JPH0619412A - Semiconductor integrated circuit, multioutput driver and fluorescent light emitting display tube module - Google Patents

Abstract

PURPOSE:To stabilize the output of the semiconductor integrated circuit (IC) having a multiple power source system by stabilizing the output of the IC when the source voltage of the circuit is off. CONSTITUTION:A control voltage detecting circuit 1 is constituted of an output power source system and the output thereof is inputted to an output fixing circuit 3 connected to the output of a level holding circuit 2. Then, the output of the IC can be fixed even if the output power source remains without being given the control power source. Since the output of the IC can be fixed, the abnormal light emission and abnormal display of the display are eliminated particularly with a multioutput driver circuit for driving the display body of a liquid crystal display, plasma display, fluorescent display tube, etc.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an output stabilizing circuit for a semiconductor integrated circuit having a multi-power supply system when the power supply voltage is off, and particularly to a liquid crystal display, a plasma display,
The present invention relates to a multi-output driver circuit that drives a display body such as a fluorescent display tube.

[0002]

2. Description of the Related Art A conventional semiconductor integrated circuit (hereinafter referred to as an IC) having multiple power supplies is as follows: (1) When the power is turned on, the power supply for the control system is applied and then the power supply voltage for the output system is applied; After lowering the power supply voltage, the power supply was externally applied so as to lower the voltage of the control system.

(2) A circuit for detecting the power supply voltage of the control system is provided inside the IC, and a circuit for fixing the circuit of the output system is provided below a certain voltage of the power supply voltage of the control system.

(3) There is a circuit configuration in which the output system is not always turned on when the voltage of the control system is not applied.

[0005]

However, in the case of the above configuration (1), switches for the control system and the output system are required as external circuits. Also, a voltage monitoring detector, a sequential circuit, and a high-power transistor are required.

The configuration as described in (2) above is shown in FIG. 2, in which a circuit for monitoring the power supply voltage of the control system is formed by the control power supply system, and its output is used as the input of the level shifter of the output system. In the case of the flip-flop type level shift of the above, if the voltage of the control system is enough to operate the power supply monitoring circuit, it can operate sufficiently and fix the output, but the voltage that the transistor of the control system cannot operate. Below (a voltage close to the threshold value of the transistor), both the input transistors 21 and 22 of the level shifter are in the off state, and the output of the level shifter should maintain the previous state. The output may change due to a junction leak. This is different due to differences in the IC manufacturing time, etc., and selection is difficult. The effect of this phenomenon is that, for example, a power supply of 5V is applied, then a second power supply of 50V is generated through a booster circuit, and a display such as a fluorescent display tube is displayed with the voltage. When the power is turned on, the voltage of the output system gradually rises after 5 V is applied, but when the power is turned off,
V disappears immediately, and the voltage of the output system gradually decreases because the charge accumulated in the smoothing capacitor remains. If the output changes at this point, high light emission will occur at a specific bit. That is, an abnormal display is displayed when the power is turned off. A configuration like the above (3) is shown in FIG.
27 is a potential lower than the power supply voltage of 6 and turns on the transistor of 23. This is a transistor load type level shift circuit, and the output 8 is turned on (the P-channel transistor 31 is turned on) by applying a high level of the control system voltage to the transistor 42, but if the control voltage disappears, The output is never turned on. However, in this type of level shift circuit, a dripping current flows between the high-voltage power supplies when the output is turned on. If this type of level shifter is used for a multi-output driver, if the drain current is 20 μA per bit and the output system voltage is 60 V, then 20 bits will be 20 μA * 60.
Since V * 20 = 240 mW, if the power dissipation of the IC package is set to 250 mW, it will be difficult to achieve more outputs.

[0007]

Means for Solving the Problems The measures taken by the present invention to solve the above-mentioned problems are as follows. First, a control circuit of a first power supply system and a second power supply using an output of the control circuit as an input. In a semiconductor integrated circuit including a system level hold circuit and a second power supply system output circuit that receives the output of the level hold circuit as an input, A detection circuit and a circuit for fixing the output of the level hold circuit according to the signal from the detection circuit are provided. Further, in the above semiconductor device, a circuit configured of a first power supply system for detecting the first power supply voltage and a circuit for fixing the input of the level hold circuit by a signal of the detection circuit are provided. .

Next, a shift register formed of a control power supply system for converting serial data into parallel data, a latch circuit for latching the parallel data, and a level shift circuit formed of an output power supply system for receiving the latch data. In a multi-output driver composed of an output circuit that receives the output of the level shift circuit as an input, a circuit that is composed of an output power supply system and detects a control system power supply voltage is provided, and the output of the level shift circuit is output by the signal of the detection circuit. Is provided with a circuit for fixing. Further, the above-mentioned multi-output driver is characterized by including a circuit configured by a control power supply system for detecting a control power supply voltage, and a circuit for fixing the input of the level shift circuit by a signal of the detection circuit.

