Tuesday, January 15, 2013
Monday, December 24, 2012
CCNP Routing, Switching and Troubleshooting quick reference and official certification guide PDFs for sharing
If anyone need the PDF of CCNP Switch, routing, Tshoot official certificate guides and quick reference, feel free to leave a comment and I will unicast them to you.
Saturday, July 2, 2011
CCNP exam preparation : EIGRP
=====EIGRP=========
1.how to configure a default route on a router to direct all the traffic to internet?
router eigrp 190
redistribute static
ip route 0.0.0.0 0.0.0.0 Null0
EIGRP has been configurated to operate over frame relay multipoint connections.
the bandwidth should be set to :
the CIR rate of the LOWEST speed connection * number of circuits
because in FR, all neighbors share the bW equally, regardless the actual CIR of each PVC.
Saturday, February 14, 2009
preparing for CCNA --note ( 1)
Typically, a Cisco router has the following types of memory components:
1. RAM (or DRAM): This type of memory is used for working storage. This is where part of IOS image, routing tables, packets, and others are stored during normal working of a router. RAM is erased when the router is powered off.
2. ROM (Read Only Memory): ROM stores bootstrap code for booting Cisco IOS. It points to the functional IOS image so that the router can complete its start-up configuration successfully. It is somewhat analogous the BIOS in PC. ROM also contains a small portion of IOS.
3. Flash memory: Flash memory contains the fully functional IOS images. It is the default location for getting IOS image at boot time. You can loosely compare the IOS image with operating system (say DOS).
4. NVRAM: NVRAM stands for Non Volatile RAM. NVRAM stores the initial or startup configuration file.
In Carrier Sense Multiple Access With Collision Detection (CSMA/CD), a node transmits only after listening to the media, and ensuring that no transmission is taking place. Further, sending nodes detect when a collision occurs and stop transmitting immediately, backing off for a random amount of time before trying again. This results in efficient use of the media since the bandwidth of transmitting the entire frame is not wasted.
The following are some Presentation Layer standards:
Graphic and Visual Image: PICT, TIFF, JPEG
Movies and Sound: MIDI, MPEG, Quick Time
The following are Session layer standards:
NFS, SQL,RPC,X-Windows.
1. RAM (or DRAM): This type of memory is used for working storage. This is where part of IOS image, routing tables, packets, and others are stored during normal working of a router. RAM is erased when the router is powered off.
2. ROM (Read Only Memory): ROM stores bootstrap code for booting Cisco IOS. It points to the functional IOS image so that the router can complete its start-up configuration successfully. It is somewhat analogous the BIOS in PC. ROM also contains a small portion of IOS.
3. Flash memory: Flash memory contains the fully functional IOS images. It is the default location for getting IOS image at boot time. You can loosely compare the IOS image with operating system (say DOS).
4. NVRAM: NVRAM stands for Non Volatile RAM. NVRAM stores the initial or startup configuration file.
In Carrier Sense Multiple Access With Collision Detection (CSMA/CD), a node transmits only after listening to the media, and ensuring that no transmission is taking place. Further, sending nodes detect when a collision occurs and stop transmitting immediately, backing off for a random amount of time before trying again. This results in efficient use of the media since the bandwidth of transmitting the entire frame is not wasted.
The following are some Presentation Layer standards:
Graphic and Visual Image: PICT, TIFF, JPEG
Movies and Sound: MIDI, MPEG, Quick Time
The following are Session layer standards:
NFS, SQL,RPC,X-Windows.
Internet Infrastucture
Table of Content
1.... Project General Specifications 3
· Projected Life. 3
· WAN Growth. 3
· LAN Growth. 3
· Workstations. 3
· Servers. 4
· Three Regional Hubs. 4
· Layer 2 Protocols-Frame Relay. 4
· Layer 3 Protocols- TCP/IP(V4) 4
· Current WAN Bandwidth. 4
· Anticipated WAN Bandwidth. 4
· Internet-Access-Servers. 4
· Horizontal Cabling. 5
· Vertical Cabling (Backbone) 5
· Classroom Cabling. 5
· Data services Distribution within the classroom.. 5
· Housing the classroom Data Switches and Cable Termination. 5
· Administrative Segment 5
· Student Segment 6
· Administrative Segment 6
· Student Segment 6
· Routing Protocol 6
· Servers and Network Interconnection Devices naming scheme. 6
· Administrative segments—IP addressing. 6
· Student Segments—IP Addressing. 6
2.... Physical Network Topology. 7
3. Specification of servers, workstations and protocols 8
· Server function-IP addressing, naming scheme and Server protocols. 8
· Router Switches and Naming Scheme. 10
· IP range for student Computers in R.E. Miller School 10
· IP range for staff computers R.E. Miller School 11
3.... Predicted Bandwidth to satisfy requirements 11
· WAN.. 11
· LAN.. 11
4.... Technical specification and pricing from vendors 11
· Servers. 11
· Routers. 15
· Layer 2 Switches. 16
5.... R.E. Miller School MDF and IDF network documentation 17
· Server Rack in MDF. 17
· LAN logical map diagram.. 17
· MDF CUT sheets. 18
6.... Reference: 25
1. Project General Specifications
1.1. Project Scope
This is a case study regarding to the assignment project 3664B- Produce a Network Architecture Design. One focus of network design here are three district hubs, which are established at District Office/Data Centre, Service Centre and Shaw Butte Elementary School; the other focus is the detailed network plan of the R.E. Miller School.
1.2. Scalability Requirements
· Projected Life
The projected life of this case study will be 7 to 10 years; therefore the design will have to take into consideration the demand growth within this period. Moreover, the hardware chosen should be stable, durable enough to serve the clients with consistent quality during this time. Manufacturer warranty and after-sale services are also important factors based on this project life.
· WAN Growth
The current WAN usage is not specified. The main traffic in the WAN will include accessing the mail server and FTP server and accessing internet though a proxy server. It is assumed that each teacher has their own email and the email activities are average level. Students only have access to filtered websites so no large amount of download is allowed. It is assumed that the bandwidth at the moment is 4 mbps. Since the estimated WAN growth is 100%, 8 mbps will be our projected bandwidth requirement.
· LAN Growth
LAN growth will mainly be the growth of users and a small amount of network activity increase. According to the scalability requirements, there will be 200% LAN growth. Therefore, there will be 250*3=750 computers in each school for curriculum usage by students; meanwhile, there will be 75*2=150 computers in each school for administration usage.
1.3. Throughput
· Workstations
The throughput of workstations is 1Mbps at the moment. It is estimated that it will increase to 3 Mbps according to the 200% projected LAN growth.
· Servers
The throughput of servers is 100Mbps currently. In the future, it will increase to 200Mbps according to the 100% projected WAN growth.
1.4. Wide Area Network
· Three Regional Hubs
Three Regional Hubs are established at District Office/Data Centre, Service Centre and Shaw Butte Elementary School. They will be high-end powerful routers.
· Layer 2 Protocols-Frame Relay
In the regional hub WAN transport, Layer 2 Protocol—Frame Relay Protocol is used. This enables cost-efficient data transmission for intermittent traffic between LANs and between end-points in a WAN. Because the virtual circuits used in Frame relay consume bandwidth only when they transport data, many virtual circuits can exist simultaneously across a given transmission line. In addition, each device can use more of the bandwidth as necessary, and thus operate at higher speeds. Also the Frame Relay protocol will discard erroneous frames and thus eliminate time-consuming error-handling processing.
· Layer 3 Protocols- TCP/IP(V4)
The layer 3 Protocol used here is TCP/IP (version 4). It manages the connectionless transfer of data one hop at a time, from end system to ingress router, router to router, and from egress router to destination end system. It detects and discards error packets. IP can also fragment large packets so that the medium can accept it.
· Current WAN Bandwidth
As we mentioned above, the current WAN bandwidth is not specified. 4Mbps will be a reasonable assumption considering the network traffic is controlled average level.
· Anticipated WAN Bandwidth
With 100% growth in WAN, the anticipated WAN bandwidth will be 8 Mbps.
· Internet-Access-Servers
The Internet Access Server housing proxy server, web server and firewall will locate in the District Office/Data Centre Server room. It is connected to the gateway and then a XDSL link to the ISP.
1.5. Local Area Network and Wiring Scheme
a) Australian Cabling Standards in use
The Australian Cabling Standards in use is AS 3080(EIA/TIA 568B).These Commercial Building Telecommunications Cabling Standards cover the specifications for categories 3, 4, and 5 Unshielded Twisted-Pair (UTP) cables and connecting hardware. New specifications for 62.5/125m optical fiber and single-mode optical fiber cables, connectors and cabling practices have also been included.
· Horizontal Cabling
Horizontal cabling is Category Unshielded Twisted Pair (CAT 5e UTP) and will have the capacity to accommodate 100 Mbps.
· Vertical Cabling (Backbone)
Vertical Cabling will be 62.5 micron fiber optic multi-mode cable. Multi-mode fiber comes in two standard widths, 62.5 micron and 50 micron. 62.5 micron multi-mode fiber can support Gigabit Ethernet over distances as long as 275 meters; 50 micron multi-mode fiber can increase that range to 550 meters. In our case, the distance reflected in the diagram between MDF and IDF is less than 275 meters; therefore, 62.5 micron will be sufficient.
· Classroom Cabling
Category Unshielded Twisted Pair (CAT 5e UTP) will be used and there will be 5 runs cablings. There will be three runs of cabling for students, one for teachers and the other run as a spare run.
· Data services Distribution within the classroom
Data services will be distributed within the room from wall outlet via decorative wire moulding to patch panel.
· Housing the classroom Data Switches and Cable Termination
The MDF room will house the classroom data switches and cable termination. It will also be the point of presence for the WAN network connection.
1.6. District Office/Data Centre
· Administrative Segment
In this segment, there will be 5 enterprise servers: DNS server, Mail server, WEB server, FTP server and library. There will be 3workgroup servers:
· The administration server to house the student tracking, attendance, grading and other administration functions;
· The application server for users to retrieve applications such as Word processing, Excel, PowerPoint;
· The library server to automated library information for curricular research purposes.
Currently, there are 75 teacher PCs and with estimated growth of 200%, there will be 225 teacher PCs in the future.
· Student Segment
In the student segment, currently there are 250 student PCs and in the future, this number will grow to 750.
1.7. R.E. Miller School
· Administrative Segment
In R.E. Miller School, there will be 2 Enterprise servers: DNS server and mail server.
Similar to the District Office, in this school, there are 3 workgroup servers: the administration server, the application server and the library server.
Currently, there are 75 teacher PCs and with estimated growth of 200%, there will be 225 teacher PCs in the future.
· Student Segment
In the student segment, currently there are 250 student PCs and in the future, this number will grow to 750.
1.8. Addressing , Networking Management and Routing Protocols
· Routing Protocol
TCP/IP and Frame Relay are the protocol used here.
· Servers and Network Interconnection Devices naming scheme
Servers and network interconnection devices will follow this naming scheme: Location + function +No.
· Administrative segments—IP addressing
The administrative segments will follow static addressing for security and stability.
