JP2010200397A - Electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electronic apparatus that suppresses cost increase and enlargement while suppressing wasteful power consumption in the charge function by a solar cell. <P>SOLUTION: When the illumination detected by an illumination sensor 104 is a specified value or more, the LDO111 of a solar charge circuit 102 is driven under control by a CPU105, and a switch circuit 108 connects the LDO111 with a battery pack 103, and charge using a solar cell 101 is performed. Moreover, when the illumination detected by an illumination sensor 104 is not a specified value or more, the LDO111 stops under control by the CPU105, and the switch circuit 108 disconnects the LDO111 from the battery pack 103, so that charge using the solar cell 101 is suppressed. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic device having a charging function using a solar cell (solar panel).

Patent Document 1 discloses a charging device (mobile phone) that charges a secondary battery using a solar battery.
In Patent Document 1, the solar charging circuit is always activated so that charging can be performed when the charging device receives light from the solar battery. In this case, even when the solar cell is not receiving light, power is consumed in the solar charging circuit, and this power can be said to be a wasteful consumption.

Therefore, it is also considered to suppress wasteful power consumption.
For example, as shown in FIG. 10, the voltage detector 313 of the solar charging circuit 302 monitors the voltage of the current flowing between the resistor 314 and the constant voltage diode 315 to indicate that the voltage is generated from the solar cell 301. A portable information terminal 30 to be detected has been devised. In this portable information terminal 30, when the voltage detector 313 detects the voltage from the solar battery 301, the CPU 305 drives an LDO (Low Drop Out) 311 to charge the battery pack (secondary battery) 303. So that it is controlled. In addition, when the voltage detector 313 does not detect the voltage, the CPU 305 controls to stop the operation of the LDO 311 and inhibit the battery pack 303 from being charged. Here, the LDO 311 is a regulator (power supply circuit) that makes the output voltage from the solar cell 301 constant and outputs a current to the battery pack 303 with the constant voltage. Thereby, since the start and stop of the charging operation by the solar battery are controlled, useless power consumption in the solar charging circuit 302 can be suppressed.

JP 2007-97330 A

  However, the solar charging circuit of the portable information terminal 30 shown in FIG. 10 has more parts than the solar charging circuit of Patent Document 1. Therefore, the portable information terminal 30 has an advantage that wasteful power consumption in the solar charging circuit 302 can be suppressed as compared with the portable information terminal including the solar charging circuit of Patent Document 1, but on the other hand, There is a problem that this leads to an increase in cost and size of the terminal.

  Then, an object of this invention is to provide the electronic device which can suppress a cost increase and an enlargement, suppressing the useless power consumption in the charge function by a solar cell.

  In order to achieve the above object, the present invention provides an electronic device, a sensor, a display whose light emission is controlled according to a detection result of the sensor, a solar battery, a secondary battery, and the secondary battery. A charging circuit that performs charging by the solar cell, and a control unit that controls switching of whether or not to perform charging using the charging circuit according to a detection result by the sensor. To do.

  According to this configuration, even when a charging function using a solar battery is added to the device, the electronic device can suppress an increase in cost and size of the device while suppressing unnecessary power consumption.

2 is a diagram illustrating an appearance of a portable information terminal 10. FIG. 3 is a diagram illustrating a configuration of a charging function in the portable information terminal 10. FIG. It is a figure which shows the structure of LDO111. 4 is a flowchart showing an operation of solar charging in the portable information terminal 10. It is a figure which shows the structure about the charge function in the portable information terminal 10a. It is a flowchart which shows the operation | movement of the solar charge in the portable information terminal 10a. It is an external view of the portable information terminal 10 in the case where the illuminance sensor 104 is arranged on the hinge part 4 at a position different from that of the first embodiment. 2 is an external view of a portable information terminal 10 when an illuminance sensor 104 is disposed on a display unit 5. FIG. It is an external view of the portable information terminal 10 when the arrangement position of the solar cell 101 is arranged on the facing surface 3 a of the housing 3. It is a figure which shows the structure about the charge function in the conventional portable information terminal.

1. 1st Embodiment The portable information terminal 10 as 1st Embodiment which concerns on this invention is demonstrated.
1.1 Overview The mobile information terminal 10 is, for example, a mobile phone, and the external appearance thereof will be described with reference to FIG. FIG. 1A is a front view of the portable information terminal 10 in the open state according to the present embodiment, and FIG. 1B is a rear view thereof. FIG. 1C is a front view of the portable information terminal 10 in the closed state.

