MF1S50YYX_V1
MIFARE Classic EV1 1K - Mainstream contactless smart card
IC for fast and easy solution development
Rev. 3.2 — 23 May 2018
279232
1
Product data sheet
COMPANY PUBLIC
General description
NXP Semiconductors has developed the MIFARE Classic EV1 contactless IC
MF1S50yyX/V1 to be used in a contactless smart card according to ISO/IEC 14443 Type
A.
The MIFARE Classic EV1 with 1K memory MF1S50yyX/V1 IC is used in applications like
public transport ticketing and can also be used for various other applications.
1.1 Anticollision
An intelligent anticollision function allows to operate more than one card in the field
simultaneously. The anticollision algorithm selects each card individually and ensures
that the execution of a transaction with a selected card is performed correctly without
interference from another card in the field.
energy
MIFARE
CARD PCD
data
001aam199
Figure 1. Contactless MIFARE product-based system
1.2 Simple integration and user convenience
The MF1S50yyX/V1 is designed for simple integration and user convenience which
allows complete ticketing transactions to be handled in less than 100 ms.
1.3 Security and privacy
•
•
•
•
Manufacturer programmed 7-byte UID or 4-byte NUID identifier for each device
Random ID support
Mutual three pass authentication (ISO/IEC DIS 9798-2)
Individual set of two keys per sector to support multi-application with key hierarchy
1.4 Delivery options
• 7-byte UID, 4-byte NUID
• Bumped die on sawn wafer
MF1S50YYX_V1
NXP Semiconductors
MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
• MOA4 and MOA8 contactless module
2
Features and benefits
• Contactless transmission of data and energy
supply
• Operating distance up to 100 mm
depending on antenna geometry and reader
configuration
• Operating frequency of 13.56 MHz
• Data transfer of 106 kbit/s
• Data integrity of 16-bit CRC, parity, bit coding, • Anticollision
bit counting
• Typical ticketing transaction time of < 100 ms
(including backup management)
• 7 Byte UID or 4 Byte NUID
• Random ID support (7 Byte UID version)
• NXP Originality Check support
2.1 EEPROM
• 1 kB, organized in 16 sectors of 4 blocks (one • User definable access conditions for each
block consists of 16 byte)
memory block
• Data retention time of 10 years
3
4
• Write endurance 200000 cycles
Applications
• Public transportation
• Access management
• Electronic toll collection
• Car parking
• School and campus cards
• Employee cards
• Internet cafés
• Loyalty
Quick reference data
Table 1. Quick reference data
Symbol
Parameter
Conditions
Ci
input capacitance
fi
input frequency
[1]
Min
Typ
Max
Unit
14.9
16.9
19.0
pF
-
13.56
-
MHz
EEPROM characteristics
tret
retention time
Tamb = 22 °C
10
-
-
year
Nendu(W)
write endurance
Tamb = 22 °C
100000
200000
-
cycle
[1]
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Tamb=22°C, f=13,56Mhz, VLaLb = 1,5 V RMS
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5
Ordering information
Table 2. Ordering information
Type number
Package
Name
MF1S5001XDUD/V1
Description
Version
FFC Bump 8 inch wafer, 120 μm thickness, on film frame carrier, electronic fail die
marking according to SECS-II format), Au bumps, 7-byte UID
-
MF1S5001XDUD2/V1 FFC Bump 12 inch wafer, 120 μm thickness, on film frame carrier, electronic fail die
marking according to SECS-II format), Au bumps, 7-byte UID
-
MF1S5001XDUF/V1
FFC Bump 8 inch wafer, 75 μm thickness, on film frame carrier, electronic fail die
marking according to SECS-II format), Au bumps, 7-byte UID
-
MF1S5000XDA4/V1
MOA4
plastic leadless module carrier package; 35 mm wide tape, 7-byte UID
SOT500-2
MF1S5000XDA8/V1
MOA8
plastic leadless module carrier package; 35 mm wide tape, 7-byte UID
SOT500-4
MF1S5031XDUD/V1
FFC Bump 8 inch wafer, 120 μm thickness, on film frame carrier, electronic fail die
marking according to SECS-II format), Au bumps, 4-byte non-unique ID
-
MF1S5031XDUD2/V1 FFC Bump 12 inch wafer, 120 μm thickness, on film frame carrier, electronic fail die
marking according to SECS-II format), Au bumps, 4-byte non-unique ID
-
MF1S5031XDUF/V1
FFC Bump 8 inch wafer, 75 μm thickness, on film frame carrier, electronic fail die
marking according to SECS-II format), Au bumps, 4-byte non-unique ID
-
MF1S5030XDA4/V1
MOA4
plastic leadless module carrier package; 35 mm wide tape,
4-byte non-unique ID
SOT500-2
MF1S5030XDA8/V1
MOA8
plastic leadless module carrier package; 35 mm wide tape,
4-byte non-unique ID
SOT500-4
6
Block diagram
RF
INTERFACE
UART
ISO/IEC 14443
TYPE A
POWER ON
RESET
CRYPTO1
RNG
VOLTAGE
REGULATOR
CRC
CLOCK
INPUT FILTER
RESET
GENERATOR
LOGIC UNIT
EEPROM
001aan006
Figure 2. Block diagram of MF1S50yyX/V1
MF1S50yyX_V1
Product data sheet
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MF1S50YYX_V1
NXP Semiconductors
MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
7
Pinning information
7.1 Pinning
The pinning for the MF1S50yyX/V1DAx is shown as an example in Figure 3 for the
MOA4 contactless module. For the contactless module MOA8, the pinning is analogous
and not explicitly shown.
