Datasheet
Data Sheet ADP2442
Rev. 0 | Page 31 of 36
POWER DISSIPATION AND THERMAL CONSIDERATIONS
POWER DISSIPATION
The efficiency of a dc-to-dc regulator is
%100×=
IN
OUT
P
P
Efficiency
(26)
where:
P
IN
is the input power.
P
OUT
is the output power.
The power loss of a dc-to-dc regulator is
P
LOSS
= P
IN
− P
OUT
There are four main sources of power loss in a dc-to-dc regulator
• Inductor losses
• Power switch conduction losses
• Switching losses
• Transition losses
Inductor Losses
Inductor conduction losses are caused by the flow of current
through the inductor DCR (internal resistance). The inductor
power loss (excluding core loss) is
P
L
= I
OUT
2
× DCR
L
(27)
Power Switch Conduction Losses
Power switch conduction losses are caused by the output current,
I
OUT
, flowing through the N-channel MOSFET power switches
that have internal resistance, R
DS(ON)
. The amount of power loss
can be approximated as follows:
P
COND
= [R
DS(ON) – HIGH SIDE
× D + R
DS(ON) – LOW SIDE
× (1 – D)] × I
OUT
2
(28)
Switching Losses
Switching losses are associated with the current drawn by the
driver to turn the power devices on and off at the switching
frequency. Each time a power device gate is turned on and off,
the driver transfers a charge (∆Q) from the input supply to the
gate and then from the gate to ground.
The amount of switching loss can by calculated as follows:
P
SW
= Q
G_TOTAL
× V
IN
× f
SW
(29)
where:
Q
G_TOTAL
is the total gate charge of both the high-side and low-
side devices and is approximately 18 nC.
f
SW
is the switching frequency.
Transition Losses
Transition losses occur because the N-channel MOSFET power
switch cannot turn on or off instantaneously. During a switch
node transition, the power switch provides all of the inductor
current, and the source-to-drain voltage of the power switch is
half the input, resulting in power loss. Transition losses increase
as the load current and input voltage increase; these losses
occur twice for each switching cycle.
The transition losses can be calculated as follows:
SWOFFON
OUT
IN
TRANS
fttI
V
P )(
2
+××=
(30)
where t
ON
and t
OFF
are the rise time and fall time of the switch
node and are each approximately 10 ns for a 24 V input.
THERMAL CONSIDERATIONS
The power dissipated by the regulator increases the die junction
temperature, T
J
, above the ambient temperature, T
A
, as follows:
T
J
= T
A
+ T
R
(31)
where the temperature rise, T
R
, is proportional to the power
dissipation, P
D
, in the package.
The proportionality coefficient is defined as the thermal
resistance from the junction temperature of the die to the
ambient temperature, as follows:
T
R
= θ
JA
+ P
D
(32)
where θ
JA
is the junction-to-ambient thermal resistance and
equals 40°C/W for the JEDEC board (see Table 3).
When designing an application for a particular ambient tempera-
ture range, calculate the expected ADP2442 p
ower dissipation (P
D
)
due to the conduction, switching, and transition losses using
Equation 28, E
quation 29, and Equation 30, and then estimate
the temperature rise using Equation 31 and Equation 32. Improved
thermal performance can be achieved by good board layout.
For
example, on the ADP2442 evaluation board (ADP2442-
EVA LZ ), the measured θ
JA
is <30°C/W. Thermal performance of
the ADP2442-EVA L Z evaluation board is shown in Figure 68
and Figure 69.