MAXIM MAX66040E

ABRIDGED DATA SHEET
219-0012; Rev 0; 1/11
KIT
ATION
EVALU
E
L
B
AVAILA
ISO/IEC 14443 Type B-Compliant
Secure Memory
The MAX66040 combines 1024 bits of user EEPROM
with secure hash algorithm (SHA-1) challenge-andresponse authentication (ISO/IEC 10118-3 SHA-1), a
64-bit unique identifier (UID), one 64-bit secret, and a
13.56MHz RF interface (ISO/IEC 14443 Type B, Parts 24) in a single chip. The memory is organized as 16
blocks of 8 bytes plus three more blocks, one for the
secret and two for data and control registers. Except for
the secret, each block has a user-readable write-cycle
counter. Four adjacent user EEPROM blocks form a
memory page (pages 0 to 3). The integrated SHA-1
engine provides a message authentication code (MAC)
using data from the EEPROM of the device and the 64bit secret to guarantee secure, symmetric authentication for both reading and writing to the device. Memory
protection features are write protection and EPROM
emulation, which the user can set for each individual
memory page. Page 3 can also be read-protected for
enhanced authentication strength. Memory access is
accomplished through the block transmission protocol
(ISO/IEC 14443-4), where requests and responses are
exchanged through I-blocks once a device is in the
ACTIVE state. The data rate can be as high as
847.5kbps. The reader must support a frame size of 26
bytes. The device supports an application family identifier (AFI) and a card identifier (CID). ISO/IEC 14443
functions not supported are chaining, frame-waiting
time extension, and power indication.
Applications
Driver Identification (Fleet Application)
Features
♦ Fully Compliant ISO/IEC 14443 (Parts 2-4) Type B
Interface
♦ 13.56MHz ±7kHz Carrier Frequency
♦ 1024-Bit Secure User EEPROM with Block Lock
Feature, Write-Cycle Counter, and Optional
EPROM-Emulation Mode
♦ 64-Bit UID
♦ 512-Bit SHA-1 Engine to Compute 160-Bit MAC
and to Generate Secrets
♦ Mutual Authentication: Data Read from Device is
Verified and Authenticated by the Host with
Knowledge of the 64-Bit Secret
♦ Read and Write (64-Bit Block)
♦ Supports AFI and CID Function
♦ 10ms Maximum Programming Time
♦ Write: 10% ASK Modulation at 105.9kbps,
211.9kbps, 423.75kbps, or 847.5kbps
♦ Read: Load Modulation Using BPSK Modulated
Subcarrier at 105.9kbps, 211.9kbps, 423.75kbps,
or 847.5kbps
♦ 200,000 Write/Erase Cycles (Minimum)
♦ 40-Year Data Retention (Minimum)
Ordering Information
PART
TEMP RANGE
PIN-PACKAGE
MAX66040E-000AA+
-25°C to +50°C
ISO Card
MAX66040K-000AA+
-25°C to +50°C
Key Fob
+Denotes a lead(Pb)-free/RoHS-compliant package.
Access Control
e-Cash
Mechanical Drawings appear at end of data sheet.
Asset Tracking
Typical Operating Circuit
13.56MHz READER
MAGNETIC
COUPLING
MAX66040
TX_OUT
IC LOAD
TRANSMITTER
RX_IN
ANTENNA
SWITCHED
LOAD
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
1
MAX66040
General Description
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
ABSOLUTE MAXIMUM RATINGS
Maximum Incident Magnetic Field Strength ..........141.5dBµA/m
Operating Temperature Range ...........................-25°C to +50°C
Relative Humidity ..............................................(Water Resistant)
Storage Temperature Range ...............................-25°C to +50°C
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
ELECTRICAL CHARACTERISTICS
(TA = -25°C to +50°C.) (Note 1)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
SHA-1 ENGINE
SHA-1 Computation Time
tCSHA
Refer to the full data sheet.
ms
EEPROM
Programming Time
Endurance
Data Retention
tPROG
NCYCLE
9
At +25°C
tRET
10
ms
200,000
cycles
40
years
RF INTERFACE
Carrier Frequency
fC
Operating Magnetic Field Strength
(Note 1)
H
Power-Up Time
tPOR
(Note 1)
13.553
13.560
At +25°C, MAX66040E
110.0
137.5
At +25°C, MAX66040K
123.5
137.5
(Note 2)
13.567
1.0
MHz
dBμA/m
ms
Note 1: System requirement.
Note 2: Measured from the time at which the incident field is present with strength greater than or equal to H(MIN) to the time at
which the MAX66040’s internal power-on reset signal is deasserted and the device is ready to receive a command frame.
Not characterized or production tested; guaranteed by simulation only.
2
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ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
The MAX66040 combines 1024 bits of user EEPROM,
128 bits of user and control registers, a 64-bit UID, one
64-bit secret, a 512-bit SHA-1 engine, and a 13.56MHz
RF interface (ISO/IEC 14443 Type B, Parts 2-4) in a single chip. The memory is organized as 19 blocks of 8
bytes each. Except for the secret, each block has a
user-readable write-cycle counter. Four adjacent user
EEPROM blocks form a memory page (pages 0 to 3).
Memory protection features include write protection
and EPROM emulation, which the user can set for each
individual memory page. Page 3 can also be read protected for enhanced authentication strength. The
MAX66040 is accessed through the ISO/IEC 14443-4
block transmission protocol, where requests and
responses are exchanged through I-blocks once a
device is in the ACTIVE state. The reader must support
a frame size of at least 26 bytes. The data rate can be
as high as 847.5kbps. The MAX66040 supports AFI
and CID. Functions not supported are chaining, framewaiting time extension, and power indication.
Applications of the MAX66040 include driver identification (fleet application), access control, electronic cash
(e-cash), and asset tracking.
Overview
Figure 1 shows the relationships between the major
control and memory sections of the MAX66040. The
device has six main data components: 64-bit UID,
64-bit read/write buffer, four 256-bit pages of user
EEPROM, two 8-byte blocks of user and control registers, 64-bit secret’s memory, and a 512-bit SHA-1
engine. Figure 2 shows the hierarchical structure of the
ISO/IEC 14443 Type B-compliant access protocol. The
master must first apply network function commands to
put the MAX66040 into the ACTIVE state before the
memory and control functions become accessible. The
protocol required for these network function commands
is described in the Network Function Commands section. Once the MAX66040 is in the ACTIVE state, the
master can issue any one of the available memory and
control function commands. Upon completion of such a
command, the MAX66040 returns to the ACTIVE state
and the master can issue another memory and control
function command or deselect the device, which
returns it to the HALT state. The protocol for these
memory and control function commands is described in
the Memory and Control Function Commands section.
All data is read and written least significant bit (LSb)
first, starting with the least significant byte (LSB).
Parasite Power
As a wireless device, the MAX66040 is not connected
to any power source. It gets the energy for operation
from the surrounding RF field, which needs to have a
minimum strength as specified in the Electrical
Characteristics table.
