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Posts Tagged ‘IPv4’

Comparison/Difference of IPv4 and IPv6

Posted by Viral Sarvaiya on July 20, 2012

Key differences between IPv4 and IPv6.



Source and destination addresses are 32 bits (4 ytes) in length. Source and destination addresses are 128 bits (16 bytes) in length.
IPsec header support is optional. IPsec header support is required.
No identification of packet flow for prioritized delivery handling by routers is present within the IPv4 header. Packet flow identification for prioritized delivery handling by routers is present within the IPv6 header using the Flow Label field.
Fragmentation is performed by the sending host and at routers, slowing router performance. Fragmentation is performed only by the sending host.
Has no link-layer packet-size requirements and must be able to reassemble a 576-byte packet. Link layer must support a 1,280-byte packet and be able to reassemble a 1,500-byte packet.
Header includes a checksum. Header does not include a checksum.
Header includes options. All optional data is moved to IPv6 extension headers.
ARP uses broadcast ARP Request frames to resolve an IPv4 address to a link-layer address. ARP Request frames are replaced with multicast Neighbor Solicitation messages.
Internet Group Management Protocol (IGMP) is used to manage local subnet group membership. IGMP is replaced with Multicast Listener Discovery (MLD) messages.
ICMP Router Discovery is used to determine the IPv4 address of the best default gateway and is optional. ICMPv4 Router Discovery is replaced with ICMPv6 Router Solicitation and Router Advertisement messages, and it is required.
Broadcast addresses are used to send traffic to all nodes on a subnet. There are no IPv6 broadcast addresses. Instead, a linklocal scope all-nodes multicast address is used.
Must be configured either manually or through DHCP for IPv4. Does not require manual configuration or DHCP forIPv6.
Uses host address (A) resource records in the Domain Name System (DNS) to map host names to IPv4 addresses. Uses AAAA records in the DNS to map host names to IPv6 addresses.
Uses pointer (PTR) resource records in the IN-ADDR.ARPA DNS domain to map IPv4 addresses to host names. Uses pointer (PTR) resource records in the IP6.ARPA DNS domain to map IPv6 addresses to host names.

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Features of IPv6

Posted by Viral Sarvaiya on July 19, 2012

The following list summarizes the features of the IPv6 protocol:
1) New header format
2) Large address space
3) Stateless and stateful address configuration
4) IPsec header support required
5) Better support for prioritized delivery
6) New protocol for neighboring node interaction
7) Extensibility

1) New Header Format:
The IPv6 header has a new format that is designed to minimize header processing. This is achieved by moving both nonessential and optional fields to extension headers that are placed after the IPv6 header. The streamlined IPv6 header is more efficiently processed at intermediate routers. IPv4 headers and IPv6 headers are not interoperable. IPv6 is not a superset of functionality that is backward compatible with IPv4. A host or router must use an implementation of both IPv4 and IPv6 to recognize and process both header formats. The new default IPv6 header is only twice the size of the default IPv4 header, even though the number of bits in IPv6 addresses is four times larger than in IPv4 addresses.

2) Large Address Space:
IPv6 has 128-bit (16-byte) source and destination addresses. Although 128 bits can express over 3.4 ~ 1038 possible combinations, the large address space of IPv6 has been designed to allow for multiple levels of subnetting and address allocation, from the Internet backbone to the individual subnets within an organization. Even with all of the addresses currently assigned for use by hosts, plenty of addresses are available for future use. With a much larger number of available addresses, address-conservation techniques, such as the deployment of NATs, are no longer necessary.

3) Stateless and Stateful Address Configuration:
To simplify host configuration, IPv6 supports both stateful address configuration (such as address configuration in the presence of a DHCP for IPv6, or DHCPv6, server) and stateless address configuration (such as address and routing configuration in the absence of a DHCPv6 server). With stateless address configuration, hosts on a link automatically configure themselves with IPv6 addresses for the link (called link-local addresses), with IPv6 transition addresses, with addresses derived from prefixes advertised by local routers, and local subnet and default routes. Both stateless and stateful addressing can be used at the same time. Even in the absence of a router, hosts on the same link can automatically configure themselves with link-local addresses and communicate without manual configuration. Link-local addresses are autoconfigured within seconds, and communication with neighboring nodes on the link is possible immediately. In comparison, some IPv4 hosts using DHCP must wait a full minute before abandoning DHCP configuration and selfconfiguring an IPv4 address.

4) IPsec Header Support Required:
Support for the IPsec headers is an IPv6 protocol suite requirement. This requirement provides a standards-based solution for network protection needs and promotes interoperability between different IPv6 implementations. IPsec consists of two types of extension headers and a protocol to negotiate security settings. The Authentication header (AH) provides data integrity, data authentication, and replay protection for the entire IPv6 packet (excluding fields in the IPv6 header that must change in transit). The Encapsulating Security Payload (ESP) header and trailer provide data integrity, data authentication, data confidentiality, and replay protection for the ESP-encapsulated payload. The protocol typically used to negotiate IPsec security settings for unicast communication is the Internet Key Exchange (IKE) protocol. The requirement to process IPsec headers does not make IPv6 inherently more secure. IPv6 packets are not required to be protected with IPsec, and IPsec is not a requirement of an IPv6 deployment. Additionally, the IPv6 standards do not require an implementation to support any specific encryption methods, hashing methods, or negotiation protocol (such as IKE).

5) Better Support for Prioritized Delivery:
New fields in the IPv6 header define how traffic is handled and identified. Traffic is prioritized by using a Traffic Class field, which specifies a DSCP value just like IPv4. A Flow Label field in the IPv6 header allows routers to identify and provide special handling for packets that belong to a flow (a series of packets between a source and destination). Because the traffic is identified in the IPv6 header, support for prioritized delivery can be achieved even when the packet payload is encrypted with IPsec and ESP.

6) New Protocol for Neighboring Node Interaction:
The Neighbor Discovery protocol for IPv6 is a series of Internet Control Message Protocol for IPv6 (ICMPv6) messages that manages the interaction of neighboring nodes (nodes on the same link). Neighbor Discovery replaces and extends the combination of the Address Resolution Protocol (ARP) (broadcast-based), ICMPv4 Router Discovery, and ICMPv4 Redirect messages with efficient multicast and unicast Neighbor Discovery messages.

7) Extensibility:
IPv6 can easily be extended for new features by adding extension headers after the IPv6 header. Unlike options in the IPv4 header, which can support only 40 bytes of options, the size of IPv6 extension headers is constrained only by the size of the IPv6 packet.

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