Next, the display data is controlled by the control power supply system,
The multi-output driver is used in a fluorescent display tube module that boosts a control power source to generate a display driving voltage and enables display.

[0010]

The circuit for detecting a decrease in the power supply voltage of the control system is composed of the output power supply system, and the output side of the level hold circuit is fixed by the output, so that the output of the IC can be stabilized when the power supply is turned off.

In order to obtain further output stability in the IC, a circuit for detecting a decrease in the power supply voltage of the control system is constructed by the control power supply system, and the output fixes the input side of the level hold circuit.

The output of the shift register circuit is fixed by forming the circuit for detecting the decrease in the power supply voltage of the control system with the output power supply system, and the output of the multi-output driver can be stabilized when the power is turned off. .

In order to obtain further output stability in the multi-output driver, a circuit for detecting a decrease in the control system power supply voltage is constructed by the control power supply system, and the output fixes the input side of the level hold circuit. .

Among the display elements, the fluorescent display tube is a grid,
Since both the anodes require push-pull drive and the brightness is high, if there is output power remaining when the control power supply is gone, the driver output will not turn off completely but will turn on. For example, abnormal light emission occurs with a specific character, but if the multi-output driver is used, the output can be completely turned off even in the above state, so abnormal light emission does not occur.

[0015]

Embodiments of the present invention will now be described with reference to the accompanying drawings.

(Embodiment 1) FIG. 1 shows an embodiment of the present invention, which is an example of a multi-power supply IC in which 5 control system power supplies and 6 output system power supplies are present. Reference numeral 1 is a circuit for detecting the power supply voltage of the control system, which is composed of an output power supply system. Reference numeral 2 is a level hold circuit, which is controlled by a control system signal. A circuit 3 receives the output of 1 as an input and directly fixes the output of the level hold circuit. Reference numeral 4 is a control circuit. FIG. 4 shows an example of the detailed circuit. 41 is resistance, 40
Is an N-channel transistor (hereinafter Nch-Tr), and a control system potential is given to its gate. 36-3
The transistor 9 is a buffer circuit. If the control system voltage drops below the threshold voltage of the transistor, N of 40
The ch-Tr is turned off, and the output of 44 becomes HIGH level. Reference numeral 11 is a flip-flop type level shift circuit.
If the potential of the gate signal (control system signal) of the Nch-Tr of 22 disappears, both are turned off, so that the output of the level shift maintains the previous state and becomes the level hold state. Three
The Nch-Tr of 2 is for fixing the output of the level hold circuit, and the gate of the transistor of 32 becomes HIGH level when the control system voltage decreases and turns on, so the output of the level shift is fixed at LOW level. . Therefore, if the control power supply voltage drops, the output 8 of the IC becomes LOW.
Fixed to the level.

(Embodiment 2) FIG. 5 shows an embodiment of the present invention, which is an example of a multi-power supply IC in which there are 5 control system power supplies and 6 output system power supplies. Reference numeral 1 is a circuit for detecting the power supply voltage of the control system, which is composed of an output power supply system. 10
Is a circuit for detecting the power supply voltage of the control system and is composed of the control power supply system. An example of the circuit diagram of 10 is shown in FIG.
1, the reference voltage generation circuit 62, the comparator circuit 63, etc. can be used to more accurately reduce the power supply voltage of the control system than the circuit of 1. By inputting this output to the input of the level hold circuit, when the voltage of the control system drops, 10 detection circuits operate first to fix the input of the level hold circuit, and when the voltage of the control system drops, 1 detection circuit is detected. The circuit operates and fixes the output of the level hold circuit.

(Embodiment 3) FIG. 7 shows an embodiment of the present invention, which is an example of a multi-output system multi-output driver in which a control system power source 88 and a high voltage power source 89 output system exist. The shift register 73 transfers the serial data 74 at the clock 75 and transfers the transferred data at the latch circuit 7 by the latch pulse 76.
Hold at 7. The latch data is output from 79 through the output circuit through the level shift circuit 78. Reference numeral 80 denotes a circuit for monitoring the control system power supply voltage, which is composed of a high voltage system power supply. If the control system potential of 81 drops, 82 Nch-Tr
Is turned off, so that 83 changes from the LOW level to the HIGH level, and the output 86 becomes the HIGH level. 87
Since the Nch-Tr of is turned on, the output of the level shift is forcibly set to the LOW level, and the output is fixed to the LOW. The level shift circuit 78 is a flip-flop type and is a level hold circuit that keeps the previous data when there is no input signal. Therefore, the transfer clock signal and the latch signal are stopped when the control system power supply is exhausted, and the level shift circuit retains the state at that time. When data is stopped in the case of AC display by time-division driving, a DC-like current flows to a specific bit, causing abnormal light emission with high brightness. However, in the case of the configuration of this embodiment, if the power supply voltage for the control system is exhausted, the output is fixed at the LOW level, so that abnormal light emission does not occur.

