FCC ID : VASETG6064 ATTACHMENT E. - USER MANUAL - HYUNDAI CALIBRATION & CERTIFICATION TECHNOLOGIES CO., LTD. SAN 136-1, AMI-RI, BUBAL-EUP, ICHEON-SI, KYOUNGKI-DO, 467-701, KOREA TEL:+82 31 639 8517 FAX:+82 31 639 8525 www.hct.co.kr Report No.
TURNSTILE GATE User’s Manual Ver 1.
INDEX 1. TRIPOD ARM .........................................................................................................................................3 1.1 TRIPOD ARM OPERATION .............................................................................................................3 1.2 TRIPOD ARM DROP.........................................................................................................................4 1.3 HOW TO OPERATE TRIPOD ARM DROP........................................
1. TRIPOD ARM 1.1 TRIPOD ARM OPERATION The releasing and locking of the tripod arm rotation is accomplished through the control of tripod arm mechanism using switch input and solenoid activation. If one enters without granted access, the tripod arm will be detected by micro switch (BV) at the 6.5° rotary position which activates the solenoid and mechanically locks at the 14° rotary position.
1.2 TRIPOD ARM DROP TRIPOD ARM DROP applies to gates for the disabled where the arm is secured with a locking pin. When the lever is rotated 90°, the drop guide pin will decline 6mm to release the locking pin. When this happens, the tripod arm descends freely and the guide pin inclines 12mm to activate the micro switch and transmit drop signal. In the drop mode, the lever maintains its 90° position through the guide pin, and retreats to its home position using coil spring when the arm is reinstated. 1.
2. Power and Network Cable 2.1 Power Input INPUT VOLTAGE : AC 110V/220V (50~60Hz) CABLE : UL 2464-3C 16AWG TERMINAL : RING TYPE 2.2 How to Connect Power POWER PANEL TERMINAL BLOCK Open the door on the backside of the gate to find the power panel toward the lower mid-section. Connect the AC input power cable to the terminal block inside the power panel.
Terminal Description 1 INPUT AC 2 INPUT AC 3 OUTPUT AC(AC on Side Gate) 4 OUTPTU AC(AC on Side Gate) 5 F.G 6 OUTPUT F.G(F.G on Side Gate) Connect #3, #4, #6 , if needed. 2.3 How to Connect Network Cable J18 CONNECTOR Connect network cable (ETHERNET) to RJ45 Connector (J18) on the interconnection board near the door on the backside of the gate.
3. Maintanance Door 3.1 FRONT DOOR Facing the entrance direction, this door is located DOOR on the front end of the gate and is used to remove the token box. This door is equipped with a lock in the center and unlike other maintenance doors, it has a separate key for security purposes. 3.2 REAR DOOR This door, located behind the gate on the exit DOOR end, is used for maintenance as well as for mode conversion. It is equipped with a lock in the center and performs the following maintenances: .
Maintanance Category 1 AC Connection / Network Cable Connection 2 Power ON/OFF 3 Power Supply Maintanance 4 Battery Replacement / Inspection 5 Mode Conversion 6 Interconnection Board Maintanance 7 Rear Switch Maintanance 3.3 TOP COVER DOOR DOOR Located on the topside of the gate for maintenance, this door is equipped with a lock in the center.
4. RF Card and Token Operation 4.1 RF Card and Token Contactless Philips Mifare 14443 Type A Card are accepted이다 ASK 100 % , 106kbs Carrier frequency 13.56 MHz 1024 Bytes EEProm 4.2 Gate Operation User tags the RF card or inserts single use token to pass the gate. User can confirm card balance and the current fare deducted through the display at the gate. The gate operates in normal mode or emergency mode. In normal mode, card or token is used to operate the gate typically.
5.
User’s Information 1. Cautions Modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. 2. FCC compliance Information This device complies with part 15 of FCC Rules. Operation is subject to the following two conditions: 1. This device may not cause harmful interference, and 2. This device must accept any interference received. Including interference that may cause undesired operation. 3.
Theory of Operation The MFRC531 is member of a family of highly integrated reader Ics for contactless communication based on 13.56MHz. The MFrc531 Supports all layers of ISO 14443. Figure 1 shows a simplified blockdiagram. Figure1 : Simplified MFRC531 Block Diagram -The parallel u-Controller interface detects automatically the connected 8bit parallel interface -The data procesing part performs the parallel to serial conversion of the data.It supports the framing generation check.
7.1 RF Interface The MIFARE technology describes an ISO 14443-Type A compliant RF interface for a communication between a reader and a contactless card. Overview MIFARE RF Interface - Energy transmission : Transformer principle; MIFARE card is passive -Operating frequency : 13.56MHz - Communication structure : Half duplex,reader talks first -Data rate : 105.6KHz -Data transmission : Both directions RWD Æ Card : 100%ASK,Miller coded Card Æ RWD : subcarrier load modulation,subcarrier frequency 847.
The current in the RWD antenna coil generates a magnetic flux.Parts of this flux flow through the card coil and induce voltage in the card itself.This voltage will vary within the distance between reader antenn and transferred power.The right part shows the equivalent electical circuitry,the transformer model. 7.3 Data transmission RWD Æ Card To transfer data between the PCD and the PICC a half-duplex communication structure is used.The PCD always starts the communication.
Figure 4 : Data Transmission PCD Æ PICC,Miller Coding The data rate of MIFARE is 105.9KHz,so the length of a frame is 9.44us.A pulse in the Miller coding has a length of 3us. A logical ‘1’ expressed with a pulse in the centre of the bit frame. Two possibilities are given to code a logical ‘0’ Tis coding depends on the previou bit; If the previous bit was a’0’,the following ‘0’ is expressed with apulse of 3us at in the first half of the next bit frame.
7.4 Data Transmission PICC Æ PCD Subcarrier load modulation principle The data transmission from the PICC back to the PCD uses the principle of load modulation shown in Figure 5. The PICC is designed as a resonance circuitry and consumes energy generated by the PCD.This energy consumption has a feedback effect as a coltage drop on PCD side.This effect is used to transfer data from the PICC back to the PCD by changing the load in the card IC.
The PCD antenna is tuned to a resonance frequency Fr=13.56MHz. The time T0 expresses he pulse length of the operationg frequency T0=1/Fr 74ns. In fact,this resonance curcuit generates voltages at the PCD antenna several times higher than the supply voltage.Due to small coupling factor between the PCD and PICC antenna PICC’s reponse is up to 60dB below thw voltage generated by the reader.To detect such a signal,it requires a well designed receiving circuit.
Figuren6 : Principle of Data Coding PICCÆ PCD,Time and Frequency Domain
Antenna Specification ANTENNA PCB Pattern Antenna ANTENNA STYLE 50 ohm Match , Loop Antenna ANTENNA SIZE Width : 83.19 mm , Length : 85.