JP2016226080A - Electronic apparatus, charger, and electronic apparatus system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology capable of simplifying a configuration of an electronic apparatus.SOLUTION: An electronic apparatus comprises: at least one connection terminal for connecting the electronic apparatus with a charger; a first battery that is charged by the charger; a battery capacity acquisition unit for acquiring first battery capacity of the first battery, on the basis of a first output voltage of the first battery; and a display unit for displaying the first battery capacity. The charger comprises a second battery and a boosting circuit for boosting a second output voltage of the second battery to generate a boosting voltage, and charges the first battery on the basis of the boosting voltage. The at least one connection terminal includes a shared terminal shared by use for inputting the second output voltage and other use. The battery capacity acquisition unit acquires second battery capacity of the second battery on the basis of the second output voltage input to the shared terminal. The display unit displays the first battery capacity and second battery capacity.SELECTED DRAWING: Figure 12

Description

  The present invention relates to an electronic device.

  As described in Patent Document 1, various techniques have been proposed for electronic devices.

JP 2008-131812 A

  It is desired that the configuration of the electronic device be simplified.

  Therefore, the present invention has been made in view of the above-described points, and an object thereof is to provide a technique capable of simplifying the configuration of an electronic device.

  An electronic device, a charger, and an electronic device system are disclosed. In one embodiment, the electronic device is based on at least one connection terminal for connecting the electronic device to a charger, a first battery charged by the charger, and a first output voltage of the first battery. The battery capacity acquisition part which calculates | requires the 1st battery capacity of a 1st battery, and the display part which displays a 1st battery capacity are provided. The charger includes a second battery and a booster circuit that boosts the second output voltage of the second battery to generate a boosted voltage, and charges the first battery based on the boosted voltage. The at least one connection terminal includes a dual-purpose terminal that is used for inputting the second output voltage and for other purposes. The battery capacity acquisition unit obtains the second battery capacity of the second battery based on the second output voltage input to the shared terminal. The display unit displays the first and second battery capacities.

  Moreover, in one embodiment, a charger is a charger which charges the 1st battery which an electronic device has. The charger includes a plurality of connection terminals for connecting the charger to an electronic device, a second battery, and a booster circuit that boosts the output voltage of the second battery to generate a boosted voltage. The plurality of connection terminals include a first connection terminal that outputs a boosted voltage and a second connection terminal that is pulled up to the output voltage. The voltage level of the second connection terminal is input to the booster circuit as a control signal for controlling the output of the booster circuit. The electronic device includes third and fourth connection terminals connected to the first and second connection terminals, respectively. The electronic device charges the first battery based on the boosted voltage input from the third connection terminal, and controls the state of the fourth connection terminal. When the electronic device sets the fourth connection terminal to the high impedance state, an output voltage is output from the second connection terminal.

  Moreover, in one embodiment, a charger is a charger which charges the 1st battery which an electronic device has. The charger includes a plurality of connection terminals for connecting the charger to an electronic device, a second battery, and a booster circuit that boosts the output voltage of the second battery to generate a boosted voltage. The plurality of connection terminals include first and second connection terminals. A control signal for controlling the output of the booster circuit, which is output from the electronic device, is input to the second connection terminal. The charger further includes a selection unit that selects one of the boost voltage and the output voltage based on the control signal and outputs the selected voltage to the first connection terminal. The electronic device charges the first battery based on the boosted voltage input to the first connection terminal.

  In one embodiment, an electronic device system includes an electronic device and a charger. The electronic device includes a first battery based on at least one connection terminal for connecting the electronic device to the charger, a first battery charged by the charger, and a first output voltage of the first battery. A battery capacity obtaining unit for obtaining the battery capacity and a display unit for displaying the first battery capacity are provided. The charger includes a second battery and a booster circuit that boosts the second output voltage of the second battery to generate a boosted voltage. The charger charges the first battery based on the boosted voltage. The at least one connection terminal includes a dual-purpose terminal that is used for inputting the second output voltage and for other purposes. The battery capacity acquisition unit obtains the second battery capacity of the second battery based on the second output voltage input to the shared terminal. The display unit displays the first and second battery capacities.

  In one embodiment, an electronic device system is provided with the electronic device which has the 1st battery, and the charger which charges the 1st battery. The charger includes a plurality of connection terminals for connecting the charger to an electronic device, a second battery, and a booster circuit that boosts the output voltage of the second battery to generate a boosted voltage. The plurality of connection terminals include a first connection terminal that outputs a boosted voltage and a second connection terminal that is pulled up to the output voltage. The voltage level of the second connection terminal is input to the booster circuit as a control signal for controlling the output of the booster circuit. The electronic device includes third and fourth connection terminals connected to the first and second connection terminals, respectively. The electronic device charges the first battery based on the boosted voltage input from the third connection terminal, and controls the state of the fourth connection terminal. When the electronic device sets the fourth connection terminal to the high impedance state, an output voltage is output from the second connection terminal.

  In one embodiment, an electronic device system is provided with the electronic device which has the 1st battery, and the charger which charges the 1st battery. The charger includes a plurality of connection terminals for connecting the charger to an electronic device, a second battery, and a booster circuit that boosts the output voltage of the second battery to generate a boosted voltage. The plurality of connection terminals include first and second connection terminals. A control signal for controlling the output of the booster circuit, which is output from the electronic device, is input to the second connection terminal. The charger further includes a selection unit that selects one of the boost voltage and the output voltage based on the control signal and outputs the selected voltage to the first connection terminal. The electronic device charges the first battery based on the boosted voltage input to the first connection terminal.

  The configuration of the electronic device can be simplified.

