two paths, while preserving redundancy?
Refer to the exhibit.
The customer network has blue and red VSANs redundantly connected. Path A having a 4-ISL
port channel and Path B having a 2-ISL port channel. Changes to the physical topology are not
allowed for the next six months. All the traffic now flows over Path A with congestion occurring on
both VSANs at peak times. The blue VSAN is, on the average, generating four times the amount
of data than that of the red VSAN. How can the blue and red VSAN traffic be separated over the
two paths, while preserving redundancy?
Exhibit:
What alarm will be sent for this RMON event?
Refer to the exhibit.
What alarm will be sent for this RMON event?
Exhibit:
Why is there no connectivity?
You have connected your Cisco MDS 9508 Switch to an existing McData SAN fabric using VSAN
100 You have changed the sWWN using McData OUI, deployed static DomainID 10, and
changed the VSAN 10 interoperability mode to 4. The Cisco MDS is having a connectivity problem
with the McData-based fabric. Why is there no connectivity?
using interoperability mode 4?
What must be changed when connecting the Cisco MDS Switch to an existing McData switch
using interoperability mode 4?
which statement is true?
With regards to FCIP encapsulation, which statement is true?
which of the following?
When configuring FCIP, packet fragmentation should be avoided in order to achieve optimal
throughput. Fragmentation can be avoided by knowing which of the following?
Which two of these environments suggest the use of FCIP Write Acceleration?
Which two of these environments suggest the use of FCIP Write Acceleration? (Choose two.)
Which option should you deploy to prevent man-in-the-middle attacks?
Refer to the exhibit.
Which option should you deploy to prevent man-in-the-middle attacks?
Exhibit:
using interoperability mode 4?
What must be changed when connecting the Cisco MDS Switch to an existing McData switch
using interoperability mode 4?
two paths, while preserving redundancy?
Refer to the exhibit.
The customer network has blue and red VSANs redundantly connected. Path A having a 4-ISL
port channel and Path B having a 2-ISL port channel. Changes to the physical topology are not
allowed for the next six months. All the traffic now flows over Path A with congestion occurring on
both VSANs at peak times. The blue VSAN is, on the average, generating four times the amount
of data than that of the red VSAN. How can the blue and red VSAN traffic be separated over the
two paths, while preserving redundancy?
Exhibit: