starts non-contact power supply to the mobile terminal. When the response signal is not received from the mobile terminal via the non-contact communication, the non-contact power feeding is stopped.

  In Patent Document 3, in a USB device equipped with a plurality of devices, the changeover switch is switched to allow the host to recognize the plurality of devices at the same time or to recognize the plurality of devices separately based on information set from the host. Is disclosed. Specifically, the USB device is provided with a changeover switch, the processor of the first device is provided with storage means for applying two outputs of the changeover switch and filled with operation selection information of a plurality of devices, A power supply output via a regulator and one output of a changeover switch are applied to the processor.

  Patent Document 4 discloses charging by setting a charging case containing a digital camera in a sealed state on a cradle. At this time, the waterproof case and the cradle are equipped with a contactless power supply module, the cradle side contactless power supply module generates magnetic lines of force by electromagnetic induction, the magnetic field lines are received by the case side contactless power supply, and the received magnetic lines of force are received by the digital camera. The battery is powered and charged.

  Patent Document 5 discloses a mobile router connected to a cradle through a USB connector. It is disclosed that the mobile router is charged by a power supply voltage supplied from the cradle to the mobile router according to the USB standard by mounting the mobile router on the cradle. Further, it is described that a USB / Ethernet conversion unit is provided in both the mobile router and the cradle, and communication is performed by mutually converting a signal conforming to the USB standard and a signal conforming to the Ethernet standard.

Re-specialized WO2012 / 005021 JP 2011-160547 A Japanese Patent Laying-Open No. 2005-165509 JP 2007-129791 A JP 2012-044477 A

  However, the related art charging system has the following problems. That is, since USB has a standard in wiring and operation, it is not possible to freely change the pin arrangement or add a signal line. Therefore, there is a problem that both the determination of the power supply capability of the USB charger and the Ethernet communication cannot be realized by using only the USB connector without providing a dedicated cradle connector. Patent Documents 1 to 5 do not disclose means for solving the problem.

  An object of the present invention is to provide a USB charger performance discrimination system, a USB charger performance discrimination method, a mobile router, and a cradle that solve the above-described problems.

  A USB charger performance determination system according to the present invention is a USB charger performance determination system including a mobile router having an Ethernet communication function, and a cradle connected to the mobile router via a first USB connector. Can be connected to a charger for charging the mobile router via the second USB connector, and is provided at least in the mobile router, and determines the power supply capability of the charger in accordance with the Battery Charging Specification. A detector and a USB-Ether converter that is provided in the cradle and can mutually convert a signal conforming to the USB standard and a signal conforming to the Ethernet standard, and after determining the power supply capability by the USB charger detector , USB-Ether converter and the first The connection with the USB connector 1 is valid, and the mobile router is ready for Ethernet communication.

  The USB charger performance determination method of the present invention is a USB charger performance determination system including a mobile router having an Ethernet communication function, and a cradle connected to the mobile router via a first USB connector. A USB-Ether converter that can be connected to a charger for charging the mobile router via the second USB connector and that can mutually convert a signal compliant with the USB standard and a signal compliant with the Ethernet standard; And determining the power supply capability of the charger in accordance with Battery Charging Specification, and after determining the power supply capability in the determination step, the connection between the USB-Ether converter and the first connector is made effective and mobile. Communication opening to enable router Ether communication A starting step.

The mobile router of the present invention can be connected to a cradle via a USB connector, has a Ethernet communication function, and determines a power supply capability in accordance with Battery Charging Specification of a charger connected to the cradle. A charger detector;
A load switch for passing a current from the charger to the mobile router according to a signal output after the determination of the power supply capability, and the cradle detects the current and the connection destination of the data line of the USB connector from the charger Ethernet (registered trademark) communication is started in response to switching to the mobile router.

  In the cradle of the present invention, a mobile router having an Ethernet (registered trademark) communication function is connected via a first USB connector, and a charger for charging the mobile router is connected via a second USB connector. A USB data line switch for switching the connection destination of the data line of the first USB connector from the second USB connector to the USB-Ether converter after determining the power supply capability of the charger in accordance with Battery Charging Specification in the mobile router It is characterized by having.