LA
top view
LB
001aan002
Figure 3. Pin configuration for SOT500-2 (MOA4)
Table 3. Pin allocation table
8
Pin
Symbol
LA
LA
Antenna coil connection LA
LB
LB
Antenna coil connection LB
Functional description
8.1 Block description
The MF1S50yyX/V1 chip consists of a 1 kB EEPROM, RF interface and Digital Control
Unit. Energy and data are transferred via an antenna consisting of a coil with a small
number of turns which is directly connected to the MF1S50yyX/V1. No further external
components are necessary. Refer to the document Ref. 1 for details on antenna design.
• RF interface:
– Modulator/demodulator
– Rectifier
– Clock regenerator
– Power-On Reset (POR)
– Voltage regulator
• Anticollision: Multiple cards in the field may be selected and managed in sequence
• Authentication: Preceding any memory operation the authentication procedure ensures
that access to a block is only possible via the two keys specified for each block
MF1S50yyX_V1
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MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
• Control and Arithmetic Logic Unit: Values are stored in a special redundant format and
can be incremented and decremented
• EEPROM interface
• Crypto unit: The CRYPTO1 stream cipher of the MF1S50yyX/V1 is used for
authentication and encryption of data exchange.
• EEPROM: 1 kB is organized in 16 sectors of 4 blocks. One block contains 16 bytes.
The last block of each sector is called "trailer", which contains two secret keys and
programmable access conditions for each block in this sector.
8.2 Communication principle
The commands are initiated by the reader and controlled by the Digital Control Unit of
the MF1S50yyX/V1. The command response is depending on the state of the IC and for
memory operations also on the access conditions valid for the corresponding sector.
8.2.1 Request standard / all
After Power-On Reset (POR) the card answers to a request REQA or wakeup WUPA
command with the answer to request code (see Section 9.4, ATQA according to ISO/IEC
14443A).
8.2.2 Anticollision loop
In the anticollision loop the identifier of a card is read. If there are several cards in the
operating field of the reader, they can be distinguished by their identifier and one can
be selected (select card) for further transactions. The unselected cards return to the idle
state and wait for a new request command. If the 7-byte UID is used for anticollision and
selection, two cascade levels need to be processes as defined in ISO/IEC 14443-3.
Remark: For the 4-byte non-unique ID product versions, the identifier retrieved from the
card is not defined to be unique. For further information regarding handling of non-unique
identifiers see Ref. 6.
8.2.3 Select card
With the select card command the reader selects one individual card for authentication
and memory related operations. The card returns the Select AcKnowledge (SAK) code
which determines the type of the selected card, see Section 9.4. For further details refer
to the document Ref. 2.
8.2.4 Three pass authentication
After selection of a card the reader specifies the memory location of the following
memory access and uses the corresponding key for the three pass authentication
procedure. After a successful authentication all commands and responses are encrypted.
Remark: The HLTA command needs to be sent encrypted to the PICC after a successful
authentication in order to be accepted.
MF1S50yyX_V1
Product data sheet
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MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
Transaction Sequence
POR
Request Standard
Typical Transaction Time
Request All
Identification and Selection
Procedure
Anticollision Loop
Get Identifier
~2.5 ms
without collision
+ ~1 ms
for 7-byte UID
+ ~1 ms
for each collision
Select Card
Authentication Procedure
3 Pass Authenticationon
specific sector
~2 ms
Memory Operations
Read
Block
Write
Block
Decrement
Increment
Restore
Halt
~2.5 ms
~5.5 ms
read block
write block
~2.5 ms
de-/increment
~4.5 ms
transfer
Transfer
001aan921
1. the command flow diagram does not include the Personalize UID Usage and the
SET_MOD_TYPE command, for details on those commands please see Section 10.1.1 and
Section 11
Figure 4. MIFARE Classic command flow diagram
8.2.5 Memory operations
After authentication any of the following operations may be performed:
• Read block
• Write block
• Decrement: Decrements the contents of a block and stores the result in the internal
Transfer Buffer
• Increment: Increments the contents of a block and stores the result in the internal
Transfer Buffer
• Restore: Moves the contents of a block into the internal Transfer Buffer
• Transfer: Writes the contents of the internal Transfer Buffer to a value block
8.3 Data integrity
Following mechanisms are implemented in the contactless communication link between
reader and card to ensure very reliable data transmission:
• 16 bits CRC per block
• Parity bits for each byte
MF1S50yyX_V1
Product data sheet
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MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
• Bit count checking
• Bit coding to distinguish between "1", "0" and "no information"
• Channel monitoring (protocol sequence and bit stream analysis)
8.4 Three pass authentication sequence
1. The reader specifies the sector to be accessed and chooses key A or B.
2. The card reads the secret key and the access conditions from the sector trailer. Then
the card sends a number as the challenge to the reader (pass one).
3. The reader calculates the response using the secret key and additional input. The
response, together with a random challenge from the reader, is then transmitted to the
card (pass two).
4. The card verifies the response of the reader by comparing it with its own challenge
and then it calculates the response to the challenge and transmits it (pass three).
5. The reader verifies the response of the card by comparing it to its own challenge.
After transmission of the first random challenge the communication between card and
reader is encrypted.
