Near Field Communication (NFC) allows communication between devices within close proximity using radio waves. NFC works through inductive coupling between loop antennas in devices operating at 13.56 MHz with data transfer rates from 106-424 Kbps. It can operate in both active and passive modes. NFC provides an easy and secure way to transfer data quickly by touching or bringing devices close together. Potential applications include mobile payments, ticketing, data sharing, and access control.
This document discusses NFC (Near Field Communication) technology. It explains that NFC allows short-range wireless communication when devices are tapped together from up to 20 centimeters. NFC uses magnetic field induction and operates at 13.56 MHz. Common applications include mobile payments, data sharing, and access control. The document outlines how NFC works, provides examples of its applications, and discusses its technical features and future potential.
Near Field Communication (NFC) is a short-range wireless technology that allows data exchange between devices when they are touched or brought within a few centimeters of each other. NFC uses magnetic field induction to enable communication between devices operating in different modes and supports data rates up to 424 kbit/s. While offering convenience, NFC data transfer is susceptible to eavesdropping and data injection attacks without additional security measures. Potential applications of NFC include mobile payments, ticketing, and pairing of Bluetooth devices.
NFC enables contactless communication between devices like phones and readers. It uses radio frequency identification (RFID) to allow devices within 4 inches of each other to establish radio communication to exchange data. This technology is designed for applications like mobile payments, ticketing, and device pairing. NFC provides secure, convenient transactions by allowing users to simply tap their phone to a reader to complete a payment or share contact information.
NFC: Shaping the Future of the Connected Customer ExperienceNFC Forum
This presentation was delivered March 8, 2017 at RETAILTECH JAPAN by Koichi Tagawa, Chairman, NFC Forum, Sony.
Technology is reshaping the face and function of the traditional brick-and-mortar store, forever changing shopping as we know it. NFC-enabled mobile payments and tags are the latest must-have accessories. Forward-thinking retailers are pushing the boundaries to further engage shoppers—often with nothing more than a simple touch, tap, or swipe. NFC, the technology link between the physical and digital world, is helping build a stronger, more meaningful—and therefore more profitable—relationships with customers. NFC-enabled industries, including transport, automotive and IoT, are opening new doors for retailers. All with a simple tap, consumers can make NFC-enabled transactions using a wearable, their car dashboard, or in an NFC-enabled train station. This presentation will highlight how the growth of NFC is leading to “retail anywhere” NFC-enabled applications. The presentation will spotlight NFC use cases in the Internet of Things, Transportation, Automotive markets and examine the future of NFC-based product innovation.
For latest developments: www.nfc-forum.org
Near field communication (NFC) allows short-range wireless data transfer when devices are brought close together. NFC grew out of RFID technology and was standardized in 2004. It can operate in passive or active mode at 13.56 MHz and up to 424 kbit/s. NFC is used for contactless payments, data sharing, and access in transit systems. While slower than Bluetooth, NFC consumes less power and sets up connections faster. Major trials of NFC payments and ticketing have occurred in several countries. Security relies on encryption and the NFC Forum standardizes protocols. Widespread adoption of NFC in mobile phones is expected in coming years.
NFC, or Near Field Communication, is a short-range wireless communication technology that allows data exchange between devices when they are touched or brought within close proximity of each other. It operates at 13.56 MHz and has a maximum range of about 10 cm. NFC uses magnetic field induction to enable communication between two devices. One device must have an NFC reader/writer while the other contains an NFC tag. Common applications of NFC include contactless payments, data sharing, and connection handovers to establish wireless links between devices. The technology is standardized by the NFC Forum and is seeing increasing adoption in smartphones and other mobile devices.
Near Field Communications (NFC) is a short-range wireless technology that allows data exchange when devices are brought within 4 cm of each other. The document discusses security concerns around NFC, including credit card skimming and malware risks. It then demonstrates NFCProxy, a proof of concept tool that can intercept NFC communications and proxy credit card transactions by relaying data between two Android phones. The tool shows how easily NFC security can be bypassed today. Mitigations include turning off NFC when not in use and only using trusted applications.
Near Field Communication (NFC) allows communication between devices within close proximity using radio waves. NFC works through inductive coupling between loop antennas in devices operating at 13.56 MHz with data transfer rates from 106-424 Kbps. It can operate in both active and passive modes. NFC provides an easy and secure way to transfer data quickly by touching or bringing devices close together. Potential applications include mobile payments, ticketing, data sharing, and access control.
This document discusses NFC (Near Field Communication) technology. It explains that NFC allows short-range wireless communication when devices are tapped together from up to 20 centimeters. NFC uses magnetic field induction and operates at 13.56 MHz. Common applications include mobile payments, data sharing, and access control. The document outlines how NFC works, provides examples of its applications, and discusses its technical features and future potential.
Near Field Communication (NFC) is a short-range wireless technology that allows data exchange between devices when they are touched or brought within a few centimeters of each other. NFC uses magnetic field induction to enable communication between devices operating in different modes and supports data rates up to 424 kbit/s. While offering convenience, NFC data transfer is susceptible to eavesdropping and data injection attacks without additional security measures. Potential applications of NFC include mobile payments, ticketing, and pairing of Bluetooth devices.
NFC enables contactless communication between devices like phones and readers. It uses radio frequency identification (RFID) to allow devices within 4 inches of each other to establish radio communication to exchange data. This technology is designed for applications like mobile payments, ticketing, and device pairing. NFC provides secure, convenient transactions by allowing users to simply tap their phone to a reader to complete a payment or share contact information.
NFC: Shaping the Future of the Connected Customer ExperienceNFC Forum
This presentation was delivered March 8, 2017 at RETAILTECH JAPAN by Koichi Tagawa, Chairman, NFC Forum, Sony.
Technology is reshaping the face and function of the traditional brick-and-mortar store, forever changing shopping as we know it. NFC-enabled mobile payments and tags are the latest must-have accessories. Forward-thinking retailers are pushing the boundaries to further engage shoppers—often with nothing more than a simple touch, tap, or swipe. NFC, the technology link between the physical and digital world, is helping build a stronger, more meaningful—and therefore more profitable—relationships with customers. NFC-enabled industries, including transport, automotive and IoT, are opening new doors for retailers. All with a simple tap, consumers can make NFC-enabled transactions using a wearable, their car dashboard, or in an NFC-enabled train station. This presentation will highlight how the growth of NFC is leading to “retail anywhere” NFC-enabled applications. The presentation will spotlight NFC use cases in the Internet of Things, Transportation, Automotive markets and examine the future of NFC-based product innovation.
