Compact dual-band antenna for wireless access point

A compact dual-band printed antenna covering the 2.4 GHz (2400-2485 MHz) and 5.2 GHz (5150-5350 MHz) WLAN bands is presented. The experimental analysis shows a 2:1 VSWR bandwidth of up to 32 and 8% for 2.4 and 5.2 GHz, respectively. The measured radiation patterns are nearly omnidirectional, with moderate gain in both the WLAN bands.

Access Point Association Coordination in Densely Deployed 802.11 Wireless Networks

Dense deployment of wireless local area network (WLAN) access points (APs) is an important part of the next generation Wi-Fi and standardization (802.11ax) efforts are underway. Increasing demand for WLAN connectivity motivates such dense deployments, especially in geographical areas with large numbers of users, such as stadiums, large enterprises, multi-tenant buildings, and urban cities. Although densification of WLAN APs guarantees coverage, it is susceptible to increased interference and uncoordinated association of stations (STAs) to APs, which degrade network throughput. Therefore, to improve network throughput, algorithms are proposed in this thesis to optimally coordinate AP associations in the presence of interference. In essence, coordination of APs in dense WLANs (DWLANs) is achieved through coordination of STAs' associations with APs. While existing approaches suggest tuning of APs' beacon powers or using transmit power control (TPC) for association control, here, the signal-to-interference-plus-noise ratio (SINRs) of STAs and the clear channel assessment (CCA) threshold of the 802.11 MAC protocol are employed. The proposed algorithms in this thesis enhance throughput and minimize coverage holes inherent in cell breathing and TPC techniques by not altering the transmit powers of APs, which determine cell coverage. Besides uncoordinated AP associations, unnecessary frequent transmission deferment is envisaged as another problem in DWLANs due to the clear channel assessment aspect of the carrier sensing multiple access collision avoidance (CSMA/CA) scheme in 802.11 standards and the short spatial reuse distance between co-channel APs. To address this problem in addition to AP association coordination, an algorithm is proposed for CCA threshold adjustment in each AP cell, such that CCA threshold used in one cell mitigates transmission deferment in neighboring cells. Performance evaluation reveals that the proposed association optimization algorithms achieve significant gain in throughput when compared with the default strongest signal first (SSF) association scheme in the current 802.11 standard. Also, further gain in throughput is observed when the CCA threshold adjustment is combined with the optimized association. Results show that when STA-AP association is optimized and CCA threshold is adjusted in each cell, throughput improves. Finally, transmission delay and the number of packet re-transmissions due to collision and contention significantly decrease.

A low-profile dual-band antenna for a wireless LAN access point

The design of dual-band 2.45/5.2 GHz antenna for an acces point of a Wireless Local Area Network (LAN) is presented. The proposed antenna is formed by a Radial Line Slot Array (RLSA) operating at 2.4 GHz and a Microstrip patch working at 5.2 GHz, both featuring circular polarization. The design of this antenna system is accomplished using commercially available Finite Element software. High Frequency Structure Simulator (HFSS) of Ansoft and an in-house developed iteration procedure. The performance of the designed antenna is assessed in terms of return loss (RL), radiation pattern and polarization purity in the two frequency bands.

TCP a ritrasmissione asimmetrica anticipata su Access Point WiFi

La perdita di pacchetti durante una trasmissione su una rete Wireless influisce in maniera fondamentale sulla qualità del collegamento tra due End-System. Lo scopo del progetto è quello di implementare una tecnica di ritrasmissione asimmetrica anticipata dei pacchetti perduti, in modo da minimizzare i tempi di recupero dati e migliorare la qualità della comunicazione. Partendo da uno studio su determinati tipi di ritrasmissione, in particolare quelli implementati dal progetto ABPS, Always Best Packet Switching, si è maturata l'idea che un tipo di ritrasmissione particolarmente utile potrebbe avvenire a livello Access Point: nel caso in cui la perdita di pacchetti avvenga tra l'AP e il nodo mobile che vi è collegato via IEEE802.11, invece che attendere la ritrasmissione TCP e Effettuata dall'End-System sorgente è lo stesso Access Point che e effettua una ritrasmissione verso il nodo mobile per permettere un veloce recupero dei dati perduti. Tale funzionalità stata quindi concettualmente divisa in due parti, la prima si riferisce all'applicazione che si occupa della bufferizzazione di pacchetti che attraversano l'AP e della loro copia in memoria per poi ritrasmetterli in caso di segnalazione di mancata acquisizione, la seconda riguardante la modifica al kernel che permette la segnalazione anticipata dell'errore. E' già stata sviluppata un'applicazione che prevede una ritrasmissione anticipata da parte dell'Access Point Wifi, cioè una ritrasmissione prima che la notifica di avvenuta perdita raggiunga l'end-point sorgente e appoggiata su un meccanismo di simulazione di Error Detection. Inoltre è stata anche realizzata la ritrasmissione asincrona e anticipata del TCP. Questo documento tratta della realizzazione di una nuova applicazione che fornisca una più effciente versione del buffer di pacchetti e utilizzi il meccanismo di una ritrasmissione asimmetrica e anticipata del TCP, cioè attivare la ritrasmissione su richiesta del TCP tramite notifiche di validità del campo Acknowledgement.

Mapping di access point wifi su android: valutazione

Sviluppo di un'applicazione Android che effettua scansioni di reti Wi-Fi in una determinata area al fine di mappare tutti gli Access Point rilevabili.

Implementation of a novel credit based SCFQ scheduler for Broadband Wireless Access

A novel tag computation circuit for a credit based Self-Clocked Fair Queuing (SCFQ) Scheduler is presented. The scheduler combines Weighted Fair Queuing (WFQ) with a credit based bandwidth reallocation scheme. The proposed architecture is able to reallocate bandwidth on the fly if particular links suffer from channel quality degradation .The hardware architecture is parallel and pipelined enabling an aggregated throughput rate of 180 million tag computations per second. The throughput performance is ideal for Broadband Wireless Access applications, allowing room for relatively complex computations in QoS aware adaptive scheduling. The high-level system break-down is described and synthesis results for Altera Stratix II FPGA technology are presented.