JPH0868986A - Back light controller - Google Patents

Abstract

PURPOSE: To obtain a back light controller capable of making the luminance of a back light uniform in a wide AC voltage range of plural rated power sources, etc. CONSTITUTION: This back light controller has an impedance circuit which is composed of capacitors 7 and 10 connected in series and a triac 11 connected in parallel with this capacitor 10 and is capable of changing impedance by turning on this triac by a triac on signal 13, diodes 8a to 8d which rectify the output of this impedance circuit, the back light 2 which emits light by the back light currents regulated by these diodes 8a to 8d and a voltage detecting means 12 which detects AC voltage and feeds the triac on signal 13 for changing the impedance to the impedance circuit according to the detection contents thereof.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backlight control device for uniforming the brightness of a backlight in a backlight power source for illuminating the back surface of a liquid crystal display regardless of the difference in input rated voltage. is there.

[0002]

2. Description of the Related Art FIG. 30 is a circuit diagram of a power supply circuit of a conventional liquid crystal display, and FIG. 31 is a circuit diagram of a conventional backlight control device. In the figure, 1 is an AC power supply, 2 is a backlight composed of, for example, a light emitting diode array, and 3 is a DC power supply circuit to which the AC power supply 1 is input.
The direct current voltage generated by is applied to the backlight 2 to light it. Reference numeral 4 is a liquid crystal display device which is turned on by the backlight 2, 5 is a liquid crystal display circuit for driving the liquid crystal display device 4, and 6 is a second direct current power supply circuit which is a power source of the liquid crystal display circuit 5, for example, direct current of DC 5V. A voltage is applied to the liquid crystal display circuit 5. Reference numeral 7 is a capacitor that acts as impedance in an alternating current circuit, 8a to 8d are diodes that rectify alternating current, and 9 is a zener diode that derives a constant voltage output. The direct current obtained by the zener diode 9 is applied to the backlight 2 and turned on. Let

In such a conventional backlight control device, when the DC power supply circuit 3 uses a constant voltage power supply, even if the AC power supply 1 fluctuates by about ± 10%, it is not affected and remains constant. Since the voltage is output, the brightness of the backlight 2 does not change. However, the rated voltage of AC power supply 1 is AC
There are various types such as 100V, AC200V, and AC240V. In order to keep the brightness constant regardless of which voltage is applied, the voltage of the AC power source 1 is, for example, AC85 to AC2.
It is necessary to use the DC power supply circuit 3 having a wide range that operates in the range of about 64V. Since this increases the cost of the device, an inexpensive method has been demanded. FIG.
Reference numeral 1 is an example in which the DC power supply circuit 3 is composed of only an unstable rectifying and smoothing circuit. Since it is an unstable power supply circuit, when the voltage of the AC power supply 1 changes, the current of the backlight 2 changes, Since the brightness is affected, it can be used only under the condition where the voltage fluctuation of the AC power supply 1 is small. Therefore, it is impossible to share the rated voltage with both AC100V and AC200V.

As a prior art related to reducing the change of the output voltage even when the power source voltage fluctuates widely, there is a power source circuit disclosed in Japanese Patent Laid-Open No. 62-117620, which has first and second impedance components. A series circuit of the third linear element is connected to a power source, a switching element is connected to both ends of the second linear element, and a control circuit for turning on and off the switching element according to the magnitude of the power source voltage is provided. We have introduced a DC circuit that has a small change in output voltage and a small power loss even when the voltage across the linear element fluctuates. Further, the backlight control device disclosed in Japanese Patent Laid-Open No. 4-53924 includes a control means for controlling the brightness of the backlight according to the detection result of the power source type detection means for the DC adapter such as an AC adapter and a dry battery. Introduces an example in which the number of parts is reduced to reduce cost and size. Further, in the motor disclosed in Japanese Patent Laid-Open No. 60-82965, an impedance element is connected in series with the main coil, and a switching element is connected in parallel with the impedance element, so that two different types of power supply voltages can be obtained. It discloses an example in which the same motor can be used.

[0005]

In the conventional backlight control device as described above, an expensive DC stabilized power supply is required to achieve uniform brightness over a wide voltage range. Further, in a device that obtains a constant voltage with a zener diode, the higher the power supply voltage, the more current flows through the zener diode, which causes heat generation.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a backlight control device which has a simple circuit configuration and can uniformize the brightness of the backlight in a wide voltage range. It is also an object of the present invention to provide an apparatus for displaying an abnormality of a device or an abnormality of a process by this apparatus.

[0007]

In the backlight control device according to the present invention, a control signal for changing the impedance according to the AC voltage detected by the AC voltage detection circuit is sent by the AC voltage detection circuit. The backlight is lit by the backlight current rectified by the rectifying circuit that rectifies the output of the impedance circuit whose impedance is changed by the control signal. In addition, the DC voltage signal output from the voltage conversion circuit for converting the AC voltage into the DC voltage signal is
An impedance circuit having a control circuit for sending a control signal for changing the impedance according to the contents of the A / D conversion data corresponding to the DC voltage signal converted by the / D conversion circuit, and the impedance being changed by the control signal The backlight current is rectified by a rectifier circuit that rectifies the output of the backlight.

Further, an impedance circuit composed of at least one capacitor and at least one triac connected in parallel, capable of inputting an AC voltage and changing the impedance by a control signal, and an output of this impedance circuit are rectified. Rectifying circuit, a backlight that emits light with the backlight current rectified by this rectifying circuit, and a switch circuit that is provided to block the backlight current with a control signal. In accordance with the above, an AC voltage detection circuit for sending a control signal for changing the impedance to the impedance circuit and for sending a control signal for blocking the backlight current to the switch circuit according to the detection content is provided. Further, an impedance circuit configured of at least one capacitor and at least one triac connected in parallel, capable of inputting an AC voltage and changing the impedance by a control signal, and a rectifying circuit for rectifying the output of the impedance circuit. A backlight that emits light with the backlight current rectified by the rectifier circuit, and a switch circuit that is provided to block the backlight current with a control signal,
A voltage conversion circuit for converting an AC voltage into a DC voltage signal, an A / D conversion circuit for A / D converting measurement data and an A / D conversion for a DC voltage signal output from the voltage conversion circuit, and this A / D conversion A corresponding to the DC voltage signal output from the circuit
The control signal for changing the impedance is sent to the impedance circuit according to the content of the / D conversion data, and the control signal for blocking the backlight current is sent to the switch circuit according to the content of the A / D conversion data corresponding to the DC voltage signal. It has a control circuit for sending.

The switch circuit is constructed by connecting a phototriac with a zero-cross function in series with an impedance circuit. The switch circuit is configured by connecting a phototriac with a zero-cross function in series to the impedance circuit and connecting a resistor in parallel to the capacitor of the impedance circuit. Furthermore, the control signal is sent to block the backlight current in a predetermined voltage range between the first predetermined voltage and the second predetermined voltage. Further, the control circuit sends a control signal to the switch circuit according to the content of the A / D conversion data corresponding to the measurement data.

