JP2013101520A - Peripheral device and its power supply control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a peripheral device and its power supply control method for enabling control of a power supply of the peripheral device without altering hardware on a host side.SOLUTION: An ExpressCard 10 performs data transmission to and from a host 20 provided with input/output interfaces 23, 24 performing data transmission by PCI Express, USB2.0. The ExpressCard 10 includes a control part 12 which transmits data and executes processing, input/output interfaces 13, 14 which mediate the data transmission by PCI Express, USB2.0, a USB bridge circuit 15 which determines data by USB2.0 output from the host 20, and outputs a control signal when the data is power supply control data and outputs the data to the input/output interface 14 when the data is not power supply control data, and a power supply control part 16 which controls supply of electric power to the control part 12 according to the control signal.

Description

  The present invention relates to a peripheral device and a power supply control method thereof.

  In recent years, techniques for reducing power consumption of peripheral devices connected to a host such as a personal computer have been disclosed.

  For example, Patent Document 1 discloses a television card having a power on / off function. The television card according to Patent Document 1 has a holding pin or cable to which a power on / off signal is transmitted from a host. When a power on / off signal is transmitted from the host, the power on / off signal is transmitted to the power on / off module via a holding pin or a cable. The power on / off module transmits or cuts off the power voltage to the television card module in response to the power on / off signal. Thereby, the power supply of the television card chip module can be controlled so that power is not consumed wastefully.

JP 2009-140465 A

  In Patent Document 1, a power on / off signal for controlling the power of a television card is transmitted from a host using a holding pin or a cable. In this method, it is necessary to make arrangements in advance on both the host side and the card side regarding the assignment (addition) of the power on / off signal at the connection interface and the shape of the connector for connecting the cable.

  As described above, the inventors of the present application have found the following problems. In the technique disclosed in Patent Document 1, an existing host cannot be used as it is for power control, and hardware must be changed on the host side. In other words, the television card according to Patent Document 1 is not compatible with an existing host computer. For this reason, the user cannot use the existing host computer as it is to use the television card. Since the change of the hardware on the host side involves time or cost, the convenience for the user cannot be improved.

  A peripheral device according to the present invention is a peripheral device that performs data transmission with a host that includes an input / output interface that performs data transmission according to a first standard and an input / output interface that performs data transmission according to a second standard. is there. The peripheral device transmits data to and from the host according to the first standard or the second standard, and executes a data processing, and the first standard between the control unit and the host A second input / output interface that mediates data transmission according to the second standard between the control unit and the host, and the second output from the host. If the data is power control data for the control unit, the first input / output interface, or the second input / output interface, a control signal is output, and the data is If the data is not control data, a data determination unit that outputs the data to the second input / output interface, and at least the control unit according to the control signal, A power supply control unit for controlling the power supply to any one output interface or the second output interface. With such a configuration, the power control data for controlling the power of the control unit, the first input / output interface, or the second input / output interface is an input / output interface that executes data transmission according to the second standard in the host. Is input to the peripheral device. Therefore, it is possible to provide a peripheral device that enables the host to control the power supply of the peripheral device without changing the hardware on the host side.

  A peripheral device power control method according to the present invention performs data transmission between an input / output interface that performs data transmission according to a first standard and a host that includes an input / output interface that performs data transmission according to a second standard. This is a power control method for peripheral devices. In this power control method, data transmission between the control unit and the host according to the first standard is mediated by a first input / output interface, and data transmission according to the second standard between the control unit and the host is performed first. Mediated by two I / O interfaces. Then, the data according to the second standard output from the host is determined, and the data is power control data for controlling the power of the control unit, the first input / output interface, or the second input / output interface. In some cases, a control signal is output, and when the data is not the power control data, the data is output to the second input / output interface. In accordance with the control signal, power supply to at least one of the control unit, the first input / output interface, and the second input / output interface is controlled. By such a method, the power control data for controlling the power of the control unit, the first input / output interface or the second input / output interface is the input / output interface for executing data transmission according to the second standard in the host. Is input to the peripheral device. Therefore, it is possible to provide a peripheral device power control method that enables the host to control the power supply of the peripheral device without changing the hardware on the host side.

  According to the present invention, it is possible to provide a peripheral device and a power supply control method thereof that can control the power supply of the peripheral device without changing the hardware on the host side.