· Student Segments—IP Addressing
The student segments will use dynamic addressing for efficiency and flexibility.
2. Physical Network Topology
3. Specification of servers, workstations and protocols
· Server function-IP addressing, naming scheme and Server protocols
In our plan, in each school, there will be about 250 people in one subnet. In total, there will be 23 subnets, 16 of them have to accommodate 250 users. 6 of them will accommodate 2 hosts and 1 of them needs to support 6 hosts.
All the servers will use static addressing. The detail is as follows:
DMZ
Server Function
Server Type
Sever Name
Server IP
Protocols
FIREWALL
DMZ_FIREWALL01
172.0.144.1
Web Server
Enterprise server
DMZ_WEB01
172.0.144.2
HTTP/HTTPS
FTP Server
Enterprise server
DMZ_FTP01
172.0.144.3
FTP
DISTRICT OFFICE/DATA CENTRE
Server Function
Server Type
Sever Name
Server IP
Protocols
Web Server
Enterprise server
DO_WEB01
172.0.128.1
HTTP
FTP Server
Enterprise server
DO_FTP01
172.0.128.2
FTP
DNS Server
Enterprise server
DO_DNS01
172.0.128.3
TCP/UDP
Mail server
Enterprise server
DO_Mail01
172.0.128.4
SMTP/IMAP
Library Server
Enterprise server
DO_Library01
172.0.128.5
TCP/IP
DHCP Server
Workgroup server
DO_DHCP01
172.0.128.6
TCP/IP
Administration Server
Workgroup server
DO_Admin01
172.0.128.7
TCP/IP
Application Server
Workgroup server
DO_App01
172.0.128.8
UDP
SERVICE CENTRE
Server Function
Server Type
Sever Name
Server IP
Protocols
DNS Server
Enterprise server
SC_DNS01
172.0.132.1
UDP/TCP
Mail server
Enterprise server
SC_MAIL01
172.0.132.2
SMTP/IMAP
DHCP Server
Workgroup server
SC_DHCP01
172.0.132.3
UDP
Administration Server
Workgroup server
SC_AD01
172.0.132.4
TCP/IP
Application Server
Workgroup server
SC_APP01
172.0.132.5
TCP/IP
SHAW BUTTE ELEMENTARY SCHOOL
Server Function
Server Type
Sever Name
Server IP
Protocols
DNS Server
Enterprise server
SB_DNS01
172.0.136.1
UDP/TCP
Mail server
Enterprise server
SB_Mail01
172.0.136.2
SMTP/IMAP
DHCP Server
Workgroup server
SB_DHCP01
172.0.136.3
UDP
Administration Server
Workgroup server
SB_Admin01
172.0.136.4
TCP/IP
Application Server
Workgroup server
SB_App01
172.0.136.5
TCP/IP
R.E.MILLER SCHOOL
Server Function
Server Type
Sever Name
Server IP
Protocols
DNS Server
Enterprise server
RE_DNS01
172.0.140.1
UDP/TCP
Mail server
Enterprise server
RE_Mail01
172.0.140.2
SMTP/IMAP
DHCP Server
Workgroup server
RE_DHCP01
172.0.140.3
UDP
Administration Server
Workgroup server
RE_Admin01
172.0.140.4
TCP/IP
Application Server
Workgroup server
RE_App01
172.0.140.5
TCP/IP
· Router Switches and Naming Scheme
Location
Router Name
Switch Name
Function
Gateway
GA-R1
connect the network to the ISP
District Office/Data Centre
DO-R2
DO-SRV-S1
teacher/ server
DO-STU-S2
student subnet1
DO-STU-S3
student subnet2
DO-STU-S4
student subnet3
SERVICE CENTRE
SC-R3
SC-SRV-S1
teacher/ server
SC-STU-S1
student subnet1
SC-STU-S2
student subnet2
SC-STU-S3
student subnet3
SHAW BUTTE ELEMENTARY SCHOOL
SB-R4
SB-SRV-S1
teacher/ server
SB-STU-S1
student subnet1
SB-STU-S2
student subnet2
SB-STU-S3
student subnet3
R.E.MILLER SCHOOL
RE-R5
RE-SRV-S1
teacher/ server
RE-STU-S1
student subnet1
RE-STU-S2
student subnet2
RE-STU-S3
student subnet3
· IP range for student Computers in R.E. Miller School
The IP range for student Computers in R.E. Miller School is: 172.0.141.1 to 172.0.143.254.
· IP range for staff computers R.E. Miller School
The IP range for staff computers R.E. Miller School is 172.0.140.6 to 172.0.140.254.
3. Predicted Bandwidth to satisfy requirements
· WAN
In the WAN, the predicted demand of bandwidth will be 2Mbs, double amount of the current bandwidth.
· LAN
In the LAN, the predicted demand of bandwidth will be 30Mbs, triple the amount of the current capacity.
4. Technical specification and pricing from vendors
· Servers
Server
Choice
Specification
Pricing
Web Server
HP ProLiant DL360 G5 2.00GHz Rack Server
Processor
Quad-Core Intel® Xeon® E5405 (2.00GHz, 1333MHz FSB, 80W) Processor
Memory
HP 1GB Fully Buffered DIMM PC2-5300 2X512 Memory
Storage controller
Smart Array E200i SAS RAID Controller with 64MB cache
Network card
2 Embedded NC373i Multifunction Gigabit Network Adapters
Power supply
HP 1u Server 700w Hot Plug Power Supply
Redundant fan options
HP Redundant Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1929.00
FTP Server
HP ProLiant DL360 G5 2.00GHz Rack Server
Processor
Quad-Core Intel® Xeon® E5405 (2.00GHz, 1333MHz FSB, 80W) Processor
Memory
HP 1GB Fully Buffered DIMM PC2-5300 2X512 Memory
Storage controller
Smart Array E200i SAS RAID Controller with 64MB cache
Network card
2 Embedded NC373i Multifunction Gigabit Network Adapters
Power supply
HP 1u Server 700w Hot Plug Power Supply
Redundant fan options
HP Redundant Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1929.00
DNS Server
HP ProLiant DL380 G5 2.00GHz Server
Processor
Quad-Core Intel® Xeon® E5405 (2.00GHz, 1333MHz FSB, 80W) Processor
Memory
HP 1GB Fully Buffered DIMM PC2-5300 2X512 Memory
Storage controller
Smart Array E200i SAS RAID Controller with 64MB cache
Network card
Embedded NC373i Multifunction Gigabit Network Adapter
Power supply
HP 1000-W Hot-Plug Power Supply
Redundant fan options
HP Redundant Hot-Plug Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$2109.00
Mail server
HP ProLiant DL385 G5
Processor
Quad-Core AMD Opteron™ Processor Model 2352 (2.1GHz, 75W ACP)
Memory
HP 2GB REG PC2-5300 2x1GB 1Rank Memory
Storage controller
HP Smart Array P400/256 Controller
Network card
Dual embedded NC373i Multifunction Gigabit Network Adapters
Power supply
HP 1000-W Hot-Plug Power Supply
Redundant fan options
HP Redundant Hot-Plug Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$2129.00
Library Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
DHCP Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
Administration Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
Application Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
· Routers
5 routers will be used in our network architecture; the main requirements are the number and type of LAN Ethernet ports to support our network. In our case, to support the fibre optic cable used in the backbone and 4 subnets is the key consideration. I have chosen Cisco ASR 1002 Router for our network.
Cisco ASR 1002
Physical specifications
Size : 2 rack units
Height: 3.5 in. (88.9 mm)
Width: 17.2 in. (437.4 mm)
Depth: 22 in. (558.8 mm)
Weight:
• 33.65 lb (15.23 kg) (with dual AC power supply and SPA blank covers)
• 36.85 lb (16.75 kg) (with dual AC power supply, blank covers and ASR1000-ESP5)
• No SPAs included
Note: The Cisco ASR 1002 has the route processor and SIP integrated.
Shared port adapters
3 SPA slots
Cisco ASR 1000 Series ESP
1 ESP slot
Route processor
Integrated in chassis
Number of SIPs supported
Integrated in chassis
Redundancy
Software: Yes
Built-in Gigabit Ethernet ports
Yes: 4 Gigabit Ethernet Small Form-Factor Pluggable (SFP) ports
Airflow
Front-to-back
Price
$12571.25
· Layer 2 Switches
The switch chosen here is Cisco Catalyst 4506-E and the main reason is that it meets the port number requirement to support all the users in one subnet. In total we need 4*4=16 switches.
Specification of the switch is as follows:
Switched 10/100 Fast Ethernet (RJ-45)
240
Switched 100 LX-10 (MT-RJ) or 100 BX-D (LC) Fast Ethernet
240
Switched 1000 Gigabit Ethernet (fiber)
244
Switched 10/100/1000BASE-T Gigabit Ethernet
240
Switched 10,000 (10 Gigabit Ethernet)
32
Dimensions(H x W x D)
17.38 x 17.31 x 12.50 in. (44.13 x 43.97 x 31.70 cm)
Rack Units (RU)
10 RU
Chassis Weight (with fan tray)
40.50 lb (18.37 kg)
Mounting
19 and 23 in. rack compatible (19 in. rack and cable guide hardware included)
Price
$3,535.99
5. R.E. Miller School MDF and IDF network documentation
· Server Rack in MDF
The server Room in MDF will house 1 router(2RU), 1 main switch(10RU), 1 fibre optic patch panel(1RU), 1 teacher patch panel(1RU), 1 student patch panel(1RU) an d 5 servers(5RU).
All these will take up 20 Rack Units. Considering redundancy and potential growth, a 24u rack will be a reasonable choice for our plan.
