JP2019040239A - Electronic apparatus, electronic system and power supply control method - Google Patents

Abstract

To provide an electronic apparatus, an electronic system and a power supply method in which a size of a connector is reduced.SOLUTION: A power supply 191 supplies power to a docking station in a state where a tablet type PC is physically connected to the docking station. A GND and detection terminal 121 connects to a ground terminal 221 connected to a ground 231 of the docking station when the tablet type PC is connected to the docking station. A power supply for detection 192 is connected to the GND and detection terminal 121. An EC 102 monitors a voltage of the GND and detection terminal 121, and when detecting change of a predetermined voltage, starts supplying power to the docking station from the power supply 191.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an electronic device, an electronic system, and a power supply control method.

  In recent years, smart phones and tablet PCs (Personal Computers) that have been widely used are often small and thin devices that are supposed to be carried. Since the casing is small, many of such portable terminal devices have few external interfaces such as for USB (Universal System Bus) and video system signals mounted on the main body.

  In such a portable terminal device, an external interface is often added by connecting the portable terminal device to a function expansion device such as a cradle or a docking station. When connecting a portable terminal device and a function expansion device, it is common to connect using a dedicated connector for connection. However, since the portable terminal device is required to be as small as possible, it is preferable that the connector is also small.

  Here, when the portable terminal device and the function expansion device are physically connected, if electricity flows through the connector terminal before the physical connection, a spark is generated when both terminals approach each other. The terminal may corrode. Various functions are assigned to the connector terminal of the portable terminal device, such as a function expansion device detection signal or an I / F signal such as USB. If any contact failure occurs due to corrosion in any terminal, the function expansion device does not operate normally. Therefore, in order to reduce the corrosion of the terminal due to the spark, electricity is applied to the pins after the physical connection is completed. As a technology for determining whether or not the physical connection is completed, a signal terminal used for communication between the portable terminal device and the function expansion device, a power source used for both power supply and reception, and a GND (Ground) terminal are different. There is a technique for determining the completion of connection based on the presence or absence of physical connection of the connection detection terminal.

  Here, as a technology for controlling power supply between the portable terminal device and the function expansion device, there is a conventional technology for stopping power supply to the electronic device when the electronic device is not connected. In addition, there is a conventional technique in which connection is determined by a magnetic sensor and power supply is started. In addition, there is a conventional technique in which a connection path is switched to be connected to ground in a no-signal state, and a cable disconnection is detected based on a detected voltage level. Furthermore, there is a conventional technique for determining a connection relationship by detecting that a dedicated electrode is in contact with or adjacent to a connector plug when connected.

Japanese Patent Laid-Open No. 05-66858 JP 2009-157877 A JP 2000-193700 A JP 2009-211838 A

  However, when a connection detection terminal is provided as in the prior art, the size of the connector is increased by that terminal. As described above, when the connection detection terminals are used, it is difficult to reduce the number of terminals to be physically connected.

  In addition, even if the conventional technology for stopping the power supply to the electronic device when the electronic device is not connected is used, the connection detection terminal is used, and it is difficult to reduce the number of terminals to be physically connected. Become. This is a conventional technology that determines the connection by a magnetic sensor and starts power supply, a conventional technology that detects cable disconnection based on the detected voltage level, and detects that a dedicated electrode is in contact or adjacent when a connector plug is connected. The same applies to the conventional technique for determining the connection relationship.

  The disclosed technology has been made in view of the above, and an object thereof is to provide an electronic device, an electronic system, and a power supply control method with a reduced connector size.

  In one aspect of the electronic device, the electronic system, and the power supply control method disclosed in the present application, the power supply supplies power to the other electronic device in a state where the power supply is physically connected to the other electronic device. When the device is physically connected to the other electronic device, the connection terminal is connected to a ground terminal connected to a first ground included in the other electronic device. The power source for detection is connected to the connection terminal. The switching unit monitors the voltage of the connection terminal, and starts power supply from the power source to the other electronic device when detecting a change in a predetermined voltage.

  In one aspect, the present invention can reduce the connector size.

