ATA556711N-DDT1

Features • • • • • • • • • Contactless Read/Write Data Transmission Radio Frequency fRF from 100 kHz to 150 kHz e5550, e5551, T5557 Binary Compatible Extended Mode Small Size, Configurable for ISO/IEC 11784/785 Compatibility 75 pF On-chip Resonant Capacitor (Mask Option) 7 × 32-bit EEPROM Data Memory Including 32-bit Password Separate 64-bit Memory for Traceability Data 32-bit Configuration Register in EEPROM to Setup: – Data Rate • RF/2 to RF/128, Binary Selectable, or • Fixed e5550 Data Rates – Modulation/Coding • FSK, PSK, Manchester, Bi-phase, NRZ – Other Options • Password Mode • Max Block Feature • Answer-On-Request (AOR) Mode • Inverse Data Output • Direct Access Mode • Sequence Terminator(s) • Write Protection (Through Lock-bit per Block) • Fast Write Method (5 Kbps versus 2 Kbps) • OTP Functionality • POR Delay up to 67 ms Multifunctional 330-bit Read/Write RF Identification IC ATA5567 1. Description The ATA5567 is a contactless R/W IDentification IC (IDIC®) for applications in the 125-kHz frequency range. A single coil, connected to the chip, serves as the IC’s power supply and bi-directional communication interface. The antenna and chip together form a transponder or tag. The on-chip 330-bit EEPROM (10 blocks, 33 bits each) can be read and written blockwise from a reader. Block 0 is reserved for setting the operation modes of the ATA5567 tag. Block 7 may contain a password to prevent unauthorized writing. Data is transmitted from the IDIC using load modulation. This is achieved by damping the RF field with a resistive load between the two terminals Coil 1 and Coil 2. The IC receives and decodes 100% amplitude-modulated (OOK) pulse-interval-encoded bit streams from the base station or reader. 4874F–RFID–07/08 2. System Block Diagram Figure 2-1. RFID System Using ATA5567 Tag Transponder Power Reader or Base station Coil interface Controller Memory Data 1) ATA5567 1) Mask option 3. ATA5567 – Building Blocks Figure 3-1. Block Diagram POR Modulation Coil 1 Analog front end Write decoder Mode register Memory (330-bit EEPROM) Controller Bit-rate generator Input register 1) Coil 2 Test logic HV generator 1) Mask option 3.1 Analog Front End (AFE) The AFE includes all circuits which are directly connected to the coil. It generates the IC’s power supply and handles the bi-directional data communication with the reader. It consists of the following blocks: • Rectifier to generate a DC supply voltage from the AC coil voltage • Clock extractor • Switchable load between Coil 1 and Coil 2 for data transmission from the tag to the reader • Field gap detector for data transmission from the base station to the tag • ESD protection circuitry 2 ATA5567 4874F–RFID–07/08 ATA5567 3.2 Data-rate Generator The data rate is binary programmable to operate at any data rate between RF/2 and RF/128 or equal to any of the fixed e5550/e5551 and T5554 bit rates (RF/8, RF/16, RF/32, RF/40, RF/50, RF/64, RF/100, and RF/128). 3.3 Write Decoder This function decodes the write gaps and verifies the validity of the data stream according to the Atmel e555x write method (pulse interval encoding). 3.4 HV Generator This on-chip charge pump circuit generates the high voltage required for programming of the EEPROM. 3.5 DC Supply Power is externally supplied to the IDIC via the two coil connections. The IC rectifies and regulates this RF source and uses it to generate its supply voltage. 3.6 Power-On Reset (POR) This circuit delays the IDIC functionality until an acceptable voltage threshold has been reached. 3.7 Clock Extraction The clock extraction circuit uses the external RF signal as its internal clock source. 3.8 Controller The control-logic module executes the following functions: • Loads mode register with configuration data from EEPROM block 0 after power-on and also during reading • Controls memory access (read, write) • Handles write data transmission and write error modes The first two bits of the reader to tag data stream are the opcode, for example, write, direct access, or reset. In password mode, the 32 bits received after the opcode are compared with the password stored in memory block 7. 3.9 Mode Register The mode register stores the configuration data from the EEPROM block 0. It is continually refreshed at the start of every block read and (re-)loaded after any POR event or reset command. On delivery, the mode register is preprogrammed with the value 0014 8000h which corresponds to continuous read of block 0, Manchester coded, RF/64. 