  According to the present invention, a USB charger performance determination system, a USB charger performance determination method, a mobile router that realizes determination of power supply capability of a charger and Ethernet (registered trademark) communication with a USB connector without providing a dedicated cradle connector. And cradle can be provided.

It is a figure which shows the structure of the USB charger performance discrimination | determination system 10 concerning 1st Embodiment. It is a flowchart explaining operation | movement of the USB charger performance discrimination | determination system 10 concerning 1st Embodiment. It is a figure which shows the structure of the USB charger performance discrimination system 40 concerning 2nd Embodiment. It is a figure which shows the structure of the electric current detection part 413 and the changeover switch control signal generation part 415 concerning 2nd Embodiment. It is a flowchart explaining operation | movement of the USB charger performance discrimination | determination system 40 concerning 2nd Embodiment. It is a flowchart explaining operation | movement of the USB charger performance discrimination | determination system 40 concerning 2nd Embodiment. It is a figure which shows the structure of the USB charger performance discrimination | determination system 60 concerning 3rd Embodiment. It is a flowchart explaining operation | movement of the USB charger performance discrimination | determination system 60 concerning 3rd Embodiment. It is an image figure at the time of performing data communication using a mobile router. It is an image figure at the time of performing data communication using the mobile router connected to the cradle. It is a figure which shows the structure of the USB charging system 30 in related technology.

[First Embodiment]
FIG. 1 is a diagram illustrating a configuration of a USB charger performance determination system 10 according to the first embodiment. The USB charger performance determination system 10 includes a mobile router 11 having an Ethernet (registered trademark) communication function, and a cradle 12 connected to the mobile router 11 via a first USB connector 13.

  The cradle 12 can be connected to a charger (not shown) for charging the mobile router 11 via the second USB connector 14.

  At least the mobile router 11 includes a USB charger detector 15 that determines the power supply capability of the charger in accordance with Battery Charging Specification (Revision 1.2, pages 6 to 35, December 7, 2010), which is a USB standard. Is provided. As discrimination results in accordance with this standard, there are Standard downstream port (SDP): Max 500 mA, Charging downstream port (CDP): Max 1.5A, and Dedicated charging port (DCP): Max 1.5A. The charging current to the mobile router 11 is determined based on the determined power supply capability. FIG. 1 illustrates an example in which a USB charger detector 15 is provided in a mobile router.

  In addition, the cradle 12 is provided with a USB-Ether converter 16 capable of mutually converting a signal compliant with the USB standard and a signal compliant with the Ethernet (registered trademark) standard.

  The operation of the USB charger performance determination system 10 according to the present embodiment will be described with reference to FIG.

  First, a charger is connected to the cradle 12 via the second USB connector 14 (step 21), and the mobile router 11 is connected via the first USB connector 13 (step 22). Subsequently, the USB charger detector 15 of the mobile router 11 determines the power supply capability of the charger (step 23). Thereafter, the connection between the USB-Ethernet converter 16 and the first USB connector 13 becomes valid (step 24), and the mobile router 11 becomes ready for Ethernet communication (step 25).

  In the USB charger performance determination system 10 according to the present embodiment, after the USB charger detector 15 determines the power supply capability of the charger, the connection between the USB-Ether converter 16 and the first connector 13 becomes effective, and the mobile router 11 is in a state where Ethernet communication is possible. This makes it possible to determine the power supply capability of the charger and Ethernet communication with the USB connector without providing a dedicated cradle connector.

  In the present embodiment, the operations in steps 21 and 22 may be reversed. That is, the charger may be connected after the mobile router is connected to the cradle.

[Second Embodiment]
FIG. 3 is a diagram illustrating a configuration of the USB charger performance determination system 40 according to the second embodiment. The USB charger performance determination system 40 includes a mobile router (main body) 41 and a cradle 42.

  The mobile router 41 includes a main control unit 400, a USB charger detector 401, a USB connector 402, a charge control unit 403, a battery 404, a power supply unit 405, a wireless communication unit 406, a storage unit 407, and a load switch 412.

  The main control unit 400 controls the entire mobile router and performs various communication controls, routing operations necessary for Internet connection, and the like. The main control unit 400 uses a CPU (Central Processing Unit).

