JPH0882804A - Method for arranging external connecting terminal of liquid crystal display device - Google Patents

Abstract

PURPOSE: To prevent the destruction and malfunction of a liquid crystal display device by erroneous connection and short circuit by adjacently arranging external connecting terminals for inputting low-frequency signals in such a manner that the external connecting terminals to be inputted with the high-frequency signals operating at timing different from each other are held from both sides. CONSTITUTION: The high-frequency signals, such as shift clock XSCL and display data latch signal OP of a signal electrode driving circuit are so arranged as to be parted from the other high-frequency signals and to be enclosed by the low-frequency signals or power sources. Namely, the XSCL is held by a scanning start pulse YD and a display prohibition signal INH. The LP is held by the INH and the logic power source Vcc. As to display data D0 to D7 , all the signals change at the same timing and, therefore, the sepn. of each of the respective display data terminals by the power source is not always necessary. The arrangement of the connecting terminals is executed by enclosing the signal wires with GND and VLCD from both sides, by which the generation of noises by the signal lines held therebetween and the infiltration of external noises into the held signal lines are relieved by a shielding effect.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of arranging signals and power supply terminals for connecting a liquid crystal display device and a system body.

[0002]

2. Description of the Related Art The arrangement of external connection terminals in a conventional liquid crystal display device is made compact as shown in FIG.
It has the following features for the purpose of saving space.

(A) The power source and the signal terminal are mixed (in the same connection) and integrally arranged.

(B) In a single-row arrangement type terminal arrangement, reverse connection,
Many of them do not have a slip connection prevention structure.

In FIG. 3, GND is a common power source for the liquid crystal driver, V _CC is a logic power source (+5 V) for the liquid crystal driver to which the signals shown in the figure are input, and V _LCD is a liquid crystal drive power source (maximum potential of 15 to +30 V). Is. Display data latch signal LP, shift clock XSCL of signal electrode drive circuit
Is a signal that should not be affected by noise or level fluctuation in circuit operation. On the other hand, the liquid crystal alternating signal FR, the display blanking signal YDIS, and the scan scan pulse YD are
It is a low frequency signal. Further, the display data D ₀ -D ₇ is XS
It is a signal that operates in synchronization with CL, but if the signal level at the falling edge of XSCL is stable, there is no problem in operation.

As already known, the outer shape of the liquid crystal display device is such that the liquid crystal display panel 1 is fixed to the circuit board 2 by the parting plate 5. The flexible cable 3 having the external connection terminal portion 4 is soldered to the circuit board 2 using a small space. The cable 3 may not be provided depending on the type of liquid crystal display device. This structure is the same in FIG. 1 showing the present invention.

[0007]

However, in the above-mentioned prior art, since the signal terminal and the V _CC terminal are adjacent to the V _LCD terminal to which a voltage several times higher than the logic power supply V _CC is applied,
If a short circuit is made with an adjacent terminal by mistake, the liquid crystal driver incorporated in the liquid crystal display device may be destroyed.
In addition, even if it is not structured to prevent reverse connection or slip connection,
In the case of incorrect connection, the liquid crystal driver may be broken as well.

As the capacity of LCD further increases, XS
Signals such as CL and D _{0 to} D ₇ have high frequencies, and malfunctions due to mutual interference with other signals have become apparent.

Therefore, the present invention solves such a problem, and an object thereof is to prevent destruction or malfunction of the liquid crystal display device due to misconnection or short circuit by devising the arrangement of the external connection terminals. To do.

[0010]

The method of arranging external connection terminals according to the present invention is characterized in that a power source or a low frequency signal terminal is arranged between high frequency signal terminals operating at different timings.

[0011]

According to the above arrangement method of the present invention, a high frequency signal is shielded by a power source and a low frequency signal, so that malfunction due to mutual interference is reduced.

[0012]

1 is an example showing a terminal arrangement of an external connection portion of a liquid crystal display device according to the present invention. Since the connection relationship between each terminal and the liquid crystal drive circuit or the liquid crystal panel 1 is already known, it is not shown here. The cause of destruction of the drive circuit at the time of erroneous connection is voltage breakdown (insulating film breakdown, junction breakdown) due to the high voltage V _LCD being applied to the logic section, and overcurrent breakdown due to forward biasing of the PN junction ( It is conceivable that the wiring melts or the bonding part peels off. For the latter cause, the current flows in a distributed manner in a plurality of drivers, and the output current capacity of the power source is finite, so the driver is less likely to be destroyed. Therefore, with a slight mistake, it is desirable to use a terminal arrangement in which no high voltage is applied other than the V _LCD terminal.

