Registers – Systems controlled by data bearing records – Credit or identification card systems
Reexamination Certificate
2001-07-02
2003-06-03
Frech, Karl D. (Department: 2876)
Registers
Systems controlled by data bearing records
Credit or identification card systems
C235S375000, C235S382500, C235S451000, C235S492000
Reexamination Certificate
active
06572015
ABSTRACT:
BACKGROUND
1. Technical Field
The invention relates generally to devices known as smart cards and, more particularly to an authorization system, apparatus and method related to operating a predetermined number of devices associated with vehicles using smart cards.
2. Description of Related Art
A smart card is a “credit card” sized card that contains electronics. Some cards include a microprocessor and a memory while some cards contain a battery and others do not. The smart card can be used to store large volumes of data. Smart cards are generally tamper-resistant hardware devices and can store private keys and other sensitive information making them ideal for data security applications. Contactless cards, which do not require physical contact between the card and a device used to read it, wirelessly transact information and thus avoid the problem of wear and tear, a problem that afflicts traditional credit cards. For example, embossed numbers on the front and magnetic strips on the back of general purpose credit cards suffer from wear and tear, which can eventually render the card unusable for its intended purpose. Smart cards may be simple memory cards with hardwired logic or may contain a microprocessor. As smart card technology continues to evolve, new and specialized versions of it will continue to be developed. Memory based cards merely store information or values, such as debit or credit information, for example. Microprocessor based cards, on the other hand, can perform calculations, including complex processing and can be used in security applications. Unlike contactless cards, contact cards rely on a physical electrical contactand read information when the card is inserted into a smart card reader. Combination cards can utilize both a contact and a contactless card reader. Harry Newton,
Newton's Telecom Dictionary,
Miller Freeman, Inc., Secaucus, N.J. (1999), p. 721.
The electronic device embedded within the smart card is generally some type of integrated circuit chip. In addition to the integrated circuit, the smart card can generally be formed with or without a magnetic stripe and can include an electronic contact module for supporting the electrical contacts to the integrated circuit. The smart card can store and transact information between the card and various other devices, such as for example, a smart card reader. Furthermore, the smart card can provide memory storage as well as computational capability depending on the particular application. The integrated circuit employed in a smart card can be, for example, a microprocessor with internal memory or a memory chip. At one end of the sophistication scale a smart card simply provides memory for storing an identification code while, at the other end of the scale, a smart card provides the computational capacity of a general purpose computer that includes a Central Processing Unit (CPU), Input/Output (I/O) control, Read Only Memory (ROM), Non-Volatile Memory (NVM) and Random Access Memory (RAM). Key applications for smart cards commonly include user identification, transportation, telephone, banking, healthcare, debit purchasing, entertainment, loyalty programs, e-commerce, securing information, telecommuting and networking, campus badging and access, and many other applications which are limited only by the developer's imagination.
As discussed hereinbefore, there are various types of smart cards designed for a specific application. Smart cards also generally include contact and contactless types. A contact type smart card includes an integrated circuit that communicates directly by way of a physical electrical connection to a reader. The contact type smart card typically includes a gold plated conductive contact module that is provided on a front surface of the smart card. The contact smart card requires the user to insert the card into a smart card reader. Inside the smart card reader, the gold plated conductive contact module makes a direct physical electrical connection to electrical contacts provided within the reader. Information including commands, data, algorithms and card status stored within the smart card are then transmitted through the physical connection.
A contactless type smart card includes an integrated circuit that communicates remotely, or wirelessly, by way of an electromagnetic interface when the smart card is placed in proximity of the card reader. The contactiess “proximity” smart card utilizes an internal antenna and an electromagnetic signal for transmitting information between the smart card and the reader. Accordingly, the contactless card need only be placed in proximity of the reader, for example within two to three inches of the reader, in order to get energized and begin a transaction.
Contactless smart cards come in passive and active varieties. Passive contactless cards are generally non-battery-powered and must derive the energy to power the integrated circuit from an external electromagnetic field generated by the reader. One drawback of the passive contactless smart card is that only a limited amount of power can be transmitted from the reader. However, passive contactless smart cards can be made having the same thickness as standard sized credit cards because there is no need to provide a bulky battery within the smart card body. Active contactless smart cards generally include a battery within the plastic card body itself in order to provide additional power to the transmitter. However, because batteries are relatively bulky (i.e., even thin watch batteries are several times thicker than a standard credit card), the active contactless cards cannot be made having the same thickness of a credit-card style smart card and are much thicker in order to accommodate the battery.
There are, however, two additional categories of smart cards that are derived from the contact and contactless family. Namely, these smart cards are combination cards and hybrid cards. Combination cards generally include a single integrated circuit having both a contact module and a contactiess interface, either of which can communicate between the integrated circuit and the smart card reader. Hybrid cards, on the other hand, include two separate integrated circuits and are sometimes referred to as dual-chip cards. The integrated circuits in a hybrid card include respective contact and contactless interfaces, but the two integrated circuits are not connected to each other within the smart card.
Smart cards are also categorized according to the type of integrated circuit used in the smart card. For example, there are smart cards that include a memory chip and there are smart cards that include either a microprocessor or a micro-controller. Smart cards having only memory chips are merely storage devices and do not have any computational capability. Their function is similar to a floppy disk that can store anywhere from a few bits to a few thousand bits. For example, memory smart cards generally store between 103 and 16,000 bits of data. Memory smart cards are less expensive than microprocessor cards but lack the sophistication of data security, data management and computational capabilities.
Alternatively, microprocessor or micro-controller based smart cards are much more sophisticated and are capable of managing data stored in its memory circuits. For example, these smart cards can edit and otherwise manipulate the data stored in its memory circuits. The computational functionality of microprocessor-based smart cards also includes the ability of managing complex algorithms. Such smart cards are really miniature computers that include microprocessors having 8, 16 or 32 bit architectures with data storage capacity ranging from 300 bytes to 32,000 bytes. However, increased computing power and storage capacity can be expected with future development and advances in semiconductor technology.
Contactless proximity smart cards require electrical power in proportion to the amount of data that is to be transmitted from the smart card. In order to transmit large amounts of data, active contactless proximit
BellSouth Intellectual Property Corporation
Frech Karl D.
Nowlin April
LandOfFree
Smart card authorization system, apparatus and method does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Smart card authorization system, apparatus and method, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Smart card authorization system, apparatus and method will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-3120617