  When charging using a USB connector, it is preferable to follow the standard of Battery Charging Specification, which is the standard of USB. The USB charger detector 401 has a function of determining the state of D + / D−, which is a data line of a USB device connected to the cradle, and determining the power supply capability of the device according to Battery Charging Specification (for example, a personal computer or the like). 500mA, dedicated charger 1.5A). This function can be realized by using a dedicated IC (Integrated Circuit) that is generally sold.

  The USB connector 402 is a connector on the mobile router side for connecting the mobile router 41 and the cradle 42, and has the same function as a general USB connector.

  The charging control unit 403 performs control for charging the battery 404 with power supplied from the USB connector 402 and control for supplying power to the power supply unit 405.

  The power supply unit 405 has a function of supplying power to each functional block.

  The wireless communication unit 406 has a function of performing wireless WAN communication for connecting to the Internet line and wireless LAN communication with an external device to be connected.

  The storage unit 407 has a function of storing the OS and settings necessary for operation.

  The load switch 412 has a function of controlling supply / non-supply of power from the USB connector 402 to the charge control unit 403 by turning on / off the power supply line. The load switch 412 transmits to the main control unit 400 that the device (cradle 41) is connected to the USB connector 402. The main control unit 400 detects a voltage applied via the load switch and starts a USB connection operation (USB connection with an Ether conversion unit 411 described later).

  The cradle 42 includes USB connectors 408 and 409, a wired LAN connector 410, a USB-Ether converter 411, a current detector 413, a USB data line changeover switch 414, and a changeover switch control signal generator 415.

  The USB connector 408 is a cradle-side connector for connecting to a mobile router.

  The USB connector 409 is a connector for connecting a USB charger when charging the battery 404.

  The wired LAN connector 410 is a connector for communicating with a PC or the like connected to the outside via a wired LAN.

  The USB-Ethernet conversion unit 411 has a function of performing USB communication with the main control unit 400 on the mobile router side and converting a USB signal into an Ethernet signal.

  The current detection unit 413 has a function of detecting that a current has flowed through the power supply line.

  The USB data line changeover switch 414 has a function of switching whether the USB data line (D + / D−) connected to the USB connector 408 is connected to the USB connector 409 on the cradle side or the USB-Ether conversion unit 411. .

  The changeover switch control signal generation unit 415 has a function of generating a control signal for switching the USB data line changeover switch 414 to which one.

  FIG. 4 is a diagram showing in detail the configuration of the current detection unit 413 and the changeover switch control signal generation unit 415.

  The current detection unit 413 includes a shunt resistor 501 and a comparator 503.

  The shunt resistor 501 is a low resistance for current detection, and is connected to a USB connector 408 for connecting to a mobile router.

  The comparator 503 has a function of comparing the voltage difference before and after the shunt resistor 501 and outputting the result.

  The changeover switch control signal generation unit 415 includes a delay unit 504 and a D-FF (D-Flip Flop) 505.

  The delay unit 504 is a delay circuit for determining the initial setting of the D-FF 505.

  The D-FF 505 outputs a control signal for the USB data line changeover switch 414 from the Q port.

  The operation of the USB charger performance discrimination system 40 in this embodiment will be described with reference to FIG.

  When the charger is connected to the cradle 41 (step 700), the changeover switch control signal generation unit 415 is initialized, and the USB data line changeover switch 414 is connected to the USB connector 408 by the USB data line (D + / D− ) Is switched to the USB connector 409 on the cradle 42 side (step 701).

  Subsequently, when the mobile router 41 is connected to the cradle 42 (step 702), the USB charger detector 401 of the mobile router 41 discriminates the power supply capability of the charger (step 703), and the discrimination result according to the Battery Charging Specification. Is output.

  The USB charger detector 401 transmits the power supply capability of the charger determined in step 703 to the charging control unit 403 (step 704). The charging control unit 403 determines a charging current for the battery 404 according to the determination result.

  After completion of the determination in step 703, the load switch 412 is turned on in response to the determination completion signal, and power can be supplied to the charging control unit 403 (step 705).

