MAX20070EVKIT [MAXIM]
2.7V to 5.5V Input Range for TFT Power Section;
| 型号: | MAX20070EVKIT |
| 厂家: | 
MAXIM INTEGRATED PRODUCTS |
| 描述: | 2.7V to 5.5V Input Range for TFT Power Section |
| 文件: | 总13页 (文件大小:572K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
General Description
Features
The MAX20070 evaluation kit (EV kit) demonstrates
the MAX20070 IC, which is a highly integrated power
supply plus LED backlight driver for automotive TFT-LCD
applications. The EV kit is a fully assembled and tested
surface-mount PCB that provides a complete power-
management solution for small-size automotive displays.
The EV kit demonstrates one buck-boost converter, one
boost converter, two gate-voltage controllers, and a boost
converter that powers a dual-string LED driver.
● 2.7V to 5.5V Input Range for TFT Power Section
● 4.5V to 16V Input Range for LED Driver Section
● 1MHz Boost and Inverted Buck-Boost Switching
Frequency on TFT Power Section
● TFT Section Output Voltages
• +6.5V Output at 100mA (Step-Up Switching
Regulator)
• -6.5V Output at 100mA (Inverting Buck-Boost
Switching Regulator)
• +16V Output at 3mA (Positive-Charge Pump)
• -7V Output at 3mA (Negative-Charge Pump)
The DC-DC converter portion of the EV kit operates
from a 2.7V to 5.5V DC supply voltage. The step-up
switching regulator (POS) is configured for a 6.5V or 15V
output that provides 100mA. The inverting buck-boost
converter (NEG) generates a negative output that tracks
the positive output and provides 100mA. The gate-driver
power supplies consist of regulated charge pumps that
generate +16V (GVDD) and -7V (GVEE) and can deliver
up to 3mA each. It is also possible to completely turn off
the inverting buck-boost regulator by changing the value
of the R15 resistor to 140kΩ.
● HB LED String Output Currents Configurable for
80mA or 160mA
● Demonstrates Cycle-by-Cycle Current-Limit and
Thermal-Shutdown Features on Boost LED Driver
● Demonstrates Adaptive Voltage Optimization on LED
Driver Section
● Proven PCB Layout and Thermal Design
● Fully Assembled and Tested
The LED driver section demonstrates a step-up DC-DC
preregulator followed by two channels of linear current
sinks. The step-up preregulator switches at 1MHz and
operates as a current-mode-controlled regulator capable
of providing up to 300mA for the linear circuits. Each
channel is capable of operating up to 38V and provides
up to 160mA. The channels are configurable for 80mA or
160mA HB LED output current.
Ordering Information appears at end of data sheet.
The LED driver portion of the EV kit operates from a DC
supply voltage of 4.5V up to the HB LED string-forward
voltage. The EV kit can withstand a 40V load-dump condi-
tion. The EV kit also demonstrates the IC’s features, such
as adaptive voltage optimization, overvoltage protection
(OVP), cycle-by-cycle current limit, thermal shutdown,
and digital PWM dimming operation using a digital PWM
input signal to control the brightness of the HB LEDs.
The EV kit is shipped with the MAX20070, but can also
be used to evaluate the MAX20070B with IC replacement
of U1.
19-7549; Rev 1; 9/15
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
15) Measure the HB LED current using the current probe
Quick Start
and verify all channels.
Required Equipment
Detailed Description of Hardware
●
●
●
●
●
MAX20070 EV kit
2.7V to 5.5V DC supply
4V to 18V DC supply
Voltmeter
The MAX20070 EV kit LED driver section demon-
strates the MAX20070 HB LED driver with an integrated
step-up DC-DC preregulator followed by two channels of
linear current sinks. The preregulator switches at 1MHz
and operates as a current-mode-controlled regulator,
providing up to 320mA for the linear circuit while
providing OVP. Cycle-by-cycle current limit is set by
resistors R5 and R7, while resistors R2, R4, and R16 set
the OVP voltage to 41.6V. The preregulator power section
consists of inductor L2, power-sense resistors R5 and R7,
and switching diode D1.
Two series-connected HB LED strings rated to no
less than 160mA
●
Current probe to measure the HB LED current
Procedure
The EV kit is fully assembled and tested. Follow the steps
below to verify board operation. Caution: Do not turn on
the power supply until all connections are completed.
The EV kit circuit operates from a DC supply voltage of
4.5V up to the HB LED forward-string voltage. The circuit
handles load-dump conditions up to 40V.