For latest developments: www.nfc-forum.org
Near field communication (NFC) allows short-range wireless data transfer when devices are brought close together. NFC grew out of RFID technology and was standardized in 2004. It can operate in passive or active mode at 13.56 MHz and up to 424 kbit/s. NFC is used for contactless payments, data sharing, and access in transit systems. While slower than Bluetooth, NFC consumes less power and sets up connections faster. Major trials of NFC payments and ticketing have occurred in several countries. Security relies on encryption and the NFC Forum standardizes protocols. Widespread adoption of NFC in mobile phones is expected in coming years.
NFC, or Near Field Communication, is a short-range wireless communication technology that allows data exchange between devices when they are touched or brought within close proximity of each other. It operates at 13.56 MHz and has a maximum range of about 10 cm. NFC uses magnetic field induction to enable communication between two devices. One device must have an NFC reader/writer while the other contains an NFC tag. Common applications of NFC include contactless payments, data sharing, and connection handovers to establish wireless links between devices. The technology is standardized by the NFC Forum and is seeing increasing adoption in smartphones and other mobile devices.
Near Field Communications (NFC) is a short-range wireless technology that allows data exchange when devices are brought within 4 cm of each other. The document discusses security concerns around NFC, including credit card skimming and malware risks. It then demonstrates NFCProxy, a proof of concept tool that can intercept NFC communications and proxy credit card transactions by relaying data between two Android phones. The tool shows how easily NFC security can be bypassed today. Mitigations include turning off NFC when not in use and only using trusted applications.
e-wallet , The future of Cards and MoneyVikram Dahiya
The document discusses e-wallets and near field communication (NFC) technology. E-wallets store digital payment information and have advantages over traditional cards like unlimited lifetime and storage of current balance. NFC allows contactless payment and data transfer between devices in close proximity by using magnetic field induction. NFC is supported on many mobile platforms and enables mobile payment apps like Google Wallet.
Near-Field Communication (NFC) allows contactless data exchange between devices within close proximity. NFC operates at 13.56 MHz and has a maximum range of about 4 cm. It can be used for applications such as contactless payment, ticketing, and data sharing when two NFC devices are tapped together. NFC has three operating modes - reader/writer mode where an NFC device can read from and write to tags, card emulation mode where a phone acts like a card, and peer-to-peer mode for data transfer between two NFC phones. NFC integration with mobile devices has potential for new opportunities but has limitations such as short range and low data transfer rates.
Near field communications (or NFC) is the latest buzz word to hit the marketing community. Now it may be a powerful new direct mail tool. Here we'll explore the pros and cons of NFC for direct mail.
Near field communication (nfc) technologyAnkur Sharma
Near Field Communication (NFC) is a short-range wireless connectivity technology that allows data exchange between devices within 20 centimeters. NFC operates at 13.56 MHz and uses magnetic field induction to transfer data between an NFC reader/writer and an NFC tag. NFC enables contactless payment systems, data sharing between devices with a tap, and access to digital content, tickets or doors with NFC-enabled phones and tags. The future of NFC looks promising as more devices and payment terminals are being equipped with NFC technology.
Mobile Transaction Using Near Field Communication(NFC)Shashank Lochan
This presentation highlights the potential of near field communication(NFC) as a secure mode of performing mobile banking and transaction.
It also shows a comparative study of google wallet and apple pay.
This presentation also highlights various use cases of near field communication in our day to day lives.
This document provides an overview of Near Field Communication (NFC) technology, including NFC modes, use cases, tag types, related specifications, and forum standards. It describes key aspects of NFC such as communication occurring when devices are 4 cm or closer, the reader/tag relationship, and operating modes including read/write, peer-to-peer, and card emulation. Common use cases like service initiation, sharing, connecting devices, ticketing, and payment are outlined. The document also discusses NFC tag types, related specifications like ISO 14443 and MIFARE, and forum standards including NDEF, RTD, and LLCP.
Near Field Communication (NFC) allows contactless communication between devices like smartphones or tablets when they are within a few centimeters of each other. NFC uses radio signals to establish short-range wireless connections and can operate in either active or passive mode. Some common uses of NFC include mobile payments through services like Google Wallet, connecting devices via Bluetooth and Wi-Fi, social networking, and identifying documents. While NFC has a short range, combining it with other radio technologies can increase its applications.
Near field communication (NFC) allows short-range wireless data transfer between devices when brought close together. In 2004, Nokia, Philips, and Sony established the NFC Forum to develop standards. NFC operates at 13.5MHz and has a maximum transfer rate of 800kbps within a 10cm range. It can be used for contactless payments, data sharing, and automated tasks. Common applications include mobile boarding passes, tickets, and keyless entry. Security risks include eavesdropping, data modification, and man-in-the-middle attacks due to the short operating distance.
All the 12 Payment Enabling Technologies & 54 Illustrative CompaniesMEDICI admin
All the 12 Payment Enabling Technologies & 54 Illustrative Companies
Near Field Communication (NFC): NFC is in its most common avatar is a Tap & Pay solution that can be used for retail
offline payments, transit, entertainment and numerous other touch points. Any unattended payment situation such
as a parking lot presents huge opportunity. For e.g., clipper card or any cashless cards being used today for public
transport can be integrated into the ubiquitous phones itself thereby making the public transport payments easier
SIM application toolkit in the context of Near Field communication ApplicationsMukta Gupta
1) The document discusses near field communication (NFC) applications and the benefits of using SIM application toolkit (SAT) for managing the secure element in NFC devices.
2) It describes how SAT allows for closed system management of applications on the secure element directly from the SIM card, which can provide remote management of apps and independence from the device operating system.
3) The SAT approach is compared to using J2ME, noting SAT provides benefits like standardized development and ability to exchange devices without affecting apps, while J2ME management depends on the device.
This document provides an overview of near field communication (NFC) technology and its use cases for mobile commerce. It discusses how NFC allows for physical interactions with "smart" posters, tags, and cards to access information or trigger applications. The document then describes NFC standards, programming with the JSR-257 API, and includes code examples of discovering supported NFC targets and listening for detections. It argues that short-term uses of NFC will likely include contactless payments, interactive marketing, and authentication.
NFC allows short-range wireless communication between devices like smartphones and tablets when they are touched or brought close together. It can be used for contactless transactions, exchanging data, and setting up connections to other technologies like WiFi. NFC builds on RFID to enable two-way communication and uses less power than other wireless standards. Common uses of NFC today include mobile payments, accessing transport systems, and exchanging contact information between devices. Improvements to security and adoption by more merchants are needed to fully realize the potential of NFC mobile payments.