8.5 RF interface
The RF-interface is according to the standard for contactless smart cards ISO/IEC
14443A.
For operation, the carrier field from the reader always needs to be present (with short
pauses when transmitting), as it is used for the power supply of the card.
For both directions of data communication there is only one start bit at the beginning of
each frame. Each byte is transmitted with a parity bit (odd parity) at the end. The LSB of
the byte with the lowest address of the selected block is transmitted first. The maximum
frame length is 163 bits (16 data bytes + 2 CRC bytes = 16 × 9 + 2 × 9 + 1 start bit).
8.6 Memory organization
The 1024 × 8 bit EEPROM memory is organized in 16 sectors of 4 blocks. One block
contains 16 bytes.
MF1S50yyX_V1
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MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
Byte Number within a Block
Sector
Block
15
3
14
1
2
3
4
5
6
Key A
7
8
9 10 11 12 13 14 15
Access Bits
Key B
Description
Sector Trailer 15
2
Data
1
Data
0
Data
3
Key A
Access Bits
Key B
Sector Trailer 14
2
Data
1
Data
0
Data
:
:
:
:
:
:
1
3
0
0
Key A
Access Bits
Key B
Sector Trailer 1
2
Data
1
Data
0
Data
3
Key A
Access Bits
Key B
Sector Trailer 0
2
Data
1
Data
0
Manufacturer Data
Manufacturer Block
001aan011
Figure 5. Memory organization
8.6.1 Manufacturer block
This is the first data block (block 0) of the first sector (sector 0). It contains the IC
manufacturer data. This block is programmed and write protected in the production test.
The manufacturer block is shown in Figure 6 and Figure 7 for the 4-byte NUID and 7-byte
UID version respectively.
Block 0/Sector 0
Byte
0
1
2
3
4
5
6
NUID
7
8
9
10
11
Manufacturer Data
12
13
14
15
001aan010
Figure 6. Manufacturer block for MF1S503yX with 4-byte NUID
MF1S50yyX_V1
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Block 0/Sector 0
Byte
0
1
2
3
4
5
6
7
8
9
UID
10
11
12
13
Manufacturer Data
14
15
001aam204
Figure 7. Manufacturer block for MF1S500yX with 7-byte UID
8.6.2 Data blocks
All sectors contain 3 blocks of 16 bytes for storing data (Sector 0 contains only two data
blocks and the read-only manufacturer block).
The data blocks can be configured by the access bits as
• read/write blocks
• value blocks
Value blocks can be used for e.g. electronic purse applications, where additional
commands like increment and decrement for direct control of the stored value are
provided
A successful authentication has to be performed to allow any memory operation.
Remark: The default content of the data blocks at delivery is not defined.
8.6.2.1 Value blocks
Value blocks allow performing electronic purse functions (valid commands are: read,
write, increment, decrement, restore, transfer). Value blocks have a fixed data format
which permits error detection and correction and a backup management.
A value block can only be generated through a write operation in value block format:
• Value: Signifies a signed 4-byte value. The lowest significant byte of a value is stored
in the lowest address byte. Negative values are stored in standard 2´s complement
format. For reasons of data integrity and security, a value is stored three times, twice
non-inverted and once inverted.
• Adr: Signifies a 1-byte address, which can be used to save the storage address of a
block, when implementing a powerful backup management. The address byte is stored
four times, twice inverted and non-inverted. During increment, decrement, restore and
transfer operations the address remains unchanged. It can only be altered via a write
command.
Byte Number
0
Description
1
2
value
3
4
5
6
7
value
8
9
10
value
11
12
13
14
15
adr adr adr adr
001aan018
Figure 8. Value blocks
An example of a valid value block format for the decimal value 1234567d and the block
address 17d is shown in Table 4. First, the decimal value has to be converted to the
hexadecimal representation of 0012D687h. The LSByte of the hexadecimal value is
stored in Byte 0, the MSByte in Byte 3. The bit inverted hexadecimal representation of
the value is FFED2978h where the LSByte is stored in Byte 4 and the MSByte in Byte 7.
The hexadecimal value of the address in the example is 11h, the bit inverted
hexadecimal value is EEh.
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Table 4. Value block format example
Byte Number
0
1
Description
Values [hex]
2
3
4
5
value
87
D6
6
7
8
value
12
00
78
9
10
11
12
87
D6
14
15
adr adr adr adr
value
29 ED FF
13
12
00
11
EE
11
EE
8.6.3 Sector trailer
The sector trailer is the last block (block 3) in one sector. Each sector has a sector trailer
containing the
• secret keys A (mandatory) and B (optional), which return logical "0"s when read and
• the access conditions for the blocks of that sector, which are stored in bytes 6...9. The
access bits also specify the type (data or value) of the data blocks.
If key B is not needed, the last 6 bytes of the sector trailer can be used as data bytes.
The access bits for the sector trailer have to be configured accordingly, see Section
8.7.2.
Byte 9 of the sector trailer is available for user data. For this byte the same access rights
as for byte 6, 7 and 8 apply.
When the sector trailer is read, the key bytes are blanked out by returning logical zeros.
If key B is configured to be readable, the data stored in bytes 10 to 15 is returned, see
Section 8.7.2.
All keys are set to FFFF FFFF FFFFh at chip delivery and the bytes 6, 7 and 8 are set to
FF0780h.