· LAN logical map diagram
MDF Location
Room AD13
IDF1 Location Media Centre
Room MC8
IDF2 Location South
Building Room SB9
IDF3 Location North Building
Room NB3
10 strand fiber optic cables
5 used (5 spare)
Link Speed=10Mb
Service area
Room MC1
Room MC3
Room MC4
Room MC6
Service area
Room SB10
Room SB18
Room SB11
Room SB19
Room SB12
Room SB20
Room SB13
Room SB21
Room SB14
Room SB22
Room SB15
Room SB23
Room SB16
Room SB24
Room SB25
Room P1
Room P2
Room P3
Room P4
Room P5
Room P6
Room SB19
Room SB20
Room SB21
Room SB22
Room SB23
Room SB24
Room SB25
Service area
Room NB12
Room NB18
Room NB13
Room NB19
Room NB14
Room NB20
Room NB15
Room NB22
Room NB16
Room NB23
Room NB17
Room NB26
Room NB27
Room P7
Room P8
Room P9
Room P10
Room P11
Legend:
MDF= Main Distribution Facility
IDF=Intermediate Distribution Facility
· MDF CUT sheets
Cut Sheet 1. MDF - Location
Room AD13
Connection
Cable ID
Cross Connection Paired # Port#
Patch panel
Cable Type
Status
MDF to IDF1 Media Centre
IDF 1-1
VCC1 /Port 1
FPP
Multi-Mode Fibre
Used
MDF to IDF1 Media Centre
IDF 1-2
VCC1/ Port 2
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 2 South Building
IDF 2-1
VCC2/ Port 3
FPP
Multi-Mode Fibre
Used
MDF to IDF 2 South Building
IDF 2-2
VCC2/ Port 4
FPP
Multi-Mode Fibre
Used
MDF to IDF 2 South Building
IDF 2-3
VCC2/ Port 5
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 2 South Building
IDF 2-4
VCC2/ Port 6
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 3 North Building
IDF 3-1
VCC3/ Port 7
FPP
Multi-Mode Fibre
Used
MDF to IDF 3 North Building
IDF 3-2
VCC3/ Port 8
FPP
Multi-Mode Fibre
Used
MDF to IDF 3 North Building
IDF 3-3
VCC3/ Port 9
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 3 North Building
IDF 3-4
VCC3/ Port 10
FPP
Multi-Mode Fibre
Not Used
MDF to Room AD9
AD9-1
MCC1/ Port 1
SPP
Cat 5 UTP
Used
MDF to Room AD9
AD9-2
MCC1/ Port2
SPP
Cat 5 UTP
Not Used
MDF to Room AD9
AD9-3
MCC1/ Port3
SPP
Cat 5 UTP
Not Used
MDF to Room AD9
AD9-4
MCC1/ Port1
TPP
Cat 5 UTP
Used
MDF to Room AD14
AD14-1
MCC2/ Port 4
SPP
Cat 5 UTP
Used
MDF to Room AD14
AD14-2
MCC2/ Port5
SPP
Cat 5 UTP
Not Used
MDF to Room AD14
AD14-3
MCC2/ Port6
SPP
Cat 5 UTP
Not Used
MDF to Room AD14
AD14-4
MCC2/ Port2
TPP
Cat 5 UTP
Used
· CUT sheets
1) North Building IDF
Cut Sheet 4. IDF3 North Building) – Location
Room NB3
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF3 North Building to MDF
IDF3-1
VCC1/ Port 1
FPP
Multi-Mode Fibre
Used
IDF3 North Building to MDF
IDF3-2
VCC1/ Port 2
FPP
Multi-Mode Fibre
Not Used
IDF3 North Building to MDF
IDF3-3
VCC2/ Port 3
FPP
Multi-Mode Fibre
Used
IDF3 North Building to MDF
IDF3-4
VCC2/ Port 4
FPP
Multi-Mode Fibre
Not Used
IDF3 to Room P7
P7-1
HCC1/ Port1
SPP1
Cat 5e UTP
Used
IDF3 to Room P7
P7-2
HCC1/ Port2
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P7
P7-3
HCC1/ Port3
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P7
P7-4
HCC1/ Port1
TPP2
Cat 5e UTP
Used
IDF3 to Room P8
P8-1
HCC2/ Port4
SPP1
Cat 5e UTP
Used
IDF3 to Room P8
P8-2
HCC2/ Port5
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P8
P8-3
HCC2/ Port6
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P8
P8-4
HCC2/ Port2
TPP2
Cat 5e UTP
Used
IDF3 to Room P9
P9-1
HCC3/ Port7
SPP1
Cat 5e UTP
Used
IDF3 to Room P9
P9-2
HCC3/ Port8
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P9
P9-3
HCC3/ Port9
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P9
P9-4
HCC3/ Port3
TPP2
Cat 5e UTP
Used
IDF3 to Room P10
P10-1
HCC4/ Port10
SPP1
Cat 5e UTP
Used
IDF3 to Room P10
P10-2
HCC4/ Port11
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P10
P10-3
HCC4/ Port12
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P10
P10-4
HCC4/ Port4
TPP2
Cat 5e UTP
Used
IDF3 to Room P11
P11-1
HCC5/ Port13
SPP1
Cat 5e UTP
Used
IDF3 to Room P11
P11-2
HCC5/ Port14
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P11
P11-3
HCC5/ Port15
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P11
P11-4
HCC5/ Port5
TPP2
Cat 5e UTP
Used
IDF3 to North Building Classroom
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF3 to Room NB12
NB12-1
HCC6/ Port16
SPP1
Cat 5e UTP
Used
IDF3 to Room NB12
NB12-2
HCC6/ Port17
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB12
NB12-3
HCC6/ Port18
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB12
NB12-4
HCC6/ Port6
TPP2
Cat 5e UTP
Used
IDF3 to Room NB13
NB13-1
HCC7/ Port19
SPP1
Cat 5e UTP
Used
IDF3 to Room NB13
NB13-1
HCC7/ Port20
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB13
NB13-1
HCC7/ Port21
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB13
NB13-1
HCC7/ Port7
TPP2
Cat 5e UTP
Used
IDF3 to Room NB14
NB14-1
HCC8/ Port22
SPP1
Cat 5e UTP
Used
IDF3 to Room NB14
NB14-1
HCC8/ Port23
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB14
NB14-1
HCC8/ Port24
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB14
NB14-1
HCC8/ Port8
TPP2
Cat 5e UTP
Used
IDF3 to Room NB15
NB15-1
HCC9/ Port25
SPP1
Cat 5e UTP
Used
IDF3 to Room NB15
NB15-1
HCC9/ Port26
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB15
NB15-1
HCC9/ Port27
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB15
NB15-1
HCC9/ Port9
TPP2
Cat 5e UTP
Used
IDF3 to Room NB16
NB16-1
HCC10/ Port28
SPP1
Cat 5eUTP
Used
IDF3 to Room NB16
NB16-1
HCC10/ Port29
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB16
NB16-1
HCC10/ Port30
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB16
NB16-1
HCC10/ Port10
TPP2
Cat 5e UTP
Used
IDF3 to Room NB17
NB17-1
HCC11/ Port31
SPP1
Cat 5e UTP
Used
IDF3 to Room NB17
NB17-1
HCC11/ Port32
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB17
NB17-1
HCC11/ Port33
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB17
NB17-1
HCC11/ Port11
TPP2
Cat 5e UTP
Used
Connection
Cable ID
Cross Connection Paired #
Cross Connection Ports #
Cable Type
Status
IDF3 to Room NB18
NB18-1
HCC12/ Port34
SPP1
Cat 5e UTP
Used
IDF3 to Room NB18
NB18-1
HCC12/ Port35
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB18
NB18-1
HCC12/ Port36
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB18
NB18-1
HCC12/ Port12
TPP2
Cat 5e UTP
Used
IDF3 to Room NB19
NB19-1
HCC13/ Port37
SPP1
Cat 5e UTP
Used
IDF3 to Room NB19
NB19-2
HCC13/ Port38
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB19
NB19-3
HCC13/ Port39
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB19
NB19-4
HCC13/ Port13
TPP2
Cat 5e UTP
Used
IDF3 to Room NB20
NB20-1
HCC14/ Port40
SPP1
Cat 5e UTP
Used
IDF3 to Room NB20
NB20-2
HCC14/ Port41
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB20
NB20-3
HCC14/ Port42
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB20
NB20-4
HCC14/ Port14
TPP2
Cat 5e UTP
Used
IDF3 to Room NB22
NB22-1
HCC15/ Port43
SPP1
Cat 5e UTP
Used
IDF3 to Room NB22
NB22-2
HCC15/ Port44
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB22
NB22-3
HCC15/ Port45
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB22
NB22-4
HCC15/ Port15
TPP2
Cat 5e UTP
Used
IDF3 to Room NB23
NB23-1
HCC16/ Port46
SPP1
Cat 5e UTP
Used
IDF3 to Room NB23
NB23-2
HCC16/ Port47
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB23
NB23-3
HCC16/ Port48
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB23
NB23-4
HCC16/ Port16
TPP2
Cat 5e UTP
Used
IDF3 to Room NB26
NB26-1
HCC17/ Port1
SPP2
Cat 5e UTP
Used
IDF3 to Room NB26
NB26-2
HCC17/ Port2
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB26
NB26-3
HCC17/ Port3
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB26
NB26-4
HCC17/ Port17
TPP2
Cat 5e UTP
Used
IDF3 to Room NB27
NB27-1
HCC18/ Port4
SPP2
Cat 5e UTP
Used
IDF3 to Room NB27
NB27-2
HCC18/ Port5
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB27
NB27-3
HCC18/ Port6
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB27
NB27-4
HCC18/ Port18
TPP2
Cat 5e UTP
Used
2) South Building IDF
Cut Sheet 3. IDF2 South Building) – Location
Room SB9
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF2 South Building to MDF
IDF2-1
VCC1/ Port 1
FPP
Multi-mode Fibre
Used
IDF2 South Building to MDF
IDF2-2
VCC1/ Port 2
FPP
Multi-mode Fibre
Not Used
IDF2 South Building to MDF
IDF2-3
VCC2/ Port 3
FPP
Multi-mode Fibre
Used
IDF2 South Building to MDF
IDF2-4
VCC2/ Port 4
FPP
Multi-mode Fibre
Not Used
IDF2 to Portable Classroom
IDF2 to Room P1
P1-1
HCC1/ Port1
SPP1
Cat 5e UTP
Used
IDF2 to Room P1
P1-2
HCC1/ Port2
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P1
P1-3
HCC1/ Port3
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P1
P1-4
HCC1/ Port1
TPP
Cat 5e UTP
Used
IDF2 to Room P2
P2-1
HCC2/ Port4
SPP1
Cat 5e UTP
Used
IDF2 to Room P2
P2-2
HCC2/ Port5
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P2
P2-3
HCC2/ Port6
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P2
P2-4
HCC2/ Port2
TPP
Cat 5e UTP
Used
IDF2 to Room P3
P3-1
HCC3/ Port7
SPP1
Cat 5e UTP
Used
IDF2 to Room P3
P3-2
HCC3/ Port8
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P3
P3-3
HCC3/ Port9
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P3
P3-4
HCC3/ Port3
TPP
Cat 5e UTP
Used
IDF2 to Room P4
P4-1
HCC4/ Port10
SPP1
Cat 5e UTP
Used
IDF2 to Room P4
P4-2
HCC4/ Port11
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P4
P4-3
HCC4/ Port12
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P4
P4-4
HCC4/ Port4
TPP
Cat 5e UTP
Used
IDF2 to Room P5
P5-1
HCC5/ Port13
SPP1
Cat 5e UTP
Used
IDF2 to Room P5
P5-2
HCC5/ Port14
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P5
P5-3
HCC5/ Port15
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P5
P5-4
HCC5/ Port5
TPP
Cat 5e UTP
Used
IDF2 to Room P6
P6-1
HCC6/ Port16
SPP1
Cat 5e UTP
Used
IDF2 to Room P6
P6-2
HCC6/ Port17
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P6
P6-3
HCC6/ Port18
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P6
P6-4
HCC6/ Port6
TPP
Cat 5e UTP
Used
IDF2 to South Building Classroom
IDF2 to Room SB10
SB10-1
HCC7/ Port19
SPP1
Cat 5e UTP
Used
IDF2 to Room SB10
SB10-1
HCC7/ Port20
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB10
SB10-1
HCC7/ Port21
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB10
SB10-1
HCC7/ Port7
TPP
Cat 5e UTP
Used
IDF2 to Room SB11
SB11-1
HCC8/ Port22
SPP1
Cat 5e UTP
Used
IDF2 to Room SB11
SB11-1