Further, the backlight is composed of light emitting diodes of a plurality of colors, and a switch circuit provided so as to block the backlight current of each light emitting diode of each color by a control signal corresponds to the measurement data. The emission color of the backlight is changed by a control circuit that sends a control signal according to the content of the A / D conversion data. In addition, the multi-color light emitting diodes are of two colors, green and red, and the control circuit uses the A / A corresponding to the measurement data.
Compare the D conversion data with the preset alarm value,
According to the comparison result, the control signal is sent so that the backlight emits green light normally, emits orange light in the one-stage alarm, and emits red light in the two-stage alarm.

Further, the switch circuit repeatedly opens and closes by inputting the reference signal generated by the reference signal generating circuit as a control signal, thereby causing the backlight to flicker. Further, the control circuit sends an alarm signal obtained by comparing the A / D converted data corresponding to the measurement data with a preset alarm value as a control signal, repeatedly opening and closing the switch circuit, and flickering the backlight. It is what makes me. Further, the control circuit is provided with a gate for passing the reference signal generated by the reference signal generation circuit and input to the switch circuit, by comparing the A / D conversion data corresponding to the measurement data with a preset alarm value. By sending an alarm signal that is generated and passing the reference signal as a control signal, the switch circuit is repeatedly opened and closed to cause the backlight to flicker.

Further, the impedance circuit is composed of a plurality of capacitors connected in series and a triac provided in parallel with a part of the capacitors, and by turning on / off the triac by a control signal,
It changes the impedance. In addition, the impedance circuit, a plurality of capacitors connected in parallel,
It is composed of triacs provided in series with some capacitors, and the impedance is changed by turning on / off the triacs by a control signal. Furthermore, the triac of the impedance circuit is a photo triac with a zero-cross function, which is used with a resistor connected in series. Further, the control signal is set and transmitted so that the voltage for turning off the triac is higher than the voltage for turning on the triac of the impedance circuit.

[0013]

In the backlight control device configured as described above, when the AC voltage detected by the AC voltage detection circuit is lower than a predetermined voltage, the impedance is reduced, and when the AC voltage is higher, the impedance is increased.
A wide range of AC voltage makes the backlight current almost uniform. The impedance of the DC voltage signal output from the voltage conversion circuit that converts the AC voltage into the DC voltage signal is changed according to the contents of the A / D conversion data corresponding to the DC voltage signal converted by the A / D conversion circuit. The control circuit changes the impedance to make the backlight current almost uniform over a wide range of AC voltage.

Further, an impedance circuit composed of at least one capacitor and at least one triac connected in parallel, capable of inputting an AC voltage and changing the impedance by a control signal, and the output of this impedance circuit are rectified. Rectifying circuit, a backlight that emits light with the backlight current rectified by this rectifying circuit, and a switch circuit that is provided to block the backlight current with a control signal. Depending on the detection content, an AC voltage detection circuit that sends a control signal for blocking the backlight current to the switch circuit according to the detected content is sent, and a wide range of AC voltage Then, change the impedance and change the backlight With substantially uniform and prevents the application of the voltage exceeding the threshold, to prevent damage to the backlight. Further, an impedance circuit configured of at least one capacitor and at least one triac connected in parallel, capable of inputting an AC voltage and changing the impedance by a control signal, and a rectifying circuit for rectifying the output of the impedance circuit. A backlight that emits light with a backlight current rectified by the rectifier circuit, a switch circuit that is provided to block the backlight current with a control signal, and a voltage conversion circuit that converts an AC voltage into a DC voltage signal, An A / D conversion circuit for A / D converting the measurement data and A / D converting the DC voltage signal output from the voltage conversion circuit, and this A / D
According to the contents of the A / D conversion data corresponding to the DC voltage signal output from the conversion circuit, a control signal for changing the impedance is sent to the impedance circuit, and according to the contents of the A / D conversion data corresponding to the DC voltage signal, Equipped with a control circuit that sends a control signal that blocks the backlight current to the switch circuit, the impedance is changed by a wide range of AC voltage, the backlight current is made almost uniform, and the application of voltage exceeding the threshold is prevented. , Prevents damage to the backlight.

In the switch circuit, a phototriac with a zero-cross function is connected in series with the impedance circuit, and a resistor for discharging the residual charge of the capacitor is connected in parallel with the capacitor of the impedance circuit. Furthermore, the control signal is sent in a predetermined voltage range between the first predetermined voltage and the second predetermined voltage so as to block the backlight current, thereby increasing the discharge time of the capacitor. Further, the control circuit sends a control signal to the switch circuit according to the content of the A / D conversion data corresponding to the measurement data to notify the abnormality of the measurement data. Further, the backlight is composed of light emitting diodes of a plurality of colors, and a switch circuit provided so as to block the backlight current for each light emitting diode of each color by a control signal is provided with A control circuit that sends a control signal according to the content of the D conversion data changes the emission color of the backlight to notify the abnormality of the measurement data. in addition,
The multi-color light emitting diodes are two colors, green and red, and the control circuit compares the A / D conversion data corresponding to the measurement data with a preset alarm value, and according to the comparison result,
The backlight emits a green light during normal operation, an orange light during a one-stage alarm, and a red light during a two-stage alarm to notify the abnormal measurement data in two stages.

Further, the switch circuit receives the reference signal generated by the reference signal generating circuit as a control signal, and thereby repeatedly opens and closes to cause the backlight to flicker to notify the abnormality of the measurement data. Further, the control circuit sends an alarm signal obtained by comparing the A / D converted data corresponding to the measurement data and a preset alarm value as a control signal, and repeatedly opens and closes the switch circuit,
Flickers the backlight to notify you of abnormal measurement data. Further, the control circuit is provided with a gate for passing the reference signal generated by the reference signal generation circuit and input to the switch circuit, by comparing the A / D conversion data corresponding to the measurement data with a preset alarm value. The alarm signal is sent, and the control signal is passed through the reference signal to repeatedly open and close the switch circuit to cause the backlight to flicker and to report an abnormality in the measurement data.

Further, the impedance circuit is composed of a plurality of capacitors connected in series and a triac provided in parallel with a part of the capacitors, and by turning on / off the triac by a control signal,
The impedance is changed finely. The impedance circuit is composed of a plurality of capacitors connected in parallel and a triac provided in series with a part of the capacitors, and the impedance is finely changed by turning the triac on and off by a control signal. . Furthermore, the triac of the impedance circuit is a phototriac with a zero-cross function, and is used together with a resistor connected in series to mitigate the transient phenomenon when the triac is turned on and off. Further, the control signal is set such that the voltage for turning off the triac is set to be higher than the voltage for turning on the triac of the impedance circuit, and the control signal is transmitted to prevent the flicker operation of the backlight when the impedance is changed.

[0018]

【Example】

Example 1. 1 is a circuit configuration diagram of a backlight control device according to a first embodiment of the present invention, and FIG. 2 is an operation explanatory diagram of the backlight control device of FIG. In the figure, 1, 2,
Reference numerals 7 and 8a to 8d are the same as those of the conventional device described above, and the description thereof will be omitted. 10 is a capacitor, 11 is a triac connected in parallel with the capacitor 10, and 12 is an AC
The voltage detection means for detecting the voltage of the power supply 1 outputs a triac-on signal 13 to turn on the triac 11 when the voltage falls below a predetermined voltage, and the capacitor 10 is bypassed to bypass the impedance of the AC power supply 1 when the voltage drops. Is lowered to make the current flowing through the backlight 2 uniform and the brightness is made constant.

