KR100282825B1 - Card reader and control method of access control system - Google Patents

Abstract

An object of the present invention is to implement an independent access management system of a compact size that does not require a resident manager.

The card reader of the access control system according to the present invention for this purpose comprises an antenna, an RF module, a one-chip microcomputer, ID code storage means, a dip switch, a relay driver, and a power monitor. The antenna is for transmitting and receiving RF signals. The RF module transmits and receives an RF signal to and from the card through an antenna and extracts an ID code from the received RF signal. The one-chip microcomputer receives the ID code from the RF module, decrypts it, and registers and deletes the new ID and controls the opening and closing of the door. The registered ID code is stored in the ID code storage means. The dip switch is for setting various state values necessary for controlling the access control system. The relay driver drives the relay according to the control signal of the one-chip microcomputer to open and close the door. The power monitoring unit detects the abnormality of the power supply voltage and initializes the system.

The RF card reader according to the present invention is provided with a power monitoring unit to be able to operate immediately after a power failure recovery, and can prevent malfunction due to mixing of noise. The registration and deletion of new IDs use a master card or a general card, which eliminates the need for a keypad, and is controlled by a one-chip microcomputer, making it easy to upgrade the program. It is possible to implement In addition, since the card of the passive type that does not require a power source can be used, the structure of the card is simplified.

Description

Card reader and control method of access control system

The present invention relates to a card reader and a control method of an access control system, and more particularly, to a card reader and a control method for controlling the door opening and closing state of the doorway in the access management system.

The access control system is a very economical access control system because the user's access can be conveniently managed without a separate administrator. In order to operate the access control system without an administrator, it is common to assign a unique ID to a registered user and to allow access by checking the ID when entering.

In order to implement such a system, an electrically controllable door and an additional control device for controlling the door are required. The separate control device refers to an automatic control device for recognizing the ID of an accessing user to confirm registration and determining whether the door is opened or closed according to the registration. It is efficient to use a computer system to recognize the user ID, confirm registration, and determine whether the door is opened or closed.

1 is a block diagram illustrating the concept of such a conventional access management system. The control computer 102 receives the ID code from the person through the two sensors 104 and 106 installed inside and outside the specific facility, respectively, and checks whether or not it is registered. If the registered ID is input, the door driving unit 108 is controlled to open the door 110.

In such a conventional access control system, a personal computer or the like is used as the control computer 102, and a separate card reader is connected to the personal computer for registration of a new ID. In order to use personal computers and card readers, they have no choice but to install them in separate indoor spaces. That is, since a dual installation area is required to have one access management system, it is impossible to build a standalone system.

An object of the present invention is to implement an independent access management system of a compact size that does not require a resident manager.

The card reader of the access control system according to the present invention for this purpose comprises an antenna, an RF module, a one-chip microcomputer, an ID code storage means, a state setting unit, a relay driver, and a power monitoring unit.

The antenna is for transmitting and receiving RF signals. The RF module transmits and receives an RF signal to and from the card through an antenna and extracts an ID code from the received RF signal. The one-chip microcomputer receives the ID code from the RF module, decrypts it, and registers and deletes the new ID and controls the opening and closing of the door. The registered ID code is stored in the ID code storage means. The state setting unit is for setting various state values necessary for controlling the access control system. The relay driver drives the relay according to the control signal of the one-chip microcomputer to open and close the door. The power monitoring unit detects the abnormality of the power supply voltage and initializes the system.

1 is a block diagram illustrating the concept of such a conventional access management system.

Figure 2 is a block diagram showing the concept of the access control system according to the present invention.

3 is a circuit diagram of a card reader according to the present invention.

Figure 4 is a flow chart showing the control flow of the access control system according to the execution of the program of the card reader according to the present invention.

When explaining the preferred embodiment of the present invention made as described above with reference to Figures 2 to 4 as follows. First, Figure 2 is a block diagram showing the concept of the access control system according to the present invention.

The card reader 202 according to the present invention is connected to an antenna ANT for transmitting and receiving RF signals. The antenna ANT transmits an RF signal generated from the card reader 202 to the card 204 or receives an RF signal generated from the card 204 and transmits the received RF signal to the card reader 202. The card reader 202 reads the received RF signal and determines whether the door 208 is opened or closed. The actual door opening and closing is made by the door driving unit 206. The door driver 206 opens or closes the door 208 according to a control signal generated from the card reader 202. The card reader 202 is manufactured in the form of a printed circuit board (PCB) having a one-chip microcomputer, a memory, and an RF signal processing unit, so as to satisfy the requirements of an independent system having a compact size.

