JP7175672B2 - Electronic device and power control method - Google Patents

Description

TECHNICAL FIELD Embodiments of the present invention relate to an electronic device and a power control method thereof.

An electronic device is provided with a dedicated AC adapter as a power supply. By connecting the AC adapter to the power connector, power is supplied from the AC adapter to the electronic device.
In recent years, a general-purpose power supply (hereinafter referred to as a USB (registered trademark) power supply) using the PD (Power Delivery) function of the USB Type-C (registered trademark) standard has been developed. By connecting the USB power source to the USB Type-C connector, power is supplied from the USB power source to the electronic device. USB power supplies include various devices with various power ratings, and some USB power supplies cannot supply a sufficient current even if the voltage is high.

An AC adapter and a USB power source may be connected to an electronic device at the same time. In this case, power is supplied from the AC adapter or the USB power supply, whichever has the higher output voltage. Therefore, if the output voltage of the USB power supply is higher than the output voltage of the AC adapter, even if the current that the USB power supply can supply is small, power will be supplied from the USB power supply to the electronic device, and sufficient power will not be supplied to the electronic device. Can not.

Japanese Patent Application Laid-Open No. 2018-063558 JP 2018-007451 A U.S. Patent Application Publication No. 2018/004277

SUMMARY OF THE INVENTION It is an object of the present invention to provide an electronic device and a power supply control method in which power is supplied from an optimum power supply when connected to a plurality of power supplies.

An electronic device according to an embodiment includes a first power supply terminal to which a first power supply can be connected, first detection means for detecting that the first power supply is connected to the first power supply terminal, and at least one second power supply. at least one second power supply terminal connectable to the at least one second power supply terminal; second detection means for detecting that the at least one second power supply is connected to the at least one second power supply terminal; When the first detection means detects that the first power supply terminal is connected, and the second detection means detects that the at least one second power supply is connected to the at least one second power supply terminal, from the first power supply when the rated voltage of the first power supply is not higher than the rated voltage of the at least one second power supply and the power rating of the first power supply is not lower than the rated power of the at least one second power supply. and control means for interrupting the power supply path of the at least one second power terminal so that the power of the at least one second power terminal is supplied to the power supply terminal.

1 is a perspective view showing an example of the appearance of a personal computer as an example of an electronic device according to a first embodiment; FIG. 1 is a circuit diagram showing an example of a power supply control circuit of a personal computer, which is an example of an electronic device according to a first embodiment; FIG. 4 is a sequence diagram showing an example of negotiation in the power supply control circuit of the electronic device according to the first embodiment; FIG. 4 is a flow chart showing an example of the operation of the power supply control circuit of the electronic device according to the first embodiment; FIG. 11 is a circuit diagram showing an example of a power supply control circuit of a personal computer, which is an example of an electronic device according to a second embodiment; 9 is a flow chart showing an example of the operation of the power supply control circuit of the electronic device according to the second embodiment; 9 is a flow chart showing an example of the operation of the power supply control circuit of the electronic device according to the second embodiment; 9 is a flow chart showing an example of the operation of the power supply control circuit of the electronic device according to the second embodiment;

Embodiments will be described below with reference to the drawings. The disclosure is merely an example, and the invention is not limited by the contents described in the following embodiments. Modifications that can be easily conceived by those skilled in the art are naturally included in the scope of the disclosure. In order to make the explanation clearer, in the drawings, the size, shape, etc. of each part may be changed from the actual embodiment and shown schematically. Corresponding elements in multiple drawings may be denoted by the same reference numerals and detailed descriptions thereof may be omitted.

[First Embodiment: Outline of Electronic Device]
FIG. 1 shows a notebook personal computer (hereinafter referred to as PC) 10 as an example of electronic equipment according to the first embodiment. The PC 10 is composed of a main body 14 and a display unit 16 . The display unit 16 is attached to the main body 14 so as to be openable and closable. An LCD (Liquid Crystal Display) panel 18 is arranged on the surface of the display unit 16 , and a panel substrate (not shown) is accommodated inside the display unit 16 . The main body 14 has a thin box-shaped housing, a keyboard 20 is arranged on the upper surface of the housing, a circuit board (not shown) is housed inside the housing, and a power connector 24 and a USB Type-C are provided on the side of the housing. Various connectors such as connector 26 are arranged. Although the number of USB Type-C connectors 26 is singular in the first embodiment, a plurality of USB Type-C connectors 26 may be provided.

[Configuration of power supply control circuit]
FIG. 2 is a circuit diagram showing an example of the power control circuit of the PC 10. As shown in FIG. An AC adapter 42 connected to an AC power supply (not shown) via a power cord is connected to the power connector 24 via a cable (not shown). The AC adapter 42 converts AC voltage to DC voltage and supplies it to the power connector 24 . Power connector 24 is connected to the anode of diode 44 . Diode 44 is for backflow prevention. The power connector 24 (the anode of the diode 44) is also connected to ground through voltage dividing resistors 46 and 48 in series. The cathode of diode 44 is connected to the input terminal of charger circuit 52 .

