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MIC2571_02 Datasheet, PDF (8/12 Pages) Micrel Semiconductor – Single-Cell Switching Regulator
MIC2571
When the output switch turns off, the voltage across the
inductor changes sign and flies high in an attempt to maintain
a constant current. The inductor voltage will eventually be
clamped to a diode drop above VOUT. Therefore, when the
output switch is off, the voltage across the inductor is:
V2 = VOUT + VDIODE – VIN
For normal operation the inductor current is a triangular
waveform which returns to zero current (discontinuous mode)
at each cycle. At the threshold between continuous and
discontinuous operation we can use the fact that I1 = I2 to get:
V1 × t1 = V2 × t2
V1 = t2
V2
t1
This relationship is useful for finding the desired oscillator
duty cycle based on input and output voltages. Since input
voltages typically vary widely over the life of the battery, care
must be taken to consider the worst case voltage for each
parameter. For example, the worst case for t1 is when VIN is
at its minimum value and the worst case for t2 is when VIN is
at its maximum value (assuming that VOUT, VDIODE and VSAT
do not change much).
To select an inductor for a particular application, the worst
case input and output conditions must be determined. Based
on the worst case output current we can estimate efficiency
and therefore the required input current. Remember that this
is power conversion, so the worst case average input current
will occur at maximum output current and minimum input
voltage.
Average IIN(max) =
VOUT × IOUT(max)
VIN(min) × Efficiency
Micrel
Referring to Figure 1, it can be seen the peak input current will
be twice the average input current. Rearranging the inductor
equation to solve for L:
L=
V
I
× t1
L=
VIN(min)
2 × Average IIN(max)
× t1
where t1 =
duty cycle
fOSC
To illustrate the use of these equations a design example will
be given:
Assume:
MIC2571-1 (fixed oscillator)
VOUT = 5V
IOUT(max) =5mA
VIN(min) = 1.0V
efficiency = 75%.
Average IIN(max) =
5V × 5mA
1.0V × 0.75
= 33.3mA
L=
1.0V × 0.7
2 × 33.3mA × 20kHz
L = 525µH
Use the next lowest standard value of inductor and verify that
it does not saturate at a current below about 75mA
(< 2 × 33.3mA).
MIC2571
8
1997