LT8300E Просмотр технического описания (PDF) - Analog Devices
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LT8300E Datasheet PDF : 24 Pages
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LT8300
OPERATION
The LT8300 is a current mode switching regulator IC
designed specially for the isolated flyback topology. The
key problem in isolated topologies is how to communicate
the output voltage information from the isolated secondary
side of the transformer to the primary side for regulation.
Historically, opto-isolators or extra transformer windings
communicate this information across the isolation bound-
ary. Opto-isolator circuits waste output power, and the extra
components increase the cost and physical size of the
power supply. Opto-isolators can also cause system issues
due to limited dynamic response, nonlinearity, unit-to-unit
variation and aging over lifetime. Circuits employing extra
transformer windings also exhibit deficiencies, as using an
extra winding adds to the transformer’s physical size and
cost, and dynamic response is often mediocre.
The LT8300 samples the isolated output voltage through
the primary-side flyback pulse waveform. In this man-
ner, neither opto-isolator nor extra transformer winding
is required for regulation. Since the LT8300 operates
in either boundary conduction mode or discontinuous
conduction mode, the output voltage is always sampled
on the SW pin when the secondary current is zero. This
method improves load regulation without the need of
external load compensation components.
The LT8300 is a simple to use micropower isolated fly-
back converter housed in a 5-lead TSOT-23 package. The
output voltage is programmed with a single external resis-
tor. By integrating the loop compensation and soft-start
inside, the part further reduces the number of external
components. As shown in the Block Diagram, many of
the blocks are similar to those found in traditional switch-
ing regulators including reference, regulators, oscillator,
logic, current amplifier, current comparator, driver, and
power switch. The novel sections include a flyback pulse
sense circuit, a sample-and-hold error amplifier, and a
boundary mode detector, as well as the additional logic for
boundary conduction mode, discontinuous conduction
mode, and low ripple Burst Mode operation.
Boundary Conduction Mode Operation
The LT8300 features boundary conduction mode opera-
tion at heavy load, where the chip turns on the primary
power switch when the secondary current is zero.
Boundary conduction mode is a variable frequency, vari-
able peak-current switching scheme. The power switch
turns on and the transformer primary current increases
until an internally controlled peak current limit. After the
power switch turns off, the voltage on the SW pin rises to
the output voltage multiplied by the primary-to-secondary
transformer turns ratio plus the input voltage. When the
secondary current through the output diode falls to zero,
the SW pin voltage collapses and rings around VIN. A
boundary mode detector senses this event and turns the
power switch back on.
Boundary conduction mode returns the secondary current
to zero every cycle, so parasitic resistive voltage drops
do not cause load regulation errors. Boundary conduc-
tion mode also allows the use of smaller transformers
compared to continuous conduction mode and does not
exhibit subharmonic oscillation.
Discontinuous Conduction Mode Operation
As the load gets lighter, boundary conduction mode
increases the switching frequency and decreases the
switch peak current at the same ratio. Running at a higher
switching frequency up to several MHz increases switch-
ing and gate charge losses. To avoid this scenario, the
LT8300 has an additional internal oscillator, which clamps
the maximum switching frequency to be less than 750kHz.
Once the switching frequency hits the internal frequency
clamp, the part starts to delay the switch turn-on and
operates in discontinuous conduction mode.
Low Ripple Burst Mode Operation
Unlike traditional flyback converters, the LT8300 has to
turn on and off at least for a minimum amount of time
and with a minimum frequency to allow accurate sampling
of the output voltage. The inherent minimum switch cur-
rent limit and minimum switch-off time are necessary to
guarantee the correct operation of specific applications.
As the load gets very light, the LT8300 starts to fold
back the switching frequency while keeping the mini-
mum switch current limit. So the load current is able to
decrease while still allowing minimum switch-off time for
the sample-and-hold error amplifier. Meanwhile, the part
switches between sleep mode and active mode, thereby
Rev. A
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