HTSFCH3201EV/DH,11 NXP Semiconductors, HTSFCH3201EV/DH,11 Datasheet

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DATA SHEET HITAG S HTS IC H32/HTS IC H56/HTS IC H48 Transponder IC Product Specification Revision 3.1 PUBLIC INFORMATION INTEGRATED CIRCUITS 2006 July 18 079231 ...

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Philips Semiconductors HITAG S CONTENTS 1 FEATURES . . . . . . . . . . . . . . . . . . . . . . . . . 3 1.1 Protocol . . . . . ...

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Philips Semiconductors HITAG S 1 FEATURES • Integrated Circuit for Contactless Identification Transponders and Cards • Integrated resonance capacitor of 210 pF with ± tolerance over full production • Frequency range 100..150 kHz. 1.1 Protocol • Modulation Read/Write ...

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Philips Semiconductors HITAG S 2 GENERAL DESCRIPTION The HITAG™ product line is well known and established in the contactless identification market. Due to the open marketing strategy of Philips Semiconductors there are various manufacturers well established for both the transponders ...

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Philips Semiconductors HITAG S 3 ORDERING INFORMATION EXTENDED TYPE DESCRIPTION NUMBER HTS IC H32 01EW/V4 Sawn 8” wafer on foil (FFC), 150 µm, inked and mapped, HTS IC H56 01EW/V4 with gold bumps HTS IC H48 01EW/V4 HTS MO H32 ...

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Philips Semiconductors HITAG S 4 BLOCKDIAGRAM The HITAG S Transponder requires no external power supply. The contactless interface generates the power supply and the system clock via the resonant circuitry by inductive coupling to the Read/Write Device (RWD). The interface ...

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Philips Semiconductors HITAG S 6 MEMORY ORGANISATION Page Address 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C 0x0D 0x0E 0x0F 0x10 0x3B 0x3C 0x3D 0x3E 0x3F The EEPROM has a capacity up to 2048 Bit ...

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Philips Semiconductors HITAG S 6.1 Unique Identifier (UID) Page 0 contains the 32 Bit Unique Identifier (UID) which is programmed during the manufacturing process. Page 0 access: Read Only (RO) MSByte Page Address MSB 0x00 UID 3 6.1.1 P (PID) ...

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Philips Semiconductors HITAG S 6.3 HITAG S Authentication Mode Page 1 In Authentication Mode, Page 1 contains three configuration Bytes CON 0 to CON 2 and the password high Byte PWDH 0. MSByte Page Address MSB 0x01 PWDH 0 Page ...

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Philips Semiconductors HITAG S 7 FUNCTIONAL DESCRIPTION 7.1 Basic System Configuration The following block diagram shows in principle the HITAG system configuration Oscillator Interface Control Host Signal & Data Processing Amplifier A control and data processing unit controls the modulation ...

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Philips Semiconductors HITAG S 7.2 Energy Transmission Passive transponders must somehow be supplied with energy to be able to operate. In the HITAG System, this is achieved by using the principle of a loose coupled transformer: RWD Antenna The RWD ...

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Philips Semiconductors HITAG S Data Transmission: Transponder → Read/Write Device 7.3 For data transmission from the HITAG S Transponder to the RWD, the implemented method is called 'load modulation'. Here the HITAG S Transponder continuously changes the load on the ...

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Philips Semiconductors HITAG S 7.3.1 C ODING Three different coding techniques for different States and Modes of the HITAG S Transponder IC are used (see also Chapters 11 “Command Set” and 12 “Transponder Talks First (TTF) Mode”: • AC: Anticollision ...

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Philips Semiconductors HITAG S 7.3 ATA ATE The data rate for HITAG S Transponder in Reader Talks First (RTF) Mode depends on the corresponding UID REQUEST xx command. For Transponder Talks First (TTF) Mode the data rate can ...

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Philips Semiconductors HITAG S Data Transmission: Read/Write Device → 7.4 Transponder (Physical Layer) Data are transmitted to the transponder using Amplitude Shift Keying (ASK) modulation with a modulation index of 100 %. When the field is switched off, the physical ...

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Philips Semiconductors HITAG S SYMBOL T g T[0] T[1] T EOF Note 1. This application specific values must be within this frame, but have to be optimized for each application depending on rise and decay times of the RWD antenna ...

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Philips Semiconductors HITAG S 7.4.2 M ODULATION DETAILS 0. 0. b).....Modulation index SYMBOL MIN m 95 (1) T ...

