1. Field of the Invention
The present invention relates generally to a semiconductor device equipped with a transfer circuit receiving an external input data signal and providing a retimed signal thereof as an external output data signal in order to make a cascade connection of a plurality of semiconductor devices, more particularly to a data driver IC to be mounted on a flat-panel display device.
2. Description of the Related Art
The data driver 20 includes a plurality of data driver ICs 21 to 24 having the same structure that are mounted on a printed board and commonly connected to lines for providing clock signals CLK and data signals DATA. Therefore, lines parallel to the longitudinal direction of the data driver 20 and lines perpendicular thereto must be formed on the printed board, and the printed board has two wiring layers. In practical, because there is a need to form other signal lines and power supply lines on the printed board, it has six wiring layers, increasing the cost of the printed board.
In this data driver 20A, each of data driver ICs 21A to 24A is provided with input and output terminals for the data signals DATA and the clock signal CLK, and the input and output terminals are connected through a buffer circuit within the data driver IC 21A. According to this configuration including such a signal transfer section in each IC, cascade connections of the data driver ICs 21A to 24A are made with respect to the data signals DATA and the clock signal CLK, so that there is no intersection between the lines on the printed board, and the printed board has only one wiring layer. In practical, because other signal lines and power supply lines are additionally provided, it has two wiring layers. This allows reducing the cost of the printed board. When such a signal transfer section is formed in each data driver IC, although the cost partially increases due to the increase of chip area, the total cost of the data driver ICs and the printed board can be reduced.
However, since the distance between adjacent lines inside the chip is much smaller than that on the printed board, crosstalk noise between signal lines becomes not negligible. Particularly, in a case where the data driver 20A is connected to a high resolution LCD panel, because the frequency of data signals DATA is relatively high, the crosstalk effect increases. In addition, because an external signal line L1 is longer than an internal signal line L3, their signals have different propagation delay times due to difference of line capacity. Due to the cascade connection between the data driver ICs 21A to 24A, the delay time differences are accumulated, making the timing adjustment difficult.
To resolve these problems, JP 2001-202052-A discloses a semiconductor device comprising a signal transfer circuit which decomposes inputted external input data signals to reduce the frequency thereof, transfers the decomposed signals, combines them to compose the retimed signals of the external input data signals, and outputs the retimed signals.
However, since the transfer direction is fixed, according to whether the semiconductor devices as data driver ICs are disposed along one side or the opposite side of a flat display panel, two kinds of semiconductor devices are required.
If bidirectional transfer circuit is incorporated into the semiconductor device, the wiring area of the signal transfer circuit increases because of the decomposition.
Therefore, it is an object of the present invention to provide a semiconductor device which can be mounted on any side of a flat display panel with reducing the crosstalk effect in a signal transfer section, and also reducing timing difference in a case where a cascade connection is made for a plurality of integrated circuit devices.
It is another object of the present invention to provide a semiconductor device which can reduce the wiring area of the signal transfer section.
In one aspect of the present invention, there is provided with a semiconductor device comprising:
According to this configuration, since the transfer circuit is bidirectional, the semiconductor devices can be mounted on any side of a flat display panel. In addition, since the signal is decomposed to reduce the frequency thereof, it is possible to reduce the crosstalk effect in a signal transfer section. Moreover, since the transferred signal is a retimed signal, it is possible to reduce timing difference in a case where a cascade connection is made for the semiconductor devices.
Hereinafter, preferred embodiments of the present invention will be described in detail referring to the drawings.
First Embodiment
In an LCD panel 10, a plurality of vertically extended data lines 11 and a plurality of horizontally extended scan lines 12 are formed crossing over each other, and a pixel is formed at each crossover point. One ends of the data lines 11 and the scan lines 12 are connected to a data driver 20B and a scan driver 30, respectively. Based on a video signal, a pixel clock signal, a horizontal synchronizing signal, and a vertical synchronizing signal provided from the external, a control circuit 40 provides a data signal DATA1 and a clock signal CLK to the data driver 20B, and also provides a scan control signal to the scan driver 30.
The data driver 20B includes data driver ICs 21B to 24B having the same configuration. The data driver IC 21B includes a transfer circuit 25 and a main body circuit 26, both operating in synchronism with the clock signal CLK. The transfer circuit 25 changes the transfer direction according to a transfer direction control signal R/L. That is, when R/L is high (indicated as ‘H’ in FIG. 1), signal transfer is made from first data signal input/output terminals to second data signal input/output terminals, and when R/L is low, the signal transfer is made in the reverse direction.
The data driver ICs 21B to 24B are cascaded with respect to the first and second data signal input/output terminals. On the other hand, the clock signal CLK is commonly provided to the data drivers ICs 21B to 25B. The transfer direction control signal R/L is fixed to high ‘H’ in a case of FIG. 1. The data signals being under transfer in the transfer circuit 25 are provided to the main body circuit 26, and based on the data signals, the main body circuit 26 determines pixel electrode voltages provided to data lines of the LCD panel 10 every one horizontal period.
As shown in
This circuit 51A includes tristate buffer circuits 511 to 514, and an inverter 515. When the transfer direction control signal R/L1 is ‘H’, DATA11 and DATA12 are provided through the tristate buffer circuits 512 and 514, respectively, to the input circuit 52A of
As shown in
A decomposing circuit 52A1 and a composing circuit 53B1 are respectively configurations associated with the external input data signal DI11A of the input circuit 52A of FIG. 3 and the external output data signal DO11B of the output circuit 53B of FIG. 3.
The decomposing circuit 52A1 includes D flip-flops 521 and 522 and an inverter 523. The data inputs D of the D flip-flops 521 and 522 commonly receive the external input data signal DI11A, and the clock inputs of the D flip-flops 521 and 522 respectively receive a clock signal CLK1 and its complementary signal inverted by the inverter 523. Non-inverted outputs Q of the D flip-flops 521 and 522 are connected to one ends of signal lines L11 and L12, respectively.