INTERNALSUPPLY
VOLTAGE
REGULATOR
RF
FRONTEND
ISO 14443
DATA
fc
MODULATION
FRAME
FORMATTING
AND
ERROR
DETECTION
UID
MEMORY AND
FUNCTION
CONTROL
SHA-1
ENGINE
SECRET
READ/WRITE BUFFER
REGISTER
BLOCK
USER
EEPROM
Figure 1. Block Diagram
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3
MAX66040
Detailed Description
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
MAX66040
COMMAND LEVEL:
NETWORK
FUNCTION COMMANDS
MEMORY AND CONTROL
FUNCTION COMMANDS
AVAILABLE COMMANDS:
DATA FIELD AFFECTED:
REQUEST (REQB)
WAKEUP (WUPB)
SLOT-MARKER
HALT (HLTB)
SELECT (ATTRIB)
DESELECT (DESELECT)
AFI, ADMINISTRATIVE DATA
AFI, ADMINISTRATIVE DATA
(ADMINISTRATIVE DATA)
PUPI
PUPI, ADMINISTRATIVE DATA
(ADMINISTRATIVE DATA)
GET SYSTEM INFORMATION
64-BIT UID, AFI, CONSTANTS
Refer to the full data sheet.
GET UID
64-BIT UID
Figure 2. Hierarchical Structure of ISO/IEC 14443 Type B Protocol
MSB
LSB
64
57 56
E0h
49 48
2Bh
45 44
0h
37 36
FEATURE CODE (03h)
1
36-BIT IC SERIAL NUMBER
Figure 3. 64-Bit UID
Unique Identification Number (UID)
Each MAX66040 contains a factory-programmed and
locked identification number that is 64 bits long
(Figure 3). The lower 36 bits are the serial number of
the chip. The next 8 bits store the device feature code,
which is 03h. Bits 45 to 48 are 0h. The code in bit locations 49 to 56 identifies the chip manufacturer, according to ISO/IEC 7816-6/AM1. This code is 2Bh for
Maxim. The code in the upper 8 bits is E0h. The UID is
read accessible through the Get UID and Get System
Information commands. The lower 32 bits of the UID are
transmitted in the PUPI field of the ATQB response to
the REQB, WUPB, or SLOT-MARKER command. By
default, the upper 32 bits of the UID are factory programmed into the application data field, which is transmitted as part of the ATQB response. This way the
master receives the complete UID in the first response
4
from the slave. See the Network Function Commands
section for details.
Detailed Memory Description
Refer to the full data sheet for this information.
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ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
MAX66040
LSB
1
0
START
BIT 1
MSB
BIT 2
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
STOP
Figure 5. ISO/IEC 14443 Data Character Format
ISO/IEC 14443 Type B
Communication Concept
The communication between the master and the
MAX66040 (slave) is based on the exchange of data
packets. The master initiates every transaction; only
one side (master or slaves) transmits information at any
time. Data packets are composed of characters, which
always begin with a START bit and typically end with
one or more STOP bits (Figure 5). The least significant
data bit is transmitted first. Data characters have 8 bits.
Each data packet begins with a start-of-frame (SOF)
character and ends with an end-of-frame (EOF) character. The EOF/SOF characters have 9 all-zero data bits
(Figure 6). The SOF has 2 STOP bits, after which data
characters are transmitted. A data packet with at least
3 bytes between SOF and EOF is called a frame
(Figure 7). The last two data characters of an
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7
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
STOP/IDLE
1
0
START
BIT 1
BIT 2
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
BIT 9
Figure 6. ISO/IEC 14443 SOF/EOF Character Format
SOF
ONE OR MORE DATA CHARACTERS
CRC (LSB)
CRC (MSB)
EOF
TIME
Figure 7. ISO/IEC 14443 Frame Format
CARRIER AMPLITUDE
MODULATION INDEX
1
0
1
M = A - B = 0.08 TO 0.14
A+B
1
0
1
A
B
t
Figure 8. Downlink: 8% to 14% Amplitude Modulation
ISO/IEC 14443 Type B frame are an inverted 16-bit
CRC of the preceding data characters generated
according to the CRC-16-CCITT polynomial. This CRC
is transmitted with the LSB first. For more details on the
CRC-16-CCITT, refer to ISO/IEC 14443-3, Annex B.
With network function commands, the command code,
parameters, and response are embedded between
SOF and CRC. With memory function commands, command code, and parameters are placed into the information field of I-blocks (see the Block Types section),
which in turn are embedded between SOF and EOF.
8
For transmission, the frame information is modulated on
a carrier frequency, which in the case of ISO/IEC 14443
is 13.56MHz. The subsequent paragraphs are a concise description of the required modulation and coding.
For full details including SOF/EOF and subcarrier on/off
timing, refer to ISO/IEC 14443-3, Sections 7.1 and 7.2.
The path from master to slave uses amplitude modulation with a modulation index between 8% and 14%
(Figure 8). In this direction, a START bit and logic 0 bit
correspond to a modulated carrier; STOP bit and
logic 1 bit correspond to the unmodulated carrier. EOF
ends with an unmodulated carrier instead of STOP bits.
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ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
DATA TO BE TRANSMITTED
847kHz SUBCARRIER
BPSK MODULATION
1
0
1
OR
TRANSMISSION OF A SINGLE BIT
POWER-UP DEFAULT = EIGHT CYCLES OF 847kHz (9.44μs)
CAN BE REDUCED TO FOUR, TWO, OR ONE SUBCARRIER CYCLES FOR COMMUNICATION IN THE ACTIVE STATE.
INDICATES 180° PHASE CHANGE (POLARITY REVERSAL)
Figure 9. Uplink: BPSK Modulation of the 847.5kHz Subcarrier
DATA*
1
0
1
TRANSMISSION OF A SINGLE BIT
SHOWN AS EIGHT CYCLES OF THE 847kHz SUBCARRIER
*DEPENDING ON THE INITIAL PHASE, THE DATA POLARITY MAY BE INVERSE.
Figure 10. Uplink: Load Modulation of the RF Field by the BPSK Modulated Subcarrier
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9
MAX66040
corresponds to logic 1. The phase of the subcarrier
changes by 180° whenever there is a binary transition
in the character to be transmitted (Figure 9). The first
phase transition represents a change from logic 1 to
logic 0, which coincides with the beginning of the SOF.
The BPSK modulated subcarrier is used to modulate
the load on the device’s antenna (Figure 10).