1) Verify that a shunt is installed on jumpers JP2, JP3,
and JP5.
Each of the two linear channels (OUT1 and OUT2) is
capable of operating up to 40V and sinks up to 160mA per
channel. Each of the two channel’s linear current sinks
are configurable for 160mA or 80mA, or can be disabled
independently by shorting the respective OUT_ channel
to ground before power-up with the LED string connected
to the corresponding OUT_ channel removed. Resistors
R6, R8, and jumper JP1 configure the linear current
setting for the IC’s ISET pin, which sets the HB LED string
current.
2) Verify that jumpers JP1 and JP4 are open.
3) Connect the positive terminal of the (2.7V to 5.5V)
power supply to the TFT_POWER_INPUT PCB
pad. Connect the negative terminal of the same
power supply to the PGND PCB pad close to the
TFT_POWER_INPUT PCB pad.
4) Turn on the power supply.
5) Verify that the step-up switching regulator output
(V
) to GND is +6.5V.
POS
6) Verify that the step-up switching regulator output
(V ) to GND is -6.5V.
7) Verify that the positive charge-pump supply (V
NEG
The EV kit features PCB pads to facilitate connecting HB
LED strings for evaluation. The OUT_ PCB pads provide
connections for connecting each HB LED string’s anode
to the DC-DC preregulator output. The OUT1 and OUT2
PCB pads provide connections for connecting each HB
LED string’s cathode to the respective linear channel’s
current sink. Capacitors C16 and C32 are included on the
design to prevent oscillations and provide stability when
using long, untwisted HB LED connecting cables during
lab evaluation. These capacitors are not required on a
typical HB LED design.
)
DGVDD
is approximately +16V.
8) Verify that the negative charge-pump supply
(V ) is approximately -7V.
DGVEE
9) Connect the positive of the (4.0V to 16V) power
supply to the BATTERY INPUT PCB pad and the
power supply’s ground to the LGND PCB pad next
to the BATTERY INPUT PCB pad.
10) Connect the digital voltmeter across the OUT1 and
LGND PCB pads. The LGND PCB pad is close to the
OUT PCB pad.
11) Connect each HB LED string as follows:
Channel 1: Connect an HB LED string anode to the
OUT PCB pad and the cathode to the OUT1 PCB pad.
Channel 2: Connect an HB LED string anode to the
OUT PCB pad and the cathode to the OUT2 PCB pad.
12) Clip the current probe across the channel 1 HB LED+
wire to measure the HB LED current.
13) Turn on the power supply and set it to 10V.
14) Measure the voltage from the OUT1–OUT2 PCB
pads to GND and verify that the lowest voltage is
approximately 0.75V.
A DIM_IN PCB pad is provided for using a digital PWM
signal to control the brightness of the HB LEDs.
Enable Input (EN)
The IC’s source-driver and gate-driver outputs (V
,
POS
V
, V
, and V
) are controlled by driving
DGVEE
NEG DGVDD
the EN pin. The LED driver section is also enabled by
the EN input. When EN is left open, all the outputs are
disabled. When EN is connected to a 2.1V logic-high (or
greater) level, all the outputs are enabled.
Maxim Integrated
│ 2
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
LED current. Remove jumper JP1 when configuring for
another current-sink threshold. If the HB LED current is
reconfigured for a different current, other components
on the EV kit may need to be modified. Refer to the
MAX20070/MAX20070B IC data sheet to calculate other
component values.
Source-Driver Output-Voltage Selection
The EV kit’s step-up switching-regulator output (POS) is
set by feedback resistors R11, R12, and R18. If R12 is 0Ω,
the output voltage is set to 6.5V independent of the state
of JP2. If R12 is changed to 10kΩ and JP2 is open, the
output voltage is 15V. To generate output voltages other
than 6.5V or 15V, open JP2 and select different external
voltage-divider resistors for R11 and R12. The negative
source-driver supply voltage (NEG) is automatically tightly
regulated to -POS within +50mV. NEG cannot be adjusted
independently of POS. Refer to the Source Driver Power
Supplies section in the MAX20070/MAX20070B IC data
sheet for more information.
HB LED Digital Dimming Control
The EV kit features a DIM_IN PCB input pad for
connecting an external digital PWM signal. The DIM_IN
input is pulled up internally to V
by an internal current
CC
source of 5μA. Apply a digital PWM signal with a 0.8V
logic-low (or less) and 2.1V logic-high (or greater) level,
and frequencies from 200Hz to 20kHz. To adjust the HB
LED brightness, vary the signal duty cycle from 0 to
100% and maintain a minimum pulse width of 1μs. Apply
the digital PWM signal to the DIM_IN PCB pad. Refer
to the LED Dimming Control section in the MAX20070/
MAX20070B IC data sheet for additional information on
the dimming feature.