  The portable information terminal 10 includes housings 2 and 3, which are configured to be able to be opened and closed with each other by being foldably connected via the hinge portion 4. Further, on the facing surface 2a of the housing 2 that faces the housing 3 when folded, a display unit 5 and a speaker unit 6 constituted by a liquid crystal display (hereinafter referred to as LCD (Liquid Crystal Monitor)) 107 are disposed. ing. A key operation unit 7 and a microphone 8 are arranged on the facing surface 3a of the housing 3 that faces the housing 2 when folded. Further, an illuminance sensor 104 that detects the amount of light is disposed on the hinge portion 4 of the housing 3. Furthermore, as shown in FIG.1 (b), the solar cell (solar panel) 101 for performing a photovoltaic power generation is arrange | positioned on the surface opposite to the opposing surface 2a of the housing 2. As shown in FIG. Further, as shown in FIG. 1C, when the portable information terminal 10 is in the closed state, the light receiving surface of the illuminance sensor 104 and the light receiving surface of the solar cell 101 are in the same direction.

The portable information terminal 10 controls charging by the solar battery 101 based on the detection result of the illuminance (light quantity) by the illuminance sensor 104.
1.2 Configuration Here, a configuration regarding a charging function in the portable information terminal 10 will be described.
As shown in FIG. 2, the charging function of the portable information terminal 10 includes a solar battery 101, a solar charging circuit 102, a battery pack 103, an illuminance sensor 104, a CPU 105, a quick charging circuit 106, an LCD 107, and a switch circuit 108. Yes.

In FIG. 2, only the components related to the charging function are shown in FIG. 2, but other functions such as the key operation unit 7 and the components related to the communication function are provided as functions of the mobile phone. The circuit block 130 is composed of various circuits for operating the portable information terminal 10.
(1) Solar cell 101
Solar cell 101 converts sunlight into electric power and outputs it to solar charging circuit 102. The output voltage at this time shall be 6.0-6.2V. Note that the output voltage of the solar cell 101 may be in a range of values other than 6.0 to 6.2 V (for example, 6.3 to 6.5 V).

(2) Solar charging circuit 102
As shown in FIG. 2, the solar charging circuit 102 includes a diode 110 and an LDO 111.
The diode 110 prevents the flow of current from the battery pack 103 side to the solar cell 101 side.

  The LDO 111 is a regulator that converts the output voltage from the solar battery 101 to a constant voltage and supplies current to the battery pack 103. The LDO 111 is controlled to be switched between driving and stopping by the CPU 105. During driving, the LDO 111 converts the output voltage from the solar cell 101 to a constant voltage (here, 4.0V) and outputs a constant current. The LDO 111 may be a constant voltage other than 4.0V.

  Here, one configuration example of the LDO 111 will be described with reference to FIG. As shown in FIG. 3, the LDO 111 includes a control transistor 131, a reference voltage circuit 132, an overcurrent protection circuit 133, resistors 134 and 135, and an operational amplifier 136. The operational amplifier 136 compares the voltage Va obtained by dividing the drain output voltage of the control transistor 131 by the two resistors 134 and 135 with the reference voltage Vr (here, 4.0 V) determined by the reference voltage circuit 132. Thus, the gate voltage Vc of the control transistor 131 is determined. As a result, the output voltage Vd at the drain of the control transistor 131 becomes equal to the reference voltage Vr. Further, when an overcurrent is applied to the LDO 111, the overcurrent protection circuit 133 prevents the overcurrent from being supplied to the battery pack 103.

(3) Switch circuit 108
The switch circuit 108 is a transistor, for example, and connects or disconnects the LDO 111 and the battery pack 103. Specifically, the switch circuit 108 is switched between on and off states under the control of the CPU 105. In the on state, the switch circuit 108 connects between the LDO 111 and the battery pack 103. In the off state, the switch circuit 108 disconnects the LDO 111 and the battery pack 103 from each other.

