JP7465143B2 - Power receiving device, control method thereof, and program - Google Patents

Description

The present invention relates to a power receiving device, a control method thereof, and a program.

Recently, wired communication interfaces used in electronic devices such as digital cameras include those that can transmit power in parallel with data transfer, such as USB (Universal Serial Bus). The USB standard was established by the non-profit organization USB Implementers Forum, Inc. (USB-IF), which promotes the USB standard. USB-IF also certifies that electronic devices comply with the USB standard.

The USB-IF has established various USB-related standards, one of which is the USB-PD (USB-Power Delivery) standard. The USB-PD standard allows a power supply device such as a USB host controller or AC adapter to supply large amounts of power up to 100 W to a power receiving device connected via a USB cable. As the amount of power handled between connected devices increases, there is a growing demand for improved safety.

The USB-AUTH (USB-AUTHentication) standard has been established to enable authentication communication between connected devices to determine whether they can be trusted. According to the USB-AUTH standard, each electronic device stores a certificate issued by the USB-IF as electronic information within the device, and authentication is possible by exchanging the certificate between devices through communication encrypted by a specified process.

Patent Document 1 discloses technology related to a power supply device that performs USB-AUTH communication on a USB cable connecting devices as a safety control using authentication communication according to the USB-AUTH standard, and controls the power supply depending on the authentication result.

JP 2018-97643 A

The certificate required for authentication via USB-AUTH communication can be issued by the USB-IF even for electronic devices or USB cables that have not passed compliance testing to confirm that they conform to the USB standard. Therefore, even if an electronic device or USB cable is authenticated via USB-AUTH communication, it does not necessarily conform to the USB standard, but Patent Document 1 does not take this point into consideration.

Now consider the case where a power receiving device receives power from a power supply device that has been authenticated by USB-AUTH communication. In this case, the power supply device may not necessarily conform to the USB standard, so if power is controlled based solely on the results of authentication via USB-AUTH communication, there is a possibility that the power receiving device will receive a large amount of power from a power supply device that does not conform to the USB standard.

The present invention was made in consideration of these circumstances, and aims to provide a technology that further improves the safety of power reception by a power receiving device from a power supply device.

To solve the above problem, the present invention provides a power receiving device comprising: an interface capable of data communication and power reception based on a predetermined power supply standard; a control means for controlling the device to receive a first power from a power supply device via the interface; a first determination means for acquiring authentication information including identification information of the power supply device from the power supply device via the interface based on a predetermined authentication standard and determining whether the authentication information is genuine; and a second determination means for determining whether the power supply device has passed a conformance test for the predetermined power supply standard based on the identification information, wherein when it is determined that the authentication information is genuine and that the power supply device has passed the conformance test, the control means controls the device to receive a second power greater than the first power from the power supply device.

The present invention makes it possible to further improve the safety of power reception by a power receiving device from a power supply device.

Other features and advantages of the present invention will become apparent from the accompanying drawings and the following detailed description of the invention.

system configuration diagram. FIG. 2 is a block diagram showing the configuration of a power receiving device 200. FIG. 3 is a block diagram showing the configuration of a portable wireless device 300. 5 is a flowchart of power reception control according to the first embodiment. 10 is a flowchart of a modified example of power receiving control according to the first embodiment. FIG. 4 is a diagram showing an example of a USB compatibility list (compatibilities management information). 4B is a flowchart showing details of the second authentication process in S407 of FIG. 4A. 10 is a flowchart of a process for updating a USB compatibility list according to the second embodiment. 13 is a sequence chart of a process of updating a USB compatibility list according to the third embodiment. 13A is a flowchart of an XID accumulation process according to the third embodiment; FIG. 13B is a diagram showing an example of a USB compatibility list including an added XID; FIG. 11 is a diagram for explaining an example of sharing a USB compatibility list. 13 is a flowchart of power reception control according to the fourth embodiment. 13A and 13B are diagrams showing examples of display of information (messages) in power receiving control according to the fourth embodiment.

The following embodiments are described in detail with reference to the attached drawings. Note that the following embodiments do not limit the invention according to the claims. Although the embodiments describe multiple features, not all of these multiple features are necessarily essential to the invention, and multiple features may be combined in any manner. Furthermore, in the attached drawings, the same reference numbers are used for the same or similar configurations, and duplicate explanations are omitted.

[First embodiment]
System Configuration Fig. 1 is a system configuration diagram according to the first embodiment. In Fig. 1, reference numeral 200 denotes a power receiving device as an electronic device. In this embodiment, a digital camera is used as an example of the power receiving device, but the power receiving device of this embodiment is not limited to a digital camera and can be applied to any type of power receiving device.

210 is a connection unit that connects the power receiving device 200 to an external device, and in this embodiment, a USB TYPE-C connector is used as an example. The connection unit 210 (interface) is configured to enable data communication and power reception based on the USB-PD standard.

120 is a cable, and in this embodiment, a USB cable is used as an example. When an external device is connected to the connection unit 210 via the cable 120, the power receiving device 200 can receive power from the external device and perform data communication with the external device.

130 is a power supply device as an external device. Here, an AC adapter is used as an example, but power supply device 130 may be a mobile battery or other electronic device with a power source.

300 is a portable wireless device as an external device, and in this embodiment, a smartphone is used as an example. However, the portable wireless device 300 may be another electronic device such as a personal computer (PC).

350 is a wireless communication medium, which complies with a communication standard such as Wi-Fi (registered trademark) or Bluetooth (registered trademark). The portable wireless device 300 is connected to the power receiving device 200 via the wireless communication medium 360. This connection allows the portable wireless device 300 to view, for example, recorded images and live view images in the digital camera that is the power receiving device 200, and control camera shooting. 360 is a wireless communication medium, which complies with a communication standard such as 4G or 5G. The portable wireless device 300 can access the web via the wireless communication medium 370. In this embodiment, an example in which the power receiving device 200 and the portable wireless device 300 are connected via the wireless communication medium 360 will be described, but the communication between the power receiving device 200 and the portable wireless device 300 is not limited to wireless communication and may be wired communication.

150 is a cloud server as an external device. The portable wireless device 300 can access the cloud server 150 via a wireless communication medium 370. The cloud server 150 stores information (called a "USB compatibility list") that links the XID with the USB compatibility information. The XID is product-specific identification information that electronic devices and cables that support the USB standard (hereinafter collectively referred to as "USB products") have. Here, the fact that the XID is "product-specific" means that the XID is assigned to each model number of the USB product. Therefore, multiple USB products with the same model number have the same XID. The USB compatibility information is information that indicates whether the USB product has passed (or is currently being tested for) the compliance test of the USB standard. Passing the compliance test is proof that the product complies with the USB standard, and is therefore important in ensuring connection compatibility.

●Configuration of power receiving device 200 Fig. 2 is a block diagram showing the configuration of the power receiving device 200. In Fig. 2, the connection unit 210 is, for example, a USB Type-C connector as described in Fig. 1. Reference numeral 201 denotes a power receiving unit connected to a power supply terminal (for example, a VBUS terminal) of the connection unit 210, and controls the power supplied from the power supply device 130 shown in Fig. 1 via the cable 120. Reference numeral 202 denotes a battery such as a lithium ion battery. The power receiving unit 201 includes a DC/DC converter and a charging circuit, and is configured to charge the battery 202 using the power received via the connection unit 210.

