Stack-power mode is
used only on Catalyst switches in a power stack. With no XPS, a power stack
operates in ring topology with a maximum of four switches in the stack. When an
XPS is in the power stack, you can connect up to nine switches in the stack
plus the XPS, providing power budgets to power stack members similar to
stack-power ring topology operation.
All Catalyst switches
connected to an XPS on SP ports are part of the same power stack, and all power
from the XPS and the switches is shared across all switches in the stack. Power
sharing is the default mode, but the XPS supports the same stack power modes
that are supported in a ring topology (strict and nonstrict power-sharing or
redundant modes).
The XPS uses neighbor
discovery to create the power stack. When it discovers a Catalyst switch on an
unconfigured port, it marks the port as an SP port, and the switch joins the
power stack. The XPS notifies the switch, begins the power-budgeting process,
and assigns budgets to each switch in the power stack based on their
requirements, priorities, current power allocations, and the stack aggregate
power capability.
The XPS sends the
power budget to each switch. If not enough input power is available to provide
every switch with its maximum requested power, power is distributed based on
priority. Switches with the highest priority receive required power first,
followed by any powered devices that have already been allocated power, in
order of their priority. Any remaining power is distributed equally through the
stack.
The RPS port priority
(1 through 9) does not affect stack power priority. Each switch participating
in stack power has its own system priority and a high and low priority for
devices connected to its ports. These priorities are used for stack power, as
is the case in a ring topology. You configure stack power priority for the
system and for high and low-priority ports by using the
power-priority
switch ,
power-priority
high , and
power-priority
low commands in switch stack power configuration mode. If a
system or set of powered devices are using the default priority, the XPS
automatically assigns a priority (1 through 27), with lower MAC addresses
receiving higher priorities.
There are four power
stack modes: power sharing, strict power sharing, redundant, or strict
redundant. You configure the power stack mode by using the
mode {power-sharing |
redundant}
[strict]
command in power-stack configuration mode. The
power-sharing
or
redundant
configurations affect the power budgeting aspect of the stack;
strict or
non-strict affects the actions of the PoE application when a budget reduction
does not result in load shedding.
-
In power sharing
modes (strict or nonstrict), the stack power budget is the cumulative capacity
of all the power supplies in the stack (minus 30 W reserved power). This is the
default.
-
In redundant modes
(strict or nonstrict), the stack power budget is the total available power
(minus 30 W) after the capacity of the largest power supply in the power stack
is subtracted. Redundant mode guarantees that no switch or powered device loses
power or experiences load sheds if a single power supply fails, but load sheds
can occur if more than one power supply fails.
-
In strict modes,
if a loss of input power results in reduced power budgets but does not result
in any hardware load shedding, the XPS automatically begins denying power to
low-priority powered devices and then the high-priority powered devices until
the amount of allocated power is less than or equal to the amount of available
PoE power.
-
In nonstrict
modes, in the event of a power reduction, the amount of allocated power is
allowed to fall under budget.
For example, a system
with a total PoE budget (available power) of 400 W can allocate 390 W of the
budget (allocated power) to powered devices. The allocated power of a device is
the maximum amount of power that the device needs. The actual power consumption
(consumed power) for a set of powered devices is usually not equal to the
allocated power. In this example, the actual power might be approximately 200
W. If a power loss in the stack reduces the available power to 210 W, this
amount is enough to sustain the power being consumed by the powered devices,
but less than the worst-case allocated power, which would put the system
under budget. In
strict mode, the stack would immediately deny power to powered devices until
the allocated power was 210 W or less. In nonstrict mode, no action is taken,
and the state is allowed to persist. In nonstrict mode if the actual power
consumption becomes more than 210 W, this triggers a load shed and can result
in the loss of power to all powered devices or switches with the lowest
priority level.