The initial state of the LDO 111 when the portable information terminal 10 is turned on is a stopped state, and the initial state of the switch circuit 108 is an off state.
(4) Battery pack 103
The battery pack 103 is a secondary battery such as a lithium ion battery.
The battery pack 103 stores the power supplied by the solar charging circuit 102 and the quick charging circuit 106 and outputs the power for driving the portable information terminal 10 to the circuit block 130.

(5) Illuminance sensor 104
The illuminance sensor 104 measures (detects) ambient brightness (illuminance (lx)) and notifies the CPU 105 of the measured (detected) illuminance. Specifically, the illuminance sensor 104 measures the amount of light flux per unit area incident on the surface of the illuminance sensor 104.
(6) CPU105
The CPU 105 controls the overall operation of the portable information terminal 10.

When the mobile information terminal 10 is in the open state, the CPU 105 controls the brightness of the LCD 107 based on the illuminance notified from the illuminance sensor 104 as in the conventional case.
In addition, when the portable information terminal 10 is in the open state, the CPU 105 determines whether or not the notified illuminance is greater than or equal to a predetermined value, and when determining that the notified illuminance is greater than or equal to the predetermined value, drives the LDO 111. And the switch circuit 108 is turned on. Thereafter, when the notified illuminance is equal to or lower than the predetermined value, the CPU 105 stops the LDO 111 and turns off the switch circuit 108.

Here, the predetermined value is a value indicating sufficient illuminance for the output voltage from the solar battery 101 to be between 6.0 and 6.2 V, and is, for example, 1000 lux (lx).
The CPU 105 also controls the charging operation in the quick charging circuit 106.
(7) Quick charging circuit 106
As illustrated in FIG. 2, the quick charging circuit 106 includes a charging control unit 120, a resistor 121, a charging transistor 122, and an input unit 123 that is a terminal connected to the AC adapter 124. The quick charging circuit 106 performs control for charging the battery pack 103 with the current supplied from the AC adapter 124 connected to the input unit 123 via the resistor 121 and the charging transistor 122. Here, it is assumed that the output voltage from the quick charging circuit 106 is 4.0 to 4.2V.

The charging control unit 120 monitors the temperature of the battery pack 103 and the output voltage, and suppresses charging when the temperature of the battery pack 103 becomes equal to or higher than a predetermined temperature. Further, charging is similarly suppressed when the value of the output voltage becomes larger than 4.2V.
1.3 Operation Here, the charging operation using the solar battery 101 in the portable information terminal 10 will be described with reference to the flowchart shown in FIG.

The illuminance sensor 104 measures the illuminance of ambient brightness (light) (step S5).
CPU105 judges whether the measurement result by the illumination intensity sensor 104 is more than predetermined value (step S10).
If it is determined that the value is not equal to or greater than the predetermined value (“NO” in step S10), the process returns to step S5.

When determining that the value is equal to or greater than the predetermined value (“YES” in step S10), the CPU 105 drives the LDO 111 and turns on the switch circuit 108 to perform charging using the solar cell 101 (step). S15).
Thereafter, the illuminance sensor 104 performs illuminance measurement (step S20), and the CPU 105 determines whether or not the measurement result is a predetermined value or more (step S25). If it is determined that the value is equal to or greater than the predetermined value (“YES” in step S25), the process returns to step S15 and charging is continued. When determining that the value is not equal to or greater than the predetermined value (“NO” in step S25), the CPU 105 stops the LDO 111 and turns off the switch circuit 108 to suppress charging using the solar cell 101 (step). S30).

1.4 Effects of the First Embodiment The portable information terminal 10 performs control of solar charging based on the illuminance detected by the illuminance sensor 104. As in the past, the solar battery charging circuit includes a voltage detector, a resistor And no diode. That is, by using the illuminance sensor 104 for both display brightness control and solar charge control, wasteful power consumption can be suppressed and the number of solar charging circuit components can be reduced. Conventionally, in a circuit provided with a voltage detector, a resistor and a diode in a solar charging circuit, the area occupied by these components (voltage detector, resistor and diode) is approximately 50 square mm. In portable information terminal 10 in the present embodiment, solar charging circuit 102 can be reduced by this area by using illuminance sensor 104 for both display brightness control and solar charging control. Therefore, the cost increase and enlargement of the portable information terminal 10 can be suppressed.

