MAX1531EVKIT Maxim Integrated Products, MAX1531EVKIT Datasheet - Page 4

MAX1531EVKIT

Manufacturer Part Number

MAX1531EVKIT

Description

Power Management Modules & Development Tools MAX1531 EVAL KIT MAX1531 EVAL KIT

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1531EVKIT.pdf (13 pages)

Specifications of MAX1531EVKIT

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can provide at least 2A. The step-down switching regu-

lator’s switching frequency is jumper configurable

between 250kHz and 500kHz. The adjustable input

undervoltage protection (EN) protects the EV kit from

undervoltage conditions. The step-up switching regula-

tor and the source-drive regulator are protected against

overloads.

The step-down switching regulator (VOUT) generates a

+3.3V output and can provide at least 1.5A. The step-

down switching-regulator output voltage can be adjust-

ed as low as +1.24V using different feedback resistors

(see the Output Voltage Selection section).

The logic voltage supply (VLOG) is set to +2.5V using a

linear regulator controller and an external pnp bipolar

pass transistor. This logic voltage supply can provide at

least 500mA of current. The logic-voltage-supply linear

regulator’s output can be adjusted between +1.24V and

its input supply, which is the step-down regulator’s out-

put voltage (see the Output Voltage Selection section).

The source-driver supply (VSRC) is set to +10V using a

linear regulator controller and an external pnp bipolar

pass transistor. This source-driver supply can provide

at least 500mA of current. The source-drive linear regu-

lator’s output can be adjusted between +1.24V and its

input voltage, which is either the EV kit input voltage

(PIN) or the output of the MAX1522 step-up regulator,

depending on jumper JU15 (see the Output Voltage

Selection section).

The gamma reference (VGAM) is set to +9.7V using a lin-

ear regulator controller and an external pnp bipolar pass

transistor. This gamma reference can provide at least

50mA of current. The gamma linear regulator’s output

can be adjusted between +1.24V and its input voltage,

which is either the EV kit input voltage (PIN) or the output

of the MAX1522 step-up regulator, depending on jumper

JU14 (see the Output Voltage Selection section).

The TFT gate-on supply (GON) uses a two-stage posi-

tive charge pump to generate approximately +33V. The

output is postregulated to +25V using a linear regulator

controller and an external pnp bipolar pass transistor

and can provide at least 25mA. The positive linear reg-

ulator’s output can be adjusted between +1.24V and its

input, which depends on the EV kit’s input voltage and

the charge-pump configuration, jumpers JU12 and

JU13 (see the Output Voltage Selection section).

The TFT gate-off supply (GOFF) uses a negative charge

pump to generate approximately -11V. The output is

postregulated to -9V using a linear regulator controller

and an external npn bipolar pass transistor and can pro-

vide greater than 50mA. The negative linear regulator’s

output can be adjusted between 0V and its input volt-

MAX1531 Evaluation Kit

_______________________________________________________________________________________

age, which is the output of the negative charge pump

(see the Output Voltage Selection section).

The EV kit also features power-up sequencing. After EN

and SEQ go high, the logic voltage supply (VLOG) soft-

starts. The gamma reference, the gate-on supply, the

source-driver supply, and the gate-off supply can soft-

start in any sequence by setting the appropriate

jumpers (see the Power-Up Sequencing section).

The EV kit includes a current-limit circuit for the step-

down switching regulator. The current-limit threshold is

set by resistor-dividers R12, R13, and the R

MOSFET N1 (refer to the MOSFET Selection and

Current-Limit Setting section in the MAX1531 data sheet

for further detail). The EV kit also includes current over-

load protection for the source-driver supply voltage. The

MAX1531 will shut down if the source-driver supply

exceeds a current threshold. The output current over-

load threshold is set by sense resistors R35 and R36

(refer to the Overcurrent Protection Block (CSH, CSL)

section in the MAX1531 data sheet for further detail).

The MAX1531 features an enable (EN) pin that enables

or disables the MAX1531 and the EV kit’s output. The

EN pin can also be used with resistor-dividers R3 and

R4 to set the lower limit of the input voltage range (refer

to the On/Off Control (EN) section in the MAX1531 data

sheet for further detail). The 3-pin jumper JU1 provides

an option to enable, disable, or use the undervoltage

threshold feature for the MAX1531 EV kit. Table 1 lists

the selectable jumper options.

The MAX1531 EV kit features an option to choose the

step-down switching regulator’s operating frequency

(JU2). Table 2 lists the selectable jumper options. The

EV kit is configured for 500kHz operation. Optimum

performance at 250kHz requires a larger inductor value

(refer to the Inductor Selection section in the MAX1531

data sheet).

Table 1. Jumper JU1 Functions

LOCATION

(Default)

SHUNT

None

1-2

2-3

Switching Frequency Selection (FREQ)

Connected to GND

dividers R3 and R4

Connected to PIN

Connected to VL

through resistor-

EN PIN

Jumper Selection

when V

MAX1531 (U1)

Enable (EN)

IC STATUS

Disabled

Enabled

DS(on)

> 9V

MAX1531EVKIT Maxim Integrated Products, MAX1531EVKIT Datasheet - Page 4

MAX1531EVKIT

Specifications of MAX1531EVKIT

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