Byte Number
0
1
2
Description
3
4
5
Key A
6
7
8
9
10
11
Access Bits
12
13
14
15
Key B (optional)
001aan013
Figure 9. Sector trailer
8.7 Memory access
Before any memory operation can be done, the card has to be selected and
authenticated as described in Section 8.2. The possible memory operations for an
addressed block depend on the key used during authentication and the access
conditions stored in the associated sector trailer.
Table 5. Memory operations
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Operation
Description
Valid for Block Type
Read
reads one memory block
read/write, value and sector trailer
Write
writes one memory block
read/write, value and sector trailer
Increment
increments the contents of a block and
stores the result in the internal Transfer
Buffer
value
Decrement
decrements the contents of a block and
stores the result in the internal Transfer
Buffer
value
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Operation
Description
Valid for Block Type
Transfer
writes the contents of the internal
Transfer Buffer to a block
value and read/write
Restore
reads the contents of a block into the
internal Transfer Buffer
value
8.7.1 Access conditions
The access conditions for every data block and sector trailer are defined by 3 bits, which
are stored non-inverted and inverted in the sector trailer of the specified sector.
The access bits control the rights of memory access using the secret keys A and B. The
access conditions may be altered, provided one knows the relevant key and the current
access condition allows this operation.
Remark: With each memory access the internal logic verifies the format of the access
conditions. If it detects a format violation the whole sector is irreversibly blocked.
Remark: In the following description the access bits are mentioned in the non-inverted
mode only.
The internal logic of the MF1S50yyX/V1 ensures that the commands are executed only
after a successful authentication.
Table 6. Access conditions
Access Bits
Valid Commands
Block
Description
C13, C23, C33
read, write
→
3
sector trailer
C12, C22, C32
read, write, increment, decrement,
transfer, restore
→
2
data block
C11, C21, C31
read, write, increment, decrement,
transfer, restore
→
1
data block
C10 ,C20, C30
read, write, increment, decrement,
transfer, restore
→
0
data block
Byte Number
0
1
Description
2
3
4
5
6
Key A
Bit 7
7
8
9
10
11
Access Bits
12
13
14
15
Key B (optional)
6
5
4
3
2
1
0
Byte 6
C23
C22
C21
C20
C13
C12
C11
C10
Byte 7
C13
C12
C11
C10
C33
C32
C31
C30
Byte 8
C33
C32
C31
C30
C23
C22
C21
C20
Byte 9
user data
001aan003
Figure 10. Access conditions
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8.7.2 Access conditions for the sector trailer
Depending on the access bits for the sector trailer (block 3) the read/write access to the
keys and the access bits is specified as ‘never’, ‘key A’, ‘key B’ or key A|B’ (key A or key
B).
On chip delivery the access conditions for the sector trailers and key A are predefined
as transport configuration. Since key B may be read in the transport configuration, new
cards must be authenticated with key A. Since the access bits themselves can also be
blocked, special care has to be taken during the personalization of cards.
Table 7. Access conditions for the sector trailer
Access bits
Access condition for
KEYA
Remark
Access bits
KEYB
C1
C2
C3
read
write
read
write
read
write
0
0
0
never
key A
key A
never
key A
key A
Key B may be read
[1]
0
1
0
never
never
key A
never
key A
never
Key B may be read
[1]
1
0
0
never
key B
key A|B never
never
key B
1
1
0
never
never
key A|B never
never
never
0
0
1
never
key A
key A
key A
key A
key A
0
1
1
never
key B
key A|B key B
never
key B
1
0
1
never
never
key A|B key B
never
never
1
1
1
never
never
key A|B never
never
never
[1]
Key B may be read,
[1]
transport configuration
For this access condition key B is readable and may be used for data
8.7.3 Access conditions for data blocks
Depending on the access bits for data blocks (blocks 0...2) the read/write access is
specified as ‘never’, ‘key A’, ‘key B’ or ‘key A|B’ (key A or key B). The setting of the
relevant access bits defines the application and the corresponding applicable commands.
• Read/write block: the operations read and write are allowed.
• Value block: Allows the additional value operations increment, decrement, transfer
and restore. With access condition ‘001’ only read and decrement are possible which
reflects a non-rechargeable card. For access condition ‘110’ recharging is possible by
using key B.
• Manufacturer block: the read-only condition is not affected by the access bits setting!
• Key management: in transport configuration key A must be used for authentication
Table 8. Access conditions for data blocks
MF1S50yyX_V1
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Application
Access bits
Access condition for
C1
C2
C3
read
write
increment
decrement,
transfer,
restore
0
0
0
key A|B
key A|B
key A|B
key A|B
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Access condition for
0
1
0
key A|B
never
never
never
read/write block
1
0
0
key A|B
key B
never
never
read/write block
1
1
0
key A|B
key B
key B
key A|B
value block
0
0
1
key A|B
never
never
key A|B
value block
0
1
1
key B
key B
never
never
read/write block
1
0
1
key B
never
never
never
read/write block
1
1
1
never
never
never
never
read/write block
[1]
9
Application
Access bits
[1]
[1]
[1]
[1]
[1]
[1]
If key B may be read in the corresponding Sector Trailer it cannot serve for authentication (see grey marked lines in Table
7). As a consequences, if the reader authenticates any block of a sector which uses such access conditions for the Sector
Trailer and using key B, the card will refuse any subsequent memory access after authentication.
Command overview
Note: In this document the term „MIFARE Classic card“ refers to a MIFARE Classic ICbased contactless card.