The path from slave to master uses an 847.5kHz subcarrier, which is modulated using binary phase-shift key
(BPSK) modulation. Depending on the data rate, the
transmission of a single bit takes 8, 4, 2 or 1 subcarrier
cycles. The slave generates the subcarrier only when
needed; i.e., starting shortly before an SOF and ending
shortly after an EOF. The standard defines the phase of
the subcarrier before the SOF as 0° reference, which
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
PROLOGUE FIELD
INFORMATION FIELD
EPILOGUE FIELD
PCB
CID
NAD
(DATA)
CRC
(LSB)
CRC
(MSB)
1 BYTE
1 BYTE
1 BYTE
0 OR MORE BYTES
1 BYTE
1 BYTE
Figure 11. ISO/IEC 14443-4 Type B Block Format
LSB
MSB
BIT 8
MSB
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 8
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
0
0
0
CH
CID
NAD
1
#
1
0
1
AN
CID
0
1
#
Figure 12. Bit Assignments for I-Block PCB
Figure 13. Bit Assignments for R-Block PCB
ISO/IEC 14443 Block
Transmission Protocol
Before the master can send a data packet to access the
memory, the MAX66040 must be in the ACTIVE state.
The protocol to put the MAX66040 into the ACTIVE state
is explained in the Network Function Commands section. While in the ACTIVE state, the communication
between master and MAX66040 follows the block transmission protocol as specified in Section 7 of ISO/IEC
14443-4. Such a block (Figure 11) consists of three
parts: the prologue field, the information field, and the
epilogue field. The prologue can contain up to 3 bytes,
called the protocol control byte (PCB), card identifier
(CID), and the node address (NAD). Epilogue is another
name for the 16-bit CRC that precedes the EOF. The
information field is the general location for data.
Block Types
The standard defines three types of blocks: I-block,
R-block, and S-block. Figures 12, 13, and 14 show the
applicable PCB bit assignments.
The I-block is the main tool to access the memory and
to run the SHA-1 engine. For I-blocks, bit 2 must be 1
and bit 6, bit 7, and bit 8 must be 0. Bit 5, marked as
CH, is used to indicate chaining, a function that is not
used or supported by the MAX66040. Therefore, bit 5
10
LSB
must always be 0. Bit 4, marked as CID, is used by the
master to indicate whether the prologue field contains a
CID byte. The MAX66040 processes blocks with and
without CID as defined in the standard. The master
must include the CID byte if bit 4 is 1. Bit 3, marked as
NAD, is used to indicate whether the prologue field
contains an NAD byte, a feature not supported by the
MAX66040. Therefore, bit 3 must always be 0. Bit 1,
marked as #, is the block number field. The block number is used to ensure that the response received relates
to the request sent. This function is important in the
error handling, which is illustrated in Annex B of
ISO/IEC 14443-4. The rules that govern the numbering
and handling of blocks are found in sections 7.5.3 and
7.5.4 of ISO/IEC 14443-4. The MAX66040 ignores
I-blocks that have bit 5 or bit 3 set to 1.
For R-blocks, the states of bit 2, bit 3, and bit 6, bit 7,
and bit 8 are fixed and must be transmitted as shown in
Figure 13. The function of bit 1 (block number) and bit 4
(CID indicator) is the same as for I-blocks. Bit 5,
marked as AN, is used to acknowledge (if transmitted
as 0) or not to acknowledge (if transmitted as 1) the
reception of the last frame for recovery from certain
error conditions. The MAX66040 fully supports the function of the R-block as defined in the standard. For
details and the applicable rules, refer to Sections 7.5.3
and 7.5.4 and Annex B of ISO/IEC 14443-4.
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ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
LSB
BIT 7
1
1
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
CID
0
1
0
Figure 14. Bit Assignments for S-Block PCB
MSB
LSB
BIT 8
BIT 7
BIT 6
BIT 5
0
0
0
0
(POWER LEVEL)
BIT 4
(FIXED)
BIT 3
BIT 2
BIT 1
CARD IDENTIFIER VALUE
Figure 15. Bit Assignments for CID Byte in I-Blocks
SOF
PCB
CID
INFORMATION FIELD
CRC (LSB) CRC (MSB)
EOF
Figure 16. Frame Format for Block Transmission Protocol
For S-blocks, the states of bit 1, bit 2, and bit 3, and bit 7
and bit 8 are fixed and must be transmitted as shown in
Figure 14. The function of bit 4 (CID indicator) is the
same as for I-blocks. Bit 5 and bit 6, when being 00b,
specify whether the S-block represents a deselect command. If bit 5 and bit 6 are 11b, the S-block represents a
frame-waiting time extension (WTX) request, a feature to
tell the master that the response is going to take longer
than specified by the frame-waiting time (FWT) (see the
ATQB Response section). However, the MAX66040 does
not use this feature and consequently, the only use of the
S-block is to transition the device from the ACTIVE state
to the HALT state using the DESELECT command (see
the Network Function Commands section).
Information Field
Since the MAX66040 does not generate WTX requests,
the information field (Figure 11) is found only with
I-blocks. The length of the information field is calculated
by counting the number of bytes of the whole block
minus length of prologue and epilogue field. The
ISO/IEC 14443 standard does not define any rules for
the contents of the information field. The MAX66040
assumes that the first byte it receives in the information
field is a command code followed by 0 or more command-specific parameters. When responding to an
I-block, the first byte of the information field indicates
success (code 00h) followed by command-specific
data or failure (code 01h) followed by one error code.
Memory and Control
Function Commands
The commands described in this section are transmitted using the block transmission protocol. The data of a
block (from prologue to epilogue) is embedded
between SOF and EOF, as shown in Figure 16. The CID
field (shaded) is optional. If the request contains a CID,
the response also contains a CID.
The command descriptions in this section only show
the information field of the I-blocks used to transmit
requests and responses. Since the MAX66040 neither
supports chaining nor generates WTX requests, when it
receives an I-block, the MAX66040 responds with an
I-block. The block number in the I-block response is the
same as in the I-block request.
Card Identifier
Figure 15 shows the bit assignment within the card
identifier byte. The purpose of bits 4 to 1 is to select
one of multiple slave devices that the master has elevated to the ACTIVE state. The CID is assigned to a
slave through Param 4 of the ATTRIB command (see
the Network Function Commands section). While in
ACTIVE state, a compliant slave only processes blocks
that contain a matching CID and blocks without CID if
the assigned CID is all zeros. If the master includes a
CID, then the slave’s response also includes a CID
byte. Blocks with a nonmatching CIDs are ignored.
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11
MAX66040
MSB
BIT 8
According to the standard, the slave can use bits 8 and
7 to inform the master whether power-level indication is
supported, and, if yes, whether sufficient power is available for full functionality. Since the MAX66040 does not
support power-level indication, the power-level bits are
always 00b. When the master transmits a CID byte, the
power-level bits must be 00b.
ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
MAX66040
Error Indication
Depending on the complexity of a function, various
error conditions can occur. In case of an error, the
response to a request begins with a 01h byte followed
by one error code.
Table 5 shows a matrix of commands and potential
errors. If there was no error, the information field of the
response begins with 00h followed by command-specific data, as specified in the detailed command
description.
If the MAX66040 does not recognize a command, it
does not generate a response.
