Duration in L-SIG

Duration in L-SIG Authors: Date: 2010-05-17 Youhan Kim, et al.

Introduction • Bits in VHT-SIG are very precious resource to signal important system parameters • Length field in L-SIG is shown to already contain sufficient information to convey the duration of a VHT packet • Relying on L-SIG length field to convey the duration of a VHT packet is not compatible with L-SIG TXOP and GF preamble • However, both L-SIG TXOP and GF preamble are shown to have limited benefit • Reducing the number of bits in VHT-SIG (improve efficiency of every VHT packet) has greater benefit than L-SIG TXOP and GF preamble • Several options to protect the integrity of duration information in L-SIG are presented Youhan Kim, et al.

L-SIG Length Conveys Number of Symbols (1) • Similar to 11n, use L-SIG spoof rate of 6 Mbps for 11ac packets • 3 bytes / symbol • Long GI packet • 4 us / symbol • Legacy spoof symbols = L-SIG length / 3 bytes per symbol • VHT payload symbols = Legacy spoof symbols – VHT preamble symbols legacy spoof symbols = L-SIG length / 3 bytes per symbol 20 usec L preamble VHT preamble VHT Payload VHT payload symbols = legacy spoof symbols – VHT preamble symbols L-SIG spoof rate is fixed at 6 Mbps (3 bytes / symbol) Youhan Kim, et al.

L-SIG Length Conveys Number of Symbols (2) • Short GI packet • 3.6 us / VHT symbol • End of frame may not be aligned to a 4 us boundary • Legacy devices using L-SIG may find the end of the packet to occur up to 3.6 usec after the energy on the air has disappeared • But this is existing problem in 11n Short GI symbol time= 3.6 usec 3.6 * VHT symbols L preamble VHT preamble VHT Payload Remainder <= 3.6 usec Legacy spoof time = 4 usec per symbol * legacy spoof symbols L-SIG symbol time = 4.0 usec Legacy spoof symbols = L-SIG length / 3 Youhan Kim, et al.

Ambiguous End of Short GI Packets • L-SIG can only indicate time in units of 4 us • Two 3.6 us short GI boundaries may map to the same4 us normal GI boundary used by L-SIG • Option A: Use L-SIG length % 3 == 1 to select between the two • Option B: Use extra bit in the VHT-SIG to select between the two • Option C: Pad to the next 3.6 usec symbol if there is ambiguity Short GI packet with N symbols 3.6 3.6 3.6 Short GI packet with N+1 symbols 3.6 3.6 3.6 3.6 L-SIG spoof with M symbols 4 4 4 Youhan Kim, et al.

L-SIG TXOP • Optional feature in 11n • L-SIG length used to signal a duration that is longer than the actual frame duration • Starts with initial handshake • RTS/CTS using L-SIG TXOP is less efficient than legacy RTS/CTS • RTS/CTS using L-SIG TXOP must be sent using HT PPDU • Legacy RTS/CTS does not have HT preamble (16 us) • Legacy RTS/CTS can be heard by legacy devices are well • EIFS always triggered in legacy devices • Legacy devices at disadvantage in gaining channel access • L-SIG TXOP initiator should transmit CF-END frame using legacy rate after L-SIG TXOP protected sequence Youhan Kim, et al.

Usefulness of L-SIG TXOP (1/3) • Hidden node at receiver • L-SIG TXOP does not help L-SIG duration To B A L-SIG B Collision at B C To B C A B Youhan Kim, et al.

Usefulness of L-SIG TXOP (2/3) • Hidden node at transmitter • EIFS can protect normal transmit frame with response ACK or SIFS-based transmit bursting A Data to B Data to B With L-SIG TXOP B ACK ACK L-SIG duration L-SIG duration C Start EIFS Clear EIFS Start EIFS A Data to B Data to B Without L-SIG TXOP (Without RTS/CTS) C B ACK ACK A B Start EIFS Clear EIFS Start EIFS C A RTS Data to B Legacy PLCP Without L-SIG TXOP (With RTS/CTS) B CTS ACK HT PLCP MAC duration C Youhan Kim, et al.

Usefulness of L-SIG TXOP (3/3) • Hidden node at transmitter (cont’d) • Legacy RTS/CTS could be used to protect cases when EIFS is not sufficient to protect the response frame (e.g. RDG) With L-SIG TXOP A Data to B Data to B ACK Data to A B L-SIG duration L-SIG duration C C A B Start EIFS A RTS Data to B Legacy PLCP Without L-SIG TXOP CTS Data to A B HT PLCP MAC duration C Youhan Kim, et al.

11ac L-SIG TXOP Viewed by 11n Devices • 11ac L-SIG TXOP, if defined, is useful for 11ac devices only • 11ac packets are detected as 11a packets by 11n devices • Even L-SIG TXOP capable 11n devices will not be able to understand 11ac L-SIG TXOP packets • 11ac L-SIG TXOP now triggers EIFS for both 11a and 11n devices • We believe 11ac networks will be mostly heterogeneous • Do not see great benefit in a 11ac L-SIG TXOP mode addressing only 11ac devices Youhan Kim, et al.

L-SIG TXOP andEfficiency Improvement for 11ac • Between improving the efficiency of VHT packets and supporting L-SIG TXOP, we feel it is a better tradeoff to improve efficiency of every VHT packet • If VHT duration is not signaled again in VHT-SIG, then efficiency of every VHT packet is increased • 12 extra bits in VHT-SIG to signal other valuable system parameters or reduce VHT-SIG length • L-SIG TXOP has limited benefit • RTS/CTS or self-CTS is a better mechanism for cases relying heavily on NAV • Even L-SIG TXOP capable 11n devices not able to understand 11ac L-SIG TXOP • L-SIG TXOP is not a widely used feature • Not aware of any silicon vendor who has implemented and deployed L-SIG TXOP • Not aware of any customer who has enabled L-SIG TXOP • Not defining 11ac L-SIG TXOP does not prevent usage of 11n L-SIG TXOP • Devices may still choose to use 11n L-SIG TXOP for HT packets if desired Youhan Kim, et al.