It is a rear view which shows the external appearance of an electronic device system. It is a side view which shows the external appearance of an electronic device system. It is a front view which shows the external appearance of an electronic device. It is a rear view which shows the external appearance of an electronic device. It is a side view which shows the external appearance of an electronic device. It is a side view which shows the external appearance of an electronic device. It is a front view which shows the external appearance of a charger. It is a rear view which shows the external appearance of a charger. It is a side view which shows the external appearance of a charger. It is a block diagram which shows the structure of an electronic device. It is a block diagram which shows the structure of a charger. It is a block diagram which shows the structure of the power supply part and control part of an electronic device. It is a flowchart which shows operation | movement of an electronic device. It is a flowchart which shows operation | movement of an electronic device. It is a figure which shows the example of a display of battery capacity. It is a figure which shows the example of a display of battery capacity. It is a block diagram which shows the structure of a charger. It is a block diagram which shows the structure of the power supply part and control part of an electronic device. It is a flowchart which shows operation | movement of an electronic device.

Embodiment 1 FIG.
<Appearance of electronic device system>
1 and 2 are views showing an appearance of the electronic device system 1 according to the first embodiment. As shown in FIGS. 1 and 2, the electronic device system 1 includes an electronic device 2 and a charger 3 that can be attached to and detached from the electronic device 2. The charger 3 is also called “jacket 3”. The electronic device 2 is, for example, a mobile phone such as a smartphone. 1 and 2 show an electronic device 2 to which a charger 3 is attached. The charger 3 is attached to the back surface 2b side of the electronic device 2, for example. FIG. 1 shows an electronic device 2 to which a charger 3 is attached from the back surface 2b side. FIG. 2 shows the electronic device 2 to which the charger 3 is attached as viewed from the direction of arrow A in FIG.

  The charger 3 can charge a battery included in the electronic device 2. The battery charger 3 is provided with a battery. The charger 3 charges the battery of the electronic device 2 by supplying the power of its own battery to the electronic device 2. Hereinafter, the electronic device 2 to which the charger 3 is attached may be referred to as “electronic device 2 with charger”.

<Appearance of electronic equipment>
FIG. 3 is a front view showing the appearance of the electronic device 2. FIG. 4 is a rear view showing the appearance of the electronic device 2. FIG. 5 is a side view showing the external appearance of the electronic device 2 when viewed from the direction of arrow B in FIG. FIG. 6 is a side view showing an appearance of the electronic device 2 when viewed from an arrow C in FIG.

  As shown in FIGS. 1 to 6, the electronic device 2 includes a plate-shaped device case 20 that is substantially rectangular in plan view. On the front surface 2 a of the electronic device 2, that is, on the front surface of the device case 20, a display area 21 on which various information such as characters, symbols, and figures is displayed is provided. A touch panel 240 described later is attached to the back surface or the front surface of the display area 21. Thereby, the user can input various information to the electronic device 2 by operating the display area 21 of the front surface 2a of the electronic device 2 with a finger or the like. Note that the user can also input various kinds of information to the electronic device 2 by operating the display area 21 with an operator other than a finger, for example, an electrostatic touch panel pen such as a stylus pen.

  A microphone hole 23 and a receiver hole 22 are respectively provided at the lower end and the upper end of the front surface of the device case 20. From the upper end of the front surface of the device case 20, an imaging lens 281 included in a front-side imaging unit 280, which will be described later, is visible. Further, as shown in FIG. 6, a USB (Universal Serial Bus) connector 206 is provided on the lower side surface 2 d of the device case 20. A USB cable is connected to the USB connector 206. An external voltage (external power) is supplied to the USB connector 206 from an AC adapter or the like via a USB cable. The electronic device 2 can charge the battery not only with the power supplied from the charger 3 but also with an external voltage supplied to the USB connector 206.

  As shown in FIGS. 1 and 4, a speaker hole 24 is provided on the back surface 2 b of the electronic device 2, that is, on the back surface of the device case 20. From the back surface of the device case 20, an imaging lens 291 included in a back surface side imaging unit 290 described later is visible. Further, a connection terminal group 207 including a plurality of connection terminals 207 z for connecting the electronic device 2 to the charger 3 is provided on the back surface of the device case 20. Each connection terminal 207z is made of a conductive material such as metal. When the charger 3 is attached to the electronic device 2, the connection terminal group 207 comes into contact with a connection terminal group 307 described later provided on the charger 3. Thereby, the electronic device 2 and the charger 3 are electrically connected. The connection terminal group 207 may be composed of at least one connection terminal 207z.

<Appearance of charger>
7 to 9 are views showing the appearance of the charger 3. 7 shows the charger 3 when viewed from the outer side surface 3a, and FIG. 8 shows the charger 3 when viewed from the inner side surface 3b. FIG. 9 shows the charger 3 as viewed from the direction of arrow D in FIG.

  As shown in FIGS. 1, 2, and 7 to 9, the charger 3 has a shallow dish shape in which the inner surface 3b is slightly recessed. The charger 3 has a shape in which the central portions of the upper, lower, left, and right sides of the rectangle with rounded corners are recessed in plan view.

  In the charger 3, four holding portions 31 to 34 extend from the four corners of the central portion 30. The charger 3 is attached to the electronic device 2 by the four holding portions 31 to 34 holding the corners of the four corners of the electronic device 2 (device case 20). As shown in FIG. 1, the holding units 31, 32, 33, and 34 are the upper left corner, upper right corner, lower left corner, and lower right corner of the electronic device 2 when the electronic device 2 is viewed from the back surface 2 b side. Hold each. For example, the four holding portions 31 to 34 hold the corner portions at the four corners by fitting the claw portions provided on the inside thereof with the concave portions provided at the corner portions at the four corners of the device case 20. To do.