FIG. 3 is a diagram of a configuration example of an ExpressCard and a host according to the first embodiment. FIG. 10 is a diagram of a configuration example of an ExpressCard and a host according to the second embodiment. FIG. 10 is a diagram of a configuration example of a USB peripheral and a USB host according to the third embodiment. FIG. 6 is a diagram of a configuration example of a portable HDD according to a fourth embodiment. FIG. 10 is a diagram of an example of the overall configuration of a DSC according to a fifth embodiment.

Embodiment 1
The ExpressCard according to the present embodiment includes a first input / output interface that executes data transmission according to the PCI (Peripheral Component Interconnect) Express standard and a second input that executes data transmission according to the USB (Universal Serial Bus) 2.0 standard. I / O interface is provided. A host connected to the ExpressCard and performing data transmission with the ExpressCard includes an input / output interface that performs data transmission according to the PCI Express standard and an input / output interface that performs data transmission according to the USB 2.0 standard. The USB bridge circuit determines data output from the host according to the USB 2.0 standard, and when the data is power control data, outputs a power control signal for controlling the power of the ExpressCard. The power supply control unit controls the power supply of the control unit, the first input / output interface, or the second input / output interface in the ExpressCard according to the power supply control signal. If the determined data is not power control data, the USB bridge circuit outputs the data to the second input / output interface. Therefore, the host can control the power supply of the ExpressCard as well as the data transmission between the ExpressCard and the host using the USB 2.0 input / output interface provided in advance. From the above, it is possible to control the power supply of ExpressCard without changing the hardware on the host side.

  Embodiment 1 of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram illustrating a configuration example of an ExpressCard and a host according to the present embodiment. The ExpressCard 10 and the host 20 are connected via an ExpressCard Connector (hereinafter referred to as a card connector) to transmit and receive information. Here, PCI Express and USB 2.0 standards are used for transmitting and receiving information.

  The ExpressCard 10 includes a card connector 11, a control unit 12, input / output interfaces 13 and 14, a USB bridge circuit 15, and a power supply control unit 16.

  The card connector 11 is a connection part between the ExpressCard 10 and the host 20. Specifically, data output from the host 20 is input to the input / output interface 13 or the USB bridge circuit 15 via the card connector 11. Note that data output by PCI Express is input to the input / output interface 13, and data output by USB 2.0 is input to the USB bridge circuit 15. Furthermore, the power output from the host via the card connector 11 is supplied to the USB bridge circuit 15 and the power control unit 16.

  The control unit 12 is a module that executes processing for transmitting / receiving information of the ExpressCard 10, various processing based on the transmitted / received information, and the like. The control unit 12 is activated by receiving power supply from the power supply control unit 16. Specifically, the control unit 12 is configured by an integrated circuit having a CPU (Central Processing Unit). Further, the control unit 12 performs processing based on an input / output interface 13, that is, an integrated circuit that performs processing based on the PCI Express standard, and input / output interface 14, that is, processing based on a standard such as USB 2.0 or UART (Universal Asynchronous Receiver Transmitter). Executes data transmission with the integrated circuit.

  The input / output interface 13 performs data transmission by PCI Express between the card connector 11 and the control unit 12. The input / output interface 14 performs data transmission by USB 2.0 or UART between the USB bridge circuit 15 and the control unit 12. The control unit 12 transmits / receives data to / from the control unit 21 of the host 20 via the input / output interface 13 based on the PCI Express standard. Further, the control unit 12 can transmit and receive data to and from the control unit 21 of the host 20 via the input / output interface 14 and the USB bridge circuit 15 based on a standard such as USB 2.0 or UART.

  The USB bridge circuit 15 (power control signal output unit) determines whether or not the data output from the host via USB 2.0 is specific data (power control data). When the USB bridge circuit 15 determines that the received data is power supply control data, the power supply control unit 16 causes the power supply control unit 16 to change the supply of power to the control unit 12, the input / output interface 13, or the input / output interface 14. Output a signal. If it is determined that the received data is not power control data, the USB bridge circuit 15 outputs the data to the input / output interface 14. The USB bridge circuit 15 is a characteristic part in the ExpressCard 10.

  Further, the USB bridge circuit 15 is provided separately from the control unit 12 and is supplied with power from the host 20 via the card connector 11. As a result, the USB bridge circuit 15 can operate by receiving power supply even when the control unit 12 is not operating (power is not supplied).

  The power supply control unit 16 receives power supply via the card connector 11, converts it to an appropriate voltage if necessary, and supplies power to the control unit 12, the input / output interface 13 and the input / output interface 14. Furthermore, the power supply control unit 16 can control power supply to the control unit 12, the input / output interface 13 or the input / output interface 14, and can switch on / off the supply of each power supply. The power supply control unit 16 is configured by a circuit such as a DC / DC converter or FET-SW, for example.