3 4874F–RFID–07/08 Figure 3-2. Block 0 Configuration Mapping – e5550 Compatibility Mode L 12 01 34 10 56 00 78 00 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 00 0 Data Bit Rate RF/8 RF/16 RF/32 0 1 Unlocked Locked RF/40 RF/50 RF/64 000 001 010 011 100 101 0 AOR Modulation PSK CF 0 ST-sequence Terminator PWD Max Block 0 0 POR delay 4874F–RFID–07/08 Lock Bit Master Key Note 1), 2) 0 0 RF/2 0 1 RF/4 1 0 RF/8 1 1 Res 0 0 0 0 0 Direct 0 0 0 0 1 PSK1 0 0 0 1 0 PSK2 0 0 0 1 1 PSK3 0 0 1 0 0 FSK1 0 0 1 0 1 FSK2 0 0 1 1 0 FSK1a 0 0 1 1 1 FSK2a 0 1 0 0 0 Manchester 1 0 0 0 0 Bi-phase ('50) 1 1 0 0 0 Reserved RF/100 1 1 0 RF/128 1 1 1 1) If Master Key = 6 then test mode write commands are ignored 2) If Master Key < > 6 or 9 then extended function mode is disabled 3.10 Modulator The modulator consists of data encoders for the following basic types of modulation: Table 3-1. Mode FSK1a FSK1 FSK2 (1) Types of e5550-compatible Modulation Modes Direct Data Output FSK/8-/5 FSK/8-/10 FSK/5-/8 FSK/10-/8 0 = RF/8; 0 = RF/8; 0 = RF/5; 0 = RF/10; 1 = RF/5 1 = RF/10 1 = RF/8 1 = RF/8 FSK2a(1) (1) (1) (2) PSK1 PSK3 Phase change when input changes Phase change on bit clock if input high Phase change on rising edge of input 0 = falling edge, 1 = rising edge 1 creates an additional mid-bit change 1 = damping on, 0 = damping off PSK2(2) (2) Manchester Bi-phase NRZ Notes: 1. A common multiple of bit rate and FSK frequencies is recommended. 2. In PSK mode the selected data rate has to be an integer multiple of the PSK sub-carrier frequency. 4 ATA5567 ATA5567 3.11 Memory The memory is a 330-bit EEPROM, which is arranged in 10 blocks of 33 bits each. All 33 bits of a block, including the lock bit, are programmed simultaneously. Block 0 of page 0 contains the mode/configuration data, which is not transmitted during regular-read operations. Block 7 of page 0 may be used as a write protection password. Bit 0 of every block is the lock bit for that block. Once locked, the block (including the lock bit itself) is not re-programmable through the RF field. Blocks 1 and 2 of page 1 contain traceability data and are transmitted with the modulation parameters defined in the configuration register after the opcode “11” is issued by the reader (see Figure 4-6 on page 11). These traceability data blocks are programmed and locked by Atmel. Figure 3-3. Memory Map 01 Page 1 32 Traceability data Traceability data User data or password User data User data User data User data User data User data Configuration data Block 2 Block 1 Block 7 Block 6 Block 5 Block 4 Block 3 Block 2 Block 1 Block 0 1 1 L L L Page 0 L L L L L 32 bits Not transmitted 3.12 Traceability Data Structure Blocks 1 and 2 of page 1 contain the traceability data and are programmed and locked by Atmel during production testing(1). The most significant byte of block 1 is fixed to E0h, the allocation class (ACL) as defined in ISO/IEC 15963-1. The second byte is therefore defined as Atmel®’s manufacturer ID (15h). The following 8 bits are used as IC reference byte (ICR bits 47 to 40). The 3 most significant bits define the IC version of the ATA5567, the foundry version, or both. The lower 5 bits are by default reset (00) as the Atmel standard value. Other values may be assigned, by request, to high volume customers as tag issuer identification. The lower 40 bits of the data encode Atmel’s traceability information, and conform to a unique numbering system. These 40 data bits are divided in two sub-groups, a 5-digit lot ID number, and the binary wafer number (5 bits) concatenated with the sequential die number per wafer. Note: 1. This is only valid for sawn wafer “DDB, DDT” delivery. 5 4874F–RFID–07/08 Figure 3-4. ATA5567 Traceability Data Structure Example: "E0" "15" "00" "41" 8 Bit No. Block 1 1 ... ACL 8 9 ... MFC 16 17 CID ... 24 ICR 25 ... LotID 32 63 MSB Bit value 31 Block 2 Bit No. 1 LotID ... ... Wafer # 12 13 DW 18 20 LSB 32 0 ... 12 "557" ... 17 ... 31 32 ACL MFC UID CID ICR LotID Wafer# DW Allocation class as defined in ISO/IEC 15963-1 = E0h Manufacturer code of Atmel Corporation as defined in ISO/IEC 7816-6 = 15h UID issuer identifier on request (respectively 5 bit CID and 3 bit ICR) Customer ID on request IC revision 5-digit lot number, e.g., “41557” 5 bits for wafer# 15 bits encoded as sequential die on wafer number 4. Operating the ATA5567 4.1 Initialization and POR Delay The Power-On-Reset (POR) circuit remains active until an adequate voltage threshold has been reached. This threshold will be reached also if the coil voltage ramps up in terms of a few volts per second. It means that the tag can be moved slowly towards the reader without performance loss. This in turn triggers the default start-up delay sequence. During this configuration period of about 192 field clocks, the ATA5567 is initialized with the configuration data stored in EEPROM block 0. During initialization of the configuration block 0, for all ATA55670x variants the load damping is active permanently (see Figure 4-5 on page 10). The ATA55671x types (without damping option) achieve a longer read range based on the lower activation field strength. If the POR-delay bit is reset, no additional delay is observed after the configuration period. Tag modulation in regular-read mode will be observed about 3 ms after entering the RF field. If the POR delay bit is set, the ATA5567 remains in a permanent damping state until 8190 internal field clocks have elapsed. TINIT = (192 + 8190 × POR delay) × TC ≈ 67 ms; TC = 8 µs at 125 kHz Any field gap occurring during this initialization phase will restart the complete sequence. After this initialization time the ATA5567 enters regular-read mode and modulation starts automatically using the parameters defined in the configuration register. 