In FIG. 1, since the V _LCD terminal receives a voltage several times higher than other terminals, it is not connected to terminals (N
C) is provided. As a result, even if the adjacent terminal and V _LCD are short-circuited, the adjacent terminal is prevented from being destroyed. Furthermore, by providing the GND terminal with the NC terminal in between,
Even if two terminals are misaligned and connected, the LCD driver can be prevented from being broken. That is, as shown in FIG. 2, the breakdown current I _D at the time of erroneous connection often flows through the GND terminal and the diodes 13 and 15 in the liquid crystal driver in many cases. Here, a block 21 surrounded by a broken line is a system substrate, and a block 22 is an input portion of the liquid crystal drive circuit. Therefore, by inserting an overcurrent blocking / limiting means (fuse or resistor) 10 in the GND wiring in the liquid crystal display device, even if no protection means is attached to another power source,
It is possible to prevent the breakdown voltage and the current from being applied to the LCD driver. The shut-off / limitation means 10 works as a protection means even when an overcurrent flows in the liquid crystal display device due to other reasons.

As a protection means in the case of reverse connection, V _LCD
The terminal (terminal 2) corresponding to the reverse connection is the NC terminal. As a result, it is possible to prevent voltage breakdown due to application of a high voltage to the logic system. Furthermore, pin 3 and 4 are NC
By using the terminals, it is possible to prevent the breakdown due to V _LCD against reverse slip connection. By the way, the GND and NC terminals at both ends of the connection terminal reduce the risk of electrical breakdown when the external conductor comes into contact with the flexible connection cable 3.

Next, a method of arranging the signal lines will be described.
The signal to the conventional liquid crystal display device is often only the input signal. As the LCD has a larger capacity, the input signal becomes faster, and noise countermeasures are becoming important. Of these, the terminals that must be provided with a measure against external noise are limited for stable operation of the LCD driver, and are only XSCL and LP. Therefore, by separating these signals from other high-frequency signals and arranging them so as to be surrounded by the low-frequency signals or the power supply, it is possible to reduce noise in the connection terminal portion, the liquid crystal display device, and the connection cable. With respect to the display data D _{0 to} D ₇ , since all the signal changes are the same timing, it is not always necessary to separate each display data terminal by the power supply. In the connection terminal arrangement, the signal lines are surrounded by GND and V _LCD from both sides, so that the generation and intrusion of noise are alleviated as a whole.

In the above arrangement method, there is no reverse connection or shift connection prevention means, but it goes without saying that the arrangement constraint corresponding to it can be eliminated depending on the prevention means. For example, if there is a reverse connection prevention means, it is possible to eliminate the NC terminal corresponding to the arrangement section-2 terminal.

[0017]

As described above, the terminal arranging method of the present invention has the following effects by slightly increasing the number of connecting terminals without changing the structure of the conventional liquid crystal display device.

(A) It is possible to prevent breakage and deterioration of the LCD driver due to an inadvertent connection mistake between the liquid crystal display device and the system base.

(B) The radiation noise of the Mizuko connection portion and the connection cable is reduced, and the coupling between signals is alleviated, so that the operational stability of the large capacity liquid crystal display device is increased.

[Brief description of drawings]

FIG. 1 is a diagram showing an external connection terminal arrangement of the present invention in a liquid crystal display device.

FIG. 2 is a diagram showing an excessive current flowing through an LCD driver in the case of offset connection.

FIG. 3 is a diagram showing a conventional external connection terminal arrangement.

[Explanation of symbols]

 1 ... ・ Liquid crystal panel 2 ・ ・ ・ ・ Circuit board 3 ・ ・ ・ ・ ・ ・ Flexible cable 4 ・ ・ ・ ・ External connection terminal part 10 ・ ・ ・ Overcurrent interruption / limitation means 21 ・ ・ ・ System base (main body) 22 ... Input part of liquid crystal drive circuit

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] September 27, 1995

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Method of arranging external connection terminals of liquid crystal display device

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of arranging signals and power supply terminals for connecting a liquid crystal display device and a system body.