FIG. 1 is a diagram for explaining the configuration of the electronic system according to the embodiment. FIG. 2 is a hardware configuration diagram of the tablet PC and the docking station. FIG. 3 is a diagram for explaining a connection state of the connection connector according to the embodiment. FIG. 4 is a circuit diagram for explaining connection detection and power supply control by the tablet PC according to the embodiment. FIG. 5 is a flowchart of connection detection and power supply processing. FIG. 6 is a flowchart of the power supply stop process at the time of removal. FIG. 7 is a circuit diagram for realizing a connection detection function on the tablet PC side when both are provided with a connection detection mechanism. FIG. 8 is a circuit diagram for realizing a connection detection function on the docking station side when both are provided with a connection detection mechanism. FIG. 9 is a diagram illustrating an example of connection of a connector for connection using pogo pins.

  Embodiments of an electronic device, an electronic system, and a power supply control method disclosed in the present application will be described below in detail with reference to the drawings. The following embodiments do not limit the electronic device, the electronic system, and the power supply control method disclosed in the present application.

  FIG. 1 is a diagram for explaining the configuration of the electronic system according to the embodiment. As shown in FIG. 1, the electronic system according to the present embodiment includes a tablet PC 1 and a docking station 2. The tablet PC 1 is an example of “electronic device” and “first electronic device”. The docking station 2 is an example of “another electronic device” and “second electronic device”.

  The tablet PC 1 and the docking station 2 can be physically connected. When the tablet PC 1 and the docking station 2 are physically connected, the state 3 is obtained. In the state 3, the tablet PC 1 can use the function of the docking station 2. Hereinafter, the connection between the tablet PC 1 and the docking station 2 is referred to as “physical connection”.

  FIG. 2 is a hardware configuration diagram of the tablet PC and the docking station. In FIG. 2, the power supply path and the control signal transmission path are shown in a mixed state. The tablet PC 1 and the docking station 2 are connected to an AC (Alternating Current) adapter 4 and receive power supply from the connected AC adapter 4. In the present embodiment, a case where power is supplied from the tablet PC 1 to the docking station 2 will be described as an example.

  The tablet PC 1 is a waterproof computer. The tablet PC 1 includes an MR (Magneto Resistance) sensor 101, an EC (Embedded Controller) 102, a battery 103, an AC connector 104, a CPU (Central Processing Unit) 105, a liquid crystal display 106, and a touch panel 107. Further, the tablet PC 1 includes a charger IC (Integrated Circuit) 108, a power supply circuit 109, a RAM (Random Access Memory) 110, an auxiliary storage device 111, a connector for connection 112, an interface wireless IC 113, and a magnet 114. This interface wireless IC 113 is an example of a “wireless communication unit”.

  The MR sensor 101 is one of magnetic sensors. Although the MR sensor 101 is used here, other magnetic sensors may be used.

  The MR sensor 101 is connected to the EC 102 and the power supply circuit 109 via a bus. The MR sensor 101 detects the magnet 202 of the docking station 2 when the tablet PC 1 approaches the docking station 2. Then, the MR sensor 101 outputs a signal notifying the detection of the magnet 202 to the EC 102 and the power supply circuit 109. In addition, when the tablet PC 1 is detached from the docking station 2, the MR sensor 101 detects that the magnet 202 is not detected. Then, the MR sensor 101 sends a signal notifying the non-detection of the magnet 202 to the EC 102 and the power supply circuit 109.

  As shown in FIG. 2, the EC 102 is connected to the MR sensor 101, the battery 103, the charger IC 108, and the power supply circuit 109 via a bus. The EC 102 communicates with the battery 103 and the charger IC 108 using a serial signal. The EC 102 communicates with the power supply circuit 109 using a GPIO (General Purpose Input Output) signal or the like.

  Further, when the tablet PC 1 and the docking station 2 are physically connected, the EC 102 receives the magnet 202 detection notification from the MR sensor 101 and temporarily stops the power supply from the power supply circuit 109. Thereafter, the EC 102 monitors the voltage of the GND combined detection terminal for detecting the physical connection, and starts supplying power from the power supply circuit 109 to the docking station 2 when a change in a predetermined voltage is detected. Further, the EC 102 connects the GND combined detection terminal to the ground of the own device, and matches the ground of the own device and the ground of the docking station 2. The EC 102 is an example of a “switching unit”. The power supply control by the EC 102 will be described in detail later.

  Further, when removing the tablet PC 1 from the docking station 2, the power supply circuit 109 receives a notification that the magnet 202 is not detected from the MR sensor 101 and stops the power supply from the power supply circuit 109 to the docking station 2.

  The battery 103 is charged by the charger IC 108 using the electric power sent from the power supply circuit 109. The battery 103 supplies power to the power supply circuit 109 when it is a power source.