HCC8/ Port23
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB11
SB11-1
HCC8/ Port24
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB11
SB11-1
HCC8/ Port8
TPP
Cat 5e UTP
Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port25
SPP1
Cat 5e UTP
Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port26
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port27
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port9
TPP
Cat 5e UTP
Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port28
SPP1
Cat 5e UTP
Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port29
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port30
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port10
TPP
Cat 5e UTP
Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port31
SPP1
Cat 5e UTP
Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port32
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port33
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port11
TPP
Cat 5e UTP
Used
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF2 to Room SB15
SB15 -1
HCC12/ Port34
SPP1
Cat 5e UTP
Used
IDF2 to Room SB15
SB15 -1
HCC12/ Port35
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB15
SB15 -1
HCC12/ Port36
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB15
SB15 -1
HCC12/ Port12
TPP
Cat 5e UTP
Used
IDF2 to Room SB16
SB16-1
HCC13/ Port37
SPP1
Cat 5e UTP
Used
IDF2 to Room SB16
SB16-2
HCC13/ Port38
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB16
SB16-3
HCC13/ Port39
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB16
SB16-4
HCC13/ Port13
TPP
Cat 5e UTP
Used
IDF2 to Room SB18
SB18-1
HCC14/Port40
SPP1
Cat 5e UTP
Used
IDF2 to Room SB18
SB18-2
HCC14/Port41
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB18
SB18-3
HCC14/Port42
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB18
SB18-4
HCC14/Port14
TPP
Cat 5e UTP
Used
IDF2 to Room SB19
SB19-1
HCC15/ Port43
SPP1
Cat 5e UTP
Used
IDF2 to Room SB19
SB19-2
HCC15/ Port44
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB19
SB19-3
HCC15/ Port45
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB19
SB19-4
HCC15/ Port15
TPP
Cat 5e UTP
Used
IDF2 to Room SB20
SB20-1
HCC16/ Port1
SPP2
Cat 5e UTP
Used
IDF2 to Room SB20
SB20-2
HCC16/ Port2
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB20
SB20-3
HCC16/ Port3
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB20
SB20-4
HCC16/ Port16
TPP
Cat 5e UTP
Used
IDF2 to Room SB21
SB21-1
HCC17/ Port4
SPP2
Cat 5e UTP
Used
IDF2 to Room SB21
SB21-2
HCC17/ Port5
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB21
SB21-3
HCC17/ Port6
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB21
SB21-4
HCC17/ Port18
TPP
Cat 5e UTP
Used
IDF2 to Room SB22
SB22-1
HCC18/ Port7
SPP2
Cat 5e UTP
Used
IDF2 to Room SB22
SB22-2
HCC18/ Port8
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB22
SB22-3
HCC18/ Port9
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB22
SB22-4
HCC18/ Port19
TPP
Cat 5e UTP
Used
IDF2 to Room SB23
SB23-1
HCC19/ Port10
SPP2
Cat 5e UTP
Used
IDF2 to Room SB23
SB23-2
HCC19/ Port11
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB23
SB23-3
HCC19/ Port12
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB23
SB23-4
HCC19/ Port20
TPP
Cat 5e UTP
Used
IDF2 to Room SB24
SB24-1
HCC20/ Port13
SPP2
Cat 5e UTP
Used
IDF2 to Room SB24
SB24-2
HCC20/ Port14
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB24
SB24-3
HCC20/ Port15
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB24
SB24-4
HCC20/ Port21
TPP
Cat 5e UTP
Used
IDF2 to Room SB25
SB25-1
HCC21/ Port16
SPP2
Cat 5e UTP
Used
IDF2 to Room SB25
SB25-2
HCC21/ Port16
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB25
SB25-3
HCC21/ Port18
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB25
SB25-4
HCC21/ Port22
TPP
Cat 5e UTP
Used
· Media centre IDF
Cut Sheet2. IDF1 Media Centre) – Location
Room MC8
Connection
Cable ID
Cross Connection Paired # Port #
Patch Panel
Cable Type
Status
IDF1 Media Centre to MDF
IDF1-1
VCC1/ Port 1
FPP
Mutli-mode Fibre
Used
IDF1 Media Centre to MDF
IDF1-2
VCC1/ Port 2
FPP
Mutli-mode Fibre
Not Used
IDF1 to Room MC1
MC1-1
HCC1/ Port 1
SPP
Cat 5e UTP
Used
IDF1 to Room MC1
MC1-2
HCC1/ Port 2
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC1
MC1-3
HCC1/ Port 3
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC1
MC1-4
HCC1/ Port1
TPP
Cat 5e UTP
Used
IDF1 to room MC3
MC3-1
HCC2/ Port 4
SPP
Cat 5e UTP
Used
IDF1 to room MC3
MC3-2
HCC2/ Port5
SPP
Cat 5e UTP
Not Used
IDF1 to room MC3
MC3-3
HCC2/ Port6
SPP
Cat 5e UTP
Not Used
IDF1 to room MC3
MC3-4
HCC2/ Port2
TPP
Cat 5e UTP
Used
IDF1 to Room MC4
MC4-1
HCC2/ Port7
SPP
Cat 5e UTP
Used
IDF1 to Room MC4
MC4-2
HCC3/ Port8
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC4
MC4-3
HCC3/ Port9
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC4
MC4-4
HCC3/ Port3
TPP
Cat 5e UTP
Used
IDF1 to Room MC6
MC6-1
HCC4 /Port 10
SPP
Cat 5e UTP
Used
IDF1 to Room MC6
MC6-2
HCC4 /Port11
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC6
MC6-3
HCC4 /Port12
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC6
MC6-4
HCC4 /Port4
TPP
Cat 5e UTP
Used
· Classroom cabinet and POP connection
In each classroom, there will be a lockable cabinet to house a patch panel, a switch and to act as the POP connection. The appropriate size for the cabinet will around 30cm*40cm* 70cm*. Here are some options from Hallam ECCO Wall Mount Cabinet and the model with size of 6 RU will be quite proper for our case.
·
6. Reference:
http://www.hp.com/cgi-bin/sbso/buyguides/tsg_product_select.cgi#Domain%20controller
http://h10010.www1.hp.com/wwpc/pscmisc/vac/us/en/sm/proliant/proliant-dl.html?jumpid=re_R295_prodexp/busproducts/computing-server/proliant-dl&psn=servers
http://www.cisco.com/en/US/prod/collateral/routers/ps9343/data_sheet_c78-447652.html
http://www.cisco.com/en/US/products/ps9436/index.html
www.pc.pcconnection.com/1/1/221402-cisco-asr1002-aggregation-services-router-chassis-dual-p-s-2u.html
http://www.cisco.com/en/US/prod/collateral/switches/ps5718/ps4324/product_data_sheet09186a008033a3bd.html
http://www.cisco.com/en/US/prod/collateral/switches/ps5718/ps7077/product_data_sheet0900aecd805bbe67.html
http://www.cisco.com/en/US/prod/collateral/switches/ps5718/ps4324/product_data_sheet0900aecd801e7846.html
http://www.superwarehouse.com/Cisco_Catalyst_4506-E_Switch_Chassis_with_PoE/WS-C4506-E/p/1513616
http://sholl.com.au/Cabinets_Racks/ECCO_Wall_Cabinets.html
1.... Project General Specifications 3
· Projected Life. 3
· WAN Growth. 3
· LAN Growth. 3
· Workstations. 3
· Servers. 4
· Three Regional Hubs. 4
· Layer 2 Protocols-Frame Relay. 4
· Layer 3 Protocols- TCP/IP(V4) 4
· Current WAN Bandwidth. 4
· Anticipated WAN Bandwidth. 4
· Internet-Access-Servers. 4
· Horizontal Cabling. 5
· Vertical Cabling (Backbone) 5
· Classroom Cabling. 5
· Data services Distribution within the classroom.. 5
· Housing the classroom Data Switches and Cable Termination. 5
· Administrative Segment 5
· Student Segment 6
· Administrative Segment 6
· Student Segment 6
· Routing Protocol 6
· Servers and Network Interconnection Devices naming scheme. 6
· Administrative segments—IP addressing. 6
· Student Segments—IP Addressing. 6
2.... Physical Network Topology. 7
3. Specification of servers, workstations and protocols 8
· Server function-IP addressing, naming scheme and Server protocols. 8
· Router Switches and Naming Scheme. 10
· IP range for student Computers in R.E. Miller School 10
· IP range for staff computers R.E. Miller School 11
3.... Predicted Bandwidth to satisfy requirements 11
· WAN.. 11
· LAN.. 11
4.... Technical specification and pricing from vendors 11
· Servers. 11
· Routers. 15
· Layer 2 Switches. 16
5.... R.E. Miller School MDF and IDF network documentation 17
· Server Rack in MDF. 17
· LAN logical map diagram.. 17
· MDF CUT sheets. 18
6.... Reference: 25
1. Project General Specifications
1.1. Project Scope
This is a case study regarding to the assignment project 3664B- Produce a Network Architecture Design. One focus of network design here are three district hubs, which are established at District Office/Data Centre, Service Centre and Shaw Butte Elementary School; the other focus is the detailed network plan of the R.E. Miller School.
1.2. Scalability Requirements
· Projected Life
The projected life of this case study will be 7 to 10 years; therefore the design will have to take into consideration the demand growth within this period. Moreover, the hardware chosen should be stable, durable enough to serve the clients with consistent quality during this time. Manufacturer warranty and after-sale services are also important factors based on this project life.
· WAN Growth
The current WAN usage is not specified. The main traffic in the WAN will include accessing the mail server and FTP server and accessing internet though a proxy server. It is assumed that each teacher has their own email and the email activities are average level. Students only have access to filtered websites so no large amount of download is allowed. It is assumed that the bandwidth at the moment is 4 mbps. Since the estimated WAN growth is 100%, 8 mbps will be our projected bandwidth requirement.
· LAN Growth
LAN growth will mainly be the growth of users and a small amount of network activity increase. According to the scalability requirements, there will be 200% LAN growth. Therefore, there will be 250*3=750 computers in each school for curriculum usage by students; meanwhile, there will be 75*2=150 computers in each school for administration usage.
1.3. Throughput
· Workstations
The throughput of workstations is 1Mbps at the moment. It is estimated that it will increase to 3 Mbps according to the 200% projected LAN growth.
· Servers
The throughput of servers is 100Mbps currently. In the future, it will increase to 200Mbps according to the 100% projected WAN growth.
1.4. Wide Area Network
· Three Regional Hubs
Three Regional Hubs are established at District Office/Data Centre, Service Centre and Shaw Butte Elementary School. They will be high-end powerful routers.