The operation of the backlight control device thus constructed will be described with reference to FIG. In the first embodiment, the backlight current is made the same when AC100V and AC200V, and the fluctuation of the backlight current is reduced according to a large fluctuation of the power supply voltage. In the case of a commercial power supply, the power supply voltage does not actually fluctuate significantly with respect to the rated voltage, and is within a fluctuation range of at most ± 10%. Therefore, the fluctuation of the backlight current within this fluctuation is almost the same as the brightness. There is no problem. When the AC power supply 1 rises from 0V, the voltage detection means 12 outputs the triac-on signal 13 to the triac 11, and the triac 11 is turned on. As a result, the backlight current I flows to the backlight 2 via the triac 11, the capacitor 7, and the diodes 8a to 8d. Moreover, the backlight current I also increases in proportion to the rise of the AC power supply 1, and the backlight current becomes I ₁₀₀ when the AC power is 100V. When the voltage further increases, the backlight current I further increases in proportion to this. When the voltage detecting means 12 detects AC150V, the triac-on signal 13 is turned off. As a result, the backlight current I flows to the backlight 2 via the capacitor 10, the capacitor 7, and the diodes 8a to 8d, so that the impedance of the capacitor 10 with respect to the AC power source 1 increases, and the backlight current I decreases. hand,
It becomes I ₁₅₀ .

Furthermore AC power supply 1 to the backlight current I rises increases, when the power supply voltage is AC200V, the backlight current I is the same current I ₁₀₀ as in the AC100V. On the contrary, when the AC power source 1 is lowered, the voltage detection means 12 turns on the triac-on signal 13 and turns on the triac 11 when the voltage is AC140V. As a result, the backlight current I flows to the backlight 2 via the triac 11, the capacitor 7, and the diodes 8a to 8d, so that the backlight current I becomes I ₁₄₀ . Although the threshold voltage for turning on the triac 11 is 140 V and the threshold voltage for turning off the triac 11 is 150 V in the first embodiment, the circuit voltage and application, the capacitors 7 and 1 are used.
It goes without saying that it may be arbitrarily determined according to the capacity of 0.

Example 2. 3 is a circuit configuration diagram of a backlight control device according to a second embodiment of the present invention, and FIG. 4 is an operation explanatory diagram of the backlight control device of FIG. In the first embodiment, the triac 11 controls the backlight current I in one circuit with respect to the change of the power supply voltage, but in the second embodiment, the triac is used in multiple circuits and the backlight current I is multistage. And the backlight current I
The fluctuation of is reduced. As shown in FIG. 3, in the second embodiment, the triac 14, the capacitor 15 and the triac on signal 16 are added as compared with FIG.

The operation of the backlight control device according to the second embodiment of the present invention is as shown in FIG. 4, and the operation of the triac-on signal 13 is the same as that of FIG. That is, when the voltage of the AC power supply 1 rises and exceeds AC150V, the backlight current I flows into the backlight 2 via the capacitor 10, the triac 14, the capacitor 7, and the diodes 8a to 8d. When the voltage of the AC power supply 1 further exceeds 200 V and rises to 225 V AC, the voltage detection means 12 turns off the triac-on signal 16 and turns off the triac 14, and the backlight current I is the capacitor 10, the capacitor 15, and the capacitor 7. To flow through
Since the impedance of the capacitor 15 increases, the backlight current I decreases. When the voltage of the AC power supply 1 further rises, when AC240V, AC100V, AC200
The backlight current I100 is the same as V. On the contrary, when the voltage of the AC power supply 1 drops, the voltage detection means 12 turns on the triac-on signal 16 and turns on the triac 14 when the voltage is AC215V. When the AC power supply 1 further descends, the same operation as described with reference to FIGS. 1 and 2 is performed. In the second embodiment, the case where two circuits of the triacs 11 and 14 are used has been described, but it is needless to say that by increasing the number of triacs to three circuits, four circuits ... Yes.

Example 3. FIG. 5 is a circuit configuration diagram of a backlight control device according to a third embodiment of the present invention, and FIG.
FIG. 3 is an operation explanatory diagram of the backlight control device of FIG. Example 3
In comparison with FIG. 1, instead of eliminating the capacitor 7, the capacitor 17 and the triac 11 are connected in parallel with the capacitor 10.
Are connected in series. AC power supply 1
When the voltage is low, the triac-on signal 13 is turned on from the voltage detection means 12, the triac 11 is turned on, and the backlight current I flows from both the capacitors 10 and 17 as a parallel circuit. When the voltage of the AC power supply 1 becomes 150V, the triac-on signal 13 is turned off and the backlight current I starts to flow only from the capacitor 10, and the backlight current I ₁₀₀ becomes the same at AC 200V as at AC 100V.

Example 4. 7 is a circuit configuration diagram of a backlight control device according to Embodiment 4 of the present invention, and FIG.
FIG. 3 is an operation explanatory diagram of the backlight control device of FIG. Example 4
5 is a circuit in which the series connection circuit of the capacitor 17 and the triac 11 is connected in parallel with the series connection circuit of the capacitor 19 and the triac 18 as compared with FIG. The on / off operation of the triacs 11 and 18 is the same as that shown in FIG. As the voltage of the AC power source 1 rises, the triacs 11 and 18 are sequentially turned off, and the capacitor 10
The capacitors 17 and 19 that were connected in parallel to are sequentially disconnected to increase the impedance of the circuit. Conversely, A
Triacs 11 and 18 depending on the voltage drop of the C power supply 1.
Are sequentially turned on, and the backlight current I is controlled as shown in FIG. 8 by lowering the impedance of the circuit to make the luminance constant.

Embodiment 5 FIG. The fifth embodiment is a backlight control device when a measurement signal from a signal source (not shown) to be measured is applied to a liquid crystal display that measures and displays using a CPU, and FIG. 9 shows a fifth embodiment of the present invention. 10 is a circuit configuration diagram of a backlight control device for measuring and displaying by FIG.
9 is a flowchart showing the processing of the CPU in the backlight control device for measuring and displaying in FIG. 9. The operation of the backlight control device according to the fifth embodiment is the same as that in FIG. In the figure, 1, 2, 7, 8a to 8d, 1
0, 11, and 13 are the same as those in FIG. 1, and the description thereof will be omitted. Reference numerals 21a, 21b and 21c are measurement signals from a signal source which is not shown, 22 is a CPU, 23 is a multiplexer for inputting the measurement signals 21a, 21b and 21c to input terminals, which is a selection signal 24 from the CPU 22. Select one. Reference numeral 25 is an A / D conversion circuit to which the measurement signal selected by the multiplexer 23 is input.
Reference numeral 26 is a start signal that the CPU 22 gives to the A / D conversion circuit 25. Upon receiving this start signal 26, the A / D conversion circuit 25 starts A / D conversion. 27 is an end signal to be output to the CPU 22 when the A / D conversion circuit 25 has completed A / D conversion, and 28 is an output of the A / D conversion circuit 25, A / D.
It is D conversion data. A voltage conversion circuit 29 converts the output voltage of the AC power supply 1 into a DC voltage signal.

