- See also
- References
In mathematics of special functions, the Neuman–Sándor mean M, of two positive and unequal numbers a and b, is defined as:
This mean interpolates the inequality of the unweighted arithmetic mean A = (a + b)/2) and of the second Seiffert mean T defined as:
so that A < M < T.
The M(a,b) mean, introduced by Edward Neuman and József Sándor,[1] has recently been the subject of intensive research and many remarkable inequalities for this mean can be found in the literature.[2] Several authors obtained sharp and optimal bounds for the Neuman–Sándor mean.[3][4][5][6][7] Neuman and others utilized this mean to study other bivariate means and inequalities.[8][9][10][11][12]
See also
- Mean
- Arithmetic mean
- Geometric mean
- Stolarsky mean
- Identric mean
- Means in Mathematical Analysis[13]
References
1. ^E. Neuman & J. Sándor. On the Schwab–Borchardt mean, Math Pannon. 14(2) (2003), 253–266. http://www.kurims.kyoto-u.ac.jp/EMIS/journals/MP/index_elemei/mp14-2/mp14-2-253-266.pdf
2. ^Tiehong Zhao, Yuming Chu and Baoyu Liu. Some Best Possible Inequalities Concerning Certain Bivariate Means. October 15, 2012. https://arxiv.org/pdf/1210.4219.pdf
3. ^Wei-Dong Jiang & Feng Qi. Sharp bounds for the Neuman-Sándor mean in terms of the power and contraharmonic means. January 9, 2015. https://www.cogentoa.com/article/10.1080/23311835.2014.995951
4. ^Hui Sun, Tiehong Zhao, Yuming Chu and Baoyu Liu. A note on the Neuman-Sándor mean. J. of Math. Inequal. dx.doi.org/10.7153/jmi-08-20
5. ^Huang, HY., Wang, N. & Long, BY. Optimal bounds for Neuman–Sándor mean in terms of the geometric convex combination of two Seiffert means. J Inequal Appl (2016) 2016: 14. https://doi.org/10.1186/s13660-015-0955-2
6. ^Chu, YM., Long, BY., Gong, WM. et al. Sharp bounds for Seiffert and Neuman-Sándor means in terms of generalized logarithmic means. J Inequal Appl (2013) 2013: 10. https://doi.org/10.1186/1029-242X-2013-10
7. ^Tie-Hong Zhao, Yu-Ming Chu, and Bao-Yu Liu, “Optimal Bounds for Neuman-Sándor Mean in Terms of the Convex Combinations of Harmonic, Geometric, Quadratic, and Contraharmonic Means,” Abstract and Applied Analysis, vol. 2012, Article ID 302635, 9 pages, 2012. doi:10.1155/2012/302635
8. ^E. Neuman, Inequalities for weighted sums of powers and their applications, Math. Inequal. Appl. 15 (2012), No. 4, 995–1005.
9. ^E. Neuman, A note on a certain bivariate mean, J. Math. Inequal. 6 (2012), No. 4, 637–643
10. ^Y.-M. Li, B.-Y. Long and Y.-M. Chu.Sharp bounds for the Neuman-Sándor mean in terms of generalized logarithmic mean. J. Math. Inequal. 6, 4(2012), 567-577
11. ^E. Neuman, A one-parameter family of bivariate mean, J. Math. Inequal. 7 (2013), No. 3, 399–412
12. ^E. Neuman, Sharp inequalities involving Neuman–Sándor and logarithmic means, J. Math. Inequal. 7 (2013), No. 3, 413–419
13. ^Gheorghe Toader and Iulia Costin. 2017. Means in Mathematical Analysis: Bivariate Means. 1st Edition. Academic Press. eBook {{ISBN|9780128110812}}, Paperback {{ISBN|9780128110805}}. https://www.elsevier.com/books/means-in-mathematical-analysis/toader/978-0-12-811080-5
{{DEFAULTSORT:Neuman-Sándor mean}}{{Statistics-stub}}2. ^Tiehong Zhao, Yuming Chu and Baoyu Liu. Some Best Possible Inequalities Concerning Certain Bivariate Means. October 15, 2012. https://arxiv.org/pdf/1210.4219.pdf
3. ^Wei-Dong Jiang & Feng Qi. Sharp bounds for the Neuman-Sándor mean in terms of the power and contraharmonic means. January 9, 2015. https://www.cogentoa.com/article/10.1080/23311835.2014.995951
4. ^Hui Sun, Tiehong Zhao, Yuming Chu and Baoyu Liu. A note on the Neuman-Sándor mean. J. of Math. Inequal. dx.doi.org/10.7153/jmi-08-20
5. ^Huang, HY., Wang, N. & Long, BY. Optimal bounds for Neuman–Sándor mean in terms of the geometric convex combination of two Seiffert means. J Inequal Appl (2016) 2016: 14. https://doi.org/10.1186/s13660-015-0955-2
6. ^Chu, YM., Long, BY., Gong, WM. et al. Sharp bounds for Seiffert and Neuman-Sándor means in terms of generalized logarithmic means. J Inequal Appl (2013) 2013: 10. https://doi.org/10.1186/1029-242X-2013-10
7. ^Tie-Hong Zhao, Yu-Ming Chu, and Bao-Yu Liu, “Optimal Bounds for Neuman-Sándor Mean in Terms of the Convex Combinations of Harmonic, Geometric, Quadratic, and Contraharmonic Means,” Abstract and Applied Analysis, vol. 2012, Article ID 302635, 9 pages, 2012. doi:10.1155/2012/302635
8. ^E. Neuman, Inequalities for weighted sums of powers and their applications, Math. Inequal. Appl. 15 (2012), No. 4, 995–1005.
9. ^E. Neuman, A note on a certain bivariate mean, J. Math. Inequal. 6 (2012), No. 4, 637–643
10. ^Y.-M. Li, B.-Y. Long and Y.-M. Chu.Sharp bounds for the Neuman-Sándor mean in terms of generalized logarithmic mean. J. Math. Inequal. 6, 4(2012), 567-577
11. ^E. Neuman, A one-parameter family of bivariate mean, J. Math. Inequal. 7 (2013), No. 3, 399–412
12. ^E. Neuman, Sharp inequalities involving Neuman–Sándor and logarithmic means, J. Math. Inequal. 7 (2013), No. 3, 413–419
13. ^Gheorghe Toader and Iulia Costin. 2017. Means in Mathematical Analysis: Bivariate Means. 1st Edition. Academic Press. eBook {{ISBN|9780128110812}}, Paperback {{ISBN|9780128110805}}. https://www.elsevier.com/books/means-in-mathematical-analysis/toader/978-0-12-811080-5
2 : Means|Special functions
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