  When power supply to the charging control unit 403 is started, charging of the battery or power supply to the power supply unit 405 is started, and current starts to flow from the USB charger connected to the cradle 42 (step 706).

  The current detector 413 of the cradle 42 detects the current and sends a trigger signal to the changeover switch control signal generator 415 (step 707).

  In response to the current detection trigger, the selector switch control signal generator 415 switches the USB data line selector switch 414 to the USB-Ether converter 411 side, and then fixes the path (step 708).

  The main control unit 400 recognizes the USB-Ether conversion unit 411 and starts USB communication (step 709).

  When the recognition is completed normally, the Ethernet function is enabled (step 710).

  The operations of the current detection unit 413 and the changeover switch control signal generation unit 415 in steps 701, 707, and 708 of FIG. 5 will be described in detail with reference to FIG.

  First, the operation in step 701 will be described. When the charger is connected to the USB connector 409 (step 800), a voltage is applied to the power supply line, and a voltage is applied to the CLEAR bar of the D-FF 505 in FIG. Here, PRESET bar: L, CLEAR bar: H, and Q becomes H (both PRESET bar and CLEAR bar are Low Active) (step 801). At this time, when the control line is H, the USB data line changeover switch 414 is switched to the USB connector 409 side (step 802).

  The voltage from the USB connector 409 passes through the delay unit 504, and after a predetermined time, the PRESET bar also becomes H (step 803). The above is the operation of the current detection unit 413 and the changeover switch control signal generation unit 415 in Step 701.

  Subsequently, when the mobile router 41 and the cradle 42 are connected and current starts to flow (step 804), the comparator 503 monitors the potential difference on both sides of the shunt resistor 501, and when the potential on the + side becomes high, the comparator 503 The output changes from L to H (step 805). The rising edge is input to the CLK terminal of the D-FF 505. Since the D terminal is L in the D-FF 505 detecting the edge, Q outputs L (step 806). The above is the operation of the current detection unit 413 and the changeover switch control signal generation unit 415 in Step 707.

  Subsequently, the USB data line changeover switch 414 changes the control signal to L and switches the path to the opposite path, that is, the USB-Ether converter 411 side (step 807). The above is the operation of the current detection unit 413 and the changeover switch control signal generation unit 415 in Step 708. Thereafter, even if the output of the comparator 503 changes, Q remains L.

  In the USB charger performance determination system 40 according to the present embodiment, the cradle 42 switches USB data between the USB connector 409 to which the charger is connected and the USB-Ether converter 411 to connect the data line of the USB connector 408. A line changeover switch 414 is provided. Thereby, without providing a dedicated cradle connector, the mobile router and the cradle can be connected by the USB connector, and both the determination of the power supply capability of the USB charger connected to the cradle and the Ethernet communication can be achieved.

  In addition, it is possible to switch data lines by installing an IC for determining power supply capacity and a host device such as a CPU or a microcomputer in the cradle, but this is not realistic in view of cost and the like. On the other hand, when determining the power supply capability on the mobile router side, it is necessary to switch the USB data line detection switch mounted on the cradle when the determination of the power supply capability by the mobile router is completed. However, when a USB connector is used for connection between the mobile router and the cradle, the number of pins cannot be increased freely according to the standard. For this reason, the determination result cannot be transmitted from the mobile router to the cradle. That is, the control signal for switching the USB data line detection switch cannot be generated at an appropriate timing in the cradle.

  In the USB charger performance determination system 40 according to the present embodiment, the mobile router 41 has a load switch 412, and the cradle 42 has a current detection unit 413. That is, when the load switch 412 is turned on after the determination of the power supply capability, a current flows from the charger to the mobile router 41, and the USB data line changeover switch 414 is triggered by the current detection unit 413 detecting the current flow. The connection destination of the data line of the USB connector 408 is switched from the USB connector 409 to the USB-Ether converter 411. As a result, the USB data line selector switch can be controlled at an appropriate timing without mounting an IC for determining the power supply capability and a host device such as a CPU or a microcomputer in the cradle.