· Layer 2 Protocols-Frame Relay
In the regional hub WAN transport, Layer 2 Protocol—Frame Relay Protocol is used. This enables cost-efficient data transmission for intermittent traffic between LANs and between end-points in a WAN. Because the virtual circuits used in Frame relay consume bandwidth only when they transport data, many virtual circuits can exist simultaneously across a given transmission line. In addition, each device can use more of the bandwidth as necessary, and thus operate at higher speeds. Also the Frame Relay protocol will discard erroneous frames and thus eliminate time-consuming error-handling processing.
· Layer 3 Protocols- TCP/IP(V4)
The layer 3 Protocol used here is TCP/IP (version 4). It manages the connectionless transfer of data one hop at a time, from end system to ingress router, router to router, and from egress router to destination end system. It detects and discards error packets. IP can also fragment large packets so that the medium can accept it.
· Current WAN Bandwidth
As we mentioned above, the current WAN bandwidth is not specified. 4Mbps will be a reasonable assumption considering the network traffic is controlled average level.
· Anticipated WAN Bandwidth
With 100% growth in WAN, the anticipated WAN bandwidth will be 8 Mbps.
· Internet-Access-Servers
The Internet Access Server housing proxy server, web server and firewall will locate in the District Office/Data Centre Server room. It is connected to the gateway and then a XDSL link to the ISP.
1.5. Local Area Network and Wiring Scheme
a) Australian Cabling Standards in use
The Australian Cabling Standards in use is AS 3080(EIA/TIA 568B).These Commercial Building Telecommunications Cabling Standards cover the specifications for categories 3, 4, and 5 Unshielded Twisted-Pair (UTP) cables and connecting hardware. New specifications for 62.5/125m optical fiber and single-mode optical fiber cables, connectors and cabling practices have also been included.
· Horizontal Cabling
Horizontal cabling is Category Unshielded Twisted Pair (CAT 5e UTP) and will have the capacity to accommodate 100 Mbps.
· Vertical Cabling (Backbone)
Vertical Cabling will be 62.5 micron fiber optic multi-mode cable. Multi-mode fiber comes in two standard widths, 62.5 micron and 50 micron. 62.5 micron multi-mode fiber can support Gigabit Ethernet over distances as long as 275 meters; 50 micron multi-mode fiber can increase that range to 550 meters. In our case, the distance reflected in the diagram between MDF and IDF is less than 275 meters; therefore, 62.5 micron will be sufficient.
· Classroom Cabling
Category Unshielded Twisted Pair (CAT 5e UTP) will be used and there will be 5 runs cablings. There will be three runs of cabling for students, one for teachers and the other run as a spare run.
· Data services Distribution within the classroom
Data services will be distributed within the room from wall outlet via decorative wire moulding to patch panel.
· Housing the classroom Data Switches and Cable Termination
The MDF room will house the classroom data switches and cable termination. It will also be the point of presence for the WAN network connection.
1.6. District Office/Data Centre
· Administrative Segment
In this segment, there will be 5 enterprise servers: DNS server, Mail server, WEB server, FTP server and library. There will be 3workgroup servers:
· The administration server to house the student tracking, attendance, grading and other administration functions;
· The application server for users to retrieve applications such as Word processing, Excel, PowerPoint;
· The library server to automated library information for curricular research purposes.
Currently, there are 75 teacher PCs and with estimated growth of 200%, there will be 225 teacher PCs in the future.
· Student Segment
In the student segment, currently there are 250 student PCs and in the future, this number will grow to 750.
1.7. R.E. Miller School
· Administrative Segment
In R.E. Miller School, there will be 2 Enterprise servers: DNS server and mail server.
Similar to the District Office, in this school, there are 3 workgroup servers: the administration server, the application server and the library server.
Currently, there are 75 teacher PCs and with estimated growth of 200%, there will be 225 teacher PCs in the future.
· Student Segment
In the student segment, currently there are 250 student PCs and in the future, this number will grow to 750.
1.8. Addressing , Networking Management and Routing Protocols
· Routing Protocol
TCP/IP and Frame Relay are the protocol used here.
· Servers and Network Interconnection Devices naming scheme
Servers and network interconnection devices will follow this naming scheme: Location + function +No.
· Administrative segments—IP addressing
The administrative segments will follow static addressing for security and stability.
· Student Segments—IP Addressing
The student segments will use dynamic addressing for efficiency and flexibility.
2. Physical Network Topology
3. Specification of servers, workstations and protocols
· Server function-IP addressing, naming scheme and Server protocols
In our plan, in each school, there will be about 250 people in one subnet. In total, there will be 23 subnets, 16 of them have to accommodate 250 users. 6 of them will accommodate 2 hosts and 1 of them needs to support 6 hosts.
All the servers will use static addressing. The detail is as follows:
DMZ
Server Function
Server Type
Sever Name
Server IP
Protocols
FIREWALL
DMZ_FIREWALL01
172.0.144.1
Web Server
Enterprise server
DMZ_WEB01
172.0.144.2
HTTP/HTTPS
FTP Server
Enterprise server
DMZ_FTP01
172.0.144.3
FTP
DISTRICT OFFICE/DATA CENTRE
Server Function
Server Type
Sever Name
Server IP
Protocols
Web Server
Enterprise server
DO_WEB01
172.0.128.1
HTTP
FTP Server
Enterprise server
DO_FTP01
172.0.128.2
FTP
DNS Server
Enterprise server
DO_DNS01
172.0.128.3
TCP/UDP
Mail server
Enterprise server
DO_Mail01
172.0.128.4
SMTP/IMAP
Library Server
Enterprise server
DO_Library01
172.0.128.5
TCP/IP
DHCP Server
Workgroup server
DO_DHCP01
172.0.128.6
TCP/IP
Administration Server
Workgroup server
DO_Admin01
172.0.128.7
TCP/IP
Application Server
Workgroup server
DO_App01
172.0.128.8
UDP
SERVICE CENTRE
Server Function
Server Type
Sever Name
Server IP
Protocols
DNS Server
Enterprise server
SC_DNS01
172.0.132.1
UDP/TCP
Mail server
Enterprise server
SC_MAIL01
172.0.132.2
SMTP/IMAP
DHCP Server
Workgroup server
SC_DHCP01
172.0.132.3
UDP
Administration Server
Workgroup server
SC_AD01
172.0.132.4
TCP/IP
Application Server
Workgroup server
SC_APP01
172.0.132.5
TCP/IP
SHAW BUTTE ELEMENTARY SCHOOL
Server Function
Server Type
Sever Name
Server IP
Protocols
DNS Server
Enterprise server
SB_DNS01
172.0.136.1
UDP/TCP
Mail server
Enterprise server
SB_Mail01
172.0.136.2
SMTP/IMAP
DHCP Server
Workgroup server
SB_DHCP01
172.0.136.3
UDP
Administration Server
Workgroup server
SB_Admin01
172.0.136.4
TCP/IP
Application Server
Workgroup server
SB_App01
172.0.136.5
TCP/IP
R.E.MILLER SCHOOL
Server Function
Server Type
Sever Name
Server IP
Protocols
DNS Server
Enterprise server
RE_DNS01
172.0.140.1
UDP/TCP
Mail server
Enterprise server
RE_Mail01
172.0.140.2
SMTP/IMAP
DHCP Server
Workgroup server
RE_DHCP01
172.0.140.3
UDP
Administration Server
Workgroup server
RE_Admin01
172.0.140.4
TCP/IP
Application Server
Workgroup server
RE_App01
172.0.140.5
TCP/IP
· Router Switches and Naming Scheme
Location
Router Name
Switch Name
Function
Gateway
GA-R1
connect the network to the ISP
District Office/Data Centre
DO-R2
DO-SRV-S1
teacher/ server
DO-STU-S2
student subnet1
DO-STU-S3
student subnet2
DO-STU-S4
student subnet3
SERVICE CENTRE
SC-R3
SC-SRV-S1
teacher/ server
SC-STU-S1
student subnet1
SC-STU-S2
student subnet2
SC-STU-S3
student subnet3
SHAW BUTTE ELEMENTARY SCHOOL
SB-R4
SB-SRV-S1
teacher/ server
SB-STU-S1
student subnet1
SB-STU-S2
student subnet2
SB-STU-S3
student subnet3
R.E.MILLER SCHOOL
RE-R5
RE-SRV-S1
teacher/ server
RE-STU-S1
student subnet1
RE-STU-S2
student subnet2
RE-STU-S3
student subnet3
· IP range for student Computers in R.E. Miller School
The IP range for student Computers in R.E. Miller School is: 172.0.141.1 to 172.0.143.254.
· IP range for staff computers R.E. Miller School
The IP range for staff computers R.E. Miller School is 172.0.140.6 to 172.0.140.254.
3. Predicted Bandwidth to satisfy requirements
· WAN
In the WAN, the predicted demand of bandwidth will be 2Mbs, double amount of the current bandwidth.
· LAN
In the LAN, the predicted demand of bandwidth will be 30Mbs, triple the amount of the current capacity.
4. Technical specification and pricing from vendors
· Servers
Server
Choice
Specification
Pricing
Web Server
HP ProLiant DL360 G5 2.00GHz Rack Server
Processor
Quad-Core Intel® Xeon® E5405 (2.00GHz, 1333MHz FSB, 80W) Processor
Memory
HP 1GB Fully Buffered DIMM PC2-5300 2X512 Memory
Storage controller
Smart Array E200i SAS RAID Controller with 64MB cache
Network card
2 Embedded NC373i Multifunction Gigabit Network Adapters
Power supply
HP 1u Server 700w Hot Plug Power Supply
Redundant fan options
HP Redundant Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1929.00
FTP Server
HP ProLiant DL360 G5 2.00GHz Rack Server
Processor
Quad-Core Intel® Xeon® E5405 (2.00GHz, 1333MHz FSB, 80W) Processor
Memory
HP 1GB Fully Buffered DIMM PC2-5300 2X512 Memory
Storage controller
Smart Array E200i SAS RAID Controller with 64MB cache
Network card
2 Embedded NC373i Multifunction Gigabit Network Adapters
Power supply
HP 1u Server 700w Hot Plug Power Supply
Redundant fan options
HP Redundant Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1929.00
DNS Server
HP ProLiant DL380 G5 2.00GHz Server
Processor
Quad-Core Intel® Xeon® E5405 (2.00GHz, 1333MHz FSB, 80W) Processor
Memory
HP 1GB Fully Buffered DIMM PC2-5300 2X512 Memory
Storage controller
Smart Array E200i SAS RAID Controller with 64MB cache
Network card
Embedded NC373i Multifunction Gigabit Network Adapter
Power supply
HP 1000-W Hot-Plug Power Supply
Redundant fan options
HP Redundant Hot-Plug Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$2109.00
Mail server
HP ProLiant DL385 G5
Processor
Quad-Core AMD Opteron™ Processor Model 2352 (2.1GHz, 75W ACP)
Memory
HP 2GB REG PC2-5300 2x1GB 1Rank Memory
Storage controller
HP Smart Array P400/256 Controller
Network card
Dual embedded NC373i Multifunction Gigabit Network Adapters
Power supply
HP 1000-W Hot-Plug Power Supply
Redundant fan options
HP Redundant Hot-Plug Fans
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$2129.00
Library Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
DHCP Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
Administration Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
Application Server
HP ProLiant DL320 G5p Server
Processor
Quad-Core Intel® Xeon® Processor X3210 (2.13GHz/8M)
Memory
HP 2GB Unbuffered Advanced ECC PC2-6400 DDR 2x1GB Memory
Storage controller
Integrated Intel® 82801GR Serial ATA Host Controller
Network card
Embedded NC326i Dual Port Gigabit Server Adapter
Server management
Integrated Lights Out 2 (iLO 2) Standard Management
Warranty
HP Standard Limited Warranty - 3 Years Parts and on-site Labor, Next Business Day
$1369.00
· Routers
5 routers will be used in our network architecture; the main requirements are the number and type of LAN Ethernet ports to support our network. In our case, to support the fibre optic cable used in the backbone and 4 subnets is the key consideration. I have chosen Cisco ASR 1002 Router for our network.
