Analysis of performance parameters for wireless network using switching multiple access control method

The developments of wireless networks have directed to search for opportunities of a broad diversity of improved and new networking contributions. Wireless Asynchronous Transfer Mode (ATM) is a non-synchronous or random mode of transferring information. The advantages of circuit switching include dedicated connections and guaranteed traffic parameters and the benefits of packet switching are the efficiency at the physical layer and a more cost-effective design. ATM is the only protocol that offers the best of both communication methods. Although the Variable Bit-Rate (VBR) transmission presents a promising prospective of stable data quality, it is usually accompanied by network traffic overload and cell packet loss, which extensively weakens that potential. This work overcomes these concerns by developing a switching-based multiple access control model to improve the data transmission performance of wireless ATM. Therefore, this work discusses the effectiveness of the developed approach to minimize the cell packet losses and network traffic overload in wireless ATM. Three control access is processed; polling, token passing, and reservation algorithms for collision avoidance. The reservation stage reserves the data before sending, which includes two timeline intervals; a fixed-time reservation period, and variable data transmission interval. Using OPNET 10.5, the results show that the presented switching-based multiple access control model can achieve a throughput value of 98.3 %, data transmission delay of about 40.2 ms, and 0.024 % of packet losses during data transmission between the source and destination. It is demonstrated that the introduced method effectively transmits information without creating any network complexity and delay

Smart Secured Wireless ATM using Finger Print Recognition

Automated Teller Machines (ATMs) have become an essential part of the individual’s daily routine as it is utilized to change one’s existing ATM Personal Identification Number (PIN), check one’s amount balance and its most important function is to extract one’s money. Nowadays, the culprits have the latest technologies at their disposal, which aids them, to easily hack into the secured systems of the banks and collect the confidential information of the clients such as their ATM PINs, Card Details, etc., To counter that, fingerprint sensing incorporated with One Time Passwords (OTPs) has been suggested, as it is globally accepted that the fingerprints of every person are unique and different, while OTPs don’t hold its value like ATM PINs. This research is based on using Python Graphical User Interface (GUI) as the ATM screen. The innovation in this study exists in two ways. The first one is that OTPs will be sent via Python Graphical User Interface (GUI), on the client’s registered email address also (along with the client’s recorded phone number), so that OTPs can still be accessed in case of Subscriber Identity Modules (SIMs) lost. The second one is that including a Uniform Resource Allocator (URL: www.msbank.co.in) for online enrollments of the clients and producing Application Program Interfaces (APIs). The main idea is to first check the client’s fingerprints and then to verify the OTPs from our Admin-Password Protected Mongo Database. The involved algorithm also maintains a check that the same email address cannot be utilized again for registration.

VIRTUAL CIRCUITS THAT MAY BE �PERMANENT� TO MAKE M-BANKING APPLICATION AS A SUCCESS BANDWIDTH MANAGEMENT IS AN IMPORTANT ISSUE FOR ANALYSING VARIABLE SIZED PACKETS AND FRAMES

ATM provides functionality that is similar to bothcircuit switchingandpacket switchingnetworks: ATM usesasynchronoustime-division multiplexing, and encodes data into small, fixed-sizedpackets(ISO-OSIframes) calledcells.This differs from approaches such as theInternet ProtocolorEthernetthat use variable sized packets and frames. ATM uses aconnection-orientedmodel in which avirtual circuitmust be established between two endpoints before the actual data exchange begins. These virtual circuits may be permanent To make m-banking application a success bandwidth management is an important issue. The increased flexibility and mobility feature of wireless ATM and its bandwidth on demand function is motivating a large number of carriers towards deployment of the WATM networks. But there are certain issues which are required to be addressed in WATM. The issues are cost effective planning of network, location management and handover management

The Research on WLAN and its Traffic Characteristics

This paper illustrates the IEEE 802.11 WLAN, Bluetooth and wireless ATM, and then analyzes the structures and traffic characteristics of them. The traffic characteristics of these three kinds of WLAN are summarized.

Heterogeneous Wireless Networks Using a Wireless ATM Platform

Within the last two decades, the world of telecommunications has started to change at a rapid pace. Data traffic, where the information is transmitted in the form of packets and the flow of information is bursty rather than constant, now accounts for almost 40 to 60% of the traffic that is transmitted over the backbone telecommunication networks (Esmailzadeh, Nakagawa, & Jones, 2003). In addition to data traffic, video traffic (variable rate with real-time constraints) was made possible by low-cost video-digitizing equipment (Houssos et al., 2003).