JP7193281B2 - Clocks, electronic devices, and methods of determining illuminance for clocks - Google Patents

Description

The present invention relates to a timepiece, an electronic device, and an illuminance determination method for the timepiece.

2. Description of the Related Art There are watches that charge a secondary battery with power generated by a solar battery and are driven by the charged power. Such watches have an overcharge protection circuit to prevent overcharging of the secondary battery. Further, in a timepiece having a solar cell, if the illuminance applied to the solar cell is low, sufficient power generation cannot be performed, and the timepiece cannot be driven.

For this reason, for example, Japanese Patent Laid-Open No. 2003-100001 discloses a technique for interrupting the display output from the driver circuit of the liquid crystal panel when the output of the solar cell becomes equal to or less than a predetermined value.
Further, Patent Document 2 discloses a technique of stopping the time display operation when incident light is not obtained continuously for a certain period of time or longer.

In addition, in a timepiece having a solar cell and a secondary battery, whether the illuminance applied to the solar cell is sufficient or not is detected by detecting the voltage of the solar cell. Some have a detection circuit (see Patent Document 3, for example). Some watches of this type switch to a power saving mode when the solar cell is not sufficiently illuminated. Here, the power saving mode means an operation mode in which no display is performed when the display of the watch is composed of a liquid crystal panel, and an operation mode in which the interval between the hand movements is lengthened when the display of the clock is composed of hands. Operation mode.

When the secondary battery is fully charged with the power generated by the solar battery, the overcharge protection circuit is turned on to prevent the secondary battery from being overcharged. When the overcharge protection circuit is turned on, the electrodes of the solar cell are short-circuited.

Japanese Utility Model Laid-Open No. 56-97795 Japanese Utility Model Laid-Open No. 61-77788 JP 2013-134167 A

However, in the prior art, in a timepiece having a solar battery and a secondary battery, when the overcharge protection circuit is turned on and the electrodes of the solar battery are short-circuited, another circuit of the timepiece, such as an illuminance detection circuit, is The detected value is lower than the actual value. For this reason, it is difficult for the conventional technology to accurately detect the power generation state of the solar cell. As a result, in the prior art, even if the illuminance is equal to or greater than the predetermined illuminance, it may be erroneously determined that the illuminance is less than the predetermined illuminance, and control may be performed in the power saving mode. The overcharge protection circuit is turned on when the secondary battery is almost fully charged.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems. , and a method for determining the illuminance of a clock.

To achieve the above object, a timepiece (1) according to an aspect of the present invention comprises a solar cell (G) having a solar panel, a secondary battery (E) charged by the solar cell, and the secondary battery. and an illuminance detection circuit (20) for detecting whether or not the illuminance irradiated to the solar panel is equal to or higher than a predetermined illuminance based on the voltage value across the solar panel. When the circuit (30) and the overcharge prevention circuit detect an overcharge state, the solar cell is short-circuited, the illumination intensity irradiated to the solar panel is determined to be equal to or higher than a predetermined illumination intensity, and the When the overcharge prevention circuit detects that the overcharge is not overcharged, the control unit (104) determines whether or not the illuminance is equal to or higher than the predetermined illuminance based on the detection value of the illuminance detection circuit without short-circuiting the solar cell. ) , wherein the solar cell, the overcharge prevention circuit, and the illuminance detection circuit are connected in parallel, and the control unit detects that the overcharge prevention circuit is not in an overcharged state. case, the first detection value detected by the illuminance detection circuit is determined to indicate that the illuminance illuminating the solar panel is less than a predetermined illuminance, and the overcharge prevention circuit detects an overcharged state. and determining, based on the first detection value detected by the illuminance detection circuit, that the illuminance illuminating the solar panel is equal to or higher than a predetermined illuminance.
In order to achieve the above object, a timepiece (1) according to an aspect of the present invention includes a solar cell (G) having a solar panel, a secondary battery (E) charged by the solar cell, An overcharge prevention circuit (20) for detecting the state of charge of the secondary battery and detecting whether or not the illuminance irradiated to the solar panel is equal to or higher than a predetermined illuminance based on the voltage value across the solar panel. When the illuminance detection circuit (30) and the overcharge prevention circuit detect an overcharge state, the solar cell is short-circuited and the illuminance radiated to the solar panel is determined to be equal to or higher than a predetermined illuminance. a control unit for determining whether or not the illuminance is equal to or higher than the predetermined illuminance based on the detected value of the illuminance detection circuit without short-circuiting the solar cell when the overcharge prevention circuit detects that the overcharge is not overcharged; (104), and a display (40), wherein the predetermined illumination is an illumination capable of supplying power capable of driving the display.

Further, in the timepiece according to one aspect of the present invention, the solar cell, the overcharge prevention circuit, and the illuminance detection circuit are connected in parallel, and the control unit controls the overcharge prevention circuit to prevent overcharging. When it is detected that the solar panel is not in the state, it may be determined whether or not the illuminance irradiated to the solar panel is equal to or higher than a predetermined illuminance, based on the detection value detected by the illuminance detection circuit.

Further, in the timepiece according to the aspect of the present invention, when the control unit detects that the overcharge prevention circuit is not in an overcharged state, when the detection value detected by the illuminance detection circuit is equal to or greater than a predetermined value, and determining that the illuminance irradiated to the solar panel is equal to or higher than a predetermined illuminance, and if the detection value detected by the illuminance detection circuit is less than the predetermined value, the illuminance irradiated to the solar panel is less than the predetermined illuminance. You may make it judge that it is.

