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Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs)

Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs) Submission Title: MAC CTRB Parameters Issues Date Submitted: [9 July 2001] Source: [Mark E. Schrader] Company [Eastman Kodak Co.] Address [4545 E. River Rd., Rochester, NY 14650-0898]

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Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs)

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  1. Project: IEEE P802.15 Working Group for Wireless Personal Area Networks (WPANs) Submission Title: MAC CTRB Parameters Issues Date Submitted: [9 July 2001] Source: [Mark E. Schrader] Company [Eastman Kodak Co.] Address [4545 E. River Rd., Rochester, NY 14650-0898] Voice:[+1.716.781.9561], FAX: [+1.716.781.9733], E-Mail:[mark.e.schrader@kodak.com] Re: [IEEE 802.15.3 MAC] Abstract: QoS based Channel Time Request Block parameters are defined mathematically. Some issues and limits of the timing are defined and briefly discussed. QoS is shown to to simple from the PNC perspective when only allocated bandwidth is important.. Purpose: Channel Time Request Block parameters toward building a QoS algorithm. Notice: This document has been prepared to assist the IEEE P802.15. It is offered as a basis for discussion and is not binding on the contributing individual(s) or organization(s). The material in this document is subject to change in form and content after further study. The contributor(s) reserve(s) the right to add, amend or withdraw material contained herein. Release: The contributor acknowledges and accepts that this contribution becomes the property of IEEE and may be made publicly available by P802.15. Mark E. Schrader, Eastman Kodak Co.

  2. Document Overview • Propose the smallest set (3) of Channel Time Request Block (CTRB) parameters usable for QoS-based requests. • Define the parameters mathematically with variables that are usable by the channel time requestor. • Identify issues and solutions. Mark E. Schrader, Eastman Kodak Co.

  3. Variable Definitions • fd = bits per second of delivered data. • NB=bits of source buffer available to store the data to be communicated. • NMPDU = bits of the data portion of one packet of data. • NOH = Equivalent bits of overhead of one packet of data including: actual MAC header bits, slot guard times, PHY or PLCP overhead, etc., everything-but-data, etc. It simplifies the explanation to express this as an equivalent number of bits. Mark E. Schrader, Eastman Kodak Co.

  4. Definitions Continued • NE = Channel (PHY) encoding, bits per symbol • fs = Channel symbol rate, symbols per second. • Tbcn = Beacon Period Mark E. Schrader, Eastman Kodak Co.

  5. CTRB Parameter 1: Allocation Period • TAP = NB / fd • This is how often the NB buffer must be sent to get the desired delivered data rate fd. • This is the size of the source buffer divided by the desired data rate. Mark E. Schrader, Eastman Kodak Co.

  6. Relationships I • We need to send NP packets over the network in order to transmit one buffer: • NP = NB / NMPDU Assume an integer for simplicity. • NT = NMPDU + NOH, the total number of bits that would have to be sent over the network to cover both the data and the overhead. Mark E. Schrader, Eastman Kodak Co.

  7. CTRB Parameter 2: GTS Time Per Allocation Period • TGTS is the total time requested for GTS allocated in order to send one buffer of data. • TGTS = ( NP NT / NE fS ). • For the sending NP packets, • of equivalent size, NT = ( NMPDU + NOH ) • with a PHY encoding of NE bits per symbol • and a PHY symbol rate of fS. Mark E. Schrader, Eastman Kodak Co.

  8. Relationships 2 • 1 / ( NE fS ) is a constant as long as the symbol rate and encoding method is unchanged. • From before: NP = NB / NMPDU • Stating the obvious: NT and NP will also be constants if the transmit packet size and the transmit buffer size both remain constant. Mark E. Schrader, Eastman Kodak Co.

  9. CTRB Parameter 3: Desired (Maximum) GTS Time per Allocation Period • TDMG defines the maximum amount of GTS time per allocation period that a DEV is capable of using. TDMG > TGTS • If there is unused bandwidth, the extra channel bandwidth can be divided up among DEVs based on what they can actually use. • Allows channel utilization to be maximized. Mark E. Schrader, Eastman Kodak Co.