  The charger IC 108 receives a notification of the setting for performing charging from the EC 102. Then, the charger IC 108 charges the battery 103 according to the notified setting.

  The CPU 105 reads out various programs stored in the auxiliary storage device 111, develops them in the RAM 110, and executes arithmetic processing. The RAM 110 is a main storage device and serves as a data storage location when the CPU 105 executes arithmetic processing. The auxiliary storage device 111 is, for example, a hard disk. The auxiliary storage device 111 stores various programs.

  The liquid crystal display 106 is a display device. The liquid crystal display 106 displays a calculation result by the CPU 105 and the like. The touch panel 107 receives input of information designated on the liquid crystal display 106. Then, the touch panel 107 outputs the input information to the CPU 105.

  That is, the CPU 105, the liquid crystal display 106, the touch panel 107, the RAM 110, and the auxiliary storage device 111 constitute a system for realizing various functions such as arithmetic processing in the tablet PC 1. The tablet PC 1 may include other various devices for realizing other functions. Hereinafter, the CPU 105, the liquid crystal display 106, the touch panel 107, the RAM 110, and the auxiliary storage device 111 may be collectively referred to as a “terminal device system”.

  The power supply circuit 109 is connected to the EC 102, the battery 103, the AC connector 104, the charger IC 108, the connection connector 112, and the interface wireless IC 113 through a power supply path. The power supply circuit 109 is connected to the CPU 105, the liquid crystal display 106, the touch panel 107, the RAM 110, and the auxiliary storage device 111 through a power supply path. The power supply circuit 109 receives power from the AC adapter 4 when the AC adapter 4 is connected to the AC connector 104 and the power supply is the AC adapter 4. When the power source is the battery 103, the power source circuit 109 receives power from the battery 103. When receiving power supply from the docking station 2, the power supply circuit 109 receives power supply from the power supply circuit 205 of the docking station 2 via the connection connector 112 and the connection connector 203 of the docking station 2.

  In addition, the power supply circuit 109 receives an instruction from the EC 102 for a power supply direction and a power supply for supplying power. Then, the power supply circuit 109 creates a power supply type used by each device mounted on the tablet PC 1 using the power supplied from the instructed power supply. When the power supply direction is the direction from the tablet PC 1 to the docking station 2, the power supply circuit 109 creates a power supply type to be supplied to the docking station 2 using the power supplied from the power supply.

  The power supply circuit 109 supplies, for example, the power supply type created using the power supplied from the power supply to the EC 102, the charger IC 108, and the terminal device system. When power is supplied to the docking station 2, the power supply circuit 109 supplies the generated power supply type to the power supply circuit 205 of the docking station 2 via the connection connector 112 and the connection connector 203 of the docking station 2.

  In addition, when the tablet PC 1 is physically connected to the docking station 2, the power supply circuit 109 receives a notification of detection of the magnet 202 from the MR sensor 101 and starts supplying power from the detection power supply 192 to the GND combined detection terminal. To do.

  The magnet 114 does not have the MR sensor in the docking station 2 according to the present embodiment. However, when the tablet PC 1 approaches the external device when physically connected to the external device having another MR sensor, the external device It is detected by the MR sensor. In addition, when the tablet PC 1 is removed from the external device having the MR sensor, the external device is separated and is not detected by the MR sensor of the external device.

  The connection connector 112 is a connection part that connects a terminal of the tablet PC 1 and a terminal of the docking station 2 when the tablet PC 1 and the docking station 2 are physically connected. The tablet PC 1 according to this embodiment is waterproof, and the signal terminal is wireless. Therefore, the connector 112 has a power terminal 122 and a GND combined detection terminal 121 as shown in FIG. This GND combined detection terminal 121 is an example of a “connection terminal”. FIG. 3 is a diagram for explaining a connection state of the connection connector according to the embodiment. The connection connector 112 supplies the power supplied from the power supply circuit 109 to the docking station 2 using the GND combined detection terminal 121 and the power supply terminal 122.

  The connection connector 112 further includes an interface wireless IC 113. In FIG. 2, the connection connector 112 and the interface wireless IC 113 are described separately for easy understanding, but actually, the interface wireless IC 113 is accommodated in the connection connector 112.

  The interface wireless IC 113 is a circuit for transmitting / receiving a signal such as a USB signal to / from the docking station 2 by wireless communication.

