MAX8784 Datasheet, PDF(17/24 Page) Maxim Integrated Products – Step-Up Regulator, Internal Charge Pumps, Switch Control, and Operational Amplifier for TFT LCDs

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MAX8784 Datasheet, PDF (17/24 Pages) Maxim Integrated Products – Step-Up Regulator, Internal Charge Pumps, Switch Control, and Operational Amplifier for TFT LCDs

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Step-Up Regulator, Internal Charge Pumps, Switch

Control, and Operational Amplifier for TFT LCDs

When CTL is logic-high, Q1 turns on and Q2 and Q3

turn off, connecting GON to POUT. When CTL is logic-

low, Q1 turns off and Q2 and Q3 turn on, connecting

GON to DRN. GON can be discharged through a resis-

tor connected between DRN and GND.

The switch control block is enabled when GDEL is

charged to VREF. GDEL is charged by a 5ÂµA current

after the negative charge pump reaches regulation.

The switch control block is disabled during fault mode

and during shutdown. When the switch control block is

disabled, GON is pulled to PGND with an internal

100kâ¦ resistor.

Operational Amplifier

The MAX8784 has three operational amplifiers that are

typically used to drive the LCD backplane (VCOM) or

the gamma-correction divider string. Each operational

amplifier features 140mA/220mA (source/sink) output

short-circuit current, 45V/Âµs slew rate, and 20MHz

bandwidth. While the op amp is a rail-to-rail input and

output design, its accuracy is significantly degraded for

input voltages within 1V of its supply rails (SUP, BGND).

Short-Circuit Current Limit

The operational amplifier limits short-circuit current to

approximately 140mA if the output is shorted to AGND

and to approximately -220mA if the output is shorted to

AVDD. If the short-circuit condition persists, the junc-

tion temperature of the IC rises until it reaches the ther-

mal-shutdown threshold (+160Â°C typ). Once the

junction temperature reaches the thermal-shutdown

threshold, an internal thermal sensor immediately sets

the thermal-fault latch, shutting off the main step-up

regulator, the charge pumps, the high-voltage switch

control block, and the operational amplifier. Those por-

tions of the device remain inactive until the input volt-

age is cycled.

Driving Pure Capacitive Loads

The operational amplifier is typically used to drive the

LCD backplane (VCOM). The LCD backplane consists

of a distributed series capacitance and resistance, a

load that can be easily driven by the operational ampli-

fier. However, if the operational amplifier is used in an

application with a pure capacitive load, steps must be

taken to ensure stable operation.

As the operational amplifierâs capacitive load increases,

the amplifierâs bandwidth decreases and gain peaking

increases. A 5â¦ to 50â¦ small resistor placed between

VCOM and the capacitive load reduces peaking, but

also reduces the gain. An alternative method of reducing

peaking is to place a series RC network (snubber) in

parallel with the capacitive load. The RC network does

not continuously load the output or reduce the gain.

Reference Voltage

The reference voltage is nominally 1.246V, and can

source at least 50ÂµA (see the Typical Operating

Characteristics). VCC is the input of the internal refer-

ence block. Bypass REF with a 0.22ÂµF ceramic capaci-

tor connected between REF and GND.

Power-Up Sequence

The MAX8784 operational amplifier and internal refer-

ence are enabled when VCC exceeds its UVLO thresh-

old. A 5ÂµA current charges ADEL after the internal

reference reaches regulation. The step-up regulator

starts the soft-start sequence after ADEL is charged to

VREF. The FB fault-detection circuit is enabled and the

negative charge-pump regulator starts up after the

step-up regulator reaches regulation. The FBN fault-

detection circuit is enabled and a 5ÂµA current charges

GDEL after the negative charge pump reaches regula-

tion. The positive charge pump starts its soft-start

sequence after GDEL is charged to 1.25V (typ). The

FBP fault-detection circuit is enabled after the positive-

charge pump reaches regulation.

Power-Down Control

The MAX8784 disables the step-up regulator, positive

charge-pump regulator, negative charge-pump regula-

tor, and high-voltage switch control block when SHDN

is logic low. The operational amplifier depends only

upon the supply voltage at SUP.

Fault Protection

During steady-state operation, if any output of the three

regulators (step-up regulator, positive charge-pump

regulator, and negative charge-pump regulator) is not

above its respective fault-detection threshold, the

MAX8784 activates an internal fault timer. If any condi-

tion or a combination of conditions indicates a continu-

ous fault for the fault-timer duration (55ms typ), the

MAX8784 sets the fault latch. The MAX8784 shuts

down all the outputs except the reference and opera-

tional amplifiers after the fault latch is set. Toggle SHDN

or cycle the input voltage to clear the fault latch and

restart the IC.

Thermal-Overload Protection

The thermal-overload protection prevents excessive

power dissipation from overheating the MAX8784.

When the junction temperature exceeds TJ = +160Â°C

(typ), a thermal sensor immediately sets its fault latch,

which shuts down all the outputs. After the device cools

down, input voltage has to be recycled to restart. The

thermal-overload protection protects the controller in

the event of fault conditions. For continuous operation,

do not exceed the absolute junction temperature rating

of TJ = +150Â°C.

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