A USB power supply 54 is connected to the USB Type-C connector 26 via a USB Type-C cable (not shown). The USB power supply 54 is a source device conforming to the PD standard of USB Type-C that transmits a DC voltage to a sink device. The USB power supply 54 includes various types of devices with different power ratings, such as Type-C power supplies, PD power supplies, mobile batteries, and the like. A Type-C power supply has a power rating of 5V, 1.5A or 5V, 3A. The rated power of the PD power supply is 20V maximum (often set to 5V, 9V, 15V, or 20V) and 5A maximum. Mobile batteries have a wide variety of power ratings. The USB power supply 54 may have a power rating different from that of the AC adapter 42, or may have the same power rating.

The USB Type-C connector 26 has multiple pins, eg VBUS pin, CC1 pin, CC2 pin. A VBUS pin is a pin for transmitting power from the USB power supply 54 to the PC 10 . The VBUS pin is connected through load switch 56 to the anode of diode 58 . Diode 58 is for backflow prevention. The load switch 56 is composed of, for example, an IC including a MOSFET, but for convenience of explanation the load switch 56 is shown as a switch P-channel MOSFET. ON/OFF of the load switch 56 is controlled by the EC 66, which will be described later.

The cathode of diode 58 is connected to the input terminal of charger circuit 52 along with the cathode of diode 44 . CC is an abbreviation for Configuration Channel, and is used to communicate information regarding power supply negotiation between the USB power supply 54 and the PC 10 .

The USB power supply 54 and the PC 10 have USB PD controllers 62, 64, respectively. The USB PD controller 62 is also called a source side controller, and the USB PD controller 64 is also called a sink side controller. The CC1 and CC2 lines of USB Type-C connector 26 are connected to both USB PD controller 62 and USB PD controller 64 . The USB PD controllers 62, 64 each have a memory 63, 65 for storing information.

The charger circuit 52 generates system power from the input voltage and supplies the system power to each part of the PC 10 . Charger circuit 52 also charges battery 68 using the system power supply. The system power supply (electric power) consists of the output power of the charger circuit 52 and the output power of the battery 68 . Therefore, even if the power consumption of the PC 10 momentarily rises and exceeds the rated power of the AC adapter 42, the output power of the battery 68 compensates for the output power of the AC adapter 42, preventing the PC 10 from shutting down. .

The charger circuit 52 monitors the input voltage and supplies a connection detection signal based on the monitoring result to an EC (embedded controller) 66 . When the input voltage is equal to or higher than the first threshold voltage, charger circuit 52 sets the connection detection signal to high level, and when the input voltage is not equal to or higher than the first threshold voltage, charger circuit 52 sets the connection detection signal to low level.

EC66 is a power management controller and may be implemented as a one-chip microcomputer. The EC 66 has a function of powering on or powering off the PC 10 according to the operation of a power switch (not shown). The EC 66 includes a PD (Power Delivery) information read block 70 , a rating determination block 72 , an A/D conversion block 74 and a battery control block 76 .

The PD information is information about the power supply capability of the USB power supply 54 obtained by the USB PD controller 64 communicating with the USB PD controller 62 via the CC1 line and CC2 line. For example, the PD information may indicate the rated power (rated voltage, rated current) of the USB power supply 54 . Information indicating the rated power of the USB power supply 54 is stored in the memory 63 within the USB PD controller 62 . The PD information obtained by the USB PD controller 64 is stored in the memory 65 .

Battery control block 76 is connected to control IC 78 in battery 68 via an SM bus. When the battery 68 is attached to the PC 10 , a battery detection signal is directly supplied from the control IC 78 to the battery control block 76 . An LED 80 is connected to the battery control block 76 . The LED 80 is an indicator that indicates the mounting status and charging status of the battery 68, the connection status of the AC adapter 42 and the USB power supply 54, and the like. A connection detection signal output from the charger circuit 52 is supplied to a PD information read block 70 , a rating determination block 72 , an A/D conversion block 74 and a battery control block 76 .

The PD information read block 70 is connected to the USB PD controller 64 via the SM bus and reads PD information from the memory 65 of the USB PD controller 64 . The PD information is a contact value (output voltage/output current), vendor-specific information, etc.

A connection point (voltage dividing point) of the voltage dividing resistors 46 and 48 is connected to an analog input terminal of the A/D conversion block 74 . The output terminal of the PD information read block 70 and the digital output terminal of the A/D conversion block 74 are connected to the rating discrimination block 72 . The rating determination block 72 compares the rated power of the AC adapter 42 and the rated power of the USB power supply 54 based on the PD information and the voltages at the voltage dividing points of the voltage dividing resistors 46 and 48 . The rating determination block 72 turns on/off the load switch 56 based on the comparison result. For example, the rating determination block 72 turns off the load switch 56 when the rated power of the AC adapter 42 is greater than the rated power of the USB power supply 54, and turns on the load switch 56 otherwise.

When the load switch 56 is on, a power supply path is formed from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52, and when the load switch 56 is off, a power supply path is formed from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52. is interrupted.

