Software-defined networking and network virtualization deliver a completely new operational model that breaks through current physical legacy network barriers, allowing you to evolve to an on-demand IT infrastructure. Join us to see how HPE offers the industry’s broadest portfolio of network virtualization solutions supporting HPE Helion OpenStack; VMware NSX® and NFV use cases, to help transition to an open, standards-based, software-defined infrastructure.

1. #ATM16
The new imperative in the data
center with workload-centric
networking
Simon Huang
Data Center TME manager
HP Enterprise
March 2016 @ArubaNetworks |

2. 2#ATM16
Agenda
Transformation with Hybrid IT
Data Center Fabric Technologies
Network Design Examples
Fulfill Cloud First Architecture with Data Center portfolio
2

3. 3#ATM16
Transformation with Hybrid IT

4. 4#ATM16
Helping customers transform to a hybrid infrastructure
Improve the user experience with accelerated the delivery of apps & services
• Increase availability to gracefully support
business growth and unpredictable
• Reduce time to service to enhance
business agility
• Enhance customer choice for freedom to
build networks that suite business
requirements
• Lower total cost of ownership to gain
competitive edge in the market
Transform
to a hybrid
infrastructure
Enable
workplace
productivity
Protect
your digital
enterprise
Empower
the data-driven
organization

5. 5#ATM16
Open Standards Open APIs Open Ecosystem Open Source
Committed to Open Networking in the Data Center
Altoline (OpenSwitch)
FlexFabric (Comware)

6. 6#ATM16
Use Gartner Data Center MQ as sales tactic
Gartner rates HPE as most OPEN
network vendor
“Organizations should consider HPE for any data center network
solution, especially those looking for open and standards-based
solutions.”
2015 Data Center Networking MQ

7. 7#ATM16
HPE Cloud First
Data Center Fabric Technologies
7

8. 8#ATM16
Types of Fabrics
Layer 2 or Layer 3 and more
 Layer 2
 STP and STP variants
 TRILL / SPB
 Proprietary protocols (IRF,
Fabricpath, VCS, MLAG)
 VXLAN (something in between)
 Layer 3
 OSPF / BGP
 Better scalability
 Predictable path
 Easy to troubleshoot

9. 9#ATM16
STP Variants
– STP
– rPVST+, RSTP, MSTP
– Load-share across the available links on a per VLAN basis
– Root Bridge (RB) election - Who remembers this?
– Lowest bridge ID (priority)
– If bridge IDs are all the same lowest MAC address
– HPE Comware devices reverse this (highest priority is elected RB)
– In PVST the lowest priority will become the root bridge for a VLAN

10. 10#ATM16
HPE Cloud First
Network Design Examples
10

11. 11#ATM16
Example 1: Traditional IRF L2 Fabric
• Centralized IRF L2/L3 core switches
• IRF L2 access switches
• Loop free L2 fabric
• STP should still be enabled to prevent any
possible loops in future
Bare Metal Servers
L2 Access Switches
IRF L2/L3 Core Switches
40G Link aggregation &
802.1Q trunks
WAN /
Internet
L2 External Zone IRF Switches
Load Balancers
Firewalls
WAN Routers
L2 Fabric

12. 13#ATM16
Example 2: L2 Fabric with control plane (SPB/TRILL)
• SPB/TRILL removes STP while still providing a loop free L2 network for east/west traffic
• Distributed control plane (No single point of failure)
• Architecture Neutral (leaf to leaf or spine leaf)
• Lack of control plane interoperability
L3 Gateway
Layer Routers
Servers/VMs
10/40G
interconnects L2 TRILL / SPB Fabric

13. 14#ATM16
What is a fabric?
– Interconnected network nodes that look like a “fabric” when viewed collectively from a distance
– Spine leaf/ CLOS /Two-Tier /Ethernet Fabric /Network Fabric are interchangeable and commonly used
terms
– For most it’s a scalable, high performing, resilient network architecture.