11ac Green-Field Preamble • An 11ac GF preamble, if defined, may not have L-SIG • 11ac GF preamble will have limited usage because most 11ac networks will be heterogeneous networks • 11ac excludes operation in 2.4 GHz band. Mainly intended for operation in 5 GHz band • Widespread usage of 5 GHz band by 11n devices important for success of 11ac • Allows smooth transition from 11n to 11ac • 5 GHz band is indeed becoming more popular with 11n deployment • 11n GF preamble had limited usage in the field so far • Prefer to have single 11ac preamble type • Having separate GF preamble just for select few cases does not justify the effort and cost to support two different preamble types Youhan Kim, et al.

Robustness of Duration in L-SIG • Validity of L-SIG can be checked by • Parity (1 bit) • Rate = 6 Mbps (4 bits) • Reserved bit (1 bit) • If further improvement on robustness is desired • Option 1 • Accept VHT packet only if both VHT-SIG CRC and L-SIG parity passes • Option 2 • Include L-SIG length field (or the entire L-SIG) in the VHT-SIG CRC Youhan Kim, et al.

Simulation Results: Ch D • Definition • L-SIG pass: Parity pass, Rsvd bit = 1 Rate = 6 Mbps • VHT-SIG pass: VHT-SIG CRC pass • Both L-SIG and VHT-SIG passed: Can I trust duration to demodulate? • Green circle • Prob. of incorrect duration if signaled in VHT-SIG • Red circle • Prob. of incorrect duration if signaled in L-SIG: Option 1 (VHT CRC only covers VHT-SIG) • Blue circle • Prob. of incorrect duration if signaled in L-SIG: Option 2 (VHT CRC also covers L-SIG length) • L-SIG passed but VHT-SIG failed: Can I trust duration in L-SIG to defer TX? • Red star • Prob. of incorrect duration if VHT CRC only covers VHT-SIG • Blue star • Prob. of incorrect duration if VHT CRC only covers VHT-SIG Youhan Kim, et al.

Simulation Results: Ch B • Definition • L-SIG pass: Parity pass, Rsvd bit = 1 Rate = 6 Mbps • VHT-SIG pass: VHT-SIG CRC pass • Both L-SIG and VHT-SIG passed: Can I trust duration to demodulate? • Green circle • Prob. of incorrect duration if signaled in VHT-SIG • Red circle • Prob. of incorrect duration if signaled in L-SIG: Option 1 (VHT CRC only covers VHT-SIG) • Blue circle • Prob. of incorrect duration if signaled in L-SIG: Option 2 (VHT CRC also covers L-SIG length) • L-SIG passed but VHT-SIG failed: Can I trust duration in L-SIG to defer TX? • Red star • Prob. of incorrect duration if VHT CRC only covers VHT-SIG • Blue star • Prob. of incorrect duration if VHT CRC only covers VHT-SIG Youhan Kim, et al.

Observations • Option 1: VHT-SIG CRC covers only VHT-SIG • Improved L-SIG robustness compared to relying on L-SIG checks only (parity, rate, reserved bit) • When VHT-SIG CRC fails, lower probability of error in L-SIG length than option 2 • More reliable for deferring transmission when VHT-SIG CRC fails • Does not require change to CRC processing compared to 11n • Option 2: VHT-SIG CRC covers L-SIG length • Further improvement on the L-SIG length protection if needed Youhan Kim, et al.

Conclusions • Do not need to indicate VHT packet duration again in VHT-SIG • Length field in L-SIG already has sufficient information to signal the duration of a VHT packet • L-SIG TXOP and GF preamble not supported in 11ac • Both have limited benefit • Reducing the number of bits in VHT-SIG (improve efficiency of every VHT packet) has greater benefit • Does not prevent devices from using 11n L-SIG TXOP on HT packets if desired • Several options may be considered to protect the integrity of the duration information in L-SIG • Option 1 • Accept VHT packet only if both VHT-SIG CRC and L-SIG parity passes • Option 2 • Include L-SIG length field (or the entire L-SIG) in the VHT-SIG CRC computation Youhan Kim, et al.

Strawpoll • Do you support adding the following item into the specification framework document, 11-09/0992? • R3.2.X: The number of OFDM symbols in a VHT packet shall be computed using the length field in L-SIG. • Yes: • No: • Abstain: Youhan Kim, et al.

Duration in L-SIG

Duration in L-SIG

Presentation Transcript

Note Duration

Security SIG in MTS

Security SIG in MTS

Duration: min.

Note Duration

Rest Duration

Security SIG in MTS

EXERCISES IN PV & DURATION

Bond Duration

Duration

Security SIG in MTS

Duration

CA Course Duration in India

Sig Fig, Sci Not, F/L

Measurement Duration in IEEE802.11k

Duration in L-SIG

Duration in L-SIG

Presentation Transcript

Note Duration

Security SIG in MTS

Security SIG in MTS

Duration: min.

Note Duration

Rest Duration

Security SIG in MTS

EXERCISES IN PV &amp; DURATION

Bond Duration

Duration

Security SIG in MTS

Duration

CA Course Duration in India

Sig Fig, Sci Not, F/L

Measurement Duration in IEEE802.11k

EXERCISES IN PV & DURATION