LTC4267-3
27
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applicaTions inForMaTion
from the PSE while the transformer will sit unused. This
configuration is not a problem in a PoE system. On the
other hand, if the wall transformer voltage is higher than
the PSE voltage, the LTC4267-3 switching regulator will
draw power from the transformer. In this situation, it is
necessary to address the issue of power cycling that may
occur if a PSE is present. The PSE will detect the PD and
apply power. If the switcher is being powered by the wall
transformer, then the PD will not meet the minimum load
requirement and the PSE will subsequently remove power.
The PSE will again detect the PD and power cycling will
start. With a transformer voltage above the PSE voltage,
it is necessary to either disable the signature, as shown
in option 2, or install a minimum load on the output of the
LTC4267-3 interface to prevent power cycling.
The third option also applies power directly to the
LTC4267-3 switching regulator, bypassing the LTC4267-3
interface controller and omitting diode D9. With the
diode omitted, the transformer voltage is applied to the
LTC4267-3 interface controller in addition to the switching
regulator. For this reason, it is necessary to ensure that
the transformer maintain the voltage between 38V and 57V
to keep the LTC4267-3 interface controller in its normal
operating range. The third option has the advantage of
automatically disabling the 25k signature resistor when
the external voltage exceeds the PSE voltage.
Power-Up Sequencing the LTC4267-3
The LTC4267-3 consists of two functional cells, the PD
interface and the switching regulator, and the power up
sequencing of these two cells must be carefully considered.
The PD designer should ensure that the switching regulator
does not begin operation until the interface has completed
charging up the load capacitor. This will ensure that the
switcher load current does not compete with the load
capacitor charging current provided by the PD interface
current limit circuit. Overlooking this consideration may
result in slow power supply ramp up, power-up oscillation,
and possibly thermal shutdown.
The LTC4267-3 includes a power good signal in the PD
interface that can be used to indicate to the switching regu
-
lator that the load capacitor is fully charged and ready to
handle the switcher load
.
Figure 7 shows two examples of
ways the PWRGD signal can be used to control the switch
-
ing regulator. The first example employs an N-channel
MOSFET to drive the I
TH
/RUN port below the shutdown
threshold (typically 0.28V). The second example drives
P
VCC
below the P
VCC
turn-off threshold. Employing the
second example has the added advantage of adding delay
to the switching regulator start-up beyond the time the
power good signal becomes active. The second example
ensures additional timing margin at start-up without the
need for added delay components. In applications where it
is not desirable to utilize the power good signal, sufficient
timing margin can be achieved with R
START
and C
PVCC
.
R
START
and C
PVCC
should be set to a delay of two to three
times longer than the duration needed to charge up C1.
Layout Considerations for the LTC4267-3
The most critical layout considerations for the LTC4267-3
are the placement of the supporting external components
associated with the switching regulator. Efficiency, stabil
-
ity, and load transient response can deteriorate without
good layout practices around critical components.
For the
LTC4267-3 switching regulator, the current loop
through C1, T1 primary, Q1, and R
SENSE
must be given
careful layout attention. (Refer to Figure 11.) Because of
the high switching current circulating in this loop, these
components should be placed in close proximity to each
other. In addition, wide copper traces or copper planes
should be used between these components. If vias are
necessary to complete the connectivity of this loop, placing
multiple vias lined perpendicular to the flow of current is
essential for minimizing parasitic resistance and reducing
current density. Since the switching frequency and the
power levels are substantial, shielding and high frequency
layout techniques should be employed. A low current,