In the backlight control device for measuring and displaying configured as described above, the A / D conversion circuit 25 is used.
Starts A / D conversion by the start signal 26 from the CPU 22, and when the A / D conversion is completed, the end signal 27 is set to CP.
Output to U22. The CPU 22 receives the end signal 27, reads the A / D conversion data 28, performs scale conversion calculation based on the read data, and displays the result on a liquid crystal display (not shown). Next, the control of the backlight current I in the fifth embodiment will be described. The voltage of the AC power source 1 is converted by the voltage conversion circuit 29 into a DC voltage signal such as AC0.
˜264V is converted into a signal of DC0-5V. This signal is input to the input terminal of the multiplexer 23, and C
Selected by the selection signal 24 of the PU 22 (process 30 in FIG. 10), A / D converted by the A / D conversion circuit 25, and the A / D converted data 28 is read into the CPU 22 (process 31 in FIG. 10). .

Thereafter, the CPU 22 performs the processing according to the processing procedure shown in FIG. First, it is confirmed with respect to the triac 11 whether the triac ON signal 13 is in the ON state (process 32). When the triac signal 13 is on, it is determined whether the A / D converted data 28 is AC150V or more (process 33). If it is 150 V AC or more, the triac-on signal 13 is turned off, and the backlight current I is suppressed (process 34). Further, the fact that the triac-on signal 13 is turned off is stored in the internal storage circuit of the CPU 22 (process 35). On the other hand, when the triac-on signal 13 is off, the A / D conversion data 28 is AC1.
It is determined whether the voltage is 40 V or less (process 36). AC14
If it is 0 V or less, the triac-on signal 13 is turned on and the backlight current I is increased (process 37). Furthermore, the fact that the triac-on signal 13 is turned on is CP
The data is stored in the memory circuit inside U22 (process 38). As described above, the backlight current I shown in FIG. 2 is controlled.

Example 6. FIG. 11 shows a sixth embodiment of the present invention.
FIG. 12 is a circuit configuration diagram of the backlight control device for performing the measurement display according to FIG. 12, and FIG. 12 is a flowchart showing the processing of the CPU in the backlight control device for performing the measurement display in FIG. The operation of the backlight control device according to the sixth embodiment is the same as that in FIG. The sixth embodiment is obtained by adding the triac 14, the capacitor 15 and the triac signal 16 to the fifth embodiment.
The operation of No. 4 is the same as that described in the second embodiment. The processing procedure of the CPU 22 regarding the control of the triac 11 is the same as the processing 30 to 38 in FIG. Regarding the processing procedure of the CPU 22 regarding the control of the triac 14, FIG.
2 will be described. First, it is confirmed with respect to the triac 14 whether the triac ON signal 16 is in the ON state (process 40). When the triac-on signal 16 is on, it is determined whether the A / D conversion data 28 is 225 V AC or more (process 41). If it is 225 V AC or more, the triac-on signal 16 is turned off and the backlight current I is suppressed (process 42). Further, the fact that the triac-on signal 16 is turned off is stored in the internal storage circuit of the CPU 22 (process 43). On the other hand, when the triac-on signal 16 is off, the A / D conversion data 28 is AC
It is determined whether the voltage is 215V or less (process 44). AC2
If it is 15 V or less, the triac-on signal 16 is turned on and the backlight current I is increased (process 45). Furthermore, the fact that the triac-on signal 16 is turned on is CP
The data is stored in the memory circuit inside U22 (process 46). Thus, the backlight current I shown in FIG. 4 is controlled. Needless to say, the number of triacs can be increased by the above method if necessary.

Example 7. FIG. 13 shows a seventh embodiment of the present invention.
FIG. 3 is a circuit configuration diagram of a backlight control device for measuring and displaying according to FIG. The operation of the backlight control device of the seventh embodiment is the same as that of FIG. 8, and the processing flow of the CPU is shown in FIG.
Is the same as The seventh embodiment is such that the series connection circuit of the capacitor 17 and the triac 18 is connected in parallel with the series connection circuit of the capacitor 17 and the triac 11 in the fifth embodiment. The operation of the triacs 11 and 18 is as described in the fourth embodiment. The processing procedure of the CPU 22 for controlling the triacs 11 and 18 is the same as the processing 30 to 38 and 40 to 46 in FIG. In this way, the backlight current I shown in FIG. 8 is controlled.
It is needless to say that the number of triacs is based on the above-mentioned embodiment, and the series connection circuit of the capacitor 17 and the triac 11 can be added in parallel if necessary.

Example 8. 14 is a circuit configuration diagram of a backlight control device according to an eighth embodiment of the present invention. In the first to seventh embodiments, the TRIAC is directly driven by the TRIAC-ON signal. However, the insulation between the AC power supply circuit and the TRIAC-ON signal and the transient phenomenon when the TRIAC is turned on and off are not severely applied. Desired. FIG. 14 improves on this problem. Instead of the triac 11 of the circuit of FIG. 1, a phototriac 30,
Phototriac drive circuit 31 and resistors 32 and 33
By adding, the measure is taken. 34
Is a light emitting diode of the phototriac 30, 35 is a zero-cross detection circuit built in the phototriac, 3
6 is a triac of the photo triac 30. That is, by turning on the triac on signal 13, the phototriac drive circuit 31 is driven, and when the light emitting diode 34 of the phototriac 30 is driven, a current flows through the resistor 32 to the light emitting diode 34. This current causes the zero-cross detection circuit 35 incorporated in the phototriac 30 to be sensitive to turn on the triac 36 when the voltage of the AC power supply 1 is zero-cross.
As a result, the triac 36 short-circuits both ends of the capacitor 10, lowers the impedance with respect to the AC power supply 1, and increases the backlight current I. The resistor 33 has an effect of suppressing an inrush current flowing when the both ends of the capacitor 10 are short-circuited at this time and preventing the triac 36 from being broken.

When the triac-on signal 13 is turned off, the current of the light emitting diode 34 is turned off, and the zero-cross detection circuit 35 responds to this by turning off the triac 36 when the voltage of the AC power supply 1 is zero-cross. This increases the impedance to the AC power source 1,
The backlight current I is suppressed. With the above configuration,
The transient phenomenon when the triac is turned on and off can be mitigated. It goes without saying that this embodiment can be applied to all of the above-described first to seventh embodiments.

Example 9. As described in FIGS. 2, 4, 6, 8, 10, and 12 as an operation explanatory diagram of Examples 1 to 8, there is hysteresis in the on and off voltages of the triac, for example, AC 150 V in FIG. When the voltage of AC power supply 1 rises, the triac is turned off, and conversely A
By providing a function to turn on when the voltage of the C power supply 1 drops to 140V AC, the TRIAC is repeatedly turned on and off around 140 to 150V AC, and the backlight current I repeatedly increases and decreases to prevent the backlight from blinking. it can. Examples 1-8 respond | correspond to such a subject.