  Furthermore, in the USB charger performance determination system 40 according to the present embodiment, the USB charger detector 401 of the mobile router 41 determines the power supply capability of the charger, and the load switch 412 is charged according to the signal output after the determination is completed. It is possible to supply power to the control unit 403. Thereby, even when the main control unit of the mobile router is not operating, such as when the power of the mobile router is OFF, the power supply capability of the charger can be determined.

[Third Embodiment]
FIG. 7 is a diagram illustrating a configuration of a USB charger performance determination system 60 according to the third embodiment. The USB charger performance discrimination system 60 is different from the USB charger performance discrimination system 40 according to the second embodiment in the following points. First, the mobile router 61 does not have a load switch. The cradle 62 does not include a current detection unit, a USB data line changeover switch, and a changeover switch control signal generation unit, and includes a USB charger detector 612. The USB-Ether converter 611 includes a general purpose I / O port 613. Other configurations are the same as those of the USB charger performance determination system 40 according to the second embodiment.

  In many cases, an IC used for a USB-Ether converter has a general-purpose I / O port. In the present embodiment, this is utilized.

  The operation of the USB charger performance discrimination system 60 will be described with reference to FIG.

  First, when a charger is connected to the USB connector 609 of the cradle 62 (step 900), the USB charger detector 612 of the cradle 62 determines the power supply capability of the connected charger (step 901).

  Subsequently, the USB charger detector 612 can read the determination result in step 901 by the general-purpose I / O port 613 of the USB-Ether converter 611 (for example, the High voltage can supply 1.5 A and the Low voltage can supply 500 mA). Etc.) is transmitted to the general-purpose I / O port of the USB-Ether converter 611 (step 902).

  Thereafter, when the mobile router 61 and the cradle 62 are connected (step 903), the USB charger detector 601 of the mobile router 61 is connected to the USB-Ether converter 611, and it is detected that the power supply capacity of the charger is 500 mA. (If D + / D− is connected to an active device, it is determined to be 500 mA) (step 904).

  Subsequently, the main control unit 600 and the USB-Ethernet conversion unit 611 are connected, and when the connection is recognized normally, Ethernet communication of the mobile router 61 becomes possible (step 905).

  When Ethernet communication becomes possible, the main control unit 600 reads the state of the general-purpose I / O port 613 to which the power supply capability detection result of the charger of the USB-Ethernet conversion unit 611 is input via USB communication (step 906). .

  The main control unit 600 overwrites the charge control unit 603 with the result read in step 906 (a value corresponding to the power supply capability of the charger connected to the cradle 62) (step 907). As a result, the result (500 mA) detected by the USB charger detector 601 of the mobile router 61 becomes invalid as the power supply capability of the charger, and the result detected by the USB charger detector 612 of the cradle 62 becomes valid.

  Also in the USB charger performance determination system 60 in the present embodiment, it is possible to determine the power supply capability of the charger and Ethernet communication with the USB connector without using a dedicated cradle connector for connection between the cradle 61 and the mobile router 62. it can.

  In this embodiment, it is necessary that the main control unit of the mobile router is always operating.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to the said embodiment, Of course, unless it deviates from the meaning of this invention, another modification and an application example are included. .

  Part or all of the above embodiments can be described as follows, but is not limited to the following.

(Appendix 1)
A USB charger performance determination system including a mobile router having an Ethernet communication function, and a cradle connected to the mobile router via a first USB connector,
The cradle can be connected to a charger for charging the mobile router via a second USB connector;
A USB charger detector that is provided at least in the mobile router and that determines the power supply capability of the charger in accordance with Battery Charging Specification;
A USB-Ether converter provided in the cradle and capable of mutually converting a signal conforming to the USB standard and a signal conforming to the Ethernet standard;
After the determination of the power supply capability by the USB charger detector, the connection between the USB-Ether converter and the first USB connector becomes valid, and the mobile router becomes ready for the Ethernet communication. Vessel performance discrimination system.

(Appendix 2)
The USB of claim 1, wherein the cradle further includes a USB data line changeover switch that switches a connection destination of a data line of the first USB connector between the second USB connector and the USB-Ether converter. Charger performance discrimination system.