6 ATA5567 4874F–RFID–07/08 ATA5567 4.2 Tag to Reader Communication During normal operation, the data stored within the EEPROM is cycled and the Coil 1 and Coil 2 terminals are load modulated. This resistive load modulation can be detected at the reader module. 4.3 Regular-read Mode In regular-read mode, data from the memory is transmitted serially, starting with block 1, bit 1, up to the last block (for example, 7), bit 32. The last block which will be read is defined by the mode parameter field MAXBLK in EEPROM block 0. When the data block addressed by MAXBLK has been read, data transmission restarts with block 1, bit 1. The user may limit the cyclic data stream in regular-read mode by setting the MAXBLK between 0 and 7 (representing each of the 8 data blocks). If set to 7, blocks 1 through 7 can be read. If set to 1, only block 1 is transmitted continuously. If set to 0, the contents of the configuration block (normally not transmitted) can be read. In the case of MAXBLK = 0 or 1, regular-read mode can not be distinguished from block-read mode. Figure 4-1. MAXBLK = 5 Examples for Different MAXBLK Settings 0 Block 1 Block 4 Block 5 Block 1 Block 2 Loading block 0 MAXBLK = 2 0 Block 1 Block 2 Block 1 Block 2 Block 1 Loading block 0 MAXBLK = 0 0 Block 0 Block 0 Block 0 Block 0 Block 0 Loading block 0 Every time the ATA5567 enters regular-read or block-read mode, the first bit transmitted is a logical 0. The data stream starts with block 1, bit 1, continues through MAXBLK, bit 32, and cycles continuously if in regular-read mode. Note: This behavior is different from the original e555x and helps to decode PSK-modulated data. 4.4 Block-read Mode With the direct access command, only the addressed block is repetitively read. This mode is called block-read mode. Direct access is entered by transmitting the page access opcode (“10” or “11”), a single “0” bit and the requested 3-bit block address when the tag is in normal mode. In password mode (PWD bit set), the direct access to a single block needs the valid 32-bit password to be transmitted after the page access opcode, whereas a “0” bit and the 3-bit block address follow afterwards. In case the transmitted password does not match with the contents of block 7, the ATA5567 tag returns to the regular-read mode. Note: A direct access to block 0 of page 1 will read the configuration data of block 0, page 0. A direct access to blocks 3 to 7 of page 1 reads all data bits as zero. 7 4874F–RFID–07/08 4.5 e5550 Sequence Terminator The sequence terminator ST is a special damping pattern which is inserted before the first block and may be used to synchronize the reader. This e5550-compatible sequence terminator consists of 4 bit periods with underlaying data values of “1”. During the second and the fourth bit periods, modulation is switched off (Manchester encoding – switched on). Bi-phase modulated data blocks need fixed leading and trailing bits in combination with the sequence terminator to be identified reliably. The sequence terminator may be individually enabled by setting mode bit 29 (ST = 1) in the e5550-compatibility mode (X-mode = 0). In the regular-read mode, the sequence terminator is inserted at the start of each MAXBLK-limited read data stream. In block-read mode – after any block-write or direct access command – or if MAXBLK was set to 0 or 1, the sequence terminator is inserted before the transmission of the selected block. This behavior is especially different from former e5550-compatible ICs (T5551, T5554). Figure 4-2. Read Data Stream with Sequence Terminator No terminator Regular read mode Sequence terminator Sequence terminator Block 1 Block 2 MAXBLK Block 1 Block 2 St = on Block 1 Block 2 MAXBLK Block 1 Block 2 Figure 4-3. e5550-compatible Sequence Terminator Waveforms Bit period Data 1 Data 1 Data 1 Data 1 Sequence Last bit Modulation off (on) Modulation off (on) First bit Waveforms per different modulation types bit 1 or 0 Manchester VCoilPP FSK Sequence terminator not suitable for Bi-phase or PSK modulation 8 ATA5567 4874F–RFID–07/08 ATA5567 4.6 Reader to Tag Communication Data is written to the tag by interrupting