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LTC3589-2_15 Datasheet, PDF (23/50 Pages) Linear Technology – 8-Output Regulator with Sequencing and I2C
LTC3589/LTC3589-1/
LTC3589-2
OPERATION
frequency is determined by desired efficiency, component
size and converter duty cycle.
Operation at lower frequency improves efficiency by
reducing internal gate charge and switching losses but
requires larger inductance and capacitance values for
comparable output ripple voltage. The lowest duty cycle
of the step-down switching regulator is determined by
the converters minimum on-time. Minimum on-time is
the shortest time duration that the converter is capable of
turning its top PMOS on and off again. The time consists
of the gate charge time plus internal delays associated
with peak current sensing. The minimum on-time of the
LTC3589 is approximately 90ns. If the duty cycle falls
below what can be accommodated by the minimum on-
time, the converter will begin to skip cycles. The output
voltage will continue to be regulated but the ripple voltage
and current will increase. With the switching frequency
set to 2.25MHz, the minimum supported duty cycle is
20%. Switching at 1.125MHz the converter can support
a 10% duty cycle.
Phase Selection
To reduce the cycle by cycle peak current drawn by the
switching regulators, the clock phase of each of the
LTC3589 step-down switching regulators can be set using
I2C command register bits B1DTV2[6], B2DTV2[6] and
B3DTV2[6]. The internal full-rate clock has a nominal
duty cycle of 20% while the half-rate clocks have a 50%
duty cycle. Setting the command register bits high will
delay the start of each converter switching cycle by 20%
or 50% depending on the selected operating frequency.
Inductor Selection
The choice of step-down switching regulator inductor
influences the efficiency of the converter and the magnitude
of the output voltage ripple. Larger inductance values
reduce inductor current ripple and therefore lower output
voltage ripple. A larger value inductor improves efficiency
by lowering the peak current to be closer to the average
output current. Larger inductors, however, generally
have higher series resistance that counters the efficiency
advantage of reduced peak current.
Inductor ripple current is a function of switching frequency,
inductance, VIN, and VOUT, as shown in this equation:
ΔIL
=
f
1
•L
⎛
• VOUT ⎝⎜1–
VOUT
VIN
⎞
⎠⎟
In an example application the LTC3589 step-down
switching regulator 3 has a maximum load of 1A, VIN
equals 3.8V, and VOUT is set for 1.2V. A good starting
design point for inductor ripple is 30% of output current
or 300mA. Using the equation for ripple current, a 1.2µH
inductor should be selected.
An inductor with low DC resistance will improve converter
efficiency. Select an inductor with a DC current rating at least
1.5 times larger than the maximum load current to ensure
the inductor does not saturate during normal operations.
If short-circuit is a possible condition, the inductor should
be rated to handle the maximum peak current specified
for the step-down converter. Table 8 shows inductors
that work well with the step-down switching regulators.
Input/Output Capacitor Selection
Low ESR (equivalent series resistance) ceramic capacitors
should be used at both the output and input supply of the
switching regulators. Only X5R or X7R ceramic capacitors
should be used because they retain their capacitance over
wider voltage and temperature ranges than other ceramic
types. A 22µF capacitor is sufficient for the step-down
switching regulator outputs. For good transient response
and stability the output capacitor should retain at least
10µF of capacitance over operating temperature and bias
voltage. Place at least 4.7µF decoupling capacitance as
close as possible to each PVIN pin. Refer to Table 12 for
recommended ceramic capacitor manufacturers.
For more information www.linear.com/LTC3589
3589fg
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