  The host 20 includes a control unit 21, a power supply 22, input / output interfaces 23 and 24, and a card connector 25. The host 20 is a personal computer to which the ExpressCard 10 is connected.

  The control unit 21 executes data transmission with the ExpressCard 10 and controls the ExpressCard 10. For example, the control unit 21 transmits / receives information to / from the control unit 12 in the ExpressCard 10. The control unit 21 is configured by a CPU or the like.

  The control unit 21 transmits / receives data related to information communication with the control unit 12 of the ExpressCard 10 via the PCI Express via the input / output interface 23. The control unit 21 transmits power supply control data to the ExpressCard 10 via the input / output interface 24 via USB 2.0. Alternatively, the control unit 21 can transmit / receive other data to / from the ExpressCard 10 via the input / output interface 24.

  The power source 22 serves as a power switch that supplies power to the ExpressCard 10, and is constituted by an internal power source in the host. The power supply 22 supplies power to the ExpressCard 10 via the card connector 25.

  The input / output interface 23 transmits data by PCI Express via the card connector 25. The input / output interface 24 transmits data by USB 2.0 via the card connector 25. The input / output interfaces 23 and 24 are connected to the control unit 21 through an internal bus and transmit data. In this way, the input / output interfaces 23 and 24 transmit data between the control unit 21 and the ExpressCard 10.

  The card connector 25 is a connection part between the ExpressCard 10 and the host 20. The power supplied from the power supply 22 and the data output from the input / output interfaces 23 and 24 are input to the ExpressCard 10 via the card connector 25. Further, the data output from the ExpressCard 10 is input via the card connector 25 to the input / output interface 23 if it is data by PCI Express, and to the input / output interface 24 if it is data by USB 2.0.

  Hereinafter, operations of the ExpressCard 10 and the host 20 will be described. The control unit 21 on the host side counts a period during which no data is transmitted by PCI Express between the host 20 and the ExpressCard 10. When the control unit 21 determines that there is no data transmission by PCI Express for a certain period (for example, 1 minute, 3 minutes, etc.), the control unit 21 connects the USB Card 2 to the ExpressCard 10 via the input / output interface 24 and the card connector 25. Transmit power control data (power-off command) by 0.

  The power control data is input to the USB bridge circuit 15 through the card connector 11. The USB bridge circuit 15 determines whether the received data is power control data. Since the received data is power control data that is a power-off command, the USB bridge circuit 15 stops power supply to the control unit 12, the input / output interface 13 or the input / output interface 14 to the power control unit 16. Outputs a power control signal. The power control unit 16 stops the supply of power to the control unit 12 or the input / output interface 13 in response to the power control signal. As described above, since the operation of the control unit 12 or the input / output interface 13 is stopped, power consumption can be prevented.

  Next, a case where data transmission by PCI Express is resumed will be described. By the user's operation, the control unit 21 on the host side executes processing for resuming communication by PCI Express between the host 20 and the ExpressCard 10. Here, the control unit 21 transmits a power-on command as power control data. The transmitted power control data is input to the USB bridge circuit 15 of the ExpressCard 10 via the input / output interface 24, the card connector 25, and the card connector 11 as described above.

  The USB bridge circuit 15 determines that the received data is power control data that is a power-on command, and outputs a power control signal to the power control unit 16 in accordance with the power control data. As a result, the USB bridge circuit 15 resumes the supply of power to the control unit 12 or the input / output interface 13. As a result, the control unit 12 or the input / output interface 13 resumes operation.

  Note that the USB bridge circuit 15 passes through or appropriately converts data other than the power supply control data, and transfers the data to the control unit 12 via the input / output interface 14. Therefore, when maintaining data transmission by USB 2.0, it is possible to stop only data transmission by PCI Express (power on / off control is performed only for the input / output interface 13).

  In the power control method described above, power control data is transmitted from the host 20 to the ExpressCard 10 by the input / output interface 24 (USB 2.0 input / output interface) provided in advance for data transmission / reception instead of the holding pin, cable, or the like. Can be output. Therefore, the host 20 can easily reduce the power of the ExpressCard 10, that is, the power of the module that uses the PCI Express, by simply adding software without changing the hardware. This is due to the fact that the ExpressCard 10 includes the USB bridge circuit 15 that determines whether or not the data output by the USB 2.0 is power control data and outputs a power control signal when the data is power control data. It is.

