JPS647325B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an improvement in a display device for a measuring instrument that displays measurement information on a display section using a light emitting diode, and in particular, by changing the display color according to changes in measurement values, the measurement information can be displayed in a The present invention provides a multicolor display device for a measuring instrument that facilitates instantaneous reading.

Conventionally, the measured values of measuring instruments such as ammeters and voltmeters have been displayed in an analog manner using a display needle. However, in recent years, measurement value display using digital or analog display using various electro-optical display elements has been put into practical use, making it possible to display measurement values that are accurate and easy to read. Furthermore, as an aspect of this improved measurement display, a measurement display device that changes the color of the display element based on a set value has been proposed. According to this device, for example, overrev display in rotation speed measurement has been proposed. , can be displayed clearly by changing the display color.

Since it is impossible to change the emitted light color of a display section made up of light emitting diodes with a single light emitting diode chip, at present two or more sets of light emitting diode chips with different light emitting colors are provided in the mold part, and each chip has a Attach the anode wire and cathode wire,
A method is used in which a light emitting diode chip of any 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.

The present invention has been made in view of the above-mentioned conventional problems, and its purpose is to configure a light emitting diode display section that accurately and easily reads measurement information of a measuring instrument without complicating the structure of the device or the driving method. Another object of the present invention is to provide a multicolor display device for a measuring instrument whose display color changes stepwise in response to changes in measured values.

In order to achieve the above object, the present invention comprises each display segment of the light emitting diode of the display section by a plurality of light emitting diode chips with different light emitting colors and light emitting current characteristics using an anode and a cathode as common electrodes. The display color of each display segment is changed by changing the voltage supplied to each display segment in accordance with the change in the measured value.

Hereinafter, preferred embodiments of the present invention will be described based on the drawings.

FIG. 2 shows the appearance of each display segment in a display device for displaying voltage values and engine speed as an automobile instrument according to the present invention, and FIG. 3 shows the display segments shown in FIG. An enlarged view of the area surrounded by is shown.

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 the 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 electrode 30 on the anode side by wire bonding. 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-emission intensity characteristic curve shown in the figure, the supply current I ₁ at which the emission intensity of the light-emitting diode chip 26 is saturated is lower than the supply current I ₃ at which the 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 voltage and engine speed measuring device installed in an automobile according to an embodiment of the present invention. The voltage value detection circuit 40 detects the battery voltage value of an automobile, and the voltage value detected there is converted into a digital signal by an AD converter 42. In this A-D converter 42, the voltage value
Signals for the tens digit, ones digit, and 1/10 digit are output to the display switching circuit 54. The display switching circuit 54 is connected to a "V" code signal generator 50 for mode display, an "O" code signal generator 46 for 1/100 digit display, and a "." code signal generator for decimal point display. The signal from the device 48 is being output.

The rotation speed detection circuit 56 detects the rotation speed of the automobile engine, and the rotation speed detected there is converted into a digital signal by an A-D converter 57.
This converter 57 has 1000 digits of rotation speed and 100 digits of rotation speed.
A signal of the digit is output to the display switching circuit 54. In addition, this display switching circuit 54 is connected to an "rpm" code signal generator 64 for remote display, an "O" code signal generator 60 for displaying the digit of 10, and an "O" code signal for displaying the digit of 1. A signal from the generator 62 is being output.

The changeover switch 52 selectively converts the code signal for voltage value display and the code signal for rotation speed display applied to the display switching circuit 54 to a decoder 68.
The selection is normally made by the user's operation. The signal from the decoder 68 is then transmitted to the driver 70.
A voltage value display or a rotation speed display can be displayed on the display section 72 shown in FIG. 2 via.

On the other hand, the A-D converter 42 for voltage value display and the A-D converter 57 for rotation speed display output digital signals to comparison circuits 44 and 58, respectively. The comparison circuits 44 and 58 compare the digital signals of the respective A-D converters 42 and 57, and can output three display color detection signals according to the voltage value or rotation speed. For the display color detection signals 45a to 45c outputted from the comparison circuit 44, a signal line that outputs at H level is selected depending on a change in the voltage value of the battery of the automobile. That is, the signal line 45a,
Either 45b or 45c becomes H depending on the voltage value of the battery, and although the range of the actual voltage value at the time of detection is three levels, it can be determined.
The voltage value range of these three signal lines 45a to 45c is set in advance, for example, a range of 12V or more where the state of charge is good, a range of 11 to 12V where it is possible to drive but requires some charging, and a range where charging is required urgently. Three states can be set, including a range of 11V or less.