Cisco ASR 1002
Physical specifications
Size : 2 rack units
Height: 3.5 in. (88.9 mm)
Width: 17.2 in. (437.4 mm)
Depth: 22 in. (558.8 mm)
Weight:
• 33.65 lb (15.23 kg) (with dual AC power supply and SPA blank covers)
• 36.85 lb (16.75 kg) (with dual AC power supply, blank covers and ASR1000-ESP5)
• No SPAs included
Note: The Cisco ASR 1002 has the route processor and SIP integrated.
Shared port adapters
3 SPA slots
Cisco ASR 1000 Series ESP
1 ESP slot
Route processor
Integrated in chassis
Number of SIPs supported
Integrated in chassis
Redundancy
Software: Yes
Built-in Gigabit Ethernet ports
Yes: 4 Gigabit Ethernet Small Form-Factor Pluggable (SFP) ports
Airflow
Front-to-back
Price
$12571.25
· Layer 2 Switches
The switch chosen here is Cisco Catalyst 4506-E and the main reason is that it meets the port number requirement to support all the users in one subnet. In total we need 4*4=16 switches.
Specification of the switch is as follows:
Switched 10/100 Fast Ethernet (RJ-45)
240
Switched 100 LX-10 (MT-RJ) or 100 BX-D (LC) Fast Ethernet
240
Switched 1000 Gigabit Ethernet (fiber)
244
Switched 10/100/1000BASE-T Gigabit Ethernet
240
Switched 10,000 (10 Gigabit Ethernet)
32
Dimensions(H x W x D)
17.38 x 17.31 x 12.50 in. (44.13 x 43.97 x 31.70 cm)
Rack Units (RU)
10 RU
Chassis Weight (with fan tray)
40.50 lb (18.37 kg)
Mounting
19 and 23 in. rack compatible (19 in. rack and cable guide hardware included)
Price
$3,535.99
5. R.E. Miller School MDF and IDF network documentation
· Server Rack in MDF
The server Room in MDF will house 1 router(2RU), 1 main switch(10RU), 1 fibre optic patch panel(1RU), 1 teacher patch panel(1RU), 1 student patch panel(1RU) an d 5 servers(5RU).
All these will take up 20 Rack Units. Considering redundancy and potential growth, a 24u rack will be a reasonable choice for our plan.
· LAN logical map diagram
MDF Location
Room AD13
IDF1 Location Media Centre
Room MC8
IDF2 Location South
Building Room SB9
IDF3 Location North Building
Room NB3
10 strand fiber optic cables
5 used (5 spare)
Link Speed=10Mb
Service area
Room MC1
Room MC3
Room MC4
Room MC6
Service area
Room SB10
Room SB18
Room SB11
Room SB19
Room SB12
Room SB20
Room SB13
Room SB21
Room SB14
Room SB22
Room SB15
Room SB23
Room SB16
Room SB24
Room SB25
Room P1
Room P2
Room P3
Room P4
Room P5
Room P6
Room SB19
Room SB20
Room SB21
Room SB22
Room SB23
Room SB24
Room SB25
Service area
Room NB12
Room NB18
Room NB13
Room NB19
Room NB14
Room NB20
Room NB15
Room NB22
Room NB16
Room NB23
Room NB17
Room NB26
Room NB27
Room P7
Room P8
Room P9
Room P10
Room P11
Legend:
MDF= Main Distribution Facility
IDF=Intermediate Distribution Facility
· MDF CUT sheets
Cut Sheet 1. MDF - Location
Room AD13
Connection
Cable ID
Cross Connection Paired # Port#
Patch panel
Cable Type
Status
MDF to IDF1 Media Centre
IDF 1-1
VCC1 /Port 1
FPP
Multi-Mode Fibre
Used
MDF to IDF1 Media Centre
IDF 1-2
VCC1/ Port 2
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 2 South Building
IDF 2-1
VCC2/ Port 3
FPP
Multi-Mode Fibre
Used
MDF to IDF 2 South Building
IDF 2-2
VCC2/ Port 4
FPP
Multi-Mode Fibre
Used
MDF to IDF 2 South Building
IDF 2-3
VCC2/ Port 5
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 2 South Building
IDF 2-4
VCC2/ Port 6
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 3 North Building
IDF 3-1
VCC3/ Port 7
FPP
Multi-Mode Fibre
Used
MDF to IDF 3 North Building
IDF 3-2
VCC3/ Port 8
FPP
Multi-Mode Fibre
Used
MDF to IDF 3 North Building
IDF 3-3
VCC3/ Port 9
FPP
Multi-Mode Fibre
Not Used
MDF to IDF 3 North Building
IDF 3-4
VCC3/ Port 10
FPP
Multi-Mode Fibre
Not Used
MDF to Room AD9
AD9-1
MCC1/ Port 1
SPP
Cat 5 UTP
Used
MDF to Room AD9
AD9-2
MCC1/ Port2
SPP
Cat 5 UTP
Not Used
MDF to Room AD9
AD9-3
MCC1/ Port3
SPP
Cat 5 UTP
Not Used
MDF to Room AD9
AD9-4
MCC1/ Port1
TPP
Cat 5 UTP
Used
MDF to Room AD14
AD14-1
MCC2/ Port 4
SPP
Cat 5 UTP
Used
MDF to Room AD14
AD14-2
MCC2/ Port5
SPP
Cat 5 UTP
Not Used
MDF to Room AD14
AD14-3
MCC2/ Port6
SPP
Cat 5 UTP
Not Used
MDF to Room AD14
AD14-4
MCC2/ Port2
TPP
Cat 5 UTP
Used
· CUT sheets
1) North Building IDF
Cut Sheet 4. IDF3 North Building) – Location
Room NB3
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF3 North Building to MDF
IDF3-1
VCC1/ Port 1
FPP
Multi-Mode Fibre
Used
IDF3 North Building to MDF
IDF3-2
VCC1/ Port 2
FPP
Multi-Mode Fibre
Not Used
IDF3 North Building to MDF
IDF3-3
VCC2/ Port 3
FPP
Multi-Mode Fibre
Used
IDF3 North Building to MDF
IDF3-4
VCC2/ Port 4
FPP
Multi-Mode Fibre
Not Used
IDF3 to Room P7
P7-1
HCC1/ Port1
SPP1
Cat 5e UTP
Used
IDF3 to Room P7
P7-2
HCC1/ Port2
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P7
P7-3
HCC1/ Port3
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P7
P7-4
HCC1/ Port1
TPP2
Cat 5e UTP
Used
IDF3 to Room P8
P8-1
HCC2/ Port4
SPP1
Cat 5e UTP
Used
IDF3 to Room P8
P8-2
HCC2/ Port5
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P8
P8-3
HCC2/ Port6
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P8
P8-4
HCC2/ Port2
TPP2
Cat 5e UTP
Used
IDF3 to Room P9
P9-1
HCC3/ Port7
SPP1
Cat 5e UTP
Used
IDF3 to Room P9
P9-2
HCC3/ Port8
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P9
P9-3
HCC3/ Port9
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P9
P9-4
HCC3/ Port3
TPP2
Cat 5e UTP
Used
IDF3 to Room P10
P10-1
HCC4/ Port10
SPP1
Cat 5e UTP
Used
IDF3 to Room P10
P10-2
HCC4/ Port11
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P10
P10-3
HCC4/ Port12
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P10
P10-4
HCC4/ Port4
TPP2
Cat 5e UTP
Used
IDF3 to Room P11
P11-1
HCC5/ Port13
SPP1
Cat 5e UTP
Used
IDF3 to Room P11
P11-2
HCC5/ Port14
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P11
P11-3
HCC5/ Port15
SPP1
Cat 5e UTP
Not Used
IDF3 to Room P11
P11-4
HCC5/ Port5
TPP2
Cat 5e UTP
Used
IDF3 to North Building Classroom
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF3 to Room NB12
NB12-1
HCC6/ Port16
SPP1
Cat 5e UTP
Used
IDF3 to Room NB12
NB12-2
HCC6/ Port17
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB12
NB12-3
HCC6/ Port18
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB12
NB12-4
HCC6/ Port6
TPP2
Cat 5e UTP
Used
IDF3 to Room NB13
NB13-1
HCC7/ Port19
SPP1
Cat 5e UTP
Used
IDF3 to Room NB13
NB13-1
HCC7/ Port20
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB13
NB13-1
HCC7/ Port21
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB13
NB13-1
HCC7/ Port7
TPP2
Cat 5e UTP
Used
IDF3 to Room NB14
NB14-1
HCC8/ Port22
SPP1
Cat 5e UTP
Used
IDF3 to Room NB14
NB14-1
HCC8/ Port23
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB14
NB14-1
HCC8/ Port24
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB14
NB14-1
HCC8/ Port8
TPP2
Cat 5e UTP
Used
IDF3 to Room NB15
NB15-1
HCC9/ Port25
SPP1
Cat 5e UTP
Used
IDF3 to Room NB15
NB15-1
HCC9/ Port26
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB15
NB15-1
HCC9/ Port27
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB15
NB15-1
HCC9/ Port9
TPP2
Cat 5e UTP
Used
IDF3 to Room NB16
NB16-1
HCC10/ Port28
SPP1
Cat 5eUTP
Used
IDF3 to Room NB16
NB16-1
HCC10/ Port29
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB16
NB16-1
HCC10/ Port30
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB16
NB16-1
HCC10/ Port10
TPP2
Cat 5e UTP
Used
IDF3 to Room NB17
NB17-1
HCC11/ Port31
SPP1
Cat 5e UTP
Used
IDF3 to Room NB17
NB17-1
HCC11/ Port32
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB17
NB17-1
HCC11/ Port33
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB17
NB17-1
HCC11/ Port11
TPP2
Cat 5e UTP
Used
Connection
Cable ID
Cross Connection Paired #
Cross Connection Ports #
Cable Type
Status
IDF3 to Room NB18
NB18-1
HCC12/ Port34
SPP1
Cat 5e UTP
Used
IDF3 to Room NB18
NB18-1
HCC12/ Port35
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB18
NB18-1
HCC12/ Port36
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB18
NB18-1
HCC12/ Port12
TPP2
Cat 5e UTP
Used
IDF3 to Room NB19
NB19-1
HCC13/ Port37
SPP1
Cat 5e UTP
Used
IDF3 to Room NB19
NB19-2
HCC13/ Port38
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB19
NB19-3
HCC13/ Port39
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB19
NB19-4
HCC13/ Port13
TPP2
Cat 5e UTP
Used
IDF3 to Room NB20
NB20-1
HCC14/ Port40
SPP1
Cat 5e UTP
Used
IDF3 to Room NB20
NB20-2
HCC14/ Port41
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB20
NB20-3
HCC14/ Port42
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB20
NB20-4
HCC14/ Port14
TPP2
Cat 5e UTP
Used
IDF3 to Room NB22
NB22-1
HCC15/ Port43
SPP1
Cat 5e UTP
Used
IDF3 to Room NB22
NB22-2
HCC15/ Port44
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB22
NB22-3
HCC15/ Port45
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB22
NB22-4
HCC15/ Port15
TPP2