  Further, when receiving data other than the power supply control data, the USB bridge circuit 15 outputs the data to the control unit 12 via the input / output interface 14. For this reason, data transmission by USB 2.0 can also be executed between the ExpressCard 10 and the host 20. When data with a small capacity is transmitted between the ExpressCard 10 and the host 20, the power control data is output from the host 20 to the ExpressCard 10 in order to stop the PCI Express input / output interface (input / output interface 13) with high power consumption. To do. As a result, it is possible to control the power supply control unit 16 so that power is not supplied to the unused input / output interface 13. As described above, the ExpressCard 10 can be used efficiently and power consumption can be reduced.

  When there is no data transmission between the host 20 and the ExpressCard 10 for both PCI Express and USB 2.0, the host 20 outputs power control data and the control unit 12, the input / output interface 13 or the input / output interface 14. Do not supply power. Note that the host 20 may output power control data for controlling the power control unit 16 that does not supply power to at least the control unit 12 or the input / output interface 13. Since the control unit 12 and the input / output interface 13 consume a large amount of power during operation compared to the input / output interface 14, the power consumption of the ExpressCard 10 can be effectively reduced by not supplying power to either of them. can do.

  Alternatively, power control data for controlling the power control unit 16 so as not to supply power to all of the control unit 12 and the input / output interfaces 13 and 14 may be output. When power is not supplied to all of the control unit 12 and the input / output interfaces 13 and 14, the power consumption of the ExpressCard 10 can be further reduced.

  Furthermore, the host 20 can use existing hardware as it is. Therefore, the convenience for the user is greatly improved.

Embodiment 2
The second embodiment of the present invention will be described below with reference to the drawings. FIG. 2 is a diagram illustrating a configuration example of the ExpressCard 10 and the host 20 according to the present embodiment. Here, USB3.0 is used as a communication standard instead of PCI Express. In other words, the ExpressCard 10 and the host 20 transmit and receive information processed by the control unit 12 via USB 3.0, and control the power supply of the control unit 12, the input / output interface 17 or the input / output interface 14 via USB 2.0. In FIG. 2, the ExpressCard 10 includes an input / output interface 17 that transmits data using USB 3.0, instead of the input / output interface 13 that transmits data using PCI Express. The host 20 is provided with an input / output interface 26 for transmitting data by USB 3.0 instead of the input / output interface 23 for transmitting data by PCI Express. Other configurations of the ExpressCard 10 and the host 20 are the same as those in the first embodiment, and thus description thereof is omitted.

  Also in the second embodiment, as in the first embodiment, the control unit 21 of the host 20 outputs power control data (power-off command) when there is no data transmission by USB 3.0. The power supply control data is input to the USB bridge circuit 15 via the input / output interface 24, the card connector 25, and the card connector 11. The USB bridge circuit 15 outputs a power control signal for stopping the power supply to the control unit 12 or the input / output interface 17 according to the power control data. Thereby, the power consumed by the ExpressCard 10 can be reduced. Furthermore, when the control unit 21 outputs power control data (power-on command), power supply to the control unit 12 or the input / output interface 17 can be resumed. As described above, in the second embodiment, the power of the module using USB 3.0 is supplied to the host 20 by the USB 2.0 input / output interface provided for data transmission / reception in advance without using a holding pin or a cable. Control from. As a result, the power consumption of the ExpressCard 10 can be reduced.

  Compared to USB 3.0, the data transfer speed by USB 2.0 is slow, but the power consumption is small. Therefore, in FIG. 2, when data with a small capacity is transmitted between the ExpressCard 10 and the host 20, communication is performed using the USB 2.0 input / output interface, and power is not supplied to the USB 3.0 input / output interface. Power consumption can be reduced. The ExpressCard 10 according to the present embodiment can obtain the same effects as those of the first embodiment.

  Further, as in the first embodiment, the host 20 can be controlled not to supply power to any one of the control unit 12, the input / output interface 17 or the input / output interface 14, or not to supply power to all. It can also be controlled.

Embodiment 3
In this embodiment, a portable device that can be connected to a power source from a plurality of locations and has two input / output interfaces will be described. Similar to the first and second embodiments, this portable device controls power supply to the control unit on the portable device side based on the power supply control data output from the host side. Thereby, power consumption can be reduced also in a portable terminal in which power to the control unit is supplied from a place other than the host.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 3 shows a configuration example of the portable device (USB peripheral) and the USB host according to the present embodiment.