203 is a power supply control unit including a DC/DC converter and the like, and supplies power to various circuits included in the power receiving device 200 using power from the power receiving unit 201 or the battery 202. 204 is a PD communication unit connected to a communication terminal (e.g., a CC terminal) of the connection unit 210, and executes data communication based on the USB-PD standard (a specified power supply standard) between the power supply device 130 and the IC built into the cable 120 shown in FIG. 1. The PD communication unit 204 also determines whether the connected power supply device 130 and cable 120 support the USB-PD standard. The power receiving device 200 performs negotiation communication based on a communication protocol defined in the USB-PD standard through the PD communication unit 204, and requests the power supply device 130 to supply the desired power.

205 is an authentication unit, which is, for example, composed of a security chip. The authentication unit 205 has a built-in non-volatile memory, and electronic information of the certificate issued by the USB-IF is stored in advance. The PD communication unit 204 receives electronic information including the encrypted certificate from each of the power supply device 130 and the cable 120 by communication defined in the USB-PD standard, and transmits it to the authentication unit 205. The authentication unit 205 performs authentication (first authentication) as to whether the connected power supply device 130 and the cable 120 are trusted by the USB-IF by decrypting the electronic information sent from the PD communication unit 204 by a predetermined process defined in the USB-AUTH standard (a predetermined authentication standard). In addition, the authentication unit 205 also obtains the XID of the power supply device 130 and the cable 120 by decrypting the electronic information of the power supply device 130 and the cable 120 sent from the PD communication unit 204.

206 is an imaging unit including an imaging lens that zooms and focuses on the subject image, and an imaging element that converts the subject image into electrical image information. The image information acquired by the imaging unit 206 undergoes image processing such as compression processing in the control unit 250, and is recorded on the recording medium 209.

207 is an operation unit consisting of buttons, a touch panel, etc., and is used by the user to operate the power receiving device 200. 208 is a display unit consisting of an LCD, etc., and is used to display the status of the digital camera, which is the power receiving device 200, and to display images. 209 is a recording medium such as a memory card or a hard disk.

211 is a non-volatile memory composed of a NOR flash memory, a NAND flash memory, or the like, and is used to store the control program and image data of the power receiving device 200. The non-volatile memory 211 may be in a removable form such as an SD card. Here, the non-volatile memory 211 is also used to store a USB compatibility list that links the XID and the USB compatibility information. For example, the USB compatibility list is stored in the non-volatile memory 211 in advance before the power receiving device 200 is shipped. Alternatively, the power receiving device 200 may obtain the USB compatibility list from the cloud server 150 via the mobile wireless device 300 according to an operation by the user and store it in the non-volatile memory 211. The power receiving device 200 can also update the USB compatibility list stored in the non-volatile memory 211. Control regarding the update of the USB compatibility list will be described later.

212 is a wireless unit that complies with Wi-Fi (registered trademark) or Bluetooth (registered trademark) and is used for data communication with an external device. The wireless unit 212 (an interface capable of data communication) is used for data communication with the portable wireless device 300 via the wireless communication medium 360, as described in FIG. 1.

250 is a control unit that controls the entire power receiving device 200. The control unit 250 includes, for example, a microprocessor and RAM, and controls the operation of the entire power receiving device 200 by loading a control program prestored in the non-volatile memory 211 into the RAM and executing it. The control program here refers to a program for executing various flowcharts in this embodiment, which will be described later. The control unit 250 is also configured to be able to determine that the power supply device 130 and the cable 120 are connected to the connection unit 210 via the power receiving unit 201 and the PD communication unit 204.

213 is a control block inside the control unit 250, and is an information update determination unit for updating the USB compatibility list that links the XID with USB compatibility information. For example, the information update determination unit 213 determines to update the USB compatibility list in response to the control unit 250 determining that the power supply device 130 and the cable 120 are connected to the connection unit 210. This is not limiting, and the information update determination unit 213 may determine to update the USB compatibility list as appropriate when it is possible to obtain the USB compatibility list from an external device. For example, the information update determination unit 213 may determine to update the USB compatibility list when it is determined by the wireless unit 212 that an external device has been connected, or when a predetermined user input is made using the operation unit 207.

214 is a control block inside the control unit 250, and is an information acquisition unit that controls to acquire the USB compatibility list from the connected external device by wired or wireless data communication when the information update determination unit 213 determines that the USB compatibility list should be updated. The information acquisition unit 214 acquires the USB compatibility list from the external device connected via the connection unit 210, for example, by using communication defined in the USB standard. As another example, the information acquisition unit 214 may acquire the USB compatibility list by connecting to the external device or the cloud server 150 by wireless communication using the wireless unit 212, or may acquire the USB compatibility list stored in the recording medium 209.

215 is a control block within the control unit 250, and is an information update unit that receives the USB compatibility list obtained from the information acquisition unit 214, determines whether to update the USB compatibility list already stored in the non-volatile memory 211, and performs the update process. The detailed processing of the information update unit 215 will be described later.

Configuration of the portable wireless device 300 Fig. 3 is a block diagram showing the configuration of the portable wireless device 300. Reference numeral 301 denotes an operation unit consisting of buttons, a touch panel, etc., which is used by the user to operate the portable wireless device 300. As described in Fig. 1, operations such as photographing control of the power receiving device 200 and image viewing can be performed.

302 is a display unit composed of an LCD or the like, and is used to display the status of the portable wireless device 300 and to display images. This allows the user to view images on the power receiving device 200 and check live view images, etc.

303 is a non-volatile memory composed of a NOR flash memory, a NAND flash memory, or the like, and is used to store programs, image data, and the like of the portable wireless device 300. The non-volatile memory 303 is also used to store a USB compatibility list that links the XID with USB compatibility information. Note that the non-volatile memory 303 may be in a removable form such as an SD card.

304 is a wireless unit that complies with Wi-Fi (registered trademark), Bluetooth (registered trademark), etc., and is used to perform data communication with external devices. As described in FIG. 1, the wireless unit 304 is used to perform data communication with the power receiving device 200.

305 is a wireless unit for mobile communications conforming to standards such as 4G and 5G, and is used not only for voice data for phone calls, but also for web access via high-speed data communications. As described in FIG. 1, the mobile wireless device 300 also uses the wireless unit 305 when accessing the cloud server 150 on the web.

4A is a flowchart of power receiving control according to the first embodiment. When the control unit 250 detects that the power supply device 130 is connected to the connection unit 210 via the cable 120, the control unit 250 starts the process of this flowchart.

At S401, the PD communication unit 204 starts transmitting and receiving information with the power supply device 130 based on the USB-PD standard communication protocol.

In S402, the PD communication unit 204 determines whether the power supply device 130 supports the USB-PD standard. If the power supply device 130 supports the USB-PD standard, the process proceeds to S403; if not, the process proceeds to S411.

Here, the PD communication unit 204 judges whether the power supply device 130 supports the PD standard depending on whether communication based on the communication protocol of the USB-PD standard is received from the power supply device 130. If the PD communication unit 204 can correctly receive communication based on the communication protocol of the USB-PD standard within a predetermined period, it judges that the power supply device 130 supports the USB-PD standard. Conversely, if the PD communication unit 204 cannot correctly receive communication based on the communication protocol of the USB-PD standard or cannot receive communication within a predetermined period, it judges that the power supply device 130 does not support the USB-PD standard. The predetermined period may be a period specified in the USB-PD standard, and may be, for example, a period of 310 ms. Moreover, communication based on the communication protocol of the USB-PD standard means Source Capability Message communication including power information that the power supply device 130 can supply. In this embodiment, as an example, the communication from the power supply device 130 includes power information indicating that it is possible to supply power of 2.5 W (5 V, 500 mA), 15 W (5 V, 3 A), 27 W (9 V, 3 A), and 30 W (15 V, 2 A).