NFC (Near Field Communication) allows contactless communication between devices like phones, POS terminals, smart posters. It enables services like transit ticketing, contactless payments, data exchange. The document discusses the NFC ecosystem including architecture, stakeholders and the Payez Mobile pilot project in France. It also covers expected trends like availability of NFC phones and growing interest from banks and retailers in providing NFC-based services.
Transforming the NFC Public Transport Experience from Vision to Reality -- Th...NFC Forum
The NFC Forum Transport SIG acts as a bridge between all transport industry stakeholders, from identifying NFC roadblocks
to enabling a seamless integration of NFC by providing all players with the information and tools they need to succeed. Significant progress has been made with harmonization efforts over the past year. This presentation by the NFC Forum Transport SIG provides an overview of where we are to date, where we are heading, and how your organization can get involved with our efforts to advance the adoption of NFC in public transport.
Near Field Communication (NFC) is a short-range wireless technology that allows data transmission between devices that are close together. NFC was created in 2003 and uses radio waves at 13.56 MHz to transmit data by reading passive tags. NFC offers simple and intuitive data transfer between electronic devices like smartphones and is compatible with existing RFID infrastructure through standards. NFC devices can both receive and transmit data and have applications like contactless payments, device pairing, and access control. The technology empowers users but implementation costs and security are weaknesses to consider.
Near Field Communication (NFC) allows for contactless communication between devices over short ranges using radio frequency identification (RFID) technology. NFC operates at 13.56 MHz and has a range of less than 10 cm. It supports both active and passive communication modes. NFC tags and readers enable two-way communication where one device acts as a reader/writer and the other as a tag. Common applications of NFC include contactless payments, data sharing, and connecting devices by simply touching them together. The technology provides a convenient way to transfer information with security and no need for manual configuration.
NFC allows for short-range wireless data transfer between devices when they are touched or brought within close proximity. It can operate in either active mode, where both devices generate an electromagnetic field to exchange data, or passive mode where one device is active and provides the field for the other. NFC is used for applications like mobile payments and connecting devices for data sharing. While it provides a simple user experience without configuration, NFC has limitations in range and transfer speed compared to other wireless technologies.
NFC (Near Field Communication) by sandip murariSandip Murari
This document provides an overview of Near Field Communication (NFC) technology. It discusses that NFC allows communication between devices within 10 cm of each other. It operates in various modes including card emulation, peer-to-peer, and reader modes. The document outlines the history and working principles of NFC. It discusses applications of NFC such as mobile payments, ticketing, data sharing, and access control. Both advantages like convenience and disadvantages like short range are highlighted. The conclusion is that NFC is a useful technology that saves time despite some security limitations.
The document discusses near field communication (NFC) technology and its potential applications in the airline industry. NFC allows contactless communication between devices within 10 cm of each other. It enables services like mobile payments, ticketing, and content sharing. The document outlines several ways NFC could streamline airline processes like check-in, boarding, baggage handling, lounge access, and purchasing ground transportation. Challenges to adoption include developing business models, infrastructure limitations, and lack of NFC devices and standards. Overall, NFC may help airlines reduce costs, increase revenue and improve the customer experience.
Near Field Communication (NFC) is a short-range wireless technology that allows data exchange between devices within 10 cm of each other. NFC was developed from RFID technology and operates at 13.56 MHz. It enables simplified transactions, data exchange, and wireless connections. NFC supports three operating modes - card emulation, peer-to-peer, and reader/writer - and has applications in areas like mobile payments, ticketing, and data sharing between devices. While convenient, NFC has limitations in range and data transfer speed.
e-wallet , The future of Cards and MoneyVikram Dahiya
The document discusses e-wallets and near field communication (NFC) technology. E-wallets store digital payment information and have advantages over traditional cards like unlimited lifetime and storage of current balance. NFC allows contactless payment and data transfer between devices in close proximity by using magnetic field induction. NFC is supported on many mobile platforms and enables mobile payment apps like Google Wallet.
Near-Field Communication (NFC) allows contactless data exchange between devices within close proximity. NFC operates at 13.56 MHz and has a maximum range of about 4 cm. It can be used for applications such as contactless payment, ticketing, and data sharing when two NFC devices are tapped together. NFC has three operating modes - reader/writer mode where an NFC device can read from and write to tags, card emulation mode where a phone acts like a card, and peer-to-peer mode for data transfer between two NFC phones. NFC integration with mobile devices has potential for new opportunities but has limitations such as short range and low data transfer rates.
Near field communications (or NFC) is the latest buzz word to hit the marketing community. Now it may be a powerful new direct mail tool. Here we'll explore the pros and cons of NFC for direct mail.
Near field communication (nfc) technologyAnkur Sharma
Near Field Communication (NFC) is a short-range wireless connectivity technology that allows data exchange between devices within 20 centimeters. NFC operates at 13.56 MHz and uses magnetic field induction to transfer data between an NFC reader/writer and an NFC tag. NFC enables contactless payment systems, data sharing between devices with a tap, and access to digital content, tickets or doors with NFC-enabled phones and tags. The future of NFC looks promising as more devices and payment terminals are being equipped with NFC technology.
Mobile Transaction Using Near Field Communication(NFC)Shashank Lochan
This presentation highlights the potential of near field communication(NFC) as a secure mode of performing mobile banking and transaction.
It also shows a comparative study of google wallet and apple pay.
This presentation also highlights various use cases of near field communication in our day to day lives.
This document provides an overview of Near Field Communication (NFC) technology, including NFC modes, use cases, tag types, related specifications, and forum standards. It describes key aspects of NFC such as communication occurring when devices are 4 cm or closer, the reader/tag relationship, and operating modes including read/write, peer-to-peer, and card emulation. Common use cases like service initiation, sharing, connecting devices, ticketing, and payment are outlined. The document also discusses NFC tag types, related specifications like ISO 14443 and MIFARE, and forum standards including NDEF, RTD, and LLCP.
Near Field Communication (NFC) allows contactless communication between devices like smartphones or tablets when they are within a few centimeters of each other. NFC uses radio signals to establish short-range wireless connections and can operate in either active or passive mode. Some common uses of NFC include mobile payments through services like Google Wallet, connecting devices via Bluetooth and Wi-Fi, social networking, and identifying documents. While NFC has a short range, combining it with other radio technologies can increase its applications.
