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Original Article
Review of TCP Versions Using Selective Acknowledgment
Bhavika M. Gambhava1
Ashish K. Gor2
C. K. Bhensdadia3
Nikhil J. Kothari4
1 2 3 Department of Computer Engineering, Dharmsinh Desai University, Gujarat, India. 4 Department of Electronics & Communication, Dharmsinh Desai University, Gujarat, India.
Published Online: September-December 2025
Pages: 276-281
Cite this article
↗ https://www.doi.org/10.59256/indjcst.20250403044
References
1. Postel, J. (1981). "Transmission Control Protocol." RFC 793, Internet Engineering Task Force.
2. Mathis, M., Mahdavi, J., Floyd, S., & Romanow, A. (1996). "TCP Selective Acknowledgment Options." RFC 2018, Internet Engineering
Task Force.
3. Floyd, S., Mahdavi, J., Mathis, M., & Podolsky, M. (2000). RFC2883: An extension to the selective acknowledgement (SACK) option for
TCP.
4. Fall, K., & Floyd, S. (1996). "Simulation-based comparisons of Tahoe, Reno, and SACK TCP." ACM SIGCOMM Computer Communication
Review, 26(3), 5- 21.
5. Allman, M., Paxson, V., & Blanton, E. (2009). "TCP congestion control." RFC 5681, Internet Engineering Task Force.
6. Padhye, J., Firoiu, V., Towsley, D. F., & Kurose, J. F. (2002). Modeling TCP Reno performance: a simple model and its empirical
validation. IEEE/ACM transactions on Networking, 8(2), 133-145.
7. Floyd, S., Henderson, T., & Gurtov, A. (2004). "The NewReno modification to TCP's fast recovery algorithm." RFC 3782, Internet
Engineering Task Force.
8. Kothari, N., Gambhava, B., & Dasgupta, K. (2007). "Adaptive flow control: An extension to delayed fast recovery." 15th International
Conference on Advanced Computing and Communications (ADCOM 2007).
9. Gambhava, B., Kothari, N. & Dasgupta, K. (2010). "Analysis of RTO Caused by Retransmission Loss to Combat Channel Noise."
International Journal of Computer Applications.
10. Brakmo, L. S., & Peterson, L. L. (2002). "TCP Vegas: End to end congestion avoidance on a global Internet." IEEE Journal on
Selected areas in Communications, 13(8), 1465-1480.
11. Casetti, C., Gerla, M., Mascolo, S., Sanadidi, M. Y., & Wang, R. (2002). "TCP Westwood: Bandwidth estimation for enhanced transport
over wireless links." Proceedings of the 7th annual international conference on Mobile computing and networking, 287-297.
12. Xu, L., Harfoush, K., & Rhee, I. (2004). "Binary increase congestion control (BIC) for fast long-distance networks." IEEE INFOCOM 2004.
[13]Ha, S., Rhee, I., & Xu, L. (2008). "CUBIC: a new TCP-friendly high-speed TCP variant." ACM SIGOPS Operating Systems Review,
42(5), 64-74.
13. Tan, K., Song, J., Zhang, Q., & Sridharan, M. (2006). "A compound TCP approach for high-speed and long distance networks."
Proceedings of IEEE INFOCOM.
14. Liu, S., Başar, T., & Srikant, R. (2008). "TCP-Illinois: A loss-and delay-based congestion control algorithm for high-speed networks."
Performance Evaluation, 65(6-7), 417-440.
15. Gambhava, B., & Bhensdadia, C. (2018). "Discrete TCP: Differentiating Slow Start and Congestion Avoidance." International
Journal of Intelligent Engineering & Systems.
16. Gambhava, B., & Bhensdadia, C. (2023). “Mathematical modelling of packet transmission during reclamation period in NewReno
TCP and CTCP" International Journal of Internet Protocol Technology.
17. Lorincz, J., Klarin, Z., & Ožegović, J. (2021). A comprehensive overview of TCP congestion control in 5G networks: Research
challenges and future perspectives. Sensors, 21(13), 4510.
18. Zhou, J., Qiu, X., Li, Z., Li, Q., Tyson, G., Duan, J., & Wu, Q. (2022). A machine learning-based framework for dynamic selection of
congestion control algorithms. IEEE/ACM Transactions on Networking, 31(4), 1566-1581.