In S403, the PD communication unit 204 transmits and receives information based on the communication protocol of the USB-PD standard, and requests the power supply device 130 to supply power _P11 . Here, the power _P11 may be the minimum power that allows the power receiving device 200 to execute the first authentication process of S405 and the second authentication process of S407. The power _P11 is determined by selecting it from the power supply device 130's available power information received in S402. In this embodiment, as an example, the power _P11 is 2.5 W (5 V, 500 mA).

In S404, the power receiving unit 201 controls the power P ₁₂ (first power) supplied from the power supply device 130 based on the control from the control unit 250 so that it does not exceed the power P _11. In this embodiment, the power receiving unit 201 controls the current value supplied from the power supply device 130 to 500 mA or less, thereby controlling the power P ₁₂ (first power) so that it does not exceed the power P _11. Here, the power receiving unit 201 uses the supplied power P ₁₂ to supply the power required for the power receiving device 200 to execute the first authentication process in S405 and the second authentication process in S407 to each unit of the power receiving device 200. In addition, in order to prevent a shortage of power for the first authentication process and the second authentication process, the operation of a block in the power receiving device 200 that is not involved in the execution of the first authentication process and the second authentication process may be restricted so as to reduce power consumption.

At S405, the power receiving device 200 performs a first authentication process on each of the power supply device 130 and the cable 120 connected to the power receiving device 200 to confirm that the power supply device 130 and the cable 120 are each trusted by the USB-IF. The first authentication process includes the transmission and reception of information based on the USB-PD standard by the PD communication unit 204, and processing based on the USB-AUTH standard by the authentication unit 205.

The first authentication process for the power supply device 130 will be specifically described. The PD communication unit 204 receives predetermined authentication information based on the communication protocol of the USB-AUTH standard from the power supply device 130. The predetermined authentication information is electronic information of a certificate that is issued and encrypted by the USB-IF. If the PD communication unit 204 does not correctly receive the predetermined authentication information within a predetermined period, the certificate unit 205 determines that the power supply device 130 is not trusted by the USB-IF. The predetermined period may be any period specified in the USB-PD standard, and may be, for example, a period of 4.5 seconds. If the PD communication unit 204 correctly receives the predetermined authentication information within the predetermined period, it sends the received authentication information to the authentication unit 205.

The authentication unit 205 performs a predetermined authentication process defined by the USB-AUTH standard on the predetermined authentication information. If the predetermined authentication process fails, the authentication unit 205 determines that the power supply device 130 is not trusted by the USB-IF. If the predetermined authentication process is successful, the authentication unit 205 determines that the power supply device 130 is trusted by the USB-IF. Here, the predetermined authentication process is a decryption process for the encrypted certificate, which makes it possible to determine whether the authentication information is genuine. If the predetermined authentication process is successful, the authentication unit 205 acquires the XID (USB product identification information) included in the electronic information of the decrypted certificate.

The first authentication process for the cable 120 is similar to the first authentication process for the power supply device 130. Note that the power receiving device 200 may perform the first authentication process for only one of the power supply device 130 and the cable 120.

In S406, the authentication unit 205 determines whether the power supply device 130 and the cable 120 are each trusted by the USB-IF based on the result of the first authentication process in S405. If the power supply device 130 and the cable 120 are trusted by the USB-IF (if the first authentication process is successful), the processing step proceeds to S407. If the power supply device 130 or the cable 120 is not trusted by the USB-IF (if the first authentication process fails), the processing step proceeds to S411.

Note that if the first authentication process is performed on only one of the power supply device 130 and the cable 120 in S405, the conditional branch in S406 is performed based on the authentication result of the USB product (e.g., the power supply device 130) on which the first authentication process was performed.

In S407, the control unit 250 performs a second authentication process to check whether the power supply device 130 and the cable 120 are compliant with the USB standard (whether they have passed a USB standard compliance test). The second authentication process is performed by comparing the XIDs of the power supply device 130 and the cable 120 acquired in S406 with a USB compliance list stored in advance in the non-volatile memory 211.

Now, with reference to FIG. 5A, an example of a USB compatibility list (compatibility management information) will be described. In FIG. 5A, 500 is a USB compatibility list. 501 indicates one or more XIDs (XID list) included in the USB compatibility list 500. 502 indicates USB compatibility information linked to each XID. The USB compatibility information 502 has a value of, for example, "OK" indicating that the corresponding USB product complies with the USB standard, "NG" indicating that it does not comply, or "under testing" indicating that it is under testing. The USB compatibility information 502 linked to the XID "0x9ABC_DEF0" is "NG".

503 indicates version information of the USB compatibility information linked to each XID. Version information 503 stores a number or a character string indicating the version, such as "0.1", "1.0", or "2.0". In the example of FIG. 5A, the larger the number in version information 503, the newer the information in the corresponding USB compatibility information 502 and expansion area 504 is.

504 indicates an extension area associated with each XID. Information related to each XID other than USB compatibility information is stored in the extension area 504. Any information associated with each XID other than USB compatibility information may be stored in the extension area 504. The information in the extension area 504 may be updated with new information associated with each XID when updating the USB compatibility list described later. In addition, for example, when it is determined not to receive power from a USB product corresponding to a specific XID by a user's menu selection or operation using the operation unit 207, the information in the extension area 504 may be updated. In the example of FIG. 5A, it is determined not to receive power from a USB product having XID "0x789A_1234" by a user's menu selection or operation using the operation unit 207, and the value of "NG" (power receiving restriction information) is stored in the extension area 504 in association with XID "0x789A_1234". Of course, Figure 5A is just an example, and the configuration of the USB compatibility list is not limited to the configuration shown in Figure 5A.

As described above, in S407 of FIG. 4A, the control unit 250 checks the XID acquired in S406 against the USB compatibility list 500.

As an example, consider a case where the XID of power supply device 130 is "0x1234_5678" and the XID of cable 120 is "0x9ABC_DEF0". In this case, in the USB compatibility list 500 in FIG. 5A, the USB compatibility information 502 linked to the XID of power supply device 130 is "OK", and the control unit 250 determines that power supply device 130 complies with the USB standard. Also, the USB compatibility information 502 linked to the XID of cable 120 is "NG", and the control unit 250 determines that cable 120 does not comply with the USB standard.

As another example, consider a case where the XID of the power supply device 130 is "0x1234_5678" and the XID of the cable 120 is "0x789A_1234". In this case, in the USB compatibility list 500 of FIG. 5A, the USB compatibility information 502 associated with the XID of the power supply device 130 is "OK", and the control unit 250 determines that the power supply device 130 complies with the USB standard. Also, the USB compatibility information 502 associated with the XID of the cable 120 is "OK", and the control unit 250 determines that the cable 120 complies with the USB standard. However, the extension area 504 associated with the XID of the cable 120 is "NG". Therefore, the control unit 250 may determine that the cable 120 does not comply with the USB standard regardless of the USB compatibility information 502 associated with the XID of the cable 120, and determine that the second authentication process has failed. In this way, the control unit 250 may perform the second authentication process based on the information in the extended area 504 in addition to the USB compatibility information 502.

The USB compatibility list 500 does not have to include the USB compatibility information 502. In this case, the control unit 250 determines that the XID list 501 indicates the XIDs of USB products that have passed the compatibility test. Therefore, for example, if the XID of the power supply device 130 is included in the USB compatibility list 500, the control unit 250 determines that the power supply device 130 has passed the compatibility test.