Table 5. Error Code Matrix
Refer to the full data sheet for this information.
12
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ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
INDICATOR
INFO
FLAGS
UID
U1
AFI
NUMBER OF
BLOCKS
MEMORY BLOCK
SIZE
IC REFERENCE
00h
0Fh
(8 Bytes)
(1 Byte)
(1 Byte)
13h
07h
(1 Byte)
Detailed Command Descriptions
Get System Information
This command allows the master to retrieve technical
information about the MAX66040. In the response, the
least significant UID byte is transmitted first. The
response is adapted from ISO 15693-3, Section 10. The
IC Reference code indicates the die revision in hexadecimal format, such as A1h, A2h, B1h, etc. To receive
the system information, issue a request with the command code 2Bh in the request information field.
For additional command descriptions, refer to the
full data sheet.
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13
MAX66040
Response Information Field for the Get System Information Command (No Error)
ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
MAX66040
Get UID
This command allows the master to retrieve the
device’s unique identification number, UID. In the
response, the least significant UID byte is transmitted
first. To read the UID, issue a request with the command code 30h in the request information field.
Response Information Field for the Get UID Command (No Error)
INDICATOR
UID
00h
(8 Bytes)
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21
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
ISO/IEC 14443-3 Type B Initialization
and Anticollision Protocol
Before an ISO/IEC 14443-compliant RF device gives
access to its memory, a communication path between
the master and the RF device must be established.
Initially, the master has no information whether there are
any RF devices in the field of its antenna. To find out
whether there are one or more RF devices compliant to
a known standard in the field, the master uses a standard-specific initialization and anticollision protocol.
The ISO/IEC 14443 Type B protocol defines six states:
POWER-OFF, IDLE, WAITING FOR SLOT-MARKER,
READY, HALT, and ACTIVE. Figure 17 shows these
states and the conditions under which a slave transitions between states. For most cases, letters surrounded by small circles reference the condition under which
a transition occurs. The conditions are explained in the
legend to Figure 17. Table 14 explains terms that are
used in the anticollision protocol and in the network
function command description.
22
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ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
MAX66040
RESPONSE LEGEND:
POWER-OFF
OUT OF FIELD
(FROM ANY STATE)
IN FIELD
ANY OTHER
COMMAND
OR CASE
1
ATQB RESPONSE
2
ATTRIB RESPONSE
3
HLTB RESPONSE
4
DESELECT RESPONSE
IDLE
S
A
ANY OTHER
COMMAND
OR CASE
WAITING FOR
SLOT-MARKER*
MS
A
S
B
a
B
1
s
1
READY
1
ANY OTHER
COMMAND OR CASE
b
ATTRIB WITH
MATCHING PUPI
2
HLTB WITH
MATCHING PUPI
EXECUTIVE BLOCK
TRANSMISSION
PROTOCOL FUNCTION
3
4
HALT
DESELECT
(SPECIAL CASE OF A BLOCK TRANSMISSION
PROTOCOL FUNCTION)
ACTIVE
ANY OTHER COMMAND
ANY OTHER COMMAND
*WHEN ENTERING “WAITING FOR SLOT-MARKER,” EACH TAG SELECTS A RANDOM NUMBER R IN THE RANGE OF 1 TO “NUMBER OF SLOTS.”
CONDITIONS LEGEND:
NAME
DESCRIPTION
A (AFI MISMATCH)
REQB/WUPB WITH NONMATCHING AFI
a
WUPB WITH NONMATCHING AFI
B (BYPASS SM)
REQB/WUPB WITH MATCHING AFI AND [(N = 1) OR [R = 1)]
b
WUPB WITH MATCHING AFI AND [(N = 1) OR [R = 1)]
S (SLOT-MARKER)
REQB/WUPB WITH MATCHING AFI AND (N 1) AND (R 1)
s
WUPB WITH MATCHING AFI AND (N 1) AND (R 1)
MS (MATCHING SLOT)
SLOT-MARKER COMMAND WITH SLOT NUMBER = R
RESULT
RETURN TO IDLE
TRANSITION DIRECTLY TO READY
WAIT FOR MATCHING SLOT NUMBER
TRANSITION TO READY WITH MATCHING SLOT-MARKER
Figure 17. ISO/IEC 14443 Type B State Transitions Diagram
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23
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
Table 14. ISO/IEC 14443 Type B Technical Terms
TERM
DESCRIPTION
ACTIVE
One of the slave’s six states. In this state, the memory and control function commands and deselect apply.
ADC
Application Data Coding. 2-Bit field of the 3rd protocol info byte of the ATQB response.
AFI
Application Family Identifier. 1-Byte field used in the REQB/WUPB request to preselect slaves.
ATQB
Answer to Request, Type B. Response to REQB, WUPB, and SLOT-MARKER command.
ATTRIB
Slave Selection Command, Type B. Used to transition a slave from READY to the ACTIVE state.
BPSK
Binary Phase-Shift Keying Modulation
CID
Card Identifier. 4-Bit temporary identification number assigned to a slave through the ATTRIB command, used
in conjunction with the block transmission protocol.
EOF
End of Frame
DESELECT
Slave Deselection Command. Transitions the slave from the ACTIVE state to the HALT state.
fc
Carrier Frequency = 13.56MHz
FO
Frame Option. 2-Bit field of the 3rd protocol info byte of the ATQB response.
fs
Subcarrier Frequency = fc/16 = 847.5kHz
FWI
Frame-Waiting Time Integer. 4-bit field of the 3rd protocol info byte of the ATQB response.
FWT
Frame-Waiting Time. Calculated from FWI.
HALT
One of the slave’s six states. The master puts a slave in this state to park it.
HLTB
Halt Command, Type B
IDLE
One of the slave’s six states. In this state, the slave has power and is waiting for action.
INF
Information Field for Higher Layer Protocol (per ISO/IEC 14443-4)
MBLI
Maximum Buffer Length Index of Slave (per ISO/IEC 14443-4). 4-Bit field of the first protocol info byte of the
ATQB response.
N
Number of Anticollision Slots (or response probability per slot)
NAD
Node Address (per ISO/IEC 14443-4)
POWER-OFF
One of the slave’s six states. In this state, the slave has no power and consequently cannot do anything.
PUPI
Pseudo Unique Identifier. 4-Byte field of the ATQB response.
R
4-Bit Random Number Chosen by a Slave When Processing the REQB or WUPB Command
READY
One of the slave’s six states; official name is READY-DECLARED SUBSTATE. In this state, the slave has
identified itself and is waiting for transition to ACTIVE (memory and control functions) or HALT (parking).
REQB
Request Command, Type B. Used to probe the RF field for the presence of slave devices.
RF
Radio Frequency
S
Slot Number. 4-Bit field sent to slave with SLOT-MARKER command.
