English
Language : 

MAX16833_11 Datasheet, PDF (16/22 Pages) Maxim Integrated Products – High-Voltage HB LED Drivers with Integrated High-Side Current Sense
High-Voltage HB LED Drivers with
Integrated High-Side Current Sense
Slope Compensation
Slope compensation should be added to converters
with peak current-mode control operating in continuous-
conduction mode with more than 50% duty cycle to
avoid current-loop instability and subharmonic oscilla-
tions. The minimum amount of slope compensation that
is required for stability is:
VSCMIN = 0.5 (inductor current downslope -
inductor current upslope) x R4
In the ICs, the slope-compensating ramp is added to the
current-sense signal before it is fed to the PWM com-
parator. Connect a resistor (R1) from CS to the inductor
current-sense resistor terminal to program the amount of
slope compensation.
The ICs generate a current ramp with a slope of 50FA/
tOSC for slope compensation. The current-ramp signal is
forced into the external resistor (R1) connected between
CS and the source of the external MOSFET, thereby
adding a programmable slope compensating voltage
(VSCOMP) at the current-sense input CS. Therefore:
dVSC/dt = (R1 x 50FA)/tOSC in V/s
The minimum value of the slope-compensation voltage
that needs to be added to the current-sense signal at
peak current and at minimum line voltage is:
SCMIN
=
(DMAX
× (VLED - 2VINMIN) × R4)
2 × LMIN × fSW
(V) Boost
SCMIN
=
(DMAX
× (VLED -
2 × LMIN
VINMIN) × R4)
× fSW
(V)Buck-boost
where fSW is the switching frequency, DMAX is the maxi-
mum duty cycle, which occurs at low line, VINMIN is the
minimum input voltage, and LMIN is the minimum value of
the selected inductor. For adequate margin, the slope-com-
pensation voltage is multiplied by a factor of 1.5. Therefore,
the actual slope-compensation voltage is given by:
VSC = 1.5SCMIN
From the previous formulas, it is possible to calculate the
value of R4 as:
For boost configuration:
0.418V
R4 =
IL P
+
0.75DMAX
VLED − 2VINMIN
L MINfSW
For buck-boost configuration:
R4 =
0.418V
IL P
+
0.75DMAX
VLED − VINMIN
L MINfSW
The minimum value of the slope-compensation resistor
(R1) that should be used to ensure stable operation at
minimum input supply voltage can be calculated as:
For boost configuration:
R1= (VLED − 2VINMIN) × R4 ×1.5
2 × LMIN × fSW × 50µA
For buck-boost configuration :
R1= (VLED − VINMIN) × R4 ×1.5
2 × LMIN × fSW × 50µA
where fSW is the switching frequency in hertz, VINMIN
is the minimum input voltage in volts, VLED is the LED
voltage in volts, DMAX is the maximum duty cycle, ILP
is the peak inductor current in amperes, and LMIN is the
minimum value of the selected inductor in henries.
Output Capacitor
The function of the output capacitor is to reduce the
output ripple to acceptable levels. The ESR, ESL, and
the bulk capacitance of the output capacitor contribute
to the output ripple. In most applications, the output ESR
and ESL effects can be dramatically reduced by using
low-ESR ceramic capacitors. To reduce the ESL and
ESR effects, connect multiple ceramic capacitors in par-
allel to achieve the required bulk capacitance. To mini-
mize audible noise generated by the ceramic capacitors
during PWM dimming, it could be necessary to minimize
the number of ceramic capacitors on the output. In these
cases, an additional electrolytic or tantalum capacitor
provides most of the bulk capacitance.
Boost and Buck-Boost Configurations
The calculation of the output capacitance is the same for
both boost and buck-boost configurations. The output rip-
ple is caused by the ESR and the bulk capacitance of the
output capacitor if the ESL effect is considered negligible.
For simplicity, assume that the contributions from ESR and
the bulk capacitance are equal, allowing 50% of the ripple
for the bulk capacitance. The capacitance is given by:
C OUT
≥
ILED × 2 × DMAX
VOUTRIPPLE × fSW
16   �������������������������������������������������������������������������������������