  The portable device 30 is a device having two input / output interfaces (signal lines), and each input / output interface is connected to the same host 40 (device). The communication standards of these two input / output interfaces are USB 3.0 and USB 2.0, respectively. The portable device 30 and the host 40 are connected by a cable corresponding to USB3.0.

  The portable device 30 includes a USB connector (USB connector) 31, a control unit 32, input / output interfaces 33 and 34, a USB bridge circuit 35, a power supply control unit 36, a battery 37, and a power supply selection unit 38.

  The USB connector 31 is a connection unit with the cable, and USB 3.0 data received from the host 40 is transmitted to the control unit 32 via the USB connector 31 and the input / output interface 33. The USB 2.0 data received from the host 40 is transmitted to the USB bridge circuit 35 via the USB connector 31. Further, the power (VBUS) supplied from the host 40 is supplied to the power selection unit 38.

  The control unit 32 controls the portable device 30 by executing data transmission with the control unit 41 of the host 40 by USB 3.0. The power supply control unit 36 converts the power supplied from the power supply selection unit 38 into an appropriate voltage if necessary, and supplies it to the control unit 32 or the input / output interfaces 33 and 34. Further, the power control unit 36 controls whether or not the power supplied from the power selection unit 38 is supplied to the control unit 32 or the input / output interfaces 33 and 34. Since the USB bridge circuit 35 executes the same processing as in the first and second embodiments, the description thereof is omitted.

  The battery 37 and the power source selection unit 38 are components of the mobile device 30 that are not in the first and second embodiments. The battery 37 is built in the portable device 30 and supplies power to the power selection unit 38.

  The power source selection unit 38 appropriately selects one of the power source supplied from the host 40 and the power source supplied from the battery 37 according to the situation, and supplies power to each module such as the USB bridge circuit 35 and the power source control unit 36. Supply. For example, when power is supplied from the host 40, the power selection unit 38 suppresses power consumption of the battery 37 by supplying the power. The power source selection unit 38 may charge the battery 37 by supplying at least a part of the power supplied from the host 40 to the battery 37.

  Since the configuration of the host 40 is the same as that of the second embodiment, description thereof is omitted.

  Hereinafter, operations of the mobile device 30 and the host 40 according to the present embodiment will be described. The control unit 41 of the host 40 transmits power control data (power-off command) via USB 2.0 and outputs it to the USB bridge circuit 35 when there is no data transmission by USB 3.0 for a predetermined period. The USB bridge circuit 35 generates a power control signal for stopping power supply to the control unit 32 or the input / output interface 33 according to the power control data, and outputs the power control signal to the power control unit 36. In response to the power control signal, the power control unit 36 stops supplying power to the control unit 32 or the input / output interface 33. As described above, the host 40 reduces the power of the portable device 30.

  The control unit 41 transmits power control data (power-on command) to the portable device 30 via the USB 2.0 when resuming data transmission by the USB 3.0 of the portable device 30 in accordance with an operation from the user. As a result, power supply to the control unit 32 or the input / output interface 33 is resumed, and the portable device 30 resumes data transmission using the USB 3.0 again. The details of the above operation are as described in the first and second embodiments.

  As described above, the control unit 41 of the host 40 can reduce the power consumption of the mobile device 30. In addition, the portable device 30 can obtain the same effects as the ExpressCard 10 according to the first and second embodiments.

  Although the mobile device 30 has two input / output interfaces, it may have a plurality of input / output interfaces. Furthermore, the portable device 30 may receive power from an external power source such as an AC adapter in addition to the built-in battery 37. In that case, the power source selection unit 38 selects an appropriate power source according to the situation from among three power sources: a built-in battery, an external power source using an AC adapter, and a power source from a USB cable.

  Further, as in the first and second embodiments, the host 40 can be controlled not to supply power to any of the control unit 32, the input / output interface 33, or the input / output interface 34, or supply power to all of them. It can also be controlled not to.

  As described above in the first to third embodiments, in a device connected via two or more plural input / output interfaces, one input / output interface is used to transfer data to another input / output interface. It is possible to control the power supply of the module used for the operation.

Embodiment 4
FIG. 4 shows an example of the overall configuration of a portable HDD (Hard Disk Drive), which is a USB peripheral compatible with USB 3.0, capable of suppressing power consumption. The USB peripheral 50 includes a USB connector 51, a battery 52, a power selection unit 53, a USB bridge circuit 54, a power control unit 55, a USB / SATA (Serial Advanced Technology Attachment) bridge circuit 60, an HDD 65, a ROM (Read Only Memory) 66, and the like. A RAM (Random Access Memory) 67 is provided. The USB peripheral 50 indicates the entire external portable HDD device connected to a host (not shown). The host and the USB peripheral 50 are connected by a USB connector 51 with a cable compatible with USB3.0. Details of this connection are as described above.

