Contactless smart card

Contactless smart card
This article is regarding smart cards that use radio to transmit data. For smart cards that use electrical conductors see smart card.
Size comparison of chip
(compared to a Canadian one cent piece)

A contactless smart card is any pocket-sized card with embedded integrated circuits that can process and store data, and communicate with a terminal via radio waves. There are two broad categories of contactless smart cards. Memory cards contain non-volatile memory storage components, and perhaps some specific security logic. Contactless smart cards do not contain an ordinary read-only RFID, but they do contain a re-writeable smart card microchip that can be transcribed via radio waves.

The first contactless smart card was the Octopus card,[citation needed] introduced in Hong Kong in 1997 for the territory's mass transit system.

Contents

Overview

A "contactless smart card" is also characterized as follows:

  • Dimensions are normally credit card size. The ID-1 of ISO/IEC 7810 standard defines them as 85.60 × 53.98 mm. Another popular size is ID-000[citation needed] which is 25 × 15 mm. Both are 0.76 mm thick.
  • Contains a security system with tamper-resistant properties (e.g. a secure cryptoprocessor, secure file system, human-readable features) and is capable of providing security services (e.g. confidentiality of information in the memory).
  • Asset managed by way of a central administration system which interchanges information and configuration settings with the card through the security system. The latter includes card hotlisting, updates for application data.
  • Card data is transferred via radio waves to the central administration system through card reading devices, such as ticket readers, ATMs etc.

Benefits

Contactless smart cards can be used for identification, authentication, and data storage.[1] They also provide a means of effecting business transactions in a flexible, secure, standard way with minimal human intervention.

History

Universal contactless smart card reader symbol

Since first[citation needed] deployed for the Octopus card scheme in Hong Kong in 1997, smart cards with contactless interfaces have been increasingly popular for payment and ticketing applications such as mass transit. Globally, contactless fare collection is being employed for efficiencies in public transit. The various standards emerging are local in focus and are not compatible, though the MIFARE Classic card from Philips has a large market share in the US and Europe.

In more recent times, Visa and MasterCard have agreed to standards for general "open loop" payments on their networks, with millions of cards deployed in the USA,[2] UK, France and globally.

Smart cards are being introduced in personal identification and entitlement schemes at regional, national, and international levels. Citizen cards, drivers’ licenses, and patient card schemes are becoming more prevalent. In Malaysia, the compulsory national ID scheme MyKad includes 8 different applications and is rolled out for 18 million users. Contactless smart cards are being integrated into ICAO biometric passports to enhance security for international travel.

Readers

Contactless smart card readers use radio waves to communicate with, and both read and write data on a smart card. When used for electronic payment, they are commonly located near PIN pads, cash registers and other places of payment. When the readers are used for public transit they are commonly located on fare boxes, ticket machines, turnstiles, and station platforms as a standalone unit. When used for security, readers are usually located to the side of an entry door.

Technology

RF smart card schematic

A contactless smart card is a card in which the chip communicates with the card reader through an induction technology similar to that of an RFID (at data rates of 106 to 848 kbit/s). These cards require only close proximity to an antenna to complete a transaction. They are often used when transactions must be processed quickly or hands-free, such as on mass transit systems, where a smart card can be used without even removing it from a wallet.

The standard for contactless smart card communications is ISO/IEC 14443. It defines two types of contactless cards ("A" and "B") and allows for communications at distances up to 10 cm. There had been proposals for ISO/IEC 14443 types C, D, E, F and G that have been rejected by the International Organization for Standardization. An alternative standard for contactless smart cards is ISO/IEC 15693, which allows communications at distances up to 50 cm.

Examples of widely used contactless smart cards are Taiwan's EasyCard, Hong Kong's Octopus card, Shanghai's Public Transportation Card, South Korea's T-money (bus, subway, taxi), London's Oyster card, Beijing's Municipal Administration and Communications Card, Japan Rail's Suica Card, which predate the ISO/IEC 14443 standard. The following tables list smart cards used for public transportation and other electronic purse applications. First Data delivers Contactless Credit and Debit cards for its customers.

A related contactless technology is RFID (radio frequency identification). In certain cases, it can be used for applications similar to those of contactless smart cards, such as for electronic toll collection. RFID devices usually do not include writeable memory or microcontroller processing capability as contactless smart cards often do.

There are dual-interface cards that implement contactless and contact interfaces on a single card with some shared storage and processing. An example is Porto's multi-application transport card, called Andante, that uses a chip in contact and contactless (ISO/IEC 14443 type B) mode.

