JPH0131634B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an improvement in a display device for an electronic timepiece having a time display section using a light emitting diode.

More specifically, in a watch having a solar cell and a rechargeable battery, the voltage state of the power supply unit related to the power generation state of the solar cell and the fully charged state or insufficiently charged state of the rechargeable battery is displayed by changing the display color of the display unit. It is characterized by

2. Description of the Related Art Conventionally, multicolor display devices have been proposed that can display the same time display section in two or more different colors. For example, a multicolor display device that provides two or more display colors using light emitting diodes will be described.

Since it is impossible to change the emitted light color of a digital display section composed of light emitting diodes with a single light emitting diode chip, at present two or more sets of light emitting diode chips with different emitting colors are provided in the mold part, and each chip is A method is used in which an anode wire and a cathode wire are attached to the LED, and a light emitting diode chip of one color is selectively displayed.

FIG. 1 shows the structure of a well-known dot type two-color light emitting diode. In the figure, a molded portion 12 of a light emitting diode 10 includes light emitting diode chips (for example, a red light emitting diode chip 14 and a green light emitting diode) that emit light in different colors. A chip 16) is provided.

A cathode line 18, which is a common electrode, and an anode line 20, 22 provided for each chip 14, 16 are connected to each chip 14, 16, and a current is applied to one of the anode lines 20, 22. By supplying each chip 14,
16, one of them is selectively emitted.

However, in the conventional device described above, lead wires must be attached to each of the chips 14 and 16, resulting in a problem that the device is complicated and the method for driving the device is also complicated.

Furthermore, it is necessary to arrange display segments of light emitting diodes that emit light of different colors in the same display section, the same number as the number of times the display color changes. As a result, the larger the number of times the display color of the display unit changes, the larger the display unit becomes. Furthermore, each time the display color of the display unit changes, the display position changes, making it difficult to see.

An object of the present invention is to provide an electronic timepiece having a power source including a solar cell and a rechargeable battery, in which the voltage state inside the power source related to the power generation state of the solar cell and the charging or discharging state of the rechargeable battery can be displayed at the same position on the same display section. It is an object of the present invention to provide a miniaturized multicolor display device using light emitting diodes that can display by changing display colors.

In order to achieve the above object, the present invention comprises a display segment of a light emitting diode in a display section by a large number of light emitting diode chips with an anode and a cathode as common electrodes. The voltage state of the power supply unit related to the insufficient charge state can be changed by detecting voltage changes applied from the solar cell and rechargeable battery and changing the supply current to each display segment of the display unit, thereby changing the display color of each display segment. Characterized by change.

Preferred embodiments of the present invention will be described below based on the drawings.

FIG. 2 shows the external appearance of each display segment in the multicolor display device according to the present invention, and FIG. 3 shows an enlarged view of a portion of the display segment shown in FIG. 2 surrounded by a dashed line.

In the figure, fine light emitting diode chips 26 and 28 having different emission colors and emission current characteristics are provided alternately in a matrix on the common electrode 24 on the cathode side.
can be combined in a desired luminescent color. In other words, the color of the emitted light can be changed by adding the impurity gallium (Ga) or tellurium (Te) to the main constituent gallium phosphide (GaP).For example, the desired red brightness can be achieved with _IA ampere. The resulting light emitting diode chip 26 and I _B
(I _A < I _B ) It is preferable to construct the light emitting diode chip 28 which can obtain the desired green brightness with amperes.

FIG. 4 shows a schematic configuration of a preferred embodiment of a multicolor display device according to the present invention, and in the figure, each of the light emitting diode chips 26 and 28 is connected to an anode side electrode 30 by wire bonding.
It is connected to the. Then, operate the changeover switch (not shown) to select each light emitting diode chip 2.
By changing the current supplied to 6 and 28, the display color can be changed. That is, the fifth
As can be understood from the supply current-light emission intensity characteristic curve shown in the figure, the supply current I ₁ at which the light emission intensity of the light emitting diode chip 26 is saturated is lower than the supply current I ₃ at which the light emission intensity of the light emitting diode chip 28 is saturated. It is configured. Therefore, with the supply current I ₁ , mainly the light emitting diode chip 26 emits light, and when the supply current is increased from I ₁ to I ₂ , in addition to the light emission of the light emitting diode chip 26 , the light emitting diode chip 28 also emits light.
When the light emission gradually becomes stronger and the supply current rises to _I3 , both the light emitting diode chips 26 and 28 emit light with the same light intensity, so that the light emitted by the human eye is an intermediate color between the light emission color of both the light emitting diode chips 26 and 28. It looks like it is.

FIG. 6 shows a block diagram of a multicolor display device according to an embodiment of the present invention. In the figure, a reference signal generator 36, a frequency dividing circuit 38, a clock circuit 40 for measuring the current time, and a decoder 42 are the same as those of a conventional electronic watch. Characteristically, in an electronic watch equipped with a DC power source composed of a rechargeable battery 200 and a solar cell 202 as a driving power source for the watch, the voltage state within the power supply unit, that is, the fully charged state of the rechargeable battery 200, and the solar The power generation state of the battery 202 can be displayed by changing the display color of the display unit.

