000			02114cam a2200229 i 4500
005			20250227091754.0
008			120829s2013 enka b 001 0 eng
020			_a9781107014695
041			_aeng
082	0	0	_a621.3980151922 _bHAE/S
100	1		_aHaenggi, Martin,
245	1	0	_aStochastic Geometry for Wireless Networks
260			_aDelhi _bCambridge University Press _c2013
300			_axv, 284 p. :
505	8		_aMachine generated contents note: Part I. Point Process Theory: 1. Introduction; 2. Description of point processes; 3. Point process models; 4. Sums and products over point processes; 5. Interference and outage in wireless networks; 6. Moment measures of point processes; 7. Marked point processes; 8. Conditioning and Palm theory; Part II. Percolation, Connectivity and Coverage: 9. Introduction; 10. Bond and site percolation; 11. Random geometric graphs and continuum percolation; 12. Connectivity; 13. Coverage; Appendix: introduction to R.
520			_a"Covering point process theory, random geometric graphs and coverage processes, this rigorous introduction to stochastic geometry will enable you to obtain powerful, general estimates and bounds of wireless network performance and make good design choices for future wireless architectures and protocols that efficiently manage interference effects. Practical engineering applications are integrated with mathematical theory, with an understanding of probability the only prerequisite. At the same time, stochastic geometry is connected to percolation theory and the theory of random geometric graphs and accompanied by a brief introduction to the R statistical computing language. Combining theory and hands-on analytical techniques with practical examples and exercises, this is a comprehensive guide to the spatial stochastic models essential for modelling and analysis of wireless network performance"--
650		0	_aWireless communication systems _xMathematics.
650		0	_aStochastic models.
650		0	_aStochastic geometry.
650		7	_aTECHNOLOGY & ENGINEERING / Mobile & Wireless Communications.
942			_cBK
999			_c4057 _d4057