MAXIM MAX756EVKIT

MAX756 Evaluation Kit
____________________________Features
♦ Operates Down to 0.7V Input Supply Voltage
♦ 87% Efficiency at 200mA
♦ 60µA Quiescent Current
♦ 20µA Shutdown Mode with Active Reference and
LBI Detector
♦ 500kHz Maximum Switching Frequency
♦ ±1.5% Reference Tolerance Over Temperature
♦ Low-Battery Detector (LBI/LBO)
♦ 8-Pin DIP and SO Packages
♦ Surface-Mount Construction
♦ Fully Assembled and Tested
______________Ordering Information
PART
MAX756EVKIT-SO
TEMP. RANGE
0°C to +70°C
BOARD TYPE
Surface Mount
EV Kit
Quick Reference
The MAX756 EV kit is a fully assembled and tested surface-mount board. Follow these steps to verify board
operation.
Do not turn on the power supply until all connections are completed.
1. Connect a 1.8V to 5.5V supply to the pad marked
VIN. The ground connects to the GND pad.
2. Connect a voltmeter and load (if any) to the VOUT
pad.
3. Place the shunt on J1 across pins 1 and 2.
4. Place the shunt on J2 across pins 1 and 2 for a 5V
output voltage. If a 3.3V output is desired, the
shunt goes across pins 2 and 3, and the input
voltage must be less than 3.6V.
5. Turn on the power and verify that the output
voltage is 5V.
6. Refer to the section Using the MAX757 to modify
the board for different output voltages.
________________________________________________________________ Maxim Integrated Products
Call toll free 1-800-998-8800 for free samples or literature.
1
Evaluates: MAX756/MAX757
_______________General Description
The MAX756 evaluation kit (EV kit) is a fully assembled
and tested surface-mount printed circuit board. It can
also be modified to fit the adjustable-output MAX757.
The MAX756/MAX757 are CMOS, step-up, DC-DC
switching regulators for small, low input voltage or battery-powered systems. The MAX756 accepts a positive
input voltage down to 0.7V and converts it to a higher
pin-selectable output voltage of 3.3V or 5V. The
MAX757 is an adjustable version that accepts an input
voltage down to 0.7V and generates a higher adjustable
output voltage in the 2.7V to 5.5V range. Typical fullload efficiencies for the MAX756/MAX757 are greater
than 87%.
A movable jumper selects either 3.3V or 5.0V output
voltage, and additional pads on the bottom of the board
are provided to place resistors for the LBI/LBO low-battery detector and MAX757 output adjustment.
Evaluates: MAX756/MAX757
MAX756 Evaluation Kit
____________________Component List
DESIGNATION
QTY
C1
1
0.1µF, 50V ceramic capacitor
DESCRIPTION
C2, C3
2
100µF, 10V, low-ESR tantalum
capacitors; Sprague
595D107X0010D7
R1, R2,
R3, R4, R5
0
Open
L1
1
22µH power inductor;
Sumida CD54-220, CoilCraft
DT3316-223, Coiltronix CTX-20,
Murata Erie LQH4N150K0M00
(lower-current 30mA applications)
D1
1
1A, 20V Schottky diode
(1N5817) Nihon EC15QS02L,
Motorola MBRS130T3
Collmer SE014, SE024
U1
1
MAX756CSA (8-pin SO)
None
2
3-pin headers
None
2
Shunts
None
1
2.00" x 2.00" PC board
None
1
MAX756 data sheet
Input Power = (5.0V x 100mA) / 85%
Input Power = 588mW
and
Input Current = 588mW / 2.5V
Input Current = 235mA
Once started, the MAX756 actually operates at 10mA
output from the regulated output voltage. This means
that the input voltage can fall below the 1.8V minimum
guaranteed start-up voltage. Typically, the regulated
output will be maintained even if the input voltage
drops to 0.7V.
Jumper Selection
Two 3-pin headers select the shutdown mode and output
voltage. Table 1 lists the selectable jumper options.
Using the Low-Battery Indicator
Refer to MAX756/MAX757 data sheet for component
suppliers’ phone numbers.