  Further, when the portable information terminal 10 does not perform solar charging, the switch circuit 108 is turned off, that is, the LDO 111 and the battery pack 103 are disconnected, so that the current output from the battery pack 103 is supplied to the LDO 111. There is no flow. Therefore, while solar charging is suppressed, no wasteful current flows from the secondary battery 103 to the LDO 111, that is, the solar charging circuit 102, so that wasteful power consumption can be further suppressed and the solar charging circuit can be suppressed. Can also prevent malfunction.

2. Second Embodiment A portable information terminal 10a as a second embodiment according to the present invention will be described.
2.1 Overview A difference from the first embodiment is that an opening / closing sensor 204 that detects opening / closing of the portable information terminal 10 is used instead of the illuminance sensor 104 as a trigger for starting solar charging. The open / close sensor 204 is conventionally used for power on / off control of the LCD 107, power on / off control of a key LED (Light Emitting Diode) for an operation key of the key operation unit 7, and the like.

2.2 Configuration Here, the configuration of the charging function in the portable information terminal 10a will be described focusing on differences from the first embodiment. In addition, the same code | symbol is used about the same component as 1st Embodiment.
As shown in FIG. 5, the portable information terminal 10 a includes a solar battery 101, a solar charging circuit 102, a battery pack 103, an open / close sensor 204, a CPU 205, a quick charging circuit 106, an LCD 107, and a switch circuit 108.

Hereinafter, the open / close sensor 204 and the CPU 205 different from those of the first embodiment will be described.
(1) Open / close sensor 204
The open / close sensor 204 detects the open / closed state of the portable information terminal 10a and notifies the CPU 205 of the detection result.

(2) CPU 205
The CPU 205 controls the overall operation of the portable information terminal 10a.
The CPU 205 controls the power on / off of the LCD 107 based on the detection result notified from the open / close sensor 204. Further, the CPU 105 determines whether the notified detection result is an open state or a closed state. When determining that the notified detection result is an open state, the CPU 105 drives the LDO 111 and turns on the switch circuit 108. To. When the CPU 205 determines that the notified detection result is in the closed state, the CPU 205 stops the operation of the LDO 111 and turns off the switch circuit 108.

The CPU 205 also controls the charging operation in the quick charging circuit 106, as in the first embodiment.
2.3 Operation Here, the operation of charging using the solar battery 101 in the portable information terminal 10a will be described with reference to the flowchart shown in FIG.

The open / close sensor 204 detects an open / closed open / closed state (step S100).
The CPU 205 determines whether or not the detection result by the open / close sensor 204 is in an open state (step S105).
If it is determined that it is not in the open state (“NO” in step S105), the process returns to step S100.

When determining that the battery is in the open state (“YES” in step S105), the CPU 205 drives the LDO 111 and turns on the switch circuit 108 to perform charging using the solar battery 101 (step S110). ).
Thereafter, the open / close sensor 204 detects the open / close state (step S115), and the CPU 205 determines whether or not the detection result is an open state (step S120). If it is determined that the battery is in the open state (“YES” in step S120), the process returns to step S110 to continue charging. When determining that it is not in the open state (“NO” in step S120), the CPU 205 stops the LDO 111 and turns off the switch circuit 108 to suppress charging using the solar cell 101 (step S125). ).

2.4 Effects in the Second Embodiment The portable information terminal 10a performs control of solar charging based on the open / closed state of the terminal detected by the open / close sensor 204. There is no need to provide a voltage detector, resistor and diode. Also, according to the detection result of the open / close sensor 204, the power on / off control of the LCD 107 and the key LRD is performed as in the conventional case. In other words, by using the open / close sensor 204 for both on / off control of the power of the LCD 107 and the key LED and control of solar charging, wasteful power consumption can be suppressed and the number of parts of the solar charging circuit can be reduced. Can do. Therefore, the cost increase and enlargement of the portable information terminal 10a can be suppressed.

Further, as in the first embodiment, the portable information terminal 10a keeps the switch circuit 108 off while solar charging is not being performed, so that wasteful power consumption can be further suppressed and solar power can be reduced. It is also possible to prevent malfunction of the charging circuit.
3. The embodiment described above is an example of the embodiment of the present invention, and the present invention is not limited to this embodiment, and can be implemented without departing from the scope of the present invention. is there. The following cases are also included in the present invention.