(Appendix 3)
The mobile router further includes a load switch for causing a current to flow from the charger to the mobile router via the power supply line of the first USB connector according to a signal output after the determination of the power supply capability.
The cradle further includes a current detection unit that detects that the current flows.
The USB data line changeover switch changes the connection destination of the data line of the first USB connector from the second USB connector to the USB-Ether conversion, triggered by the current detection unit detecting the start of the current flow. The USB charger performance discrimination system according to attachment 2, wherein the system is switched to a part.

(Appendix 4)
The cradle is further provided with a second USB charger detector,
A control unit is provided in the mobile router,
The USB-Ether conversion unit includes a general-purpose I / O port to which the determination result of the power supply capability by the second USB charger detector is written.
The USB charger performance determination system according to appendix 1, wherein the control unit reads out the determination result of the power supply capability written in the general-purpose I / O port by the Ethernet communication.

(Appendix 5)
In a USB charger performance determination system including a mobile router having an Ethernet communication function, and a cradle connected to the mobile router via a first USB connector,
The cradle can be connected to a charger for charging the mobile router via a second USB connector and can convert a signal conforming to the USB standard and a signal conforming to the Ethernet standard to each other. -Ether converter,
A determination step of determining the power supply capability of the charger in accordance with Battery Charging Specification;
A communication start step for enabling the connection between the USB-Ethernet converter and the first connector and enabling the Ethernet communication of the mobile router after determining the power supply capability in the determining step. USB charger performance discrimination method.

(Appendix 6)
The USB charging according to appendix 5, further comprising a switching step of switching the connection destination of the data line of the first USB connector between the second USB connector and the USB-Ether converter in the communication start step. Method for determining vessel performance.

(Appendix 7)
A control step of controlling current to flow from the charger to the mobile router via the power supply line of the first USB connector according to a signal output after the determination of the power supply capability;
A detection step of detecting that the current flows;
In the switching step, the connection destination of the data line of the first USB connector is switched from the second USB connector to the USB-Ether converter, triggered by the detection of the start of the current flow in the detection step. The USB charger performance discrimination method according to appendix 6.

(Appendix 8)
The USB-Ether converter has a general-purpose I / O port,
A second determination step of determining the power supply capability by the cradle;
The USB charger performance determination according to appendix 5, further comprising a reading step of reading out the determination result by the Ethernet communication from a general-purpose I / O port in which the determination result of the power supply capability in the second determination step is written Method.

(Appendix 9)
A mobile router that can be connected to a cradle via a USB connector and has an Ethernet communication function,
A USB charger detector for determining a power supply capability in accordance with Battery Charging Specification of a charger connected to the cradle;
A load switch that causes the current from the charger to flow to the mobile router according to a signal output after the determination of the power supply capability,
The mobile router is in a state in which the Ethernet communication is possible when the cradle detects the current and switches the connection destination of the data line of the USB connector from the charger to the mobile router.

(Appendix 10)
A mobile router having an Ethernet communication function is connected via the first USB connector,
A charger for charging the mobile router is connected via a second USB connector,
A USB data line for switching the connection destination of the data line of the first USB connector from the second USB connector to the USB-Ether converter after determining the power supply capability of the charger in accordance with Battery Charging Specification in the mobile router And a changeover switch.

(Appendix 11)
A current detection unit for detecting a current flowing from the charger to the mobile router via the power supply line of the first USB connector;
The USB data line changeover switch changes the connection destination of the data line of the first USB connector from the second USB connector to the USB-Ether conversion, triggered by the current detection unit detecting the start of the current flow. The cradle according to appendix 10, which is switched to a part.

10, 40, 60 USB charger performance discrimination system 11, 31, 41, 61, 101, 200 Mobile router 12, 32, 42, 62, 201 Cradle 13 First USB connector 14 Second USB connector 15, 301, 401, 601, 612 USB charger detector 16, 312, 411, 611 USB-Ether converter 30 Charging system 100 Mobile device 102, 204 Base station 103, 205 Internet 203 PC
300, 400, 600 Main control unit 302, 309 Dedicated cradle connector 303, 403, 603 Charge control unit 304, 404, 604 Battery 305, 405, 605 Power supply unit 306, 406, 606 Wireless communication unit 307, 407, 607 Storage unit 308, 310, 402, 408, 409, 602, 608, 609 USB connector 311, 410, 610 Wired LAN connector 412 Load switch 413 Current detection unit 414 USB data line changeover switch 415 Changeover switch control signal generation unit 501 Shunt resistance 503 Comparator 504 Delay unit 505 D-Flip Flop
613 General purpose I / O port