The MIFARE Classic card activation follows the ISO/IEC 14443 Type A. After the
MIFARE Classic card has been selected, it can either be deactivated using the ISO/IEC
14443 Halt command, or the MIFARE Classic commands can be performed. For more
details about the card activation refer to Ref. 4.
9.1 MIFARE Classic command overview
All MIFARE Classic commands typically use the MIFARE Classic using Crypto1 and
require an authentication.
All available commands for the MIFARE Classic EV1 with 1K memory are shown in Table
9.
Table 9. Command overview
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Command
ISO/IEC 14443
Command code
(hexadecimal)
Request
REQA
26h (7 bit)
Wake-up
WUPA
52h (7 bit)
Anticollision CL1
Anticollision CL1
93h 20h
Select CL1
Select CL1
93h 70h
Anticollision CL2
Anticollision CL2
95h 20h
Select CL2
Select CL2
95h 70h
Halt
Halt
50h 00h
Authentication with Key A
-
60h
Authentication with Key B
-
61h
Personalize UID Usage
-
40h
SET_MOD_TYPE
-
43h
MIFARE Read
-
30h
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Command
ISO/IEC 14443
Command code
(hexadecimal)
MIFARE Write
-
A0h
MIFARE Decrement
-
C0h
MIFARE Increment
-
C1h
MIFARE Restore
-
C2h
MIFARE Transfer
-
B0h
All commands use the coding and framing as described in Ref. 3 and Ref. 4 if not
otherwise specified.
9.2 Timings
The timing shown in this document are not to scale and values are rounded to 1 μs.
All given times refer to the data frames including start of communication and end of
communication. A PCD data frame contains the start of communication (1 "start bit")
and the end of communication (one logic 0 + 1 bit length of unmodulated carrier). A
PICC data frame contains the start of communication (1 "start bit") and the end of
communication (1 bit length of no subcarrier).
The minimum command response time is specified according to Ref. 4 as an integer n
which specifies the PCD to PICC frame delay time. The frame delay time from PICC to
PCD is at least 87 μs. The maximum command response time is specified as a time-out
value. Depending on the command, the TACK value specified for command responses
defines the PCD to PICC frame delay time. It does it for either the 4-bit ACK value
specified in Section 9.3 or for a data frame.
All command timings are according to ISO/IEC 14443-3 frame specification as shown for
the Frame Delay Time in Figure 11. For more details refer to Ref. 3 and Ref. 4.
last data bit transmitted by the PCD
first modulation of the PICC
FDT = (n* 128 + 84)/fc
128/fc
logic „1“
256/fc
end of communication (E)
128/fc
start of
communication (S)
FDT = (n* 128 + 20)/fc
128/fc
logic „0“
256/fc
end of communication (E)
128/fc
start of
communication (S)
aaa-006279
Figure 11. Frame Delay Time (from PCD to PICC) and TACK and TNAK
Remark: Due to the coding of commands, the measured timings usually excludes (a part
of) the end of communication. Consider this factor when comparing the specified with the
measured times.
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9.3 MIFARE Classic ACK and NAK
The MIFARE Classic uses a 4 bit ACK / NAK as shown in Table 10.
Table 10. MIFARE ACK and NAK
Code (4-bit)
Transfer Buffer Validity
Description
Ah
Acknowledge (ACK)
0h
valid
invalid operation
1h
valid
parity or CRC error
4h
invalid
invalid operation
5h
invalid
parity or CRC error
9.4 ATQA and SAK responses
For details on the type identification procedure please refer to Ref. 2.
The MF1S50yyX/V1 answers to a REQA or WUPA command with the ATQA value
shown in Table 11 and to a Select CL1 command (CL2 for the 7-byte UID variant) with
the SAK value shown in Table 12.
Table 11. ATQA response of the MF1S50yyX/V1
Bit Number
Sales Type
Hex Value
16 15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
MF1S500yX
00 44h
0
0
0
0
0
0
0
0
0
1
0
0
0
1
0
0
MF1S503yX
00 04h
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
MF1S700yX
00 42h
0
0
0
0
0
0
0
0
0
1
0
0
0
0
1
0
MF1S703yX
00 02h
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
Table 12. SAK response of the MF1S50yyX/V1
Bit Number
Sales Type
Hex Value
8
7
6
5
4
3
2
1
MF1S50yyX/V1
08h
0
0
0
0
1
0
0
0
Remark: The ATQA coding in bits 7 and 8 indicate the UID size according to ISO/IEC
14443 independent from the settings of the UID usage.
Remark: The bit numbering in the ISO/IEC 14443 starts with LSBit = bit 1, but not LSBit
= bit 0. So one byte counts bit 1 to 8 instead of bit 0 to 7.
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10 UID Options and Handling
The MF1S50yyX/V1 product family offers two delivery options for the UID which is stored
in block 0 of sector 0.
• 7-byte UID
• 4-byte NUID (Non-Unique ID)
This section describes the MIFARE Classic MF1S50yyX/V1 operation when using one of
the 2 UID options with respect to card selection, authentication and personalization. See
also Ref. 6 for details on how to handle UIDs and NUIDs with MIFARE Classic products.
10.1 7-byte UID Operation
All MF1S500yXDyy products are featuring a 7-byte UID. This 7-byte UID is stored in
block 0 of sector 0 as shown in Figure 7. The behaviour during anti-collision, selection
and authentication can be configured during personalization for this UID variant.