(1) The arrangement position of the illuminance sensor 104 is not limited to the position shown in the first embodiment.
Below, the modification which concerns on the arrangement position of the illumination intensity sensor 104 is shown.
(1-1) The illuminance sensor 104 may be disposed near the center depending on the structure of the hinge portion 4. The external appearance of the portable information terminal 10 in this case is shown in FIG. FIG. 7A is a front view of the portable information terminal 10 in the open state when the illuminance sensor 104 is arranged near the center of the hinge portion 4, and FIG. 7B is a rear view thereof. FIG. 7C is a front view in the closed state. As shown in FIGS. 7B and 7C, the solar cell 101 is arranged on the surface opposite to the facing surface 2a of the housing 2 as in the first embodiment. When the portable information terminal 10 is in the open state as shown in FIG. 7A, the illuminance sensor 104 is used to control the brightness of the display unit 5. In the closed state as shown in FIG. 7B, the light receiving surface of the illuminance sensor 104 and the light receiving surface of the solar cell 101 are always in the same direction. Used to control charging by 101.

  (1-2) The illuminance sensor 104 may be disposed on the housing 2 on which the display unit 5 is disposed. The external appearance of the portable information terminal 10 in this case is shown in FIG. FIG. 8A is a front view of the portable information terminal 10 in an open state when the illuminance sensor 104 is arranged on the housing 2, and FIG. 8B is a rear view thereof. FIG. 8C is a side view in the closed state, and FIG. 8D is a rear view in the closed state. As shown in FIGS. 8B and 8D, the solar cell 101 is disposed on the surface opposite to the facing surface 3 a of the housing 3. Further, as shown in FIGS. 8A and 8C, the housing 3 is provided with a light guide portion 250 that allows light to pass so as to face the light receiving surface of the illuminance sensor 104 in the closed state. . Thereby, even when the portable information terminal 10 is in the closed state, the illuminance sensor 104 can receive light via the light guide unit 250. Here, as shown in FIGS. 8C and 8D, when the portable information terminal 10 is in the closed state, the light receiving surface of the illuminance sensor 104 and the light receiving surface of the solar cell 101 are in the same direction. Light can be received. Therefore, when the portable information terminal 10 is in the closed state, the illuminance sensor 104 receives light through the light guide unit 250, so that charging by the solar cell 101 can be controlled.

Here, the illuminance sensor 104 is disposed on the facing surface 2 a of the housing 2, but may be disposed on the facing surface 3 a of the housing 3. At this time, the arrangement relationship with the light guide portion 250 is reversed from the above, and the solar cell 101 is provided on the surface opposite to the facing surface 2a of the housing 2 as in the first embodiment.
(1-3) Another example is shown in FIG. FIG. 9 is a front view of the portable information terminal 10 in which the solar cell 101 is disposed on the facing surface 3a of the casing 3 in the open state. In this case, the portable information terminal 10 can control the brightness of the LCD 107 in the display unit 5 based on the measurement result of the illuminance of the illuminance sensor 104 in the open state as usual. Further, since the light receiving surface of the illuminance sensor 104 and the light receiving surface of the solar cell 101 are in the same direction, the portable information terminal 10 can also control charging by the solar cell 101. The key operation in this case is performed on the display unit 5 by a touch panel method.

In FIG. 9, the illuminance sensor 104 is disposed on the facing surface 2 a of the housing 2, but may be disposed on the facing surface 3 a of the housing 3.
(1-4) According to the first embodiment and each modification related to the arrangement position of the illuminance sensor 104, the light receiving surface of the illuminance sensor 104 and the surface of the display unit 5 are the same when the portable information terminal 10 is open. The display unit 5, the solar cell 101, and the illuminance sensor 104 are arranged so that the light receiving surface of the illuminance sensor 104 and the light receiving surface of the solar cell 101 are in the same direction in either the open state or the closed state. It only has to be arranged.

(2) In the first embodiment, the illuminance sensor 104 is used for controlling the brightness of the LCD 107, but is not limited to this.
The illuminance sensor 104 may be used for other purposes, for example, to control the brightness of a key LED for a key provided in a key operation unit. That is, the illuminance sensor 104 only needs to be used for the purpose of controlling light emission within the own device.

(3) In the first embodiment, the predetermined values used in steps S10 and S25 in FIG. 4 are the same as each other, but are not limited thereto. The values used for each determination may be different.
For example, a value (hereinafter referred to as “second value”) used for determination in step S25 rather than a value (hereinafter referred to as “first value”, for example, 1100 lux) used for determination in step S10. Set to be smaller. For example, the second value is 1000 lux.