Near field communication (NFC) allows short-range wireless data transfer between devices when brought close together. In 2004, Nokia, Philips, and Sony established the NFC Forum to develop standards. NFC operates at 13.5MHz and has a maximum transfer rate of 800kbps within a 10cm range. It can be used for contactless payments, data sharing, and automated tasks. Common applications include mobile boarding passes, tickets, and keyless entry. Security risks include eavesdropping, data modification, and man-in-the-middle attacks due to the short operating distance.
All the 12 Payment Enabling Technologies & 54 Illustrative CompaniesMEDICI admin
All the 12 Payment Enabling Technologies & 54 Illustrative Companies
Near Field Communication (NFC): NFC is in its most common avatar is a Tap & Pay solution that can be used for retail
offline payments, transit, entertainment and numerous other touch points. Any unattended payment situation such
as a parking lot presents huge opportunity. For e.g., clipper card or any cashless cards being used today for public
transport can be integrated into the ubiquitous phones itself thereby making the public transport payments easier
SIM application toolkit in the context of Near Field communication ApplicationsMukta Gupta
1) The document discusses near field communication (NFC) applications and the benefits of using SIM application toolkit (SAT) for managing the secure element in NFC devices.
2) It describes how SAT allows for closed system management of applications on the secure element directly from the SIM card, which can provide remote management of apps and independence from the device operating system.
3) The SAT approach is compared to using J2ME, noting SAT provides benefits like standardized development and ability to exchange devices without affecting apps, while J2ME management depends on the device.
This document provides an overview of near field communication (NFC) technology and its use cases for mobile commerce. It discusses how NFC allows for physical interactions with "smart" posters, tags, and cards to access information or trigger applications. The document then describes NFC standards, programming with the JSR-257 API, and includes code examples of discovering supported NFC targets and listening for detections. It argues that short-term uses of NFC will likely include contactless payments, interactive marketing, and authentication.
NFC allows short-range wireless communication between devices like smartphones and tablets when they are touched or brought close together. It can be used for contactless transactions, exchanging data, and setting up connections to other technologies like WiFi. NFC builds on RFID to enable two-way communication and uses less power than other wireless standards. Common uses of NFC today include mobile payments, accessing transport systems, and exchanging contact information between devices. Improvements to security and adoption by more merchants are needed to fully realize the potential of NFC mobile payments.
NFC (Near Field Communication) allows contactless communication between devices like phones, POS terminals, smart posters. It enables services like transit ticketing, contactless payments, data exchange. The document discusses the NFC ecosystem including architecture, stakeholders and the Payez Mobile pilot project in France. It also covers expected trends like availability of NFC phones and growing interest from banks and retailers in providing NFC-based services.
Transforming the NFC Public Transport Experience from Vision to Reality -- Th...NFC Forum
The NFC Forum Transport SIG acts as a bridge between all transport industry stakeholders, from identifying NFC roadblocks
to enabling a seamless integration of NFC by providing all players with the information and tools they need to succeed. Significant progress has been made with harmonization efforts over the past year. This presentation by the NFC Forum Transport SIG provides an overview of where we are to date, where we are heading, and how your organization can get involved with our efforts to advance the adoption of NFC in public transport.
Near Field Communication (NFC) is a short-range wireless technology that allows data transmission between devices that are close together. NFC was created in 2003 and uses radio waves at 13.56 MHz to transmit data by reading passive tags. NFC offers simple and intuitive data transfer between electronic devices like smartphones and is compatible with existing RFID infrastructure through standards. NFC devices can both receive and transmit data and have applications like contactless payments, device pairing, and access control. The technology empowers users but implementation costs and security are weaknesses to consider.
Near Field Communication (NFC) allows for contactless communication between devices over short ranges using radio frequency identification (RFID) technology. NFC operates at 13.56 MHz and has a range of less than 10 cm. It supports both active and passive communication modes. NFC tags and readers enable two-way communication where one device acts as a reader/writer and the other as a tag. Common applications of NFC include contactless payments, data sharing, and connecting devices by simply touching them together. The technology provides a convenient way to transfer information with security and no need for manual configuration.
NFC allows for short-range wireless data transfer between devices when they are touched or brought within close proximity. It can operate in either active mode, where both devices generate an electromagnetic field to exchange data, or passive mode where one device is active and provides the field for the other. NFC is used for applications like mobile payments and connecting devices for data sharing. While it provides a simple user experience without configuration, NFC has limitations in range and transfer speed compared to other wireless technologies.
NFC (Near Field Communication) by sandip murariSandip Murari
This document provides an overview of Near Field Communication (NFC) technology. It discusses that NFC allows communication between devices within 10 cm of each other. It operates in various modes including card emulation, peer-to-peer, and reader modes. The document outlines the history and working principles of NFC. It discusses applications of NFC such as mobile payments, ticketing, data sharing, and access control. Both advantages like convenience and disadvantages like short range are highlighted. The conclusion is that NFC is a useful technology that saves time despite some security limitations.
The document discusses near field communication (NFC) technology and its potential applications in the airline industry. NFC allows contactless communication between devices within 10 cm of each other. It enables services like mobile payments, ticketing, and content sharing. The document outlines several ways NFC could streamline airline processes like check-in, boarding, baggage handling, lounge access, and purchasing ground transportation. Challenges to adoption include developing business models, infrastructure limitations, and lack of NFC devices and standards. Overall, NFC may help airlines reduce costs, increase revenue and improve the customer experience.
Near Field Communication (NFC) is a short-range wireless technology that allows data exchange between devices within 10 cm of each other. NFC was developed from RFID technology and operates at 13.56 MHz. It enables simplified transactions, data exchange, and wireless connections. NFC supports three operating modes - card emulation, peer-to-peer, and reader/writer - and has applications in areas like mobile payments, ticketing, and data sharing between devices. While convenient, NFC has limitations in range and data transfer speed.
Guide du tag NFC : quels usages dans quels contextes ?Olivier Devillers
Guide rédigé pour le Forum SMSC sur le tag NFC (Etiquette intelligente lisible avec un smartphone NFC) et ses usages dans le commerce, le tourisme, les transports publics.
This document provides an overview of NXP's NFC product portfolio and use cases for NFC technology. It discusses NFC applications for access control, pairing/commissioning, authentication, extended user interfaces, device communication, and payment. For each use case, it recommends suitable NXP NFC products including connected tags, frontends, and controllers with customizable or integrated firmware. It positions NXP as the leading NFC provider with the broadest portfolio to address every application.
