ADP1870ACPZ-0.3-R7 Analog Devices Inc, ADP1870ACPZ-0.3-R7 Datasheet - Page 27
ADP1870ACPZ-0.3-R7
Manufacturer Part Number
ADP1870ACPZ-0.3-R7
Description
300kHz, Light Load Eff Enabled
Manufacturer
Analog Devices Inc
Datasheet
1.ADP1870-0.3-EVALZ.pdf
(44 pages)
Specifications of ADP1870ACPZ-0.3-R7
Frequency - Max
300kHz
Pwm Type
Current Mode
Number Of Outputs
1
Duty Cycle
84%
Voltage - Supply
2.95 V ~ 20 V
Buck
Yes
Boost
No
Flyback
No
Inverting
No
Doubler
No
Divider
No
Cuk
No
Isolated
No
Operating Temperature
-40°C ~ 125°C
Package / Case
10-WFDFN, CSP Exposed Pad
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Other names
ADP1870ACPZ-0.3-R7
ADP1870ACPZ-0.3-R7TR
ADP1870ACPZ-0.3-R7TR
Diode Conduction Loss
The ADP1870/ADP1871 employ anticross conduction circuitry
that prevents the upper- and lower-side MOSFETs from conducting
current simultaneously. This overlap control is beneficial, avoiding
large current flow that may lead to irreparable damage to the
external components of the power stage. However, this blanking
period comes with the trade-off of a diode conduction loss
occurring immediately after the MOSFETs change states and
continuing well into idle mode. The amount of loss through the
body diode of the lower-side MOSFET during the antioverlap
state is given by the following expression:
where:
t
dead time periods).
t
V
(Refer to the selected external MOSFET data sheet for more
information about the V
Inductor Loss
During normal conduction mode, further power loss is caused
by the conduction of current through the inductor windings,
which have dc resistance (DCR). Typically, larger sized inductors
have smaller DCR values.
The inductor core loss is a result of the eddy currents generated
within the core material. These eddy currents are induced by the
changing flux, which is produced by the current flowing through
the windings. The amount of inductor core loss depends on the
core material, the flux swing, the frequency, and the core volume.
Ferrite inductors have the lowest core losses, whereas powdered
iron inductors have higher core losses. It is recommended that
shielded ferrite core material type inductors be used with the
ADP1870/ADP1871 for a high current, dc-to-dc switching
BODY(LOSS)
SW
F
is the forward drop of the body diode during conduction.
is the period per switching cycle.
Figure 82. Body Diode Conduction Time vs. Low Voltage Input (V
P
BODY
80
72
64
56
48
40
32
24
16
8
2.7
is the body conduction time (refer to Figure 82 for
(
LOSS
)
=
t
BODY
3.4
t
SW
(
LOSS
F
1MHz
300kHz
parameter.)
)
×
I
V
LOAD
REG
4.1
(V)
×
V
F
×
2
4.8
+125°C
+25°C
–40°C
5.5
REG
)
Rev. A | Page 27 of 44
application to achieve minimal loss and negligible electromagnetic
interference (EMI).
INPUT CAPACITOR SELECTION
The goal in selecting an input capacitor is to reduce or minimize
input voltage ripple and to reduce the high frequency source
impedance, which is essential for achieving predictable loop
stability and transient performance.
The problem with using bulk capacitors, other than their
physical geometries, is their large equivalent series resistance
(ESR) and large equivalent series inductance (ESL). Aluminum
electrolytic capacitors have such high ESR that they cause
undesired input voltage ripple magnitudes and are generally not
effective at high switching frequencies.
If bulk capacitors are to be used, it is recommended that muli-
layered ceramic capacitors (MLCC) be used in parallel due to
their low ESR values. This dramatically reduces the input voltage
ripple amplitude as long as the MLCCs are mounted directly
across the drain of the upper-side MOSFET and the source
terminal of the lower-side MOSFET (see the Layout Considerations
section). Improper placement and mounting of these MLCCs
may cancel their effectiveness due to stray inductance and an
increase in trace impedance.
The maximum input voltage ripple and maximum input capacitor
rms current occur at the end of the duration of 1 − D while the
upper-side MOSFET is in the off state. The input capacitor rms
current reaches its maximum at Time D. When calculating the
maximum input voltage ripple, account for the ESR of the input
capacitor as follows:
where:
V
I
ESR is the equivalent series resistance rating of the input capacitor.
Inserting V
the minimum input capacitor requirement gives
or
where D = 50%.
LOAD,max
RIPP
V
C
C
P
I
is usually 1% of the minimum voltage input.
CIN
DCR
RIPPLE,max
IN,min
IN,min
is the maximum load current.
,
(
rms
LOSS
RIPPLE,max
=
=
=
)
I
V
= V
4
=
I
LOAD,max
RIPPLE,max
f
LOAD,max
DCR
SW
I
RIPP
LOAD,max
into the charge balance equation to calculate
V
×
RIPPLE,max
+ ( I
×
I
2
LOAD
×
LOAD,max
V
D
OUT
1 ( −
+ Core Loss
f
SW
×
V
× ESR )
(
D
V
OUT
ADP1870/ADP1871
)
IN
−
V
OUT
)
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