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Philips Semiconductors HITAG S 8 CONFIGURATION 8.1 Configuration Page Memory Page 1 contains the three configuration Bytes CON 0, CON 1 and CON 2 (see Chapter “Memory Organisation”). Changes on the Configuration Bytes are effective after a power on reset ...

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Philips Semiconductors HITAG S The Transponder Talks First Coding Bit TTFC defines the used coding during transmitting data to the RWD. This effects the TTF State only. Table 4 Transponder Talks First Coding Bit TTFC TTFC 0 1 The Transponder ...

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Philips Semiconductors HITAG S The Lock Key and Password Bit LKP defines the access rights of the PWDH 0 Byte of Page 1, password low Bytes and key high Bytes of Page 2 and key low Bytes of Page 3 ...

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Philips Semiconductors HITAG S 8.2 Delivery Configuration 8.2.1 HITAG S32 This delivery configuration is valid for the following HITAG S 32 types: • HTS IC H32 01EW/V4 • HTS MO H32 01EV • HTS FC H32 01EV/DH MSByte MSB LSB ...

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Philips Semiconductors HITAG S 8.2.2 HITAG S256 This delivery configuration is valid for the following HITAG S 256 types: • HTS IC H56 01EW/V4 • HTS MO H56 01EV • HTS FC H56 01EV/DH MSByte Page Address MSB 0x00 UID ...

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Philips Semiconductors HITAG S 8.2.3 HITAG S2048 This delivery configuration is valid for the following HITAG S 2048 types: • HTS IC H48 01EW/V4 • HTS MO H48 01EV • HTS FC H48 01EV/DH MSByte Page Address MSB 0x00 UID ...

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Philips Semiconductors HITAG S 9 PROTOCOL TIMING 9.1 Read/Write Device waiting time before sending the first command C oded D ata Voltage Antenna y = 0.95 a Fig.9 Read/Write Device waiting time ...

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Philips Semiconductors HITAG S 9.2 Read/Write Device waiting time before sending a subsequent command Data RWD Coded Data RWD Voltage on RWD Antenna Voltage on Transponder Antenna Coded Data(MC) Transponder Data Transponder Fig.10 Read/Write Device waiting time before sending a ...

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Philips Semiconductors HITAG S 9.3 Reset Time The powering field must be switched off for at least t into Power Off State lta Table ...

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Philips Semiconductors HITAG S 9.4 HITAG S Transponder waiting time before transmitting a response after receiving an EOF Data 1 RWD Coded Data RWD Voltage on RWD Antenna Voltage on Transponder Antenna Coded Data(MC) Transponder Data Transponder Fig.12 HITAG S ...

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Philips Semiconductors HITAG S 9.5 HITAG S Transponder programming time Write Data RWD Transponder Fig.13 HITAG S Transponder programming time. When receiving the EOF of the write data from the Read/Write Device, the transponder waits t SOF and acknowledge to ...

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Philips Semiconductors HITAG S 9.6 HITAG S Transponder waiting time before transmitting data in TTF Mode C oded D ata oltage ntenna V oltage on Transponder A ntenna C oded ...

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Philips Semiconductors HITAG S 9.7 HITAG S Transponder Mode switching time Code Data RW a Voltag Antenn y = 0.95 a Fig.15 HITAG S Transponder Mode switching time. With an UID REQUEST xx command starting with the ...

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Philips Semiconductors HITAG S 10 STATE DIAGRAM 10.1 General Description of States Power Off The powering magnetic field is switched off or the HITAG S Transponder is out of field. Ready After start up phase, the HITAG S Transponder is ...

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Philips Semiconductors HITAG S 10.2 HITAG S 32 Transmission error Any other command or transmission error Note: Switching off the powering magnetic field or moving the HITAG S Transponder out of the RWD antenna field, enters the HITAG S Transponder ...

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Philips Semiconductors HITAG S 10.3 HITAG S 256 and HITAG S 2048 ...

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Philips Semiconductors HITAG S 11 COMMAND SET 11.1 General Comments For HITAG S 32 only the commands described in the corresponding State diagram are valid commands. 11.2 UID REQUEST xx MSB LSB RWD: UID REQUEST xx EOF Transponder t wresp ...

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Philips Semiconductors HITAG S 11.3 AC SEQUENCE If more than one HITAG S Transponder is in the field of the antenna a special designed RWD detects the first collision at the Bit position the UID response. ...