The RF signal transmitted from the card reader 202 to the card 204 is a signal for charging the card 204. The card 204 is a passive type card that does not contain a power supply (such as a battery), and has a capacitor built therein. This capacitor is charged by receiving an RF signal (power pulse) transmitted from the card reader 202. The charged capacitor is used as a power source for generating an RF signal of a predetermined frequency transmitted from the card 204 to the card reader 202. The RF signal generated at the card 204 is a signal in which the unique ID assigned to the card 204 is modulated. The card reader 202 recognizes the unique ID code of the card 204 by receiving and decoding the RF signal generated by the card 204.

The RF signal transmission and reception between the card reader 202 and the card 204 uses a frequency shift keying (FSK) scheme. For example, the card reader 202 transmits a power pulse of 123.2 Hz for about 50 Hz, and the card 204 transmits a signal modulated with an ID code of 134.2 Hz for about 20 Hz. The operation of the card reader 202 is repeatedly performed in a transmission mode of 50 ms and a reception mode of 20 ms.

3 is a circuit diagram of a card reader 202 according to the present invention. Although not shown in FIG. 3, the card reader according to the present invention includes two power supply circuits. The first power circuit receives AC 220V and generates AC 12V. The second power supply circuit receives AC 12V and generates DC 12V and DC 5V. Each part of the circuit shown in FIG. 3 operates with these 12V and 5V as power supply voltages.

The power supply watcher U2 detects an abnormality of the power supply voltages 12V and 5V and controls the reset operation of the RF module U3 and the one-chip microcomputer A1.

The one-chip microcomputer A1 receives and decodes the RF signal received through the antennas ANT1 and ANT2 through the RF module U3. When a new ID code is input in the ID registration mode, the one-chip microcomputer A1 stores and registers the new ID code in EPI-U4 and generates a relay driving signal when an ID code already registered in the normal operation mode is input.

The RF module U3 transmits and receives an RF signal with the card through the antennas ANT1 and ANT2, and transmits the received signal to the one-chip microcomputer A1 and the header JP3.

This pyrom U4 stores ID codes of accessible cards. By using a nonvolatile memory that can be electrically recorded and erased, such as Y pyrom U4, it is possible to register a new ID and delete a registered ID.

The dip switch S1 is used to set various state values necessary for controlling the access control system. Switch 1 to switch 3 is for setting the operating state of the RF module (U3). The switch 1 activates the RF module U3 so that the RF signal transmitted from the card can always be read. The switch 2 activates the external interference minimization state. The switch 3 is a switch for setting the RF module U3 to continuously read. Eight different door open times can be set by combining three switches, from switch 5 to switch 7. For example, the door opening time is set at an interval of about 1 second, such as "0.5 seconds, 1 second, 2 seconds, ..., 6 seconds, 7 seconds". Switch 8 sets the door open sensor check. If switch 8 is off, the door open sensor is not checked. The door open sensor is for detecting whether the door is currently open. If the door is open, there is no need to drive the door locks (such as dead bolts or strikes). Therefore, the door open sensor is for generating a control signal for driving the locking device only when the door is closed.

The relay driver U5 drives the relay REDP DP in accordance with the control signal of the one-chip microcomputer A1. The relay DPDT is used to determine the opening and closing operation of the door.

The first state display unit D2 is composed of a light emitting diode (LED) D2 and is turned on when the system is initialized.

The second state display units D6 to D8 are composed of three light emitting diodes D6 to D8. D6 is an operation indicator light, D7 is lit in the RF Burst mode, and D8 is lit when the ID code sent from the card is normally decoded.

The third state display units D9 to D12 are composed of four light emitting diodes D9 to D12. D9 is for indicating the current operation mode through the blink interval. In the registration mode, the blinking interval is shorter than that in the normal operation mode (that is, the blinking speed is faster). D10 lights up when a beep is output. D11 lights up when the door is opened, and D12 lights up when in registration mode.

The program memory of the one-chip microcomputer A1 stores a program for controlling the access control system. The one-chip microcomputer A1 generates various control signals necessary for controlling the access control system through the execution of this program. As described above, the control flow of the access management system of the one-chip microcomputer A1 according to the execution of the program will be described with reference to the flowchart shown in FIG. 4.