10.1.1 Personalization Options
The 7-byte UID variants of the MF1S50yyX/V1 can be operated with four different
functionalities, denoted as UIDFn (UID Functionality n).
1. UIDF0: anti-collision and selection with the double size UID according to ISO/IEC
14443-3
2. UIDF1: anti-collision and selection with the double size UID according to ISO/IEC
14443-3 and optional usage of a selection process shortcut
3. UIDF2: anti-collision and selection with a single size random ID according to ISO/IEC
14443-3
4. UIDF3: anti-collision and selection with a single size NUID according to ISO/IEC
14443-3 where the NUID is calculated out of the 7-byte UID
The anti-collision and selection procedure and the implications on the authentication
process are detailed in Section 10.1.2 and Section 10.1.3.
The default configuration at delivery is option 1 which enables the ISO/IEC 14443-3
compliant anti-collision and selection. This configuration can be changed using the
‘Personalize UID Usage’ command. The execution of this command requires an
authentication to sector 0. Once this command has been issued and accepted by the
PICC, the configuration is automatically locked. A subsequently issued ‘Personalize UID
Usage’ command is not executed and a NAK is replied by the PICC.
Remark: As the configuration is changeable at delivery, it is strongly recommended to
send this command at personalization of the card to prevent unwanted changes in the
field. This should also be done if the default configuration is used.
Remark: The configuration becomes effective only after PICC unselect or PICC field
reset.
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PCD
Cmd
Type
CRC
ACK
PICC #ACK#
368 µs
TACK
59 µs
TNAK
59 µs
NAK
PICC #NAK#
TTimeOut
TimeOut
001aan919
Figure 12. Personalize UID Usage
Table 13. Personalize UID Usage command
Name
Code
Description
Length
Cmd
40h
Set anti-collision, selection and
authentication behaviour
1 byte
Type
-
Encoded type of UID usage:
UIDF0: 00h
UIDF1: 40h
UIDF2: 20h
UIDF3: 60h
1 byte
CRC
-
CRC according to Ref. 4
2 bytes
ACK, NAK
see Table 10
see Section 9.3
4-bit
Table 14. Personalize UID Usage timing
TACK min
Personalize UID Usage n=9
TACK max
TNAK min
TNAK max
TTimeOut
TTimeOut
n=9
TTimeOut
10 ms
10.1.2 Anti-collision and Selection
Depending on the chosen personalization option there are certain possibilities to perform
anti-collision and selection. To bring the MIFARE Classic contactless IC into the ACTIVE
state according to ISO/IEC 14443-3, the following sequences are available.
Sequence 1: ISO/IEC 14443-3 compliant anti-collision and selection using the cascade
level 1 followed by the cascade level 2 SEL command
Sequence 2: using cascade level 1 anti-collision and selection procedure followed by a
Read command from block 0
Sequence 3: ISO/IEC 14443-3 compliant anti-collision and selection using the cascade
level 1 SEL command
Remark: The Read from Block 0 in Sequence 2 does not require a prior authentication to
Sector 0 and is transmitted in plain data. For all other sequences, the readout from Block
0 in Sector 0 is encrypted and requires an authentication to that sector.
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Remark: The settings done with Personalize UID Usage do not change the ATQA
coding.
Table 15. Available activation sequences for 7-byte UID options
UID Functionality
Available Activation Sequences
UIDF0
Sequence 1
UIDF1
Sequence 1, Sequence 2
UIDF2
Sequence 3
UIDF3
Sequence 3
10.1.3 Authentication
During the authentication process, 4-byte of the UID are passed on to the MIFARE
Classic Authenticate command of the contactless reader IC. Depending on the activation
sequence, those 4-byte are chosen differently. In general, the input parameter to the
MIFARE Classic Authenticate command is the set of 4 bytes retrieved during the last
cascade level from the ISO/IEC 14443-3 Type A anticollision.
Table 16. Input parameter to MIFARE Classic Authenticate
UID Functionality
Input to MIFARE Classic Authenticate Command
Sequence 1
CL2 bytes (UID3...UID6)
Sequence 2
CL1 bytes (CT, UID0...UID2)
Sequence 3
4-byte NUID/RID (UID0...UID3)
10.2 4-byte UID Operation
All MF1S503yXDyy products are featuring a 4-byte NUID. This 4-byte NUID is stored in
block 0 of sector 0 as shown in Figure 6.
10.2.1 Anti-collision and Selection
The anti-collision and selection process for the product variants featuring 4-byte NUIDs is
done according to ISO/IEC 14443-3 Type A using cascade level 1 only.
10.2.2 Authentication
The input parameter to the MIFARE Classic Authenticate command is the full 4-byte
UID retrieved during the anti-collision procedure. This is the same as for the activation
Sequence 3 in the 7-byte UID variant.
11 Load Modulation Strength Option
The MIFARE Classic EV1 with 1K memory features the possibility to set the load
modulation strength to high or normal. The default level is set to a high modulation
strength and it is recommended for optimal performance to maintain this level and only
switch to the low load modulation strength if the contactless system requires it.
Remark: The configuration becomes effective only after a PICC unselect or a PICC field
reset. The configuration can be changed multiple times by asserting the command.
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Remark: The MIFARE Classic EV1 with 1K memory needs to be authenticated to sector
0 with Key A to perform the SET_MOD_TYPE command. The Access Bits for sector 0
are irrelevant.