[0002]

2. Description of the Related Art The arrangement of external connection terminals in a conventional liquid crystal display device is made compact as shown in FIG.
It has the following features to save space .

(A) The power source and the signal terminal are mixed (in the same connection) and integrally arranged.

(B) In a single-row arrangement type terminal arrangement, reverse connection,
Many of them do not have a slip connection prevention structure.

In FIG. 3, GND is a common power source for the liquid crystal driver, V _CC is a logic power source (+5 V) for the liquid crystal driver to which the signals shown in the figure are input, and V _LCD is a liquid crystal drive power source (maximum potential of 15 to +30 V). Is. Display data latch signal LP, signal electrode drive circuit shift clock XSCL
Is a signal that should be free of noise and level fluctuations in circuit operation. On the other hand, the liquid crystal alternating signal FR, the display blanking signal YDIS, and the scan scan pulse YD are
It is a low frequency signal. Further, the display data D ₀ -D ₇ is XS
It is a signal that operates in synchronization with CL, but if the signal level at the falling edge of XSCL is stable, there is no problem in operation.

As already known, the outer shape of the liquid crystal display device is such that the liquid crystal display panel 1 is fixed to the circuit board 2 by the parting plate 5. The flexible cable 3 having the external connection terminal portion 4 is soldered to the circuit board 2 using a small space. The cable 3 may not be provided depending on the type of liquid crystal display device. This structure is the same in FIG. 1 showing the present invention.

[0007]

However, in the above-mentioned prior art, since the signal terminal and the V _CC terminal are adjacent to the V _LCD terminal to which a voltage several times higher than the logic power supply V _CC is applied,
If a short circuit is made with an adjacent terminal by mistake, the liquid crystal driver incorporated in the liquid crystal display device may be destroyed.
In addition, even if it is not structured to prevent reverse connection or slip connection,
In the case of incorrect connection, the liquid crystal driver may be broken as well.

As the capacity of LCD further increases, XS
Signals such as CL and D _{0 to} D ₇ have high frequencies, and malfunctions due to mutual interference with other signals have become apparent.

Therefore, the present invention solves such a problem, and an object thereof is to prevent destruction or malfunction of the liquid crystal display device due to misconnection or short circuit by devising the arrangement of the external connection terminals. To do.

[0010]

In the liquid crystal display device of the present invention ,
The method of arranging the external connection terminals is as follows:
Liquid crystal display device having a path, and a signal and a signal to the liquid crystal display device
Possible to connect / separate from the system substrate that supplies power supply voltage
And a connector supplied to the liquid crystal display device.
Signal and a plurality of external connection terminals for inputting the power supply voltage
Outside the liquid crystal display device, which is continuously arranged adjacent to the connector
A method of arranging partial connection terminals, the method comprising:
The signals supplied are operated at different timings
Insert the external connection terminal that inputs the high frequency signal from both sides
The external connection terminal for inputting low frequency signals or the
External connection terminals for inputting the source voltage must be placed adjacent to each other.
Is characterized by.

Further , it has a liquid crystal panel and a liquid crystal drive circuit.
Liquid crystal display device, and a signal and power supply voltage for the liquid crystal display device
The system base that supplies the
Signal and power supplied to the liquid crystal display device.
Connect a plurality of external connection terminals for inputting the source voltage to the connector
External connection end of liquid crystal display device that is continuously arranged adjacent to
A sub-array method, provided from the system substrate
Insert multiple external connection terminals to input signals from both sides
The external connection terminal for inputting the power supply voltage.
It is characterized by

[0012]

According to the above arrangement method of the present invention, a high frequency signal is shielded by a power source and a low frequency signal, so that malfunction due to mutual interference is reduced.

[0013]

1 is an example showing a terminal arrangement of an external connection portion of a liquid crystal display device according to the present invention. The connection relationship between each terminal and the liquid crystal drive circuit or the liquid crystal panel 1 is already known and will not be shown here. The cause of destruction of the drive circuit at the time of erroneous connection is voltage breakdown (insulating film breakdown, junction breakdown) due to the high voltage V _LCD being applied to the logic section, and overcurrent breakdown due to forward biasing of the PN junction ( It is conceivable that the wiring melts or the bonding part peels off. For the latter cause, the current flows in a distributed manner in a plurality of drivers, and the output current capacity of the power source is finite, so the driver is less likely to be destroyed. Therefore, with a slight mistake, it is desirable to use a terminal arrangement in which no high voltage is applied other than the V _LCD terminal.