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Philips Semiconductors HITAG S 11.4 SELECT (UID) The SELECT (UID) command consists of 5 Zero-Bits followed by the determined 32 Bit UID and an 8 Bit Cyclic Redundancy Check (CRC). The selected transponder then responds with a start of frame ...

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Philips Semiconductors HITAG S 11.5 CHALLENGE By means of the response of the SELECT (UID) command the RWD detects that the HITAG S Transponder is configured in Authentication Mode (Bit AUT = 1) and starts the encrypted Challenge sequence. MSB ...

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Philips Semiconductors HITAG S 11.6 SELECT_QUIET (UID) With this command a HITAG S Transponder in Init State can be directly entered into the Quiet State. LSByte MSB LSB MSB RWD: 00000 UID 0 UID 1 Transponder The ‘start of frame’ ...

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Philips Semiconductors HITAG S 11.8 READ BLOCK After transmitting the READ BLOCK command, the Page address PADR (8 Bits) within a block and the 8 Bit Cyclic Redundancy Check CRC 8, the HITAG S Transponder responds with the SOF and ...

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Philips Semiconductors HITAG S 11.9 WRITE PAGE After a HITAG S Transponder was selected by the corresponding SELECT (UID) command (or SELECT (UID) and CHALLENGE for Authentication Mode) a write operation of data onto the memory can be carried out. ...

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Philips Semiconductors HITAG S 11.10 WRITE BLOCK After transmitting the WRITE BLOCK command, the Page address PADR (8 Bits) within a Block and the 8 Bit Cyclic Redundancy Check (CRC 8), the HITAG S Transponder responds with the SOF and ...

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Philips Semiconductors HITAG S 11.11 QUIET With this command a Selected HITAG S Transponder can be entered into the Quiet State. A valid Page address PADR (8 Bits) and Cyclic Redundancy Check (CRC 8) must be sent for command structure ...

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Philips Semiconductors HITAG S 12 TRANSPONDER TALKS FIRST (TTF) MODE This special mode of the HITAG S Transponder enables data transmission to a Read/Write Device without sending any command. The TTF Mode can be enabled/disabled and configured by setting the ...

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Philips Semiconductors HITAG S 12.3 128 Bit TTF Mode Configuration: In this Mode, the HITAG S Transponder continuously transmits the data content of Page 4, Page 5, Page 6 and Page 7. Page 4 LSByte MSByte LSByte Transponder: t TTF ...

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Philips Semiconductors HITAG S 13 DATA INTEGRITY / CALCULATION OF CRC The following explanations show the features of the HITAG S protocol to protect read and write access to transponders from undetected errors. 13.1 Data Transmission: Read/Write Device to HITAG ...

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Philips Semiconductors HITAG S 13.3 Source Code for CRC-Checksum The following lines of C-Code show an example for a CRC-Calculation. #include <stdio.h> #define CRC_PRESET 0xFF #define CRC_POLYNOM 0x1D void calc_crc(unsigned char * crc, unsigned char data, unsigned char Bitcount) { ...

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Philips Semiconductors HITAG S 14 ABBREVIATIONS ABBREVIATION AC Anticollision Code ASK Amplitude Shift Keying BC Biphase Code BPLC Binary Pulse Length Coding CRC Cyclic Redundancy Check EEPROM Electrically Erasable Programmable Memory EOF End of frame LSB Least Significant Bit LSByte ...

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Philips Semiconductors HITAG S 15 DATA SHEET STATUS DATA SHEET PRODUCT LEVEL (1) STATUS STATUS I Objective data Development II Preliminary data Qualification III Product data Production Notes 1. Please consult the most recently issued data sheet before initiating or ...

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Philips Semiconductors HITAG S Life support applications ⎯ These products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. Philips Semiconductors customers using ...

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Philips Semiconductors HITAG S 18 REVISION HISTORY Table 28 HTS IC H32/HTS IC H56/HTS IC H48 Revision History REVISION DATE CPCN 1.0 2002 August - 1.1 2002 October - 1.2 2003 January - 2.0 2003 Sept - 3.0 2003 Nov ...

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Philips Semiconductors – a worldwide company Contact information For additional information please visit http://www.semiconductors.philips.com. For sales offices addresses send e-mail to: sales.addresses@www.semiconductors.philips.com. © Koninklijke Philips Electronics N.V. 2002 All rights are reserved. Reproduction in whole or in part is prohibited ...