KR20020051130A - Contactless IC Card Reader of Contactless IC Card System - Google Patents

Abstract

PURPOSE: A contactless IC(integrated circuit) card reader for contactless IC card system is provided to decrease a power consumption in a contactless IC card and contactless IC card reader by supplying only a predetermined power set value to the contactless IC card after generating an electromagnetic wave. CONSTITUTION: A sensor circuit I(214) senses the access of a contactless IC card(220) and a card user through an infrared ray and a supersonic wave. A sensor circuit II(215) senses a maximum distance for communication between the contactless IC card(220) and the contactless IC card reader(210). A distance calculating circuit(216) calculates a distance between the contactless IC card(220) and the contactless IC card reader(210). A power source control circuit(217) provides a predetermined power supply setting value to the contactless IC card(220) according to the distance between the contactless IC card(220) and the contactless IC card reader(210).

Description

Contactless IC Card Reader of Contactless IC Card System {Contactless IC Card Reader of Contactless IC Card System}

The present invention relates to a contactless IC card reader of a contactless IC card system, and more particularly, to a contactless IC card reader of a contactless IC card system capable of reducing power consumed inefficiently in the contactless IC card reader.

Generally, a contactless IC card reader continuously generates electromagnetic waves of a constant frequency, and when the contactless IC card approaches the frequency operating range of the contactless IC card reader, power is supplied from the contactless IC card and is activated. However, this method causes a problem of wasting power since it continuously generates electromagnetic waves regardless of the presence or absence of a contactless IC card from the contactless IC card reader side.

In addition, in receiving the power transmitted from the contactless IC card reader, the contactless IC card does not always receive constant power, but the received power varies depending on the communication distance between the contactless IC card and the contactless IC card reader. Because of this, if the contactless IC card receives additional power that is still transmitted after receiving enough power to communicate with the contactless IC card reader, it receives the excess power, which is consumed as heat. It causes the destruction of the IC chip constituting the internal circuit of the contactless IC card and the like, and the deterioration of lifetime and reliability.

In addition, the prior art differs in the power received when the contactless IC card and the card reader are at the maximum distance that they can communicate, and the power received until the contactless IC card and the card reader are at a very close distance. As a result, the power received after the maximum distance that can be communicated is unnecessary power in terms of the contactless IC card, which causes the IC chip constituting the internal circuit of the card to be destroyed, the lifespan, and the reliability is reduced. To provide a cause.

An object of the present invention for solving the problems of the prior art is to generate an electromagnetic wave only when the presence of a contactless IC card and a card user is detected, thereby reducing the power consumed inefficiently from the contactless IC card reader. To provide a contactless IC card reader.

1 is a configuration diagram of a contactless IC card system,

2 is a block diagram of a contactless IC card reader and a contactless IC card of the contactless IC card system according to an embodiment of the present invention.

※ Explanation of code about main part of drawing ※

200: Contactless IC Card System

210: Contactless IC Card Reader

220: contactless IC card 214: sensor circuit Ⅰ

215: sensor circuit Ⅱ 216: distance calculation circuit

217: power supply control circuit 221: rectifier circuit

222: internal circuit

In order to achieve the above object, the present invention is used in a contactless IC card system, the contactless IC card reader for supplying power to a contactless IC card that does not have a built-in power supply, infrared and Sensor circuit I for sensing by ultrasonic waves, sensor circuit II for sensing the maximum distance that can be communicated between the contactless IC card and the card reader, and distance between the contactless IC card and the card reader by sensing the sensor circuit II. And a power supply control circuit for supplying a power supply set value determined according to the distance between the contactless IC card and the card reader calculated by the distance calculating circuit to the contactless IC card.

Preferably, in the non-contact IC card system including a non-contact IC card reader for supplying power to a non-contact IC card without a built-in power supply, the sensor circuit for detecting the contact of the non-contact IC card and the user of the card through infrared and ultrasonic waves I And a distance calculation circuit for calculating a distance between the contactless IC card and the card reader by sensing the sensor circuit II and the sensor circuit II for sensing a maximum distance that can be communicated between the contactless IC card and the card reader. And a power supply control circuit for supplying a power supply set value determined according to the distance between the contactless IC card and the card reader calculated through the calculation circuit to the contactless IC card.