Cat 5e UTP
Used
IDF3 to Room NB23
NB23-1
HCC16/ Port46
SPP1
Cat 5e UTP
Used
IDF3 to Room NB23
NB23-2
HCC16/ Port47
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB23
NB23-3
HCC16/ Port48
SPP1
Cat 5e UTP
Not Used
IDF3 to Room NB23
NB23-4
HCC16/ Port16
TPP2
Cat 5e UTP
Used
IDF3 to Room NB26
NB26-1
HCC17/ Port1
SPP2
Cat 5e UTP
Used
IDF3 to Room NB26
NB26-2
HCC17/ Port2
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB26
NB26-3
HCC17/ Port3
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB26
NB26-4
HCC17/ Port17
TPP2
Cat 5e UTP
Used
IDF3 to Room NB27
NB27-1
HCC18/ Port4
SPP2
Cat 5e UTP
Used
IDF3 to Room NB27
NB27-2
HCC18/ Port5
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB27
NB27-3
HCC18/ Port6
SPP2
Cat 5e UTP
Not Used
IDF3 to Room NB27
NB27-4
HCC18/ Port18
TPP2
Cat 5e UTP
Used
2) South Building IDF
Cut Sheet 3. IDF2 South Building) – Location
Room SB9
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF2 South Building to MDF
IDF2-1
VCC1/ Port 1
FPP
Multi-mode Fibre
Used
IDF2 South Building to MDF
IDF2-2
VCC1/ Port 2
FPP
Multi-mode Fibre
Not Used
IDF2 South Building to MDF
IDF2-3
VCC2/ Port 3
FPP
Multi-mode Fibre
Used
IDF2 South Building to MDF
IDF2-4
VCC2/ Port 4
FPP
Multi-mode Fibre
Not Used
IDF2 to Portable Classroom
IDF2 to Room P1
P1-1
HCC1/ Port1
SPP1
Cat 5e UTP
Used
IDF2 to Room P1
P1-2
HCC1/ Port2
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P1
P1-3
HCC1/ Port3
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P1
P1-4
HCC1/ Port1
TPP
Cat 5e UTP
Used
IDF2 to Room P2
P2-1
HCC2/ Port4
SPP1
Cat 5e UTP
Used
IDF2 to Room P2
P2-2
HCC2/ Port5
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P2
P2-3
HCC2/ Port6
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P2
P2-4
HCC2/ Port2
TPP
Cat 5e UTP
Used
IDF2 to Room P3
P3-1
HCC3/ Port7
SPP1
Cat 5e UTP
Used
IDF2 to Room P3
P3-2
HCC3/ Port8
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P3
P3-3
HCC3/ Port9
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P3
P3-4
HCC3/ Port3
TPP
Cat 5e UTP
Used
IDF2 to Room P4
P4-1
HCC4/ Port10
SPP1
Cat 5e UTP
Used
IDF2 to Room P4
P4-2
HCC4/ Port11
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P4
P4-3
HCC4/ Port12
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P4
P4-4
HCC4/ Port4
TPP
Cat 5e UTP
Used
IDF2 to Room P5
P5-1
HCC5/ Port13
SPP1
Cat 5e UTP
Used
IDF2 to Room P5
P5-2
HCC5/ Port14
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P5
P5-3
HCC5/ Port15
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P5
P5-4
HCC5/ Port5
TPP
Cat 5e UTP
Used
IDF2 to Room P6
P6-1
HCC6/ Port16
SPP1
Cat 5e UTP
Used
IDF2 to Room P6
P6-2
HCC6/ Port17
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P6
P6-3
HCC6/ Port18
SPP1
Cat 5e UTP
Not Used
IDF2 to Room P6
P6-4
HCC6/ Port6
TPP
Cat 5e UTP
Used
IDF2 to South Building Classroom
IDF2 to Room SB10
SB10-1
HCC7/ Port19
SPP1
Cat 5e UTP
Used
IDF2 to Room SB10
SB10-1
HCC7/ Port20
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB10
SB10-1
HCC7/ Port21
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB10
SB10-1
HCC7/ Port7
TPP
Cat 5e UTP
Used
IDF2 to Room SB11
SB11-1
HCC8/ Port22
SPP1
Cat 5e UTP
Used
IDF2 to Room SB11
SB11-1
HCC8/ Port23
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB11
SB11-1
HCC8/ Port24
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB11
SB11-1
HCC8/ Port8
TPP
Cat 5e UTP
Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port25
SPP1
Cat 5e UTP
Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port26
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port27
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB12
SB12 -1
HCC9/ Port9
TPP
Cat 5e UTP
Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port28
SPP1
Cat 5e UTP
Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port29
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port30
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB13
SB13 -1
HCC10/ Port10
TPP
Cat 5e UTP
Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port31
SPP1
Cat 5e UTP
Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port32
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port33
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB14
SB14 -1
HCC11/ Port11
TPP
Cat 5e UTP
Used
Connection
Cable ID
Cross Connection Paired # Port#
Patch Panel
Cable Type
Status
IDF2 to Room SB15
SB15 -1
HCC12/ Port34
SPP1
Cat 5e UTP
Used
IDF2 to Room SB15
SB15 -1
HCC12/ Port35
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB15
SB15 -1
HCC12/ Port36
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB15
SB15 -1
HCC12/ Port12
TPP
Cat 5e UTP
Used
IDF2 to Room SB16
SB16-1
HCC13/ Port37
SPP1
Cat 5e UTP
Used
IDF2 to Room SB16
SB16-2
HCC13/ Port38
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB16
SB16-3
HCC13/ Port39
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB16
SB16-4
HCC13/ Port13
TPP
Cat 5e UTP
Used
IDF2 to Room SB18
SB18-1
HCC14/Port40
SPP1
Cat 5e UTP
Used
IDF2 to Room SB18
SB18-2
HCC14/Port41
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB18
SB18-3
HCC14/Port42
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB18
SB18-4
HCC14/Port14
TPP
Cat 5e UTP
Used
IDF2 to Room SB19
SB19-1
HCC15/ Port43
SPP1
Cat 5e UTP
Used
IDF2 to Room SB19
SB19-2
HCC15/ Port44
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB19
SB19-3
HCC15/ Port45
SPP1
Cat 5e UTP
Not Used
IDF2 to Room SB19
SB19-4
HCC15/ Port15
TPP
Cat 5e UTP
Used
IDF2 to Room SB20
SB20-1
HCC16/ Port1
SPP2
Cat 5e UTP
Used
IDF2 to Room SB20
SB20-2
HCC16/ Port2
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB20
SB20-3
HCC16/ Port3
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB20
SB20-4
HCC16/ Port16
TPP
Cat 5e UTP
Used
IDF2 to Room SB21
SB21-1
HCC17/ Port4
SPP2
Cat 5e UTP
Used
IDF2 to Room SB21
SB21-2
HCC17/ Port5
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB21
SB21-3
HCC17/ Port6
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB21
SB21-4
HCC17/ Port18
TPP
Cat 5e UTP
Used
IDF2 to Room SB22
SB22-1
HCC18/ Port7
SPP2
Cat 5e UTP
Used
IDF2 to Room SB22
SB22-2
HCC18/ Port8
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB22
SB22-3
HCC18/ Port9
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB22
SB22-4
HCC18/ Port19
TPP
Cat 5e UTP
Used
IDF2 to Room SB23
SB23-1
HCC19/ Port10
SPP2
Cat 5e UTP
Used
IDF2 to Room SB23
SB23-2
HCC19/ Port11
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB23
SB23-3
HCC19/ Port12
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB23
SB23-4
HCC19/ Port20
TPP
Cat 5e UTP
Used
IDF2 to Room SB24
SB24-1
HCC20/ Port13
SPP2
Cat 5e UTP
Used
IDF2 to Room SB24
SB24-2
HCC20/ Port14
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB24
SB24-3
HCC20/ Port15
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB24
SB24-4
HCC20/ Port21
TPP
Cat 5e UTP
Used
IDF2 to Room SB25
SB25-1
HCC21/ Port16
SPP2
Cat 5e UTP
Used
IDF2 to Room SB25
SB25-2
HCC21/ Port16
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB25
SB25-3
HCC21/ Port18
SPP2
Cat 5e UTP
Not Used
IDF2 to Room SB25
SB25-4
HCC21/ Port22
TPP
Cat 5e UTP
Used
· Media centre IDF
Cut Sheet2. IDF1 Media Centre) – Location
Room MC8
Connection
Cable ID
Cross Connection Paired # Port #
Patch Panel
Cable Type
Status
IDF1 Media Centre to MDF
IDF1-1
VCC1/ Port 1
FPP
Mutli-mode Fibre
Used
IDF1 Media Centre to MDF
IDF1-2
VCC1/ Port 2
FPP
Mutli-mode Fibre
Not Used
IDF1 to Room MC1
MC1-1
HCC1/ Port 1
SPP
Cat 5e UTP
Used
IDF1 to Room MC1
MC1-2
HCC1/ Port 2
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC1
MC1-3
HCC1/ Port 3
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC1
MC1-4
HCC1/ Port1
TPP
Cat 5e UTP
Used
IDF1 to room MC3
MC3-1
HCC2/ Port 4
SPP
Cat 5e UTP
Used
IDF1 to room MC3
MC3-2
HCC2/ Port5
SPP
Cat 5e UTP
Not Used
IDF1 to room MC3
MC3-3
HCC2/ Port6
SPP
Cat 5e UTP
Not Used
IDF1 to room MC3
MC3-4
HCC2/ Port2
TPP
Cat 5e UTP
Used
IDF1 to Room MC4
MC4-1
HCC2/ Port7
SPP
Cat 5e UTP
Used
IDF1 to Room MC4
MC4-2
HCC3/ Port8
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC4
MC4-3
HCC3/ Port9
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC4
MC4-4
HCC3/ Port3
TPP
Cat 5e UTP
Used
IDF1 to Room MC6
MC6-1
HCC4 /Port 10
SPP
Cat 5e UTP
Used
IDF1 to Room MC6
MC6-2
HCC4 /Port11
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC6
MC6-3
HCC4 /Port12
SPP
Cat 5e UTP
Not Used
IDF1 to Room MC6
MC6-4
HCC4 /Port4
TPP
Cat 5e UTP
Used
· Classroom cabinet and POP connection
In each classroom, there will be a lockable cabinet to house a patch panel, a switch and to act as the POP connection. The appropriate size for the cabinet will around 30cm*40cm* 70cm*. Here are some options from Hallam ECCO Wall Mount Cabinet and the model with size of 6 RU will be quite proper for our case.
