Power Management

Power management controls power up/down of the modules in the GigaVUE‑HC3 node through software. It determines the priority of the modules to power up or down based on the total PSMs present.

All four of the slots on the GigaVUE‑HC3 are assigned a power priority. Slot 1 defaults to the highest priority of 1. Slot 2 defaults to a priority of 2. Slot 3 defaults to a priority of 3. Slot 4 defaults to the lowest priority of 4.

A GigaVUE‑HC3 chassis can have up to four PSMs. The power supply modules can be either AC or DC. Two or four PSMs are recommended for 1+1 redundancy (two PSMs) or 2+2 redundancy (four PSMs). A mix of AC and DC power supply modules is not recommended.

When all PSMs are plugged in and are up (LED status light is green), their power is pooled and used to calculate the available power. Available power is the total power available to power up the modules in the GigaVUE‑HC3. The modules present and configured in the chassis are used to calculate needed power. The modules are powered up based on the available power. If the needed power is more than the available power, only the modules in the higher priority slots are powered up.

For example, when the available power falls below the needed power due to a PSM failing or being unplugged or removed, the module in the lowest priority slot is powered down first. When additional power is added, power management powers up the modules present in the higher priority slots before it powers up the modules in the lower priority slots.

When a module is powered down by power management, the operational status of the module is shown as nopower in the output of the show cards command, which indicates that it was powered down by power management.

Note:  Power management does not control power up/down of the control card.

Defining Power Attributes

The following attributes for power computation are defined as follows:

■   Total power—the total power available in the system, based on the PSMs
■   Base power—the power needed for the control card and base system
■   Power allocated—the power allocated to the modules by power management
■   Power available—the power remaining and available after power has been allocated
■   Power redundant—the status of yes/no of whether or not the system currently has redundant power
■   Total redundant power—the total redundant power in the system

Calculating Available Power

Every PSM has maximum rated Watts. Table 1: Input Voltage and Maximum Watts lists the PSMs with their input voltage and maximum rated Watts. The maximum Watts is the available power for each AC or DC power supply module.

Table 1: Input Voltage and Maximum Watts

Power Supply Module

AC/DC Input Voltage

Maximum Watts per PSM

DC PSM -48V

40V-72V

1500W

AC PSM 110V

100V-200B

1100W

AC PSM 208V

200V-240V

1500W

For a PSM to be included in available power, the PSM must be plugged in and have a status of on. Power management adds the eligible rated Watts to the available power and subtracts any removed, failed, or no input voltage power supply module from the available power.

Table 2: Total Available Power with Three PSMs shows the calculation for total available power, where there are three PSMs and one empty slot.

Table 2: Total Available Power with Three PSMs

PSM

Slot

Power (Watts)

Status

AC PSM 110V

1

1100W

on

AC PSM 208V

2

1500W

on

 

3

 

Empty

AC PSM 208V

4

1500W

on

Total Available Power

 

4100W

 

Table 3: Total Available Power with Four PSMs shows the calculation for the total available power, where a PSM is present in all slots.

Table 3: Total Available Power with Four PSMs

PSM

Slot

Power (Watts)

Status

AC PSM 110V

1

1100W

on

AC PSM 208V

2

1500W

on

AS PSM 110V

3

1100W

on

AC PSM 208V

4

1500W

on

Total Available Power

 

5200W

 

Calculating Needed Power

Every module for the GigaVUE‑HC3 has a rated maximum Watts. The maximum Watts of each module is used to calculate the total needed power. Table 4: Needed Power Per Module lists the maximum power for each module, which you can use to calculate the maximum needed power.

Table 4: Needed Power Per Module

Module

Maximum Power (Watts)

Base Chassis Hardware with CCv1

820W

Base Chassis Hardware with CCv2

940W

PRT-HC3-C08Q08

160W

PRT-HC3-X24

60W

SMT-HC3-C05

200W

BPS-HC3-C25F2G

60W

BPS-HC3-C35C2G

60W

BPS-HC3-Q35C2G

60W

PRT-HC3-C16

130W

A minimum of one PSM powers the base chassis hardware, including the main board, the extension board, and the fan modules. All the present modules that are not yet powered up are calculated as needed power.

When a module is shutdown or removed from the system, it is not immediately subtracted from the needed power. To subtract the module from the needed power, unconfigure the module from the slot using the no card <slot ID> command.

If the module is shutdown and removed without unconfiguring, the needed power will not be subtracted.

If there is a power failure or if a PSM is removed when there is insufficient power, the module will be powered down.

Calculating Redundant Power

The power redundancy of the system is calculated based on the number of PSMs currently available that are in an up and running state.