Prior to the contactless IC card reader of the contactless IC card system according to an embodiment of the present invention, the contactless IC card system is as follows.

First, a contactless IC card system is based on a wireless communication method between a contactless IC card and a card reader, and communication is performed by an antenna and an RF module which both the contactless IC card and the card reader have. In general, a contactless IC card includes a memory, an IC circuit, a microprocessor, and an antenna for storing data. The contactless IC card is an active card and a passive card, depending on the presence of an internal power source and energy source. Are distinguished. When a contactless IC card uses a power and energy source contained in the card to transmit and receive data, it is called an active card, and when not used, a passive card. The present invention relates to a contactless IC card reader of a contactless IC card system that supplies power to a passive card that does not use a power source and energy source inside the contactless IC card.

1 is a configuration diagram of a contactless IC card system to which the present invention is applied. The contactless IC card system 100 is composed of a contactless IC card reader 110 and a contactless IC card 120, as shown.

The operation principle and process of the contactless IC card system characterized by such a configuration are as follows. The contactless IC card reader 110 continuously emits electromagnetic waves of a constant frequency, and the contactless IC card 120 is supplied with power and activated when approaching the frequency operating range of the contactless IC card reader 110. The contactless IC card 120 activated by the supplied power waits for a command from the contactless IC card reader 110 and sends a response back to the contactless IC card reader 110 when a correct command is received. If the contactless IC card reader 110 sends a command and there is no response from the contactless IC card 120 after the delay time defined by the standard, no further communication is made.

The contactless IC card reader and the contactless IC card in the contactless IC card system including these features will be described in detail as follows. 2 is a diagram illustrating in detail a contactless IC card reader and a contactless IC card according to an embodiment of the present invention.

The contactless IC card reader 210 in the contactless IC card system 200 includes a matching circuit 212, a sensor circuit I 214, a sensor circuit II 215, a distance calculation circuit 216, and power control as shown. Circuit 217, and thus the contactless IC card 220 is composed of a rectifier circuit 221 and an internal circuit 222, respectively.

The sensor circuit I 214 detects the proximity of the contactless IC card 220 and the card user through infrared and ultrasonic waves, and the sensor circuit II 215 enables communication between the contactless IC card 220 and the card reader 210. The maximum distance is sensed, and the distance calculation circuit 216 calculates the distance between the non-contact IC card 220 and the card reader 210 by sensing the sensor circuit II 215, and the power control circuit 217 The power supply set value determined according to the distance between the contactless IC card 220 and the card reader 210 calculated by the distance calculating circuit 216 is supplied to the contactless IC card 220.

The operation process of the non-contact IC card reader and the non-contact IC card according to the above configuration will be described below.

Through the sensor circuit I 214, the non-contact IC card 220 is recognized using infrared rays or ultrasonic waves, or the card user is recognized at a distance farther than the distance at which the non-contact IC card 220 and the card reader 210 can operate. By doing so, it is intended to reduce power consumed by unnecessary operation of the contactless IC card reader 210.

That is, if any contactless IC card 220 or card user enters within the range that the sensor circuit I 214 can detect, the sensor circuit I 214 transfers a detection signal to the power supply control circuit 217. The power control circuit 217 receiving the power detection signal turns on the power source 211 that generates the high frequency power and turns the contactless IC card reader 210 in the sleep mode in the active mode. Switch on and start generating electromagnetic waves. Thereafter, electromagnetic waves of high frequency generated from the power source 211 are organically coupled to the antenna 223 of the contactless IC card 220 through the antenna 213 of the contactless IC card reader 220 via the matching circuit 212. Is passed. The transferred organic power is generated as an induced voltage through the rectifier circuit 221, and the DC voltage is supplied to the internal circuit 222 of the contactless IC card 220.

Here, the tuning capacitor 224 constituting the antenna 223 of the contactless IC card 220 and the resonant circuit may have internal circuits even if the distance between the contactless IC card 220 and the card reader 210 increases. DC voltage may be supplied to 222.

On the other hand, when the contactless IC card 220 is getting closer to the card reader 210, the contactless IC card reader 210 sends a request command to the contactless IC card 220. Then, when receiving a response to the request command transmitted from the contactless IC card reader 210 from the contactless IC card 220, communication power supply is transmitted, which is the contactless IC card 220 and the card reader 210 ) Is the maximum distance at which communication is possible and at the same time the minimum supply power.

At this time, the sensor circuit II (215) detects the maximum distance that can be communicated between the contactless IC card 220 and the card reader 210, the detected maximum distance is the distance between the contactless IC card 220 and the card reader 210 Is passed to the distance calculation circuit 216 for calculating. The distance calculation circuit 216 informs the power control circuit 217 of the power supply control circuit 217 that controls the power supply according to the distance between the contactless IC card 220 and the card reader 210, and the power control circuit 217. ) Sets the power supply at this maximum distance to the appropriate power supply set point that can be communicated. Thereafter, the contactless card reader 210 supplies the predetermined power supply set value to the contactless IC card 220.

In addition, the power supply set value is a fixed power to be supplied to the contactless IC card 220, and the internal circuit of the contactless IC card 220 on the contactless IC card 220 side, rather than the variable voltage which changes from the minimum voltage to the maximum voltage, which is the prior art. At 222, a more stable supply voltage is obtained.

Further, even when the contactless IC card 220 is closer to this distance, supplying the electric power of the power set value or more to the contactless IC card 220 becomes unnecessary as extra power on the contactless IC card 220 side. For this reason, in the present invention, the contactless IC card 220 receives only the minimum required power to supply appropriate and safe power to the internal circuit 222 of the contactless IC card 220. In addition, on the contactless IC card reader 210 side, since the contactless IC card 220 supplies only the minimum power necessary for communication with the card reader 210, power consumption may be reduced.

While the invention has been described above based on the preferred embodiments thereof, these embodiments are intended to illustrate rather than limit the invention. It will be apparent to those skilled in the art that various changes, modifications, or adjustments to the above embodiments can be made without departing from the spirit of the invention. Therefore, the protection scope of the present invention will be limited only by the appended claims, and should be construed as including all such changes, modifications or adjustments.

As described above, according to the present invention, according to the approach of the contactless IC card and the card user, by supplying only a predetermined power set value to the contactless IC card after generating the electromagnetic waves, it is possible to reduce the power consumed by the contactless IC card and the card reader. In addition, it is possible to supply a proper and safe power supply regardless of the distance, there is an effect that can be applied to RFID technology using radio frequency, such as radio recognition.

Claims (7)

A contactless IC card reader, which is used in a contactless IC card system and supplies power to a contactless IC card without a built-in power supply, Sensor circuit I for detecting the contactless IC card and the user of the card via infrared and ultrasonic waves, A sensor circuit II for sensing a maximum distance that can be communicated between the contactless IC card and a card reader; A distance calculation circuit for calculating a distance between the contactless IC card and a card reader by detecting the sensor circuit II; And a power supply control circuit for supplying a power supply set value determined according to the distance between the contactless IC card and the card reader calculated through the distance calculating circuit to the contactless IC card. The method of claim 1, Wherein the sensor circuit I recognizes the user of the contactless IC card at a distance farther than the distance at which the contactless IC card and the card reader can operate. The method of claim 1, The power supply control circuit is a contactless IC card reader, characterized in that for supplying power by the antenna inductive coupling between the contactless IC card and the card reader to the contactless IC card. The method of claim 1, And said sensor circuit I starts generating electromagnetic waves after detecting said contactless IC card and card user. The method of claim 1, And the distance calculating circuit calculates a maximum distance that can be communicated between the contactless IC card and the card reader. The method according to claim 1 or 5, A contactless IC card reader, characterized in that for supplying minimum power even if the contactless IC card is closer to the contactless IC card reader at a distance closer than the maximum distance. In a contactless IC card system including a contactless IC card reader for supplying power to a contactless IC card without a built-in power supply, Sensor circuit I for detecting the contactless IC card and the user of the card via infrared and ultrasonic waves, A sensor circuit for detecting a maximum distance that can be communicated between the contactless IC card and a card reader; A distance calculation circuit for calculating a distance between the contactless IC card and a card reader by detecting the sensor circuit II; And a power supply control circuit for supplying a power supply set value determined according to the distance between the contactless IC card and the card reader calculated through the distance calculating circuit to the contactless IC card.