SLOT-MARKER
Command used in the time-slot approach to identify slaves in the RF field
SOF
Start of Frame
TR0
Guard Time per ISO/IEC 14443-2
TR1
Synchronization Time per ISO/IEC 14443-2
WAITING FOR
SLOT-MARKER
One of the slave’s six states; official name is READY-REQUESTED SUBSTATE. In this state, the slave is
waiting to be called by its random number R to transition to READY.
WUPB
Wake-Up Command, Type B. Similar to REQB, required to wake up slaves in the HALT state.
24
______________________________________________________________________________________
ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
POWER-OFF State
This state applies if the slave is outside the master’s RF
field. A slave transitions to the POWER-OFF state when
leaving the power-delivering RF field. When entering
the RF field, the slave automatically transitions to the
IDLE state.
IDLE State
The purpose of the IDLE state is to have the slave population ready to participate in the anticollision protocol.
When transitioning to the IDLE state, the slave does not
generate any response. To maintain this state, the slave
must continuously receive sufficient power from the
master’s RF field to prevent transitioning into the
POWER-OFF state. While in the IDLE state, the slave listens to the commands that the master sends, but reacts
only on the REQB and WUPB commands, provided that
they include a matching AFI value. If the master sends
a command with a nonmatching AFI byte (conditions A
and a), a transition to IDLE is also possible from the
HALT state, the READY state, and the WAITING FOR
SLOT-MARKER state. From IDLE, a slave can transition
to the higher states READY (condition B) or WAITING
FOR SLOT-MARKER (condition S). For details, see the
REQB/WUPB command description in the Network
Function Commands section.
WAITING FOR SLOT-MARKER State
(READY REQUESTED SUBSTATE)
The WAITING FOR SLOT-MARKER state is used in the
time-slot anticollision approach. A slave can transition
to WAITING FOR SLOT-MARKER from the IDLE, HALT,
or READY state upon receiving a REQB or WUPB command with a matching AFI (conditions S and s), provided that both the number of slots specified in the
REQB/WUPB command and the random number that
the slave has chosen are different from 1. To maintain
this state, the slave must continuously receive sufficient
power from the master’s RF field to prevent transitioning
into the POWER-OFF state. A slave in the WAITING
FOR SLOT-MARKER state listens to the commands that
the master sends, but reacts only on the REQB, WUPB,
and SLOT-MARKER commands. From WAITING FOR
SLOT-MARKER, a slave can transition to the higher
state READY under condition B (bypassing the SLOTMARKER), or MS (matching slot, SLOT-MARKER command with a slot number that matches the random
number R). Condition A (AFI mismatch) returns the
slave to the IDLE state.
READY State (READY DECLARED SUBSTATE)
The READY state applies to a slave that has met the criteria in the anticollision protocol to send an ATQB
response. A slave can transition to READY from IDLE or
HALT (conditions B and b) or from WAITING FOR
SLOT-MARKER (conditions B and MS). When transitioning to the READY state, the slave transmits an ATQB
response. To maintain this state, the slave must continuously receive sufficient power from the master’s RF
field to prevent transitioning into the POWER-OFF state.
A slave in the READY state listens to the commands
that the master sends, but reacts only on the REQB,
WUPB, ATTRIB and HLTB commands. From READY, a
slave can transition to ACTIVE (ATTRIB command with
matching PUPI), HALT (HLTB command with matching
PUPI), or IDLE (condition A).
HALT State
The HALT state is used to silence slaves that have
been identified and shall no longer participate in the
anticollion protocol. This state is also used to park
slaves after communication in the ACTIVE state was
completed. A slave transitions to the HALT state either
from READY (HLTB command with matching PUPI) or
from ACTIVE (DESELECT command with matching
CID). When transitioning to the HALT state, the slave
transmits a response that confirms the transition. To
maintain this state, the slave must continuously receive
sufficient power from the master’s RF field to prevent
transitioning into the POWER-OFF state. The normal
way out of the HALT state is through the WUPB command. From HALT, a slave can transition to IDLE (condition a), READY (condition b), or WAITING FOR
SLOT-MARKER (condition s).
ACTIVE State
The ACTIVE state enables the slave to process commands sent through the block transmission protocol.
When entering the ACTIVE state, the slave confirms the
transition with a response. The only way for a slave to
transition to the ACTIVE state is from the READY state
(ATTRIB command with a matching PUPI). In the
ATTRIB command, the master assigns a 4-bit CID that
is used to address one of multiple slaves that could all
be in the ACTIVE state. To maintain this state, the slave
must continuously receive sufficient power from the
master’s RF field to prevent transitioning into the
POWER-OFF state. The normal way out of the ACTIVE
state is through the DESELECT command, which transitions the slave to the HALT state.
______________________________________________________________________________________
25
MAX66040
ISO/IEC 14443 Type B States and
Transitions
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
Network Function Commands
To transition slaves devices between states, the
ISO/IEC 14443 Type B standard defines six network
function commands, called REQB, WUPB, SLOTMARKER, HLTB, ATTRIB, and DESELECT. The master
issues the commands in the form of request frames and
the slaves respond by transmitting response frames.
With network function commands, command code,
parameters and response are embedded between SOF
and CRC. This section describes the format of the
response and request frames and the coding of the
data fields inside the frames as detailed as necessary
to operate the MAX66040. Not all of the fields and
cases that the standard defines are relevant for the
MAX66040. For a full description of those fields refer to
the ISO/IEC 14443-3, Section 7.
REQB/WUPB Command
The REQUEST command, Type B (REQB) and the
WAKEUP command, Type B (WUPB) are the general
tools for the master to probe the RF field for the presence of slave devices and to preselect them for action
based on the value of the application family identifier
(AFI). An ISO/IEC 14443 Type B-compliant slave
watches for these commands while in the IDLE state,
WAITING FOR SLOT-MARKER state, and READY
state. In the HALT state, the slave only acts upon
receiving a WUPB command. The REQB or WUPB
command is transmitted as a frame, as shown in
Figure 18. Besides the command code, the request
includes two parameters, AFI and PARAM. The
response to REQB/WUPB is named ATQB. See the
ATQB Response section for details.
The ISO/IEC 14443 standard defines rules for the
assignment of the AFI codes and the behavior of the
slaves when receiving a REQB/WUPB request. If the
request specifies an AFI of 00h, a slave must process
the command regardless of its actual AFI value. If the
least significant nibble of the AFI in the request is
0000b, the slave must process the command only if the
most significant nibble of the AFI sent by the master
matches the most significant nibble of the slave’s AFI.
For all other AFI values, the slave processes the command only if the AFI in the request and the slave match.
The AFI code can be programmed and locked by the
user. For details see the Memory and Control Function
Commands section.
The bit assignments of the PARAM byte are shown in
Figure 19. Bits 5 to 8 are reserved and must be transmitted as 0. Bit 4, if 0, indicates that the request is a
REQB command; bit 4, if 1, defines a WUPB command.
