Texas Instruments LM3402HV Evaluation Board LM3402HVEVAL/NOPB LM3402HVEVAL/NOPB 데이터 시트
제품 코드
LM3402HVEVAL/NOPB
I
IN(rms)
= I
F
x D(1 - D)
C
IN(MIN)
=
'
V
IN(MAX)
I
F
x t
ON
'
i
F
=
Z
C
= ESR +
'
i
L
r
D
1 +
Z
C
1
2
S
x f
SW
x C
O
'
i
L
ESR
r
D
R
SNS
'
i
C
'
i
F
'
i
L
C
O
SNVS450E – SEPTEMBER 2006 – REVISED MAY 2013
Figure 22. LED and C
O
Ripple Current
To calculate the respective ripple currents the LED array is represented as a dynamic resistance, r
D
. LED
dynamic resistance is not always specified on the manufacturer’s datasheet, but it can be calculated as the
inverse slope of the LED’s V
inverse slope of the LED’s V
F
vs. I
F
curve. Note that dividing V
F
by I
F
will give an incorrect value that is 5x to 10x
too high. Total dynamic resistance for a string of n LEDs connected in series can be calculated as the r
D
of one
device multiplied by n. Inductor ripple current is still calculated with the expression from Buck Regulators without
Output Capacitors. The following equations can then be used to estimate
Output Capacitors. The following equations can then be used to estimate
Δ
i
F
when using a parallel capacitor:
(12)
The calculation for Z
C
assumes that the shape of the inductor ripple current is approximately sinusoidal.
Small values of C
O
that do not significantly reduce
Δ
i
F
can also be used to control EMI generated by the
switching action of the LM3402/02HV. EMI reduction becomes more important as the length of the connections
between the LED and the rest of the circuit increase.
between the LED and the rest of the circuit increase.
INPUT CAPACITORS
Input capacitors at the VIN pin of the LM3402/02HV are selected using requirements for minimum capacitance
and rms ripple current. The input capacitors supply pulses of current approximately equal to I
and rms ripple current. The input capacitors supply pulses of current approximately equal to I
F
while the power
MOSFET is on, and are charged up by the input voltage while the power MOSFET is off. Switching converters
such as the LM3402/02HV have a negative input impedance due to the decrease in input current as input
voltage increases. This inverse proportionality of input current to input voltage can cause oscillations (sometimes
called ‘power supply interaction’) if the magnitude of the negative input impedance is greater the the input filter
impedance. Minimum capacitance can be selected by comparing the input impedance to the converter’s negative
resistance; however this requires accurate calculation of the input voltage source inductance and resistance,
quantities which can be difficult to determine. An alternative method to select the minimum input capacitance,
C
such as the LM3402/02HV have a negative input impedance due to the decrease in input current as input
voltage increases. This inverse proportionality of input current to input voltage can cause oscillations (sometimes
called ‘power supply interaction’) if the magnitude of the negative input impedance is greater the the input filter
impedance. Minimum capacitance can be selected by comparing the input impedance to the converter’s negative
resistance; however this requires accurate calculation of the input voltage source inductance and resistance,
quantities which can be difficult to determine. An alternative method to select the minimum input capacitance,
C
IN(MIN)
, is to select the maximum voltage ripple which can be tolerated. This value,
Δ
v
IN(MAX)
, is equal to the
change in voltage across C
IN
during the converter on-time, when C
IN
supplies the load current. C
IN(MIN)
can be
selected with the following:
(13)
A good starting point for selection of C
IN
is to use an input voltage ripple of 5% to 10% of V
IN
. A minimum input
capacitance of 2x the C
IN(MIN)
value is recommended for all LM3402/02HV circuits. To determine the rms current
rating, the following formula can be used:
(14)
16
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