Texas Instruments LM3410 Boost Evaluation Board LM3410XMFLEDEV/NOPB LM3410XMFLEDEV/NOPB 데이터 시트
제품 코드
LM3410XMFLEDEV/NOPB
:
=
T
JA
R
P
n
Dissipatio
-
A
T
J
T
=
<
JC
R
P
n
Dissipatio
-
Case-Top
T
J
T
:
=
T
JA
R
P
n
Dissipatio
-
A
T
J
T
=
<
JC
R
P
n
Dissipatio
-
Case
T
J
T
SNVS541G – OCTOBER 2007 – REVISED MAY 2013
P
INTERNAL
= P
COND
+ P
SW
= 107 mW
(48)
Calculating R
θ
JA
and R
Ψ
JC
(49)
We now know the internal power dissipation, and we are trying to keep the junction temperature at or below
125°C. The next step is to calculate the value for R
125°C. The next step is to calculate the value for R
θ
JA
and/or R
Ψ
JC
. This is actually very simple to accomplish,
and necessary if you think you may be marginal with regards to thermals or determining what package option is
correct.
correct.
The LM3410 has a thermal shutdown comparator. When the silicon reaches a temperature of 165°C, the device
shuts down until the temperature drops to 150°C. Knowing this, one can calculate the R
shuts down until the temperature drops to 150°C. Knowing this, one can calculate the R
θ
JA
or the R
Ψ
JC
of a
specific application. Because the junction to top case thermal impedance is much lower than the thermal
impedance of junction to ambient air, the error in calculating R
impedance of junction to ambient air, the error in calculating R
Ψ
JC
is lower than for R
θ
JA
. However, you will need
to attach a small thermocouple onto the top case of the LM3410 to obtain the R
Ψ
JC
value.
Knowing the temperature of the silicon when the device shuts down allows us to know three of the four variables.
Once we calculate the thermal impedance, we then can work backwards with the junction temperature set to
125°C to see what maximum ambient air temperature keeps the silicon below the 125°C temperature.
Once we calculate the thermal impedance, we then can work backwards with the junction temperature set to
125°C to see what maximum ambient air temperature keeps the silicon below the 125°C temperature.
Procedure:
Place your application into a thermal chamber. You will need to dissipate enough power in the device so you can
obtain a good thermal impedance value.
obtain a good thermal impedance value.
Raise the ambient air temperature until the device goes into thermal shutdown. Record the temperatures of the
ambient air and/or the top case temperature of the LM3410. Calculate the thermal impedances.
ambient air and/or the top case temperature of the LM3410. Calculate the thermal impedances.
Example from previous calculations (SOT-23 Package):
P
INTERNAL
= 107 mW
(50)
T
A
@ Shutdown = 155°C
(51)
T
C
@ Shutdown = 159°C
(52)
(53)
R
θ
JA
SOT-23 = 93°C/W
(54)
R
Ψ
JC
SOT-23 = 56°C/W
(55)
Typical WSON and MSOP-PowerPad typical applications will produce R
θ
JA
numbers in the range of 50°C/W to
65°C/W, and R
Ψ
JC
will vary between 18°C/W and 28°C/W. These values are for PCB’s with two and four layer
boards with 0.5 oz copper, and four to six thermal vias to bottom side ground plane under the DAP. The thermal
impedances calculated above are higher due to the small amount of power being dissipated within the device.
impedances calculated above are higher due to the small amount of power being dissipated within the device.
Note: To use these procedures it is important to dissipate an amount of power within the device that will indicate
a true thermal impedance value. If one uses a very small internal dissipated value, one can see that the thermal
impedance calculated is abnormally high, and subject to error.
a true thermal impedance value. If one uses a very small internal dissipated value, one can see that the thermal
impedance calculated is abnormally high, and subject to error.
shows the nonlinear relationship of
internal power dissipation vs . R
θ
JA
.
22
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