Display color detection signal 5 output from comparison circuit 58
Signal lines 9a to 59c are selected to output at H level depending on the change in engine speed. That is, the signal line 59a, 59b or 59c is
Which one becomes H depending on the engine rotational speed, and although the range of the actual value of the rotational speed at the time of detection is in three stages, it is possible to discriminate. These three signal lines 59a to 5
The rotation speed range according to 9c is preset, for example, the rotation speed range 1000 to 1000 in normal operation.
Three states can be set: 4500rpm, cautionary rotational speed area (commonly known as yellow zone) of 4500 to 5500rpm, and dangerous rotational speed area (commonly known as red zone) of 5500rpm or more.

Display color detection signals 45a to 45c and 59a to 59c from comparison circuits 44 and 58 are input to display color detection signal switching circuit 60. The display color detection signal switching circuit 60 selects one of the display color detection signals 45a to 45c from the comparison circuit 44 and the display color detection signals 59a to 59c from the comparison circuit 58 to the driver 70 according to the output signal from the off switch 52. supply by switching to . The driver 70 receives three types of current 86 from the current control circuit 80.
~90 are supplied. This current control circuit 80
connects resistors 83 and 84 in series with the DC power supply 92, and supplies currents 86 to 90 with different current values, respectively.
It forms the These three types of supply currents 86 to 90 are the display color detection signal 45 supplied from the display color detection signal switching circuit 66 to the driver 70.
A to 45c and 59a to 59c are selected and supplied to a display section 72 comprised of light emitting diodes. That is, the supply currents 86 to 90 supplied to the display section 72 are selectively controlled by changes in the battery voltage value or the engine rotation speed. In addition, in the figure, 94 is a regulating resistor.

The display device as an automobile meter according to the present invention has the above configuration, and its operation will be explained below. Which display function is displayed on the display section 72 is determined by operating the changeover switch 52. For example, in the case where a voltage value is displayed by operating the changeover switch 52, the code signal output from the display changeover circuit 54 to the decoder 68 converts information from the voltage value detection circuit 40 into the A-D converter 42. It is the one that has been converted. This signal is further supplied to the display section 72 via the driver 70, making it possible to display the battery voltage value as shown in FIG.

On the other hand, when the changeover switch 52 is operated to display the rotation speed, the code signal output from the display switching circuit 54 to the decoder 68 is obtained by converting information from the rotation speed detection circuit 56 by the A-D converter 57. The decoder 68 displays the engine rotational speed as shown in FIG. 8 on the display section 72 via the driver 70. Three types of currents 8 are supplied to the driver 70 from a current control circuit 80.
6, 88 or 90 are supplied, and these 3
The light emitting diodes of the display section 72 emit light with the seed supply currents 86 and 90. Supply current here 8
6, 88 or 90 are display color detection signals 45a to 45c from the comparator circuit 44 when displaying voltage values.
When the rotation speed is displayed, display color detection signals 59a to 59 from the comparison circuit 58 are selected.
The selection is controlled by c.

As described above, the display unit 72 is configured such that the color of light emitted from the light emitting diode changes depending on the supplied current, and the display unit 72 is configured such that the color of the light emitted from the light emitting diode changes depending on the supplied current.
The selection control 90 is used to change the color of light emitted from the display section 72. That is, the color of the light emitted from the light emitting diode of the display section 72 can be changed in three stages depending on the battery voltage value or the engine rotation speed. Therefore, when determining the numerical value displayed on the display section 72, the user (driver) can judge the voltage value or the displayed value of the rotational speed simply by looking at the emitted light color, and especially the rotational speed display. In some cases, this has the effect of making it extremely easy to check whether the engine speed has reached a cautionary speed range or a dangerous speed range as the engine speed increases.