PCD
Cmd
Type
CRC
ACK
PICC #ACK#
368 µs
TACK
59 µs
TNAK
59 µs
NAK
PICC #NAK#
TTimeOut
TimeOut
001aan919
Figure 13. SET_MOD_TYPE
Table 17. SET_MOD_TYPE command
Name
Code
Description
Length
Cmd
43h
Set load modulation strength
1 byte
Type
-
Encoded load modulation strength:
strong modulation: 01h (default)
normal modulation: 00h
1 byte
CRC
-
CRC according to Ref. 4
2 bytes
ACK, NAK
see Table 10
see Section 9.3
4-bit
Table 18. SET_MOD_TYPE timing
SET_MOD_TYPE
TACK min
TACK max
TNAK min
TNAK max
TTimeOut
n=9
TTimeOut
n=9
TTimeOut
5 ms
The configured load modulation is shown in the manufacturer data of block 0 in sector 0.
The exact location is shown below in Figure 14 and Table 19.
Block 0/Sector 0
Byte
0
1
2
3
4
5
6
7
8
9
10
11
12
13
Load Modulation Status Byte
14
15
aaa-012192
Figure 14. Byte Location of Load Modulation Status in Block 0 / Sector 0
Table 19. Load Modulation Status Indication
Bit Number
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Product data sheet
COMPANY PUBLIC
Load Modulation Type
Hex Value
7
6
5
4
3
2
1
0
strong load modulation
20h (default)
0
0
1
0
0
0
0
0
normal load modulation
00h
0
0
0
0
0
0
0
0
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12 MIFARE Classic commands
12.1 MIFARE Classic Authentication
The MIFARE Classic authentication is a 3-pass mutual authentication which needs two
pairs of command-response. These two parts, MIFARE Classic authentication part 1 and
part 2 are shown in Figure 15, Figure 16 and Table 20.
Table 21 shows the required timing.
PCD
Auth
Addr
CRC
Token RB
PICC ,,ACK''
TACK
368 µs
359 µs
NAK
PICC ,,NAK''
TNAK
59 µs
TTimeOut
Time out
001aan004
Figure 15. MIFARE Authentication part 1
PCD
Token AB
Token BA
PICC #ACK#
TACK
708 µs
359 µs
TTimeOut
TimeOut
001aan917
Figure 16. MIFARE Authentication part 2
Table 20. MIFARE Classic authentication command
MF1S50yyX_V1
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Name
Code
Description
Length
Auth (with Key A)
60h
Authentication with Key A
1 byte
Auth (with Key B)
61h
Authentication with Key B
1 byte
Addr
-
MIFARE Block address (00h to FFh)
1 byte
CRC
-
CRC according to Ref. 4
2 bytes
Token RB
-
Challenge 1 (Random Number)
4 bytes
Token AB
-
Challenge 2 (encrypted data)
8 bytes
Token BA
-
Challenge 2 (encrypted data)
4 bytes
NAK
see Table 10
see Section 9.3
4-bit
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Table 21. MIFARE Classic authentication timing
TACK min
TACK max
TNAK min
TNAK max
TTimeOut
Authentication part 1
n=9
TTimeOut
n=9
n=9
1 ms
Authentication part 2
n=9
TTimeOut
1 ms
Remark: The minimum required time between MIFARE Classic Authentication part 1
and part 2 is the minimum required FDT according to Ref. 4. There is no maximum time
specified.
Remark: The MIFARE Classic authentication and encryption requires an NFC reader
IC for MIFARE products (e.g. the CL RC632). For more details about the authentication
command refer to the corresponding data sheet (e.g. Ref. 5). The 4-byte input parameter
for the MIFARE Classic Authentication is detailed in Section 10.1.3 and Section 10.2.2.
12.2 MIFARE Read
The MIFARE Read requires a block address, and returns the 16 bytes of one MIFARE
Classic block. The command structure is shown in Figure 17 and Table 22.
Table 23 shows the required timing.
PCD
Cmd
Addr
CRC
Data
PICC ,,ACK''
TACK
368 µs
CRC
1548 µs
NAK
PICC ,,NAK''
TNAK
59 µs
TTimeOut
Time out
001aan014
Figure 17. MIFARE Read
Table 22. MIFARE Read command
Name
Code
Description
Length
Cmd
30h
Read one block
1 byte
Addr
-
MIFARE Block address (00h to FFh)
1 byte
CRC
-
CRC according to Ref. 4
2 bytes
Data
-
Data content of the addressed block
16 bytes
NAK
see Table 10
see Section 9.3
4-bit
Table 23. MIFARE Read timing
Read
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TACK min
TACK max
TNAK min
TNAK max
TTimeOut
n=9
TTimeOut
n=9
TTimeOut
5 ms
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12.3 MIFARE Write
The MIFARE Write requires a block address, and writes 16 bytes of data into the
addressed MIFARE Classic EV1 with 1K memory block. It needs two pairs of commandresponse. These two parts, MIFARE Write part 1 and part 2 are shown in Figure 18 and
Figure 19 and Table 24.
Table 25 shows the required timing.