Near Field Communication (NFC Architecture and Operating Modes)Deepak Kl
This document discusses near field communication (NFC) technology and its use for secure mobile transactions. NFC allows contactless communication between devices within 10 cm of each other. It can be used for applications like mobile payments, data transfers, and access control. The document explores NFC architecture, communication modes, security considerations, and potential future applications like unlocking vehicles and doors with a tap. It concludes that NFC is widely used in mobile devices today and enables contactless payment models through technologies like mobile wallets.
The document discusses Near Field Communication (NFC) technology. It defines NFC as a short-range wireless communication standard that allows data exchange between devices within 10 centimeters. The document outlines NFC's technical features, modes of operation including active/passive communication, categories like touch and go/confirm, and common uses like mobile payments, data transfers, and access control. It also compares NFC to other wireless standards like Bluetooth and RFID, highlighting NFC's security, speed and potential for future integration with other technologies.
Near Field Communication (NFC) is a short-range wireless communication technology that allows data exchange between devices within 10 cm of each other. NFC operates at 13.56 MHz and supports data transfer rates of 106-424 Kbit/s. For communication to occur, one device must have an NFC reader/writer and the other an NFC tag. NFC provides secure data transfer and enables technologies like mobile payments and connection between devices with a touch.
NFC is a short-range wireless technology that allows data exchange between electronic devices within 20 centimeters. It uses magnetic field induction and operates at 13.56 MHz. For two devices to communicate using NFC, one must have an NFC reader/writer and the other an NFC tag. NFC is expected to be included in one in five phones by 2013 and enable uses like downloading content, exchanging contact cards, and mobile payments at point-of-sale terminals. The NFC Forum is working to expand the NFC ecosystem through education, research projects, and industry partnerships.
The document provides an overview of Near Field Communication (NFC) technology. It defines NFC as a short-range wireless connectivity standard that allows data exchange between electronic devices within 10cm of each other. The document discusses NFC's operating modes of reader/writer, card emulation, and peer-to-peer communication. It also describes NFC tags, the NDEF data format, mobile architecture, comparisons to other wireless technologies, and examples of NFC applications and trials.
This document examines the future of Near Field Communication (NFC) technology. It begins with an introduction to NFC, describing it as a short-range wireless connection using 13.56 MHz frequency with a maximum bandwidth of 424Kbits/sec. It then discusses how NFC operates using contactless technologies and RFID, requiring a reader and tag. The document outlines current NFC capabilities like data sharing and mobile payments. It envisions a future where NFC powers smart devices for security, vehicle access, and online shopping. Benefits include ease of use, automation, and security, though limitations are short range and low data transfer rates. Overall, the document concludes that NFC will provide convenience for consumers and retailers.
RFID is a system that uses radio waves to wirelessly transmit data between a tag and reader. It has advantages over barcodes like not needing line of sight and ability to read/write data. There are different types of tags based on power source and range. Common frequencies used are low, high and ultra-high frequency. RFID is used for applications like asset tracking, process control, data lineage tracing and automated replenishment. The Internet of Things connects physical objects through embedded technology like sensors to exchange data. Near Field Communication is a short-range wireless technology that allows data exchange when devices are 10cm apart and is used for contactless payments, ticketing and access control.
Track 4 session 5 - st dev con 2016 - simplifying the setup and use of iot ...ST_World
The document summarizes how NFC dynamic tags can simplify the setup and use of IoT devices. It discusses how NFC helps with commissioning devices by providing a standard way to connect them to networks and write credentials. NFC also aids in connecting devices to Bluetooth and WiFi networks by encoding connection details on tags. Interacting with tags allows controlling headless devices for configuration and data retrieval. The document concludes that NFC's ease of use, security, and low cost make it a promising technology for simplifying IoT adoption challenges around connectivity and control of devices.
NFC Development with Qt - v2.2.0 (5. November 2012)Andreas Jakl
Learn developing Near Field Communication (NFC) apps for Nokia's Symbian and MeeGo phones with step-by-step tutorials!
The three development options Qt, Symbian native and Java ME are outlined. A more detailed explanation shows the Qt Mobility 1.2 APIs to create modern NFC applications for smartphones.
In the final part, step-by-step hands-on tutorials walk you through developing your first two NFC apps. The first demo extends an example from the Qt SDK with reading & writing both URI and text NDEF records to create new sticky notes on the virtual corkboards visible on the screen. The second demo uses the LLCP protocol to create a peer-to-peer chat application between two NFC Forum compatible devices.
NFC (Near Field Communication) is a short-range wireless communication technology that allows data exchange between devices over short distances typically less than 20 cm. It uses radio frequency identification (RFID) standards to establish communication by bringing two enabled devices in close proximity. Common applications of NFC include contactless payment, data sharing and connectivity with smart posters, tags, or cards. Security is a concern for NFC since communications can potentially be intercepted, though using higher-level encryption protocols can help address this.
On Relaying NFC Payment Transactions using Android devicescgvwzq
NFC (Near Field Communication) defines the set of RFID standards designed to bidirectionally communicate via wireless and interchange data point-to-point between devices in proximity, normally a few centimeters (up to 10cm). Services that use NFC communications as contactless payments are exponentially growing: Public transport, parkings, fast supermarket cashers, vending machines and even NFC-capable credit/debit cards.In this talk, we investigate relay attacks in NFC-capable credit/debit cards. This attack exploits the communication proximity principle in NFC, which is shown to be non secure. Although a lot of attack countermeasures exist, they do not face with this attack vector since up to date special hardware was required to perform it. However, the story is rewritten with the NFC-capable mobile devices available in the market.
This work shows how nowadays a relay attack in NFC-capable credit/debit cards is possible using an NFC-capable Android device without further modifications (i.e., no root permissions, custom firmware, or custom OS are required). A PoC app implementing the attack is shown in the talk, as well as distributed relay attack scenarios that might become real before long.
Near field communication and RFID - opening for new businessJosef Noll
This document provides an agenda and slides for an RFID and NFC tutorial given by Josef Noll. The agenda covers RFID basics like frequencies and applications. It also discusses NFC technology and scenarios. The slides define RFID and its components like tags and readers. They describe communication modes and provide examples of RFID applications in areas like sports, payment systems, and supply chain management. Potential security issues with RFID like cloning and uncontrolled surveillance are also addressed.
Near field communication (NFC) allows short-range wireless communication between devices when they are brought within close proximity of a few inches. It was established as a standard in 2004 and the first NFC phone was released in 2006. NFC operates at 13.56 MHz and has a theoretical range of about 4 cm. It can be used to transfer contact information, URLs, initiate Bluetooth connections, and for contactless payments. While NFC provides convenience, its adoption has been limited due to lack of agreement between companies and some security concerns exist. Alternatives to NFC include digital wallets that are accessible from multiple devices.
