STMicroelectronics 19V - 90W Adapter with PFC for Laptop computers using the L6563H and L6699 EVL6699-90WADP EVL6699-90WADP Ficha De Dados
Códigos do produto
EVL6699-90WADP
Application information
L6699
12/38
Doc ID 022835 Rev 2
6 Application
information
The L6699 is an advanced double-ended controller specific to resonant half bridge topology.
In these converters the MOSFETs of the half bridge leg are alternately switched on and off
(180° out-of-phase) for exactly the same time. This is commonly referred to as symmetrical
operation at “50% duty cycle”, although the real duty cycle, i.e. the ratio of the ON-time of
either switch to the switching period, is actually less than 50%. The reason is that there is a
deadtime T
In these converters the MOSFETs of the half bridge leg are alternately switched on and off
(180° out-of-phase) for exactly the same time. This is commonly referred to as symmetrical
operation at “50% duty cycle”, although the real duty cycle, i.e. the ratio of the ON-time of
either switch to the switching period, is actually less than 50%. The reason is that there is a
deadtime T
D
inserted between the turn-off of either MOSFET and the turn-on of the other
one, where both MOSFETs are off. This deadtime is essential in order for the converter to
work correctly: it enables soft-switching and, then, high-frequency operation with high
efficiency and low EMI emissions.
work correctly: it enables soft-switching and, then, high-frequency operation with high
efficiency and low EMI emissions.
A special feature of this IC is that it is able to automatically adjust T
D
within a range so that it
best fits the transition times of the half bridge midpoint (adaptive deadtime). This allows the
user to optimize the design of the resonant tank so that soft-switching can be achieved with
a lower level of reactive energy (i.e. magnetizing current), therefore optimizing efficiency
under a broader load range, from full to light load.
user to optimize the design of the resonant tank so that soft-switching can be achieved with
a lower level of reactive energy (i.e. magnetizing current), therefore optimizing efficiency
under a broader load range, from full to light load.
To perform converter output voltage regulation the device is able to operate in different
modes (
modes (
), depending on the load conditions:
1.
Variable frequency at heavy and medium/light load. A relaxation oscillator (see
for more details) generates a symmetrical triangular waveform,
which MOSFET switching is locked to. The frequency of this waveform is related to a
current that is modulated by the feedback circuitry. As a result, the tank circuit driven by
the half bridge is stimulated at a frequency dictated by the feedback loop to keep the
output voltage regulated, therefore exploiting its frequency-dependent transfer
characteristics.
current that is modulated by the feedback circuitry. As a result, the tank circuit driven by
the half bridge is stimulated at a frequency dictated by the feedback loop to keep the
output voltage regulated, therefore exploiting its frequency-dependent transfer
characteristics.
2.
Burst-mode control with no or very light load. When the load falls below a value, the
converter enters a controlled intermittent operation, where a series of a few switching
cycles at a nearly fixed frequency are spaced out by long idle periods where both
MOSFETs are in the OFF-state. A further load decrease is translated into longer idle
periods and then in a reduction of the average switching frequency. When the converter
is completely unloaded, the average switching frequency can go down even to few
hundred hertz, therefore minimizing magnetizing current losses as well as all
frequency-related losses and making it easier to comply with energy saving
specifications.
converter enters a controlled intermittent operation, where a series of a few switching
cycles at a nearly fixed frequency are spaced out by long idle periods where both
MOSFETs are in the OFF-state. A further load decrease is translated into longer idle
periods and then in a reduction of the average switching frequency. When the converter
is completely unloaded, the average switching frequency can go down even to few
hundred hertz, therefore minimizing magnetizing current losses as well as all
frequency-related losses and making it easier to comply with energy saving
specifications.
Figure 4.
Multimode operation of the L6699
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