  As shown in FIG. 8, a connection terminal group 307 including a plurality of connection terminals 307 z for connecting the charger 3 to the electronic device 2 is provided at the lower end portion of the inner side surface of the central portion 30. . Each connection terminal 307z is made of a conductive material such as metal. When the charger 3 is attached to the electronic device 2, the plurality of connection terminals 307 z of the charger 3 come into contact with the plurality of connection terminals 207 z of the electronic device 2, respectively. The connection terminal group 307 may include at least one connection terminal 307z.

  As shown in FIGS. 2 and 9, a USB connector 306 is provided on the curved outer surface 3 a of the charger 3. Specifically, a USB connector 306 is provided on the outer surface of the holding unit 34 of the charger 3. A USB cable is connected to the USB connector 306. In the electronic device 2 with a charger, a USB cable can be connected to the USB connector 306 from the side. An external voltage is supplied to the USB connector 306 from an AC adapter or the like via a USB cable. The charger 3 can charge its own battery with an external voltage supplied to the USB connector 306.

<Electrical configuration of electronic equipment>
FIG. 10 is a block diagram mainly showing an electrical configuration of the electronic apparatus 2. As shown in FIG. 10, the electronic device 2 includes a power supply unit 200, a control unit 210, a wireless communication unit 220, a display panel 230, and a touch panel 240. Further, the electronic device 2 is provided with a microphone 250, a receiver 260, an external speaker 270, a front side imaging unit 280, and a back side imaging unit 290. These components provided in the electronic device 2 are housed in the device case 20.

  The control unit 210 is a control circuit including a CPU (Central Processing Unit) 211, a DSP (Digital Signal Processor) 212, a storage unit 213, and the like. The control unit 210 comprehensively manages the operation of the electronic device 2 by controlling other components of the electronic device 2.

  The storage unit 213 is configured by a non-transitory recording medium that can be read by the control unit 210 (the CPU 211 and the DSP 212), such as a ROM (Read Only Memory) and a RAM (Random Access Memory). The storage unit 213 stores various programs for controlling the operation of the electronic device 2, specifically, the respective components such as the wireless communication unit 220 and the display panel 230 provided in the electronic device 2. Various functions of the control unit 210 are realized by the CPU 211 and the DSP 212 executing various programs in the storage unit 213. Note that the storage unit 213 may include a computer-readable non-transitory recording medium other than the ROM and RAM. The storage unit 213 may include, for example, a small hard disk drive and an SSD (Solid State Drive).

  The wireless communication unit 220 has an antenna 221. The wireless communication unit 220 receives a signal from a mobile phone different from the electronic device 2 or a signal from a communication device such as a web server connected to the Internet via an antenna 221 via a base station or the like. Radio communication unit 220 performs amplification processing and down-conversion on the received signal and outputs the result to control unit 210. The control unit 210 performs demodulation processing or the like on the input reception signal, and acquires a sound signal indicating voice or music included in the reception signal. The wireless communication unit 220 performs up-conversion and amplification processing on the transmission signal including the sound signal generated by the control unit 210 and wirelessly transmits the processed transmission signal from the antenna 221. A transmission signal from the antenna 221 is received through a base station or the like by a mobile phone different from the electronic device 2 or a communication device connected to the Internet.

  The display panel 230 is, for example, a liquid crystal display panel or an organic EL panel. The display panel 230 displays various types of information such as characters, symbols, and figures under the control of the control unit 210. The display panel 230 is disposed facing the display area 21 in the device case 20. Information displayed on the display panel 230 is displayed in the display area 21.

  The touch panel 240 detects an operation with an operator such as a finger on the display area 21. The touch panel 240 is, for example, a projected capacitive touch panel, and is attached to the back surface of the display area 21. When the user operates the display area 21 with an operator such as a finger, an electrical signal corresponding to the operation is input from the touch panel 240 to the control unit 210. Based on the electrical signal from the touch panel 240, the control unit 210 identifies the content of the operation performed on the display area 21, and performs processing according to the content.

  The microphone 250 converts sound input from the outside of the electronic device 2 into an electrical sound signal and outputs the electrical sound signal to the control unit 210. Sound from the outside of the electronic device 2 is taken into the electronic device 2 through the microphone hole 23 and input to the microphone 250.

  The external speaker 270 is, for example, a dynamic speaker. The external speaker 270 converts the electrical sound signal from the control unit 210 into sound and outputs the sound. Sound output from the external speaker 270 is output from the speaker hole 24 to the outside. The sound output from the speaker hole 24 can be heard at a place away from the electronic device 2.

  The receiver 260 outputs a received sound. The receiver 260 is composed of, for example, a dynamic speaker. The receiver 260 converts the electrical sound signal from the control unit 210 into sound and outputs the sound. Sound output from the receiver 260 is output from the receiver hole 22 to the outside. The volume of the sound output from the receiver hole 22 is smaller than the volume of the sound output from the speaker hole 24.

  The front-side imaging unit 280 includes an imaging lens 281 and an imaging element. The front-side imaging unit 280 captures still images and moving images based on control by the control unit 210. The back side imaging unit 290 includes an imaging lens 291 and an imaging element. The back side imaging unit 290 captures a still image and a moving image based on control by the control unit 210.

  The power supply unit 200 outputs a power supply for the electronic device 2. The power output from the power supply unit 200 is supplied to various circuits such as the control unit 210 and the wireless communication unit 220 included in the electronic device 2. The power supply unit 200 includes a battery 201 and can output the power of the battery 201 as a power supply. The battery 201 is charged by the power of the battery 301 provided in the charger 3.

<Electric configuration of charger>
FIG. 11 is a block diagram showing an electrical configuration of the charger 3. As shown in FIG. 11, the charger 3 includes a battery 301, a charging unit 302, a booster circuit 303, a resistance element 304, a charging LED 305, a USB connector 306, and a connection terminal group 307. .