Bits 1, 2, and 3 specify the number of slots (N) to be
used in the anticollision protocol. Table 15 shows the
codes. In the case of N = 1, the SLOT-MARKER command does not apply and all slaves with a matching AFI
transition to the READY state. With multiple slaves in the
field, this leads to a data collision, since the response
frames are transmitted simultaneously. If N is larger then
1, each slave in the field selects its own 4-bit random
MSB
SOF
COMMAND
AFI
PARAM
CRC
05h
(1 BYTE)
(1 BYTE)
(2 BYTES)
EOF
LSB
BIT 8
BIT 7
BIT 6
BIT 5
0
0
0
0
(FIXED)
Figure 18. REQB/WUPB Request Frame
BIT 4
BIT 3
BIT 2
REQB/
WUPB
N
Figure 19. Bit Assignments for PARAM Byte
Table 15. Number of Slots Codes
26
BIT 3
BIT 2
BIT 1
N
0
0
0
1
0
0
1
2
0
1
0
4
0
1
1
8
1
0
0
16
1
0
1
(RESERVED)
1
1
X
(RESERVED)
______________________________________________________________________________________
BIT 1
ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
The bits marked as “nnnn” specify the slot number as
defined in the Table 16. Any sequence of the allowable
slot numbers is permitted.
ATQB Response
The response for both the REQB/WUPB and the SLOTMARKER command is called ATQB, which stands for
“answer to request, Type B.” Figure 21 shows the format of the ATQB response. The PUPI field (pseudounique identifier) is used by the master to address a
slave for transitioning to the ACTIVE or HALT state. The
data reported as PUPI is the least significant 4 bytes of
the 64-bit UID. The application data field reports userdefined data that is relevant for distinguishing otherwise
equal slaves in the RF field. Application data is the first
4 bytes of memory block 10h. By default, the application data field is factory programmed to reflect the most
significant 4 bytes of the 64-bit UID. This allows the
master to obtain the full 64-bit UID in the first response
from the slave. However, since this field is not factory
locked, it may be written to any value.
The protocol info field provides the master with administrative information, such as data rate, frame size,
ISO/IEC 14443-4 compliance, frame waiting time, and
whether the slave supports CID and NAD in the
ISO/IEC 14443-4 block transmission protocol. Figure 22
SLOT-MARKER Command
Instead of relying on the fact that a participating slave
chooses a new random number for every REQB/WUPB
command, in the “time-slot approach” the master calls
the slaves by their random number R using the SLOTMARKER command. Before this can be done, the master must have issued the REQB/WUPB command with a
number of slots (N) value greater than 1. The master
can send up to (N - 1) SLOT-MARKER commands.
Figure 20 shows the format of the SLOT-MARKER
request frame. The AFI field is not needed since the
slaves have already been preselected through the preceding REQB/WUPB request. The response to the
SLOT-MARKER command is called ATQB. See the
ATQB Response section for details.
SOF
COMMAND
CRC
nnnn0101b
(2 BYTES)
EOF
SOF
Figure 20. SLOT-MARKER Request Frame
INDICATOR
PUPI
50h
(4 BYTES)
APPLICATION DATA PROTOCOL INFO
(4 BYTES)
(3 BYTES)
CRC
EOF
(2 BYTES)
Figure 21. ATQB Response Frame
Table 16. Slot Numbering
BIT 8
BIT 7
BIT 6
BIT 5
SLOT NUMBER
0
0
0
1
2
0
0
1
0
3
0
0
1
1
4
…
…
…
…
…
1
1
1
0
15
1
1
1
1
16
______________________________________________________________________________________
27
MAX66040
number, R, in the range of 1 to N. A slave that happens
to choose R = 1 responds to the REQB/WUPB request.
The larger N is the lower the probability of colliding
response frames; however, if N is 16 and there is only a
single slave in the field, it can take up to 15 SLOTMARKER commands to get a response. The method to
identify all slaves in the field relying solely on the random number R and the REQB/WUPB command is
called the “probabilistic approach.” For mode information about the anticollision process see the Anticollision
Examples section.
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
3RD BYTE,
UPPER NIBBLE
3RD BYTE,
BIT 4, BIT 3
MAXIMUM FRAME SIZE, PROTOCOL TYPE
FWI
ADC
FO
21h
0111b
00b
01b
1ST BYTE
2ND BYTE
BIT RATE CABILITY
77h
3RD BYTE,
BIT 2, BIT 1
Figure 22. Protocol Info Field Details
SOF
COMMAND
PUPI
CRC
50h
(4 BYTES)
(2 BYTES)
SOF
EOF
INDICATOR
CRC
00h
(2 BYTES)
EOF
Figure 23. HLTB Request Frame
Figure 24. HLTB Response Frame
shows where this information is located in the protocol
info field and what the values are.
The bit-rate capability of the MAX66040 ranges from
105.9kbps to 847.5kbps in both directions (request and
response); request and response bit rate need not be
the same. The maximum frame size (upper nibble of the
2nd byte) of any request/response specifies 32 bytes.
The largest frame that occurs with the MAX66040 is 26
bytes (copy buffer request, compute page MAC
response). The protocol type (lower nibble of the 2nd
byte) specifies that the MAX66040 supports the
ISO/IEC 14443-4 block transmission protocol. The FWI
code 0111b specifies a frame waiting time of 38.7ms,
which is long enough to generate a computed secret.
Note that a slave may respond long before the maximum frame waiting time is expired. The ADC code 00b
specifies that the MAX66040 uses proprietary coding
for the application data field. The FO code 01b implies
that the MAX66040 supports CID, but does not support
the NAD field in the ISO/IEC 14443-4 block transmission protocol.
slave has transmitted in the ATQB response. While in
the HALT state, the slave only responds to the WUPB
request.
HLTB Command
The HLTB command is the only network function command to silence a slave by parking it in the HALT state.
If, based on the ATQB response, the master does not
want to further communicate with the slave, the master
issues the HLTB command. Figures 23 and 24 show
the format of the HLTB request frame and the corresponding response frame. The data to be used in the
PUPI field must match the PUPI information that the
SOF
ATTRIB Command
The ATTRIB command is the only way to select a slave
and make it process commands that are transmitted
according to the ISO/IEC 14443 block transmission protocol. If, based on the ATQB response, the master
wants to communicate with the slave, the master must
put the slave into the ACTIVE state using the slave
selection command ATTRIB. The normal way for the
master to move a slave out of the ACTIVE state is by
sending a DESELECT command, which uses an
S-block to convey a network function command.
Figure 25 shows the format of the ATTRIB request
frame. The data to be used in the PUPI field must
match the PUPI information that the slave has transmitted in the ATQB response. Param 1 tells the slave how
much time the master needs to switch from transmit to
receive (TR0), how much time the master needs to synchronize to the slave’s subcarrier (TR1), and whether
the master is capable of receiving response frames
without SOF and/or EOF.