In FIG. 1, since the V _LCD terminal receives a voltage several times higher than other terminals, it is not connected to both terminals (N
C) is provided. As a result, even if the adjacent terminal and V _LCD are short-circuited, the adjacent terminal is prevented from being destroyed. Furthermore, by providing the GND terminal with the NC terminal in between,
Even if two terminals are misaligned and connected, the LCD driver can be prevented from being broken. That is, as shown in FIG. 2, the breakdown current I _D at the time of erroneous connection often flows through the GND terminal and the diodes 13 and 15 in the liquid crystal driver in many cases. Here, a block 21 surrounded by a broken line is a system substrate, and a block 22 is an input portion of the liquid crystal drive circuit. Therefore, by inserting an overcurrent blocking / limiting means (fuse or resistor) 10 in the GND wiring in the liquid crystal display device, even if no protection means is attached to another power source,
It is possible to prevent the breakdown voltage and the current from being applied to the LCD driver. The shut-off / limitation means 10 works as a protection means even when an overcurrent flows in the liquid crystal display device due to other reasons.

As a protection means in the case of reverse connection, V _LCD
The terminal (No. 2 terminal) corresponding to the reverse connection with is the NC terminal. As a result, it is possible to prevent voltage breakdown due to application of a high voltage to the logic system. Furthermore, pin 3 and 4 are NC
By using the terminals, it is possible to prevent the breakdown due to V _LCD against reverse slip connection. By the way, the GND and NC terminals at both ends of the connection terminal reduce the risk of electrical breakdown when the external conductor comes into contact with the flexible connection cable 3.

Next , a method of arranging signal lines according to an embodiment of the present invention
The method will be explained. The signal to the conventional liquid crystal display device is
Often only the input signal. As the LCD has a larger capacity, the input signal becomes faster, and noise countermeasures are becoming important. The stable operation of the LCD driver in this, the terminal must be external noise countermeasures are limited, signal
Electrode drive circuit shift clock XSCL, display data
Only the high frequency signal of the switch signal LP . Therefore, by separating these signals from other high-frequency signals and arranging them so as to be surrounded by the low-frequency signals or the power supply, noises of the connection terminal portion, the liquid crystal display device, and the connection cable can be alleviated . In FIG. 1, XSCL is the scan start pulse YD
It is sandwiched by the INHIBIT signal INH.
It Further, LP today by IHN and logic power source Vcc
It is rare. With respect to the display data D _{0 to} D ₇ , since all the signal changes are the same timing, it is not always necessary to separate each display data terminal by the power supply. The connection terminal arrangement is such that by enclosing the signal line from both sides with GND and V _LCD , the signal lines sandwiched between them are shielded by the shield effect.
Noise and external noise on the sandwiched signal line
It is mitigating intrusion.

In the above arrangement method, there is no reverse connection or shift connection prevention means, but it goes without saying that the arrangement constraint corresponding to it can be eliminated depending on the prevention means. For example, if reverse connection prevention means, Oh is possible to eliminate the NC terminal sequence portion -2 Pin corresponding thereto
It

[0018]

As described above, the terminal arranging method of the present invention does not change the structure of the conventional liquid crystal display device and only increases the number of connecting terminals, and the terminal connecting portion and the connecting case are improved.
The radiated noise of the cable is reduced, and the
Bringing is mitigated, further reducing the intrusion of external noise
Therefore, the operational stability of the liquid crystal display device is increased.

[Brief description of drawings]

FIG. 1 is a diagram showing an external connection terminal arrangement of the present invention in a liquid crystal display device.

FIG. 2 is a diagram showing an excessive current flowing in an LCD driver in the case of misaligned connection.

FIG. 3 is a diagram showing a conventional external connection terminal arrangement.

[Explanation of reference signs] 1 ... Liquid crystal panel 2 ... Circuit board 3 ... Flexible cable 4 ... External connection terminal 10 ... Overcurrent shutoff / limitation means 21 ... System base (main body) 22 ... Input part of liquid crystal drive circuit

Claims (1)

[Claims] 1. In a liquid crystal display device in which a system substrate for generating display information and a liquid crystal drive circuit substrate can be separated, a power source or a low frequency signal terminal is arranged between high frequency signal terminals operating under different timings. A method for arranging external connection terminals of a particular liquid crystal display device.