The GigaVUE‑HC3 has a total of four PSMs. A system is declared power redundant if there are a minimum of two PSMs in an up and running state and if the power from one of the PSMs can keep the current system fully up.

If two PSMs are up and running, a system is declared power redundant if the required power of the modules and the base power can be addressed by one of the PSMs.

In summary, redundant power is calculated based on the total power needed by the modules and the PSMs available in the system and their capacity.

While a single PSM can power the entire chassis, the GigaVUE‑HC3 can be configured with up to four PSMs for power redundancy. To be considered redundant power, there must be more than one PSM. Two PSMs can provide 1+1 power redundancy. Four PSMs can provide 2+2 power redundancy.

Power management scans all four power slots and stores the lowest rated Watts by product code and input voltage. The lowest rated Watts for each group of two PSMs is used to determine the redundant power pool. To be determined for the redundant power pool, the PSM must be present and have a status of on.

Table 5: Total Redundant Power with Three PSMs shows the total redundant power with three eligible PSMs, where there is one group of two PSMs for 1+1 redundancy and a single third PSM. The lowest rated module is 1100W in slot 1. Therefore, the total redundant power is 1100W.

Table 5: Total Redundant Power with Three PSMs

PSM

Slot

Power (Watts)

Status

AC PSM 110V

1

1100W

on

AC PSM 208V

2

1500W

on

 

3

 

Empty

AC PSM 208V

4

1500W

on

Total Redundant Power

 

1100W

 

Table 6: Total Redundant Power with Four PSMs shows the total redundant power with four eligible PSMs, where there are two groups of two PSMs for 2+2 redundancy. The lowest rated module is 1100W, one in slot 1 and one in slot 3. Therefore, the total redundant power is 2200W.

Table 6: Total Redundant Power with Four PSMs

PSM

Slot

Power (Watts)

Status

AC PSM 110V

1

1100W

on

AC PSM 208V

2

1500W

on

AS PSM 110V

3

1100W

on

AC PSM 208V

4

1500W

on

Total Redundant Power

 

2200W

 

Displaying Power and Voltage Information

The output of the following CLI command displays power information on a GigaVUE‑HC3:

(config) show environment type psu
*** Box 1 (GVS-HC300) ***
-----------------------------------------------------------
 Power Module 1 (PSM-HC3-001):
 Product Code                   132-00DU
 Serial Num                     1DU0-0001
 HW Rev                         1.0
 Status                         on output=1500W
 Capacity                       1500W
-----------------------------------------------------------
 Power Module 2 (PSM-HC3-001):
 Product Code                   132-00DU
 Serial Num                     1DU0-0002
 HW Rev                         1.0
 Status                         on output=1500W
 Capacity                       1500W
===========================================================
Total Power: 3000W
Total Base Power: 820W
Power Allocated: 220W
Power Available: 1960W
Power Redundant: Yes
Total Redundant power: 1500W

The output of the following CLI command displays voltage information on a GigaVUE‑HC3 CCv1:

(config) show environment type voltage
*** Box 1 (GVS-HC300) ***
-----------------------------------------------------------
 Card cc1 (CTL-HC3-001):
 12v voltage :                  12.402V
-----------------------------------------------------------
 Card 1 (PRT-HC3-C08Q08):
 12v voltage :                  12.402V
-----------------------------------------------------------
 Card 2 (BPS-HC3-C25F2G):
 12v voltage :                  12.342V
-----------------------------------------------------------
 Card 3 (SMT-HC3-C05):
 12v voltage :                  12.342V
-----------------------------------------------------------
 Card 4 (PRT-HC3-X24):
 12v voltage :                  12.342V
===========================================================

The output of the following CLI command displays voltage information on a GigaVUE‑HC3 CCv2:

(config) show environment type voltage
*** Box 2 (GVS-HC300) ***
-----------------------------------------------------------
 Card cc1 (CTL-HC3-002):
 12v voltage :                  12.281V
-----------------------------------------------------------
 Card 1 (PRT-HC3-C16):
 12v voltage :                  12.160V
-----------------------------------------------------------
 Card 2 (PRT-HC3-C08Q08):
 12v voltage :                  12.281V
-----------------------------------------------------------
 Card 4 (BPS-HC3-C25F2G):
 12v voltage :                  12.281V
===========================================================

The output of the following CLI command displays power requirement and priority information on a GigaVUE‑HC3 CCv1:

(config) show card

 

The output of the following CLI command displays power requirement and priority information on a GigaVUE‑HC3 CCv2:

(config) show card