19. Hasan, H. H., & Alisa, Z. T. (2023). Effective IoT congestion control algorithm. Future Internet, 15(4), 136.
20. Sacco, A., Flocco, M., Esposito, F., & Marchetto, G. (2021, May). Owl: Congestion control with partially invisible networks via
reinforcement learning. In IEEE INFOCOM 2021-IEEE Conference on Computer Communications (pp. 1-10)
21. Shi, H., & Wang, J. (2023). Intelligent TCP congestion control policy optimization. Applied Sciences, 13(11), 6644.
22. Allman, M., Paxson, V., & Blanton, E. (2009). TCP congestion control (RFC 5681).
2. Mathis, M., Mahdavi, J., Floyd, S., & Romanow, A. (1996). "TCP Selective Acknowledgment Options." RFC 2018, Internet Engineering
Task Force.
3. Floyd, S., Mahdavi, J., Mathis, M., & Podolsky, M. (2000). RFC2883: An extension to the selective acknowledgement (SACK) option for
TCP.
4. Fall, K., & Floyd, S. (1996). "Simulation-based comparisons of Tahoe, Reno, and SACK TCP." ACM SIGCOMM Computer Communication
Review, 26(3), 5- 21.
5. Allman, M., Paxson, V., & Blanton, E. (2009). "TCP congestion control." RFC 5681, Internet Engineering Task Force.
6. Padhye, J., Firoiu, V., Towsley, D. F., & Kurose, J. F. (2002). Modeling TCP Reno performance: a simple model and its empirical
validation. IEEE/ACM transactions on Networking, 8(2), 133-145.
7. Floyd, S., Henderson, T., & Gurtov, A. (2004). "The NewReno modification to TCP's fast recovery algorithm." RFC 3782, Internet
Engineering Task Force.
8. Kothari, N., Gambhava, B., & Dasgupta, K. (2007). "Adaptive flow control: An extension to delayed fast recovery." 15th International
Conference on Advanced Computing and Communications (ADCOM 2007).
9. Gambhava, B., Kothari, N. & Dasgupta, K. (2010). "Analysis of RTO Caused by Retransmission Loss to Combat Channel Noise."
International Journal of Computer Applications.
10. Brakmo, L. S., & Peterson, L. L. (2002). "TCP Vegas: End to end congestion avoidance on a global Internet." IEEE Journal on
Selected areas in Communications, 13(8), 1465-1480.
11. Casetti, C., Gerla, M., Mascolo, S., Sanadidi, M. Y., & Wang, R. (2002). "TCP Westwood: Bandwidth estimation for enhanced transport
over wireless links." Proceedings of the 7th annual international conference on Mobile computing and networking, 287-297.
12. Xu, L., Harfoush, K., & Rhee, I. (2004). "Binary increase congestion control (BIC) for fast long-distance networks." IEEE INFOCOM 2004.
[13]Ha, S., Rhee, I., & Xu, L. (2008). "CUBIC: a new TCP-friendly high-speed TCP variant." ACM SIGOPS Operating Systems Review,
42(5), 64-74.
13. Tan, K., Song, J., Zhang, Q., & Sridharan, M. (2006). "A compound TCP approach for high-speed and long distance networks."
Proceedings of IEEE INFOCOM.
14. Liu, S., Başar, T., & Srikant, R. (2008). "TCP-Illinois: A loss-and delay-based congestion control algorithm for high-speed networks."
Performance Evaluation, 65(6-7), 417-440.
15. Gambhava, B., & Bhensdadia, C. (2018). "Discrete TCP: Differentiating Slow Start and Congestion Avoidance." International
Journal of Intelligent Engineering & Systems.
16. Gambhava, B., & Bhensdadia, C. (2023). “Mathematical modelling of packet transmission during reclamation period in NewReno
TCP and CTCP" International Journal of Internet Protocol Technology.
17. Lorincz, J., Klarin, Z., & Ožegović, J. (2021). A comprehensive overview of TCP congestion control in 5G networks: Research
challenges and future perspectives. Sensors, 21(13), 4510.
18. Zhou, J., Qiu, X., Li, Z., Li, Q., Tyson, G., Duan, J., & Wu, Q. (2022). A machine learning-based framework for dynamic selection of
congestion control algorithms. IEEE/ACM Transactions on Networking, 31(4), 1566-1581.
19. Hasan, H. H., & Alisa, Z. T. (2023). Effective IoT congestion control algorithm. Future Internet, 15(4), 136.
20. Sacco, A., Flocco, M., Esposito, F., & Marchetto, G. (2021, May). Owl: Congestion control with partially invisible networks via
reinforcement learning. In IEEE INFOCOM 2021-IEEE Conference on Computer Communications (pp. 1-10)
21. Shi, H., & Wang, J. (2023). Intelligent TCP congestion control policy optimization. Applied Sciences, 13(11), 6644.
22. Allman, M., Paxson, V., & Blanton, E. (2009). TCP congestion control (RFC 5681).
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