  The charging unit 302 is a charging circuit that charges the battery 301 based on the first external voltage EV1 supplied to the USB connector 306. A charging LED (Light Emitting Diode) 305 is a kind of light emitting unit, and is controlled by the charging unit 302. The charging LED 305 is lit while the battery 301 is being charged. The charging LED 305 is provided in the charger 3 so that its lighting state can be visually recognized from the outside of the charger 3.

  The booster circuit 303 is a kind of DC / DC converter, which boosts the input voltage to 5V and outputs a boosted voltage BV obtained thereby. The boosted voltage BV (5 V) is higher than the output voltage VB1 of the battery 301. The output voltage VB1 of the fully charged battery 301 is about 4.2V. The booster circuit 303 can also stop its output.

  The plurality of connection terminals 307z constituting the connection terminal group 307 are configured by a VDD terminal 307a, a control terminal 307b, and a GND terminal 307c. The VDD terminal 307 a outputs the boosted voltage BV output from the booster circuit 303 to the outside of the charger 3. The control terminal 307b is pulled up to the output voltage VB1 of the battery 301. Specifically, the output voltage VB1 of the battery 301 is applied to the control terminal 307b via the resistance element 304. The resistive element 304 is called a “pull-up resistor”. The signal level of the control terminal 307b is input to the booster circuit 303 as a control signal CNT for controlling the output of the booster circuit 303. The signal level of the control terminal 307b is controlled by the control unit 210 of the electronic device 2 as described later. A ground potential at the charger 3 is connected to the GND terminal 307d.

  The booster circuit 303 has, as operation modes, a boost mode that boosts and outputs the output voltage VB1 of the battery 301, and a stop mode that stops operation and does not output. When the first external voltage EV1 is supplied to the USB connector 306, the booster circuit 303 operates in the stop mode under the control of the charging unit 302 regardless of the signal level of the control signal CNT. Further, the booster circuit 303 operates in the stop mode when the low-level control signal CNT is input. When the booster circuit 303 is operating in the stop mode, the boosted voltage BV is not output from the VDD terminal 307a.

  The booster circuit 303 operates in the boost mode when the first external voltage EV1 is not supplied to the USB connector 306 and the high-level control signal CNT is input. When the booster circuit 303 is operating in the boost mode, the boosted voltage BV is output from the VDD terminal 307a. The control signal CNT is also called an “enable signal”.

  The charging unit 302 can charge the battery 301 based on the first external voltage EV1. When the first external voltage EV1 is supplied to the USB connector 306 and the battery 301 is not fully charged, the charging unit 302 charges the battery 301 based on the first external voltage EV1. However, the charging unit 302 does not charge the battery 301 when the control signal CNT is at the low level. That is, the charging unit 302 supplies the battery 301 based on the first external voltage EV1 when the first external voltage EV1 is supplied to the USB connector 306, the control signal CNT is at the low level, and the battery 301 is not fully charged. Charge. Further, when the first external voltage EV1 is supplied to the USB connector 306, the charging unit 302 sets the operation mode of the booster circuit 303 to the stop mode. Therefore, when battery 301 is being charged, boosted voltage BV is not output from VDD terminal 307a. The charging unit 302 turns on the charging LED 305 while the battery 301 is being charged, and turns off the charging LED 305 when the charging of the battery 301 is completed. When the control signal CNT is at the low level, the battery 301 is not charged, so the charging LED 305 is turned off.

  On the other hand, when the first external voltage EV1 is not supplied to the USB connector 306, the charging unit 302 supplies the output voltage VB1 of the battery 301 to the booster circuit 303 without charging the battery 301. At this time, when the control signal CNT is at a high level and the booster circuit 303 operates in the boost mode, the boosted voltage BV is output from the VDD terminal 307a.

<Configuration of power supply unit of electronic device>
FIG. 12 is a diagram illustrating a configuration of the power supply unit 200 and a part of the configuration of the control unit 210 of the electronic device 2. As shown in FIG. 12, the power supply unit 200 includes a battery 201, a charging unit (charging circuit) 202, a step-down circuit 203, a USB connector 206, and a connection terminal group 207. The control unit 210 includes a terminal control unit 210a, an AD converter 210b, a battery capacity acquisition unit 210c, and a display control unit 210d that controls the display panel 230.

  The plurality of connection terminals 207z constituting the connection terminal group 207 are configured by a VDD terminal 207a, a control terminal 207b, and a GND terminal 207c. The VDD terminal 207 a is in contact with the VDD terminal 307 a of the charger 3. The boosted voltage BV output from the charger 3 is input to the VDD terminal 207a. The control terminal 207b is in contact with the control terminal 307b of the charger 3. The state of the control terminal 207b is controlled by a terminal control unit 210a included in the control unit 210. The GND terminal 207 c is in contact with the GND terminal 307 c of the charger 3. A ground potential in the electronic device 2 is connected to the GND terminal 207c.

  The charging unit 202 can charge the battery 201 based on the second external voltage EV2 supplied to the USB connector 206. Furthermore, the charging unit 202 can charge the battery 201 based on the boosted voltage BV input to the VDD terminal 207a. When the charging unit 202 charges the battery 201 based on the boosted voltage BV, the battery 201 is charged by the charger 3.

  The charging unit 202 can input the second external voltage EV2 supplied to the USB connector 206 to the step-down circuit 203. Furthermore, the charging unit 202 can input the output voltage VB <b> 2 of the battery 201 to the step-down circuit 203. Hereinafter, the output voltage VB2 of the battery 201 may be referred to as “terminal-side battery voltage VB2”. Further, the output voltage VB1 of the battery 301 of the charger 3 may be referred to as “charger side battery voltage VB1”.