14. 15#ATM16
Example 3: CLOS Fabric
• CLOS (physical) network architecture provide edge/core multi-tier design
• Each leaf switch is connected to all spine switches
• Customers may choose to deploy a 2 spine fabric (2 x 40G uplinks) and expand to 4+ spines (4 x 40G uplinks
or more) when they require additional bandwidth
• Protocol independent (STP/TRILL/SPB/L3) over the physical fabric
Leaf
Switches
Spine
Switches
4 Spine CLOS Fabric2 Spine CLOS Fabric
Spine
Switches
Leaf
Switches

15. 16#ATM16
Example 4: L3 Fabric
• Removal of STP
• Usage of standards based routing protocol
• Shortest path routing
• Provides Equal Cost Multi Pathing (ECMP)
• Traffic engineering
Servers/VMs
Default gateway for
each subnet terminates
at access switch
Multiple /30 L3
subnets
L2
Routing
protocol
L3 EMCP routes
10/40G
interconnects

16. 17#ATM16
Example 5: Network Virtualization Enabled Fabric
• Network Virtualization enabled fabric provides virtual to physical networking bridging capabilities
• Underlay network fabric can be deployed either as L2 / L3
• Most devices do not need to be VXLAN Tunnel End Points (VTEP) or VXLAN capable (e.g. SPINEs
only need to route traffic between VTEPs)
• L3 fabric recommended if network virtualization software supports different subnets between VTEPs
• Hardware VTEPs used to bridge between virtual and physical networks
Software VTEPPhysical Servers, WAN Routers/ Firewalls
172.16.2.10/24
VM2: 172.16.2.2/24
HPE
Hardware
VTEPs
Network Virtualization
Controller
OVSDB /
NETCONF

17. 18#ATM16
Example 6: L2 over L3 VXLAN overlay Fabric
• Loop free L2 fabric without
STP or network virtualization
controllers
• VXLAN overlay tunnels
provides link load sharing
across the physical fabric
• High performance multicast
forwarding in the underlay
(compared to multicast
forwarding using the overlay)
Servers/VMs
Leaf/EoR Layer
(L2 VTEPs)
Spine/Core Layer
(L2 VTEPs)
L2 Fabric
Access/ToR Layer
L3 Gateway
Layer
POD 1 POD 2 POD 3 POD 4 POD …
Overlay VXLAN
tunnels
Underlay L3
Network

18. 19#ATM16
Example 7: Multiple Fabrics
• Network fabrics can be deployed as different availability zones to limit failure domains
• L2 network connectivity between VMs/Servers are provided within an availability zone
• L3 used between different availability zones
• Border leaf switches used to connect out of an availability zone
Border Leaf
IGP: OSPF
EGP: BGP AS#65001
IGP: OSPF
EGP: BGP AS#65002
Availability Zone#1
(10.1.0.0/16)
Availability Zone#2
(10.2.0.0/16)
Core Network: BGP AS#65100
Border Leaf
Example with multiple availability zones
L3 L3

19. 20#ATM16
Example 8: Inter Data Center Fabric Connectivity
• VXLAN and HPE EVI technologies can be combined for active/active inter-DC L2 DCI over L3 WAN
• EVI provides additional benefits such as:
− Active/Active VRRP default gateways for VMs
− STP failure domain local to each DC
− Improves WAN utilization by dropping unknown frames and providing ARP suppression
− Optimized Server/Client Traffic Paths
• VXLAN based DCI must avoid full networking “interconnect”
Virtual Overlay VXLAN tunnels
Physical Underlay Network
Active Data Center (DC) 1
L2 or L3
Virtual Overlay VXLAN tunnels
Physical Underlay Network
Active Data Center (DC) 2
L2 or L3
WAN
L1/L2
network
EVI tunnel

20. 21#ATM16
IP Fabric
Example 9: Storage & Converged Fabric
• When storage connectivity is required, converged both FC/Ethernet or FCoE/IP with universal access
• Spilt out to separate IP/SAN fabrics from leaf/ToR switches:
IRF
FCoE
Storage
VN_PortVN_Port
VF_Port
FCoE Storage
5900CP FCF
IRF
FC Storage
N_PortN_Port
F_Port
FC Storage
5900CP FCF
Server/CNA Server/CNA Server/CNA Server/HBA
Native FCEthernet FCoE
IP Fabric
SAN
Fabric A
SAN
Fabric B
SAN
Fabric A
SAN
Fabric B
VF_Port
F_Port