  The docking station 2 includes an external display interface 201, a magnet 202, a connector for connection 203, an interface wireless IC 204, and a power supply circuit 205. Furthermore, the docking station 2 includes a LAN (Local Area Network) interface 206, a USB interface 207, an AC connector 208, an EC 209, and a photo sensor 210.

  The external display interface 201 is an interface for connecting an image display device such as a monitor or a liquid crystal display. The LAN interface 206 is an interface for connecting to a network. The USB interface 207 is an interface for connecting a USB device. The external display interface 201, the LAN interface 206, and the USB interface 207 all operate with the power supplied from the power supply circuit 205.

  The magnet 202 is detected by the MR sensor 101 of the tablet PC 1 when the docking station 2 approaches when the tablet PC 1 is physically connected to the docking station 2. Further, when the tablet PC 1 is removed when the tablet PC 1 is removed from the docking station 2, the MR sensor 101 of the tablet PC 1 is not detected.

  The connection connector 203 is a connection unit that connects the terminals of the tablet PC 1 and the terminals of the docking station 2 when the tablet PC 1 and the docking station 2 are physically connected. As shown in FIG. 3, the connection connector 203 has a power supply terminal 222 and a ground terminal 221. The connection connector 203 supplies the power supplied from the tablet PC 1 to the power circuit 205 using the power terminal 222 and the ground terminal 221.

  The connection connector 203 further includes an interface wireless IC 204. In FIG. 2, the connection connector 203 and the interface wireless IC 204 are separately illustrated for easy understanding. However, the interface wireless IC 204 is actually accommodated in the connection connector 203.

  The interface wireless IC 204 is a circuit for transmitting / receiving a signal such as a USB signal to / from the interface wireless IC 113 of the tablet PC 1 by wireless communication.

  The power supply circuit 205 is connected to the EC 209, the connection connector 203, and the interface wireless IC 204 through a power supply path. The power supply circuit 205 is connected to the external display interface 201, the LAN interface 206, and the USB interface 207 through a power supply path. The power supply circuit 205 receives power supply from the AC adapter 4 when the AC adapter 4 is connected to the AC connector 208 and the power supply is the AC adapter 4. When receiving power from the tablet PC 1, the power circuit 205 receives power from the power circuit 109 of the tablet PC 1 via the connection connector 203 and the connection connector 112 of the tablet PC 1.

  In addition, the power supply circuit 205 receives from the EC 209 an instruction of a power supply direction and a power supply for supplying power. Then, the power supply circuit 205 creates a power supply type used by each device mounted on the docking station 2 using the power supplied from the instructed power supply. When the power supply direction is the direction from the docking station 2 to the tablet PC 1, the power supply circuit 205 creates a power supply type to be supplied to the tablet PC 1 using the power supplied from the power supply.

  The power supply circuit 205 supplies, for example, the power source created using the power supplied from the power supply to the EC 209, the external display interface 201, the LAN interface 206, and the USB interface 207. When power is supplied to the tablet PC 1, the power circuit 205 supplies the generated power source type to the power circuit 109 of the tablet PC 1 through the connection connector 203 and the connection connector 112 of the tablet PC 1.

  The EC 209 is connected to the photosensor 210 and the power supply circuit 205 via a bus. The EC 209 communicates with the power supply circuit 205 using a GPIO signal or the like.

  Further, when supplying power from the docking station 2 to the tablet PC 1, the EC 209 performs the same control as the power supply control by the EC 102 of the tablet PC 1 described later.

  The photo sensor 210 is an interface for performing infrared communication or the like. The photo sensor 210 outputs the received signal to the EC 209. In addition, the photo sensor 210 sends a transmission signal instructed from the EC 209 to the outside.

  Here, with reference to FIG. 3, the connection of the connectors 112 and 203 for connection is demonstrated. A state 31 in FIG. 3 is a state before the connection connector 112 and the connection connector 203 are connected. The state 32 is a state after the connection connector 112 and the connection connector 203 are connected.

  In the state 31, the power supply terminal 222 and the ground terminal 221 in the connection connector 203 are pushed outward by the force of a spring arranged inside the connection connector 203. Further, the interface wireless IC 113 and the interface wireless IC 204 are not communicated because they are separated from each other by a communicable distance.

