On the minimum latency transmission scheduling in wireless networks with power control under SINR constraints

Abstract: In order to alleviate interference and contention in a wireless network, we may exploit the existence of multiple orthogonal channels or time slots, thus achieving a substantial improvement in performance. In this paper, we study a joint transmission scheduling and power control problem that arises in wireless networks. The goal is to assign channels (or time slots) and transmitting powers to communication links such that all communication requests are processed correctly, specified quality-of-service requirem… Show more

“…The noise floor can be obtained by the well‐known thermal noise equation (Rappaport, ; Zamalloa and Krishnamachari, ) and the threshold β value is a hardware‐dependent constant that can be approximated from empirical experiments (Son et al., ; Zamalloa and Krishnamachari, ). The physical interference model has been used, for example, for wireless link scheduling (Jain et al., ; Goussevskaia et al., ), wireless link scheduling with power control (Fu et al., ; Katz et al., ; Gogu et al., ; Gong and Yang, ; Charalambous et al., ), and topology control (Moscibroda and Wattenhofer, ; Moscibroda et al., ; Gao et al., ; Zhang et al., ). The three interference models discussed in this section will be used in the next section to build exact formulations to solve the minimum interference problem.…”

Exact formulations for the minimum interference problem in k‐connected ad hoc wireless networks

“…The noise floor can be obtained by the well‐known thermal noise equation (Rappaport, ; Zamalloa and Krishnamachari, ) and the threshold β value is a hardware‐dependent constant that can be approximated from empirical experiments (Son et al., ; Zamalloa and Krishnamachari, ). The physical interference model has been used, for example, for wireless link scheduling (Jain et al., ; Goussevskaia et al., ), wireless link scheduling with power control (Fu et al., ; Katz et al., ; Gogu et al., ; Gong and Yang, ; Charalambous et al., ), and topology control (Moscibroda and Wattenhofer, ; Moscibroda et al., ; Gao et al., ; Zhang et al., ). The three interference models discussed in this section will be used in the next section to build exact formulations to solve the minimum interference problem.…”

Exact formulations for the minimum interference problem in k‐connected ad hoc wireless networks

Power-efficient and interference-free link scheduling algorithms for connected wireless sensor networks

Reduced power expenditure in the minimum latency transmission scheduling problem