Because the external input data signal DI11A is latched into the D flip-flops 521 and 522 at rising and falling edges, respectively, of the clock signal CLK1, each of internal data signals DI11A1 and DI11A2 on the signal lines L11 and L12 becomes half the clock signal CLK1 in frequency at the maximum as shown in FIG. 6. Because crosstalk noise between the signal lines L11 and L12 occurs upon change of signal voltage, the crosstalk effect becomes reduced to under a half of the prior art where the data signal is not decomposed.
The composing circuit 53B1 is for regenerating the external input data signal DI11A by combining the decomposed data signals, and includes NAND gates 531 to 533 and an inverter 534. One inputs of the NAND gates 531 and 532 receives the internal data signals DI11A1 and DI11A2, respectively, from the D flip-flops 521 and 522, and the other inputs respectively receive the clock signal CLK1 and its complementary signal inverted by the inverter 534.
Output signals A1 and A2 of the NAND gates 531 and 532 as shown in
Because the external output data signal DO11B is a retimed signal of the external input data signal DI11A, there is no accumulation of differences of signal propagation delay time due to the length difference between inner and outer data signal lines that are disposed between the data driver ICs 21B to 24B of
Referring back to
When the transfer direction control signal R/L is ‘L’, the data signal DATA2 is provided through the I/O buffer circuit 51B to the input circuit 52B, the signals decomposed by the circuit 52B are provided through the signal lines L21 to L24 to the output circuit 53A to compose for regenerating, and it is output as the data signal DATA1 through the I/O buffer circuit 51A. In addition, signals on signal lines L21 are selected by the multiplexer 57 to provide to the main body circuit 26 of FIG. 1.
The main body circuit 26 includes at the input stage thereof the same circuit as the output circuit 53A to compose for regenerating, and the other circuits may embodied by the same circuits as the prior art, for example, circuits disclosed in the Japanese patent application No. 2000-333517.
Second Embodiment
In this circuit, the input circuits 52A and 52B of FIG. 3 are omitted by connecting an input circuit 52 to the output of a multiplexer 57A. The input circuit 52 has the same structure as the input circuit 52A of FIG. 3.
The multiplexer 57A selects external input data signals DI11A and DI12A provided from the I/O buffer circuit 51A when the transfer direction control signal R/L is ‘H’, and external input data signals DI11B and DI12B provided from the I/O buffer circuit 51B when R/L is ‘L’, and then provides the selected signals to the input circuit 52.
The outputs of the input circuit 52 are connected to first ends of the signal lines L31 to L34, and second and third ends of the signal lines L31 to L34 are connected to the inputs of the output circuits 53A and 53B, respectively.
When the transfer direction control signal R/L is ‘H’, the data signal DATA1 is provided through the I/O buffer circuit 51A and the multiplexer 57A to the input circuit 52, decomposed into signals under a half in frequency, and provided to the output circuits 53A and 53B. The output of the output circuit 53A is invalid because the input of the I/O buffer circuit 51A that receives it is in a high impedance state. On the other hand, the output signal of the output circuit 53B is output through the I/O buffer circuit 51B.
When the transfer direction control signal R/L is ‘L’, the data signal DATA2 is provided through the I/O buffer circuit 51B and the multiplexer 57A to the input circuit 52, decomposed into signals under a half in frequency, and provided to the output circuits 53A and 53B. The output of the output circuit 53B is invalid because the input of the I/O buffer circuit 51B that receives it is in a high impedance state. On the other hand, the output signal of the output circuit 53A is output through the I/O buffer circuit 51A.
The relatively long signal lines L31 to L34 between the first and second end side circuits 50C and 50D get small crosstalk effect thanks to the decrease of frequency. On the other hand, Although the external input data signals DI11A and DI12A have the same frequency as the data signal DATA1, because the length of their signal lines is about a half of the distance between the first and second end side circuits 50C and 50D, their crosstalk effects become low. The same applies to the signal lines of the external input data signals DI11B and DI12B.
Third Embodiment
In this circuit, the output circuits 53A and 53B of
According to the third embodiment, it is possible to make the number of data signal lines smaller than the first and second embodiments, and thereby ground lines GND as shown in
Fourth Embodiment
In this circuit, the chip sides of I/O buffer circuits 51C and 51D are also bidirectional, reducing the number of signal lines to a half of the case of FIG. 8. There is provided a demultiplexer 58 near the output circuit 53, and an output destination of the output circuit 53 is determined according to the transfer direction control signal R/L.
When R/L is ‘H’, the demultiplexer 58 provides the output of the output circuit 53 to the I/O buffer circuit 51D, while the I/O buffer circuit 51C side output of the demultiplexer 58 is in a high impedance state. When R/L is ‘L’, the demultiplexer 58 provides the output of the output circuit 53 to the I/O buffer circuit 51C, while the I/O buffer circuit 51D side output of the demultiplexer 58 is in a high impedance state.
According to the fourth embodiment, because the number of data signal lines is smaller, ground lines GND can be easily formed at intervals between the data lines like the third embodiment. In addition, because there is no relatively long data signal line directly connected between the I/O buffer circuits 51C and 51D, the crosstalk effect can be reduced.
Although preferred embodiments of the present invention have been described, it is to be understood that the invention is not limited thereto and that various changes and modifications may be made without departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
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2001-367833 | Nov 2001 | JP | national |
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5848289 | Studor et al. | Dec 1998 | A |
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Number | Date | Country |
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2001-202052 | Jul 2001 | JP |
Number | Date | Country | |
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20030103390 A1 | Jun 2003 | US |