  When the connector for connection 112 and the connector for connection 203 come close to each other for physical connection, the power terminal 122 and the power terminal 222 come into contact with each other. Further, the GND shared detection terminal 121 and the ground terminal 221 come into contact with each other. When the connecting connector 112 further approaches the connecting connector 203 from this state, the power terminal 222 is pushed by the power terminal 122 and sinks into the connecting connector 203. The ground terminal 221 is pushed by the GND combined detection terminal 121 and sinks into the connection connector 203. When the physical connection is completed, the connection connector 112 and the connection connector 203 are in a state represented by state 32. In the state 32, the power terminal 122 and the power terminal 222 are in contact with each other, the GND combined detection terminal 121 and the ground terminal 221 are in contact with each other, and the interface wireless IC 113 and the interface wireless IC 204 perform wireless communication.

  Next, connection detection and power supply control by the tablet PC according to the present embodiment will be described with reference to FIG. FIG. 4 is a circuit diagram for explaining connection detection and power supply control by the tablet PC according to the embodiment.

  A power source 191 and a power source for detection 192 exist on the tablet PC 1 side. The power supply 191 and the detection power supply 192 are power supplies that use the power supply type generated by the power supply circuit 109. The power source 191 has a voltage of 5V, for example. The detection power source 192 has a voltage of 3.3 V, for example.

  The detection power source 192 is connected to the GND combined detection terminal 121 via the resistor 132. The resistor 132 has a resistance value of 10 kΩ, for example. Further, an FET (Field Effect Transistor) switch is disposed between the detection power source 192 and the resistor 132. The gate of the FET switch 131 is connected to the MR sensor 101.

  Furthermore, the path between the resistor 132 and the GND combined detection terminal 121 is branched and connected to the system ground 134 via the FET switch 133. The gate of the FET switch 133 is connected to the EC102. This system ground 134 is an example of a “second ground”.

  Further, the path between the resistor 132 and the GND combined use detection terminal 121 is branched at a point closer to the GND combined use detection terminal 121 than the point connected to the system ground 134 and connected to the EC 102. A path extending from the path connecting the detection power source 192 and the GND shared detection terminal 121 to the GND shared detection terminal 121 is branched halfway and connected to the ground 136 via the resistor 135. The resistor 135 has a resistance value of 100 kΩ, for example.

  The power supply 191 is connected to the load 139 and the power supply terminal 122 of the tablet PC 1 via the diode 137. Further, an FET switch 138 is disposed between the power source 191 and the diode 137. The gate of FET switch 138 is connected to EC102.

  On the other hand, on the docking station 2 side, the ground terminal 221 is connected to the ground 231. The ground 231 corresponds to an example of “first ground”. The power terminal 222 is connected to the load 232 of the docking station 2. The load 232 is, for example, the external display interface 201.

  Next, the operation of each unit when the tablet PC 1 is physically connected to the docking station 2 will be described. In the state before physical connection, the FET switch 133 is off. The FET switch 138 is also off.

  When the tablet PC 1 approaches the docking station 2, the MR sensor 101 detects the magnet 202. The MR sensor 101 then outputs a signal indicating that the magnet 202 has been detected to the EC 102 and the gate of the FET switch 131. The FET switch 131 is turned on upon receiving a signal input from the MR sensor 101.

  When the FET switch 131 is turned on, the voltage of the detection power source 192 is supplied to the GND combined detection terminal 121. In this state, the EC 102 receives a voltage divided by the resistors 132 and 135 of the voltage output from the detection power source 192. When the resistor 132 is 10 kΩ, the resistor 135 is 100 kΩ, and the voltage value of the detection power source 192 is 3.3 V, the EC 102 receives a voltage of 3 V. If the EC 102 detects a voltage of 3V, the EC switch 138 maintains the FET switch 138 in an off state. In this case, since the FET switch 138 is in an off state, the power output from the power supply 191 is not supplied to the load 139 and the power supply terminal 122. The FET switch 131 is an example of a “switch”.

  Thereafter, when the tablet PC 1 further approaches the docking station 2, the GND combined detection terminal 121 is connected to the ground terminal 221, and the power supply terminal 122 is connected to the power supply terminal 222.

  The detection power supply 192 is connected to the ground 231 through the resistor 132 by connecting the GND combined detection terminal 121 to the ground terminal 221. Thereby, the voltage of the path connected to the GND combined detection terminal 121 falls to the voltage of the ground 231. When the EC 102 detects that the voltage of the path connected to the GND combined detection terminal 121 has dropped to the voltage of the ground 231 and the signal has changed from High to Low, the power supply terminal 122 and the power supply terminal 222 are physically connected. judge. Then, the EC 102 applies a voltage to the FET switch 133 to turn it on. Further, the EC 102 applies a voltage to the FET switch 138 to turn it on. Here, the detection that the voltage of the path connected to the GND shared detection terminal 121 has dropped to the voltage of the ground 231 and the signal has changed from High to Low corresponds to an example of “detection of a change in a predetermined voltage”.