Further details of the second authentication process of S407 will be described later with reference to FIG. 5B. Note that the power receiving device 200 may perform the second authentication process for only one of the power supply device 130 and the cable 120.

In S408, the control unit 250 determines whether the power supply device 130 and the cable 120 each comply with the USB standard based on the result of the second authentication process in S407. If the power supply device 130 and the cable 120 comply with the USB standard (if the second authentication process is successful), the process proceeds to S409. If the power supply device 130 or the cable 120 does not comply with the USB standard (if the second authentication process fails), the process proceeds to S411.

Note that if the second authentication process is performed on only one of the power supply device 130 and the cable 120 in S407, the conditional branch in S408 is performed based on the authentication result of the USB product (e.g., the power supply device 130) on which the second authentication process was performed.

In S409, the PD communication unit 204 transmits and receives information based on the communication protocol of the USB-PD standard, and requests the power supply device 130 to supply power _P21 based on the power supply information that can be supplied from the power supply device 130. Here, the power _P21 may be a power that exceeds the power _P11 . Furthermore, the power _P21 may be a power required for the operation of the power receiving device 200. Furthermore, the power _P21 is determined by selecting it from the power supply information that can be supplied by the power supply device 130 received in S402. In this embodiment, as an example, the power _P21 is 30 W (15 V, 2 A).

In S410, the power receiving unit 201 controls the power _P22 (second power) supplied from the power supply device 130 based on the control from the control unit 250 so that it does not exceed the power _P21 . In this embodiment, the power receiving unit 201 controls the current value supplied from the power supply device 130 to 2 A or less, thereby controlling the power _P22 (second power) so that it does not exceed the power _P21 . Here, the power receiving unit 201 uses the supplied power _P22 to supply necessary power to each unit of the power receiving device 200. Note that the power receiving device 200 may release the operation restriction performed in S404 and switch the operation setting of each unit of the power receiving device 200 so that it consumes more power (however, does not exceed the power _P21 ).

If it is determined in S402 that the power supply device 130 does not support the USB-PD standard, if it is determined in S406 that the first authentication process has failed, or if it is determined in S408 that the second authentication process has failed, the process of S411 is executed. In S411, the control unit 250 controls the power receiving unit 201 to stop receiving power from the power supply device 130, and ends the power receiving control of this flowchart. Also, the PD communication unit 204 may stop the communication process.

In addition, in S411, the control unit 250 may control the power receiving unit 201 to limit the power received from the power supply device 130 instead of completely stopping the power reception. The power received from the power supply device 130 may be lower than 2.5 W (5 V, 500 mA), for example.

The control unit 250 may perform different processing depending on whether the processing step transitions to S411 from S402, S406, or S408. For example, when the processing step transitions from S402 to S411, the power supply device 130 does not support the USB-PD standard. Therefore, the control unit 250 controls to stop power reception. When the processing step transitions from S406 to S411, the power supply device 130 supports the USB-PD standard, but it cannot be confirmed that it was manufactured by a reliable manufacturer. Therefore, the control unit 250 controls to receive a relatively small amount of power, such as 0.5 W (5 V, 100 mA). When the processing step transitions from S408 to S411, it can be confirmed that the power supply device 130 supports the USB-PD standard and that it was manufactured by a reliable manufacturer, but it cannot be confirmed that it complies with the USB standard. Therefore, the control unit 250 performs control so as to receive a relatively large amount of power, such as 2.5 W (5 V, 500 mA), within a range not exceeding the power _P11 .

Next, the second authentication process in S407 of FIG. 4A will be described in detail with reference to FIG. 5B. Here, the second authentication process for the power supply device 130 will be described as an example, but the second authentication process for the cable 120 is similar.

In S501, the control unit 250 compares the XID of the power supply device 130 acquired by the first authentication process (S406 in FIG. 4A) with the XID list 501 of the USB compatibility list 500 to determine whether a matching XID exists in the XID list 501. If an XID matching the power supply device 130 XID exists in the XID list 501, the process proceeds to S502; otherwise, the process proceeds to S506. For example, if the XID of the power supply device 130 is "0x1234_5678", a matching XID "0x1234_5678" exists in the XID list 501, and so the process proceeds to S502.

In S502, the control unit 250 determines whether the USB compatibility information 502 linked to the XID of the power supply device 130 in the USB compatibility list 500 is "OK" (information indicating that the USB product complies with the USB standard). If the USB compatibility information 502 linked to the XID of the power supply device 130 is "OK", the processing step proceeds to S503, and if not, the processing step proceeds to S506. For example, if the XID of the power supply device 130 is "0x1234_5678", the corresponding USB compatibility information 502 is "OK" (information indicating that the USB product complies with the USB standard), and so the processing step proceeds to S503.

In S503, the control unit 250 determines whether or not information on the expansion area 504 linked to the XID of the power supply device 130 exists in the USB compatibility list 500. If information on the expansion area 504 linked to the XID of the power supply device 130 exists, the process proceeds to S504; if not, the process proceeds to S505. For example, if the XID of the power supply device 130 is "0x1234_5678", there is no information on the corresponding expansion area 504, so the process proceeds to S505. As another example, if the XID of the power supply device 130 is "0x789A_1234", there is information on the corresponding expansion area 504, so the process proceeds to S504.

In S504, the control unit 250 determines whether the information in the extension area 504 linked to the XID of the power supply device 130 is "NG". If the information in the extension area 504 linked to the XID of the power supply device 130 is "NG", the processing step proceeds to S506, otherwise the processing step proceeds to S505. For example, if the XID of the power supply device 130 is "0x789A_1234", the information in the corresponding extension area 504 is "NG", so the processing step proceeds to S506.

In S505, the control unit 250 determines that the power supply device 130 complies with the USB standard. Therefore, if the USB compatibility information 502 corresponding to the XID of the power supply device 130 is "OK" and there is no "NG" in the extended area 504 corresponding to the XID of the power supply device 130, the second authentication process for the power supply device 130 is successful.

On the other hand, in S506, the control unit 250 determines that the power supply device 130 does not comply with the USB standard. Therefore, if the XID of the power supply device 130 does not exist in the XID list 501, the corresponding USB compatibility information 502 is not "OK", or the corresponding extension area 504 is "NG", the second authentication process for the power supply device 130 fails.

The control unit 250 may perform the second authentication process without using the information in the extended area 504. In this case, the processes of S503 and S504 are not executed, and if the USB compatibility information 502 corresponding to the XID of the power supply device 130 is "OK", the process proceeds from S502 to S505.

According to the above power reception control, when it is confirmed that the power supply device 130 is trusted by the USB-IF and also complies with the USB standard, control is performed to receive power _P22 , which is greater than power _P12 . Therefore, according to the above power reception control, it is possible to further improve the safety of power reception.

Modification of power receiving control Fig. 4B is a flowchart of a modification of the power receiving control according to the first embodiment. In Fig. 4B, steps in which the same or similar processes as those in Fig. 4A are performed are denoted by the same reference numerals as those in Fig. 4A. When the control unit 250 detects that the power supply device 130 is connected to the connection unit 210 via the cable 120, it starts the process of this flowchart.

In S421, the PD communication unit 204 transmits and receives information based on the communication protocol of the USB-PD standard, and requests the power supply device 130 to supply power _P11 . Here, the power _P11 may be the minimum power that allows the power receiving device 200 to execute the first authentication process in S405. The power _P11 is determined by selecting it from the power supply information that the power supply device 130 can supply and received in S402. In this embodiment, as an example, the power _P11 is 2.5 W (5 V, 500 mA).