  The step-down circuit 203 is a kind of DC / DC converter, and generates a plurality of types of step-down voltages by stepping down an input voltage. A plurality of types of step-down voltages generated by the step-down circuit 203 are supplied as power supply voltages to the CPU 211, DSP 212, storage unit 213, wireless communication unit 220, display panel 230, and the like.

  The terminal control unit 210a of the control unit 210 sets the control terminal 207b to either the high impedance state or the low level. Here, the high impedance state is an electrical state of the control terminal 207 b in a state where the charger 3 is not attached to the electronic device 2. That is, the high impedance state is an electrical state of the control terminal 207b when the control terminal 207b is not in contact with the control terminal 307b of the charger 3. Therefore, when the control terminal 207b set in the high impedance state is in contact with the control terminal 307b pulled up to the charger side battery voltage VB1, the control terminal 307b and the control terminal 207b are connected to the charger side. Battery voltage VB1 is input. When the charger side battery voltage VB1 is input to the control terminal 307b and the control terminal 207b, the control signal CNT is at a high level. Therefore, when the control terminal 207b is set to the high impedance state, the boosted voltage BV is input to the VDD terminal 207a.

  On the other hand, when the control terminal 207b is set to the low level, the signal level of the control terminal 307b in contact with the control terminal 207b is the low level. Therefore, the control signal CNT becomes a low level. Therefore, when the control terminal 207b is set to the low level, the boosted voltage BV is not input to the VDD terminal 207a.

  Thus, the electronic device 2 controls the control signal CNT by controlling the electrical state of the control terminal 207b. That is, the control unit 210 can cause the booster circuit 303 to output the boosted voltage BV or not to output it by controlling the electrical state of the control terminal 207b. Basically, the control unit 210 sets the control terminal 207b to the Low level, and sets the control terminal 207b to the high impedance state as necessary. For example, when the charging unit 202 charges the battery 201, the control unit 210 sets the control terminal 207b to a high impedance state and inputs the boosted voltage BV to the VDD terminal 207a.

<About battery charging operation of electronic devices>
<When an external voltage is supplied to the electronic device>
Hereinafter, the charging operation of the battery 201 when the second external voltage EV2 is supplied to the USB connector 206 of the electronic device 2 will be described.

  Charging unit 202 charges battery 201 based on second external voltage EV2 and supplies second external voltage EV2 to step-down circuit 203 when battery 201 is not fully charged. On the other hand, the charging unit 202 outputs the second external voltage EV2 to the step-down circuit 203 without charging the battery 201 when the battery 201 is fully charged.

  Thus, when the second external voltage EV2 is supplied to the electronic device 2, the charging unit 202 uses the battery 201 based on the second external voltage EV2 without using the power of the charger 3. Charge the battery.

<When external voltage is not supplied to the electronic device>
Hereinafter, the charging operation of the battery 201 when the second external voltage EV2 is not supplied to the electronic device 2 will be described. The charging operation in this case differs depending on whether or not the first external voltage EV1 is supplied to the charger 3.

<When external voltage is supplied to the charger>
As described above, when the first external voltage EV1 is supplied to the charger 3, the output of the booster circuit 303 is stopped. Therefore, the booster voltage BV is not output from the charger 3. The charging unit 202 detects the voltage at the VDD terminal 207a, and determines that the boosted voltage BV is not supplied to the electronic device 2 if the detected voltage is equal to or lower than the threshold value. On the other hand, the charging unit 202 determines that the boosted voltage BV is supplied to the electronic device 2 if the voltage at the VDD terminal 207a is greater than the threshold value. If the charging unit 202 determines that the boosted voltage BV is not supplied to the electronic device 2, the charging unit 202 supplies the terminal-side battery voltage VB <b> 2 to the step-down circuit 203.

  As described above, when the second external voltage EV2 is not supplied to the electronic device 2 and the first external voltage EV1 is supplied to the charger 3, the charging unit 202 charges the battery 201. Instead, the terminal side battery voltage VB <b> 2 is supplied to the step-down circuit 203.

<When no external voltage is supplied to the charger>
When the first external voltage EV1 is not supplied to the charger 3, the charging unit 202 charges the battery 201 based on the boosted voltage BV input from the VDD terminal 207a and supplies the boosted voltage BV to the step-down circuit 203. To do.

  Charging unit 202 outputs boosted voltage BV to step-down circuit 203 without charging battery 201 when battery 201 is fully charged. On the other hand, when battery 201 is not fully charged, charging unit 202 charges battery 201 based on boosted voltage BV from charger 3 and supplies boosted voltage BV to step-down circuit 203.

  As described above, when the second external voltage EV2 is not supplied to the electronic device 2 and the first external voltage EV1 is not supplied to the charger 3, the charging unit 202 is connected to the charger 3 from the charger 3. The battery 201 is charged based on the boosted voltage BV.

<Display of battery capacity in electronic devices>
In the electronic device 2, the battery capacity of the battery 201 is displayed. In the electronic device 2 with the charger, not only the battery capacity of the battery 201 but also the battery capacity of the battery 301 of the charger 3 is displayed. Hereinafter, the battery capacity of the battery 201 may be referred to as “terminal-side battery capacity”. Further, the battery capacity of the battery 301 of the charger 3 may be referred to as “charger-side battery capacity”.

  FIG. 13 is a flowchart showing the operation of the electronic device 2 when the electronic device 2 calculates the terminal-side battery capacity. As shown in FIG. 13, in step s1, the AD converter 210b of the control unit 210 converts the terminal-side battery voltage VB2 from an analog value to a digital value. Next, in step s2, the battery capacity acquisition unit 210c obtains the current terminal side battery capacity based on the digital value of the terminal side battery voltage VB2 obtained by the AD converter 210b. The battery capacity is also called “battery remaining amount”.