Gate-Driver Output-Voltage Selection
The EV kit’s positive gate-driver power supply (GVDD)
is set to +16V by feedback resistors R9 and R10. To
generate output voltages other than 16V, select
different external voltage-divider resistors for R9 and R10.
The negative gate-driver power supply (GVEE) is set to
-7V by feedback resistors R13 and R14. To generate
output voltages other than -7V, select different external
voltage-divider resistors for R13 and R14. Refer to the
Gate-Driver Power Supplies section in the MAX20070/
MAX20070B IC data sheet for more information.
FLT Signal
The EV kit features a FLT signal. The FLT signal is pulled
up to TFT_POWER_INPUT if JP5 is installed. Refer to the
Short Led Detection and the Fault Protection on the TFT
Section sections in the MAX20070/MAX20070B IC data
sheet for further information on the FLT signal.
HB LED Current
The EV kit features a jumper to reconfigure the IC’s LED
current sinks on both channels. When inserted, jumper
JP1 configures the current sink to 160mA; removing the
jumper configures the current sink to 80mA. See Table
1 for jumper JP1 settings. To reconfigure the circuit for
another current-sink threshold, replace resistor R6 and
use the following equation to calculate a new value for
the desired current:
OVP Configuration
The IC’s LED driver OVP resistors (R2, R4, and R16) are
configured for an OVP of 41.6V. This sets the maximum
channel (V
) voltage at 41.6V. Capacitor C31 provides
OUT
noise filtering to the OVP signal. To reconfigure the circuit
for a different OVP voltage, replace resistors R2 and R16
with a different value using the following equation:
OVP
1500
(R2 + R16) =
−1 ×R4
R6 =
1.25V
I
LED
where R4 is 7.5kΩ, OVP is the overvoltage-protection
voltage desired, and R2 + R16 is the new resistor value
for obtaining the desired overvoltage protection. Refer to
the Open-LED Management and Overvoltage Protection
section in the MAX20070/MAX20070B IC data sheet for
additional information on the OVP feature. Use the N1
MOSFET, in series with resistor R4, to lower the current
drawn from the BATTERY_INPUT when EN is low.
where I
is the desired HB LED current in amps and
LED
R6 is the new resistor value for obtaining the desired HB
Table 1. HB LED Current (JP1)
HB LED
SHUNT
POSITION
ISET PIN
CURRENT-SINK
LIMITS (mA)
Not installed*
Installed
Connected to R6
80
Connected to R6
160
and R8
*Default position.
Maxim Integrated
│ 3
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Component List
PART
QTY
DESCRIPTION
PART
QTY
DESCRIPTION
D1
1
60V, 3A Schottky diode (SMB)
10µF ±20%, 50V aluminum
electrolytic capacitor
Panasonic EEEFK1H100P
C1
1
60V, 2A Schottky diode
(DO-220AA) SS2P6-M3/84A
D2
D6, D9
D10, D11
D12
1
2
2
1
1
33µF ±20%, 50V aluminum
electrolytic capacitor
Suncon 50HVH33M
30V, 0.2A dual-in series zener
diodes (SOT23) BAT54S
C2
1
75V, 0.6A dual-in series zener
diodes (SOT23) MMBD4148SE
1µF ±10%, 50V X7R ceramic
capacitor (0805)
C3
1
1
3
3
5
3
30V, 0.5A Schottky diode
(SOD323) (B0530)
2.2µF ±10%, 50V X7R ceramic
capacitor (1210)
C4
40V, 0.5A Schottky diode
(SOD323) (CMHSH05-4)
D17
1µF ±10%, 50V X7R ceramic
capacitors (1210)
C5, C28, C30
C6, C7, C34
FB1
1
0Ω, 0.25W resistor (1206)
10µF ±10%, 6.3V X7R ceramic
capacitors (0805)
JP1–JP5
5
2-pin headers
0.56μH ±20%, 2.8A inductor
Coilcraft LPS4018-561MR
L1
L2
1
1
2