In S422, the power receiving unit 201 controls the power _P12 (first power) supplied from the power supply device 130 based on the control from the control unit 250 so that it does not exceed the power _P11 . In this embodiment, the power receiving unit 201 controls the current value supplied from the power supply device 130 to 500 mA or less, thereby controlling the power _P12 (first power) so that it does not exceed the power _P11 . Here, the power receiving unit 201 uses the supplied power _P12 to supply the power required for the power receiving device 200 to execute the first authentication process of S405 to each unit of the power receiving device 200. In addition, in order to prevent a shortage of power for the first authentication process, the operation of a block in the power receiving device 200 that is not involved in the execution of the first authentication process may be restricted so as to reduce power consumption. For example, if the power required to execute the first authentication process is 0.5 W and a block in the power receiving device 200 that is not involved in the execution of the first authentication process does not consume power, the power receiving unit 201 may control the current value supplied from the power supply device 130 to be 100 mA.

In S423, the PD communication unit 204 transmits and receives information based on the communication protocol of the USB-PD standard, and requests the power supply device 130 to supply power _P31 based on the power supply information available from the power supply device 130. Here, the power _P31 may be the minimum power that allows the power receiving device 200 to execute the second authentication process in S407, and may be a power that exceeds the power _P11 , but is smaller than the power _P21 described below. The power _P31 is determined by selecting it from the power supply information available from the power supply device 130 received in S402. In this embodiment, as an example, the power _P31 is 15 W (5 V, 3 A).

In S424, the power receiving unit 201 controls the power _P32 (third power) supplied from the power supply device 130 based on the control from the control unit 250 so that it does not exceed the power _P31 . In this embodiment, the power receiving unit 201 controls the current value supplied from the power supply device 130 to 3 A or less, thereby controlling the power _P32 (third power) so that it does not exceed the power _P31 . The power _P32 (third power) is greater than the power _P12 (first power) and less than the power _P22 (second power). Here, the power receiving unit 201 uses the supplied power _P32 to supply the power required for the power receiving device 200 to execute the second authentication process of S407 to each unit of the power receiving device 200. In addition, in order to prevent a shortage of power for the second authentication process, the operation of a block not involved in the execution of the second authentication process in the power receiving device 200 may be restricted so as to reduce power consumption. For example, if the power required to execute the second authentication process is 5 W and a block in the power receiving device 200 that is not involved in the execution of the second authentication process does not consume power, the power receiving unit 201 may control the current value supplied from the power supply device 130 to be 1 A.

The process of S425 is the same as the process of S408, except for the transition of the processing step according to the judgment result. Specifically, if the second authentication process of S407 is successful, the processing step proceeds to S426, and if the second authentication process fails, the processing step proceeds to S428.

In S426, the PD communication unit 204 transmits and receives information based on the communication protocol of the USB-PD standard, and requests the power supply device 130 to supply power _P21 based on the power supply information that can be supplied from the power supply device 130. Here, the power _P21 may be a power that exceeds the power _P31 . Furthermore, the power _P21 may be a power required for the operation of the power receiving device 200. Furthermore, the power _P21 is determined by selecting it from the power supply information that can be supplied by the power supply device 130 received in S402. In this embodiment, as an example, the power _P21 is 30 W (15 V, 2 A).

In S427, the power receiving unit 201 controls the power _P22 (second power) supplied from the power supply device 130 based on the control from the control unit 250 so that it does not exceed the power _P21 . In this embodiment, the power receiving unit 201 controls the current value supplied from the power supply device 130 to 2 A or less, thereby controlling the power _P22 (second power) so that it does not exceed the power _P21 . Here, the power receiving unit 201 uses the supplied power _P22 to supply necessary power to each unit of the power receiving device 200. Note that the power receiving device 200 may release the operation restrictions performed in S422 and S424, and switch the operation settings of each unit of the power receiving device 200 so that it consumes more power (however, does not exceed the power _P21 ).

If it is determined in S425 that the second authentication process has failed, the process proceeds to S428. In S428, the control unit 250 controls the power receiving unit 201 to continue receiving the power _P32 (see S424).

4B, the power receiving unit 201 requests power _P31 and receives power _P32 (S423 and _S424 ) before the second authentication process (S407) is performed. However, the power receiving unit 201 may request power P31 and receive power _P32 (S423 and S424) after the second authentication process (S407) has failed.

According to the above-described modified example of the power receiving control, it is possible to perform the power receiving control according to the level of safety (reliability) of the power supply device 130. At the time of S422 (before the first authentication process is executed), it is unclear whether the power supply device 130 is manufactured by a reliable manufacturer. Also, at the time of S424 (after the first authentication process is successful and before the second authentication process is executed), it is unclear whether the power supply device 130 complies with the USB standard, but since it is confirmed that the power supply device 130 is manufactured by a reliable manufacturer, the power supply device 130 can be trusted to a certain extent. Furthermore, at the time of S427 (after the first authentication process and the second authentication process are successful), it is confirmed that the power supply device 130 is manufactured by a reliable manufacturer and complies with the USB standard, so the power supply device 130 can be trusted to a certain extent. Therefore, the power receiving device 200 gradually increases the power to be received in the order of the time of S422, the time of S424, and the time of S427. This allows the power receiving device 200 to receive a relatively large amount of power while ensuring safety even if the power supply device 130 does not comply with the USB standard. As a result, for example, even if the power consumption of the second authentication process is greater than the power _P11 (the maximum value of the power _P12 ), the power receiving device 200 can execute the second authentication process by receiving the power _P32 .

● Summary of the First Embodiment As described above, according to the first embodiment, the power receiving device 200 obtains a certificate including an XID from the power supply device 130 based on the USB-AUTH standard, and determines whether or not the certificate is genuine (first authentication process). In addition, the power receiving device 200 determines whether or not the power supply device 130 has passed a conformance test of the USB standard based on the XID (second authentication process). If it is determined that the certificate is genuine and that the power supply device 130 has passed the conformance test, the power receiving device 200 controls to receive power P ₂₂ (second power) from the power supply device 130 that is greater than power P ₁₂ (first power). This makes it possible to further improve the safety of the power receiving device 200 receiving power from the power supply device 130.

In the above description, the second authentication process is executed based on the XID of the power supply device 130 and the USB compatibility list 500, but this embodiment is not limited to a configuration that uses the USB compatibility list 500. Any configuration that can determine whether the compatibility test has passed or failed based on the XID that identifies the power supply device 130 is included in the scope of this embodiment.

Second Embodiment
In the second embodiment, a configuration will be described in which the power receiving device 200 updates the USB compatibility list (first compatibility management information) stored in the non-volatile memory 211 by acquiring a USB compatibility list (second compatibility management information) from the power supply device 130. In this embodiment, the basic system configuration is similar to that of the first embodiment (see FIG. 1). Below, differences from the first embodiment will be mainly described.

The manufacturer of the power supply device 130 can store the USB compatibility list in the non-volatile memory of the power supply device 130, for example, before shipping the power supply device 130.

Figure 6 is a flowchart of the process of updating the USB compatibility list according to the second embodiment. When the information update determination unit 213 of the power receiving device 200 determines that the USB compatibility list should be updated, the process of this flowchart begins.

The conditions under which the information update determination unit 213 determines to update the USB compatibility list are not particularly limited. For example, as described in the first embodiment, the information update determination unit 213 determines to update the USB compatibility list when the control unit 250 determines that the power supply device 130 and the cable 120 are connected to the connection unit 210.

The update process in FIG. 6 is performed on each USB product that is directly or indirectly connected to the connection unit 210. Below, the update process for the power supply device 130 is described, but the update process for the cable 120 is similar.

