Datasheet
+
-
PANEL
REPAIR
BUFFER
20 TO 100:
COLUMN DRIVER
OPEN
COLUMN
LINE
TFT-LCD
PANEL
PANEL
REPAIR
LINE
LM6588
www.ti.com
SNOSA77D –MAY 2003–REVISED MARCH 2013
capacitance on that line increases substantially. For instance, a column typically has 50pF to 100pF of line
capacitance, but a repaired column can have up to 200pF. Column drivers are not designed to drive this extra
capacitance, so a panel repair buffer provides additional output current to the repaired column line. Note that
there is typically a 20Ω to 100Ω resistor in series with the buffer output. This resistor isolates the output from the
200pF of capacitance on a repaired column line, ensuring that the buffer remains stable. A pole is created by this
resistor and capacitance, but its frequency will be in the range of 8MHz to 40MHz, so it will have only a minor
effect on the buffer’s transient response time. Panel repair buffers transmit a column driver signal, and as
mentioned in the gamma buffer section, this signal is set by the gamma levels. It was also mentioned that many
displays have upper and lower gamma levels that are within 500mV of the supply rails. Therefore, op amps used
as panel repair buffers should have rail-to-rail input and stages. Otherwise, they may clip the column driver
signal.
The signal from a panel repair buffer is stored by a pixel when the pixel’s row is selected. In high-resolution
displays, each row is selected for as little as 11μs. To insure that a pixel has adequate time to settle-out during
this brief period, a panel repair buffer should settle to within 1% of its final value approximately 1μs after a row is
selected. This is hardest to achieve when transmitting a column line’s maximum voltage swing, which is the
difference between the upper and lower gamma levels (i.e. voltage between VGMA1 and VGMA10). For a
LM6588, the most demanding application occurs in displays that operate from a 16V supply. In these displays,
voltage difference between the top and bottom gamma levels can be as large as 15V, so the LM6588 needs to
transmit a ±15V pulse and settle to within 60mV of its final value in approximately 1μs (60mV is approximately
1% of the dynamic range of the high or low polarity gamma levels). LM6588 settling times for 15V and –15V
pulses were measured in a test circuit similar to the one in Figure 35. V
+
and V
−
were set to 15.5V and –0.5V,
respectively, when measuring settling time for a 0V to 15V pulse. Likewise, V
+
and V
−
were set to 0.5V and
–15.5V when measuring settling time for a 0V to –15V pulse. In both cases, the LM6588 output was connected
to a series RC load of 51Ω and 200pF. When tested this way, the LM6588 settled to within 60mV of 15V or –15V
in approximately 1.1μs. These observed values are very close to the desired 1μs specification, demonstrating
that the LM6588 has the bandwidth and slew rate required for repair buffers in high-resolution TFT displays.
Figure 36. Panel Repair Buffer
SUMMARY
This application note provided a basic explanation of how op amps are used in TFT displays, and it also
presented the specifications required for these op amps. There are three major op amp applications in a display:
V
COM
Driver, Gamma Buffer, and Panel Repair Buffer, and the LM6588 can be used for all of them. As a V
COM
Driver, the LM6588 can supply large values of output current to regulate V
COM
load transients. It has rail-to-rail
input common-mode range and output swing required for gamma buffers and panel repair buffers. It also has the
necessary gain bandwidth and slew-rate for regulating gamma levels and driving column repair lines. All these
features make the LM6588 very well suited for use in TFT displays.
Copyright © 2003–2013, Texas Instruments Incorporated Submit Documentation Feedback 21
Product Folder Links: LM6588