Example 10. FIG. 15 is a first embodiment of the present invention.
0 is a circuit configuration diagram of the backlight control device, and FIG. 16 is an operation explanatory diagram of the backlight control device of FIG. For example, in FIG. 1, as the voltage of the AC power supply 1 rises, the triac-on signal 13 is output at a predetermined voltage, and the backlight current I is adjusted by turning the triac 11 on and off. If the voltage of the AC power source 1 rises abnormally, the backlight current I may flow abnormally accordingly, and the backlight 2 may be damaged. Example 10 presents the solution. FIG. 15 shows a tenth embodiment of the present invention. In comparison with FIG. 1, a phototriac 30, a resistor 32, and a phototriac drive circuit 31 are added instead of the triac 11, and a photocoupler 38, a resistor 39, and a backlight off signal are added. 40 and a photo coupler driving circuit 41 are added. Regarding the operation of the photo triac 30, although it has a zero-cross detection circuit like the photo triac 30 described in the eighth embodiment, the illustration is omitted and the operation is the same.

The operation of the backlight control device according to the tenth embodiment thus constructed will be described with reference to FIG. When the voltage of the AC power supply 1 is lower than 260 V AC, for example, the voltage detection means 12 does not output the backlight off signal 40, so that the photocoupler drive circuit 41 causes a current to flow through the light emitting diode of the photocoupler 38 through the resistor 39 and outputs it. The backlight current I is supplied by turning on the side transistor. The voltage of AC power supply 1 is AC20
When it goes beyond 0V and rises further, for example, AC260V
When the voltage reaches, the voltage detecting means 12 outputs the backlight off signal 40. With this signal, the photocoupler drive circuit 41 causes the light emitting diode of the photocoupler 38 to have a resistance 3
The current flowing through 9 is turned off. This turns off the transistor on the output side of the photocoupler 38, shuts off the backlight current, and prevents damage due to overcurrent. When the voltage of the AC power supply 1 decreases and falls below AC 260, the backlight off signal 40 is released again, the photocoupler 38 is turned on, and the backlight current I flows.

In the tenth embodiment, the backlight off signal 40 is configured to be output at AC260V.
When the voltage of the AC power source 1 repeatedly changes in the vicinity of 260 V AC, the backlight off signal 40 is also repeatedly turned on and off correspondingly, and the backlight current I is also intermittently output. As described in Section 9, for example, turn off the photo coupler at AC260V, A
It is also possible to add a hysteresis so that it is turned on when the voltage drops to C250V. Further, it goes without saying that the tenth embodiment can be applied to FIGS. 3 and 7 of the second and fourth embodiments.

Embodiment 11 FIG. 17 is a circuit configuration diagram of a backlight control device for measuring and displaying according to an eleventh embodiment of the present invention, and FIG. 18 is a flow chart showing a process of a CPU in the backlight control device for measuring and displaying in FIG. The operation of the backlight control device of FIG. 17 is the same as that of FIG. In the eleventh embodiment, instead of the triac 11 in FIG. 9 of the fifth embodiment, a phototriac 30, a resistor 32, a phototriac drive circuit 3 are provided.
1 is added, and a photo coupler 38, a resistor 39, a photo coupler off signal 40, and a photo coupler drive circuit 41 are added. The operation of the phototriac 30 is the same as that described in the eighth embodiment, and therefore its description is omitted. In FIGS. 17 and 18, the CPU 22 outputs the output of the voltage conversion circuit 29 via the multiplexer 23 to A
A / D conversion circuit 25 performs A / D conversion and reading, and AC15
The comparison between 0 V and 140 V AC for the magnitude comparison is the same as that described with reference to FIG. 10 of the fifth embodiment.
In the process 33, the CPU 22 determines that the voltage of AC1 is AC15.
When it is determined that the voltage is higher than 0 V, triac off (process 3)
4) After the processing of the triac-off storage (process 35), it is further determined whether or not it is larger than AC260V (process 70), and when it is larger than AC260V, the photo coupler is turned off (process 71). Off signal 40
Is output as shown in FIG. 16, the photocoupler 38 is turned off, and the backlight current I is cut off. Also AC26
When the voltage is less than 0 V, the photo coupler off signal 40 is stopped by turning on the photo coupler (step 72), the photo coupler 38 is turned on, and the backlight current I is supplied. It goes without saying that this embodiment can be applied to the sixth and seventh embodiments.

Embodiment 12 FIG. FIG. 19 is a circuit configuration diagram of a backlight control device according to Embodiment 12 of the present invention, and FIG.
FIG. 20 is an operation explanatory diagram of the backlight control device of FIG. 19. In the twelfth embodiment, in place of the photocoupler 38, the resistor 39, the backlight off signal 40, and the photocoupler drive circuit 41 in FIG. 15 of the tenth embodiment, a phototriac 42, a resistor 43, a triac-on signal 44, a phototriac drive circuit are provided. 45 is added. FIG.
The operation will be described with reference to FIG. Voltage detection means 1
When the voltage of the AC power supply 1 is, for example, 260 V AC or less, 2 turns on the triac-on signal 44, and the phototriac drive circuit 45 turns on the phototriac 42.
Is turned on to bring the capacitor 10 into a state in which an alternating current flows. When the voltage of the AC power source 1 is less than AC150V, the voltage detecting means 12 turns on the triac-on signal 13, the phototriac 30 turns on, lowers the impedance, and increases the backlight current I. AC power supply 1
When the voltage of is gradually increased to reach 150V AC, the voltage detection means 12 turns off the triac-on signal 13,
The phototriac 30 is turned off, the impedance is increased, and the backlight current I is caused to flow through the phototriac 42, the capacitor 10, and the capacitor 7, thereby suppressing the backlight current I. Furthermore, when the voltage of the AC power source 1 reaches AC260V, the triac-on signal 44 is turned off, the phototriac 42 is turned off, and the backlight current I is blocked.
Prevents damage to the backlight 2.

Example 13. FIG. 21 is an operation explanatory view of a backlight control device according to Embodiment 13 of the present invention, and FIG.
FIG. 13 is a circuit diagram in which a resistor for discharging residual charge of a capacitor according to Embodiment 13 of the present invention is provided. In the twelfth embodiment, the backlight current I is controlled by outputting the triac-on signals 13 and 44 as shown in FIG.
In the thirteenth embodiment, the triacs 30 and 42 are turned off and the backlight current I is blocked during the control method shown in FIG. 21, that is, between AC150V and AC160V. With such a configuration, the residual charge of the capacitor 10 remains. Therefore A
C200V down to 150, again from 150V to 20
When the TRIAC 42 is turned on when the AC voltage is 160V while increasing to 0V, the capacitor 10 has a high withstand voltage because the residual voltage due to the residual charge and the circuit voltage are superimposed and applied to the capacitor 10. In addition, the transient phenomenon at that time may be severe. Therefore, by providing a resistor 46 in parallel with the capacitor 10, AC150V and AC1
Since the residual charge of the capacitor 10 is discharged through the resistor 46 during 60V, the above problems can be solved. Although the resistor 33 is provided in FIG. 14 of the eighth embodiment, since the backlight current I constantly flows through the resistor 33, a resistor having a considerably large wattage is required. In the case of the thirteenth embodiment, according to the circuit of FIG. 22, the resistor 46 acts as a resistor for discharging the residual charge of the capacitor 10. Therefore, since the resistance value can be increased,
It has the effect of reducing the wattage.