  When the ambient brightness is close to a predetermined value (1000 lux), the same value (1000 lux) is used as the predetermined value in step S10 and step S25 as shown in the first embodiment. Due to external factors (for example, the orientation of the portable information terminal 10 changes), it is considered that the measurement result frequently fluctuates when the measured illuminance becomes greater than or equal to the value. In such a case, the start and suppression of charging by the solar battery 101 are frequently switched.

Therefore, by using the first value and the second value, when the ambient brightness is an environment close to the first value, the measured illuminance becomes equal to or higher than the first value, Even if the measurement result fluctuates frequently, for example, when the value is less than or equal to this value, charging is not inhibited unless it falls below the second value. That is, the start and suppression of charging by the solar battery 101 are not frequently switched.
(4) In each of the above embodiments, a portable information terminal is used as an example in order to explain the present invention. However, a terminal for carrying out the present invention is not limited to a portable terminal. Any electronic device provided with a sensor for controlling light emission in the device itself may be used.

  Moreover, in the said 2nd Embodiment, although the portable information terminal was made into the foldable type terminal, it is not limited to this. For example, instead of a foldable terminal, a sliding electronic device may be used. In this case, a state where the key operation unit is hidden is a closed state, and a state where the key operation unit appears is an open state. That is, a terminal for carrying out the invention according to the second embodiment may be an electronic device whose shape is switched between an open state and a closed state. Such an electronic device is referred to as an openable / closable information terminal in the present invention, and the concept naturally includes the above-described foldable portable information terminal and slide-type portable information terminal.

(5) In each of the above embodiments, a transistor is given as a specific example of the switch circuit 108; however, the invention is not limited to this.
The switch circuit 108 only needs to have a mechanism for connecting or disconnecting the LDO 111 and the battery pack 103.
(6) The above embodiment and the above modifications may be combined.

4). Summary (1) The present invention is an electronic device, which is a sensor, a display whose light emission is controlled according to a detection result of the sensor, a solar battery, a secondary battery, and the secondary battery. A charging circuit that performs charging by a solar battery, and a control unit that controls switching between charging and deterring using the charging circuit according to a detection result by the sensor.

  According to this configuration, the electronic device controls whether charging by the solar cell is performed or suppressed by using a detection result of a sensor used for controlling light emission of the display. In other words, the electronic device can reduce the voltage detector, the resistor and the constant voltage diode, which are components related to voltage detection, by using the sensor for both the light emission control of the display and the charging control by the solar battery. The scale of the charging circuit can be reduced as compared with the conventional one while suppressing the cost of the parts related to the charging function as compared with the case of using the conventional solar charging circuit. In addition, when charging by the solar cell is suppressed based on the detection result of the sensor, the charging circuit does not require power, and therefore wasteful power consumption can be suppressed. Therefore, when a charging function using a solar battery is added to an electronic device, it is possible to suppress an increase in cost and size of the device while suppressing unnecessary power consumption.

(2) Here, the control means may control switching between charging and suppressing by switching a path between the charging circuit and the secondary battery between conduction and interruption.
According to this configuration, the electronic device switches between charging by the solar battery and suppression of charging by switching the path between the charging circuit and the secondary battery between conduction and interruption. Thereby, while the electronic device is suppressing charging by the solar battery, the current output from the secondary battery does not flow to the charging circuit. That is, while charging is suppressed, no wasteful current flows from the secondary battery to the charging circuit, so that wasteful power consumption can be further suppressed and malfunction of the charging circuit can be prevented.

(3) Here, the sensor is an illuminance sensor that detects illuminance, and the control unit controls the path to be conducted when the illuminance sensor detects brightness of a predetermined illuminance or higher, When the illuminance sensor does not detect brightness exceeding a predetermined illuminance, the route may be controlled to be blocked.
According to this configuration, the electronic device uses the illuminance sensor for both light emission control of the display and charge control by the solar battery. Conventionally, an illuminance sensor is provided to control light emission of the display. In other words, the electronic device can control the charging by the solar cell using the existing component (illuminance sensor), thereby reducing the cost of the component related to the charging function and reducing the scale.

