%% You should probably cite draft-cardwell-ccwg-bbr instead of this I-D. @techreport{cardwell-iccrg-bbr-congestion-control-02, number = {draft-cardwell-iccrg-bbr-congestion-control-02}, type = {Internet-Draft}, institution = {Internet Engineering Task Force}, publisher = {Internet Engineering Task Force}, note = {Work in Progress}, url = {https://datatracker.ietf.org/doc/draft-cardwell-iccrg-bbr-congestion-control/02/}, author = {Neal Cardwell and Yuchung Cheng and Soheil Hassas Yeganeh and Ian Swett and Van Jacobson}, title = {{BBR Congestion Control}}, pagetotal = 66, year = 2022, month = mar, day = 7, abstract = {This document specifies the BBR congestion control algorithm. BBR ("Bottleneck Bandwidth and Round-trip propagation time") uses recent measurements of a transport connection's delivery rate, round-trip time, and packet loss rate to build an explicit model of the network path. BBR then uses this model to control both how fast it sends data and the maximum volume of data it allows in flight in the network at any time. Relative to loss-based congestion control algorithms such as Reno {[}RFC5681{]} or CUBIC {[}RFC8312{]}, BBR offers substantially higher throughput for bottlenecks with shallow buffers or random losses, and substantially lower queueing delays for bottlenecks with deep buffers (avoiding "bufferbloat"). BBR can be implemented in any transport protocol that supports packet-delivery acknowledgment. Thus far, open source implementations are available for TCP {[}RFC793{]} and QUIC {[}RFC9000{]}. This document specifies version 2 of the BBR algorithm, also sometimes referred to as BBRv2 or bbr2.}, }