  Next, in step s3, the display control unit 210d causes the display panel 230 to display the terminal-side battery capacity obtained by the battery capacity acquisition unit 210c. The terminal-side battery capacity displayed on the display panel 230 is displayed in the display area 21 on the front surface of the electronic device 2.

  Thereafter, the electronic device 2 executes Step s1 again, and thereafter operates in the same manner. The electronic device 2 performs a series of processes of steps s1 to s3, for example, periodically. Thereby, the terminal side battery capacity displayed on the display area 21 is always updated to the latest value.

  FIG. 14 is a flowchart showing the operation of the electronic device 2 with a charger when the electronic device 2 with a charger calculates the battery capacity on the charger side. As shown in FIG. 14, in step s11, the terminal control unit 210a sets the control terminal 207b to a high impedance state. Next, in step s12, the AD converter 210b converts the charger side battery voltage VB1 input to the control terminal 207b from an analog value to a digital value.

  Next, in step s13, the battery capacity acquisition unit 210c obtains the current charger side battery capacity based on the digital value of the charger side battery voltage VB1 obtained by the AD converter 210b. Next, in step s14, the display control unit 210d causes the display panel 230 to display the charger-side battery capacity obtained by the battery capacity acquisition unit 210c. The battery capacity on the charger side displayed on the display panel 230 is displayed in the display area 21.

  Thereafter, the electronic device 2 executes Step s11 again, and thereafter operates similarly. The electronic device 2 periodically executes a series of processes of steps s11 to s14, for example. Thereby, the battery capacity on the charger side displayed in the display area 21 is always updated to the latest value.

  Thus, the electronic device 2 can obtain and display the terminal-side battery capacity and the charger-side battery capacity. Thereby, the terminal side battery capacity is displayed in the display area 21 of the electronic device 2 to which the charger 3 is not attached, and the terminal side battery capacity and the charger side battery capacity are displayed in the display area 21 of the electronic device 2 with a charger. Both are displayed.

  FIG. 15 is a diagram illustrating a display example of the terminal-side battery capacity in the electronic device 2 to which the charger 3 is not attached. FIG. 16 is a diagram illustrating a display example of the terminal-side battery capacity and the charger-side battery capacity in the electronic device 2 with the charger.

  As shown in FIGS. 15 and 16, for example, a graphic 500 indicating the current terminal-side battery capacity is displayed in the display area 21 of the electronic device 2. Further, as shown in FIG. 16, the display area 21 of the electronic device 2 with the charger has, for example, a graphic 510 indicating the current battery capacity of the charger and the graphic 510 corresponding to the battery of the jacket 3 (charger 3). A character 511 for notifying the user that the battery capacity is 301 is displayed. In the example of FIG. 16, “J” is shown as the character 511.

  The display mode of the battery capacity of the batteries 201 and 301 is not limited to the display mode shown in FIGS. For example, the display panel 230 may display a ratio (for example, percentage) of the current battery capacity to the maximum battery capacity (battery capacity when fully charged).

  Moreover, the electronic device 2 with a charger may convert the terminal side battery voltage from an analog value to a digital value in the above-described step s12. In step s13, the electronic device 2 with the charger obtains the terminal-side battery capacity based on the digital value of the terminal-side battery voltage obtained in step s12, and displays the obtained terminal-side battery capacity in step s14. May be.

  As described above, the electronic device 2 is provided with the control terminal 207b, which is a dual-purpose terminal used for inputting the charger-side battery voltage VB1 and for other purposes. In the above example, the control terminal 207b is used both for input of the charger side battery voltage VB1 and for control of the output of the booster circuit 303. Therefore, the electronic device 2 can display not only the battery capacity of its own battery 201 but also the battery capacity of the battery 301 of the charger 3 with a simple configuration. Therefore, the configuration of the electronic device 2 is simplified.

  In the above example, when the control terminal 207b is set to a high impedance state, that is, when the battery voltage VB1 on the charger side is input to the control terminal 207b, the boost voltage BV is supplied from the boost circuit 303. Is output. Therefore, the electronic device 2 can obtain and display the charger side battery capacity even when the battery 201 is charged based on the boosted voltage BV.

  Note that the booster circuit 303 may operate in the stop mode when the control signal CNT is set to the high level, and may operate in the boost mode when the control signal CNT is set to the low level. In this case, the electronic device 2 changes the state of the control terminal 207b from the low level to the high impedance state when obtaining the battery capacity on the charger side while charging the battery 201 based on the boosted voltage BV. It is necessary to temporarily stop the charging of the battery 201. Then, after obtaining the battery capacity on the charger side, the electronic device 2 changes the state of the control terminal 207b from the high impedance state to the low level, and resumes charging of the battery 201 based on the boosted voltage BV.

  In the above example, the charging unit 302 of the charger 3 does not charge the battery 301 when the control signal CNT indicates a high level. Thereby, when the battery 301 of the charger 3 is charged, the possibility that the electronic device 2 calculates the terminal-side battery capacity can be reduced. When the battery 301 is charged based on the first external voltage EV1, it is difficult to correctly determine the terminal-side battery capacity. Therefore, the terminal-side battery capacity may be calculated when the battery 301 is charged. By reducing the battery capacity, the terminal-side battery capacity can be obtained more accurately.

  Further, since the charging unit 302 does not charge the battery 301 when the control signal CNT for controlling the output of the booster circuit 303 indicates a high level, there is a possibility that the terminal-side battery capacity is required during charging of the battery 301. No new configuration is required to reduce For example, the electronic device 2 does not need to output a control signal for permitting / disallowing charging of the battery 301 by the charger 3 to the charger 3. Therefore, with a simple configuration, the possibility that the terminal-side battery capacity is required during charging of the battery 301 can be reduced.