the RF field with short field gaps (on-off keying) in accordance with the e5550 write method. The time between two gaps encodes the “0” or “1” information to be transmitted (pulse interval encoding). The duration of the gaps is usually 50 µs to 150 µs. The time between two gaps is nominally 24 field clocks for a “0” and 54 field clocks for a “1”. When there is no gap for more than 64 field clocks after a previous gap, the ATA5567 exits the write mode. The tag starts with the command execution if the correct number of bits were received. If a failure is detected, the ATA5567 does not continue and will enter regular-read mode. 4.7 Start Gap The initial gap is referred to as the start gap. This triggers the reader to tag communication. During this mode of operation, the receive damping is permanently enabled to ease gap detection. The start gap may need to be longer than subsequent gaps in order to be detected reliably. A start gap will be accepted at any time after the mode register has been loaded (≥ 3 ms). A single gap will not change the previously selected page (by former opcode “10” or “11”). Figure 4-4. Start of Reader to Tag Communication Read mode Write mode d1 dn Sgap Wgap Table 4-1. Parameters Start gap Write gap Write Data Decoding Scheme Remark Normal write mode “0” data “1” data Symbol Sgap Wgap d0 d1 Min. 10 8 16 48 Max. 50 30 31 63 Unit FC FC FC FC Write data in normal mode 9 4874F–RFID–07/08 4.8 Write Data Protocol The ATA5567 expects to receive a dual bit opcode as the first two bits of a reader command sequence. There are three valid opcodes: • The opcodes “10” and “11” precede all block write and direct access operations for page 0 and page 1 • The RESET opcode “00” initiates a POR cycle • The opcode “01” precedes all test mode write operations. Any test mode access is ignored after the master key (bits 1 to 4) in block 0 has been set to “6”. Any further modifications of the master key are prohibited by setting the lock bit of block 0 or the OTP bit Writing must follow these rules: • Standard write needs the opcode, the lock bit, 32 data bits, and the 3-bit address (38 bits total) • Protected write (PWD bit set) requires a valid 32-bit password between the opcode and data bits or address bits • For the AOR wake-up command, an opcode and a valid password are necessary to select and activate a specific tag Note: The data bits are read in the same order as written. If the transmitted command sequence is invalid, the ATA5567 enters regular-read mode with the previously selected page (by former opcode “10” or “11”). Figure 4-5. Complete Writing Sequence Read mode ATA55671x ATA556701 Opcode Block data Block address Programming Write mode Read mode Block 0 loading Start gap Lock bit POR 10 ATA5567 4874F–RFID–07/08 ATA5567 Figure 4-6. ATA5567 Command Formats OP Standard write 1p1) L 1 Data 32 2 Addr 0 Protected write 1p1) 1 Password 32 L 1 Data 32 2 Addr 0 AOR (wake-up command) 10 1 Password 32 Direct access (PWD = 1) 1p1) 1 Password 32 0 2 Addr 0 Direct access (PWD = 0) 1p1) 0 2 Addr 0 Page 0/1 regular read 1p1) Reset command 00 1) p = page selector 4.9 Password When password mode is active (PWD = 1), the first 32 bits after the opcode are regarded as the password. They are compared bit by bit with the contents of block 7, starting at bit 1. If the comparison fails, the ATA5567 will not program the memory, instead it will restart in regular-read mode once the command transmission is finished. Note: In password mode, MAXBLK should be set to a value below 7 to prevent the password from being transmitted by the ATA5567. Each transmission of the direct access command (two opcode bits, 32-bit password, “0” bit plus 3 address bits = 38 bits) needs about 18 ms. Testing all possible combinations (about 4.3 billion) would take about two years. 4.10 Answer-On-Request (AOR) Mode When the AOR bit is set, the ATA5567 does not start modulation in the regular-read mode after loading configuration block 0. The tag waits for a valid AOR data stream (wake-up command) from the reader before modulation is enabled. The wake-up command consists of the opcode (“10”) followed by a valid password. The selected tag will remain active until the RF field is turned off or a new command with a different password is transmitted which may address another tag in the RF field. Table 4-2. PWD 1 AOR 1 ATA5567 — Modes of Operation Behavior of Tag after Reset Command or POR Answer-On-Request (AOR) mode: • Modulation starts after wake-up with a matching password • Programming needs valid password Password mode: • Modulation in regular-read mode starts after reset • Programming and direct access needs valid password Normal mode: • Modulation in regular-read mode starts after reset • Programming and direct access without password De-activate Function