Claims (10)

A USB charger performance determination system including a mobile router having an Ethernet communication function, and a cradle connected to the mobile router via a first USB connector,
The cradle can be connected to a charger for charging the mobile router via a second USB connector;
A USB charger detector that is provided at least in the mobile router and that determines the power supply capability of the charger in accordance with Battery Charging Specification;
A USB-Ether converter provided in the cradle and capable of mutually converting a signal conforming to the USB standard and a signal conforming to the Ethernet standard;
After the determination of the power supply capability by the USB charger detector, the connection between the USB-Ether converter and the first USB connector becomes valid, and the mobile router becomes ready for the Ethernet communication. Vessel performance discrimination system.   The cradle further includes a USB data line changeover switch that switches a connection destination of a data line of the first USB connector between the second USB connector and the USB-Ether converter. USB charger performance discrimination system. The mobile router further includes a load switch for causing a current to flow from the charger to the mobile router via the power supply line of the first USB connector according to a signal output after the determination of the power supply capability.
The cradle further includes a current detection unit that detects that the current flows.
The USB data line changeover switch changes the connection destination of the data line of the first USB connector from the second USB connector to the USB-Ether conversion, triggered by the current detection unit detecting the start of the current flow. The USB charger performance determination system according to claim 2, wherein the system is switched to a unit. The cradle is further provided with a second USB charger detector,
A control unit is provided in the mobile router,
The USB-Ether conversion unit includes a general-purpose I / O port to which the determination result of the power supply capability by the second USB charger detector is written.
2. The USB charger performance determination system according to claim 1, wherein the control unit reads out the determination result of the power supply capability written in the general-purpose I / O port by the Ethernet communication. In a USB charger performance determination system including a mobile router having an Ethernet communication function, and a cradle connected to the mobile router via a first USB connector,
The cradle can be connected to a charger for charging the mobile router via a second USB connector and can convert a signal conforming to the USB standard and a signal conforming to the Ethernet standard to each other. -Ether converter,
A determination step of determining the power supply capability of the charger in accordance with Battery Charging Specification;
A communication start step for enabling the connection between the USB-Ethernet converter and the first connector and enabling the Ethernet communication of the mobile router after determining the power supply capability in the determining step. USB charger performance discrimination method.   6. The USB according to claim 5, further comprising a switching step of switching a connection destination of a data line of the first USB connector between the second USB connector and the USB-Ether converter in the communication start step. Charger performance discrimination method. A control step of controlling current to flow from the charger to the mobile router via the power supply line of the first USB connector according to a signal output after the determination of the power supply capability;
A detection step of detecting that the current flows;
In the switching step, the connection destination of the data line of the first USB connector is switched from the second USB connector to the USB-Ether converter, triggered by the detection of the start of the current flow in the detection step. The USB charger performance discrimination method according to claim 6. The USB-Ether converter has a general-purpose I / O port,
A second determination step of determining the power supply capability by the cradle;
The USB charger performance according to claim 5, further comprising: a reading step of reading out the determination result by the Ethernet communication from a general-purpose I / O port in which the determination result of the power supply capability in the second determination step is written. How to determine. A mobile router that can be connected to a cradle via a USB connector and has an Ethernet communication function,
A USB charger detector for determining a power supply capability in accordance with Battery Charging Specification of a charger connected to the cradle;
A load switch that causes the current from the charger to flow to the mobile router according to a signal output after the determination of the power supply capability,
The mobile router is in a state in which the Ethernet communication is possible when the cradle detects the current and switches the connection destination of the data line of the USB connector from the charger to the mobile router. A mobile router having an Ethernet communication function is connected via the first USB connector,
A charger for charging the mobile router is connected via a second USB connector,
A USB data line for switching the connection destination of the data line of the first USB connector from the second USB connector to the USB-Ether converter after determining the power supply capability of the charger in accordance with Battery Charging Specification in the mobile router And a changeover switch.

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