To achieve the above object, an electronic device according to one aspect of the present invention includes any one of the watches described above.

To achieve the above object, a timepiece illuminance determination method according to one aspect of the present invention detects a solar battery having a solar panel, a secondary battery charged by the solar battery, and a state of charge of the secondary battery. and an illuminance detection circuit for detecting whether the illuminance illuminating the solar panel is equal to or higher than a predetermined illuminance, based on the voltage across the solar panel. In the determination method, when the control unit detects that the overcharge prevention circuit is in an overcharge state, the solar cell is short-circuited, and the illuminance irradiated to the solar panel is equal to or higher than a predetermined illuminance. If the overcharge prevention circuit detects that the overcharge prevention circuit is not in an overcharged state, it is determined whether or not the illuminance is equal to or higher than the predetermined illuminance based on the detection value of the illuminance detection circuit without short-circuiting the solar cell. wherein the solar cell, the overcharge prevention circuit, and the illuminance detection circuit are connected in parallel with each other, and the control unit detects that the overcharge prevention circuit is not in an overcharge state. case, the first detection value detected by the illuminance detection circuit is determined to indicate that the illuminance illuminating the solar panel is less than a predetermined illuminance, and the overcharge prevention circuit detects an overcharged state. and determining, based on the first detection value detected by the illuminance detection circuit, that the illuminance illuminating the solar panel is equal to or higher than a predetermined illuminance .
To achieve the above object, a timepiece illuminance determination method according to one aspect of the present invention detects a solar battery having a solar panel, a secondary battery charged by the solar battery, and a state of charge of the secondary battery. an overcharging prevention circuit, an illuminance detection circuit that detects whether or not the illuminance illuminating the solar panel is equal to or higher than a predetermined illuminance, based on the voltage across the solar panel, and a display unit. wherein, when the control unit detects that the overcharge prevention circuit is in an overcharged state, the solar cell is short-circuited and the illuminance radiated to the solar panel is reduced to a predetermined illuminance If it is determined that the overcharge prevention circuit detects that the overcharge prevention circuit is not in an overcharged state, it is determined whether or not the illuminance is equal to or higher than the predetermined illuminance based on the detection value of the illuminance detection circuit without short-circuiting the solar cell. wherein the predetermined illuminance is an illuminance that can supply power for driving the display unit.

According to the present invention, it is possible to accurately detect the power generation state of the solar cell even when the secondary battery is in an overcharged state close to full charge.

1 is a block diagram showing a configuration example of a timepiece according to a first embodiment; FIG. 4 is a diagram showing output characteristics (IV curve) of a solar cell G; FIG. 4 is a flow chart showing an example of a processing procedure performed by the watch according to the first embodiment; FIG. 10 is a flow chart in the case where electrodes of a solar cell are short-circuited when overcharging occurs according to the prior art, and illuminance detection is performed during that time. FIG. 2 is a block diagram showing a configuration example when the clock according to the first embodiment is an analog clock; FIG. 9 is a flow chart showing an example of a processing procedure performed by the watch according to the second embodiment;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[First embodiment]
FIG. 1 is a block diagram showing a configuration example of a timepiece 1 (electronic device) according to this embodiment. As shown in FIG. 1, the timepiece 1 includes a secondary battery E, a solar cell G, a diode D1, a resistor R1, a resistor R2, a control circuit 10, and a display section 40.
The control circuit 10 also includes a power supply circuit 101 , an oscillation circuit 102 , a frequency dividing circuit 103 , a control section 104 , a display driving circuit 105 , an overcharge prevention circuit 20 and an illuminance detection circuit 30 .
The overcharge protection circuit 20 has a comparator Q1, a switching element Q2, and a reference voltage source Vr1.
The illuminance detection circuit 30 has a switching element Q3, a comparator Q4, and a reference voltage source Vr2.

Note that the clock 1 shown in FIG. 1 is a digital clock that displays the measured time on a display unit 40 such as a liquid crystal display. Moreover, the timepiece 1 is a so-called solar timepiece that is operated by light emitted from the solar cell G. As shown in FIG. In addition, in the embodiment, the watch 1 is described as an example of the electronic device.

First, the connection relationship will be explained.
The secondary battery E has a positive electrode connected to the cathode of the diode D1 and the power supply terminal Vdd of the control circuit 10, and a negative electrode grounded to Vss.
The diode D<b>1 has an anode connected to the positive electrode of the solar cell G and the terminal Vsc of the control circuit 10 .
The solar cell G has its negative electrode grounded to Vss.

The resistor R1 has one end connected to the terminal CN1 of the control circuit 10 and the other end connected to one end of the resistor R2 and the terminal CN2 of the control circuit 10 .
The resistor R2 has its other end grounded to Vss.

A power supply terminal Vdd of the control circuit 10 is connected to the input of the power supply circuit 101 and the first input of the comparator Q1.
A terminal Vsc of the control circuit 10 is connected to the drain terminal of the switching element Q2 and the source terminal of the switching element Q3. The switching element Q2 is, for example, an N-channel MOSFET (Metal-Oxide-Semiconductor Field-Effect Transistor). The switching element Q3 is, for example, a P-channel MOSFET.

A terminal CN1 of the control circuit 10 is connected to a drain terminal of the switching element Q3.
Terminal CN2 of control circuit 10 is connected to a first input of comparator Q4.
A terminal Vss of the control circuit 10 is grounded to Vss.