[Operation of power supply control circuit]
FIG. 3 shows an example of power supply negotiation initiated when the USB power supply 54 is connected to the USB Type-C connector 26 . When the USB power supply 54 is connected to the USB Type-C connector 26, the USB PD controller 62 and the USB PD controller 64 are connected to each other via the CC1 and CC2 lines.

First, the USB PD controller 62 on the source side provides PD information consisting of information indicating what kind of device the USB power supply 54 is and information indicating the power (voltage/current) that the USB power supply 54 can supply to the VBUS pin. to the USB PD controller 64 (#12). The voltage/current that can be supplied is not limited to a fixed value, but may be a variable value, and not limited to a single voltage/current combination, but may be a combination of multiple voltages/currents. The USB PD controller 64 requests the required voltage/current combination from the USB PD controller 62 (#14). If the required voltage/current combination is not included in the PD information, the voltage/current combination with the highest power among the voltage/current combinations included in the PD information may be requested, or nothing may be requested. You don't have to ask.

USB PD controller 62 returns a signal to USB PD controller 64 confirming the requested voltage/current combination (#16). Power according to the requested voltage/current combination is then supplied to the PC 10 via the VBUS pin. The USB PD controller 64 stores in the memory 65 the PD information indicating the voltage/current combination that has been affirmed by the USB PD controller 62 (#18).

FIG. 4 is a flowchart showing an example of power control by the EC 66. As shown in FIG. The processing of the flowchart of FIG. 4 is performed before power is supplied from the AC adapter 42 or the USB power supply 54, and the power for this processing is supplied from the battery 68.
The rating determination block 72 turns on the load switch 56 at block 102 . Thereby, a power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 via the load switch 56 and the diode 58 is formed. Assume that the AC adapter 42 is then connected to the power connector 24 and/or the USB power supply 54 is connected to the USB Type-C connector 26 . Assume that when the USB power supply 54 is connected to the USB Type-C connector 26 , the negotiation shown in FIG. 3 is also completed and the PD information is stored in memory 65 within the USB PD controller 64 .

A voltage equal to or greater than the first threshold is applied from the AC adapter 42 to the cathode of the diode 44 and/or from the USB power supply 54 to the cathode of the diode 58 via the load switch 56 . The charger circuit 52 always determines whether the input voltage is equal to or higher than the first threshold voltage, and if the input voltage is equal to or higher than the first threshold voltage, the connection detection signal supplied to the EC 66 is set to high level. .

Therefore, the rating determination block 72 determines in block 104 whether or not the connection detection signal is at a high level. When the connection detection signal is low level (determination of No in block 104), it can be determined that the AC adapter 42 is not connected to the power connector 24 and the USB power supply 54 is not connected to the USB Type-C connector 26 either. If the rating determination block 72 determines that the connection detection signal is at low level, it repeatedly executes the determination of block 104 .

If the connection detection signal is high (determination of block 104 is Yes), it is determined that the AC adapter 42 is connected to the power connector 24 and/or the USB power supply 54 is connected to the USB Type-C connector 26. can. However, only with the connection detection signal, whether the AC adapter 42 is connected to the power connector 24, whether the USB power supply 54 is connected to the USB Type-C connector 26, or whether the AC adapter 42 is connected to the power connector 24 and the USB It cannot be determined whether the power supply 54 is connected to the USB Type-C connector 26 or not. EC 66 then identifies these three states based on other information.

When the AC adapter 42 is connected to the power connector 24, the voltage at the connection point of the voltage dividing resistors 46 and 48 becomes equal to or higher than the second threshold voltage. The second threshold voltage can be predetermined based on the rated voltage of AC adapter 42 . For example, if the rated voltage of the AC adapter 42 is 19V, the second threshold voltage can be 17V.

Therefore, the A/D conversion block 74 A/D converts the voltage at the connection point of the voltage dividing resistors 46 and 48 in block 106 and supplies the A/D conversion result to the rating determination block 72 . The rating determination block 74 determines in block 112 whether the A/D conversion result is 17 V (second threshold voltage) or higher. If the A/D conversion result is not 17V or more (if the determination in block 112 is No), the AC adapter 42 is not connected to the power connector 24, but the USB power supply 54 is connected to the USB Type-C connector 26. can be judged. In this case, the rating determination block 72 keeps the load switch 56 on. As a result, the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 via the load switch 56 and the diode 58 is maintained, the output voltage of the USB power supply 54 is applied to the charger circuit 52, and the system power supply of the PC 10 is supplied. is generated.

If the A/D conversion result is 17V or more (if the determination in block 112 is Yes), is the AC adapter 42 connected to the power connector 24, or is the USB power supply 54 connected to the USB Type-C connector 26? It can be judged that it is unclear whether or not In this case, to determine if the USB power supply 54 is connected to the USB Type-C connector 26, the PD information read block 70 reads the PD information stored in the memory 65 within the USB PD controller 64 at block 114. Determine whether or not

If the PD information is not stored in the memory 65 within the USB PD controller 64 (determination of block 114 is No), the AC adapter 42 is connected to the power connector 24, but the USB power source 54 is connected to the USB Type-C connector. 26 is not connected. In this case, the output voltage of the AC adapter 42 is applied to the charger circuit 52 to generate system power for the PC 10 . The rating determination block 72 may turn off the load switch 56 at block 126 or keep the load switch 56 on because the USB power supply 54 is not connected to the USB Type-C connector 26 .