(Embodiment 4) FIG. 8 shows an embodiment of the present invention, which is an example of a multi-output multi-output driver in which a control system power source 88 and an output system high voltage power source 89 exist. The shift register 73 transfers the serial data 74 at the clock 75 and transfers the transferred data at the latch circuit 7 by the latch pulse 76.
Hold at 7. The latch data passes through the level shift circuit 78 and the output circuit and is output from 79. Reference numeral 80 denotes a circuit for monitoring the control system power supply voltage, which is composed of a high voltage system power supply. When the control system potential of 81 decreases, Nch-Tr of 82 is turned off, so that 83 changes from the LOW level to the HIGH level, and the output 86 becomes the HIGH level. Since the 87 Nch-Tr is turned on, the output of the level shift is forcibly set to the LOW level, and the output is fixed to the LOW.
Reference numeral 90 denotes a circuit for monitoring the control system power supply voltage, which is composed of the control system power supply. The internal circuit has the same circuit configuration as that in FIG.
This circuit monitors the power supply voltage with high accuracy (about 2.5V), fixes the level shift input, and outputs the output LOW.
To Further, when the power supply voltage drops to about 1.0 V which is lower than the threshold voltage of the high voltage system transistor, the circuit of 80 operates and the level shift output becomes LOW level, and the output is fixed to LOW. The level shift circuit 78 is a flip-flop type and is a level hold circuit that keeps the previous data when there is no input signal. Therefore, when the control system power supply is exhausted, the transfer clock signal,
Since the latch signal also stops, the level shift circuit keeps the state at that time. When data is stopped in the case of AC display by time-division driving, a DC-like current flows to a specific bit, causing abnormal light emission with high brightness. If the power supply voltage of the IC that generates the clock and data signals and so on also drops, the signal will stop, so it is necessary to fix the output to LOW before the power supply voltage completely disappears. However, in the case of the configuration of this embodiment, when the control system power supply voltage drops to about 2.5 V, the level shift input can be fixed and the output can be fixed to the LOW level.
Further, when the voltage of the control system circuit including the control system power supply voltage monitoring circuit 90 does not operate to about 1.0 V or less, the level shift retains the previous state, but the output may change due to junction leak, channel leak, etc. However, since the voltage monitoring circuit 80 operates and the output is fixed at the LOW level, abnormal light emission does not occur.

(Embodiment 5) FIG. 9 shows an embodiment of the present invention, 96 is a display data generating control IC, 92 is the multi-output driver, and 93 is a booster for boosting a control system voltage to generate a display drive voltage. The circuit, 94 is a fluorescent display tube.
Reference numeral 95 is a smoothing capacitor for the boosted voltage. When the display is turned off, the power supply switch 97 of the control system is turned off, the power supply 98 of the control system is cut off, the power supply voltage of the control system is lowered, and the boosting operation is stopped. As shown in FIG. 10, when the switch is turned off at the timing of 104,
The control system potential 103 is immediately discharged to about 1 V through the path of the transistor of the booster circuit, but immediately falls below about 1 V, but the transistor is turned off, and the voltage drops slowly. On the other hand, the boosting system potential 102 gradually decreases because the smoothing capacitor is large. In the part 107 in the figure, the voltage of the control system transistor is inoperable, and the input of the level shift circuit in the multi-output driver becomes indefinite, but the output of the level shift is fixed, so the output does not turn on. For example, if 94 is a liquid crystal display element, an abnormal display when the power is off is invisible due to the response speed of the liquid crystal. Even if 94 is a head for a thermal transfer printer, the driver circuit is N-
Since it is an output of ch open drain, as long as there is a detection circuit configured by the power supply voltage of the control system, the output transistor has no gate voltage and thus has no ability to flow current, and abnormal printing does not occur. In the case of a plasma display, there are row and column drivers, and the column driver is an open drain or open collector output, and when the control voltage drops, the column driver does not turn on and abnormal light emission does not occur. However, in the case of a fluorescent display tube, the response speed is fast, the brightness is high, and both the anode and the grid are driven by push-pull. It causes light emission. Therefore, by using the multi-output driver in the fluorescent display tube module, it is possible to suppress abnormal light emission which does not appear in other display elements.