  10. CTRB Parameter 4: Maximum Allocation Delay • TMAD defines an allowable time jitter to the allocation of time slots by the piconet coordinator, PNC. • The maximum allocation delay starts before the end of the allocation period, but does not affect the PNC’s reference timing of the TAP period. It allows some variability in position of the GTS slot(s).. Mark E. Schrader, Eastman Kodak Co.

  11. TAP TGTS The TGTS (blue) time is the total amount of slot time that must be allocated by the PNC within the TMAD(green) time centered around the start of the TAP interval (vertical arrows). ½TMAD ½TMAD TMAD TMAD Mark E. Schrader, Eastman Kodak Co.

  12. Possible PNC Slot Allocations TMAD TAP Mark E. Schrader, Eastman Kodak Co.

  13. Proposed Fragmentation Policy • The PNC shall provide the GTS time in as few time slots as possible. The PNC may provide more GTS time than the amount requested. • The PNC shall create at least one slot for each distinct channel time request. Mark E. Schrader, Eastman Kodak Co.

  14. Proposed CTRB Structure Mark E. Schrader, Eastman Kodak Co.

  15. 1 1 2 Octets: 1 2 2 Stream index EPS status Allocation Period Target Address Minimum GTS Time Desired GTS Time CTRB field that exists in draft D0.8 CTRB field proposed in this proposal 1 CTRB field proposed in document 01/485 EPS Set 2 Maximum Allocation Delay Proposed CTRB Structure Mark E. Schrader, Eastman Kodak Co.

  16. Appendix 1 Comments and Issues Mark E. Schrader, Eastman Kodak Co.

  17. Issue 1: QoS Restrictions to Allocation • This is ISOC slot specification. • A request for a fixed offset from the beacon for low power devices, etc., will require different additional parameters to indicate that the time slot position is guaranteed with respect to the beacon. • If a QoS request defined both the a fixed delay from the beacon and a fixed rate, it would set the beacon period. Should this “super QoS” mode be allowed? Mark E. Schrader, Eastman Kodak Co.

  18. TMAD and the Beacon • If TMAD > TBCN + TGTS then the beacon will never interfere with the allocation of time slots • If TMAD is smaller than this interval, then the following slides apply. Mark E. Schrader, Eastman Kodak Co.

  19. Issue 2: Beacon & CAP Delays • Any PNC QoS strategy must take into account accommodating the beacon/CAP. The occurrence of the beacon plus the CAP could delay some or all of a member’s ISOC time slots beyond the requested interval, TAP. • The PNC must be able guarantee a limit to the size of the beacon and the CAP or QoS policies will breakdown. Mark E. Schrader, Eastman Kodak Co.

  20. TMAD The Beacon May Upset the timing of ISOC Slots TAP Delayed Interval Alternative 1 Start of TAP Beacon Alternative 2 Start of TAP Mark E. Schrader, Eastman Kodak Co.

  21. TAPAdjustment to Beacon Delay • How should the TAP be adjusted if the beacon forces the slot allocation to be late. Should the next allocation be early according to the current TAP interval (Alternative 1), or should it be late and sync off the most recent slot allocation (blue) (Alternative 2)? • The user could specify which alternative to use if we defined the QoS parameter switch. Mark E. Schrader, Eastman Kodak Co.

  22. Appendix 2 Data Rate Driven QoS Mark E. Schrader, Eastman Kodak Co.

  23. Requirements for Data Rate Only QoS • The transmit buffer is large enough to accept GTS slots anywhere in the superframe. • The amount of bandwidth only depends on the data rate required fd, the data rate available, and the amount of overhead. • TAP / TGTS = ( fd / fs ) / ( NT / NENMPDU ) • Define TMAD = 0xFFFF, which will be a special value indicating “anywhere in CFP”. Mark E. Schrader, Eastman Kodak Co.

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