Thus, when one of the AC adapter 42 and the USB power supply 54 is connected to the power connector 24 or the USB Type-C connector 26, power is supplied from the connected device.
Next, power supply when the AC adapter 42 is connected to the power connector 24 and the USB power supply 54 is connected to the USB Type-C connector 26 will be described.

When PD information is stored in memory 65 in USB PD controller 64 (determination in block 114 is Yes), AC adapter 42 is connected to power connector 24 and USB power source 54 is connected to USB Type-C connector 26. can be determined to be connected. In this case, the PD information read block 70 reads the PD information from the memory 65 within the USB PD controller 64 at block 116 . The PD information read block 70 recognizes the rated power (rated voltage, rated current) of the USB power supply 54 based on the read PD information in block 118 .

The execution order of the processing of block 112 and the processing of blocks 114, 116, and 118 may be reversed. That is, blocks 106, 114, 116, 118, and 112 may be executed in order.
The rating determination block 72 determines at block 122 whether the rated voltage of the AC adapter 42 is higher than the rated voltage of the USB power supply 54 . Since the cathode of the diode 44 and the cathode of the diode 58 are commonly connected to the input terminal of the charger circuit 52, the higher one of the cathode voltages of the diodes 44 and 58 is applied to the input terminal of the charger circuit 52. voltage is applied.

Therefore, when the rated voltage of the AC adapter 42 is higher than the rated voltage of the USB power supply 54 (when the determination in block 122 is Yes), the output voltage of the AC adapter 42 is applied to the charger circuit 52 and the system power of the PC 10 is generated. be. At this time, the rating determination block 72 keeps the load switch 56 on. As a result, when the AC adapter 42 is removed from the state in which the AC adapter 42 and the USB power supply 54 are connected, power is instantly supplied from the USB power supply 54 .

If the rated voltage of the AC adapter 42 is not higher than the rated voltage of the USB power supply 54 (determination in block 122 is No), the rating determination block 72 determines in block 124 that the power rating of the AC adapter 42 is equal to the power rating of the USB power supply 54 . Determine whether it is smaller than the power. The rated power of the AC adapter 42 is, for example, 45 W (fixed value).

If the rated power of the AC adapter 42 is less than the rated power of the USB power supply 54 (Yes in block 124 ), it can be determined that the USB power supply 54 is preferable to the AC adapter 42 . Therefore, the rating determination block 72 keeps the load switch 56 on. As a result, the output voltage of the USB power supply 54 is applied to the charger circuit 52 and the system power supply of the PC 10 is generated.

If the power rating of the AC adapter 42 is not less than the power rating of the USB power supply 54 (determination in block 124 is No), it can be determined that using the AC adapter 42 is preferable to using the USB power supply 54 . Therefore, in block 126 , the rating determination block 72 turns off the load switch 56 to cut off the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 via the load switch 56 and the diode 58 . As a result, the output voltage of the AC adapter 42, which has a low rated voltage but a high rated power, is applied to the charger circuit 52, and the system power supply of the PC 10 is generated.

When the AC adapter 42 or the USB power supply 54 is removed from the power connector 24 or the USB Type-C connector 26, the rating determination block 72 turns on the load switch 56. FIG.
As described above, according to the first embodiment, when the AC adapter 42 and the USB power supply 54 are connected to the power connector 24 and the USB Type-C connector 26, respectively, the rated voltage and rated power of both are compared. Power can be supplied to the PC 10 from the most suitable device based on. For example, if the rated voltage of the AC adapter 42 is higher than the rated voltage of the USB power supply 54, the power from the AC adapter 42 is supplied to the PC 10 regardless of the magnitude of the rated power. At this time, the load switch 56 for conducting/disconnecting the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 is turned on, but it may be turned off. If the rated voltage of the USB power supply 54 is higher than the rated voltage of the AC adapter 42 and the rated power of the USB power supply 54 is higher than the rated power of the AC adapter 42 , the power from the USB power supply 54 is supplied to the PC 10 . At this time, the load switch 56 for conducting/disconnecting the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 is turned on. Even if the rated voltage of the USB power supply 54 is higher than the rated voltage of the AC adapter 42 , if the rated power of the AC adapter 42 is higher than the rated power of the USB power supply 54 , the power from the AC adapter 42 is supplied to the PC 10 . At this time, the load switch 56 for conducting/disconnecting the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 is turned off.

As described above, according to the first embodiment, the power connector 24 and the USB Type-C connector 26 are connected to the charger circuit 52 so that the charger circuit 52 is supplied with power from a device with a higher voltage among the plurality of power devices. is connected, but if the rated power of the AC adapter 42 is higher than the rated voltage of the AC adapter 42, the load switch 56 is turned off, and power is supplied from the USB Type-C connector 26 to the charger circuit 52. The path is cut off and power is supplied from the AC adapter 42 . Therefore, sufficient power is supplied to the PC 10, and it is possible to charge the battery 68 while supplying system power.