The comparator Q1 has a second input connected to the positive terminal of the reference voltage source Vr1, and an output connected to the REG1 terminal of the control section 104 and the gate terminal of the switching element Q2.
The reference voltage source Vr1 has its negative terminal grounded to Vss.
The switching element Q2 has a source terminal grounded to Vss.

The switching element Q3 has a gate terminal connected to the CNT terminal of the control section 104 .
The comparator Q4 has a second input connected to the positive terminal of the reference voltage source Vr2 and an output connected to the REG2 terminal of the controller 104 .
The reference voltage source Vr2 has its negative terminal grounded to Vss.

As described above, the timepiece 1 has a configuration in which the solar battery G, the overcharge prevention circuit 20, and the illuminance detection circuit 30 are connected in parallel.

Next, the constituent elements of the timepiece 1 will be described.
The solar cell G has a solar panel, for example. The solar cell G converts light energy into electric power and supplies the converted electric power to the secondary battery E and the control circuit 10 .
The diode D1 is inserted between the solar cell G and the secondary battery E to prevent backflow from the secondary battery E to the solar cell G. As shown in FIG.
The secondary battery E is a storage battery that stores electrical energy supplied from the solar battery G. The secondary battery E supplies the stored power to the control circuit 10 .

The power supply circuit 101 steps up or steps down the output voltage of the secondary battery E, generates an internal operating voltage for each circuit inside the control circuit 10, and supplies the generated internal operating voltage to each circuit. The voltage value supplied to the first input portion of the comparator Q1 of the overcharge prevention circuit 20 is the voltage value of the secondary battery E.

The oscillator circuit 102 is a passive element that uses, for example, the piezoelectric phenomenon of crystal and is used to oscillate a predetermined frequency from its mechanical resonance. Here, the predetermined frequency is, for example, 32 [kHz].
The frequency dividing circuit 103 frequency-divides the signal of a predetermined frequency output from the oscillation circuit 102 into a desired frequency, and outputs the frequency-divided signal to the control unit 104 .

The overcharge prevention circuit 20 compares the voltage value Vdd of the secondary battery E with the voltage value Vref1 of the reference voltage source Vr1. As a result of the comparison, when the voltage value Vdd is equal to or higher than the voltage value Vref1, the overcharge prevention circuit 20 outputs an H (high) level signal to the REG1 terminal of the control unit 104 as the overcharge prevention signal sg1 indicating overcharge prevention. do. Moreover, the overcharge prevention circuit 20 performs control so that the electrodes of the solar cell G are short-circuited when the voltage value Vdd is equal to or greater than the voltage value Vref1 as a result of the comparison. Overcharge prevention circuit 20 outputs an L (low) level overcharge prevention signal sg1 to a REG1 terminal of control unit 104 when voltage value Vdd is less than voltage value Vref1 as a result of the comparison. The overcharge protection circuit 20 is turned on when the secondary battery E is almost fully charged.

The comparator Q1 compares the voltage value Vdd of the secondary battery E and the voltage value Vref1 of the reference voltage source Vr1. Comparator Q1 outputs an H-level signal as overcharge prevention signal sg1 to REG1 terminal of control unit 104 when voltage value Vdd is equal to or greater than voltage value Vref1 as a result of the comparison. Further, when the voltage value Vdd is equal to or higher than the voltage value Vref1, the comparator Q1 outputs an H level signal to the gate terminal of the switching element Q2 to switch the electrodes of the solar cell G to short-circuit. Comparator Q1 also outputs L-level overcharge prevention signal sg1 to REG1 terminal of control unit 104 when voltage value Vdd is less than voltage value Vref1 as a result of the comparison.

Assume that the maximum voltage value when the electrodes of the solar cell G are open is 3.6 [V]. Moreover, the voltage value is 0 V when the solar cell G is not irradiated with light. In this case, the voltage value Vref1 (also referred to as reference voltage value Vref1) of the reference voltage source Vr1 is a voltage value between 0 [V] and 3.6 [V]. The voltage value Vref1 of the reference voltage source Vr1 is the upper limit value of the allowable voltage value applied to the secondary battery E during charging.

The illuminance detection circuit 30 divides the voltage of the solar cell G with the resistors R1 and R2 when the CNT signal from the control unit 104 is at H level. The illuminance detection circuit 30 compares the divided voltage value with the voltage value Vref2 of the reference voltage source Vr2. As a result of the comparison, if the divided voltage value is equal to or higher than the voltage value Vref2, the illuminance detection circuit 30 outputs an H-level signal to the REG2 terminal of the control unit 104 as the illuminance detection signal sg2 indicating the illuminance detection result. As a result of the comparison, the illuminance detection circuit 30 outputs an L (low) level illuminance detection signal sg2 to the REG2 terminal of the control unit 104 when the divided voltage value is less than the voltage value Vref2.

The switching element Q3 is turned on when the CNT signal from the control unit 104 is at H level. In this case, the terminal Vsc and one end of the resistor R1 are connected. The switching element Q3 is turned off when the CNT signal from the control unit 104 is at L level. In this case, the terminal Vsc and one end of the resistor R1 are not connected.

Comparator Q4 compares a voltage value obtained by dividing the voltage of solar cell G by resistors R1 and R2 with voltage value Vref2 of reference voltage source Vr2 (also referred to as reference voltage value Vref2). Comparator Q4 outputs an H-level signal as illuminance detection signal sg2 to REG2 terminal of control unit 104 when the divided voltage value is equal to or higher than voltage value Vref2 as a result of the comparison. Further, the comparator Q4 outputs an L-level illuminance detection signal sg2 to the REG2 terminal of the control unit 104 when the divided voltage value is less than the voltage value Vref2 as a result of the comparison. Here, the voltage value Vref2 of the reference voltage source Vr2 is a voltage value corresponding to a predetermined illuminance. The predetermined illuminance is an illuminance that can supply power enough to drive the display unit 40 .