Initialization S1 is performed by power-on or generation of a reset signal RESET of the power monitoring unit U2. During initialization, it will beep for 0.5 seconds. When the initialization is completed and the normal operation mode is reached, the operation indicator turns on for 2 seconds and turns off for 1 second.

The ID input S2 is a step of obtaining the ID code of the card by coding the inputted RF signal in the one-chip microcomputer A1.

When the input of the ID code is completed (S3), it is checked whether it is the master ID code (S4).

When the master ID code is input, the number of inputs Mcount is increased by one (S5), and a different type of beep is generated at every increase of the number of inputs Mcount. When the master ID code is input once or twice, three short beeps of about 0.1 seconds are generated. When the master ID code is input three times (S6), an intermediate beep sound of about 0.2 seconds is generated three times, and the mode is switched to the ID registration mode, followed by the ID input step N after initialization. At this time, the operation indicator (D6) blinks quickly about twice a second. When an unregistered ID code is input in the ID registration mode, the ID code is registered. If registration of a new ID code is successful, a 0.3 second beep sound is generated once. If registration fails, a 0.5 second beep sound is generated two to five times. When the master ID code is input 4 or 5 times, it generates three short beeps about 0.1 seconds again. When the master ID code is input six times (S7), a long beep of about 1 second is generated once, and all of the ID codes currently registered, that is, the registration ID codes stored in YPIROM U4, are deleted. After all of the ID codes stored in Y pyrom U4 are deleted, the ID input step N after initialization is continued.

The one-chip microcomputer A1 counts a certain time at every input of the master ID code. This is to determine the number of times the master ID code is input. If another master ID code is input within a predetermined count time, the count starts anew. However, if the additional input of the master ID code does not occur for a certain time, it is determined that no further input occurs, and the number of inputs until then is determined as the total number of inputs of the master ID code.

If the input ID code is not the master ID code, it is checked whether it is a registered ID code (S8). When the unregistered ID code is input in the ID registration mode, the input ID code is registered (S9), and the ID input step N after initialization is continued. The ID registration mode lasts for about 5 seconds, during which time it is possible to continuously register a plurality of ID codes. However, when the unregistered ID code is input in the normal operation mode other than the ID registration mode, two short beeps are generated as a warning sound (S10). When the registered ID code is input, the relay is normally driven to open the door, and then the ID input step N is initialized (S11).

The RF card reader according to the present invention is provided with a power monitoring unit to be able to operate immediately after a power failure recovery, and can prevent malfunction due to mixing of noise.

The registration and deletion of new IDs use a master card or a general card, which eliminates the need for a keypad, and is controlled by a one-chip microcomputer, making it easy to upgrade the program. It is possible to implement

In addition, since the card of the passive type that does not require a power source can be used, the structure of the card is simplified.

Claims (6)

In the card reader of the access control system, An antenna for transmitting and receiving an RF signal; An RF module for transmitting and receiving an RF signal through the antenna and extracting an ID code from the received RF signal; A one-chip microcomputer that receives the ID code from the RF module, decrypts the ID code, and controls registration and deletion of a new ID and opening and closing of the door; ID code storage means for storing the registered ID code; A state setting unit for setting various state values necessary for controlling the access control system; A relay driver for driving the relay according to a control signal of the one-chip microcomputer to open and close the door; Card reader of the access control system including a power monitoring unit for initializing the system by detecting the abnormality of the power supply voltage. The card reader of claim 1, wherein the state setting unit is configured to set an activation time of a sensor for detecting an open / closed state of the door and an opening time of the door. The RF card reader of claim 1, wherein the frequency of the RF signal has a band between 120 kHz and 140 kHz. The card reader of claim 1, wherein the method for transmitting / receiving an RF signal through the antenna is a frequency shift keying method. The card reader of claim 1, wherein the card reader is formed on a printed circuit board. In the control method of the access control system, An initialization step of initializing the system; Extracting an ID code from an input RF signal; Checking whether the extracted ID code is a master ID code; When the master ID code is input, the number of inputs of the master ID code is increased by 1, and when the master ID code is input by the first number, the mode is switched to ID registration mode, and when the master ID code is input by the second number Deleting all currently registered ID codes; If the entered ID code is not the master ID code, check whether it is a registered ID code. If an unregistered ID code is entered in ID registration mode, register the entered ID code, and enter an unregistered ID code in normal operation mode. And generating a warning sound when the registered ID code is input in the normal operation mode.