[Second embodiment]
FIG. 5 is a circuit diagram showing an example of the power control circuit of the PC 10 of the second embodiment. In the first embodiment shown in FIG. 2, one USB Type-C connector 26 is provided. Two USB Type-C connectors 26-1 and 26-2 are provided for connection to the PC 10. FIG.

The VBUS pins of USB Type-C connectors 26-1 and 26-2 are connected to the anodes of diodes 58-1 and 58-2 via load switches 56-1 and 56-2, respectively.
The cathodes of diodes 58 - 1 and 58 - 2 are connected to the input terminal of charger circuit 52 together with the cathode of diode 44 .

The USB power supplies 54-1 and 54-2 are provided with USB PD controllers 62-1 and 62-2, respectively. USB PD controllers 62-1 and 62-2 are provided with memories 63-1 and 63-2 for storing information, respectively.
The PD information read block 70 is connected to the USB PD controllers 64-1 and 64-2 via the SM bus, and reads PD information from the memories 65-1 and 65-2 of the USB PD controllers 64-1 and 64-2.

The rating determination block 72 turns on/off the load switches 56-1 and 56-2. When the load switch 56-1 is off, the power supply path from the VBUS terminal of the USB Type-C connector 26-1 to the charger circuit 52 is cut off. When the load switch 56-2 is off, the power supply path from the VBUS terminal of the USB Type-C connector 26-2 to the charger circuit 52 is cut off.

6, 7, and 8 are flowcharts showing an example of power control by the EC 66 of the second embodiment. 6 to 8 are also performed before power is supplied from the AC adapter 42 or the USB power supply 54, and the power for this process is supplied from the battery 68. FIG.

The rating determination block 72 turns on the load switches 56-1 and 56-2 in block 202 (FIG. 6). Thereby, two power supply paths are formed from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 via the load switches 56-1, 56-2 and the diodes 58-1, 58-2. After this, the AC adapter 42 is connected to the power connector 24 and/or the USB power supplies 54-1, 54-2 are connected to the USB Type-C connectors 26-1, 26-2, completing the negotiation shown in FIG. Assume that the PD information of the USB power supplies 54-1 and 54-2 is stored in the memories 65-1 and 65-2 in the USB PD controllers 64-1 and 64-2, respectively.

The rating determination block 72 determines at block 204 whether the connection detection signal is high. The rating determination block 72 repeats the determination of block 204 when the connection detection signal is at low level.
If the connection detection signal is at a high level (if the determination in block 204 is Yes), the A/D conversion block 74 A/D converts the voltage at the connection point of the voltage dividing resistors 46 and 48 in block 206, The A/D conversion result is supplied to the rating discrimination block 72 . The PD information read block 70 reads the PD information from the memories 65-1, 65-2 in the USB PD controllers 64-1, 64-2 at block 208. FIG. In block 210, the PD information read block 70 recognizes the rated power (rated voltage, rated current) of the USB power supplies 54-1 and 54-2 based on the read PD information. The recognition result is supplied to rating determination block 72 . Note that if the USB power supplies 54-1 and 54-2 are not connected to the USB Type-C connectors 26-1 and 26-2, the rated power of the USB power supplies 54-1 and 54-2 are not recognized.

The rating determination block 72 determines in block 216 whether the A/D conversion result is greater than or equal to 17V (second threshold voltage). If the A/D conversion result is not 17V or higher (if the determination in block 216 is No), the AC adapter 42 is not connected to the power connector 24, but the USB power supplies 54-1 and/or 54-2 are USBType- It can be determined that they are connected to the C connectors 26-1 and/or 26-2. In this case, rating determination block 72 performs the processing of block 242 (FIG. 7).

If the A/D conversion result is 17 V or more (the determination in block 216 is Yes), the rating determination block 72 determines in block 218 whether or not the USB power supply 54-1 has been recognized. When the USB power supply 54-1 is not recognized (when the determination in block 218 is No), it can be determined that the AC adapter 42 and the USB power supply 54-2 are connected, and the rating determination block 72 changes to block 262 (FIG. 8). process.

If USB power source 54-1 is recognized (determination of block 218 is Yes), rating determination block 72 determines at block 220 whether USB power source 54-2 is recognized. When the USB power supply 54-2 is not recognized (when the determination of block 220 is No), it can be determined that the AC adapter 42 and the USB power supply 54-1 are connected, and the rating determination block 72 executes the processing of block 224. do.

Note that the execution order of the processing of blocks 216, 218, and 220 is not limited to this, and may be executed in any order.
When the USB power supply 54-2 is recognized (when the determination in block 220 is Yes), it can be determined that the AC adapter 42 and the USB power supplies 54-1 and 54-2 are connected, and the rating determination block 72 At 222, it is determined whether the power rating of USB power supply 54-1 is greater than the power rating of USB power supply 54-2.