Assume that the maximum voltage value when the electrodes of the solar cell G are open is 3.6 [V]. Moreover, the voltage value is 0 V when the solar cell G is not irradiated with light. In this case, the voltage value Vref2 of the reference voltage source Vr2 is a voltage value between 0 [V] and 3.6 [V].

The control unit 104 measures time using the frequency signal output from the frequency dividing circuit 103 and outputs time information to the display driving circuit 105 . Also, the control unit 104 generates the timing for detecting the illuminance using the frequency signal output from the frequency dividing circuit 103 .
When the overcharge prevention signal sg1 indicating the overcharge state output from the overcharge prevention circuit 20 is at the H level, the control unit 104 determines that the secondary battery E is in a nearly fully charged state. When it is determined that the state of charge is close to full charge, the control unit 104 outputs an L-level CNT signal to the illuminance detection circuit 30, does not turn on the switching element Q3, and outputs the overcharge prevention signal sg1. Based on this, it is determined that there is illuminance.
When the overcharge prevention signal sg1 output from the overcharge prevention circuit 20 is at the L level, the control unit 104 controls the switching element Q3 to the ON state at the timing of measuring the illuminance, and detects the illuminance output from the comparator Q4. Based on the signal sg2, it is determined whether or not the illuminance is equal to or higher than a predetermined illuminance. When the illuminance detection signal sg2 is at H level, the control unit 104 determines that the illuminance is equal to or higher than a predetermined illuminance. The control unit 104 determines that the illuminance is less than a predetermined illuminance when the illuminance detection signal sg2 is at L level. The control unit 104 controls each circuit to enter the power saving mode when, for example, less than a predetermined illuminance has continued for a predetermined time or longer. Here, the predetermined time is 30 minutes, for example. Note that the power saving mode is controlled so that the display unit 40 does not display.

The display driving circuit 105 causes the display unit 40 to display information such as time based on the time information output by the control unit 104 .
The display unit 40 is, for example, a liquid crystal display (LCD) or an organic EL (electroluminescence) display. The display unit 40 displays, for example, time information, information on the remaining amount of the secondary battery E, information on illuminance, and the like, by means of the display drive circuit 105 .

Next, the voltage values when the electrodes of the solar cell G are open and when they are short-circuited will be described.
FIG. 2 is a diagram showing the output characteristics (IV curve) of the solar cell G. FIG. In FIG. 2, the horizontal axis is voltage and the vertical axis is current. FIG. 2 is a diagram showing that the voltage V generated between the electrodes of the solar cell G changes according to the load (output current I) connected to the solar cell G. As shown in FIG.

A curve g21 is the output characteristic of the solar cell at the first illuminance, and shows that the power obtained changes according to the connected load. Curve g21 shows the short-circuit current when both ends of the solar cell are short-circuited when the current value is 0 [V], and when the load resistance connected to the solar cell gradually increases from 0Ω, the output It is a characteristic of voltage versus current that indicates that the voltage rises, and the voltage value when the output current value is 0 [A], which corresponds to an infinite load resistance, indicates the release voltage when both ends of the solar cell are released. be. A curve g22 is the output characteristic of the solar cell G when the second illumination is higher than the first illumination. A curve g23 is the output characteristic of the solar cell G at a third illuminance higher than the second illuminance.

A straight line g31 represents an image of a load line when the electrodes of the solar cell G are open. Point g1 is the output voltage (at terminal Vsc and terminal CN1) of solar cell G, and point g11 is the voltage (at terminal CN2) divided by resistors R1 and R2. A straight line g32 represents an image of a load line when the electrodes of the solar cell G are short-circuited.

When the illuminance is high and the electrodes of the solar cell G are short-circuited by the overcharge protection circuit 20, the output voltage of the solar cell G is open as indicated by the arrow g2 in FIG. The voltage value at short circuit (point g3) is lower than the voltage value at short circuit (point g1).

For example, when the illuminance is as low as about 200 [lux] and the electrodes of the solar cell G are short-circuited, the voltage at the terminal CN2 input to the comparator Q4 when detected by the illuminance detection circuit 30 is the arrow in FIG. As shown by g12, the voltage value at short circuit (point g13) is lower than the voltage value at open circuit (point g11). Here, the reference voltage value Vref2 (first detection value) is set to 0.8 [V]. In this case, if the electrodes of the solar cell G are open, the voltage value input to the comparator Q4 is, for example, 0.9 [V], which is 0.8 of the reference voltage value Vref2 (first detected value). Since it is more than [V], it is judged that it is more than predetermined illuminance. However, when the electrodes of the solar cell G are short-circuited, the voltage value input to the comparator Q4 is, for example, 0.7 [V], and the reference voltage value Vref2 (first detected value) is 0.8 [V]. Therefore, the conventional method erroneously determines that the illuminance is less than the predetermined illuminance. Therefore, in this embodiment, when the overcharged state is detected, it is determined that the illuminance is equal to or higher than the predetermined illuminance.

Next, an example of a processing procedure performed by the clock 1 will be described.
FIG. 3 is a flow chart showing an example of a processing procedure performed by the timepiece 1 according to this embodiment. In the initial state, the CNT signal output from control unit 104 is assumed to be at H level (switching element Q3 is off).