  When the FET switch 133 is turned on, the ground 231 and the system ground 134 are connected, and the system ground 134 of the tablet PC 1 and the ground 231 of the docking station 2 coincide. Thus, the GND combined detection terminal 121 serves as a ground terminal.

  When the FET switch 138 is turned on, supply of the power output from the power supply 191 to the load 139 and the power supply terminal 122 is started. In this case, since the connection between the power supply terminal 122 and the power supply terminal 222 has already been completed, no spark is generated between the power supply terminal 122 and the power supply terminal 222. Since the power supply terminal 122 and the power supply terminal 222 are connected, the power supplied from the power supply 191 to the power supply terminal 122 is supplied to the load 232 of the docking station 2.

  Next, with reference to FIG. 5, the flow of processing for connection detection and power supply when the tablet PC 1 is physically connected to the docking station 2 will be described. FIG. 5 is a flowchart of connection detection and power supply processing.

  The MR sensor 101 determines whether or not the magnet 202 has been detected (step S1). When the magnet 202 is not detected (No at Step S <b> 1), the MR sensor 101 stands by until the magnet 202 is detected.

  On the other hand, when the magnet 202 is detected (step S1: affirmative), the MR sensor 101 connects the detection power source 192 to the GND combined detection terminal 121 by applying a voltage to the FET switch 131 to turn it on. (Step S2).

  The EC 102 monitors the voltage of the GND combined detection terminal 121 (step S3). Then, the EC 102 determines whether or not the voltage of the GND combined detection terminal 121 has transitioned from High to Low (Step S4). When the transition of the voltage of the GND combined detection terminal 121 from High to Low has not occurred (No at Step S4), the EC 102 returns to Step S3.

  On the other hand, when the voltage of the GND combined detection terminal 121 transits from High to Low (Step S4: Yes), the EC 102 determines that there is a physical contact between the power terminal 122 and the power terminal 222 (Step S4). S5).

  Then, the EC 102 applies a voltage to the FET switch 133 to turn on the FET switch 133, thereby connecting the GND combined detection terminal 121 and the system ground 134 (step S6).

  Thereafter, the EC 102 applies a voltage to the FET switch 138 to turn it on, thereby starting supply of the power output from the power source 191 to the docking station 2 (step S7).

  Next, with reference to FIG. 6, the flow of the process of stopping the power supply when the tablet PC 1 is removed from the docking station 2 will be described. FIG. 6 is a flowchart of the power supply stop process at the time of removal.

  The EC 102 monitors the input from the MR sensor 101 (step S11). Then, the EC 102 determines whether or not the MR sensor 101 is in a non-detection state of the magnet 202 (step S12). When the detection of the magnet 202 by the MR sensor 101 is continued (No at Step S12), the EC 102 returns to Step S11.

  On the other hand, when the MR sensor 101 is in the non-detection state of the magnet 202 (step S12: Yes), the EC 102 determines that the tablet PC 1 has been removed from the docking station 2 (step S13).

  Thereafter, the EC 102 stops applying the voltage to the FET switch 138 and turns off the FET switch 138, thereby stopping the supply of the power output from the power source 191 to the docking station 2 (step S14).

  Furthermore, the EC 102 stops applying the voltage to the FET switch 133 and turns off the FET switch 133, thereby disconnecting the GND combined detection terminal 121 and the system ground 134 (step S15).

  As described above, in the electronic system according to the present embodiment, the physical connection is determined according to the change in the voltage of one GND combined detection terminal having the role of the connection detection terminal and the ground terminal, and the connection Later, the GND shared detection terminal is connected to the system ground. As a result, one terminal can serve as both a connection detection terminal and a ground terminal, the number of terminals can be reduced, and the connector size can be kept small. And since electric power supply is started after the connection of power supply terminals is completed, generation | occurrence | production of a spark can be suppressed and corrosion can be reduced.