Voltage dividing resistors 204 and 206 are connected in parallel with the solar cell 202 constituting the DC power supply, and a backflow blocking diode 208 and a current limiting resistor 210 are connected in series with the solar cell 202. Further, a resistor 212 and a field effect transistor (hereinafter referred to as FET) 214 are connected in parallel with the rechargeable battery 200,
The gate terminal of the FET 214 is connected to the voltage dividing resistor 204,
It is connected to the connection part 206. FET214
A switching signal 100, which is an output signal of the FET 214, is input to the display color control circuit 218 and the driver 62 from the drain terminal of the FET 214. In addition, voltage dividing resistors 220, 222, resistor 224, FET 226,
MOS inverter 228, voltage dividing resistors 97, 98,
The voltage control circuit 96 consisting of 99 is the rechargeable battery 2.
00 in parallel. And FET2
The gate terminal of 26 is connected to the voltage dividing resistors 220 and 222.
connected to the connection part. An output signal 230 from the drain terminal of the FET 226 is input to the display color control circuit 218 and the input terminal of the MOS inverter 228. Furthermore, the MOS inverter 22
The output signal 234 from the output terminal No. 8 is input to the display color control circuit 218.

The display color control circuit 218 includes an AND gate 232,
236, and gate 23
A switching signal 100, which is an output signal of the FET 214, is input to one input terminal of the FET 2,236.
The other input terminal of AND gate 232 is FET2
The output signal 230 of 26 is also connected to the AND gate 23
The output signal 234 of the MOS inverter 228 is input to the other input terminals of the MOS inverter 228, respectively. Switching signals 102, 10 are output from AND gates 232, 236.
4 is outputted and input to the driver 62 together with other switching signals 100.

The voltage control circuit 96 divides the voltage of the rechargeable battery 200 into voltages V ₁ , V ₂ , and V ₃ using voltage dividing resistors 97 , 98 , and 99 , and supplies currents corresponding to these voltages V ₁ , V ₂ , and V ₃ to the driver 62 . supply to. The driver 62 receives switching signals 100 and 10 of the display color control circuit 218.
2, 104, a preset current value is selected and supplied to the display unit 76 via the regulating resistor 63.

FIG. 7 is a diagram showing a partial configuration of the driver 62. As shown in FIG. In the figure, the driver 62 receives display switching signals 100, 102,
104 and output signal 106 from decoder 42
and gate signals 1 from AND gates 70, 72, 74 that input
08, 110, 112, the voltage control circuit 96
The control current _I 1 corresponding to the value of the control voltages V ₁ , V ₂ , V ₃ is selected from among the applied voltages V ₁ , V ₂ , and V ₃ and sent to the display section 76 via the regulating resistor 63. ,I ₂ ,
transistors 78, 80, 82 supplying _I3 ;
A plurality of current switching circuits 84 are included.

A state in which the solar cell 202 receives sufficient light and is in a power generation state, and the rechargeable battery 200 is sufficiently charged will be described. Since the voltage across resistor 206 is higher than the threshold voltage of FET 214, FET 214 is turned on and the FET
The output signal 216 of 214 becomes L. In addition, since the voltage applied to the resistor 222 is higher than the threshold voltage of the FET 226 and becomes H, the voltage applied to the FET 222 is higher than the threshold voltage of the FET 226.
6 is on, and the output signal 230 of FET 226 is L.
becomes. Output signal 23 of MOS inverter 228
4 is inverted and becomes H when the output signal 230 of the FET 226 becomes L. As a result, the switching signal 104 from the AND gate 236 of the display color control circuit 218 becomes H, and is input to the driver 62, which causes the driver 62 to output a current I ₃ corresponding to the highest voltage V ₃ output from the voltage control circuit 96. is supplied to the display unit 76 via the regulating resistor 63. When the current _I3 is supplied to the display section 76, the light emitting intensities of the light emitting diode chips 26 and 28 of the display section 76 become the same, and to the human eye it appears to be displayed in a color intermediate between red and green.

Next, a case where the solar cell 202 is in a power generation state and the rechargeable battery 200 is in a low voltage state due to insufficient charging will be described.

The voltage applied to the gate terminal of FET214 is higher than the threshold voltage, so the FET
214 is turned on, and the output signal 216 becomes L.

On the other hand, the voltage of the rechargeable battery 200 is low, and the resistor 222
The voltage divided by is below the threshold voltage of FET 226, and the output signal 230 of FET 226 becomes H.

Therefore, the switching signal 102, which is the output signal of the AND gate 232, becomes H and is input to the driver 62. The driver 62 operates at a voltage lower than the voltage V ₃ output from the voltage control circuit 96 via the regulating resistor 63.
A current I ₂ corresponding to V ₂ is selected and supplied to the display section 76. When the current I ₂ is supplied to the display section 76, the light emitting diode chip 26 emits red light in the display section 76, and the green light emission of the light emitting diode chip 28 gradually weakens, so that the human eye sees a mixed color of red and green. appears to be displayed.