If the power rating of USB power supply 54-1 is not greater than the power rating of USB power supply 54-2 (determination in block 222 is No), rating determination block 72 executes the process of block 262 (FIG. 8).
If the rated power of the USB power supply 54-1 is greater than the rated power of the USB power supply 54-2 (determination in block 222 is Yes), or if the USB power supply 54-2 is not recognized (determination in block 220 is No) ), the rating determination block 72 determines in block 224 whether or not the rated voltage of the AC adapter 42 is higher than the rated voltage of the USB power supply 54-1, as in the first embodiment. When the rated voltage of the AC adapter 42 is higher than the rated voltage of the USB power supply 54-1 (when the determination in block 224 is Yes), the output voltage of the AC adapter 42 is applied to the charger circuit 52 to generate system power for the PC 10. be. At this time, the rating determination block 72 keeps the load switches 56-1 and 56-2 on. As a result, when the AC adapter 42 is removed from the state in which the AC adapter 42 and the USB power sources 54-1 and 54-2 are connected, power is instantaneously supplied from the USB power source 54-1 or 54-2.

If the rated voltage of the AC adapter 42 is not higher than the rated voltage of the USB power supply 54-1 (determination of block 224 is No), the rating determination block 72 proceeds to block 226 where the rated power of the AC adapter 42 is higher than the USB power supply 54-1. Determine whether or not the rated power is less than -1.

If the rated power of the AC adapter 42 is less than the rated power of the USB power supply 54-1 (determination in block 226 is Yes), it can be determined that the use of the USB power supply 54-1 is preferable to the use of the AC adapter 42. Therefore, the rating determination block 72 keeps the load switches 56-1 and 56-2 on. As a result, the output voltage of the USB power supply 54-1 is applied to the charger circuit 52, and the system power supply of the PC 10 is generated.

If the rated power of the AC adapter 42 is not less than the rated power of the USB power supply 54-1 (determination in block 226 is No), it can be determined that using the AC adapter 42 is preferable to using the USB power supply 54-1. Therefore, the rating determination block 72 turns off the load switches 56-1 and 56-2 in block 228, and the VBUS terminals of the USB Type-C connectors 26-1 and 26-2 are connected to the load switches 56-1, 56-2, 56-2, and 56-2. The two power supply paths to charger circuit 52 via diodes 58-1 and 58-2 are cut off. As a result, the output voltage of the AC adapter 42 is applied to the charger circuit 52 to generate system power for the PC 10 . Note that the rating determination block 72 may keep the load switch 56-2 on because the USB power supply 54-2 is not connected to the USB Type-C connector 26-2.

If it is determined in block 216 that the A/D conversion result is not 17 V or higher (determination of No), the AC adapter 42 is not connected to the power connector 24, but the USB power supplies 54-1 and/or 54-2 are USBType. -C connectors 26-1 and/or 26-2. In this case, the rating determination block 72 determines whether or not the USB power supply 54-1 is recognized in block 242 shown in FIG. If the USB power supply 54-1 is not recognized (determination in block 242 is No), it can be determined that only the USB power supply 54-2 is connected, and the rating determination block 72, in block 250, determines the load switch 56-1. to cut off the power supply path from the VBUS terminal of the USB Type-C connector 26-1 to the charger circuit 52 via the load switch 56-1 and the diode 58-1. As a result, the output voltage of the USB power supply 54-2 is applied to the charger circuit 52, and the system power supply of the PC 10 is generated.

If USB power supply 54-1 is recognized (determination of block 242 is Yes), rating determination block 72 determines in block 244 whether USB power supply 54-2 is recognized. If the USB power supply 54-2 is not recognized (determination of block 244 is No), it can be determined that only the USB power supply 54-1 is connected, and the rating determination block 72, in block 248, determines the load switch 56-2. to cut off the power supply path from the VBUS terminal of the USB Type-C connector 26-2 to the charger circuit 52 via the load switch 56-2 and the diode 58-2. As a result, the output voltage of the USB power supply 54-1 is applied to the charger circuit 52, and the system power supply of the PC 10 is generated.

When the USB power supply 54-2 is recognized (when the determination in block 244 is Yes), it can be determined that the USB power supplies 54-1 and 54-2 are connected, and the rating determination block 72 determines in block 245 whether the USB It is determined whether or not the rated voltage of the power supply 54-1 is higher than the rated voltage of the USB power supply 54-2.

If the rated voltage of the USB power supply 54-1 is higher than the rated voltage of the USB power supply 54-2 (determination in block 245 is Yes), it is preferable to use the USB power supply 54-1 rather than the USB power supply 54-2. I can judge. Therefore, rating determination block 72 performs the processing of block 248 . As a result, the output voltage of the USB power supply 54-1 is applied to the charger circuit 52, and the system power supply of the PC 10 is generated.

If the rated voltage of USB power supply 54-1 is not higher than the rated voltage of USB power supply 54-2 (determination of block 245 is No), rating determination block 72, in block 246, determines the power rating of USB power supply 54-1. is greater than the rated power of the USB power supply 54-2.