Command with non-matching password deactivates the selected tag 1 0 0 -- 11 4874F–RFID–07/08 Figure 4-7. Answer-On-Request (AOR) Mode ATA55671x ATA556701 VCoil1 - Coil2 Modulation Block 0 loading No modulation because AOR = 1 POR AOR wake-up command (with valid PWD) Figure 4-8. Coil Voltage after Programming of a Memory Block VCoil 1 - Coil 2 Write data to tag 5.6 ms Programming and data verification Read programmed memory block (Block-read mode) POR or Single gap Read block 1 to MAXBLK (Regular-read mode) 12 ATA5567 4874F–RFID–07/08 ATA5567 Figure 4-9. Anticollision Procedure Using AOR Mode Reader Initialize tags with AOR = 1, PWD = 1 Tag Field OFF ON Power on reset read configuration Wait for tW > 2.5 ms Enter AOR mode Wait for opcode + PWD "wake up command" "Select a single tag" send opcode + PWD "wake up command" Receive damping ON No Password correct ? Yes Decode data Send block 1 to MAXBLK No All tags read ? Yes Field ON OFF Exit 13 4874F–RFID–07/08 4.11 Programming When all necessary information has been received by the ATA5567, programming may proceed. There is a clock delay between the end of the writing sequence and the start of programming. Typical programming time is 5.6 ms. This cycle includes a data verification read to grant secure and correct programming. After programming was executed successfully, the ATA5567 enters block-read mode transmitting the block just programmed (see Figure 4-8 on page 12). Note: This timing and behavior is different from the e555x-family predecessors. 5. Error Handling Several error conditions can be detected to ensure that only valid bits are programmed into the EEPROM. There are two error types, which lead to two different actions. 5.1 Errors During Writing The following detectable errors could occur during writing data to the ATA5567: • Wrong number of field clocks between two gaps (that is, not a valid “1” or “0” pulse stream) • Password mode is activated and the password does not match the contents of block 7 • The number of bits received in the command sequence is incorrect Valid bit counts accepted by the ATA5567 are: Password write Standard write AOR wake up Direct access with PWD Direct access Reset command Page 0/1 regular-read 70 bits 38 bits 34 bits 38 bits 6 bits 2 bits 2 bits (PWD = 1) (PWD = 0) (PWD = 1) (PWD = 1) (PWD = 0) If any of these erroneous conditions were detected, the ATA5567 enters regular-read mode, starting with block 1 of the page defined in the command sequence. 5.2 Errors Before or During Programming If the command sequence was received successfully, the following error could still prevent programming: • The lock bit of the addressed block is set already In case of a locked block, programming mode will not be entered. The ATA5567 reverts to block-read mode, continuously transmitting the currently addressed block. If the command sequence is validated and the addressed block is not write protected, the new data will be programmed into the EEPROM memory. The new state of the block write protection bit (lock bit) will be programmed at the same time accordingly. Each programming cycle consists of 4 consecutive steps: erase block, erase verification (data = 0 ), programming, write verification (corresponding data bits = 1). • If a data verification error is detected after an executed data block programming, the tag will stop modulation (modulation defeat) until a new command is transmitted. 14 ATA5567 4874F–RFID–07/08 ATA5567 Figure 5-1. ATA5567 Functional Diagram Power-on reset Setup modes AOR = 0 Regular-read mode Page 0 addr = 1 to MAXBLK AOR = 1 AOR mode Page 0 or 1 Start gap Gap Modulation defeat Command mode Command decode OP(11..) Page 1 OP(00) Reset to page 0 OP(10..) Write OP(1p) 1) Write Number of bits Password check Lock bit check Data verification failed 1) Gap Block-read mode addr = current Direct access OP(1p) 1) OP(1p) 1) Single gap Page 0 OP(01) Test mode if master key < > 6 Fail Fail Fail Ok data = old data = old data = old data = new Program and verify p = page selector 6. ATA5567 in Extended Mode (X-mode) In general, the block 0 setting of the master key (bits 1 to 4) to the value “6” or “9” together with the X-mode bit will enable the extended mode functions. • Master key = 9: Test mode access and extended mode are both enabled. • Master key = 6: Any test mode access will be denied but the extended mode is still enabled. Any other master key setting will prevent the activation of the ATA5567 extended mode options, even when the X-mode bit is set. 15 4874F–RFID–07/08 6.1 Binary Bit-rate Generator In extended mode the data rate is binary programmable to operate at any data rate between RF/2 and RF/128 as given in the formula below. Data rate = RF / (2n + 2) 6.2 OTP Functionality If the OTP bit is set to “1”, all memory blocks are write protected