FIG. 9 is a block diagram showing the configuration of a VU meter as another embodiment of the present invention. This VU meter (Volume unit indicator) displays the audio level using an analog bar display, and is usually incorporated into recording equipment. Input circuit 10
0 is a circuit for detecting the audio level, and the signal from this input circuit 100 is integrated by an integrating circuit 102. The output signal from the integrating circuit 102 is converted by the voltage discrimination circuit 103 into a level signal 104 with nine levels, and this level signal 104 causes the corresponding segment of the bar segment 110 of the display section 108 to emit light via the driver 106. . The bar segment 110 of the display section 108 is composed of two types of light emitting diode chips having different emission colors and emission current characteristics similar to those shown in FIGS. 2 and 3, with the anode and cathode used as common electrodes. The color of the emitted light changes depending on the current.

The output of the level signal 104 from the voltage discrimination circuit 103 is a low level output 104a to a high level output 1.
It takes the form of integrated output according to the level of the integrating circuit 102 up to 04i, and the audio level can be determined by the lighting length of the bar segment 110 on the display section 108. The current control circuit 120 is a circuit for obtaining three types of supply currents from a power supply 128, and three types of supply currents 130, 132, and 134 are supplied to the driver 106 from respective resistors 122 and 124. Comparison circuit 136 detects three level values from level signals 104a to 104i from voltage discrimination circuit 103, and selectively controls the supply current from current control circuit 120 based on the level values. That is, three types of display color detection signals 138 to 142 are selectively outputted from the comparison circuit 136, and the supply current 130, 132 or 134 of the current control circuit 120 is adjusted based on the selected display color detection signal 138, 140 or 142. The user can select which one of the images is to be supplied to the display section 108. Therefore, the color of the light emitted from the display unit 108 can be changed in three steps depending on the audio level, and a VU meter can be provided in which changes in the audio level can also be determined by color. In addition, in the figure, 15
0 is the regulated resistance.

As explained above, in the present invention, each display segment of a light emitting diode is composed of a plurality of light emitting diode chips having different emission colors and emission current characteristics with the anode and cathode as common electrodes, and By changing the current supplied to the display segments and changing the display colors, instantaneous reading of measurement information is facilitated. The present invention provides a multicolor display device for a measuring instrument, which eliminates the need to attach an anode line and a cathode line to each chip as in the conventional device, and which greatly simplifies the device and driving method.

[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; FIG. 4 is a schematic configuration diagram showing a preferred embodiment of a display device according to the present invention. FIG. 5 is an explanatory diagram showing a supply current-emission intensity characteristic curve for each light emitting diode chip. FIG. 6 is a block circuit diagram showing an automobile meter as an embodiment of the present invention. 7th
FIG. 8 is an explanatory diagram showing a display form. FIG. 9 is a block circuit diagram of a VU meter as another embodiment of the present invention. 24... Common electrode on the cathode side, 26, 28...
...Light emitting diode chip, 30...Anode side electrode, 40...Voltage value detection circuit, 56...Rotation speed detection circuit, 44, 58, 136...Comparison circuit, 7
2,108...Display unit, 80,120...Current control circuit, 92...DC power supply, 82,83,84...
…resistance.

Claims (1)

[Claims] 1. In a display device of a measuring instrument that displays measurement information detected by a detection circuit on a display section using a light emitting diode, each display segment of the light emitting diode of the display section is connected to an anode and a cathode as a common electrode. It is composed of a plurality of light emitting diode chips having different emission colors and emission current characteristics, and is provided with a current variable means for changing the current supplied to each display segment in accordance with the change in the measurement value related to the measurement information detected by the detection circuit. A multicolor display device for a measuring instrument, characterized in that the display color changes according to changes in measured values. 2. A multicolor display device for a measuring instrument according to claim 1, characterized in that a plurality of light emitting diode chips having different emission colors and emission current characteristics are arranged alternately in a matrix. 3. In claim 1 or 2, the current variable means has a plurality of resistors connected in series to a DC power supply, and one of the intermediate potentials of each resistor is selected. A multicolor display device for a measuring instrument, characterized in that the display color is changed by changing the current supplied to each display segment by supplying the current to each display segment via a regulating resistor.