Like smart cards with contacts, contactless cards do not have a battery. Instead, they use a built-in inductor, using the principle of resonant inductive coupling, to capture some of the incident electromagnetic signal, rectify it, and use it to power the card's electronics.

Communication protocols

Communication protocols
Name Description
ISO/IEC 14443 APDU transmission via the protocol defined in ISO/IEC 14443-4

Applications

Credit card contactless technology

A major application of the technology has been contactless payment credit and debit cards. Some major examples include:

  • payWave - Visa
  • PayPass - MasterCard
  • ExpressPay - American Express
  • Zip - Discover

Roll-outs started in 2005 in USA, and in 2006 in some parts of Europe (England) and Asia (Singapore).[3] In USA, contactless (non PIN) transactions cover a payment range of ~$5–$100.

Non-EMV cards work like magnetic stripe cards. This is a typical card technology in the USA (PayPass Magstripe and VISA MSD). The cards do not control amount remaining. All payment passes without a PIN and usually in off-line mode. The security level of such a transaction is no greater than with classical magnetic stripe card transaction.

EMV cards have two interfaces (contact and contactless) and they work as a normal EMV card via contact interface. Via contactless interface they work almost like an EMV (card command sequence adopted on contactless features as low power and short transaction time).

Other financial application

The applications of Contactless smart cards include their use as credit or ATM cards, in a fuel card, authorization cards for pay television, pre-pay utilities in household, high-security identification and access-control cards, and public transport payment cards.

Smart cards may also be used as electronic wallets. The smart card chip can be loaded with funds which can be spent in vending machines or at various merchants. Cryptographic protocols protect the exchange of money between the Contactless smart card and the accepting machine.

Identification

A quickly growing application is in digital identification cards. In this application, the cards are used for authentication of identity. The most common example is in conjunction with a PKI. The smart card will store an encrypted digital certificate issued from the PKI along with any other relevant or needed information about the card holder. Examples include the U.S. Department of Defense (DoD) Common Access Card (CAC), and the use of various smart cards by many governments as identification cards for their citizens. When combined with biometrics, smart cards can provide two- or three-factor authentication. Smart cards are not always a privacy-enhancing technology, for the subject carries possibly incriminating information about him all the time. By employing contactless smart cards, that can be read without having to remove the card from the wallet or even the garment it is in, one can add even more authentication value to the human carrier of the cards.

Transportation

Examples of contactless smart cards used for transportation are:

These cards usually contain electronic purses, and may also store access rights.

Other

The Malaysian government uses smart card technology in the identity cards carried by all Malaysian citizens and resident non-citizens. The personal information inside the smart card (called MyKad) can be read using special APDU commands.[5]

Security

Smart cards have been advertised as suitable for personal identification tasks, because they are engineered to be tamper resistant. The embedded chip of a smart card usually implements some cryptographic algorithm. There are, however, several methods of recovering some of the algorithm's internal state.

Differential power analysis

Differential power analysis[6] involves measuring the precise time and electrical current[dubious ] required for certain encryption or decryption operations. This is most often used against public key algorithms such as RSA in order to deduce the on-chip private key, although some implementations of symmetric ciphers can be vulnerable to timing or power attacks as well.

Physical disassembly

Smart cards can be physically disassembled by using acid, abrasives, or some other technique to obtain direct, unrestricted access to the on-board microprocessor. Although such techniques obviously involve a fairly high risk of permanent damage to the chip, they permit much more detailed information (e.g. photomicrographs of encryption hardware) to be extracted.

Problems

Another problem of smart cards may be the failure rate. The plastic card in which the chip is embedded is fairly flexible, and the larger the chip, the higher the probability of breaking. Smart cards are often carried in wallets or pockets — a fairly harsh environment for a chip. However, for large banking systems, the failure-management cost can be more than offset by the fraud reduction. A card enclosure may be used as an alternative to help prevent the smart card from failing.

Using a smart card for mass transit presents a risk for privacy, because such a system enables the mass transit operator (and the authorities) to track the movement of individuals. In Finland, the Data Protection Ombudsman prohibited the transport operator YTV from collecting such information, in spite of YTV's argument that the owner of the card has the right to get a list of journeys paid with the card. Prior to this, such information was used in the investigation of the Myyrmanni bombing.

See also

Notes

References

  • Rankl, W.; W. Effing (1997). Smart Card Handbook. John Wiley & Sons. ISBN 0-471-96720-3. 
  • Guthery, Scott B.; Timothy M. Jurgensen (1998). SmartCard Developer's Kit. Macmillan Technical Publishing. ISBN 1-57870-027-2. 

External links


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