and behave as if all lock bits are set to 1. If the master key is set to “6” additionally, the ATA5567 mode of operation is locked forever (= OTP functionality). If the master key is set to “9”, the test-mode access allows the re-configuration of the tag again. Figure 6-1. Block 0 — Configuration Map in Extended Mode (X-mode) L 12 10 34 01 56 00 78 00 n5 n4 n3 n2 n1 n0 Data Bit Rate RF/(2n+2) Direct PSK1 0 1 Unlocked Locked PSK2 PSK3 FSK1 FSK2 Manchester 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 1 X-mode PWD AOR OTP SST-sequence Start Marker Modulation PSK CF Max Block Lock Bit Master Key Note 1), 2) Fast Write Inverse Data 0 0 RF/2 00000 00001 00010 00011 00100 00101 01000 0 1 RF/4 1 0 RF/8 1 1 Res Bi-phase ('50) 1 0 0 0 1 Bi-phase ('57) 1 1 0 0 0 1) If Master Key = 6 and bit 15 is set, then test mode access is disabled and extended mode is active 2) If Master Key = 9 and bit 15 is set, then extended mode is enabled Table 6-1. Mode FSK1 FSK2 (1) (1) (2) ATA5567 Types of Modulation in Extended Mode Direct Data Output Encoding FSK/5-/8 FSK/10-/8 0 = RF/5; 1 = RF/8 0 = RF/10; 1 = RF/8 Inverse Data Output Encoding FSK/8-/5 FSK/8-/10 0 = RF/8; 1 = RF/5 0 = RF/8; 1 = RF/10 (= FSK1a) (= FSK2a) PSK1 Phase change when input changes Phase change on bit clock if input high Phase change on rising edge of input 0 = falling edge, 1 = rising edge on mid-bit “1” creates an additional mid-bit change “0” creates an additional mid-bit change 1 = damping on, 0 = damping off Phase change when input changes Phase change on bit clock if input low Phase change on falling edge of input 1 = falling edge, 0 = rising edge on mid-bit “0” creates an additional mid-bit change “1” creates an additional mid-bit change 0 = damping on, 1 = damping off PSK2(2) PSK3(2) Manchester Bi-phase 1 (’50) Bi-phase 2 (’57) NRZ Notes: 1. A common multiple of bit rate and FSK frequencies is recommended. 2. In PSK mode the selected data rate has to be an integer multiple of the PSK sub-carrier frequency. 16 ATA5567 4874F–RFID–07/08 POR delay ATA5567 6.3 Sequence Start Marker ATA5567 Sequence Start Marker in Extended Mode Sequence Start Marker Figure 6-2. Block read mode 10 Block n 01 Block n 10 Block n 01 Block n 10 Block n 01 Regular read mode 10 Block 1 Block 2 MAXBLK 01 Block 1 Block 2 MAXBLK 10 The ATA5567 sequence start marker is a special damping pattern, which may be used to synchronize the reader. The sequence start marker consists of two bits (“01” or “10”) which are inserted as a header before the first block to be transmitted if bit 29 in extended mode is set. At the start of a new block sequence, the value of the two bits is inverted. 6.4 Inverse Data Output The ATA5567 supports in its extended mode (X-mode) an inverse data output option. If inverse data is enabled, the modulator as shown in Figure 6-3 works on inverted data (see Table 6-1 on page 16). This function is supported for all basic types of encoding. Figure 6-3. Data Encoder for Inverse Data Output PSK1 PSK2 PSK3 Intern out data D Sync XOR Direct/NRZ MUX FSK1 Data output Data clock CLK R FSK2 Manchester Biphase Inverse data output Modulator 17 4874F–RFID–07/08 6.5 Fast Write In the optional fast write mode, the time between two gaps is nominally 12 field clocks for a “0” and 27 field clocks for a “1”. When there is no gap for more than 32 field clocks after a previous gap, the ATA5567 will exit the write mode. Please refer to Table 6-2 and Figure 4-3 on page 8. Table 6-2. Parameters Start gap Write gap Fast Write Data Decoding Schemes Remark – Normal write mode Fast write mode “0” data “1” data “0” data “1” data Symbol Sgap Wngap Wfgap d0 d1 d0 d1 Min. 10 8 8 16 48 8 24 Max. 50 30 20 31 63 15 31 Unit FC FC FC FC FC FC FC Write data in normal mode Write data in fast mode 18 ATA5567 4874F–RFID–07/08 4874F–RFID–07/08 Figure 6-4. 1 0 0 1 1 0 Data rate = 16 field clocks (FC) 8 FC 8 FC Data stream Inverted modulator signal Manchester coded 9 8 9 16 16 1 8 1 8 16 1 8 9 16 12 8 9 16 1 8 9 16 12 Example of Manchester Coding with Data Rate RF/16 RF-field ATA5567 19 20 Figure 6-5. 1 0 0 1 1 0 8 FC 8 FC 8 9 16 1 8 1 89 16 16 1 8 9 16 12 8 9 16 1 89 16 ATA5567 Example of Bi-phase Coding with Data Rate RF/16 Data rate = 16 field clocks (FC) Data stream Inverted modulator signal Bi-phase coded 12 RF-field 4874F–RFID–07/08 ATA5567 Figure 6-6. Example: FSK1a Coding with Data Rate RF/40, Subcarrier f0 = RF/8, f1 = RF/5 0 1 1 0 0 Data rate = 40 field clocks (FC) 1 15 1 8 1 8 15 15 1 8 f0 = RF/8 Inverted modulator signal Data stream f1 = RF/5 RF-field 21 4874F–RFID–07/08 22 Figure 6-7. 1 0 0 1 1 0 8 FC ATA5567 Example of PSK1 Coding with Data Rate RF/16 89 16 1 8 16 1 8 16 1 8 16 1 8 16 1 8 Data rate = 16 field clocks (FC) 8 FC Data stream Inverted modulator signal Subcarrier RF/2 12 RF-field 4874F–RFID–07/08 4874F–RFID–07/08 Figure 6-8. 