  The USB connector 51 is a connection portion with the cable, and data output from the host is input to the input / output interface 61 or the USB bridge circuit 54. The data output by USB 3.0 is input to the input / output interface 61, and the data output by USB 2.0 is input to the USB bridge circuit 54. Further, the power output from the host via the USB connector 51 is supplied to the power selection unit 53.

  The battery 52 is an internal power supply built in the USB peripheral 50. The battery 52 supplies power to the power selection unit 53.

  The power source selection unit 53 appropriately selects one of the power source supplied from the host and the power source supplied from the battery 52 according to the situation, and supplies power to the USB bridge circuit 54 and the power source control unit 55. Details of this selection are as described in the third embodiment.

  The USB bridge circuit 54 determines data output from the host via the USB 2.0, and when the received data is power control data, the power control unit 55 is connected to the input / output interfaces 61, 62, 63 or the control unit 64. A power control signal for changing the supply of power is output. If the received data is not power control data, the USB bridge circuit 54 outputs the data to the input / output interface 62.

  Further, the USB bridge circuit 54 is supplied with power from the power selection unit 53. As a result, the USB bridge circuit 54 can operate by receiving power supply even when the control unit 64 is not operating (power is not supplied).

  The power supply control unit 55 converts the power supplied from the power supply selection unit 53 into an appropriate voltage if necessary, and supplies it to the input / output interfaces 61, 62, 63 or the control unit 64. Further, the power control unit 55 controls the power supply to the input / output interfaces 61, 62, 63 or the control unit 64 based on the power control signal from the USB bridge circuit 54, and turns on / off each power supply. Can be switched.

  The USB / SATA bridge circuit 60 includes input / output interfaces 61, 62, 63 and a control unit 64. The USB / SATA bridge circuit 60 converts USB data received from the host side and SATA data received from the HDD side, and executes data transmission between the host and the HDD 65.

  The input / output interface 61 is connected to the control unit 64 through an internal bus, and executes data transmission by USB 3.0 between the USB connector 51 and the control unit 64.

  The input / output interface 61 is supplied with power from the power control unit 55. Therefore, when the power control unit 55 is supplying power, the input / output interface 61 performs data transmission between the USB connector 51 and the control unit 64. Thereby, the input / output interface 61 mediates data transmission between the control unit 64 and an external host. However, when the power control unit 55 is not supplying power, the input / output interface 61 does not execute data transmission between the USB connector 51 and the control unit 64. In this case, the control unit 64 does not execute information transmission / reception processing by USB 3.0.

  The input / output interface 62 performs data transmission by USB 2.0 between the USB bridge circuit 54 and the control unit 64. The input / output interface 63 performs data transmission using the HDD 65 and SATA. The input / output interfaces 62 and 63 are connected to the control unit 64 via an internal bus. That is, the input / output interface 62 executes data transmission between the USB bridge circuit 54 and the control unit 64, and the input / output interface 63 executes data transmission between the control unit 64 and the HDD 65.

  The input / output interfaces 62 and 63 are supplied with power by the power control unit 55. When the control unit 64 needs to reliably execute data transmission by USB 2.0, the input / output interface 62 is supplied with power.

  The control unit 64 includes a CPU and the like, and is a module that executes transmission / reception of information of the USB peripheral 50, information processing, and the like. For example, the control unit 64 outputs data input from the host via the USB connector 51 and the input / output interface 61 via the USB 3.0 to the HDD 65 via the input / output interface 63. Conversely, data from the HDD 65 can be output to the host. Alternatively, data can be appropriately transmitted and received from the host via the USB connector 51, the USB bridge circuit 54, and the input / output interface 62 by USB 2.0 from the host. Further, the control unit 64 transmits / receives data to / from the ROM 66 and RAM 67 as appropriate. The control unit 64 is activated by receiving power supply from the power supply control unit 55.

  The HDD 65 is a recording medium capable of recording data, and is connected to the control unit 64 via the input / output interface 63. The ROM 66 and the RAM 67 are also connected to the control unit 64, respectively.

  Hereinafter, the operation of the USB peripheral 50 will be described. In the host connected to the USB peripheral 50, as described above, when the period of no data transmission with the USB peripheral 50 by the USB 3.0 becomes a certain period or longer, the power control data by the USB 2.0 is sent to the USB peripheral 50. (Power off command) is transmitted. Alternatively, the host may transmit power control data (power-off command) based on USB 2.0 when a period in which no data is transmitted based on both USB 3.0 and USB 2.0 exceeds a certain period.

