User's Manual
Table Of Contents
- Trademarks
- Statement of Conditions
- Federal Communications Commission (FCC) Compliance Notice: Radio Frequency Notice
- Canadian Department of Communications Compliance Statement
- CE Declaration of Conformity
- Contents
- Chapter 1 About This Manual
- Chapter 2 Introduction
- Chapter 3 Basic Installation and Configuration
- Observing Placement and Range Guidelines
- Default Factory Settings
- Understanding WG602 v2 Wireless Security Options
- Installing the 54 Mbps Wireless Access Point WG602 v2
- Two Ways to Log In to the WG602 v2
- Using the Basic IP Settings Options
- Understanding the Basic Wireless Settings
- Understanding Wireless Security Options
- How to Configure WEP Wireless Security
- How to Configure WPA-PSK Wireless Security
- How to Restrict Wireless Access by MAC Address
- Chapter 4 Management
- Chapter 5 Advanced Configuration
- Chapter 6 Troubleshooting
- Troubleshooting
- No lights are lit on the access point.
- The Ethernet LAN light is not lit.
- The Wireless LAN activity light is not lit.
- I cannot configure the wireless access point from a browser.
- I cannot access the Internet or the LAN with a wireless capable computer.
- When I enter a URL or IP address I get a timeout error.
- Using the Reset Button to Restore Factory Default Settings
- Troubleshooting
- Appendix A Specifications
- Appendix B Wireless Networking Basics
- Appendix C Network, Routing, Firewall, and Cabling Basics
- Appendix D Preparing Your PCs for Network Access
- Glossary
- Index
User’s Guide for the WG602 54 Mbps Wireless Access Point
C-4 Network, Routing, Firewall, and Cabling Basics
This addressing structure allows IP addresses to uniquely identify each physical network and each
node on each physical network.
For each unique value of the network portion of the address, the base address of the range (host
address of all zeros) is known as the network address and is not usually assigned to a host. Also,
the top address of the range (host address of all ones) is not assigned, but is used as the broadcast
address for simultaneously sending a packet to all hosts with the same network address.
Netmask
In each of the address classes previously described, the size of the two parts (network address and
host address) is implied by the class. This partitioning scheme can also be expressed by a netmask
associated with the IP address. A netmask is a 32-bit quantity that, when logically combined (using
an AND operator) with an IP address, yields the network address. For instance, the netmasks for
Class A, B, and C addresses are 255.0.0.0, 255.255.0.0, and 255.255.255.0, respectively.
For example, the address 192.168.170.237 is a Class C IP address whose network portion is the
upper 24 bits. When combined (using an AND operator) with the Class C netmask, as shown here,
only the network portion of the address remains:
11000000 10101000 10101010 11101101 (192.168.170.237)
combined with:
11111111 11111111 11111111 00000000 (255.255.255.0)
Equals:
11000000 10101000 10101010 00000000 (192.168.170.0)
As a shorter alternative to dotted-decimal notation, the netmask may also be expressed in terms of
the number of ones from the left. This number is appended to the IP address, following a backward
slash (/), as “/n.” In the example, the address could be written as 192.168.170.237/24, indicating
that the netmask is 24 ones followed by 8 zeros.
Subnet Addressing
By looking at the addressing structures, you can see that even with a Class C address, there are a
large number of hosts per network. Such a structure is an inefficient use of addresses if each end of
a routed link requires a different network number. It is unlikely that the smaller office LANs would
have that many devices. You can resolve this problem by using a technique known as subnet
addressing.