1 0 0 1 1 0 Data rate = 16 field clocks (FC) 8 FC 8 FC Data stream Inverted modulator signal 89 16 1 8 16 1 8 16 1 8 16 1 8 16 1 8 Subcarrier RF/2 Example of PSK2 Coding with Data Rate RF/16 12 RF-field ATA5567 23 24 Figure 6-9. 1 0 0 1 1 0 8 FC ATA5567 Example of PSK3 Coding with Data Rate RF/16 89 16 1 8 16 1 8 16 1 8 16 1 8 16 1 8 Data rate = 16 field clocks (FC) 8 FC Data stream Inverted modulator signal Subcarrier RF/2 12 RF-field 4874F–RFID–07/08 ATA5567 7. Absolute Maximum Ratings Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Parameters Maximum DC current into Coil 1/Coil 2 Maximum AC current into Coil 1/Coil 2 f = 125 kHz Power dissipation (die) (free-air condition, time of application: 1s) Electrostatic discharge maximum to MIL-Standard 883 C method 3015 Operating ambient temperature range Storage temperature range (data retention reduced) Symbol Icoil Icoil p Ptot Vmax Tamb Tstg Value 20 20 100 4000 –40 to +85 –40 to +150 Unit mA mA mW V °C °C 8. Electrical Characteristics Tamb = +25°C; fcoil = 125 kHz; unless otherwise specified No. 1 2.1 2.2 2.3 3.1 3.2 3.3 4.1 4.2 5 Start-up time Start-up voltage ramp Clamp voltage Coil voltage (AC supply) Parameters RF frequency range Supply current (without current consumed Read – full temperature by the external LC tank range circuit) Programming – full temperature range POR threshold (50 mV hysteresis) Read mode and write command(2) Program EEPROM(2) Vcoil pp = 6V Vcoil pp = 0 to 6V 10 mA current into Coil 1/Coil 2 tstartup tmax Vclamp 17 Vcoil pp Tamb = 25°C(1) (see Figure 6-9 on page 24) IDD Test Conditions Symbol fRF Min. 100 Typ. 125 1.5 2 25 3.2 6 8 2.5 3.6 Max. 150 3 4 40 4.0 Vclamp Vclamp 3 1 23 Unit kHz µA µA µA V V V ms s V T Q Q Q Q Q Q Q T Type* *) Type means: T: directly or indirectly tested during production; Q: guaranteed based on initial product qualification data Notes: 1. IDD measurement setup R = 100 kΩ; VCLK = Vcoil = 5V: EEPROM programmed to 00 ... 000 (erase all); chip in modulation defeat. IDD = (VOUTmax – VCLK) / R 2. Current into Coil 1/Coil 2 is limited to 10 mA. The damping circuitry has the same structure as the e5550. The damping characteristics are defined by the internally limited supply voltage (= minimum AC coil voltage) 3. Vmod measurement setup: R = 2.3 kΩ; VCLK = 3V; setup with modulation enabled (see Figure 8-1 on page 26). 4. Since EEPROM performance is influenced by assembly processes, Atmel confirms the parameters for DOW (tested die on uncut wafer) delivery. 5. The tolerance of the on-chip resonance capacitor Cr is ±10% at 3σ over whole production. The capacitor tolerance is ±3% at 3σ on a wafer basis. 6. The tolerance of the micromodule resonance capacitor Cr is ±5% at 3σ over whole production. 25 4874F–RFID–07/08 8. Electrical Characteristics (Continued) Tamb = +25°C; fcoil = 125 kHz; unless otherwise specified No. 6.1 6.2 6.3 7 8 9.1 9.2 9.3 10 11.1 Micromodule capacitor 11.2 parameters 11.3 Notes: Resonance capacitor Data retention Programming time Endurance Modulation parameters Parameters Test Conditions Vcoilpp = 6V on test circuit generator and modulation ON(3) Thermal stability From last command gap to re-enter read mode (64 + 648 internal clocks) Erase all/Write all(4) Top = 55°C (4) (4) Symbol V mod pp I mod pp Vmod/Tamb Tprog ncycle tretention tretention tretention Cr Cr TBD TBD Min. Typ. 4.2 Max. 4.8 Unit V µA mV/°C Type* T T Q T Q T Q T T TBD TBD 400 600 –6 5 100,000 10 96 24 70 313.5 TBD TBD 5.7 6 ms Cycles 20 50 Years hrs hrs Top = 150°C Top = 250°C(4) Mask option(5) Capacitance tolerance Tamb Temperature coefficient 78 330 TBD TBD 86 346.5 TBD TBD pF pF TBD TBD *) Type means: T: directly or indirectly tested during production; Q: guaranteed based on initial product qualification data 1. IDD measurement setup R = 100 kΩ; VCLK = Vcoil = 5V: EEPROM programmed to 00 ... 000 (erase all); chip in modulation defeat. IDD = (VOUTmax – VCLK) / R 2. Current into Coil 1/Coil 2 is limited to 10 mA. The damping circuitry has the same structure as the e5550. The damping characteristics are defined by the internally limited supply voltage (= minimum AC coil voltage) 3. Vmod measurement setup: R = 2.3 kΩ; VCLK = 3V; setup with modulation enabled (see Figure 8-1 on page 26). 4. Since EEPROM performance is influenced by assembly processes, Atmel confirms the parameters for DOW (tested die on uncut wafer) delivery. 5. The tolerance of the on-chip resonance capacitor Cr is ±10% at 3σ over whole production. The capacitor tolerance is ±3% at 3σ on a wafer basis. 