21. 22#ATM16
Which Fabric deployment to choose?
• It depends on customer requirements!
• L2 between access/core layer in the DC: Used in the DC mainly because it L2 connectivity is required by the
applications across racks, L2 loops are typically more difficult to troubleshoot compared to L3
• Traditional IRF L2 fabric works and is mature
• L3 between access/core layer in the DC: Main benefit is STP is no longer required to prevent loops, L3 routing
protocol is used, easier to troubleshoot for network OPs
• Decision for L2/L3 between access/core layer in the DC really depends on application network requirements.
• VXLAN over L3 fabric in the DC provides L3 fabric benefits while providing L2 network connectivity for
applications
• Is there a requirement to support storage traffic FC/FCoE and/or iSCSI?

22. 23#ATM16
DC Fabrics
Multiple options
Layer 2 Layer 3
STP (MSTP, rPVST+)
IRF
TRILL/SPB-m
OSPF
BGP
VXLAN
• HPE has comprehensive fabric capabilities
• HPE offers standard based “open” fabric
• Final design depends on customer
requirements
• Typical products:
− Spine = 7900/ 12900
− Leaf = 5900/ 5930/ 7900 / 12900

23. 24#ATM16
Guidance currently in FFRA
• DC Architecture Guidance

24. 25#ATM16
Fulfill the Architecture with
Data Center portfolio
25

25. 26#ATM16
HPE Data Center – Built to Win
High Performance
DC Fabric
High Density / High Performance /
Highly Scalable / Highly Resilient
Composable
Infrastructure
“Instantiating open, complex networks and
associated policies in minutes vs. weeks”
Zero Touch Provisioning
- DC Fabric
IMC Platform (ZTP / Fabric Manager)
DevOps (Python, Ansible …)
Hybrid Cloud Integration Helion/Openstack/CSA integration

26. 27#ATM16
HPE Data Center FlexFabric for Spine/Leaf Deployment
Modular network OS with Intelligent Resilient Fabric
1/10/40GbE L2/L3 and converged switches
25GbE/100GbE Roadmap
HPEIMCManagement
Core switches
Spine
HPE Comware
Network OS
L2/L3 IPv4/v6
MPLS/VPLS
VXLAN
Top of Rack
(TOR)
Leaf switches
High Density 10/40/100GbE switches
HPETechnologyServices
HPEConsultingServices
SDN

27. 28#ATM16
HPE Insertion Point
10G/40G Spine10/40G Top-of-Rack/Leaf High Density 100GbE Spine
Lead with HPE FlexFabric Modular 5930
LAN/SAN/MACSEC/VXLAN Ready
HPE FlexFabric 7910/7904
The power of the 129xx
@ smaller scale
HPE FlexFabric 12900E
When density is everything

28. 29#ATM16
Data Center Core Switching
FlexFabric 129xxE FlexFabric 79xx
Large/Very Large Core Compact Modular Core
Same switching architecture (CLOS/VoQ)
Spine/Leaf (deployment architecture)
HPE FlexFabric Core Switches At-a-Glance
All Platforms SDN Ready with OF 1.3 support and IPv6 Ready Phase2

29. 30#ATM16
HPE Modular 5930
Universal Ports
LAN/SAN convergence
1/10GbE and 4/8G FC
OpenFlow 1.3
SDN automation and
central management
L2 encryption (MACSEC)
End-to-End Security
Maximum
performance
Quick set up and
upgrades
Lower energy
and utility costs
Investment
protection
VXLAN in hardware
Overlay Ready − HPE DCN/NSX
NSX Certification soon
Cloud enabled Comware 7
HPE 5930-2SLOT-2QSFP ChassisHPE 5930-4SLOT Chassis

30. 31#ATM16
HPE FlexFabric Access Switches At-a-Glance
FlexFabric Top-of Rack, Access Blade Switches
Portfolio
Modular
5930
& 5930
5900 5900CP 5700 6127XLG
Moonshot-
45XGc
Highlights
40G ToR
Converged
LAN/SAN
MACSEC (HW)
10/40GbE ToR
Converged
LAN/SAN ToR
1/10GbE ToR
HPE
BladeSystem
Interconnect
Comware
based
HPE
BladeSystem
Interconnect
Comware
based