C8, C17, C18,
C25, C26
4.7µF ±10%, 25V X7R ceramic
capacitors (0805)
4.7μH ±20%, 6.9A inductor
Coilcraft MSS1048-472ML
1µF ±10% , 25V X7R ceramic
capacitors (0805)
C9, C14, C19
10μH ±20%, 1.25A inductors
Coilcraft LPS4018-103MR
L3, L4
C10–C12, C15,
C20, C21, C27,
C33, C37, C38
0.1µF ±10%, 50V X7R ceramic
capacitors (0603)
10
30V, 1.4A n-channel MOSFET
SuperSot-3 (NDS351AN)
N1
R1
1
1
2
33nF ±10%, 50V X7R ceramic
capacitor (0805)
10Ω ±1%, 0.25W resistor (1206)
C13
1
0
4
1
1
1
1
2
121kΩ ±1%, 0.1W resistors
(0603)
R2, R16
Not installed, ceramic capacitors
(0603)
C16, C32
2.55kΩ ±1%, 0.1W resistor
(0603)
R3
R4
1
1
2
C22, C24, C35,
C36
2.2µF ±10%, 25V X7R ceramic
capacitors (0805)
7.5kΩ ±1%, 0.1W resistor (0603)
0.22µF ±10%, 50V X7R ceramic
capacitor (0603)
C23
C29
0.082Ω ±1%, 0.5W resistors
(1210)
R5, R7
470pF ±10%, 50V X7R ceramic
capacitor (0603)
18.7kΩ ±1%, 0.1W resistor
(0603)
R6, R8
R10
2
1nF ±1%, 50V, C0G ceramic
capacitor (0603)
C31
16.9kΩ ±1%, 0.1W resistor
(0603)
1
220pF ±5%, 50V C0G ceramic
capacitor (0603)
C39
110kΩ ±1%, 0.1W resistors
(0603)
R11, R18
R12
2
100pF ±5%, 25V C0G ceramic
capacitors (0603)
C40, C41
1
0Ω, 0.1W resistor (0603)
Maxim Integrated
│ 4
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Component List (continued)
PART
R13
R14
R15
R17
QTY
DESCRIPTION
PART
QTY
DESCRIPTION
1
1
1
1
845kΩ ±1%, 0.1W resistor (0603)
150kΩ ±1%, 0.1W resistor (0603)
20kΩ ±1%, 0.1W resistor (0603)
10kΩ ±1%, 0.1W resistor (0603)
100kΩ ±1%, 0.1W resistors
(0603)
R23, R24
2
Integrated TFT power supply
and LED backlight driver
(32 TQFN-EP*)
U1
1
1
4.99kΩ ±1%, 0.1W resistor
(0603)
Maxim MAX20070GTJ/V+
R19
1
—
PCB: MAX20070 EVKIT+
R20
0
2
Not installed, resistor (0603)
*EP = Exposed pad.
R21, R22
32Ω ±1%, 0.25W resistors (1206)
Maxim Integrated
│ 5
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
ꢁ
ꢀ
ꢆ ꢁ " "
ꢊ
ꢇ
ꢄ ꢇ
ꢋ ꢀ
ꢄ ꢄ
ꢁ
ꢀ
ꢁ
ꢀ
ꢏ ꢂ # ꢊ ꢉ "
ꢈ ꢈ ꢂ ꢀ ꢅ ꢆ ꢅ ꢉ " ꢊ
ꢂ ꢃ # ꢄ ꢅ "
Figure 1. MAX20070 EV Kit Schematic
Maxim Integrated
│ 6
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Figure 2. MAX20070 EV Kit Component Placement Guide—Component Side
Maxim Integrated
│ 7
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Figure 3. MAX20070 EV Kit PCB Layout—Component Side
Maxim Integrated
│ 8
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Figure 4. MAX20070 EV Kit PCB Layout—PGND Layer 2
Maxim Integrated
│ 9
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Figure 5. MAX20070 EV Kit PCB Layout—LGND Layer 3
Maxim Integrated
│ 10
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Figure 6. MAX20070 EV Kit PCB Layout—Solder Side
Maxim Integrated
│ 11
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Ordering Information
PART
TYPE
EV Kit
MAX20070EVKIT#
#Denotes RoHS compliant.
Maxim Integrated
│ 12
www.maximintegrated.com
Evaluates: MAX20070/MAX20070B
MAX20070 Evaluation Kit
Revision History
REVISION REVISION
PAGES
CHANGED
DESCRIPTION
NUMBER
DATE
0
3/15
9/15
Initial release
—
1
Added MAX20070B to data sheet
1–13
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim Integrated’s website at www.maximintegrated.com.
Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses
are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time.
©
Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc.
2015 Maxim Integrated Products, Inc.
│ 13
相关型号:
©2020 ICPDF网 联系我们和版权申明