(Step S<b>1 ) The control unit 104 acquires an overcharge prevention signal sg<b>1 output by the overcharge prevention circuit 20 . Subsequently, the control unit 104 determines whether or not the secondary battery E is in a nearly fully charged state based on whether the overcharge prevention signal sg1 is at H level or L level. If the controller 104 determines that the state of charge is close to full charge (step S1; YES), the process proceeds to step S2, and if it determines that the state of charge is not close to full charge (step S1; NO), The process proceeds to step S4.

(Step S2) The comparator Q1 of the overcharge prevention circuit 20 controls to short-circuit the electrodes of the solar cell G by turning on the switching element Q2. In this embodiment, this state is referred to as the overcharge protection circuit 20 being in the ON state. The control unit 104 proceeds to the process of step S3.

(Step S3) Since the overcharge prevention signal sg1 is at H level, the control unit 104 determines that the illuminance is equal to or higher than the predetermined illuminance, that is, there is illuminance. In this case, the control unit 104 does not control each component of the timepiece 1 to the power saving mode. After processing, the control unit 104 returns the processing to step S1.

(Step S4) The control unit 104 controls the illuminance detection circuit 30 to the ON state by outputting the L-level CNT signal at the timing of detecting the illuminance. As a result, the switching element Q3 of the illuminance detection circuit 30 is switched to the ON state. When the overcharge prevention signal sg1 is at the L level, the control unit 104 switches the switching element Q2 to the OFF state and releases the short circuit between the electrodes of the solar cell G. FIG. After processing, the control unit 104 advances the processing to step S5.

(Step S5) The comparator Q4 detects the illuminance by comparing the voltage value obtained by dividing the voltage of the solar cell G by the resistors R1 and R2 with the reference voltage value Vref2 of the reference voltage source Vr2. As a result of comparing the divided voltage value and the reference voltage value Vref2, the comparator Q4 outputs an H-level illuminance detection signal sg2 to the control unit 104 when the divided voltage value is equal to or higher than the reference voltage value Vref2. Alternatively, the comparator Q4 outputs an L-level illuminance detection signal sg2 to the control unit 104 when the divided voltage value is less than the reference voltage value Vref2. After processing, the control unit 104 advances the processing to step S6.

(Step S6) If the illuminance detection signal sg2 output from the comparator Q4 is at the H level, that is, if the detected value is equal to or greater than the reference voltage value Vref2 (Step S6; YES), the controller 104 proceeds to the process of Step S7. . If the illuminance detection signal sg2 output from the comparator Q4 is at L level, that is, if the detected value is less than the reference voltage value Vref2 (step S6; NO), the control unit 104 proceeds to step S8.

(Step S7) The control unit 104 determines that the illuminance is equal to or higher than the predetermined illuminance, and proceeds to the process of step S10.

(Step S8) The control unit 104 determines that the illuminance is less than the predetermined illuminance, and proceeds to the process of step S9.
(Step S9) The control unit 104 controls each component of the timepiece 1 to the power saving mode. After processing, the control unit 104 advances the processing to step S10. Note that the control unit 104 may perform control to enter the power saving mode when the state of no illuminance continues for a predetermined time.

(Step S10) The control unit 104 controls the illuminance detection circuit 30 to the off state by outputting the CNT signal of H level. As a result, the switching element Q3 of the illuminance detection circuit 30 is switched from the ON state to the OFF state. After processing, the control unit 104 returns the processing to step S1.

As described with reference to FIG. 3, in this embodiment, when the overcharge prevention circuit 20 detects that the overcharge state is present, the illuminance detection circuit 30 detects that the illuminance is equal to or higher than a predetermined illuminance, and when the overcharge state is not detected, the illuminance detection circuit 30 detects the illuminance. is used to detect whether the illuminance is greater than or equal to a predetermined illuminance or less than the predetermined illuminance. Thereby, according to this embodiment, when the solar cell G is sufficiently irradiated, it can be appropriately determined that the illuminance is equal to or higher than the predetermined illuminance.

Here, for example, when the clock 1 is under the sleeve of the clothes and the irradiation to the solar cell G is cut off, when the clock 1 is exposed from the sleeve, the solar cell G immediately generates power to restart the time display. I want to let Therefore, even in the power saving mode, the control unit 104 may detect the illuminance once every two seconds, for example. Note that the control unit 104 performs illuminance detection, for example, once per minute during normal operation.

Here, an example of processing in the case where the electrodes of the solar cell are short-circuited when overcharging occurs as in the conventional art and the illuminance is detected during that time will be described.
FIG. 4 is a flow chart in the case where the electrodes of the solar cell are short-circuited when overcharging occurs according to the prior art, and the illuminance is detected during that time. It is assumed that the configuration of the conventional timepiece is the same as that of the timepiece 1 shown in FIG. 1, for example.

(Step S901) Based on the signal output from the comparator of the overcharge prevention circuit, the control unit detects that the secondary battery is in an overcharged state close to full charge.
(Step S902) The controller controls the overcharge protection circuit to short-circuit the electrodes of the solar cell. In this case, as described with reference to FIG. 2, since the electrodes of the solar cell are short-circuited, the voltage value of the solar cell is lower than the actual voltage value.

(Step S903) Based on the signal output by the comparator of the illuminance detection circuit, the control unit erroneously detects that the illuminance is less than a predetermined illuminance.
(Step S904) The control unit controls each component of the watch to the power saving mode.