The MAX66040 ignores the data of Param 1. To ease
requirements for ISO/IEC 14443 Type B readers, the
MAX66040 has TR0 and TR1 fixed at 128/fs (151µs; fs
is the subcarrier frequency of 847.5kHz) and always
begins and ends its responses with SOF and EOF,
respectively.
COMMAND
PUPI
PARAM 1
PARAM 2
PARAM 3
PARAM 4
1Dh
(4 BYTES)
(1 BYTE)
(1 BYTE)
01h
(1 BYTE)
HLINF
CRC
EOF
(≥ 0 BYTES) (2 BYTES)
Figure 25. ATTRIB Request Frame
28
______________________________________________________________________________________
ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
BIT 8
LSB
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
X
X
X
X
RESPONSE DATA RESPONSE DATA
RECEIVER FRAME SIZE CAPABILITY
RATE (UPLINK) RATE (DOWNLINK)
Figure 26. Bit Assignments for Param 2 Byte
MSB
LSB
BIT 8
BIT 7
BIT 6
BIT 5
0
0
0
0
BIT 4
(FIXED)
BIT 3
BIT 2
BIT 1
CARD IDENTIFIER VALUE (CID)
Figure 27. Bit Assignments for Param 4 Byte
SOF
INDICATOR
HL RESPONSE
CRC
MBLI, CID
(≥ 0 BYTES)
(2 BYTES)
EOF
Figure 28. ATTRIB Response Frame
FRAME WITHOUT CID
SOF
COMMAND
CRC
C2h
(2 BYTES)
EOF
The HL response field is optional. There are three
cases to be distinguished:
FRAME WITH CID
SOF
sets the upper nibble of Param 3 to 0000b, the Param 3
value to be used for the MAX66040 in the ATTRIB
request is 01h.
Param 4 assigns the slave the CID number that is used
with the block transmission protocol to address one of
several slaves in the ACTIVE state. Figure 27 shows the
Param 4 bit assignments. Since the MAX66040 supports the CID field, the master can assign any number
in the range from 0 to 14. According to ISO/IEC 144433, code 15 is reserved.
The ATTRIB request frame contains one optional field,
called higher layer information (HLINF). This field can
be used to include data as in the information field of the
ISO/IEC 14443 Type B block transmission protocol (see
Figure 11). If such data is present and the slave supports the HLINF field, then the slave processes the
HLINF data and returns the result in its response to the
ATTRIB request. Typically, the ATTRIB request is transmitted without HLINF field. The only HLINF data that the
MAX66040 accepts and processes is the Get UID command, code 30h.
If the ATTRIB request has a matching PUPI and a valid
CRC, the slave transmits an ATTRIB response frame, as
shown in Figure 28. The upper nibble of the indicator,
also referred to as MBLI, is 0000b, telling that the slave
does not provide any information on its internal input
buffer size; the lower nibble returns the card identifier
value that the master has just assigned to the slave.
COMMAND
CID
CRC
CAh
(1 BYTE)
(2 BYTES)
EOF
Figure 29. DESELECT Request and Response Frames
Param 2 informs the slave about the data rate that shall
be used for communication in the ACTIVE state and the
maximum frame size that the master can receive.
Figure 26 shows the bit assignments for the Param 2
byte. The MAX66040 supports the data rates of
105.9kbps (code 00b), 211.9kbps (code 01b),
423.75kbps (code 10b), and 847.5kbps (code 11b).
The master can choose different data rates for request
and response. Since it does not support chaining, the
MAX66040 ignores the frame size capability and
assumes that the master can receive frames as large
as specified in the ATQB response.
The lower nibble of Param 3 is used to confirm the protocol type as specified in the lower nibble of the second
byte of the ATQB protocol info. Since ISO/IEC 14443-3
a) If there was no HLINF field in the ATTRIB request,
then there is no HL response field in the response.
b) If there was a Get UID command code (30h) in the
HLINF field of the ATTRIB request, then the HL
response field is identical to the Get UID response
information field (i.e., 00h followed by the 8-byte UID).
c) If the code in the HLINF field of the ATTRIB request
was different from 30h, then the response frame does
not contain an HL response field.
DESELECT Command
The DESELECT command is used to transition the slave
from the ACTIVE to the HALT state after the master has
completed the communication with the slave. There are
two versions of the deselect request frame, one without
CID and one with CID. Figure 29 shows both versions.
Figure 27 shows the CID format.
Logically, the DESELECT command is a special case of
the S-block of the block transmission protocol, as
defined in part 4 of the ISO/IEC 14443 standard. The
MAX66040 responds to a Deselect command if the CID
______________________________________________________________________________________
29
MAX66040
MSB
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
in the request and the CID in the device match. If the
DESELECT request does not include a CID, the
MAX66040 only responds to the request if its CID is
0000b.
The response frame to the DESELECT command is
identical to the request frame. The slave returns the
same data that it had received, confirming that the
slave addressed in the request has been transitioned to
the HALT sate.
Anticollision Examples
Probabilistic Anticollision
The master starts the anticollision process by issuing an
REQB or WUPB command. The WUPB command
involves any slave in the field with a matching AFI code.
The REQB command performs the same function, but is
ignored by slaves in the HALT state. Both commands
include the parameter N, which according to Table 15 is
used to set the probability of an ATQB response to 1/N.
If N = 1, all participating slaves respond with the ATQB
response. If N is greater than one, then each slave
selects a random number R in the range of 1 to N. If a
slave happens to choose R = 1, then it responds with
ATQB. If R is greater than 1, then the slave waits for
another REQB or WUPB command, which causes the
participating slaves to choose a new random number R.
The ATQB response contains a field named PUPI,
which is used to direct commands to a specific slave
during the anticollision process. When the master
receives an ATQB response, it should issue a matching
TESTING FOR SLAVES
MASTER
REQB
(N = 1)
ATTEMPT 1
ATTEMPT 2
HLTB command to halt the slave or issue a matching
ATTRIB command to assign a CID and place the slave
in the ACTIVE state. If this is not done, the slaves continue to participate in the anticollision process. A slave
in the ACTIVE state ignores all REQB, WUPB, SLOTMARKER, ATTRIB, and HLTB commands, but responds
to the DESELECT command.
An ATQB response received with a CRC error indicates
a collision because two or more slaves have responded
at the same time. With probabilistic anticollision, the
master must issue another REQB command to cause
the slaves in the field that are not in the HALT or
ACTIVE state to select a new random number R. If one
of the slaves has chosen R = 1, it responds with ATQB.
A REQB without ATQB response does not guarantee that all slaves in the field have been identified.
Figure 30 shows an example of the time-slot anticollision, assuming that there are four slaves in IDLE state in
the field. The process begins with the master sending
an REQB request with N = 1, which forces all slaves to
respond with ATQB, resulting in a collision. Knowing that
slaves are present, the master now sends REQB with N
= 8. This causes all slaves to select a random number in
the range of 1 to 8. Only the slave that has chosen R = 1
responds, which is slave C in the example. Knowing that
there are more slaves in the field, the master continues
issuing REQB commands, which in the example, eventually identifies all slaves. Due to its statistical nature,
probabilistic anticollision is less likely to find every slave
in the field than the time-slot anticollision.