(4) Here, the light receiving surface of the illuminance sensor and the light receiving surface of the solar cell may be arranged to receive light from the same direction.
According to this configuration, since the electronic device arranges the light receiving surface of the illuminance sensor and the light receiving surface of the solar cell so as to receive light in the same direction, the solar cell has an illuminance equivalent to the illuminance detected by the illuminance sensor. Can also receive light.

(5) Here, the electronic device is an open / close type information terminal, the sensor is an open / close sensor that detects an open / closed state of the information terminal, and the control means includes the open / close sensor of the information terminal. When the open state is detected, the path may be controlled to be conducted, and when the closed state is detected, the path may be controlled to be blocked.
According to this configuration, the electronic device which is an open / close type information terminal uses the open / close sensor for both light emission control of the display and charge control by the solar cell. Conventionally, an open / close type information terminal has been provided with an open / close sensor to detect the start of use by the user. When the open / close sensor detects an open state, it is determined that the user has started use, and the display is turned on. Is done. That is, the electronic device can control the charging by the solar cell using the existing component (opening / closing sensor), thereby reducing the scale of the electronic device while suppressing the cost of the component related to the charging function.

  (6) Moreover, this invention is an electronic device, Comprising: The illumination intensity sensor currently used in order to detect illumination intensity, and to control the light emission in a self-machine according to a detection result, a solar cell, a secondary battery, A charging circuit that charges the secondary battery with the solar battery, and a control unit that controls switching of whether or not to perform charging using the charging circuit according to a detection result of the illuminance sensor; It is characterized by providing.

  According to this configuration, the electronic device controls charging by the solar cell using the detection result of the illuminance sensor that controls the light emission in the device itself. That is, the electronic device can reduce the voltage detector, the resistor, and the constant voltage diode, which are components related to voltage detection, by using the illuminance sensor for both the light emission control in the device itself and the charge control by the solar cell. Therefore, the scale of the charging circuit can be reduced while suppressing the cost of the parts related to the charging function as compared with the case of using the conventional solar charging circuit. In addition, when charging by the solar battery is suppressed based on the detection result of the illuminance sensor, the charging circuit does not require power, and therefore wasteful power consumption can be suppressed. Therefore, when a charging function using a solar battery is added to an electronic device, it is possible to suppress an increase in cost and size of the device while suppressing unnecessary power consumption.

  The present invention can be used in a management, that is, repetitively and continuously, in an industry that manufactures and sells electronic devices that are charged by solar cells.

DESCRIPTION OF SYMBOLS 10 Portable information terminal 101 Solar cell 102 Solar charging circuit 103 Battery pack 104 Illuminance sensor 105 CPU
106 Quick charge circuit 107 Liquid crystal display 108 Switch circuit 110 Diode 111 LDO
130 circuit block 204 open / close sensor 205 CPU

Claims (6)

A sensor,
A display whose emission is controlled according to the detection result of the sensor;
Solar cells,
A secondary battery,
A charging circuit for charging the secondary battery with the solar battery;
An electronic apparatus comprising: a control unit that controls switching of whether or not charging using the charging circuit is performed according to a detection result of the sensor. The control unit controls switching between charging and deterring by switching a path between the charging circuit and the secondary battery between conduction and interruption. Electronic equipment. The sensor is an illuminance sensor that detects illuminance,
The control means controls the path to be conducted when the illuminance sensor detects brightness exceeding a predetermined illuminance, and controls the path when the illuminance sensor does not detect brightness exceeding the predetermined illuminance. The electronic device according to claim 2, wherein the electronic device is controlled so as to be blocked. The electronic device according to claim 3, wherein the light receiving surface of the illuminance sensor and the light receiving surface of the solar cell are arranged to receive light from the same direction. The electronic device is an openable information terminal,
The sensor is an open / close sensor that detects an open / closed state of the information terminal,
The control means controls the path to be conducted when the open / close sensor detects the open state of the information terminal, and controls to block the path when the closed state is detected. The electronic device according to claim 2. An illuminance sensor that is used to detect illuminance and control light emission in the aircraft according to the detection result;
Solar cells,
A secondary battery,
A charging circuit for charging the secondary battery with the solar battery;
An electronic apparatus comprising: a control unit that controls switching of whether or not charging using the charging circuit is performed according to a detection result of the illuminance sensor.

Images