If the power rating of the USB power supply 54-1 is not greater than the power rating of the USB power supply 54-2 (determination of block 246 is No), the rating determination block 72 executes the processing of block 250. FIG. As a result, the output voltage of the USB power supply 54-2 is applied to the charger circuit 52, and the system power supply of the PC 10 is generated. If the power rating of the USB power supply 54-1 is greater than the power rating of the USB power supply 54-2 (determination of block 246 is Yes), the rating determination block 72 executes the process of block 248. FIG. As a result, the output voltage of the USB power supply 54-1 is applied to the charger circuit 52, and the system power supply of the PC 10 is generated.

If it is determined in block 218 of FIG. 6 that the USB power supply 54-1 is not recognized, it can be determined that the AC adapter 42 and the USB power supply 54-2 are connected, and the rating determination block 72 performs block 262 (FIG. 8). process.
If the rated power of the USB power supply 54-1 is not greater than the rated power of the USB power supply 54-2 in block 222 of FIG. Run. The rating determination block 72 determines in block 262 whether the rated voltage of the AC adapter 42 is higher than the rated voltage of the USB power supply 54-2. When the rated voltage of the AC adapter 42 is higher than the rated voltage of the USB power supply 54-2 (when the determination in block 262 is Yes), the output voltage of the AC adapter 42 is applied to the charger circuit 52 to generate system power for the PC 10. be. At this time, the rating determination block 72 keeps the load switches 56-1 and 56-2 on. Thus, when the AC adapter 42 is removed from the state in which the AC adapter 42 and the USB power supply 54-1 or 54-2 are connected, power is instantly supplied from the USB power supply 54-1 or 54-2.

If the rated voltage of the AC adapter 42 is not higher than the rated voltage of the USB power supply 54-2 (determination in block 262 is No), the rating determination block 72 determines in block 264 that the rated power of the AC adapter 42 is higher than that of the USB power supply 54-2. It is determined whether or not it is less than the rated power of -2.

If the rated power of the AC adapter 42 is less than the rated power of the USB power supply 54-2 (determination in block 264 is Yes), it can be determined that the use of the USB power supply 54-2 is preferable to the use of the AC adapter 42. Therefore, the rating determination block 72 keeps the load switches 56-1 and 56-2 on. Note that the rating determination block 72 may turn off the load switch 56-1. As a result, the output voltage of the USB power supply 54-2 is applied to the charger circuit 52, and the system power supply of the PC 10 is generated.

If the power rating of the AC adapter 42 is not less than the power rating of the USB power supply 54-2 (determination in block 264 is No), it can be determined that the AC adapter 42 is preferable to using the USB power supply 54-2. Therefore, in block 286, the rating determination block 72 turns off the load switches 56-1 and 56-2, and the VBUS terminals of the USB Type-C connectors 26-1 and 26-2 are connected to the load switches 56-1, 56-2, 56-2, and 56-2. The two power supply paths to charger circuit 52 via diodes 58-1 and 58-2 are cut off. As a result, the output voltage of the AC adapter 42 is applied to the charger circuit 52 to generate system power for the PC 10 . Note that the rating determination block 72 may keep the load switch 56-1 on.

As described above, according to the second embodiment, the AC adapter 42 and the USB power sources 54-1 and 54-2 are connected to the power connector 24 and the USB Type-C connectors 26-1 and 26-2, respectively. In this case, power can be supplied to the PC 10 from the optimum device based on the results of comparing the rated voltages and rated powers of the three devices. For example, if the rated voltage of the AC adapter 42 is higher than the rated voltages of the USB power supplies 54-1 and 54-2, the power from the AC adapter 42 is supplied to the PC 10 regardless of the magnitude of the rated power. At this time, the load switches 56-1 and 65-2 for conducting/disconnecting the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 are turned on, but they may be turned off. If the rated voltage of the USB power supply 54-1 or 54-2 is higher than the rated voltage of the AC adapter 42, if the rated power of the USB power supply 54-1 or 54-2 is higher than the rated power of the AC adapter 42, the USB power supply 54- Power is supplied to the PC 10 from 1 or 54-2. At this time, the load switches 56-1 and 56-2 for conducting/disconnecting the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 are turned on. Even if the rated voltage of the USB power supply 54-1 or 54-2 is higher than the rated voltage of the AC adapter 42, if the rated power of the USB power supply 54-1 or 54-2 is lower than the rated power of the AC adapter 42, the rated voltage is Electric power is supplied to the PC 10 from the AC adapter 42 having a low but high rated power. At this time, the load switches 56-1 and 56-2 for conducting/disconnecting the power supply path from the VBUS terminal of the USB Type-C connector 26 to the charger circuit 52 are turned off.

According to the second embodiment as well, when the USB power supply 54 having a lower rated power than the AC adapter 42 is connected, the load switch 56 is turned off, and the power supply path from the USB Type-C connector 26 to the charger circuit 52 is cut off. The power is supplied from the AC adapter 42, and the battery 68 can be charged while supplying the system power.

