Computer graphics processing and selective visual display system – Plural physical display element control system – Display elements arranged in matrix
Reexamination Certificate
2001-02-14
2003-09-30
Hjerpe, Richard (Department: 2674)
Computer graphics processing and selective visual display system
Plural physical display element control system
Display elements arranged in matrix
C345S100000
Reexamination Certificate
active
06628259
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a circuit for driving a display unit such as a liquid crystal display (LCD) for a personal computer (PC), and in particular, a drive circuit of a display unit in which clock signals are increased in speed.
2. Description of the Related Art
FIG. 1
is a circuit diagram showing a conventional general drive circuit of a display unit (hereinafter, referred to as a prior art
1
). As shown in
FIG. 1
, a plurality of source lines
113
and a plurality of gate lines
116
are formed in LCD panel
105
, and at the intersection of them, pixels using a TFT (a thin-film transistor) (not shown) as a switching device are arranged in a matrix form.
In
FIG. 1
, eight source driver LSIs (a display driver LSI) (hereinafter, referred to as a source driver)
103
A through
103
H to be connected to source lines
113
are arranged in a row, and four gate driver LSIs (hereinafter, referred to as gate drivers)
106
connected to the gate lines
116
are arranged in a column. These drivers comprise large scale integrated circuits (LSI).
Data is transmitted from PC (a personal computer)
100
to control circuit
101
of the liquid crystal module. Then, clock signals or the like are transmitted in parallel to the gate drivers
106
from the control circuit
101
, a vertical synchronizing signal is transmitted to the first LSI of the gate drivers
106
, and clock signals, digital image data signals, latch signals and others are transmitted to the source drivers
103
A through
103
H.
Then, at the point of time at which the TFT is turned ON by a positive voltage applied through the gate lines
116
from the gate drivers
106
, a voltage applied through the source lines
113
from the source drivers charges liquid crystal load capacitance, and the TFT is turned OFF by a negative voltage applied through the gate lines
116
from the gate drivers
106
, whereby the charged charge is held.
In a case where LCD panel
105
is an XGA (an extended Graphics Array) having 1024×768 pixels and a color type, the source lines
113
are 1024×3=3072 lines, so that eight source drivers having 384 outputs become necessary. Due to the limitation of the semiconductor manufacturing device, the size of each chip is approximately 20 mm, and in the case of the XGA, eight to ten source drivers become necessary. In addition, when it is unnecessary to distinguish the eight source drivers, the drivers are just called source drivers
103
A through
103
H, and in a case where it is necessary to distinguish the eight source drivers, source drivers at 1st through 8th stages are called the first through eighth source drivers
103
A through
103
H, respectively.
As mentioned above, clock signals, digital image data signals, latch signals are transmitted to the source drivers
103
A through
103
H from the control circuit
101
to control each of the source drivers.
On the other hand, a start pulse signal (SP) is transmitted to only the first source driver
103
A at the first stage shown at the left end in
FIG. 1
among the source drivers
103
A through
103
H from the control circuit
101
. Then, the first source driver
103
A operates to shift by the clock signal, synchronously, and selects a bit number for sampling data. After the first source driver
103
A reads-in data, the start pulse signal is transferred to the second source driver
103
B at the next stage (at the next on the right) from the first source driver
103
A. Then, the start pulse signal operates the second source driver
103
B in the same manner as the operation for the first source driver
103
A. Thus, as shown by the arrows in
FIG. 1
, the start pulse signal is transferred from first source driver
103
A to the eighth source driver
103
H in order. Such connection is called cascade connection, and this has been generally used.
Next, unlike the abovementioned case, an example of a connection between source drivers LSIs and a control circuit, which is not the cascade connection, is described.
FIG. 2
is a circuit diagram showing a control circuit and source drivers in a display unit which are not cascade-connected. As shown in
FIG. 2
, in the case where a plurality of source drivers
203
are not cascade-connected, wiring for clock signals, digital image data signals, latch signals and others are connected from control circuit
201
to the source drivers
203
in parallel. Therefore, the timings of the transmission of these signals to the source drivers
203
can be directly controlled by the control circuit
201
. Therefore, the start pulse signal (SP) becomes unnecessary. However, in such a method, the number of wires increases, so that this case is not realistic.
FIG. 3
is a timing chart showing signals inputted into the source drivers in the circuit of the display unit having a plurality of source drivers that are cascade-connected to each other in prior art
1
shown in FIG.
1
. Latch signal (STB), clock signal (CLK), digital image data signals (D
00
to Dxx), and polarity signal (POL) of
FIG. 3
are inputted into the source drivers
103
A through
103
H in the same manner, however, the start signal (SP) of
FIG. 3
show the timing chart of the start pulse signal to be inputted into the first source driver
103
A at the first stage of FIG.
1
. The period between one rise and the next rise of the start pulse signal shows the period of transfer (1 horizontal period) of the start pulse signal (SP) inputted into the first source driver
103
A at the first stage to the eighth source driver
103
H at the final stage of FIG.
1
. As shown in
FIG. 3
, conventionally, the clock signals (CLK) to be inputted into the source drivers
103
A through
103
H always have clock pulses of a fixed frequency. When the digital image data signals (D
00
through Dxx) are read into memories (not shown) inside the source drivers from the source drivers to which the start pulse signal has been transferred, and the source drivers
103
A through
103
H read the digital image data corresponding to 1 horizontal period, the data read in synchronization with the latch signals (STB) is latched, digital-analog converted, and then outputted.
Recently, as in prior art 1 shown in
FIG. 1
, the LVDS (the Low Voltage Differential Signaling) method has been used for data transmission from the PC to the control circuit
101
of the module. The advantage in the use of this LVDS method is that high-rate transfer is possible and the EMI (the Electro Magnetic Interference) can be suppressed since the transfer is carried out at a low amplitude voltage.
In the future, data transfer at a high-rate and at a low amplitude voltage also becomes important between the control circuit
101
and the source drivers
103
A through
103
H in the display module.
That is, the clock signals from the PC are currently at approximately 70 MHz in an XGA panel, however, the signals are at 160 MHz or more in a UXGA panel with 1600×1200 pixels, and now, to double the frequency to be 320 MHz or more is being attempted.
However, in the abovementioned prior art 1 as shown in
FIG. 3
, the clock signal (CLK) always acts at a fixed frequency. Therefore, if the frequency of the clock signal increased, the action of the start pulse signal (SP) between the source drivers and transfer of the digital image data signals from the control circuit becomes unreliable.
The reason for this is because the transfer speed of the start pulse signal is limited to 200 MHz due to the use of CMOS interfaces between the source drivers. The internal functions of the source drivers stop until the start pulse signal is inputted. Even if the interfaces between the source drivers are improved, several nanoseconds (nsec) are required until the signals inside the source drivers, which have stopped, are started by the start pulse signal (SP). Therefore, the time for transferring the start pulse signal (SP) that is longer than the increased speed for the clock signal is required. However, the transfer time for the start pulse signal (SP), that is
Eisen Alexander
Hjerpe Richard
NEC Electronics Corporation
Young & Thompson
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