Next, a state in which the watch is operating only with the rechargeable battery 200 in a state in which power generation is impossible because the solar cell 202 receives no light will be described.

Since no voltage is applied to the FET 214 because the solar cell 202 does not generate power, the FET 214 is turned off and the switching signal 1, which is the output signal of the FET 214, is turned off.
00 becomes H. Since the voltage of the rechargeable battery 200 is sufficiently high to the gate input of the FET 226, a voltage higher than the threshold voltage is applied.
FET 226 is turned on and output signal 230 becomes L. Therefore, the output signal 2 of MOS inverter 228
34 becomes H. As a result, the display color control circuit 21
The output signals of the AND gates 232 and 236 of 8 are both L, and the switching signal 1 of the display color control circuit 218 is
Only 00 becomes H and is input to the driver 62. The driver 62 selects the current I ₁ corresponding to the voltage V ₁ lower than the voltages V ₃ and V ₂ output from the voltage control circuit 96 via the regulating resistor 63 and supplies it to the display section 79 . When the current _I1 is supplied to the display section 76, the light emitting diode chip 26 mainly emits light in the display section 76, so that the display appears red to the human eye.

In this way, according to the present embodiment, the fully charged state and insufficiently charged state of the rechargeable battery 200, as well as the solar cell 2
The power generation status of 02 can be displayed by changing the display color of the display section 76, and the display section itself is also smaller than before.

FIG. 8 shows an external view of a display segment in another embodiment of the present invention. In the embodiment described above, a large number of different light emitting diode chips were arranged alternately in a matrix in each display segment, but in FIG. Two light emitting diode chips 26 and 28 are arranged, one each.

FIG. 9 shows a cross-sectional view of each display segment in FIG. 8. Light emitting diode chips 26 and 28 are placed on the cathode common electrode 301 on the insulating substrate 300.
is arranged, and further this light emitting diode chip 2
6 and 28 are connected to the same anode electrode 302. When current is supplied to both electrodes 301 and 302, when the current value is low, as in the previous embodiment, the light emitting diode chip 26 mainly emits light, and as the supplied current value increases, the light emitting diode chip 26 emits light. The light emission from the light emitting diode chips 28 becomes stronger, and finally the light emission intensities from the light emitting diode chips 26 and 28 become the same. This light emitting diode chip 26,2
The two-color light emitted from the display panel 8 is reflected by the reflecting plates 303 and 304, passes through the diffuser plate 305 and the display cover 306, and is emitted to the outside. This diffusion plate 305 is
It is attached to the entire display segment and has the effect of scattering incident light. Therefore, when the two colors of light from the light emitting diode chips 26 and 28 are incident, these lights are mixed by scattering and the light is emitted from the entire diffuser plate 305. Therefore, even if there is only one light emitting diode chip 26, 28 in each display segment, the light emitting diode chips 26, 28 can be easily changed by changing the supply current in the same way as when a large number of different light emitting diode chips 26, 28 are arranged alternately in a matrix as in the previous embodiment. The color of the emitted light can be changed freely. Further, compared to the above-described embodiments, since wire bonding and other labor are not required, a significant cost reduction can be expected, and a cheaper display device can be provided.

As described above, according to the present invention, in a watch having a solar cell and a rechargeable battery as power sources, the fully charged state and insufficiently charged state of the rechargeable battery are displayed by changing the display color of the display unit. Therefore, the user can visually check the voltage status of the rechargeable battery and the power supply section of the solar cell.

Furthermore, even if the display color changes, the display position remains the same, making it easy to see, and since the anode and cathode are common electrodes, it is much smaller and easier to drive than when each light emitting diode chip has its own electrode. The method is also simplified.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram of a conventional display device, FIG. 2 is an external view of each segment in the display device according to the present invention, FIG. 3 is a partially enlarged view of the segment shown in FIG. 2, and FIG. FIG. 5 is an explanatory diagram showing a supply current-emission intensity characteristic curve in a light emitting diode chip, and FIG. 6 is a schematic diagram showing a preferred embodiment of the display device according to the invention. The block circuit diagram shown in FIG.
A block circuit diagram showing a detailed circuit of the driver in the block circuit shown in the figure, FIG. 8 is an external view of a display segment in another embodiment of the display device according to the present invention, and FIG. 9 is a sectional view of FIG. . 24... Common electrode, 26, 28... Light emitting diode chip, 96... Voltage control circuit, 218...
Display color control circuit, 200... Rechargeable battery, 202...
solar cells.

Claims (1)

[Claims] 1. In an electronic watch equipped with a solar cell and a rechargeable battery and a time display section composed of light emitting diodes, each display segment of the light emitting diode has a different emission color and emission-voltage characteristics, and the anodes and cathodes are connected to each other. It is composed of a large number of light emitting diode chips as a common electrode, and is provided with means for detecting changes in the voltage applied from the solar cell and the rechargeable battery to change the current supplied to each display segment, and detecting the power generation state of the solar cell. A multicolor light emitting diode display device, characterized in that a change in the state of a power supply unit related to a fully charged state or an insufficiently charged state of the rechargeable battery is displayed by changing the display color of each display segment.