Example 14 23 is a circuit configuration diagram of a backlight control device for measuring and displaying according to a fourteenth embodiment of the present invention, and FIG. 24 is a flowchart showing a process of a CPU in the backlight control device for measuring and displaying in FIG. . In the fourteenth embodiment, instead of the photocoupler 38, the resistor 39, the photocoupler drive circuit 41, and the photocoupler off signal 40 in FIG. 17 of the eleventh embodiment, a phototriac 42, a resistor 43, a triac-on signal 44, and a phototriac drive circuit. 45 is added. Voltage conversion circuit 29, multiplexer 23, A /
The operations of the D conversion circuit 25 and the like are the same as in the eleventh embodiment. Hereinafter, the description of the same parts as those of the eleventh embodiment will be omitted.

In FIG. 24, the CPU 22 executes a process 73.
If it is determined that the voltage of the AC power source 1 is lower than AC160V, the triac-on signal 44 is turned off, and the phototriac drive circuit 45 turns off the drive of the phototriac 42 (process 71b). On the other hand, if it is determined that it is larger than AC160V, then it is determined whether or not it is larger than AC260V (process 70). When the voltage is smaller than AC260V, the triac-on signal 44 is turned on and the phototriac 42 is turned on (process 72b). On the other hand, AC26
When it is higher than 0 V, the triac-on signal 44 is turned off, and the phototriac 42 is turned off (process 71).
b). As a result, the backlight current I is turned off in both the phototriacs 30 and 42 and blocked. In addition,
By connecting the circuit in which the triac and the capacitor are connected in parallel as shown in FIGS. 11 and 13 based on the idea of the fourteenth embodiment, or by connecting them in series,
It goes without saying that the amount of change in the backlight current I can be suppressed. This also applies to the thirteenth embodiment.

Example 15. 25 is a circuit configuration diagram of a backlight control device according to a fifteenth embodiment of the present invention.
The fifteenth embodiment provides a flicker display for notifying an observer as an alarm when the data to be measured exceeds the upper limit or exceeds the lower limit, for example. In the figure, the same parts as those in FIG. 15 will not be described. 47 is an alarm signal, which is sent from a monitoring means (not shown). Reference numeral 48 is a reference clock generation circuit, which outputs a rectangular wave signal 49 corresponding to the frequency of flicker display. 50 is a gate circuit,
When the alarm signal 47 is input, the gate circuit 50 opens and the rectangular wave signal 49 passes through the gate circuit 50. 51
Is an OR gate circuit, and when the rectangular wave signal 49 that has passed through the gate circuit 50 is input, the photo coupler 38 is driven on and off in synchronization with the rectangular wave signal 49. As a result, the backlight current I is interrupted, and the backlight 2 is repeatedly turned on and off in synchronization with this. This allows the observer to be notified of the abnormality. In the fifteenth embodiment, when the voltage of the AC power supply 1 exceeds AC260V, the backlight 2 is turned off by the photo coupler off signal 40.

Example 16. FIG. 26 is a first embodiment of the present invention.
6 is a circuit configuration diagram of the backlight control device for measuring and displaying, and FIG. 27 is a flowchart showing the processing of the CPU in the backlight control device for measuring and displaying in FIG. The sixteenth embodiment is a configuration example in which the backlight 2 is made to blink when an alarm is issued to notify a person in the same manner as in the fifteenth embodiment. Description of the same parts as those in FIG. 17 will be omitted. Reference numeral 48 is a reference clock generation circuit, which is a rectangular wave signal 4
9 is output and input to the CPU 22. The CPU 22 receives the measurement signals 21a, 2 input via the multiplexer 23.
The A / D conversion data 25 obtained by A / D converting 1b, 21c ... Read A / D
The conversion data 28 is compared with an alarm value stored in advance by the CPU 22, and an alarm is issued if it is determined that the upper limit value is exceeded or the lower limit value is exceeded. Then, the alarm process shown in FIG. 27 is executed. That is, the rectangular wave signal 49 is read (process 73), and it is determined whether the rectangular wave signal 49 is an on level or an off level (process 7).
4) If it is an off level, the photocoupler off signal 40 is turned on, the photocoupler 38 is turned off, the backlight current I is blocked, and the backlight 2 is turned off (process 75). Next, if it is on level, the photocoupler off signal 40 is turned off, the photocoupler 38 is turned on, the backlight current I is supplied, and the backlight 2 is turned on (process 76). By the above processing, the backlight 2 can be blinked when an alarm is issued.

Example 17 28 is a first embodiment of the present invention.
7 is a circuit configuration diagram of a backlight control device for measuring and displaying according to FIG. In the sixteenth embodiment, the rectangular wave signal 49 of the reference clock generation circuit 48 is once taken into the CPU 22, and the CPU 22 judges the level of the rectangular wave signal 49,
In response to this, the backlight 2 is configured to blink, but in the seventeenth embodiment, as shown in FIG.
Outputs an alarm signal 47, the gate circuit 50 is opened by this signal, and the rectangular wave signal 49 passing through the gate circuit 50
The photo coupler 38 is turned on and off.

Example 18. FIG. 29 is a first embodiment of the present invention.
9 is a circuit configuration diagram showing an internal configuration of a backlight according to No. 8 and a control device. FIG. The backlight 2 of Example 18 is a circuit in which light-emitting diodes are connected in series and is connected in parallel. When the backlight current I is applied to the circuits, the light-emitting diodes are turned on. It allows light to pass through and makes the liquid crystal easier to see. In the eighteenth embodiment, the backlight 2 includes a plurality of red light emitting diodes 52R.
52Rn and a plurality of green light emitting diodes 52G1, 52G2, 52G3 ... 52Gn are connected in parallel as shown in the figure. Each of the two light emitting diode rows is provided with a photo coupler 38 as shown in FIG.
53, resistors 39 and 54, and a photocoupler drive circuit 41,
55 is provided. 40 and 56 are photo coupler off signals. Normally, the CPU 22 turns off the photo coupler off signal 40, turns on the photo coupler 38, turns on the photo coupler off signal 56, turns off the photo coupler 53, and turns on the green light emitting diode 52G1.
52Gn is made conductive, and the liquid crystal surface is lit in green.

Next, when the CPU 22 judges the one-stage alarm, the photocoupler off signal 56 is turned off to turn on the photocoupler 53, and the red light emitting diode 52R1,
The backlight current I is also applied to 52R2, 52R3 ... 52Rn.
To conduct. As a result, since red light emission is also applied, it is combined with green light emission and the liquid crystal surface lights up in orange.
Next, when the CPU 22 judges the two-stage alarm, the photocoupler off signal 40 is turned on and the photocoupler 38 is turned off, so that the green light emitting diodes 52G1 and 52G are turned on.
The backlight current I of 2, 52G3 ... 52Gn is blocked. As a result, the backlight current I flows only to the red light emitting diodes 52R1, 52R2, 52R3, ..., 52Rn, so that the liquid crystal surface lights up in red and the user can be alerted. Further, in this state, the photocoupler 53 is alternately turned on / off by the photocoupler off signal 56 of the CPU 22, so that the blinking display in red can be performed, and the effect can be further enhanced.