6. The tolerance of the micromodule resonance capacitor Cr is ±5% at 3σ over whole production. Figure 8-1. Measurement Setup for IDD and Vmod R BAT68 Coil 1 750Ω VOUTmax 750Ω Coil 2 Substrate BAT68 26 ATA5567 4874F–RFID–07/08 ATA5567 9. Ordering Information(1) ATA5567 ab -xxx Package - DDW - DDT 1 - DDB 11N 14N 01N Note: - Die on wafer, 6” unsawn wafer, thickness 300 µm (on request) - Die in tray (waffle pack), thickness 300 µm - Die on foil, 6” sawn wafer with ring, thickness 150 µm - 2 pads without on-chip capacitor - 4 pads with on-chip 75 pF capacitor - 2 pads without capacitor, damping during initialization Figure 10-3 on page 30 Figure 10-1 on page 28 Figure 10-2 on page 29 Figure 10-1 on page 28 Drawing 1. For available order codes, contact your local Atmel Sales/Marketing office. ATA556711 -xxx Package - TASY - SO8 package (lead-free) Drawing Figure 10-7 on page 34 ATA556715 -xxx Package - PAE - NOA3 micromodule (lead-free) Drawing Figure 10-5 on page 32 and Figure 10-6 on page 33 9.1 Ordering Examples ATA556714N-DDB Tested die on sawn 6” wafer on foil with ring, thickness 150 µm, 75 pF on-chip capacitor, no damping during POR initialization; especially for ISO 11784/785 and access control applications 9.2 Available Order Codes ATA556711N-DDT 1 ATA556711N-DDB ATA556714N-DDB ATA556715-PAE ATA556711-TASY New order codes will be created by customer request if order quantities are over 250k pieces. 27 4874F–RFID–07/08 10. Package Information Figure 10-1. 2-pad Layout Dimensions in µm 124 94 994 134.5 149.5 ATA5567 934 87 125 497 28 ATA5567 4874F–RFID–07/08 72 C2 125 ATA5567 Figure 10-2. 4-pad Layout Dimensions in µm 124 94 994 82 142 97 60 157 60 ATA5567 934 107 100 497 92 C2 100 29 4874F–RFID–07/08 Figure 10-3. 6” Sawn Wafer with Ring, Thickness 150 µm 59.5 63.6 30 ˚ 30 ˚ 30 ˚ 87.5 86.5 A ∅1 94 .5 A ∅227.7 212 A-A 2.5 2.5:1 (∅194.5) 1.5x45˚ 30 ATA5567 4874F–RFID–07/08 212 ATA5567 Figure 10-4. Wafer Map Die: 0.894 × 0.864, Step: 0.994 × 0.934, N: 14 × 7, Frame Step: 13.916 × 15.878 > Shift-ASML = [0.3; –6.9]: 15539 dice, 87 shots (11 columns × 9 rows) > Shift-CANON/ALARM/SEM = [0.3; –6.9] – W2 = [–13.152; 6.9] – W1 = [–6.648; 6.9] 10.1 Failed Die Identification Every die on the wafer not passing Atmel’s test sequence is marked with ink. The ink dot specification: • Dot size: 200 µm • Position: center of die • Color: black 31 4874F–RFID–07/08 Figure 10-5. NOA3 Micromodule 9.5±0.03 4.75+0.02 1.42±0.05 0.03 A B 4.625 31.83 1.42±0.05 25.565 21.815 ∅ 2±0.05 Note 1 15.915 12.165 6.265 2.515 0 1.585 technical drawings according to DIN specifications B Dimensions in mm A X X5:1 Note: 1. Reject hole by testing device 2. Punching cutline recommendation for singulation 3. Total package thickness exclusive punching burr 4. Module dimension after electrical disconnection 2.375 2.375 4.8±0.05 0.05 A Note 3 0.05 B 4874F–RFID–07/08 0.38-0.035 5.15±0.03 0.03 B Note 2 R1.5±0.03 0.09-0.01 8.1±0.03 Note 2 R0.2 max. Drawing-No.: 6.549-5035.01-4 Issue: 1; 28.04.06 Subcontractor: NedCard Drawing refers to following types: Micromodule NOA-3 5.06±0.03 Note 4 R1.1±0.03 (4x) 32 ATA5567 5.1±0.05 8-0.02 Note 4 ATA5567 Figure 10-6. Shipping Reel Ø 329.6 41.4 to max 43.0 0 ˚ (3 x) 2.3 Ø171 Ø175 16.7 2 2.2 Ø 298.5 R1.14 Ø13 12 33 4874F–RFID–07/08 Figure 10-7. SO8 Package Package: SO 8 Dimensions in mm 4.9±0.1 5±0.2 3.7±0.1 0.2 0.1+0.15 1.4 0.4 1.27 3.81 3.8±0.1 6±0.2 8 5 technical drawings according to DIN specifications 1 Drawing-No.: 6.541-5031.01-4 Issue: 1; 15.08.06 Figure 10-8. Pinning SO8 4 COIL2 NC NC NC 1 2 3 4 8 7 6 5 COIL1 NC NC NC 34 ATA5567 4874F–RFID–07/08 ATA5567 11. Revision History Please note that the following page numbers referred to in this section refer to the specific revision mentioned, not to this document. Revision No. 4874F-RFID-07/08 History • Section 3.12 “Traceability Data Structure” on page 5 changed • Section 6 “ATA5567 in Extended Mode (X-mode) on page 15 changed • Section 9 “Ordering Information” on page 27 changed • Put datasheet in a new template • Section 9 “Ordering Information” on page 27 changed • Old Figure 10-3 “Solder Bump on NiAu” replaced with new Figure 10-3 “6” Sawn Wafer with Ring, Thickness 150 µm” 4874E-RFID-10/07 35 4874F–RFID–07/08 Headquarters Atmel Corporation 2325 Orchard Parkway San Jose, CA 95131 USA Tel: 1(408) 441-0311 Fax: 1(408) 487-2600 International Atmel Asia Room 1219 Chinachem Golden Plaza 77 Mody Road Tsimshatsui East Kowloon Hong Kong Tel: (852) 2721-9778 Fax: (852) 2722-1369 Atmel Europe Le Krebs 8, Rue Jean-Pierre Timbaud BP 309 78054 Saint-Quentin-en-Yvelines Cedex France Tel: (33) 1-30-60-70-00 Fax: (33) 1-30-60-71-11 Atmel Japan 9F, Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan Tel: (81) 3-3523-3551 Fax: (81) 3-3523-7581 Product Contact Web Site www.atmel.com Technical Support rfid@atmel.com Sales Contact www.atmel.com/contacts Literature Requests www.atmel.com/literature Disclaimer: T he information in this document is provided in connection with Atmel products. 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