  The power control data is input to the USB bridge circuit 54 via the USB connector 51. Since the USB bridge circuit 54 receives the power-off command, the USB bridge circuit 54 outputs a power control signal for stopping the power supply to the input / output interfaces 61, 62, 63 or the control unit 64 to the power control unit 55. The power control unit 55 stops the supply of power to the input / output interfaces 61, 62, 63 or the control unit 64 in response to the power control signal. For example, when the supply of power to only the input / output interface 61 is stopped, the power consumption of the input / output interface 61 can be suppressed. Further, since the control unit 64 cannot transmit data with the host side via USB 3.0, the control unit 64 does not execute data transmission / reception processing with USB 3.0. Therefore, the power consumption of the control unit 64 can also be suppressed. As described above, the power consumption of the USB peripheral 50 can be suppressed.

  Next, a case where data transmission by USB 3.0 is resumed will be described. By a user operation, the host transmits a power-on command to the USB peripheral 50 as power control data. The transmitted power control data is output to the USB bridge circuit 54 as described above.

  The USB bridge circuit 54 outputs a power control signal to the power control unit 55 according to the received power control data. The power control unit 55 resumes the supply of power to the input / output interfaces 61, 62, 63 or the control unit 64 in response to the power control signal. Thereby, the control part 64 can transmit data by the host side and USB3.0.

  The USB bridge circuit 54 passes data other than the power supply control data and transfers it to the input / output interface 62.

  By the power supply control method described above, the same effect as that described in the first embodiment can be obtained. That is, the power supply control data is output to the USB peripheral 50 through the USB 2.0 input / output interface provided for data transmission / reception in advance, so the power of the USB peripheral 50 is easily changed without changing the hardware of the host. Can be reduced. This is an effect obtained by providing the USB peripheral circuit 54 with the USB peripheral circuit 50.

  USB 3.0 has a higher data transfer speed than USB 2.0. For this reason, the power consumption of the input / output interface 61 that is the USB 3.0 input / output interface is larger than the power consumption of the input / output interface 62 that is the USB 2.0 input / output interface. In the present embodiment, the power consumption of the USB peripheral 50 can be effectively suppressed by turning off the power of the input / output interface that consumes more power. Further, the control unit 64 can also suppress power consumption by not executing large-capacity data transmission using USB 3.0.

  Further, in the USB peripheral 50, even when the power of the USB 3.0 input / output interface 61 is turned off by the power control data, the power of the USB 2.0 input / output interface 62 remains on. Thereby, since the control part 64 can receive the information from a host, control of the control part 64 from the host side is possible. If data transmission by USB 2.0 is not required, the power of the input / output interfaces 61, 62, 63 and the control unit 64 can be turned off, and power consumption can be further reduced.

Embodiment 5
FIG. 5 shows an overall configuration example of a DSC (Digital still camera) corresponding to USB 3.0 as in the fourth embodiment. The DSC 70 includes a USB connector 71, a battery 72, a power selection unit 73, a USB bridge circuit 74, a power control unit 75, an input device 76, an ASIC (Application Specific Integrated Circuit) 80, an SD (Secure Digital) memory card 84, an LCD (Liquid Crystal Display) 85, a signal processing circuit 86, a ROM 87, a RAM 88, and a lens 89. The DSC 70 is connected to a host (not shown) by a USB connector 71 with a cable corresponding to USB3.0.

  Since the configuration and operation of the USB connector 71 to the power supply control unit 75 are substantially the same as those of the USB connector 51 to the power supply control unit 55 according to the fourth embodiment, description thereof will be omitted.

  The input device 76 is an input device such as a button that is provided in the DSC 70 and that can be operated by the user. The input device 76 outputs a control signal to the control unit 83 based on a user operation.

  The ASIC 80 includes input / output interfaces 81 and 82 and a control unit 83. Since the configuration and operation of the input / output interfaces 81 and 82 are substantially the same as those of the input / output interfaces 61 and 62 according to the fourth embodiment, description thereof is omitted.

  The control unit 83 is configured by a CPU or the like. The control unit 83 transmits data to and from the host connected to the DSC 70. Further, data is transmitted as appropriate between the SD memory card 84, the LCD 85, the signal processing circuit 86, the ROM 87, and the RAM 88.