[0046]

Since the present invention is constructed as described above, it has the following effects. When the AC voltage detected by the AC voltage detection circuit is lower than a predetermined voltage, the impedance is reduced, and when it is high, the impedance is increased, and the backlight current is almost uniform over a wide range of AC voltages such as multiple rated power sources. It is possible to make the brightness of the backlight constant by changing the ratio.
The impedance of the DC voltage signal output from the voltage conversion circuit that converts the AC voltage into the DC voltage signal is changed according to the contents of the A / D conversion data corresponding to the DC voltage signal converted by the A / D conversion circuit. The control circuit can change the impedance, make the backlight current almost uniform by a wide range of AC voltage such as multiple rated power supplies, and make the brightness of the backlight constant, and process the measurement data and AC voltage. Since the same control circuit is used, the circuit can be shared and the judgment value of the power supply voltage can be freely set by software.

Further, an impedance circuit composed of at least one capacitor and at least one triac connected in parallel, capable of inputting an AC voltage and changing the impedance by a control signal, and the output of this impedance circuit are rectified. Rectifying circuit, a backlight that emits light with the backlight current rectified by this rectifying circuit, and a switch circuit that is provided to block the backlight current with a control signal. In accordance with the above, an impedance voltage control circuit is sent to the impedance circuit, and an AC voltage detection circuit that sends a control signal to block the backlight current to the switch circuit is also provided according to the detected content. Change impedance with wide range AC voltage , Almost uniform backlight current, it is possible to the brightness of the backlight constant, prevent the application of an abnormal voltage exceeding the threshold, to prevent damage to the backlight due to overcurrent. Further, an impedance circuit configured of at least one capacitor and at least one triac connected in parallel, capable of inputting an AC voltage and changing the impedance by a control signal, and a rectifying circuit for rectifying the output of the impedance circuit. A backlight that emits light with a backlight current rectified by the rectifier circuit, a switch circuit that is provided to block the backlight current with a control signal, and a voltage conversion circuit that converts an AC voltage into a DC voltage signal, A / D that converts the measurement data into A / D and also A / D converts the DC voltage signal output from the voltage conversion circuit.
According to the contents of the D conversion circuit and the A / D conversion data corresponding to the DC voltage signal output from the A / D conversion circuit, a control signal for changing the impedance is sent to the impedance circuit, and at the same time, it corresponds to the DC voltage signal. Equipped with a control circuit that sends a control signal that blocks the backlight current to the switch circuit according to the contents of the A / D conversion data. By changing the impedance with a wide range of AC voltage such as multiple rated power supplies, the backlight current is almost uniform. The brightness of the backlight can be made constant by preventing the application of an abnormal voltage exceeding the threshold value and the damage of the backlight due to overcurrent is prevented, and the measurement data and AC voltage processing are the same. Since the control circuit is used, the circuit can be shared and the judgment value of the power supply voltage can be set by software.

Also, the control circuit can send a control signal to the switch circuit according to the content of the A / D conversion data corresponding to the measurement data, and notify the supervisor of the abnormality of the measurement data. Further, the backlight is composed of light emitting diodes of a plurality of colors, and a switch circuit provided so as to block the backlight current for each light emitting diode of each color by a control signal is provided with A control circuit that sends a control signal in accordance with the content of the D-converted data can change the emission color of the backlight to notify the abnormality of the measurement data and alert the observer. In addition, the multi-color light emitting diodes are of two colors, green and red, and the control circuit uses the A / A corresponding to the measurement data.
Compare the D conversion data with the preset alarm value,
Depending on the comparison result, the backlight emits a green light during normal operation, an orange light during a one-step alarm, and a red light during a two-step alarm, sending a control signal to the monitor to detect abnormal measurement data. It can be notified in two steps.

The switch circuit receives the reference signal generated by the reference signal generating circuit as a control signal to repeatedly open and close, flicker the backlight, and notify the observer of an abnormality in the measurement data. be able to. In addition, the control circuit sets A corresponding to the measurement data.
An alarm signal obtained by comparing the D / D converted data with a preset alarm value is sent as a control signal, the switch circuit is repeatedly opened and closed, and the backlight is flickered to cause an observer to detect an abnormality in the measurement data. . The impedance circuit is composed of multiple capacitors connected in series and a triac provided in parallel with some capacitors.By turning the triac on and off with a control signal, the impedance can be finely changed to simplify the operation. In such a circuit, the backlight currents in a plurality of rated power supplies are made substantially the same, and by configuring the impedance circuit with a capacitor, power loss can be reduced and heat generation can be suppressed. In addition, the impedance circuit, a plurality of capacitors connected in parallel,
It consists of a triac provided in series with some capacitors, and by turning the triac on and off by a control signal, the impedance is finely changed, and with a simple circuit, the backlight currents at multiple rated power supplies are made approximately the same. Since the impedance circuit is configured by a capacitor, power loss can be reduced, heat generation can be suppressed, and the capacitors are connected in parallel, so that the capacity of one capacitor may be small.

Furthermore, the triac of the impedance circuit is a phototriac with a zero-cross function, and it can be used together with a resistor connected in series to alleviate the transient phenomenon when the triac is turned on and off, and the current margin of the triac can be set small. Can be miniaturized. Also,
The control signal is set and transmitted so that the voltage for turning off the triac is higher than the voltage for turning on the triac of the impedance circuit, and the flicker operation of the backlight is prevented when the impedance is changed, and the brightness of the backlight is bright or dark. By repeating the above, it is possible to eliminate the possibility of causing anxiety to the user.

[Brief description of drawings]

FIG. 1 is a circuit configuration diagram of a backlight control device according to a first embodiment of the present invention.

FIG. 2 is an operation explanatory diagram of the backlight control device of FIG.

FIG. 3 is a circuit configuration diagram of a backlight control device according to a second embodiment of the present invention.

FIG. 4 is an operation explanatory diagram of the backlight control device of FIG.

FIG. 5 is a circuit configuration diagram of a backlight control device according to a third embodiment of the present invention.

FIG. 6 is an operation explanatory diagram of the backlight control device of FIG.

FIG. 7 is a circuit configuration diagram of a backlight control device according to a fourth embodiment of the present invention.

FIG. 8 is an operation explanatory diagram of the backlight control device of FIG. 7.

FIG. 9 is a circuit configuration diagram of a backlight control device for measuring and displaying according to a fifth embodiment of the present invention.

10 is a flowchart showing the processing of the CPU in the backlight control device for measuring and displaying in FIG.

FIG. 11 is a circuit configuration diagram of a backlight control device for performing measurement display according to a sixth embodiment of the present invention.

FIG. 12 is a flowchart showing the processing of the CPU in the backlight control device for measuring and displaying in FIG.

FIG. 13 is a circuit configuration diagram of a backlight control device for measuring and displaying according to a seventh embodiment of the present invention.

FIG. 14 is a circuit configuration diagram of a backlight control device according to Embodiment 8 of the present invention.

FIG. 15 is a circuit configuration diagram of a backlight control device according to Embodiment 10 of the present invention.

16 is an operation explanatory diagram of the backlight control device of FIG.

FIG. 17 is a circuit configuration diagram of a backlight control device for measuring and displaying according to an eleventh embodiment of the present invention.

18 is a flowchart showing the processing of the CPU in the backlight control device for measuring and displaying in FIG.

FIG. 19 is a circuit configuration diagram of a backlight control device according to a twelfth embodiment of the present invention.