In this way, in the conventional technology, if the illuminance is detected when the secondary battery is in an overcharged state close to being fully charged, the voltage value of the solar battery will drop below the actual voltage value, so that it will be erroneously detected that the illuminance is less than the predetermined illuminance. It will be done. This erroneous detection causes the watch to be controlled to the power saving mode. Here, when the secondary battery is in an overcharged state close to full charge, it is a state in which a sufficient amount of light is applied to the solar cell and sufficient power generation is being performed. That is, in reality, the illuminance is equal to or higher than the predetermined illuminance.
On the other hand, in the present embodiment, when an overcharged state close to full charge is detected, the controller determines that the illuminance is equal to or higher than the predetermined illuminance based on the detection result of the overcharge prevention circuit 20 instead of the detection result of the illuminance detection circuit 30. made to judge. As a result, according to the present embodiment, even if the secondary battery E is in an overcharged state close to full charge, the power generation state of the solar cell G can be detected with high accuracy.

As described above, conventionally, when the secondary battery is fully charged and the overcharge protection circuit is in operation, illuminance detection is erroneously detected, and the system switches to the power saving mode even though power is being generated. . According to the embodiment, it is possible to prevent a transition to the power saving mode due to an erroneous illuminance detection determination that occurs while the overcharge prevention circuit is operating in a fully charged state.

Although FIG. 1 illustrates an example in which the clock 1 is a digital clock, the clock may be an analog clock.
FIG. 5 is a block diagram showing a configuration example when the timepiece 1A according to this embodiment is an analog timepiece. As shown in FIG. 5, a timepiece 1A includes a secondary battery E, a solar cell G, a diode D1, a resistor R1, a resistor R2, a control circuit 10A, and a display section 40A.

The display section 40A includes an hour hand 40a, a minute hand 40b, and a second hand 40c.
The control circuit 10A includes a power supply circuit 101, an oscillation circuit 102, a frequency dividing circuit 103, a control section 104A, an overcharge prevention circuit 20, an illuminance detection circuit 30, a first pointer driving section 106a, a second pointer driving section 106b, and a third pointer. It has a driving portion 106c, a first motor 107a, a second motor 107b, a third motor 107c, a train wheel 108a, a train wheel 108b, and a train wheel 108c. Components having the same functions as those of the timepiece 1 are denoted by the same reference numerals, and descriptions thereof are omitted.

A timepiece 1A shown in FIG. 5 is an example of an analog timepiece that includes an hour hand 40a, a minute hand 40b, and a second hand 40c. Note that the number of pointers is not limited to three. The number of pointers may be one or four or more. The watch 1A may further include a display drive circuit 105 and a display section 40 such as a liquid crystal display section.

104 A of control parts perform an overcharge prevention process and an illumination intensity detection process like the control part 104. FIG. In addition, the control section 104A controls the first pointer driving section 106a, the second pointer driving section 106b, and the third pointer driving section 106c according to the measured time information.

The first pointer driving section 106a generates a pulse signal for rotating the first motor 107a forward or backward under the control of the control section 104A. The first pointer driving section 106a drives the first motor 107a with the generated pulse signal.

The second pointer driving section 106b generates a pulse signal for rotating the second motor 107b forward or backward under the control of the control section 104A. The second pointer driving section 106b drives the second motor 107b with the generated pulse signal.

The third pointer driving section 106c generates a pulse signal for forward or reverse rotation of the third motor 107c under the control of the control section 104A. The third pointer driving section 106c drives the third motor 107c with the generated pulse signal.

Each of the first motor 107a, the second motor 107b, and the third motor 107c is, for example, a stepping motor. The first motor 107a drives the hour hand 40a via the wheel train 108a in accordance with the pulse signal output by the first pointer driving section 106a. The second motor 107b drives the minute hand 40b via the train wheel 108b in accordance with the pulse signal output by the second pointer driving section 106b. The third motor 107c drives the second hand 40c via the gear train 108c in accordance with the pulse signal output by the third pointer driving section 106c.

Each of the train wheel 108a, the train wheel 108b, and the train wheel 108c includes at least one gear. For example, the train wheel 108c is configured such that the second hand 40c rotates once in 60 steps, and the train wheel 108b is configured such that the minute hand 40b rotates once in 360 steps.
The hour hand 40a, minute hand 40b, and second hand 40c are each rotatably supported by a support (not shown).

When the control unit 104A determines that the illuminance is less than the predetermined illuminance, the second hand 40c stops moving and only the hour hand 40a and the minute hand 40b move to display the current time. The power saving mode is controlled by changing the cycle of the minute hand to 10 seconds. Alternatively, the control unit 104A may control the power saving mode by stopping the operation of the hour hand 40a and the minute hand 40b, for example.

Similarly to the timepiece 1, the timepiece 1A, which is an analog timepiece shown in FIG.

[Second embodiment]
In the first embodiment, when the overcharge prevention circuit 20 detects that the overcharge state is present, the illuminance detection circuit 30 detects whether or not the illuminance is above the predetermined illuminance when the overcharge state is not detected. Although an example of detecting that the illuminance is less than the predetermined illuminance has been described, detection and determination of the illuminance are not limited to this.

The configuration of the timepiece 1 of the second embodiment (FIG. 1) is the same as that of the first embodiment, or the configuration of the timepiece 1A (FIG. 5) is the same as that of the first embodiment. In the following example, the configuration of the watch 1 will be used to explain an example of the processing procedure. When the configuration is the clock 1A, the processing of the control unit 104 is performed by the control unit 104A.
FIG. 6 is a flow chart showing an example of a processing procedure performed by the timepiece 1 according to this embodiment. It is assumed that the CNT signal output from the control unit 104 is at H level in the initial state.