  The signal processing circuit 86 outputs an electrical signal of a captured image captured by the lens 89 to the control unit 83. For example, the control unit 83 performs processing to display the captured image on the LCD 85.

  With the above configuration, the effect of suppressing the power consumption of the DSC 70 can be obtained as in the fourth embodiment. The method for controlling the power supply of the DSC 70 is the same as the method described in the fourth embodiment, and a description thereof will be omitted.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention. For example, the standard of data transmission is not limited to USB and PCI Express, but may be other standards. Even in such a case, it is desirable to use a data transfer rate of the input / output interface used for normal information communication that is faster than the data transfer rate of the input / output interface used for power supply control data. The reason is that in the case of normal large-capacity data transfer, the use efficiency of peripheral devices can be increased by using an input / output interface having a high data transfer rate. Furthermore, in the first to fifth embodiments, as described above, when small-capacity data transfer is being executed, the power consumption of the peripheral device can be further increased by controlling the power supply of the input / output interface that consumes more power. Can be suppressed.

  The inventions according to the first to fifth embodiments can be applied to devices, portable devices, and the like having two or more input / output interfaces. A representative example of the peripheral device to be applied is ExpressCard. Examples of portable devices include a portable HDD, DSC, USB memory, PMP (Portable Multimedia Player), portable BD / DVD writer, and the like that support USB 3.0.

  The operation of the peripheral device described in the above embodiment can be executed by the peripheral device as one of the control methods. For example, the peripheral device can be executed as a control program such as firmware. The control program may be recorded on a program recording medium so that it can be read by a peripheral device.

10 ExpressCard
11 Card connector 12 Control unit 13, 14, 17 Input / output interface 15 USB bridge circuit 16 Power supply control unit 20 Host 21 Control unit 22 Power supply 23, 24, 26 Input / output interface 25 Card connector 30 Portable device 31 USB connector 32 Control unit 33 34 Input / output interface 35 USB bridge circuit 36 Power supply control unit 37 Battery 38 Power supply selection unit 40 Host 41 Control unit 42 Power supply 43, 44 Input / output interface 45 USB connector 50 USB peripheral 51 USB connector 52 Battery 53 Power supply selection unit 54 USB bridge Circuit 55 Power supply control unit 60 USB / SATA bridge circuit 61, 62, 63 Input / output interface 64 Control unit 65 HDD
66 ROM
67 RAM
70 DSC
71 USB Connector 72 Battery 73 Power Supply Selection Unit 74 USB Bridge Circuit 75 Power Supply Control Unit 76 Input Device 80 ASIC
81, 82 I / O interface 83 Control unit 84 SD memory card 85 LCD
86 Signal processing circuit 87 ROM
88 RAM
89 lenses

Claims (5)

A peripheral device that performs data transmission with an input / output interface that performs data transmission according to a first standard and a host that includes an input / output interface that performs data transmission according to a second standard;
A controller that transmits data to or from the host according to the first standard or the second standard, and executes data processing;
A first input / output interface that mediates data transmission between the control unit and the host according to the first standard;
A second input / output interface that mediates data transmission between the control unit and the host according to the second standard;
When data according to the second standard output from the host is determined, and the data is power control data for controlling the power of the control unit, the first input / output interface, or the second input / output interface Outputs a control signal, and if the data is not the power control data, a data determination unit that outputs the data to the second input / output interface;
A power control unit that controls supply of power to at least the control unit, the first input / output interface, or the second input / output interface according to the control signal;
Peripheral equipment equipped with. The data transfer rate of the first input / output interface is faster than the data transfer rate of the second input / output interface, and the power consumption of the first input / output interface is the power consumption of the second input / output interface. Bigger than
The peripheral device according to claim 1. The first input / output interface and the second input / output interface are a PCI-Express interface or a USB interface.
The peripheral device according to claim 1 or 2. The peripheral device is an ExpressCard.
The peripheral device according to claim 1. A peripheral power supply control method for performing data transmission with a host having an input / output interface for performing data transmission according to a first standard and an input / output interface for performing data transmission according to a second standard,
Data transmission between the control unit and the host according to the first standard is mediated by a first input / output interface, and data transmission between the control unit and the host according to the second standard is performed as a second input / output interface. Mediated by
When data according to the second standard output from the host is determined, and the data is power control data for controlling the power of the control unit, the first input / output interface, or the second input / output interface Outputs a control signal, and if the data is not the power control data, outputs the data to the second input / output interface,
According to the control signal, to control power supply to at least the control unit, the first input / output interface, or the second input / output interface;
Peripheral power control method.

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