The User Experience of Near Field CommunicationMemi Beltrame
The information age took us by storm and the mobile revolution is still in full effect – yet we already stand on the brink of the next paradigm shift: the seamless connection of information and personal devices. Imagine a world where you have the possibility of giving your devices context by simply holding them close to a tiny chip. Things like sharing your WiFi credentials or telling your mobile phone that you are going to bed and it should mute and dim itself and also set the alarm clock to 7am. All with one simple touch — Welcome to the world of Near Field Communication. This talk focuses on the amazing possibilities of NFC in everyday use. A variety of actual and (once) futuristic use cases will illustrate how NFC can enrich our experiences with technology and how this relates to our profession of User Experience Design and our role in shaping the future.
Near-Field Communication (NFC) can be used in a range of different ways at a variety of different places. Here is a list of the top 6 ways NFC can be used by consumers.
Near Field Communication . In modern era every type of work we can do by the use of technology. So Nfc is a better way to use our technology in a comfortable way
Near field communication (NFC) allows contactless communication between devices within close proximity. It uses magnetic field induction to enable communication between devices within 4 centimeters of each other. NFC operates at 13.56 MHz and can be used for purposes such as contactless payment, data sharing, and connecting to other devices and networks. While NFC provides convenience, its short range and slow data transfer limits its capabilities compared to other wireless technologies. However, its integration into many mobile devices indicates its future role in mobile commerce and connectivity applications.
This document discusses Near Field Communication (NFC) technology. It explains that NFC allows short-range wireless communication between devices when they are touched or within a few centimeters of each other. The document outlines several uses of NFC including mobile payments, data transfer, social networking, and identity verification. It also discusses the advantages of NFC such as convenience and security, and disadvantages like limited range. The future of NFC is presented as the technology becoming more widely adopted in mobile devices and enabling new applications like digital ticketing and travel planning.
This document discusses Near Field Communication (NFC) technology. It explains that NFC allows short-range wireless communication between devices when they are touched or within a few centimeters of each other. The document outlines several uses of NFC including mobile payments, data transfer, social networking, and identity verification. It also discusses the advantages of NFC such as convenience and security, and disadvantages like short range and slow data transfer rates. The document concludes that NFC will likely be implemented in most mobile devices in the future and its applications could be expanded by combining it with other radio frequency technologies.
NFC is an emerging technology that combines RFID and mobile devices to allow communication between devices within 4 centimeters of each other. It operates at 13.56 MHz and can transfer data up to 424 Kbits/sec. NFC has applications in mobile payments, access control, transit payments, social networking and more. While not supported by iPhone 5, NFC is driving mobile payment revolution and a new marketing ecosystem of location-based offers and interactions between physical objects and mobile devices.
Sound Based Payment technology enables contactless payments through sound waves. There is no dependence on any specific platform and the technology behind it enables
payments on various devices such as smartphones, feature phones, card swipe machines and point-of-sale devices.
Near field communication (NFC) is a set of standards for smartphones and similar devices to establish radio communication with each other by touching them together or bringing them into close proximity, usually no more than a few inches.
This document introduces NFC (near-field communication) technology, which allows cell phones to function like digital wallets by enabling contactless payments at merchant terminals simply by tapping the phone. NFC works over short distances and is being adopted by cell phone companies and payment providers to integrate payment credentials directly into phones. The technology is based on existing contactless payment standards and provides a more convenient alternative to physical cards by allowing users to pay with just their phone.
Near Field Communication (NFC) allows contactless transactions and data sharing through devices like smartphones and credit cards. NFC uses electromagnetic induction to transmit information short distances. It provides several applications like contactless payments, digital tickets, content sharing, and keyless entry. However, NFC also faces security risks like eavesdropping, data interception and lost device attacks. Future applications include more uses of mobile devices as digital keys and wallets. Security can be improved through encryption and authentication.
Near Field Communication (NFC) is a short-range wireless communication technology that allows data transfer between devices when they are brought within close proximity of a few centimeters. NFC operates using magnetic field induction to enable communication between electronic devices like smartphones. It supports various applications like contactless payment, data transfer between devices with a tap, and access control by bringing an NFC device close to a reader. Mobile handsets are a primary target for NFC integration to enable mobile wallet-based contactless payments without physical cards.
Will Mobile Phones Replace Your Wallet? - The State of Mobile Payments TodayWeb Ad.vantage Inc.
Will mobile phones replace your wallet? An exploration of the state of mobile payments today, the major players leading the transformation, and the technology that's making it possible.
An Electronic Ticketing System based on Near Field Communication for Concerts...Hussain Shah
NFC allows for short-range wireless communication between electronic devices like smartphones and payment terminals. It enables contactless transactions where users simply tap or touch their device to complete payments or data transfers. While NFC adoption has been limited, standards coordination by groups like the NFC Forum aim to address this by ensuring interoperability. NFC provides benefits like intuitive interactions, versatility across industries, and built-in security due to its short operating range. However, challenges remain around mass adoption including the need for industry collaboration between different players in the mobile ecosystem.
A short summary of trends and technology in mobile payments. A brief look into the past, present and future of mobile payments. We will have detailed sessions on each in the coming versions.
NFC, or Near Field Communication, allows contactless communication between devices within 10 cm of each other. It was established in 2002 by Sony and Philips and works using magnetic field induction to enable functions like contactless payments, data sharing, and electronic tickets. NFC provides a secure and convenient way for devices to connect and exchange information by simply bringing them close together.
NFC is a short-range wireless connectivity technology that allows for intuitive, simple, and secure communication between electronic devices when brought within close proximity of 4 centimeters of each other. It operates at 13.56MHz and can transfer data at speeds of up to 424Kbits/second. NFC distinguishes itself from other wireless technologies by enabling seamless interoperability between proprietary platforms and providing a simple interface for contactless transactions, accessing digital content, and connecting devices with a touch.
Near field communication (NFC) is a short-range wireless technology that allows data transfer between devices when they are brought within close proximity of a few centimeters. NFC was developed in 2004 and the first NFC-enabled phones were released in 2006 and 2010. NFC operates using magnetic field induction at 13.56 MHz and can transfer data at rates from 106-424 Kbps. NFC has applications in areas like contactless payment, data sharing, and device configuration and is expected to be widely adopted in the future as mobile payment and connectivity options continue to evolve.