(Step S<b>101 ) The control unit 104 acquires the overcharge prevention signal sg<b>1 output by the overcharge prevention circuit 20 . Subsequently, the control unit 104 determines whether or not the secondary battery E is in a nearly fully charged state based on whether the overcharge prevention signal sg1 is at H level or L level. If the control unit 104 determines that the state of charge is close to full charge (step S101; YES), the process proceeds to step S102, and if it determines that the state of charge is not close to full charge (step S101; The process proceeds to step S103.

(Step S102) The control unit 104 sets an overcharge flag, and proceeds to the process of step S103.

(Step S103) The comparator Q1 of the overcharge prevention circuit 20 controls to short-circuit the electrodes of the solar cell G by turning on the switching element Q2. The control unit 104 proceeds to the process of step S104.

(Step S104) The control unit 104 controls the illuminance detection circuit 30 to the ON state by outputting the L-level CNT signal at the timing of detecting the illuminance. As a result, the switching element Q3 of the illuminance detection circuit 30 is switched to the ON state. After processing, the control unit 104 advances the processing to step S105.

(Step S105) The comparator Q4 compares the voltage value obtained by dividing the voltage of the solar cell G by the resistors R1 and R2 with the first detected value (reference voltage value Vref2) of the reference voltage source Vr2, thereby determining the illuminance. to detect Note that the first detection value is, for example, a voltage value of 0.8 [V] corresponding to 200 [lux]. After processing, the control unit 104 advances the processing to step S106.

(Step S106) When the illuminance detection signal sg2 output from the comparator Q4 is at H level, that is, when the detected value is equal to or greater than the first detected value (reference voltage value Vref2) (step S106; YES), the control unit 104 The process proceeds to step S109. When the illuminance detection signal sg2 output from the comparator Q4 is at L level, that is, when the detected value is less than the first detected value (reference voltage value Vref2) (step S106; NO), the control unit 104 performs the process of step S107. proceed to

(Step S107) The control unit 104 determines whether or not the overcharge flag is set. If the control unit 104 determines that the overcharge flag is set (step S107; YES), the process proceeds to step S109, and if it determines that the overcharge flag is not set (step S107; NO), The process proceeds to step S108.

(Step S108) The control unit 104 determines that the illuminance is less than the predetermined illuminance, and proceeds to the process of step S110.
(Step S109) The control unit 104 determines that the illuminance is equal to or higher than the predetermined illuminance, and advances the process to step S110. Note that, as in the first embodiment, the control unit 104 controls the watch 1 to enter the power saving mode when the illuminance below a predetermined level continues for a predetermined period of time.

(Step S110) The control unit 104 controls the illuminance detection circuit 30 to the off state by outputting the CNT signal of H level. As a result, the switching element Q3 of the illuminance detection circuit 30 is switched from the ON state to the OFF state. After processing, the control unit 104 returns the processing to step S101.

As described above, in the present embodiment, the overcharge flag is set when the overcharge prevention circuit 20 detects the overcharge state. In this embodiment, when the first detection value detected by the illuminance detection circuit 30 is in the overcharge state, that is, when the overcharge flag is set, the illuminance detection value is erroneously detected as being less than the first detection value. However, it is determined that the illuminance is equal to or higher than the predetermined illuminance. Thereby, according to this embodiment, when the solar cell G is sufficiently irradiated, it can be appropriately determined that the illuminance is equal to or higher than the predetermined illuminance. Also in the present embodiment, as in the first embodiment, it is possible to prevent transition to the power saving mode due to erroneous illuminance detection determination that occurs while the overcharge prevention circuit 20 is operating in a fully charged state. .

A program for realizing all or part of the functions of the control unit 104 (or 104A) in the present invention is recorded on a computer-readable recording medium, and the program recorded on this recording medium is read into the computer system. All or part of the processing performed by the control unit 104 (or 104A) may be performed by setting and executing. It should be noted that the "computer system" referred to here includes hardware such as an OS and peripheral devices. Also, the "computer system" includes a WWW system provided with a home page providing environment (or display environment). The term "computer-readable recording medium" refers to portable media such as flexible discs, magneto-optical discs, ROMs and CD-ROMs, and storage devices such as hard discs incorporated in computer systems. In addition, "computer-readable recording medium" means a volatile memory (RAM) inside a computer system that acts as a server or client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. , includes those that hold the program for a certain period of time.

Further, the above program may be transmitted from a computer system storing this program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in a transmission medium. Here, the "transmission medium" for transmitting the program refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line. Further, the program may be for realizing part of the functions described above. Further, it may be a so-called difference file (difference program) that can realize the above-described functions in combination with a program already recorded in the computer system.

As described above, the mode for carrying out the present invention has been described using the embodiments, but the present invention is not limited to such embodiments at all, and various modifications and replacements can be made without departing from the scope of the present invention. can be added.

