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
Current sensing, OCP and OLP
L6699
24/38
Doc ID 022835 Rev 2
8
Current sensing, OCP and OLP
In the L6699 the current sense input ISEN (pin 6) senses the current flowing in the resonant
tank to perform multiple tasks:
tank to perform multiple tasks:
1.
Primary overcurrent protection (OCP function).
2.
).
3.
Capacitive-mode detection during operation (see
).
In this section the discussion is concentrated on the OCP function.
Unlike PWM-controlled converters, where energy flow is controlled by the duty cycle of the
primary switch (or switches), in a resonant half bridge the duty cycle is fixed and energy flow
is controlled by its switching frequency. This has an impact on the way current limitation can
be realized. While in PWM-controlled converters energy flow can be limited simply by
terminating switch conduction in advance when the sensed current exceeds a preset
threshold (cycle-by-cycle limitation), in a resonant half bridge the most efficient way to
reduce an excessive current level is to increase the switching frequency, i.e. the oscillator
frequency.
primary switch (or switches), in a resonant half bridge the duty cycle is fixed and energy flow
is controlled by its switching frequency. This has an impact on the way current limitation can
be realized. While in PWM-controlled converters energy flow can be limited simply by
terminating switch conduction in advance when the sensed current exceeds a preset
threshold (cycle-by-cycle limitation), in a resonant half bridge the most efficient way to
reduce an excessive current level is to increase the switching frequency, i.e. the oscillator
frequency.
a couple of current sensing methods are illustrated.
Note:
The L6699 must sense the instantaneous tank current for proper operation of the smooth
startup function and the capacitive-mode detection circuit. Therefore, if a smoothing RC
circuit (the one shown in the dashed box) is used to reduce the noise level on the ISEN pin,
its time constant RF CF should be in the range of 100 - 200 ns. With slightly longer time
constants it is recommended that converter operation close to the capacitive-mode
boundary and during short-circuit, as well as at the end of the smooth-start phase, be
checked for possible hard-switching cycles. With considerably longer time constants (> 200
ns) hard-switching under the above mentioned conditions becomes very likely.
startup function and the capacitive-mode detection circuit. Therefore, if a smoothing RC
circuit (the one shown in the dashed box) is used to reduce the noise level on the ISEN pin,
its time constant RF CF should be in the range of 100 - 200 ns. With slightly longer time
constants it is recommended that converter operation close to the capacitive-mode
boundary and during short-circuit, as well as at the end of the smooth-start phase, be
checked for possible hard-switching cycles. With considerably longer time constants (> 200
ns) hard-switching under the above mentioned conditions becomes very likely.
Figure 18.
Current sensing techniques
with sense resistor
with sense resistor
Figure 19.
Current sensing techniques
“lossless”, with capacitive
shunt
“lossless”, with capacitive
shunt
!-V
,
#R
2S
)
#R
/PTIONAL
2
&
#
&
!-V
,
#R
#S
)
#R
2S
/PTIONAL
2
&
#
&