In S601, the information update determination unit 213 makes an inquiry to determine whether or not the power supply device 130 has a USB compatibility list through data communication by the PD communication unit 204. Based on the response from the power supply device 130, the information update determination unit 213 determines whether or not the power supply device 130 has a USB compatibility list. If the power supply device 130 has a USB compatibility list, the processing step proceeds to S602; if not, the update processing of this flowchart ends.

In S602, the information acquisition unit 214 acquires a USB compatibility list from the power supply device 130 through data communication by the PD communication unit 204. The USB compatibility list acquired from the power supply device 130 (hereinafter referred to as the "USB compatibility list of the power supply device 130") has the same data structure (see FIG. 5A) as the USB compatibility list stored in the non-volatile memory 211 of the power receiving device 200 (hereinafter referred to as the "existing USB compatibility list"). However, the USB compatibility list of the power supply device 130 does not need to have information on the extension area 504.

In the following description, a set of information corresponding to one row of the USB compatibility list 500 shown in FIG. 5A is referred to as a "list entry." For example, the USB compatibility list of the power supply device 130 includes a list entry that associates the USB compatibility information "OK" and Version "1.0" with the XID "0x3456_ABCD."

The USB compatibility list of the power supply device 130 may include multiple XIDs. In this case, the processes from S603 onwards are executed with each of the multiple XIDs as the target XID (target identification information). The USB compatibility list of the power supply device 130 may or may not include the XID of the power supply device 130.

In S603, the information update unit 215 determines whether the XID included in the USB compatibility list of the power supply device 130 (hereinafter referred to as the "acquired XID") is present in the existing USB compatibility list. If the acquired XID is present in the existing USB compatibility list, the process proceeds to S605; if not, the process proceeds to S604.

At S604, the information update unit 215 adds a list entry corresponding to the acquired XID to the existing USB compatibility list.

In S605, the information update unit 215 determines whether the Version associated with the acquired XID is newer than the Version associated with the same XID in the existing USB compatibility list (hereinafter referred to as the "current Version"). If the Version associated with the acquired XID is newer than the current Version, the process proceeds to S606; if not, there is no need to update the existing USB compatibility list, and the update process of this flowchart ends.

The USB compatibility list of the power supply device 130 and the existing USB compatibility list do not need to include Version (version information). In this case, for example, if it is determined in S603 that the acquired XID is present in the existing USB compatibility list, the update process of this flowchart may end.

In S606, the information update unit 215 determines whether or not information exists in the extension area of the existing USB compatibility list that corresponds to the acquired XID. If information exists in the extension area, the process proceeds to S607; if not, the process proceeds to S608.

In S607, the information update unit 215 determines whether the information in the extended area is "NG" (power reception restriction information indicating that power will not be received from the USB product). If the information in the extended area is "NG", the update process in this flowchart ends, and if not, the process proceeds to step S608.

At S608, the information update unit 215 updates the existing USB compatibility list with the list entry corresponding to the acquired XID.

Summary of the Second Embodiment As described above, according to the second embodiment, the power receiving device 200 acquires a USB compatibility list (second compatibility management information) from the power supply device 130. Then, the power receiving device 200 updates the USB compatibility list (first compatibility management information) stored in the non-volatile memory 211 based on the USB compatibility list (second compatibility management information) acquired from the power supply device 130. This makes it possible to improve the usefulness of the USB compatibility list held by the power receiving device 200.

[Third embodiment]
In the third embodiment, a configuration will be described in which the power receiving device 200 updates the USB compatibility list (first compatibility management information) stored in the non-volatile memory 211 by acquiring a USB compatibility list (second compatibility management information) from the mobile wireless device 300. In this embodiment, the basic system configuration is similar to that of the first embodiment (see FIG. 1). Below, differences from the first embodiment will be mainly described.

7 is a sequence chart of a process of updating the USB compatibility list according to the third embodiment. When the information update determination unit 213 of the power receiving device 200 determines to update the USB compatibility list, the process of this sequence chart starts.

The conditions under which the information update determination unit 213 determines to update the USB compatibility list are not particularly limited. For example, as described in the first embodiment, the information update determination unit 213 determines to update the USB compatibility list when a specific user input is performed using the operation unit 207.

At S700, the control unit 250 of the power receiving device 200 performs processing to establish a wireless connection with the portable wireless device 300 using the wireless unit 212. Similarly, the control unit 350 of the portable wireless device 300 performs processing to establish a wireless connection with the power receiving device 200 using the wireless unit 304.

The control unit 250 of the power receiving device 200 may start the process of S700 to establish a wireless connection with the portable wireless device 300 when the power supply device 130 is connected to the connection unit 210. The control unit 350 of the portable wireless device 300 may also start the process of S700 to establish a wireless connection with the power receiving device 200 when an operation to view an image of the power receiving device 200 on the portable wireless device 300 is performed. In these cases, the information update determination unit 213 may determine to update the USB compatibility list in response to the establishment of a wireless connection.

At S701, the control unit 250 of the power receiving device 200 uses the wireless unit 212 to transmit the XID included in the USB compatibility list (USB compatibility list of the power receiving device 200) stored in the non-volatile memory 211 to the portable wireless device 300. The control unit 350 of the portable wireless device 300 uses the wireless unit 304 to receive the XID transmitted from the power receiving device 200.

In addition, in S701, the control unit 250 may transmit the XID of a USB product (e.g., power supply device 130) currently connected to the connection unit 210 instead of or in addition to the XID included in the USB compatibility list of the power receiving device 200. The control unit 250 may also transmit the XID of a USB product previously connected to the connection unit 210. To be able to transmit the XID of a USB product previously connected to the connection unit 210, the power receiving device 200 accumulates the XIDs of USB products that have been connected to the connection unit 210. The XID accumulation process will be described later.

At S702, the control unit 350 of the portable wireless device 300 uses the wireless unit 305 to request USB compatibility information corresponding to the XID received at S701 from the cloud server 150.

In S703, the control unit 350 of the portable wireless device 300 receives the USB compatibility information requested in S702 from the cloud server 150 using the wireless unit 305. Note that the USB compatibility information may be received by receiving information having a data structure similar to that of the USB compatibility list 500 shown in FIG. 5A, for example.

In S704, the control unit 350 of the portable wireless device 300 creates a USB compatibility list based on the XID received in S701 and the USB compatibility information received in S703, and stores it in the non-volatile memory 303. The USB compatibility list stored in the non-volatile memory 303 (hereinafter referred to as the "USB compatibility list of the portable wireless device 300") has a data structure similar to that of the USB compatibility list 500 shown in FIG. 5A, for example. If the USB compatibility list of the portable wireless device 300 already exists, the control unit 350 updates the USB compatibility list of the portable wireless device 300 by a process similar to the update process shown in FIG. 6, for example. For this update process, in S703, the control unit 350 may receive version information in addition to the USB compatibility information. Alternatively, since it is highly likely that the latest USB compatibility information is stored in the cloud server 150, the control unit 350 may perform the update process without using the version information. In this case, for example, if it is determined in S603 of FIG. 6 that the acquired XID is present in the existing USB compatibility list, the processing proceeds to step S608.

At S705, the control unit 350 of the portable wireless device 300 transmits the USB compatibility list of the portable wireless device 300 to the power receiving device 200 using the wireless unit 304. The control unit 250 of the power receiving device 200 receives the USB compatibility list of the portable wireless device 300 from the portable wireless device 300 using the wireless unit 212.