1, 1A... clock, E... secondary battery, G... solar battery, D1... diode, R1, R2... resistance, 10, 10A... control circuit, 40, 40A... display unit, 101... power supply circuit, 102... oscillation circuit , 103... Frequency dividing circuit 104, 104A... Control section 105... Display drive circuit 20... Overcharge prevention circuit 30... Illuminance detection circuit Q1, Q4... Comparator, Q2, Q3... Switching element, Vr1, Vr2 Reference voltage source 106a First pointer driving unit 106b Second pointer driving unit 106c Third pointer driving unit 107a First motor 107b Second motor 107c Third motor 108a Wheel row, 108b... train wheel, 108c... train wheel, 40a... hour hand, 40b... minute hand, 40c... second hand

Claims (7)

a solar cell having a solar panel;
a secondary battery charged from the solar battery;
an overcharge prevention circuit that detects the state of charge of the secondary battery;
an illuminance detection circuit that detects whether the illuminance irradiated to the solar panel is equal to or higher than a predetermined illuminance, based on the voltage value across the solar panel;
When the overcharge prevention circuit detects an overcharged state, the solar cell is short-circuited, the illuminance irradiated to the solar panel is determined to be equal to or higher than a predetermined illuminance, and the overcharge prevention circuit is overcharged. a control unit that determines whether or not the illuminance is equal to or higher than the predetermined illuminance based on the value detected by the illuminance detection circuit without short-circuiting the solar cell when detecting that the solar cell is not in a charged state;
with
the solar cell, the overcharge protection circuit, and the illuminance detection circuit are connected in parallel;
The control unit
when the overcharge prevention circuit detects that the overcharge state is not overcharged, the first detection value detected by the illuminance detection circuit determines that the illuminance radiated to the solar panel is less than a predetermined illuminance;
wherein, when the overcharge prevention circuit detects an overcharge state, the first detection value detected by the illuminance detection circuit is used to determine that the illuminance radiated to the solar panel is equal to or higher than a predetermined illuminance. . a solar cell having a solar panel;
a secondary battery charged from the solar battery;
an overcharge prevention circuit that detects the state of charge of the secondary battery;
an illuminance detection circuit that detects whether the illuminance irradiated to the solar panel is equal to or higher than a predetermined illuminance, based on the voltage value across the solar panel;
When the overcharge prevention circuit detects an overcharged state, the solar cell is short-circuited, the illuminance irradiated to the solar panel is determined to be equal to or higher than a predetermined illuminance, and the overcharge prevention circuit is overcharged. a control unit that determines whether or not the illuminance is equal to or higher than the predetermined illuminance based on the value detected by the illuminance detection circuit without short-circuiting the solar cell when detecting that the solar cell is not in a charged state;
a display unit;
The predetermined illuminance is an illuminance that can supply power capable of driving the display unit.
A clock with the solar cell, the overcharge protection circuit, and the illuminance detection circuit are connected in parallel;
When the overcharge prevention circuit detects that the overcharge prevention circuit is not in an overcharge state, the control unit detects that the illuminance applied to the solar panel is equal to or higher than a predetermined illuminance based on the detection value detected by the illuminance detection circuit. 3. The timepiece according to claim 1 or 2 , which determines whether or not there is. The control unit
When the overcharge prevention circuit detects that the overcharge state is not overcharged, and when the detection value detected by the illuminance detection circuit is equal to or greater than a predetermined value, it is determined that the illuminance irradiated to the solar panel is equal to or greater than the predetermined illuminance. judge,
4. The timepiece according to claim 3 , wherein when the detected value detected by said illuminance detection circuit is less than a predetermined value, it is determined that the illuminance radiated to said solar panel is less than a predetermined illuminance. An electronic device comprising the timepiece according to any one of claims 1 to 4 . a solar battery having a solar panel, a secondary battery charged from the solar battery, an overcharge prevention circuit for detecting the charging state of the secondary battery, and a voltage value between both ends of the solar panel. an illuminance detection circuit for detecting whether the illuminance illuminating the panel is equal to or higher than a predetermined illuminance, the method comprising:
When the control unit detects that the overcharge prevention circuit is in an overcharge state, the control unit short-circuits the solar cell, determines that the illuminance radiated to the solar panel is equal to or higher than a predetermined illuminance, and determines the overcharge. determining whether the illuminance is equal to or higher than the predetermined illuminance based on the value detected by the illuminance detection circuit without short-circuiting the solar cell when the prevention circuit detects that the battery is not in an overcharged state;
including
the solar cell, the overcharge protection circuit, and the illuminance detection circuit are connected in parallel;
The control unit
when the overcharge prevention circuit detects that the overcharge state is not overcharged, the first detection value detected by the illuminance detection circuit determines that the illuminance radiated to the solar panel is less than a predetermined illuminance;
wherein, when the overcharge prevention circuit detects an overcharge state, the first detection value detected by the illuminance detection circuit is used to determine that the illuminance radiated to the solar panel is equal to or higher than a predetermined illuminance. illuminance judgment method. a solar battery having a solar panel, a secondary battery charged from the solar battery, an overcharge prevention circuit for detecting the charging state of the secondary battery, and a voltage value between both ends of the solar panel. An illuminance determination method for a timepiece having an illuminance detection circuit for detecting whether or not the illuminance illuminating a panel is equal to or higher than a predetermined illuminance, and a display unit, comprising:
When the control unit detects that the overcharge prevention circuit is in an overcharge state, the control unit short-circuits the solar cell, determines that the illuminance radiated to the solar panel is equal to or higher than a predetermined illuminance, and determines the overcharge. determining whether the illuminance is equal to or higher than the predetermined illuminance based on the value detected by the illuminance detection circuit without short-circuiting the solar cell when the prevention circuit detects that the battery is not in an overcharged state;
including
The illuminance determination method for a timepiece, wherein the predetermined illuminance is an illuminance capable of supplying power for driving the display unit .

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