  In particular, in a waterproof portable terminal device, a connection connector called a pogo pin that performs physical contact using a spring may be used as a dedicated connection connector. Furthermore, the waterproof portable terminal device is assumed to be used around water such as a bath or kitchen. When the portable terminal device is physically connected to the function expansion device in a wet state, corrosion of the terminal due to energization causes more serious damage. For this reason, the waterproof portable terminal device keeps the minimum terminals that are difficult to remove, such as the power supply terminal and the GND terminal, and avoids pin corrosion by making wireless the majority of other signal communications. Techniques to do this have been proposed. In such a waterproof information processing apparatus, the occurrence of corrosion can be reduced if there is no connection detection terminal. However, it is difficult to make the connection detection terminal wireless. Therefore, as in the present embodiment, grounding and connection detection are performed on one terminal, so that the physical connection can be reliably detected with the number of terminals required for power supply. Thereby, a connector size can also be restrained small. Furthermore, power can be supplied after the physical connection has been reliably completed, and even the waterproof portable terminal device can reduce the occurrence of corrosion.

(Modification)
In the above description, the physical connection is detected on the tablet PC 1 side. However, when power is supplied from the docking station 2 to the tablet PC 1, the physical connection is detected on the docking station 2 side. You can also.

  FIG. 7 is a circuit diagram for realizing a connection detection function on the tablet PC side when both are provided with a connection detection mechanism. FIG. 8 is a circuit diagram for realizing a connection detection function on the docking station side when both are provided with a connection detection mechanism. 7 and 8, an outline of the circuit is described, and detailed portions not used for description are omitted.

  Any of the tablet PC 1 and the docking station 2 according to this modification can detect connection. That is, the power supply side of the tablet PC 1 and the docking station 2 detects connection and starts power supply.

  The tablet PC 1 according to this modification includes a ground terminal 124 shown in FIG. 7 and a ground terminal 125 shown in FIG. 8 in addition to the GND combined detection terminal 121 and the power supply terminal 222 shown in FIG. The docking station 2 according to the present modification includes a ground terminal 224 shown in FIG. 7 and a GND combined detection terminal 225 shown in FIG. 8 in addition to the ground terminal 221.

  The docking station 2 has the same configuration as the configuration for detecting connection and starting power supply in the tablet PC 1. For example, a path connecting the detection power source 251 and the GND combined detection terminal 225 to the EC 209 is branched and connected to the ground 243 via the resistor 242. In addition, although omitted in FIG. 8, the docking station 2 has switches similar to the FET switches 131, 133, and 138 and other configurations.

  The ground terminal 124 is connected to the load 139 and the system ground 141. The ground terminal 224 is connected to the load 232 and the ground 241. At the time of connection, the ground terminal 124 and the ground terminal 224 are connected so that the system ground 141 and the ground 241 coincide with each other.

  As described above, by providing the ground terminals 124 and 224, the system ground 141 and the ground 241 are matched at the time of physical connection before the physical connection is detected and the operation of matching both the grounds is performed. And at least one point can match the ground.

  When power is supplied from the tablet PC 1 to the docking station 2, the EC 102 shown in FIG. Then, it is determined that the physical connection is completed, and power supply is started.

  On the other hand, when power is supplied from the docking station 2 to the tablet PC 1, the detection power source 251 receives a voltage input from the GND combined detection terminal 225 as shown in FIG. In this state, the EC 209 is disconnected from the ground 244 and detects the divided voltage of the voltage output from the detection power supply 251. When the GND combined detection terminal 225 is connected to the ground terminal 125, the output path of the detection power supply 251 is connected to the system ground 142. Therefore, the voltage of the GND combined detection terminal 225 falls to the voltage of the system ground 142 connected to the ground terminal 125.

  The EC 209 determines that the physical connection is completed when the voltage of the GND combined detection terminal 225 drops to the voltage of the system ground 142 to which the ground terminal 125 is connected. Then, the EC 209 instructs the power supply circuit 205 of the docking station 2 to supply power to the tablet PC 1. Further, the EC 209 connects the ground 244 to a path connecting the detection power source 251 and the GND combined detection terminal 225. As a result, the ground 244 and the system ground 142 coincide with each other, and the GND combined detection terminal 225 serves as a ground terminal.

  In this modification, one ground terminal set called ground terminals 124 and 224 is provided in addition to the GND combined detection terminals 121 and 225. However, the number is not particularly limited. However, if the number of grounding terminal groups other than the GND combined detection terminals 121 and 225 is increased, the ground can be surely secured, but the size of the connecting connector is increased. Therefore, it is preferable to determine the number of ground terminal sets according to the required degree of securing the ground and the size of the connector for connection.