ATTEMPT 3
ATTEMPT 4 ATTEMPT 5
ATTEMPT 6
REQB
(N = 8)
REQB
(N = 8)
REQB
(N = 8)
REQB
(N = 8)
REQB
(N = 8)
REQB
(N = 8)
(R = 1) ATQB
(R = 3)
(R = 6)
(R = 8)
SLAVE A
ATQB
(R = 3)
(R = 7)
SLAVE B
ATQB
(R = 6)
(R = 4)
(R = 8)
(R = 8)
(R = 5)
(R = 1) ATQB
SLAVE C
ATQB
(R = 1) ATQB (R = 8)
(R = 2)
(R = 4)
(R = 3)
(R = 4)
SLAVE D
ATQB
(R = 2)
(R = 1) ATQB (R = 5)
(R = 8)
(R = 4)
(R = 2)
Figure 30. Probabilistic Anticollision Example
30
______________________________________________________________________________________
ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
MASTER
REQB
(N = 1)
SLOT 1
REQB
(N = 8)
SLAVE A
ATQB
(R = 3)
SLAVE B
ATQB
(R = 6)
SLAVE C
ATQB
(R = 1) ATQB
SLAVE D
ATQB
(R = 2)
SLOT 2
SM2
SLOT 3
SM3
SLOT 4 SLOT 5
SM4
SM5
SLOT 6
SM6
SLOT 7 SLOT 8
SM7
SM8
ATQB
ATQB
ATQB
Figure 31. Time-Slot Anticollision Example
Time-Slot Anticollision
The master starts the anticollision process by issuing
an REQB or WUPB command. The WUPB command
involves any slave in the field with a matching AFI code.
The REQB command performs the same function, but is
ignored by slaves in the HALT state. Both commands
include the parameter N, which according to Table 15
specifies the number of slots to be used in the anticollision protocol.
If N = 1, all participating slaves respond with the ATQB
response. If N is greater than one, then each slave
selects a random number R in the range of 1 to N. If a
slave happens to choose R = 1, then it responds with
ATQB. If R is greater than 1, then the slave waits for a
SLOT-MARKER command with a slot number that is
equal to R and then responds with ATQB. The master
must try all slot numbers from 2 to N to ensure that no
slave is missed.
The ATQB response contains a field named PUPI,
which is used to direct commands to a specific slave
during the anticollision process. When the master
receives an ATQB response, it should issue a matching
HLTB command to halt the slave, or issue a matching
ATTRIB command to assign a CID and place the slave
in the ACTIVE state. A slave in the ACTIVE state ignores
all REQB, WUPB, SLOT-MARKER, ATTRIB, and HLTB
commands, but responds to the DESELECT command.
An ATQB response received with a CRC error indicates
a collision because two or more slaves have responded
at the same time. Typically the master continues issuing
SLOT-MARKER commands to test for slaves with random numbers R different from 1. If additional collisions
were encountered, the master must issue a new REQB
command, causing each slave in the field that is not in
the HALT or ACTIVE state to select a new random number R. The anticollision process then continues in this
manner until all slaves in the field have been identified
and put either into the HALT or ACTIVE state.
Figure 31 shows an example of the time-slot anticollision, assuming that there are four slaves in IDLE state
in the field. The process begins with the master sending an REQB request with N = 1, which forces all slaves
to respond with ATQB, resulting in a collision. Knowing
that slaves are present, the master now sends REQB
with N = 8. This causes all slaves to select a random
number in the range of 1 to 8. This does not prevent
two slaves from choosing the same value for R, but the
higher N is, the less likely this is to occur. In the example, slave C has chosen R = 1 and responds right after
REQB. The master now sends a Slot-MARKER command with slot number 2 (SM2), which causes slave D
to respond. The master continues testing all slots, and,
if a slave with matching R is present, receives an
ATQB. In case the master detects a collision in a slot,
the slaves identified in the remaining slots need to be
put in the HALT or ACTIVE state first, before another
anticollision process is started. Note that there is no
need for the master to test the slots in numerical order,
as in the example.
______________________________________________________________________________________
31
MAX66040
TESTING FOR SLAVES
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
CRC Generation
The other CRC is a 16-bit type, generated according to
the CRC-16-CCITT polynomial function: X16 + X12 +
X5 + 1 (Figure 33). This CRC is used for error detection
in request and response data packets and is always
communicated in the inverted form. After all data bytes
are shifted into the CRC generator, the state of the 16
flip-flops is parallel-copied to a shift register and shifted
out for transmission with the LSb first. For more details
on this CRC, refer to ISO/IEC 14443-3, Annex B,
CRC_B encoding.
The MAX66040 uses two different types of CRCs. One
CRC is an 8-bit type. The equivalent polynomial function of this CRC is X8 + X5 + X4 + 1.
POLYNOMIAL = X8 + X5 + X4 + 1
MSb
LSb
1ST
STAGE
X0
2ND
STAGE
X1
3RD
STAGE
X2
4TH
STAGE
5TH
STAGE
X3
6TH
STAGE
X4
X5
7TH
STAGE
X6
8TH
STAGE
X7
X8
INPUT DATA
Figure 32. 8-Bit CRC Generator
POLYNOMIAL = X16 + X12 + X5 + 1
MSb
1ST
STAGE
X0
3RD
STAGE
2ND
STAGE
X2
X1
4TH
STAGE
X3
5TH
STAGE
6TH
STAGE
X4
X5
7TH
STAGE
X6
8TH
STAGE
X7
LSb
9TH
STAGE
X8
10TH
STAGE
X9
11TH
STAGE
X10
12TH
STAGE
X11
13TH
STAGE
X12
14TH
STAGE
X13
15TH
STAGE
X14
16TH
STAGE
X15
X16
INPUT DATA
Figure 33. CRC-16-CCITT Generator
32
______________________________________________________________________________________
ABRIDGED DATA SHEET
ISO/IEC 14443 Type B-Compliant
Secure Memory
TOP VIEW
54mm
7.7mm
28mm
MAX66040K-000AA+
1.6mm
SIDE VIEW
KEY FOB
TOP VIEW
85.60mm
14.29mm
MAX66040E-000AA+
3.49mm
53.98mm
0.76mm
SIDE VIEW
ISO CARD
______________________________________________________________________________________
37
MAX66040
Mechanical Drawings
ABRIDGED DATA SHEET
MAX66040
ISO/IEC 14443 Type B-Compliant
Secure Memory
Revision History
REVISION
NUMBER
REVISION
DATE
0
1/11
DESCRIPTION
Initial release
PAGES
CHANGED
—
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