It should be noted that the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying constituent elements without departing from the scope of the present invention at the implementation stage. Also, various inventions can be formed by appropriate combinations of the plurality of constituent elements disclosed in the above embodiments. For example, some components may be omitted from all components shown in the embodiments. Furthermore, constituent elements of different embodiments may be combined as appropriate. For example, power supply devices other than the AC adapter 42 are not limited to USB power sources, and may be devices connected to connectors other than USB Type-C connectors.

24...Power supply connector 26...USB Type-C connector 42...AC adapter 54...USB power supply 56...Load switch 64...USB PD controller 65...Memory 66...EC 70...PD information read block 72 ... rating discrimination block, 74 ... A/D conversion block.

Claims (12)

a first power supply terminal to which the first power supply can be connected;
a first detection means for detecting that the first power supply is connected to the first power supply terminal;
at least one second power supply terminal to which at least one second power supply can be connected;
second detection means for detecting that the at least one second power supply is connected to the at least one second power supply terminal;
The first detection means detects that the first power supply is connected to the first power supply terminal, and the second detection means detects that the at least one second power supply is connected to the at least one second power supply terminal. When the detection means detects, the rated voltage of the first power supply is not higher than the rated voltage of the at least one second power supply and the rated power of the first power supply is not lower than the rated power of the at least one second power supply. control means for interrupting the power supply path of the at least one second power supply terminal so that power is supplied from the first power supply when the power is supplied from the first power supply;
An electronic device comprising The control means controls the power of the at least one second power supply terminal such that power from the first power supply is supplied when the rated voltage of the first power supply is higher than the rated voltage of the at least one second power supply. 2. The electronic device according to claim 1, wherein the supply path is interrupted. When the rated voltage of the first power supply is not higher than the rated voltage of the at least one second power supply and the rated power of the first power supply is lower than the rated power of the at least one second power supply, the control means controls the 2. The electronic device according to claim 1, wherein the power supply path of said at least one second power supply terminal is conductive so that power is supplied from at least one second power supply. the at least one second power supply terminal is a plurality of second power supply terminals to which a plurality of second power supplies can be connected;
The control means detects that the first power supply is not connected to the first power supply terminal by the first detection means, and that the plurality of second power supplies are connected to the plurality of second power supply terminals. 2. The electronic device according to claim 1, wherein the power supply path of the plurality of second power supply terminals is selectively cut off based on the rated voltage and rated power of the plurality of second power supplies when the second detection means detects machine. The first detection means detects whether or not the first power supply is connected to the first power supply terminal based on the voltage of the first power supply terminal,
The second detection means detects whether or not the at least one second power supply is capable of supplying power from the at least one second power supply via the second power supply terminal based on the presence or absence of information indicating the power supply capability of the at least one second power supply. 2. The electronic device according to claim 1, which detects whether or not it is connected to the second power terminal. further comprising a power supply circuit that generates a system power supply for the electronic device;
2. The electronic device according to claim 1, wherein said first power terminal and said second power terminal are commonly connected to an input terminal of said power circuit. a rechargeable battery and
a charger that charges the battery,
2. The electronic device according to claim 1, wherein said first power terminal and said second power terminal are commonly connected to an input terminal of said charger. a first power supply terminal to which the first power supply can be connected;
a first detection means for detecting that the first power supply is connected to the first power supply terminal;
at least one second power supply terminal to which at least one second power supply can be connected;
second detection means for detecting that the at least one second power supply is connected to the at least one second power supply terminal;
In an electronic device comprising
The first detection means detects that the first power supply is connected to the first power supply terminal, and the second detection means detects that the at least one second power supply is connected to the at least one second power supply terminal. When the detection means detects, the rated voltage of the first power supply is not higher than the rated voltage of the at least one second power supply and the rated power of the first power supply is not lower than the rated power of the at least one second power supply. case, the power supply control method for interrupting the power supply path of the at least one second power supply terminal so that power is supplied from the first power supply. If the rated voltage of the first power supply is higher than the rated voltage of the at least one second power supply, cut off the power supply path of the at least one second power supply terminal so that the power from the first power supply is supplied. 9. The power control method according to claim 8 . If the rated voltage of the first power supply is not higher than the rated voltage of the at least one second power supply and the rated power of the first power supply is less than the rated power of the at least one second power supply, the at least one second power supply 9. The power supply control method according to claim 8 , wherein the power supply path of said at least one second power supply terminal is turned on so that power from a power supply is supplied. the at least one second power supply terminal is a plurality of second power supply terminals to which a plurality of second power supplies can be connected;
The first detection means detects that the first power supply is not connected to the first power supply terminal, and the second detection means that the plurality of second power supplies are connected to the plurality of second power supply terminals. 9. The power supply control method according to claim 8 , wherein when the means detects, the power supply paths of the plurality of second power supply terminals are selectively cut off based on the rated voltage and rated power of the plurality of second power supplies. The first detection means detects whether or not the first power supply is connected to the first power supply terminal based on the voltage of the first power supply terminal,
The second detection means detects whether or not the at least one second power supply is capable of supplying power from the at least one second power supply via the second power supply terminal based on the presence or absence of information indicating the power supply capability of the at least one second power supply. 9. The power control method according to claim 8 , further comprising detecting whether or not the second power terminal is connected.

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