1 / 14

SkyWay 4000 & 7000 QoS systems

SkyWay 4000 & 7000 QoS systems. David Gell VP Engineering. New Applications The Internet and private enterprise intranets have been evolving steadily over the last 5-10 years and are responsible for the effective communication of ever-growing applications.

addo
Télécharger la présentation

SkyWay 4000 & 7000 QoS systems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. SkyWay 4000 & 7000 QoS systems David Gell VP Engineering

  2. New Applications • The Internet and private enterprise intranets have been evolving steadily over the last 5-10 years and are responsible for the effective communication of ever-growing applications. • Three of the fastest growing are real time voice, video and wireless communication.

  3. Video • Tremendous gains in standardized video compression and IP conversion technologies has created an important, but difficult to implement purpose for IP networks – real time video transport. • Applications include CCTV and IP camera-based surveillance, video conferencing and video streaming. • While the technology to convert video to and from IP packets is highly standardized (e.g. – Motion JPEG, MPEG2, MPEG4, H.264), the ability to transport such IP packets in a timely manner has been left to other technologies.

  4. VoIP • International groups (ITU, IETF) have standardized a series of end-to-end protocols for IP based telephony. Such standards encompass and address necessary functions at OSI layer 4 and above (e.g. – H.323, SIP, RTP, H.245, G.711, G.72x) • Like with real-time video, the technology to convert voice to and from IP packets is highly standardized but the ability at layer 3 and below to deliver IP packets in a timely manner has been left to other technologies.

  5. The need for QoS… • It is clear that in both voice and video standardization, the means to assure timely and error free packet delivery is left to other, QoS technologies. • When combined with Broadband Wireless systems, it becomes clear that an effective mechanism is needed…

  6. PSTN Internet ‘Typical’ Enterprise BWA application Satellite Office A Main Site … … … … Satellite Office B … … In this example, how can VoIP intranet performance be properly managed?....

  7. Congested Networks • Despite gains in throughput performance, a long-distance, fixed wireless system can often become a network bottleneck during peak times of network usage. • At such times, latency and packet-loss sensitive payload, such as voice or video can suffer significant degradation.

  8. Priority Queuing • Conceptually simple, priority queuing uses multiple queues to allow higher priority traffic to ‘jump ahead’ of lower priority traffic. 6 5 4 3 2 1 Input traffic High Priority Queue Low Priority Queue 5 4 6 2 Output traffic 3 1 Priority Engine 5 4 6 2 3 1

  9. Priority Tagging • Multiple approaches are available to tag frames with desired priority: • Ethernet frame tagging (802.1q) Ethernet Frame PRE SFD Dest Addr. Src Addr TPID TCI Len Data FCS VID CFI Priority 3 bits: 0-7

  10. Priority Tagging, cont. • IP frame tagging via ToS (RFC 791) Ethernet Frame PRE SFD Dest Addr. Src Addr TPID TCI Len Data FCS IP Packet Vers IHL ToS Len Iden Flags Frag TTL Protocol H Cksm Src Dest Opt Data 3 priority bits: 0-7

  11. Priority Tagging, cont. • IP frame tagging via DiffServ (RFC 2474) • Redefines ToS byte as DS byte. Supercedes ToS definition Ethernet Frame PRE SFD Dest Addr. Src Addr TPID TCI Len Data FCS IP Packet Vers IHL DS Len Iden Flags Frag TTL Protocol H Cksm Src Dest Opt Data 6 priority bits: 0-63

  12. SkyWay 4000 + 7000 QoS Features • Priority Queuing System • 4 Queues. From highest priority to lowest: Voice, Video, Best Effort, Background • Line speed packet inspection supports the three most common tagging methods: 1) 802.1p VLAN tag priority bits 2) IP ToS field 3) IP Diffserv • Note: QoS requires end-to-end network support. SkyWay will prioritize traffic but will not actually tag the data. Endpoint devices/appliances are responsible for tagging data.

  13. SkyWay Queue mapping Voice Video Best Effort Background 802.1q bits: 0x6, 0x7 0x3, 0x4, 0x0 0x1, 0x2 0x5 IP ToS/Diffserv Byte: 0x30, 0xe0 0x28, 0x88, Default 0x08, 0x20 0xa0 Note: If a frame has multiple tags, then the tag with the highest priority will establish queue assignment

  14. SkyWay System Design for QoS • The SkyWay system provides support for QoS, but the proper, end-to-end network design is critical for QoS performance. • Tagging device: the closer to the data source the better. Ideally, the voice or video generation device itself will tag frames. Examples: Uniden VoIP phones Vbrick CCTV/IP converter Polycom Video Conferencing systems • QoS-enabled network. For best results all switches, routers and gateways should be QoS enabled.

More Related