Texas Instruments TPS61150A-150 Evaluation Board TPS61150AEVM-150 TPS61150AEVM-150 TPS61150AEVM-150 데이터 시트
제품 코드
TPS61150AEVM-150
www.ti.com
DETAILED DESCRIPTION
CURRENT REGULATION
I
O
+
V
ISET
R
SET
K
ISET
(1)
START UP
OVERVOLTAGE PROTECTION
UNDERVOLTAGE LOCKOUT
THERMAL SHUTDOWN
SLVS706 – OCTOBER 2006
The TPS61150A uses a single boost regulator to drive 2 WLED strings whose current can be programmed
independently. The boost converter adopts PWM control which is ideal for high output current and low output
ripple noises. The feedback loop regulates the IFB pin to a threshold voltage (330mV typical), giving the current
sink circuit just enough headroom to operate.
independently. The boost converter adopts PWM control which is ideal for high output current and low output
ripple noises. The feedback loop regulates the IFB pin to a threshold voltage (330mV typical), giving the current
sink circuit just enough headroom to operate.
The regulation current is set by the resistor on the Iset pin based on
where
I
O
= output current
V
ISET
= Iset pin voltage (1.229V typical)
R
SET
= Iset pin resistor value
K
ISET
= current multiplier (920 typical)
When both outputs are enabled, the boost converter regulates to the IFB pin that demands higher Iout pin
voltage, V
voltage, V
(IOUT)
, and let the other IFB pin rise above its regulation voltage. The feedback path dynamically
switches to the other IFB pin if its voltage drops more than the IFB low hysterisis (60mV typical) below it's
regulation voltage. This ensures proper current regulation for both outputs. When both IFB voltages are low,
IFB1 is used for regulation. Once IFB1 reaches its regulation voltage, the feedback path may hand over to IFB2
if it is still low, and the boost output will continue to rise.
regulation voltage. This ensures proper current regulation for both outputs. When both IFB voltages are low,
IFB1 is used for regulation. Once IFB1 reaches its regulation voltage, the feedback path may hand over to IFB2
if it is still low, and the boost output will continue to rise.
The overall efficiency in this mode depends on the voltage different between the IFB1 and IFB2. A large
difference reduces the efficiency due to power losses across the current sink circuit. To improve the efficiency of
the both-on mode, the two current outputs can be turned on complimentarily by applying out of phase enable
signal to the SEL pins. The ISET pin resistors need to be recalculated to compensate for the reduced DC
current.
difference reduces the efficiency due to power losses across the current sink circuit. To improve the efficiency of
the both-on mode, the two current outputs can be turned on complimentarily by applying out of phase enable
signal to the SEL pins. The ISET pin resistors need to be recalculated to compensate for the reduced DC
current.
During start up, both the boost converter and the current sink circuitry are trying to establish steady state
simultaneously. The current sink circuitry ramps up current in 16 steps, with each step taking 64 clock cycles.
This ensures that the current sink loop is slower than the boost converter response during startup. Therefore,
the boost converter output comes up slowly as current sink circuitry ramps up the current. This ensures smooth
start up and minimizes in-rush current.
simultaneously. The current sink circuitry ramps up current in 16 steps, with each step taking 64 clock cycles.
This ensures that the current sink loop is slower than the boost converter response during startup. Therefore,
the boost converter output comes up slowly as current sink circuitry ramps up the current. This ensures smooth
start up and minimizes in-rush current.
To prevent the boost output run away as the result of WLED disconnection, there is an overvoltage protection
circuit which stops the boost converter from switching as soon as its output exceeds the OVP threshold. When
the voltage falls below the OVP threshold, the converter resumes switching. TPS61150A provides 28V(typical)
OVP to prevent a 25V rated output capacitor or the internal 30V FET from breaking down.
circuit which stops the boost converter from switching as soon as its output exceeds the OVP threshold. When
the voltage falls below the OVP threshold, the converter resumes switching. TPS61150A provides 28V(typical)
OVP to prevent a 25V rated output capacitor or the internal 30V FET from breaking down.
An undervoltage lockout prevents mis-operation of the device for input voltages below 1.65V (typical). When the
input voltage is below the undervoltage threshold, the device remains off and both the boost converter and
current sink circuit are turned off, providing isolation between input and output.
input voltage is below the undervoltage threshold, the device remains off and both the boost converter and
current sink circuit are turned off, providing isolation between input and output.
An internal thermal shutdown turns off the IC when the typical junction temperature of 160
°
C is exceeded. The
thermal shutdown has a hysteresis of typically 15
°
C.
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