31. 32#ATM16
Capturing the transition from 10 to 25 Gb/s
SYS
FlexFabric
5930
Series
PN JG996A SN AFK6740
3.2 Tbps ASIC – 32x100G QSFP28
SYS
FlexFabric
5950
Series
2.0 Tbps ASIC – 48x25G SFP28 and 8x100G QSFP28 Switch
PN JG996A SN AFK6740
SYS
FlexFabric
5930
Series
PN JG996A SN AFK6740 PN JG996A SN AFK6740
3.2 Tbps ASIC – 4xSlot
2016 – Server transitioning from 10 Gb/S driving an inflection point for
100 GbE in Data Center networking
Leaf : XGS/Tomahawk
5950 (32 * 100G, 48 * 25G + 8 * 100G) – 1RU
Modular 5950 (10/25/40/100G + 16/32G
Converged Ports) – 2RU
Spine: ARAD+/Jericho/Jericho+TCAM
12902E/12904E/12908E/12916E (3/6/12/21RU)

32. 33#ATM16
IMC Value Proposition
The foundation of a complete DC management, monitoring and orchestration solution
Lead with HPE Intelligent Management
Center Platform
FCAPS Ready
Consistent
visibility
Actionable
data
Flexible
deployment Remediation
Accessible
management
Security
driven

33. 34#ATM16
Orchestrate
network fabrics
Complete the SDN
architecture with management
Accelerates deployment of
services and applications
•Unified SPB, TRILL, IRF fabric
management
•Manages across geo
dispersed locations (DCI/EVI)
•VMware vMotion playback
•Unified DCB, FCoE mgt
•Configuration, monitoring &
policy mgt for all SDN layers
•OpenFlow switch
management
•SDN controller performance
management
•One application for managing
SDN and traditional environ.
•“Just right” network services
tuned to business needs
•Simplifies provisioning,
monitoring of applications
•Eliminates manual
provisioning
•Easy drag and drop UI
IMC Orchestration for Data Center

34. 35#ATM16
Industry leading energy efficiency
Built the cloud on HPE Converged Infrastructure
A customizable RA built on our industry-leading infrastructure portfolio
35
The data center standard delivering
optimal performance, expandability,
and availability for your workload
HPE ProLiant Gen9 servers
Affordable, intelligent, and resilient
flash with unmatched performance,
flexibility, and ease of management
HPE 3PAR StoreServ storage
High-density, ultra-low-latency, top-of-
rack (ToR) switches designed to deliver
optimal throughput and availability
HPE FlexFabric Switch series
Powered by Intel® Xeon ® Processor E5-
2600 v3 product family
“Future proof” design
Agile infrastructure management
All-flash at nearly the same cost as HDDs
Industry-leading scale and density
Architected for 99.9999% availability
Simplified management for lower TCO
Low latency, high-performance
data switching
Business resilience and high availability

35. 36#ATM16
HPE Data Center Switching Positioning
• Integrated, fully featured
• Enterprise data centers
• Comware
• Disaggregated
• Web-scale data centers
• Choice of NOS
HPE FlexFabric HPE Altoline
Worldwide SDN market growing to over $8 billion by 2018

36. 37#ATM16
HPE Network Virtualization Solutions
Industry’s most complete portfolio - addressing varied/complex use cases
37
Virtual Cloud Network HPE-VMware NSX Distributed Cloud
Network
Enhanced Neutron Networking
Open source, DevOps Virtualized VMW Enterprises Service Provider/Telcos
De-risk the journey with HPE Trusted Network Transformation Services
DCNVCN
Multi DC NFV
Powered by HPE

37. 38#ATM16

38. 39#ATM16
Join Aruba’s Titans of Tomorrow
force in the fight against network
mayhem. Find out what your
IT superpower is.
Share your results with friends
and receive a free superpower
t-shirt.
www.arubatitans.com

39. Thank you