In S706, the control unit 250 of the power receiving device 200 updates the USB compatibility list of the power receiving device 200 based on the USB compatibility list of the portable wireless device 300 received in S705. The control unit 250 can update the USB compatibility list of the power receiving device 200, for example, by a process similar to the update process shown in FIG. 6. Also, similar to the update process described in S704, the control unit 250 may perform the update process without using version information.

8A is a flowchart of the XID accumulation process according to the third embodiment. The control unit 250 starts the process of this flowchart when it detects that a USB product is connected to the connection unit 210. In the following description, it is assumed that the power supply device 130 is connected to the connection unit 210.

In S801, the control unit 250 acquires the XID of the power supply device 130 from the power supply device 130. Here, it is assumed that the XID "0x5678_ABCD" is acquired. There are no particular limitations on the method of acquiring the XID, but for example, the control unit 250 can acquire the XID acquired by the authentication unit 205 through the first authentication process in S405 of FIG. 4A.

In S802, the control unit 250 determines whether the XID acquired in S801 is included in the XID list 501 of the USB compatibility list 500 in the non-volatile memory 211. If the acquired XID is included in the XID list 501, the processing of this flowchart ends. If the acquired XID is not included in the XID list 501, the processing proceeds to S803.

In S803, the control unit 250 adds the XID acquired in S801 to the XID list 501. The control unit 250 also associates this XID with the USB compatibility information "Unknown" and Version "0".

Figure 8(b) is a diagram showing an example of a USB compatibility list including an added XID. Compared to Figure 5A, Figure 8(b) includes an additional column 851 including the XID "0x5678_ABCD".

The control unit 250 can accumulate XIDs with unknown USB compatibility information by adding the XID to the USB compatibility list each time a new XID is acquired from a USB product connected to the connection unit 210. The control unit 250 can then acquire the corresponding USB compatibility information by transmitting the accumulated XID to the portable wireless device 300 in S701 described above.

The storage destination of the XID is not limited to the USB compatibility list. Also, it is not essential to link the USB compatibility information such as "Unknown" to the stored XID. For example, the control unit 250 may create a new XID list in the non-volatile memory 211 and store the new XID in the new XID list.

Sharing of USB Compatibility List According to this embodiment, when a user has a plurality of power receiving devices, the USB compatibility list can be shared among the plurality of power receiving devices via the mobile wireless device 300.

Figure 9 is a diagram illustrating an example of sharing a USB compatibility list. It is assumed that the user has a power receiving device 900 having a similar configuration to the power receiving device 200, in addition to the power receiving device 200. The connection unit 910 and wireless communication medium 960 have the same configuration as the connection unit 210 and wireless communication medium 360. It is also assumed that the user has a cable 920 and a power supply device 930 having the same configuration as the cable 120 and the power supply device 130, in addition to the cable 120 and the power supply device 130.

In the situation shown in Figure 9, when the power receiving device 200 to which the power supply device 130 has been connected executes the update process shown in Figure 7, in S704, the XID and USB compatibility information of the power supply device 130 are stored in the USB compatibility list of the portable wireless device 300. Thereafter, when the power receiving device 900 executes the update process shown in Figure 7, the XID and USB compatibility information of the power supply device 130 are stored in the USB compatibility list of the power receiving device 900 by the processes of S705 and S706. Similarly, when the power receiving device 900 to which the power supply device 930 has been connected executes the update process shown in Figure 7, in S704, the XID and USB compatibility information of the power supply device 930 are stored in the USB compatibility list of the portable wireless device 300. Thereafter, when the power receiving device 200 executes the update process shown in FIG. 7, the XID and USB compatibility information of the power supply device 930 are stored in the USB compatibility list of the power receiving device 200 by the processes of S705 and S706.

In this way, the power receiving devices 200 and 900 can share the USB compatibility list by performing an update process using the portable wireless device 300. Therefore, even if the portable wireless device 300 is not usable when the power supply device 130 is first connected to the power receiving device 900, the power receiving device 900 can determine the standard compatibility of the power supply device 130 if the USB compatibility list has been shared in advance.

Summary of the Third Embodiment As described above, according to the third embodiment, the power receiving device 200 acquires a USB compatibility list (second compatibility management information) from the portable wireless device 300 (communication device). Then, the power receiving device 200 updates the USB compatibility list (first compatibility management information) stored in the non-volatile memory 211 based on the USB compatibility list (second compatibility management information) acquired from the portable wireless device 300. This makes it possible to improve the usefulness of the USB compatibility list held by the power receiving device 200.

Also, according to the third embodiment, the power receiving device 200 acquires the XID of the power supply device 130 from the power supply device 130, stores it in the non-volatile memory 211, and transmits the stored XID of the power supply device 130 to the mobile wireless device 300. The power receiving device 200 then receives USB compatibility information associated with the XID of the power supply device 130 from the mobile wireless device 300 and stores it in the non-volatile memory 211. This makes it possible to selectively store the XID and USB compatibility information of the power supply device 130 that is actually connected to the power receiving device 200 (i.e., that is likely to be used in the future) in the USB compatibility list, thereby making it possible to effectively utilize the storage area of the non-volatile memory 211.

[Fourth embodiment]
In the fourth embodiment, a configuration for displaying information (message) when the first authentication process or the second authentication process fails will be described. In this embodiment, the basic system configuration is similar to that of the first embodiment (see FIG. 1). Below, differences from the first embodiment will be mainly described.

Figure 10 is a flowchart of power receiving control according to the fourth embodiment. In this flowchart, steps in which the same or similar processing as in Figure 4A is performed are given the same reference numerals as in Figure 4A. When the control unit 250 detects that the power supply device 130 is connected to the connection unit 210 via the cable 120, it starts the processing of this flowchart. In the following description, it is assumed that the first authentication processing and the second authentication processing are performed for the power supply device 130, but the same applies when the first authentication processing and the second authentication processing are performed for other USB products.

The process of S406 in FIG. 10 is similar to S406 in FIG. 4A, but the transition destination when the first authentication process fails is different from S406 in FIG. 4A. Specifically, when the first authentication process fails, the process proceeds to S1001. The process of S408 in FIG. 10 is similar to S408 in FIG. 4A, but the transition destination when the second authentication process succeeds and fails is different from S408 in FIG. 4A. Specifically, when the second authentication process succeeds, the process proceeds to S1004, and when the second authentication process fails, the process proceeds to S1002.

In S1001, the control unit 250 performs a first display control to display first information. For example, the control unit 250 displays information indicating that the power supply device 130 is not trusted by the USB-IF (the first authentication process has failed) on the display unit 208. The control unit 250 also displays information on the display unit 208 that prompts the user to select whether or not to supply power (receive power _P22 ) using the power supply device 130.

11(a) and 11(b) are diagrams showing examples of display of information in S1001. First, the control unit 250 displays information indicating that the power supply device 130 is not trusted by the USB-IF (the first authentication process has failed) on the display unit 208 as shown in FIG. 11(a). After that (for example, after a predetermined time has elapsed), the control unit 250 displays information prompting the user to select whether or not to supply power (receive power _P22 ) using the power supply device 130 on the display unit 208 as shown in FIG. 11(b). Note that the method of displaying information in S1001 is not particularly limited, and the control unit 250 may display information corresponding to FIG. 11(a) and information corresponding to FIG. 11(b) together on one screen as shown in FIG. 11(c).

The user can recognize that the first authentication process has failed from the information displayed in S1001. The user can then receive this information and safely supply power, for example by replacing the power supply device 130 with another power supply device that is trusted by the USB-IF.