Near Field Communication (NFC) is a short-range wireless technology that allows data exchange between devices within close proximity. NFC operates at 13.56 MHz and has a maximum range of about 4 cm. It can be used for contactless payments, data sharing, and connecting electronic devices like accessing a building. NFC provides security through its very short transmission range which requires devices to be in close physical contact to communicate, preventing unwanted access. It also uses protocols that prevent collisions when multiple devices transmit simultaneously.
An introduction to Near Field Communication (NFC) and how it impacts Singapore Marketing industry. A comparison with QR codes is also provided as well as the future of the NFC
TrustArc Webinar - 2024 Global Privacy SurveyTrustArc
How does your privacy program stack up against your peers? What challenges are privacy teams tackling and prioritizing in 2024?
In the fifth annual Global Privacy Benchmarks Survey, we asked over 1,800 global privacy professionals and business executives to share their perspectives on the current state of privacy inside and outside of their organizations. This year’s report focused on emerging areas of importance for privacy and compliance professionals, including considerations and implications of Artificial Intelligence (AI) technologies, building brand trust, and different approaches for achieving higher privacy competence scores.
See how organizational priorities and strategic approaches to data security and privacy are evolving around the globe.
This webinar will review:
- The top 10 privacy insights from the fifth annual Global Privacy Benchmarks Survey
- The top challenges for privacy leaders, practitioners, and organizations in 2024
- Key themes to consider in developing and maintaining your privacy program
Maruthi Prithivirajan, Head of ASEAN & IN Solution Architecture, Neo4j
Get an inside look at the latest Neo4j innovations that enable relationship-driven intelligence at scale. Learn more about the newest cloud integrations and product enhancements that make Neo4j an essential choice for developers building apps with interconnected data and generative AI.
Threats to mobile devices are more prevalent and increasing in scope and complexity. Users of mobile devices desire to take full advantage of the features
available on those devices, but many of the features provide convenience and capability but sacrifice security. This best practices guide outlines steps the users can take to better protect personal devices and information.
Climate Impact of Software Testing at Nordic Testing DaysKari Kakkonen
My slides at Nordic Testing Days 6.6.2024
Climate impact / sustainability of software testing discussed on the talk. ICT and testing must carry their part of global responsibility to help with the climat warming. We can minimize the carbon footprint but we can also have a carbon handprint, a positive impact on the climate. Quality characteristics can be added with sustainability, and then measured continuously. Test environments can be used less, and in smaller scale and on demand. Test techniques can be used in optimizing or minimizing number of tests. Test automation can be used to speed up testing.
Cosa hanno in comune un mattoncino Lego e la backdoor XZ?Speck&Tech
ABSTRACT: A prima vista, un mattoncino Lego e la backdoor XZ potrebbero avere in comune il fatto di essere entrambi blocchi di costruzione, o dipendenze di progetti creativi e software. La realtà è che un mattoncino Lego e il caso della backdoor XZ hanno molto di più di tutto ciò in comune.
Partecipate alla presentazione per immergervi in una storia di interoperabilità, standard e formati aperti, per poi discutere del ruolo importante che i contributori hanno in una comunità open source sostenibile.
BIO: Sostenitrice del software libero e dei formati standard e aperti. È stata un membro attivo dei progetti Fedora e openSUSE e ha co-fondato l'Associazione LibreItalia dove è stata coinvolta in diversi eventi, migrazioni e formazione relativi a LibreOffice. In precedenza ha lavorato a migrazioni e corsi di formazione su LibreOffice per diverse amministrazioni pubbliche e privati. Da gennaio 2020 lavora in SUSE come Software Release Engineer per Uyuni e SUSE Manager e quando non segue la sua passione per i computer e per Geeko coltiva la sua curiosità per l'astronomia (da cui deriva il suo nickname deneb_alpha).
AI 101: An Introduction to the Basics and Impact of Artificial IntelligenceIndexBug
Imagine a world where machines not only perform tasks but also learn, adapt, and make decisions. This is the promise of Artificial Intelligence (AI), a technology that's not just enhancing our lives but revolutionizing entire industries.
GraphSummit Singapore | The Future of Agility: Supercharging Digital Transfor...Neo4j
Leonard Jayamohan, Partner & Generative AI Lead, Deloitte
This keynote will reveal how Deloitte leverages Neo4j’s graph power for groundbreaking digital twin solutions, achieving a staggering 100x performance boost. Discover the essential role knowledge graphs play in successful generative AI implementations. Plus, get an exclusive look at an innovative Neo4j + Generative AI solution Deloitte is developing in-house.
Removing Uninteresting Bytes in Software FuzzingAftab Hussain
Imagine a world where software fuzzing, the process of mutating bytes in test seeds to uncover hidden and erroneous program behaviors, becomes faster and more effective. A lot depends on the initial seeds, which can significantly dictate the trajectory of a fuzzing campaign, particularly in terms of how long it takes to uncover interesting behaviour in your code. We introduce DIAR, a technique designed to speedup fuzzing campaigns by pinpointing and eliminating those uninteresting bytes in the seeds. Picture this: instead of wasting valuable resources on meaningless mutations in large, bloated seeds, DIAR removes the unnecessary bytes, streamlining the entire process.
In this work, we equipped AFL, a popular fuzzer, with DIAR and examined two critical Linux libraries -- Libxml's xmllint, a tool for parsing xml documents, and Binutil's readelf, an essential debugging and security analysis command-line tool used to display detailed information about ELF (Executable and Linkable Format). Our preliminary results show that AFL+DIAR does not only discover new paths more quickly but also achieves higher coverage overall. This work thus showcases how starting with lean and optimized seeds can lead to faster, more comprehensive fuzzing campaigns -- and DIAR helps you find such seeds.
- These are slides of the talk given at IEEE International Conference on Software Testing Verification and Validation Workshop, ICSTW 2022.
Unlocking Productivity: Leveraging the Potential of Copilot in Microsoft 365, a presentation by Christoforos Vlachos, Senior Solutions Manager – Modern Workplace, Uni Systems
UiPath Test Automation using UiPath Test Suite series, part 6DianaGray10
Welcome to UiPath Test Automation using UiPath Test Suite series part 6. In this session, we will cover Test Automation with generative AI and Open AI.
UiPath Test Automation with generative AI and Open AI webinar offers an in-depth exploration of leveraging cutting-edge technologies for test automation within the UiPath platform. Attendees will delve into the integration of generative AI, a test automation solution, with Open AI advanced natural language processing capabilities.
