1. High Speed Interconnect Project May08-06

2. Problem Statement
At this time, the maximum real-world throughput of 10 Gbps network configurations is unknown.

3. Need Statement
Lockheed Martin (LM) needs a test plan designed and executed to measure the maximum real-world throughput of a 10 Gbps network composed of COTS components.

4. Project Goals
Create and test a network capable of reaching 10 Gbps with Commercial Off The Shelf (COTS) components
Topology has to use fiber optics
Remain within approx. $3500 budget

5. Possible Strategies Use Advanced TCA or µTCA Architectures
Use PCI Express Network Cards with a XFP Switch
Use PCI-X Network Cards with a XFP Switch

6. µTCA Node Strategy

7. µTCA Configuration Single Node composed of the following
Three 10 Gbps Network Interface Cards
MicroTCA Carrier Hub
Power module
Nodes can be connected in any way possible
Testing would be done with a single node due to the cost of components

8. PCI Express Slot Speeds
Implementation
Encoded Data Rate
Unencoded Data Rate x1
5 Gbps
4 Gbps (500 MB/sec) x4
20 Gbps
16 Gbps (2 GB/sec) x8
40 Gbps
32 Gbps (4 GB/sec)
x16
80 Gbps
64 Gbps (8 GB/sec)
Source:
System PCI-E slots must be at least x4 to allow for 10 Gbps testing

9. PCI Express Node Strategy
Node to Node Testing Configuration
Final Testing Configuration

10. PCI Express Configuration
Composed of three systems and a Ethernet switch
Initial testing will be completed with two systems directly connected
Final testing will be done with whole system

11. PCI-X Configuration Same node strategy as PCI Express
Bus speed max of approx Gbps
Rarity of cards and slots achieving this bandwidth
This configuration would be used only as a backup plan

12. Feature Comparison of uTCA & PCI-E
Advanced TCA and µTCA
PCI Express
Advantages
Modular design allows for expansion
262.5 Gbps maximum throughput for Advanced Mezzanine Cards
Disadvantages
Network Interface Card Technology for Advanced Mezzanine Cards hasn’t reached 10 Gbps
Costly components
Advantages
Readily available optical 10 Gbps NICs
Variety of 10 Gbps XFP Switches
Relatively low cost components
Disadvantages
PCI-E bus bandwidth does not reach 10 Gbps
Lack of systems that support PCI-E NICs
Source:

13. System Interface Speed Comparison
Maximum Transfer Rate
PCI 33-MHz
2.13 Gbps (266 MB/sec)
PCI 66-MHz
4.26 Gbps (532 MB/sec)
PCI-X 100-MHz
6.4 Gbps (800 MB/sec)
PCI-X 133-MHz
8 Gbps (1 GB/sec)
PCI-E x1
4 Gbps (500 MB/sec)
PCI-E x4
16 Gbps (2 GB/sec)
PCI-E x8
32 Gbps (4 GB/sec)
PCI-E x16
64 Gbps (8 GB/sec)
uTCA (AMC)
262.5 Gbps (32.8 GB/sec)
Source:

14. Presented Hardware Setup
NXB-10GXxR Intelligent NIC®
10 Gigabit Ethernet PCIe Adapter with pluggable XFP optical interface (
Node 1
Node 2
Node 3
TigerSwitch 10G 8-Port Standalone XFP 10Gigabit Ethernet Managed Layer 2 Switch
SMC Networks, Inc.

15. Host System: Dell PowerEdge SC440
Capable of PCI-E x1/x4/x8
Operating System Linux
Approximate Cost: $500/system
Separate system needed for each node

16. NetXen NXB-10GXxR NIC Pluggable XFP optical interface
10GBASE-SR and –LR support
PCIe Ver 1.1 Interface
x1/x4/x8 compatible
4 GB/s throughput
Linux and Window OS supported
Source: NetXen website

17. XFP – 10 Gigabit Small Form Factor Pluggable
Used for 10 Gbps connections
Operate at 850 nm (short range), 1310 nm (long range), or 1550nm (extended range).

18. TigerSwitch™ 10G Standalone 8-port XFP 10G Managed Layer 2 switch
Model Number: SMC8708L2
Supports up to 8 XFP ports
Delivers 10-Gigabit Ethernet
Switching fabric – 160Gbps
AC Input – 100 to 240 V, – 60 Hz, 2 A

19. Estimated Resource Costs
Quantity
Unit Cost
Total Cost
Optical NICs 2
$1000
$2000 1
Donated1
XFP Switch
Donated
Fiber optic cables 3
$802
$240
Host System
$500
$15003
Total
$3740
1 One optical NIC will need to be donated if the team must purchase the host systems
2 Source:
3 ISU ECpE Department’s update of the Senior Design lab may cover this cost

20. Testing Specifications
Bandwidth Measurement
Channel Capacity
Bandwidth Efficiency (Throughput)
Switching Time Measurement
Latency Measurement
Quality of Service Measurement
Load Balancing Measurement

21. Bandwidth Measurement
Node 1
Node 2
What is the maximum Channel Capacity between two nodes?
What is the effective bandwidth efficiency or amount of information transmitted versus overhead (frame formatting, coding, etc.)?

22. Switching Time Measurement
Node 1
Node 2
Node 3
How quickly can the source for information to Node 3 be switched?

23. Latency Measurement Node 3 Node 1 Node 2
What is the time delay between output on Node 1 or Node 2 to input on Node 3?

24. Quality of Service Measurement
Node 1
Node 2
Node 3
If two Nodes are transmitting to the same Node how is bandwidth allocation or QOS handled?

25. Load Balancing Measurement
Node 1
Node 2
Node 3
If two Nodes are transmitting to the same Node how is bandwidth balanced between the two sources?

26. Questions? ?