  As described above, the connection detection and power supply start mechanism described in the embodiments can be mounted not only on the information processing apparatus side but also on an attached device. As a result, the power supply can be started after the physical connection is completed, and the size of the connector for connection can be reduced, regardless of where the power is supplied. Moreover, even if it is a case where electric power supply is performed from which, the corrosion of a terminal can be reduced.

  Furthermore, in the present embodiment, the waterproof tablet PC 1 has been described as an example. However, even with other electronic devices, the same mechanism can be installed to reduce the size of the connector for connection and to corrode the terminals. Mitigation can be achieved.

  For example, FIG. 9 is a diagram illustrating an example of connection of a connector for connection using pogo pins. The connection connectors 112 and 203 shown in FIG. 9 are not wireless. That is, the terminals 126 and 226 of the connection connectors 112 and 203 include terminals for transmitting and receiving signals in addition to the power supply terminals. The state 33 is a state before connection, and the state 34 is a state after connection.

  In the state 33, the terminal 226 is pushed outward from the connection connector 203 by a spring. In the state 34, the terminal 226 is pushed by the terminal 126 and sinks into the connection connector 203, and the connection between the connection connector 112 and the connection connector 203 is completed.

  Also in this case, for example, if any one of the ground terminals in the terminal 126 is used as the GND combined detection terminal 121 and has the same configuration as that of the first embodiment shown in FIG. The power connection can be started after the physical connection is completed.

  Furthermore, FIG. 9 shows the case where pogo pins are used, but even if a normal fixed terminal is used in addition to this, power supply is started after the physical connection is completed by using the same configuration. can do.

  Thus, if the connection connector has a ground terminal, the same configuration as in the first embodiment is used regardless of the shape of the connection connector, so that the power supply can be started after the physical connection is completed, and corrosion is caused. The connector size can be reduced while suppressing this.

1 Tablet PC
2 Docking station 101 MR sensor 102 EC
103 battery 104 AC connector 105 CPU
106 Liquid crystal display 107 Touch panel 108 Charger IC
109 Power supply circuit 110 RAM
111 Auxiliary storage device 112 Connector for connection 113 Interface wireless IC
114 Magnet 201 External display interface 202 Magnet 203 Connector 204 Interface wireless IC
205 Power supply circuit 206 LAN interface 207 USB interface 208 AC connector 209 EC
210 Photosensor

Claims (6)

A power supply for supplying power to the other electronic device in a state where the device is physically connected to the other electronic device;
When the device itself is physically connected to the other electronic device, a connection terminal connected to a ground terminal connected to the first ground of the other electronic device;
A power supply for detection connected to the connection terminal;
An electronic device comprising: a switching unit that monitors the voltage of the connection terminal and starts power supply from the power source to the other electronic device when a change in a predetermined voltage is detected.   When the switching unit detects a change in the predetermined voltage, the switching unit connects a path for supplying power output from the power source to a load of the other electronic device, and the connection terminal is connected to the own device. 2. The power supply from the power source to the other electronic device is started by connecting the first ground and the second ground to each other and connecting to the second ground. Electronic equipment. A magnetic sensor;
The electronic apparatus according to claim 1, further comprising: a switch that connects the detection power source and the connection terminal with a signal transmitted from the magnetic sensor.   The electronic device according to claim 1, further comprising a wireless communication unit that transmits and receives signals other than power supply to and from the other electronic device using a wireless signal. . An electronic system having a first electronic device and a second electronic device,
The first electronic device is
A power supply for supplying power to the second electronic device in a state in which the device is physically connected to the second electronic device;
When the device is physically connected to the second electronic device, a connection terminal connected to a ground terminal connected to the first ground of the second electronic device;
A power supply for detection connected to the connection terminal;
An electronic system comprising: a switching unit that monitors a voltage of the connection terminal and detects power supply from the power source to the second electronic device when a change in a predetermined voltage is detected. Connected to a power source for supplying power to the other electronic device in a state physically connected to the other electronic device, and to a first ground of the other electronic device when physically connected to the other electronic device. A power supply control method in an electronic device having a connection terminal connected to the ground terminal and a power supply for detection connected to the connection terminal,
Monitoring the voltage of the connection terminal;
A power supply control method characterized by starting power supply from the power supply to the other electronic device when a change in a predetermined voltage is detected.

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