[0021]

According to the semiconductor integrated circuit of the present invention, the output of the level hold circuit can be fixed if the control system power supply voltage is lowered, so that the output of the IC can be fixed when the power is off. Therefore, there is no need to do special things when externally applying power to the multi-power supply IC, and it is possible to eliminate the need to attach external parts. Although the channel leak of the transistor and the junction leak of the drain part were different due to the difference in the manufacturing time of the IC, and the selection was difficult, there is an effect that the selection work is not necessary. Even if a flip-flop type level shift circuit is used, the output can be fixed when the power is turned off, so that it is possible to provide a multi-output driver having a free power sequence. When the multi-output driver of the present invention is used in the fluorescent display tube module, it has an effect of suppressing abnormal light emission when the power is off.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a semiconductor integrated circuit according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a circuit configuration of a conventional semiconductor integrated circuit.

FIG. 3 is a diagram showing a circuit configuration of a conventional semiconductor integrated circuit.

FIG. 4 is a diagram showing a circuit example in a first embodiment of a semiconductor integrated circuit according to the present invention.

FIG. 5 is a diagram showing a circuit example in a second embodiment of a semiconductor integrated circuit according to the present invention.

FIG. 6 is a diagram showing an example of a power supply voltage detection circuit in a second embodiment of a semiconductor integrated circuit according to the present invention.

FIG. 7 is a diagram showing a circuit example in a third embodiment of a multi-output driver according to the present invention.

FIG. 8 is a diagram showing a circuit example in a fourth embodiment of a multi-output driver according to the present invention.

FIG. 9 is a diagram showing an example of a circuit in a fifth embodiment of the fluorescent display tube module according to the present invention.

FIG. 10 is a diagram showing a potential change when the power is off in the fifth embodiment of the fluorescent display tube module according to the present invention.

[Explanation of symbols]

1 Control system power supply voltage detection circuit composed of output power supply system 2 Level hold circuit 3 Output fixed circuit 4 Control circuit 5 Control system power supply 6 Output system power supply 7 Output circuit 8 Output terminal 9 Ground power supply 10 Control system power supply voltage detection circuit 11 flip-flop type level shift circuit 21, 22, 32 to 34, 38 to 40, 42 Nch
-Tr 23, 24, 30, 31, 36, 37, 43 Pch
-Tr 25 AND circuit composed of control power supply system 26 Inverter circuit composed of control power supply system 27 Voltage lower than output power supply voltage 35, 41, 61 Resistance 62 Reference voltage generation circuit 63 Comparator circuit 73 Shift register circuit 74 Serial data input 75 Transfer clock input 76 Latch pulse input 77 Latch circuit 78 Level shift circuit 79 Output terminal 80 Control system power supply voltage detection circuit composed of output power system 81 Control system potential 84 Serial data output 88 Indicates control power supply voltage region 89 Output Reference numeral 90 indicates a power supply voltage region, which is composed of a control power supply system with a control system power supply voltage detection circuit 92 Multi-output driver 93 of the present invention 93 Booster circuit 94 Fluorescent display tube 95 Smoothing capacitor 96 Control IC 97 Power switch 98 Control system power supply 99 Boost The output serves as the output power supply. X-axis 102 the output power supply voltage curve 103 controls the supply voltage curve representing the Y-axis 101 hours representing a 100 power supply voltage

Claims (5)

[Claims] 1. A control circuit for a first power supply system, a level hold circuit for a second power supply system that receives the output of the control circuit, and a second power supply system that receives the output of the level hold circuit. In the semiconductor integrated circuit composed of the output circuit of, the means for detecting the first power supply voltage, which is composed of the second power supply system, and the means for fixing the output of the level hold circuit by the signal from the detection means are provided. A semiconductor integrated circuit characterized by being provided. 2. The semiconductor device according to claim 1, wherein the means for detecting the first power supply voltage is constituted by a first power supply system, and the means for fixing the input of the level hold circuit by the signal of the detection means. A semiconductor integrated circuit comprising: 3. A shift register for converting serial data into parallel data in a first power supply system, a latch circuit for latching the parallel data, a level shift circuit for receiving the latched data in a second power supply system, and the level shift. In a multi-output driver composed of an output circuit having the output of the circuit as an input, means for detecting a first power supply voltage which is composed of a second power supply system, and fixing the output of the level shift circuit by the signal of the means A multi-output driver comprising means. 4. The multi-output driver according to claim 3, wherein the means for detecting the first power supply voltage is constituted by the first power supply system, and the means for fixing the input of the level shift circuit by the detection means. A multi-output driver characterized by having. 5. A fluorescent display tube module which performs display data control by a first power supply system and boosts the first power supply to generate a display drive voltage to perform display.
2. A fluorescent display tube module using the multi-output driver described in 1.