MAX749ESA Ver la hoja de datos (PDF) - Maxim Integrated
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MAX749ESA Datasheet PDF : 12 Pages
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Digitally Adjustable LCD Bias Supply
+4.5V to +6V
INPUT
0.1µF
V+ CS
MAX749 DHI
CTRL
DLOW
22µF
RSENSE
Q1
SMD10P05L
ADJ
GND
L1
47µH
R1
R2
VOUT(MIN) = -R1(13.33µA)
VOUT(MAX) = -(R1+R2)(13.33µA)
CCOMP
D1
1N5819
VOUT
(NEGATIVE)
22µF
30V
Figure 8. Using a Potentiometer to Adjust the Output Voltage
counter rolls over and sets the DAC to -VOUT(MIN),
where -VOUT(MIN) = RFB x 6.66µA. In other words, a sin-
gle rising edge of ADJ increments the DAC output by
one, and 63 rising edges of ADJ decrement the DAC
output by one.
Potentiometer Adjustment
It is also possible to adjust the output voltage using a
potentiometer instead of the internal DAC (Figure 8). On
power-up (V+ applied), the internal current source is set
to mid-scale, or 13.33µA. Choose R1 and R2 with the fol-
lowing equations:
R1 = -VOUT(MIN)/13.33µA
R2 = -VOUT(MAX)/13.33µA - R1.
Where the potentiometer can be varied from 0 (producing
VOUT(MIN)) to R2Ω (producing VOUT(MAX)). Notice that ADJ
is connected to ground, allowing the device to be shut
down.
PWM Adjustment
A positive pulse-width modulated (PWM) logic signal
(e.g., from a microcontroller) can control the MAX749’s
output voltage. Use the PWM signal to pull up the FB
pin through a suitable resistor. An RC network on the
PWM output would also be required. In this configura-
tion, the longer the PWM signal remains high, the more
negative the MAX749’s output will be driven.
Current-Sense Resistor
The current-sense resistor limits the peak switch cur-
rent to 140mV/RSENSE, where RSENSE is the value of the
current-sense resistor, and 140mV is the typical cur-
rent-sense comparator threshold (see V+ to CS Voltage
in the Electrical Characteristics).
To maximize efficiency and reduce the size and cost of
the external components, minimize the peak current.
However, since the output current is a function of the peak
current (Figures 9a-9e), the limit should not be set too low.
No calculations are required to choose the proper cur-
rent-sense resistor; simply follow this two-step procedure:
1. Determine:
- the minimum input voltage, VIN(MIN),
- the maximum output voltage, VOUT(MAX), and
- the maximum output current, IOUT(MAX).
For example, assume that the output voltage must be
adjustable to -24V (VOUT(MAX) = -24V) at up to 30mA
(IOUT(MAX) = 30mA). The supply voltage ranges from
4.75V to 6V (VIN(MIN) = 4.75V).
2. In Figures 9a-9e, locate the graph drawn for the
appropriate output voltage (which is either the
desired output voltage or, if that is not shown, the
graph for the nearest voltage more negative than the
desired output). On this graph find the curve for the
highest RSENSE (the lowest current limit) with an out-
put current that is adequate at the lowest input
voltage.
In this example, select the -24V output graph, Figure 9d.
We then want a curve where IOUT is ≥30mA with a 4.75V
input. The 0.3Ω RSENSE graph shows 25mA of output cur-
rent with a 4.75V input, so we look next at the 0.25Ω
RSENSE graph. It shows IOUT = 30mA for VIN = 4.75V and
VOUT = -24V. Therefore select RSENSE = 0.25Ω. This pro-
vides a current limit in the range 440mA to 720mA.
Alternatively, a 0.2Ω sense resistor can be used. This
gives a current limit in the range 550mA to 900mA, but
enables over 40mA to be generated at -24V with input
voltages down to 4.5V. A 0.2Ω resistor may be easier to
obtain than an 0.25Ω resistor.
The theoretical design curves shown in Figures 9a-9e
assume the minimum (worst-case) value for the current-
limit comparator threshold. Having selected the cur-
rent-sense resistor, the maximum current limit is given
by 180mV/RSENSE. Use the maximum current-limit fig-
ure when choosing the transistor, coil, and diode.
IRC (see Table 2) makes surface-mount resistors with pre-
ferred values including: 0.1Ω, 0.2Ω, 0.3Ω, 0.5Ω, and 1.0Ω.
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