·
6. Reference:
http://www.hp.com/cgi-bin/sbso/buyguides/tsg_product_select.cgi#Domain%20controller
http://h10010.www1.hp.com/wwpc/pscmisc/vac/us/en/sm/proliant/proliant-dl.html?jumpid=re_R295_prodexp/busproducts/computing-server/proliant-dl&psn=servers
http://www.cisco.com/en/US/prod/collateral/routers/ps9343/data_sheet_c78-447652.html
http://www.cisco.com/en/US/products/ps9436/index.html
www.pc.pcconnection.com/1/1/221402-cisco-asr1002-aggregation-services-router-chassis-dual-p-s-2u.html
http://www.cisco.com/en/US/prod/collateral/switches/ps5718/ps4324/product_data_sheet09186a008033a3bd.html
http://www.cisco.com/en/US/prod/collateral/switches/ps5718/ps7077/product_data_sheet0900aecd805bbe67.html
http://www.cisco.com/en/US/prod/collateral/switches/ps5718/ps4324/product_data_sheet0900aecd801e7846.html
http://www.superwarehouse.com/Cisco_Catalyst_4506-E_Switch_Chassis_with_PoE/WS-C4506-E/p/1513616
http://sholl.com.au/Cabinets_Racks/ECCO_Wall_Cabinets.html
Friday, February 13, 2009
IIS 6.0 Resource Kit
This article describes the tools that are included with the Microsoft Internet Information Services (IIS) 6.0 Resource Kit Tools. The IIS 6.0 Resource Kit Tools can help you administer, secure, and manage IIS. You can use these tools to query log files, to deploy Secure Sockets Layer (SSL) certificates, to verify permissions, to troubleshoot problems, to migrate your server, to run stress tests, and more.
IIS Documentation
CustomAuth 1.0
The CustomAuth tool (CustomAuth.dll and CustomAuth.ini) provides a Web client authentication alternative to Basic authentication, to NTLM authentication, and to other authentication methods. The CustomAuth tool helps administrators create custom logon pages to collect user credentials. The CustomAuth tool also supports either manual logoffs or timeout-based logoffs.
IIS State.1.0
IISState (IISState.exe and IISState.log) can help you troubleshoot slow performance and application failures for applications that are running on IIS 6.0. IISState can also help you identify the causes of ASP0115 errors and errors that Dr. Watson detects
Log parse 2.1
Log Parser (LogParser.exe or LogParser.dll) supports different input formats, including all IIS log file formats. Log Parser also supports multiple output formats, such as text files and database tables. You can use Log Parser to filter entries, to convert log files to other formats, and to perform data mining.
Metabase Explorer 1.6
Metabase Explorer 1.6 (MBExplorer.exe) provides a graphical user interface (GUI) for viewing and for editing local and remote IIS metabase stores. You can also use Metabase Explorer to do the following:
Permissions verifier 1.0
Permissions Verifier (Permissions Verifier.js) provides sample XML configuration files that you can use to verify permissions on a server that is running IIS. You can use Permissions Verifier to define a group of tasks that verify permissions and administrator rights and to select the tasks to be performed at run time. You can also use Permissions Verifier to verify Access Control Lists (ACLs), to verify permissions for users and groups, and to make sure that permission issues do not cause Web server problems.
RemapUrl 1.0
RemapUrl (RemapUrl.ini and RemapUrl.dll) helps an administrator dynamically change the URL that a client requests. If the URL is local to the application pool, this action is transparent to the client. RemapUrl also supports conventional URL redirects and sending custom error messages.
TinyGet 5.2
TinyGet 5.2 (TinyGet.exe) is a command-line Hypertext Transfer Protocol (HTTP) client that supports multiple threads and looping. You can use TinyGet to test or to troubleshoot HTTP client-to-server communication. By using TinyGet, you can customize your test request by configuring many different factors, including the authentication method, the HTTP version, and the output format. You can also use scripts that specify looping and multithreading.
WebCapacity Analysis tools 5.2
Web Capacity Analysis Tool (WCAT) (Wcclient.exe and Wcctl.exe) is a tool for capacity testing and planning. You can use WCAT to test different server and network configurations by using custom-designed content and workload simulations. You can test servers that have single processors or multiple processors. You can also test servers that are connected to multiple networks
WFetch 1.3
WFetch (Wfetch.exe) is an HTTP client that has a GUI. You can use WFetch to test or to troubleshoot HTTP servers. WFetch displays the request and the response so that the communication can be easily understood. You can use WFetch to create HTTP requests that test the performance of new Web sites or of Web sites that contain new elements such as Active Server Pages (ASP) or wireless protocols. Because WFetch provides only HTTP connection information, you can analyze and troubleshoot HTTP performance issues faster by using WFetch than by running a Network Monitor trace.
IIS Documentation
CustomAuth 1.0
The CustomAuth tool (CustomAuth.dll and CustomAuth.ini) provides a Web client authentication alternative to Basic authentication, to NTLM authentication, and to other authentication methods. The CustomAuth tool helps administrators create custom logon pages to collect user credentials. The CustomAuth tool also supports either manual logoffs or timeout-based logoffs.
IIS State.1.0
IISState (IISState.exe and IISState.log) can help you troubleshoot slow performance and application failures for applications that are running on IIS 6.0. IISState can also help you identify the causes of ASP0115 errors and errors that Dr. Watson detects
Log parse 2.1
Log Parser (LogParser.exe or LogParser.dll) supports different input formats, including all IIS log file formats. Log Parser also supports multiple output formats, such as text files and database tables. You can use Log Parser to filter entries, to convert log files to other formats, and to perform data mining.
Metabase Explorer 1.6
Metabase Explorer 1.6 (MBExplorer.exe) provides a graphical user interface (GUI) for viewing and for editing local and remote IIS metabase stores. You can also use Metabase Explorer to do the following:
Permissions verifier 1.0
Permissions Verifier (Permissions Verifier.js) provides sample XML configuration files that you can use to verify permissions on a server that is running IIS. You can use Permissions Verifier to define a group of tasks that verify permissions and administrator rights and to select the tasks to be performed at run time. You can also use Permissions Verifier to verify Access Control Lists (ACLs), to verify permissions for users and groups, and to make sure that permission issues do not cause Web server problems.
RemapUrl 1.0
RemapUrl (RemapUrl.ini and RemapUrl.dll) helps an administrator dynamically change the URL that a client requests. If the URL is local to the application pool, this action is transparent to the client. RemapUrl also supports conventional URL redirects and sending custom error messages.
TinyGet 5.2
TinyGet 5.2 (TinyGet.exe) is a command-line Hypertext Transfer Protocol (HTTP) client that supports multiple threads and looping. You can use TinyGet to test or to troubleshoot HTTP client-to-server communication. By using TinyGet, you can customize your test request by configuring many different factors, including the authentication method, the HTTP version, and the output format. You can also use scripts that specify looping and multithreading.
WebCapacity Analysis tools 5.2
Web Capacity Analysis Tool (WCAT) (Wcclient.exe and Wcctl.exe) is a tool for capacity testing and planning. You can use WCAT to test different server and network configurations by using custom-designed content and workload simulations. You can test servers that have single processors or multiple processors. You can also test servers that are connected to multiple networks
WFetch 1.3
WFetch (Wfetch.exe) is an HTTP client that has a GUI. You can use WFetch to test or to troubleshoot HTTP servers. WFetch displays the request and the response so that the communication can be easily understood. You can use WFetch to create HTTP requests that test the performance of new Web sites or of Web sites that contain new elements such as Active Server Pages (ASP) or wireless protocols. Because WFetch provides only HTTP connection information, you can analyze and troubleshoot HTTP performance issues faster by using WFetch than by running a Network Monitor trace.
Wednesday, March 21, 2007
BIOS upgrade
The BIOS needs to be updated every few years when technology changes to accommodate the operation of new parts. The update is normally obtained from the maker of the computer, or in the case of a non-brand computer, from the maker of the motherboard or sometimes the BIOS maker itself. Before we get into the nitty gritty, here's some basic information you need to know.The BIOS (or basic input/output system) is software. In newer computers it exists on a special chip called CMOS (complementary metal oxide semiconductor). If the CMOS is a flash memory chip, it can be updated. So an older BIOS can be updated to a newer version. Most Pentium computers and some 486 PCs have these chips installed and can be updated. The BIOS contains all the technical information about key components of the computer like disk drives, keyboards and display settings. It also keeps track of the date and time. In recent years some computers required BIOS updates to make them better operate with plug and play features built into Windows. BIOS updates were also required to accommodate larger hard drives.Before you do anything to your BIOS, it's always a good idea to record the settings on a sheet of paper that can be kept in a safe place.The BIOS can normally be accessed when you start your computer. You may see a reference to "setup" when you turn your computer on. That's your opportunity to get into the BIOS. It usually requires the push of a function key, such as F10, to get access to it. That "F" key varies between computers.If a logo screen is displayed during the start up process instead, then you may want to check with your computer maker for a command to turn off that screen and display the start up information, which is listed when a computer is powered on.Now for the nitty gritty.To do a BIOS upgrade you need to figure out where to get a BIOS update program. Most computer makers such as IBM, Dell, Compaq and Packard Bell have these updates on their web sites. Support for older Packard Bell computers (which the reader has) is run by a company called Alorica at www.priorityonesupport.com. As with most PC maker sites, you need to sign up for free, to get access to the system updates. The site requires that you enter a five-digit Zip code. (Note to Canadians: you can circumvent this by typing "11111".)The BIOS updates are generally downloadable from these sites. Once downloaded to your hard drive, run the update program and you may be prompted to create a floppy disk, which can then be used to update the BIOS.
However some newer programs will do a BIOS upodate without the need to create a floppy disk (they are obsolete now). You just the run the update and the BIOS is updated after a reboot.In the event that your PC maker won't provide a BIOS update, you can often acquire one from the motherboard maker. You'll have to do some detective work to figure out what brand and model of motherboard is in the system that you have to update. If you bought your PC from a small shop, a manual for the motherboard is usually included with the system's documentation.For those that are a little flummoxed by all this, your local computer store can probably do the update for you for the price of an hour's labour.
However some newer programs will do a BIOS upodate without the need to create a floppy disk (they are obsolete now). You just the run the update and the BIOS is updated after a reboot.In the event that your PC maker won't provide a BIOS update, you can often acquire one from the motherboard maker. You'll have to do some detective work to figure out what brand and model of motherboard is in the system that you have to update. If you bought your PC from a small shop, a manual for the motherboard is usually included with the system's documentation.For those that are a little flummoxed by all this, your local computer store can probably do the update for you for the price of an hour's labour.
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