Throughout the session, participants will discover how this synergy empowers testers to automate repetitive tasks, enhance testing accuracy, and expedite the software testing life cycle. Topics covered include the seamless integration process, practical use cases, and the benefits of harnessing AI-driven automation for UiPath testing initiatives. By attending this webinar, testers, and automation professionals can gain valuable insights into harnessing the power of AI to optimize their test automation workflows within the UiPath ecosystem, ultimately driving efficiency and quality in software development processes.
What will you get from this session?
1. Insights into integrating generative AI.
2. Understanding how this integration enhances test automation within the UiPath platform
3. Practical demonstrations
4. Exploration of real-world use cases illustrating the benefits of AI-driven test automation for UiPath
Topics covered:
What is generative AI
Test Automation with generative AI and Open AI.
UiPath integration with generative AI
Speaker:
Deepak Rai, Automation Practice Lead, Boundaryless Group and UiPath MVP
HCL Notes und Domino Lizenzkostenreduzierung in der Welt von DLAUpanagenda
Webinar Recording: https://www.panagenda.com/webinars/hcl-notes-und-domino-lizenzkostenreduzierung-in-der-welt-von-dlau/
DLAU und die Lizenzen nach dem CCB- und CCX-Modell sind für viele in der HCL-Community seit letztem Jahr ein heißes Thema. Als Notes- oder Domino-Kunde haben Sie vielleicht mit unerwartet hohen Benutzerzahlen und Lizenzgebühren zu kämpfen. Sie fragen sich vielleicht, wie diese neue Art der Lizenzierung funktioniert und welchen Nutzen sie Ihnen bringt. Vor allem wollen Sie sicherlich Ihr Budget einhalten und Kosten sparen, wo immer möglich. Das verstehen wir und wir möchten Ihnen dabei helfen!
Wir erklären Ihnen, wie Sie häufige Konfigurationsprobleme lösen können, die dazu führen können, dass mehr Benutzer gezählt werden als nötig, und wie Sie überflüssige oder ungenutzte Konten identifizieren und entfernen können, um Geld zu sparen. Es gibt auch einige Ansätze, die zu unnötigen Ausgaben führen können, z. B. wenn ein Personendokument anstelle eines Mail-Ins für geteilte Mailboxen verwendet wird. Wir zeigen Ihnen solche Fälle und deren Lösungen. Und natürlich erklären wir Ihnen das neue Lizenzmodell.
Nehmen Sie an diesem Webinar teil, bei dem HCL-Ambassador Marc Thomas und Gastredner Franz Walder Ihnen diese neue Welt näherbringen. Es vermittelt Ihnen die Tools und das Know-how, um den Überblick zu bewahren. Sie werden in der Lage sein, Ihre Kosten durch eine optimierte Domino-Konfiguration zu reduzieren und auch in Zukunft gering zu halten.
Diese Themen werden behandelt
- Reduzierung der Lizenzkosten durch Auffinden und Beheben von Fehlkonfigurationen und überflüssigen Konten
- Wie funktionieren CCB- und CCX-Lizenzen wirklich?
- Verstehen des DLAU-Tools und wie man es am besten nutzt
- Tipps für häufige Problembereiche, wie z. B. Team-Postfächer, Funktions-/Testbenutzer usw.
- Praxisbeispiele und Best Practices zum sofortigen Umsetzen
UiPath Test Automation using UiPath Test Suite series, part 5DianaGray10
Welcome to UiPath Test Automation using UiPath Test Suite series part 5. In this session, we will cover CI/CD with devops.
Topics covered:
CI/CD with in UiPath
End-to-end overview of CI/CD pipeline with Azure devops
Speaker:
Lyndsey Byblow, Test Suite Sales Engineer @ UiPath, Inc.
GraphSummit Singapore | The Art of the Possible with Graph - Q2 2024Neo4j
Neha Bajwa, Vice President of Product Marketing, Neo4j
Join us as we explore breakthrough innovations enabled by interconnected data and AI. Discover firsthand how organizations use relationships in data to uncover contextual insights and solve our most pressing challenges – from optimizing supply chains, detecting fraud, and improving customer experiences to accelerating drug discoveries.
For the full video of this presentation, please visit: https://www.edge-ai-vision.com/2024/06/building-and-scaling-ai-applications-with-the-nx-ai-manager-a-presentation-from-network-optix/
Robin van Emden, Senior Director of Data Science at Network Optix, presents the “Building and Scaling AI Applications with the Nx AI Manager,” tutorial at the May 2024 Embedded Vision Summit.
In this presentation, van Emden covers the basics of scaling edge AI solutions using the Nx tool kit. He emphasizes the process of developing AI models and deploying them globally. He also showcases the conversion of AI models and the creation of effective edge AI pipelines, with a focus on pre-processing, model conversion, selecting the appropriate inference engine for the target hardware and post-processing.
van Emden shows how Nx can simplify the developer’s life and facilitate a rapid transition from concept to production-ready applications.He provides valuable insights into developing scalable and efficient edge AI solutions, with a strong focus on practical implementation.
Let's Integrate MuleSoft RPA, COMPOSER, APM with AWS IDP along with Slackshyamraj55
Discover the seamless integration of RPA (Robotic Process Automation), COMPOSER, and APM with AWS IDP enhanced with Slack notifications. Explore how these technologies converge to streamline workflows, optimize performance, and ensure secure access, all while leveraging the power of AWS IDP and real-time communication via Slack notifications.
5. • Vodafone Cash service “The fastest, safest and
• most convenient means of transferring money”.
• Vodafone Cash will allow sending and receiving money
through mobile phones to any Vodafone number,
anywhere in Egypt and at any time.
6. Pay “vodafone
cash “card
Charge the card
with credit
You can
recharge your
sim card with
credit
OR
Transfer
money to any
one at any city
7. Is to ease the process of transferring & receiving
using The new technology is called:
NFCNear Field Communication
8. Nowadays you can use your mobile to
exchange data via :
WiFi WiMax
Bluetooth
3G
ZigBee
Wireless USB
10. In NFC,
the communication occurs when two NFC
compatible devices are brought together
less than four centimeters, or simply by
touching themselves.
It operates at 13.56 MHz and can transfer
data up to 424 Kbits/sec
11. •Now with using NFC in Vodafone Cash ,, just
You can using your smart mobile to read “NFC
tags” which will be available in places such as
(banks , Pharmacy , hospitals , Gas stations
,shops ,….) .
•After reading NFC tag , you must put your
password , and then will appear a list of
choices such that (see your credit , transform
credit to anther number ,….).
•NFC tags will available to you at any time ,at
any place .