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Note ● For information about switching modules that support PoE, see the Release Notes for Cisco IOS Release 15.2SY publication at this URL:
http://www.cisco.com/en/US/docs/switches/lan/catalyst6500/ios/15.1SY/release_notes.html
http://www.cisco.com/en/US/products/ps11846/prod_command_reference_list.html
http://www.cisco.com/en/US/products/hw/switches/ps708/tsd_products_support_series_home.html
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Note Not all PoE-capable devices are powered from the switch. There are two sources of local power for PoE-capable devices:
When a locally powered PoE-capable device is present on a switching module port, the switching module itself cannot detect its presence. If the device supports CDP, the supervisor engine can discover a locally powered PoE-capable device through CDP messaging with the device. If a locally powered PoE-capable device loses local power, the switching module can discover and supply power to the IP phone if the inline power mode is set to auto.
Cisco PoE daughtercards support one or more PoE implementation:
– Supported only with the PoE daughtercard on the WS-X6148E-GE-45AT switching module.
– These features are supported for IEEE 802.3at-compliant class 4 PDs:
• Class 4: 30.00 W at the PSE (12.95 W to 25.50 W at the PD).
• Optionally, LLDP Inline Power Negotiation for PoE+.
– With releases earlier than Release 15.1(1)SY, maximum 16.8 W at the PSE (ePoE for 45 ports maximum).
– Supported with the WS-F6K-48-AF PoE daughtercard and the PoE daughtercard on the WS-X6148E-GE-45AT switching module.
– The IEEE 802.3af PoE standard defines a method to sense a PD and to immediately classify the power requirement of the PD into these per port power ranges at the PSE:
• Class 0: Up to 15.4 W (0.44–12.95 W at the PD; default classification)
• Class 1: Up to 4 W (0.44–3.84 W at the PD)
• Class 2: Up to 7 W (3.84–6.49 W at the PD)
• Class 3: Up to 15.4 W (6.49–12.95 W at the PD)
With a PoE daughtercard installed, a switching module can automatically detect and provision a PoE-capable device that adheres to a PoE implementation supported by the PoE daughtercard. The switching module can supply power to devices supporting other PoE implementations only through manual configuration.
Only a PD connected directly to the switch port can be powered from the switch. If a second PD is daisy-chained from the PD that is connected to the switch port, the second PD cannot be powered by the switch.
Each PD requires power to be allocated from the chassis power budget. Because each PD can have unique power requirements, more devices can be supported if the system’s power management software can intelligently allocate the necessary power on a per-port basis.
You can configure ports to allocate power at a level based on the following:
When a switching module port detects an unpowered PD, the default-allocated power is provided to the port. When the correct amount of power is determined through CDP messaging with the PD, the supervisor engine reduces or increases the allocated power, up to the hardware limit of the installed PoE daughtercard.
The IEEE 802.3af standard contains no provision for adjustment of the power allocation. 802.3af-compliant PDs that support CDP can use CDP to override the IEEE 802.3af power classification.
The WS-F6K-48-AF PoE daughtercard or the PoE daughtercard on the WS-X6148E-GE-45AT switching module support these inline power IEEE 802.3af power classification override features:
With power measurement and policing, you can safely override the IEEE 802.3af power classification of a device that requires a power level at the lower end of its IEEE power classification range.
PoE monitoring and policing compares the power consumption on ports with the administrative maximum value (either a configured maximum value or the port’s default value). If the power consumption on a monitored port exceeds the administrative maximum value, the following actions occur:
The PoE daughtercard on the WS-X6148E-GE-45AT switching module supports IEEE 802.3at -compliant LLDP PoE power negotiation, which supports additional negotiation that can reduce power usage.
http://www.cisco.com/en/US/docs/ios/cether/configuration/guide/ce_lldp-med.html
This example shows how to display the PoE status on switch:
To configure per-port PoE support, perform this task:
When configuring inline power support with the power inline command, note the following information:
– The configurable range of maximum power using the max keyword is 4000 to 16800 milliwatts. If no maximum power level is configured, the default maximum power is 15400 milliwatts.
Note To support a large number of inline-powered ports using power levels above 15400 milliwatts on an inline power card, we recommend using the static keyword so that the power budget is deterministic.
– When the auto keyword is entered and CDP is enabled on the port, an inline-powered device that supports CDP can negotiate a power level up to 16800 milliwatts unless a lower maximum power level is configured.
This example shows how to disable inline power on GigabitEthernet port 2/10:
This example shows how to enable inline power on GigabitEthernet port 2/10:
This example shows how to verify the inline power configuration on GigabitEthernet port 2/10:
You can configure how the switch responds if a power shortage occurs by setting the priority of ports providing PoE. The priority determines the order in which PoE is removed from ports if a power shortage occurs: low-priority, then high-priority, with power maintained for critical-priority ports as long as possible. These sections describe how to configure PoE power priority:
To disable PoE power priority globally, perform this task:
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This example shows how to disable PoE power priority globally:
The column heading of any show power inline command displays the PoE power priority global state (“disabled” in this example):
To configure PoE port power priority, perform this task:
This example shows how to configure the PoE port power priority of GigabitEthernet port 2/10 as high:
This example shows how to verify the PoE port power priority configuration of GigabitEthernet port 2/10:
With the WS-F6K-48-AF PoE daughtercard or the PoE daughtercard on the WS-X6148E-GE-45AT switching module, to configure PoE monitoring and policing, perform this task:
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Router# show power inline { type slot/port | module slot }[ detail ] |
This example shows how to enable monitoring and policing on GigabitEthernet port 1/9:
These examples shows how to verify the power monitoring and policing configuration on GigabitEthernet port 2/10:
With the WS-X6148E-GE-45AT switching module, LLDP power negotiation is enabled by default. To disable LLDP power negotiation, perform this task:
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This example shows how to display the LLDP power negotiation configuration on interface GigabitEthernet 3/1 when LLDP power negotiation is enabled:
This example shows how to disable LLDP power negotiation on interface GigabitEthernet 2/10:
http://www.cisco.com/en/US/products/hw/switches/ps708/tsd_products_support_series_home.html
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