Embodiment 2. FIG.
FIG. 17 is a diagram illustrating a configuration of the charger 3 of the electronic device system 1 according to the second embodiment. FIG. 18 is a diagram illustrating a partial configuration of the electronic device 2 of the electronic device system 1 according to the second embodiment. The external appearance of the electronic device 2 and the charger 3 according to Embodiment 2 is the same as the external appearance of the electronic device 2 and the charger 3 according to Embodiment 1. The electronic device system 1 according to the second embodiment will be described below with a focus on differences from the electronic device system 1 according to the first embodiment.

  As shown in FIG. 17, the charger 3 according to the second embodiment includes a selection unit 308 instead of the resistance element 304 as compared with the first embodiment. The selection unit 308 is a selection circuit that selects one of the boosted voltage BV and the charger side battery voltage VB1 output from the booster circuit 303 and outputs the selected voltage to the VDD terminal 307a.

  In the second embodiment, a control signal CNT for controlling the output of the booster circuit 303 output from the electronic device 2 is input to the control terminal 307b. As in the first embodiment, the booster circuit 303 operates in the boost mode when the control signal CNT is at the high level, and operates in the stop mode when the control signal CNT is at the low level. Note that the booster circuit 303 may operate in the boost mode when the control signal CNT is at the low level, and may operate in the stop mode when the control signal CNT is at the high level.

  The control signal CNT input to the control terminal 307b is also input to the selection unit 308. The selection unit 308 selects one of the boosted voltage BV and the charger side battery voltage VB1 based on the control signal CNT, and outputs the selected voltage to the VDD terminal 307a. Specifically, the selection unit 308 outputs the boosted voltage BV output from the booster circuit 303 to the VDD terminal 307a when the control signal CNT is at a high level, that is, when the booster circuit 303 operates in the boost mode. On the other hand, the selection unit 308 outputs the charger side battery voltage VB1 to the VDD terminal 307a when the control signal CNT is at the low level, that is, when the booster circuit 303 operates in the stop mode.

  The control signal CNT input to the control terminal 307b is also input to the charging unit 302. Unlike Embodiment 1, charging unit 302 does not charge battery 301 when control signal CNT is at a low level.

  In the electronic apparatus 2 according to the second embodiment, as illustrated in FIG. 18, the control unit 210 includes a generation unit 210e instead of the terminal control unit 210a, as compared with the first embodiment. The generation unit 210e generates a control signal CNT and inputs it to the control terminal 207b.

<Display of battery capacity in electronic devices>
Next, the operation of the electronic device 2 when the electronic device 2 determines the battery capacity on the charger side will be described. FIG. 19 is a flowchart showing the operation. The operation of the electronic device 2 when the electronic device 2 calculates the terminal-side battery capacity is the same as that of the first embodiment.

  As illustrated in FIG. 19, in step s21, the generation unit 210e sets the signal level of the control signal CNT to the low level. As a result, the low level control signal CNT is input to the selection unit 308 of the charger 3, and the charger side battery voltage VB <b> 1 is output from the selection unit 308.

  Next, in step s22, the AD converter 210b converts the charger side battery voltage VB1 input to the VDD terminal 207a from an analog value to a digital value. Next, in step s23, the battery capacity acquisition unit 210c obtains the current charger side battery capacity based on the digital value of the charger side battery voltage VB1 obtained by the AD converter 210b. Next, in step s24, the display control unit 210d causes the display panel 230 to display the charger-side battery capacity obtained by the battery capacity acquisition unit 210c.

  Thereafter, the electronic device 2 with the charger executes Step s21 again, and thereafter operates similarly. The electronic device 2 with a charger performs a series of processes of steps s21 to s24, for example, periodically. Thereby, the battery capacity on the charger side displayed in the display area 21 is always updated to the latest value.

  In the second embodiment, the boosted voltage BV is not supplied to the electronic device 2 when the control signal CNT is at the low level. Therefore, the charging unit 202 temporarily stops the charging of the battery 201 when the control signal CNT changes from the High level to the Low level while the battery 201 is being charged. When the control unit 210 sets the control signal CNT to the Low level and obtains the charger side battery capacity, the control unit 210 changes the control signal CNT from the Low level to the High level. The charging unit 202 resumes charging of the battery 201 when the control signal CNT returns to the high level.

  As described above, the electronic device 2 is provided with the VDD terminal 207a, which is a dual-purpose terminal used for inputting the charger-side battery voltage VB1 and for other purposes. In the above example, the VDD terminal 207a is used both for inputting the battery voltage VB1 on the charger side and for inputting the boosted voltage BV. Therefore, the electronic device 2 can display not only the battery capacity of its own battery 201 but also the battery capacity of the battery 301 of the charger 3 with a simple configuration. Therefore, the configuration of the electronic device 2 is simplified.

  Further, the charging unit 302 of the charger 3 does not charge the battery 301 when the control signal CNT indicates the Low level. Thereby, when the battery 301 of the charger 3 is charged, the possibility that the electronic device 2 calculates the terminal-side battery capacity can be reduced. Therefore, as in the first embodiment, the terminal-side battery capacity can be obtained more accurately.

  Furthermore, since charging unit 302 does not charge battery 301 when control signal CNT for controlling the output of booster circuit 303 indicates a low level, the terminal during charging of battery 301 is the same as in the first embodiment. A new configuration is not required to reduce the possibility of the required side battery capacity. Therefore, with a simple configuration, the possibility that the terminal-side battery capacity is required during charging of the battery 301 can be reduced.