_______________Detailed Description
Input Source
The input source for the MAX756 evaluation board
must be greater than 1.8V for guaranteed start-up (0.7V
for operation once started), and less than the output
voltage plus 0.5V. A typical input voltage range would
be the 2.0V to 3.3V range of a 2-cell NiCd battery. An
input voltage greater than the selected output voltage
(but less than 7V) will not damage the circuit.
However, the MAX756 output will equal the input voltage minus the 0.3V drop of the Schottky diode, D1.
The input current depends on the power delivered to
the load. The following equations show how to calculate the expected input current requirement.
Input Power = Output Power / Efficiency
and
Input Current = Input Power / Input Voltage
To calculate the input current for a typical operating circuit, assume a 2.5V input voltage, a 5V output voltage,
2
and a 100mA load. The expected efficiency can be
taken from the graphs on the MAX756 data sheet.
Under the above conditions, the MAX756 delivers 85%
efficiency.
The MAX756 has an additional comparator useful for
monitoring the input source’s voltage level. Resistor
locations R3 and R4 on the bottom of the printed circuit
board are connected as a voltage divider between the
LBI pad and the MAX756 LBI pin. Note that a printed
circuit board trace across R4 shorts the LBI pin to
ground when this function is not used. Cut the trace
before installing R4. Refer to the Low-Battery Detection
section of the MAX756/MAX757 data sheet for instructions on selecting values for resistors R3 and R4.
Table 1. Jumper Selection
J1 Shunt J2 Shunt SHDN Pin
Location Location Connection
3V/5V Pin
Connection
MAX756
Output
1&2
1&2
VOUT
GND
5.0V
1&2
2&3
VOUT
VOUT
3.3V
2&3
1&2
GND
GND
VIN -0.3V
2&3
2&3
GND
VOUT
VIN -0.3V
_______________________________________________________________________________________
MAX756 Evaluation Kit
The MAX756 can be replaced with a MAX757 to generate output voltages in the 2.7V to 5.5V range using
external resistors. Besides replacing the IC, the only
other modification required is to remove the shunt on
J2 and add the output voltage-divider resistors R1 and
R2 (located on the bottom of the board). The Output
Voltage Selection section of the MAX756/MAX757 data
sheet gives instructions for calculating R1 and R2 values.
Inductor Selection
The 22µH Sumida CD54-220 inductor that comes standard with the EV kit is a low-resistance, medium current inductor. It will provide excellent performance
over the line and load ranges of the MAX756/MAX757.
A smaller 22µH Sumida inductor (CD43-220) can
also be used in most applications. For ultra-smalll,
lower-current applications, the 15µH Murata Erie
LQH4N150K0M00 inductor is a good choice. Its
dimensions are 3.2 x 4.5 x 3.6mm, and it can be used
for outputs in the 30mA range. Efficiency will typically
be greater than 80% using this inductor.
VIN
1
SHDN
3
C2
100µF
R1
OPEN
R5
OPEN
2
J1
1
SHDN
L1
22µH
LX 8
D1
1N5817
3
2 3/5
2
1
J2
3
R2
OPEN
C1
0.1µF
4
VREF
LBO
C3
100µF
10V
MAX756 GND 7
OUT
LBI
VOUT
+5V
6
5
R3
OPEN
LBI
R4
0Ω
(SHORT)
LBO
Figure 1. MAX756 EV Kit Schematic
_______________________________________________________________________________________
3
Evaluates: MAX756/MAX757
Using the MAX757
Another location on the board facilitates the addition of
a pull-up resistor on the LBO output. The LBO output
is an open-drain output that can sink 2mA, but will
source only 1µA. Install resistor R5 if an external circuit
is to be driven from LBO.
Evaluates: MAX756/MAX757
MAX756 Evaluation Kit
Figure 2. MAX756 EV Kit Component Placement Guide—
Component Side
Figure 3. MAX756 EV Kit Component Placement Guide—
Solder Side
Figure 4. MAX756 EV Kit Component-Side Layout
Figure 5. MAX756 EV Kit Solder-Side Layout
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are
implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
4 ___________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 (408) 737-7600
© 1995 Maxim Integrated Products
Printed USA
is a registered trademark of Maxim Integrated Products.