FIG. 20 is an operation explanatory diagram of the backlight control device of FIG. 19.

FIG. 21 is an operation explanatory view of the backlight control device according to the thirteenth embodiment of the present invention.

FIG. 22 is a circuit diagram in which a residual charge discharging resistor of a capacitor according to a thirteenth embodiment of the present invention is provided.

FIG. 23 is a circuit configuration diagram of a backlight control device for measuring and displaying according to Embodiment 14 of the present invention.

FIG. 24 is a flowchart showing the processing of the CPU in the backlight control device for measuring and displaying in FIG.

FIG. 25 is a circuit configuration diagram of a backlight control device according to Embodiment 15 of the present invention.

FIG. 26 is a circuit configuration diagram of a backlight control device for measuring and displaying according to Embodiment 16 of the present invention.

27 is a flowchart showing the processing of the CPU in the backlight control device for measuring and displaying in FIG.

FIG. 28 is a circuit configuration diagram of a backlight control device for measuring and displaying according to Embodiment 17 of the present invention.

FIG. 29 is a circuit configuration diagram showing an internal configuration of a backlight and a control device according to Example 18 of the present invention.

FIG. 30 is a power supply circuit configuration diagram of a conventional liquid crystal display.

FIG. 31 is a circuit configuration diagram of a conventional backlight control device.

[Explanation of symbols]

1 AC power source, 2 backlights, 7, 10, 15, 1
7,19 capacitors, 8a-8d diodes, 1
1,14,18 Triac, 12 Voltage detection means,
22 CPU, 25 A / D conversion circuit, 29 voltage conversion circuit, 30, 42 phototriac, 32, 33, 4
6 resistors, 38 photocouplers, 48 reference clock generation circuit, 50 gates, 52Rn red light emitting diode, 52Gn green light emitting diode.

Claims (17)

[Claims] 1. An impedance circuit capable of changing impedance according to a control signal by inputting an AC voltage, a rectifying circuit for rectifying an output of the impedance circuit, and a backlight which emits light by a backlight current rectified by the rectifying circuit. , Detect the AC voltage,
A backlight control device comprising an AC voltage detection circuit that sends a control signal for changing the impedance to the impedance circuit according to the detected content. 2. An impedance circuit capable of inputting an AC voltage and changing impedance according to a control signal, a rectifying circuit for rectifying an output of the impedance circuit, and a backlight for emitting light by a backlight current rectified by the rectifying circuit. A voltage conversion circuit for converting the AC voltage into a DC voltage signal, an A / D conversion circuit for A / D converting the measurement data and an A / D conversion for the DC voltage signal output from the voltage conversion circuit, and this A / D A backlight control device comprising a control circuit for sending a control signal for changing the impedance to the impedance circuit according to the contents of A / D conversion data corresponding to a DC voltage signal output from the conversion circuit. 3. Composed of at least one capacitor and at least one triac connected in parallel,
An impedance circuit that can input an AC voltage and change the impedance according to a control signal, a rectifier circuit that rectifies the output of this impedance circuit, a backlight that emits light with a backlight current that is rectified by this rectifier circuit, and a back light that uses a control signal. A switch circuit provided to block a write current, detects the AC voltage, and sends a control signal for changing the impedance to the impedance circuit according to the detected content, and the switch according to the detected content. A backlight control device comprising an AC voltage detection circuit for sending a control signal for blocking a backlight current to the circuit. 4. At least one capacitor and at least one triac connected in parallel,
An impedance circuit that can input an AC voltage and change the impedance according to a control signal, a rectifier circuit that rectifies the output of this impedance circuit, a backlight that emits light with a backlight current that is rectified by this rectifier circuit, and a back light that uses a control signal. A switch circuit provided to block a write current, a voltage conversion circuit for converting the AC voltage into a DC voltage signal, A / D conversion of measurement data, and A / D conversion of a DC voltage signal output from the voltage conversion circuit. The A / D conversion circuit, which sends a control signal for changing the impedance to the impedance circuit according to the contents of the A / D conversion data corresponding to the DC voltage signal output from the A / D conversion circuit, and the DC voltage signal. Depending on the contents of A / D conversion data corresponding to Backlight control apparatus characterized by comprising a control circuit that sends a control signal to prevent site current. 5. The backlight control device according to claim 3, wherein the switch circuit is configured by connecting a phototriac with a zero-cross function in series with an impedance circuit. 6. The switch circuit according to claim 5, wherein a phototriac with a zero-cross function is connected in series to the impedance circuit, and a resistor is connected in parallel to the capacitor of the impedance circuit. Backlight control device. 7. The backlight according to claim 6, wherein the control signal is sent to block the backlight current in a predetermined voltage range between the first predetermined voltage and the second predetermined voltage. Control device. 8. The backlight control device according to claim 4, wherein the control circuit sends a control signal to the switch circuit according to the content of the A / D conversion data corresponding to the measurement data. 9. A switch circuit provided with a backlight composed of light-emitting diodes of a plurality of colors and capable of blocking a backlight current for each light-emitting diode of each color according to a control signal corresponds to measurement data. 9. The backlight control device according to claim 8, wherein the emission color of the backlight is changed by a control circuit that sends a control signal according to the content of the A / D conversion data to be performed. 10. The multi-color light emitting diode has two colors, green and red, and the control circuit has an A / D corresponding to the measurement data.
The converted data is compared with a preset alarm value, and the backlight emits green light during normal operation, orange light during one-stage alarm, and red light during two-stage alarm according to the comparison result. 10. The backlight control device according to claim 9, wherein a control signal is sent to cause the backlight control device to operate. 11. The switch circuit is repeatedly opened and closed by inputting a reference signal generated by a reference signal generation circuit as a control signal, thereby causing the backlight to perform a flicker operation. 4. The backlight control device according to 4. 12. The control circuit sets A corresponding to the measurement data.
9. An alarm signal obtained by comparing the / D conversion data with a preset alarm value is sent as a control signal to repeatedly open and close the switch circuit to flicker the backlight. 10. The backlight control device according to claim 10. 13. The control circuit has a gate for passing a reference signal, which is generated by a reference signal generation circuit and is input to a switch circuit, between A / D conversion data corresponding to measurement data and a preset alarm value. 11. The alarm signal obtained by comparison is sent, and the reference signal is passed to be a control signal, whereby the switch circuit is repeatedly opened and closed, and the backlight is flickered. 2. A backlight control device according to claim 1. 14. The impedance circuit includes a plurality of capacitors connected in series and a triac provided in parallel with a part of the capacitors, and the impedance is changed by turning on / off the triac by a control signal. The backlight control device according to any one of claims 1 to 13, wherein: 15. The impedance circuit comprises a plurality of capacitors connected in parallel and a triac provided in series with a part of the capacitors, and the impedance is changed by turning on / off the triac by a control signal. The backlight control device according to any one of claims 1 to 13, wherein: 16. The backlight control device according to claim 14, wherein the triac of the impedance circuit is a phototriac with a zero-cross function, and is used with a resistor connected in series. 17. The control signal is set and transmitted such that a voltage for turning off the triac of the impedance circuit is set to be higher than a voltage for turning on the triac of the impedance circuit. The backlight control device according to claim 1.