  As mentioned above, although the electronic device system 1 was demonstrated in detail, above-described description is an illustration in all the aspects, Comprising: This indication is not limited to it. The various modifications described above can be applied in combination as long as they do not contradict each other. And it is understood that the countless modification which is not illustrated can be assumed without deviating from the scope of this disclosure.

DESCRIPTION OF SYMBOLS 1 Electronic device system 2 Electronic device 3 Battery charger 201,301 Battery 207a VDD terminal 207b Control terminal 210c Battery capacity acquisition part 230 Display panel 303 Booster circuit

Claims (11)

An electronic device comprising a battery charged by a charger,
At least one connection terminal for connecting the electronic device to the charger;
A first battery charged by the charger;
A battery capacity obtaining unit for obtaining a first battery capacity of the first battery based on a first output voltage of the first battery;
A display unit for displaying the first battery capacity,
The charger includes a second battery and a booster circuit that boosts the second output voltage of the second battery to generate a boosted voltage, and charges the first battery based on the boosted voltage;
The at least one connection terminal includes a dual-purpose terminal that is used both for input of the second output voltage and for other purposes,
The battery capacity acquisition unit obtains a second battery capacity of the second battery based on the second output voltage input to the dual-purpose terminal;
The display unit is an electronic device that displays the first and second battery capacities. The electronic device according to claim 1,
The dual-purpose terminal is an electronic device that is shared for input of the second output voltage and for control of the output of the booster circuit. The electronic device according to claim 1,
The dual-purpose terminal is an electronic device that is used both for inputting the second output voltage and for inputting the boosted voltage. A charger for charging a first battery of an electronic device,
A plurality of connection terminals for connecting the charger to the electronic device;
A second battery;
A booster circuit that boosts the output voltage of the second battery to generate a boosted voltage;
The plurality of connection terminals include a first connection terminal that outputs the boosted voltage, and a second connection terminal that is pulled up to the output voltage,
The booster circuit receives the signal level of the second connection terminal as a control signal for controlling the output of the booster circuit,
The electronic device includes third and fourth connection terminals connected to the first and second connection terminals, respectively, and charges the first battery based on the boosted voltage input from the third connection terminal. Controlling the state of the fourth connection terminal;
The charger in which the output voltage is output from the second connection terminal when the electronic device sets the fourth connection terminal in a high impedance state. The charger according to claim 4,
The booster circuit outputs the boosted voltage to the first connection terminal when the fourth connection terminal is set to a high impedance state and the control signal indicates a high level. The charger according to any one of claims 4 and 5,
The charging apparatus further includes a charging unit that receives the control signal and charges the second battery based on an external voltage supplied from the outside of the charger.
The charger is a charger that does not charge the second battery when the external voltage is supplied and the fourth connection terminal is set to a high impedance state and the control signal indicates a high level. A charger for charging a first battery of an electronic device,
A plurality of connection terminals for connecting the charger to the electronic device;
A second battery;
A booster circuit that boosts the output voltage of the second battery to generate a boosted voltage;
The plurality of connection terminals include first and second connection terminals,
A control signal for controlling the output of the booster circuit, which is output from the electronic device, is input to the second connection terminal,
A selection unit that selects one of the boosted voltage and the output voltage based on the control signal and outputs the selected voltage to the first connection terminal;
The electronic device is a charger that charges the first battery based on the boosted voltage input to the first connection terminal. The electronic device according to claim 7,
The selection unit includes:
When the control signal is in the first state, the boosted voltage is output to the first connection terminal,
When the control signal is in the second state, the output voltage is output to the first connection terminal;
A charging unit for charging the second battery based on an external voltage supplied from the outside of the charger;
The charger is a charger that does not charge the second battery when the control signal is in the second state when the external voltage is supplied. Electronic equipment,
With a charger,
The electronic device is
At least one connection terminal for connecting the electronic device to the charger;
A first battery charged by the charger;
A battery capacity obtaining unit for obtaining a first battery capacity of the first battery based on a first output voltage of the first battery;
A display unit for displaying the first battery capacity,
The charger includes a second battery and a booster circuit that boosts the second output voltage of the second battery to generate a boosted voltage, and charges the first battery based on the boosted voltage;
The at least one connection terminal includes a dual-purpose terminal that is used both for input of the second output voltage and for other purposes,
The battery capacity acquisition unit obtains a second battery capacity of the second battery based on the second output voltage input to the dual-purpose terminal;
The display unit is an electronic device system that displays the first and second battery capacities. An electronic device having a first battery;
A charger for charging the first battery;
The charger is
A plurality of connection terminals for connecting the charger to the electronic device;
A second battery;
A booster circuit that boosts the output voltage of the second battery to generate a boosted voltage;
The plurality of connection terminals include a first connection terminal that outputs the boosted voltage, and a second connection terminal that is pulled up to the output voltage,
The booster circuit receives the signal level of the second connection terminal as a control signal for controlling the output of the booster circuit,
The electronic device includes third and fourth connection terminals connected to the first and second connection terminals, respectively, and charges the first battery based on the boosted voltage input from the third connection terminal. Controlling the state of the fourth connection terminal;
The electronic device system, wherein the output voltage is output from the second connection terminal when the electronic device sets the fourth connection terminal in a high impedance state. An electronic device having a first battery;
A charger for charging the first battery;
The charger is
A plurality of connection terminals for connecting the charger to the electronic device;
A second battery;
A booster circuit that boosts the output voltage of the second battery to generate a boosted voltage;
The plurality of connection terminals include first and second connection terminals,
A control signal for controlling the output of the booster circuit, which is output from the electronic device, is input to the second connection terminal,
The charger further includes a selection unit that selects one of the boosted voltage and the output voltage based on the control signal and outputs the selected voltage to the first connection terminal,
The electronic device system is an electronic device system that charges the first battery based on the boosted voltage input to the first connection terminal.

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