When the user selects "Yes" or "No" via the operation unit 207 in FIG. 11(b) or FIG. 11(c), the processing proceeds to step S1003.

In S1002, the control unit 250 performs a second display control to display second information. For example, the control unit 250 displays information indicating that the power supply device 130 has not passed the USB standard conformance test (the second authentication process has failed) on the display unit 208. The control unit 250 also displays information on the display unit 208 that prompts the user to select whether or not to supply power (receive power _P22 ) using the power supply device 130.

11(d) and 11(b) are diagrams showing examples of display of information in S1002. First, the control unit 250 displays information indicating that the power supply device 130 has not passed the USB standard conformance test (failed in the second authentication process) on the display unit 208 as shown in FIG. 11(d). After that (for example, after a predetermined time has elapsed), the control unit 250 displays information prompting the user to select whether or not to use the power supply device 130 to supply power (receive power _P22 ) on the display unit 208 as shown in FIG. 11(b). Note that the method of displaying information in S1002 is not particularly limited, and the control unit 250 may display information corresponding to FIG. 11(d) and information corresponding to FIG. 11(b) together on one screen as shown in FIG. 11(e).

The user can recognize that the second authentication process has failed from the information displayed in S1002. The user can then use this information to safely supply power, for example by replacing the power supply device 130 with another power supply device that has passed the compatibility test. Alternatively, if there is a possibility that the second authentication process has failed because the USB compatibility list is out of date, the user may operate the power receiving device 200 to update the USB compatibility list.

When the user selects "Yes" or "No" via the operation unit 207 in FIG. 11(b) or FIG. 11(e), the processing proceeds to step S1003.

By displaying different information in S1001 and S1002 as described above, the user can recognize whether the first authentication process or the second authentication process has failed, and the measures to safely supply power become clearer. However, as shown in FIG. 11(f), for example, the control unit 250 may display the same information in S1001 and S1002. Even in this case, the user can recognize that at least the first authentication process or the second authentication process has failed.

In S1003, the control unit 250 determines whether or not to supply power (receive power _P22 ). If the user selects "Yes" in S1001 or S1002, the control unit 250 determines to supply power, and if the user selects "No" in S1001 or S1002, the control unit 250 determines not to supply power. If power is to be supplied, the process proceeds to S409, and if not, the process proceeds to S411.

In this way, the user can supply power by selecting "Yes" (user operation to select power supply) in response to information (power supply selection information) displayed in S1001 or S1002 that prompts the user to select whether or not to supply power. Therefore, even if the first authentication process or the second authentication process fails, the user can select to supply power if, for example, the user knows that the safety of the power supply device 130 has been ensured in some way. As a result, convenience for the user is improved. Note that the control unit 250 may display information (power supply selection information) that prompts the user to select whether or not to supply power only in one of S1001 and S1002.

At S1004, the control unit 250 displays information on the display unit 208 indicating that both the first authentication process and the second authentication process were successful.

Figure 11 (g) is a diagram showing an example of information display in S1004. By displaying information as shown in Figure 11 (g), the user can clearly recognize that both the first authentication process and the second authentication process have been successful. However, the process of S1004 may be omitted. Even in this case, the user can recognize that both the first authentication process and the second authentication process have been successful because the information display of S1001 or S1002 is not performed.

● Summary of the Fourth Embodiment As described above, according to the fourth embodiment, the power receiving device 200 obtains a certificate including an XID from the power supply device 130 based on the USB-AUTH standard, and determines whether or not this certificate is genuine (first authentication process). Furthermore, the power receiving device 200 determines whether or not the power supply device 130 has passed a conformance test of the USB standard based on the XID (second authentication process). Then, the power receiving device 200 displays information (message) when the first authentication process or the second authentication process fails. This allows the user to easily recognize that the first authentication process or the second authentication process has failed.

[Other embodiments]
The present invention can also be realized by a process in which a program for implementing one or more of the functions of the above-described embodiments is supplied to a system or device via a network or a storage medium, and one or more processors in a computer of the system or device read and execute the program. The present invention can also be realized by a circuit (e.g., ASIC) that implements one or more of the functions.

The invention is not limited to the above-described embodiment, and various modifications and variations are possible without departing from the spirit and scope of the invention. Therefore, the following claims are appended to disclose the scope of the invention.

120...cable, 130...power supply device, 150...cloud server, 200...power receiving device, 210...connection unit, 300...portable wireless device, 360...wireless communication medium, 370...wireless communication medium

Claims (13)

An interface capable of data communication and receiving power based on a predetermined power supply standard;
A control means for controlling the power supply device to receive a first power from the power supply device via the interface;
a first determination means for obtaining authentication information including identification information of the power supply device from the power supply device via the interface based on a predetermined authentication standard and determining whether the authentication information is genuine;
a second determination means for determining whether or not the power supply device has passed a conformity test for the predetermined power supply standard based on the identification information;
Equipped with
When the authentication information is determined to be authentic and the power supply device is determined to have passed the conformity test, the control means controls the power receiving device to receive a second power greater than the first power from the power supply device. a memory for storing compatibility management information including one or more identification information;
The power receiving device according to claim 1 , wherein the second determination unit determines that the power supply device has passed the conformance test when identification information of the power supply device is included in the conformance management information. In the conformance management information, each identification information is associated with conformance information indicating pass/fail of the conformance test,
The power receiving device according to claim 2, characterized in that the second determination means determines that the power supplying device has passed the conformance test when identification information of the power supplying device is included in the conformance management information and conformance information associated with the identification information of the power supplying device indicates passing the conformance test. The power receiving device further includes an associating means for associating power receiving limit information with specific identification information in the compatibility management information,
The power receiving device according to claim 3, characterized in that, when the power receiving limit information is associated with the identification information of the power supply device in the compatibility management information, the second determination means determines that the power supply device has not passed the compatibility test, regardless of the compatibility information associated with the identification information of the power supply device. The power receiving device according to claim 1 , wherein, when it is determined that the authentication information is not authentic, the control means performs control so as to stop receiving power from the power supply device. 6. The power receiving device according to claim 1, wherein, when the authentication information is determined to be authentic and the power supply device is determined to have not passed the conformity test, the control means controls the power receiving device to receive a third power from the power supply device, the third power being greater than the first power and less than the second power. The power receiving device according to any one of claims 1 to 5, characterized in that, when the authentication information is determined to be genuine, the control means controls the power receiving device to receive a third power from the power supply device, the third power being greater than the first power and less than the second power, before a determination is made by the second determination means. 8. The power receiving device according to claim 1, wherein the predetermined authentication standard is a USB-AUTH standard. 9. The power receiving device according to claim 1, wherein the interface includes a USB TYPE-C connector. 10. The power receiving device according to claim 1, wherein the interface is capable of data communication based on the USB standard. The power receiving device according to claim 1 , wherein the identification information is an XID of the USB standard. A method for controlling a power receiving device having an interface capable of data communication and receiving power based on a predetermined power supply standard, comprising:
a control step of controlling the power supply device to receive a first power from the power supply device via the interface;
a first determination step of acquiring authentication information including identification information of the power supply device from the power supply device via the interface based on a predetermined authentication standard and determining whether the authentication information is genuine;
a second determination step of determining whether or not the power supply device has passed a conformity test for the predetermined power supply standard based on the identification information;
Equipped with
a control step of controlling the power supply device to receive a second power greater than the first power from the power supply device when the authentication information is determined to be authentic and the power supply device is determined to have passed the conformity test. A program for causing a computer to function as each of the means of a power receiving device according to any one of claims 1 to 11.

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