PCD
Cmd
Addr
CRC
ACK
PICC ,,ACK''
TACK
368 µs
59 µs
NAK
PICC ,,NAK''
TNAK
59 µs
TTimeOut
Time out
001aan015
Figure 18. MIFARE Write part 1
PCD
Data
CRC
ACK
PICC ,,ACK''
1558 µs
TACK
59 µs
NAK
PICC ,,NAK''
TNAK
59 µs
TTimeOut
Time out
001aan016
Figure 19. MIFARE Write part 2
Table 24. MIFARE Write command
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Name
Code
Description
Length
Cmd
A0h
Write one block
1 byte
Addr
-
MIFARE Block or Page address (00h 1 byte
to FFh)
CRC
-
CRC according to Ref. 4
2 bytes
Data
-
Data
16 bytes
NAK
see Table 10
see Section 9.3
4-bit
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Table 25. MIFARE Write timing
TACK min
TACK max
TNAK min
TNAK max
TTimeOut
Write part 1
n=9
TTimeOut
n=9
TTimeOut
5 ms
Write part 2
n=9
TTimeOut
n=9
TTimeOut
10 ms
Remark: The minimum required time between MIFARE Write part 1 and part 2 is the
minimum required FDT according to Ref. 4. There is no maximum time specified.
12.4 MIFARE Increment, Decrement and Restore
The MIFARE Increment requires a source block address and an operand. It adds the
operand to the value of the addressed block, and stores the result in the Transfer Buffer.
The MIFARE Decrement requires a source block address and an operand. It subtracts
the operand from the value of the addressed block, and stores the result in the Transfer
Buffer.
The MIFARE Restore requires a source block address. It copies the value of the
addressed block into the Transfer Buffer. The 4 byte Operand in the second part of the
command is not used and may contain arbitrary values.
All three commands are responding with a NAK to the first command part if the
addressed block is not formatted to be a valid value block, see Section 8.6.2.1.
The two parts of each command are shown in Figure 20 and Figure 21 and Table 26.
Table 27 shows the required timing.
PCD
Cmd
Addr
CRC
ACK
PICC ,,ACK''
368 µs
TACK
59 µs
NAK
PICC ,,NAK''
TNAK
59 µs
TTimeOut
Time out
001aan015
Figure 20. MIFARE Increment, Decrement, Restore part 1
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PCD
Data
CRC
PICC ,,ACK''
538 µs
NAK
PICC ,,NAK''
TNAK
59 µs
TTimeOut
Time out
001aan009
1. Increment, Decrement and Restore part 2 does not acknowledge
Figure 21. MIFARE Increment, Decrement, Restore part 2
Table 26. MIFARE Increment, Decrement and Restore command
Name
Code
Description
Length
Cmd
C1h
Increment
1 byte
Cmd
C0h
Decrement
1 byte
Cmd
C2h
Restore
1 byte
Addr
-
MIFARE source block address (00h to FFh)
1 byte
CRC
-
CRC according to Ref. 4
2 bytes
Data
-
Operand (4 byte signed integer)
4 bytes
NAK
see Table 10
see Section 9.3
4-bit
Table 27. MIFARE Increment, Decrement and Restore timing
TACK min
TACK max
TNAK min
TNAK max
TTimeOut
Increment,
Decrement, and
Restore part 1
n=9
TTimeOut
n=9
TTimeOut
5 ms
Increment,
Decrement, and
Restore part 2
n=9
TTimeOut
n=9
TTimeOut
5 ms
Remark: The minimum required time between MIFARE Increment, Decrement, and
Restore part 1 and part 2 is the minimum required FDT according to Ref. 4. There is no
maximum time specified.
Remark: The MIFARE Increment, Decrement, and Restore commands require a
MIFARE Transfer to store the value into a destination block.
Remark: The MIFARE Increment, Decrement, and Restore command part 2 does not
provide an acknowledgement, so the regular time out has to be used instead.
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12.5 MIFARE Transfer
The MIFARE Transfer requires a destination block address, and writes the value stored
in the Transfer Buffer into one MIFARE Classic block. The command structure is shown
in Figure 22 and Table 28.
Table 29 shows the required timing.
PCD
Cmd
Addr
CRC
ACK
PICC ,,ACK''
TACK
368 µs
59 µs
NAK
PICC ,,NAK''
TNAK
59 µs
TTimeOut
Time out
001aan015
Figure 22. MIFARE Transfer
Table 28. MIFARE Transfer command
Name
Code
Description
Length
Cmd
B0h
Write the value from the Transfer
Buffer into destination block
1 byte
Addr
-
MIFARE destination block address
(00h to FFh)
1 byte
CRC
-
CRC according to Ref. 4
2 bytes
NAK
see Table 10
see Section 9.3
4-bit
Table 29. MIFARE Transfer timing
Transfer
TACK min
TACK max
TNAK min
TNAK max
TTimeOut
n=9
TTimeOut
n=9
TTimeOut
10 ms
13 Limiting values
Stresses above one or more of the limiting values may cause permanent damage to the
device. Exposure to limiting values for extended periods may affect device reliability.
Table 30. Limiting values
In accordance with the Absolute Maximum Rating System (IEC 60134).
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Symbol
Parameter
Min
Max
Unit
II
input current
-
30
mA
Ptot/pack
total power dissipation per package
-
120
mW
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MF1S50YYX_V1
NXP Semiconductors
MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
Symbol
Parameter
Min
Max
Unit
Tstg
storage temperature
-55
125
°C
Tamb
ambient temperature
-25
70
°C
2
-
kV
VESD
[1]
electrostatic discharge voltage on LA/LB
[1]
ANSI/ESDA/JEDEC JS-001; Human body model: C = 100 pF, R = 1.5 kΩ
CAUTION
This device has limited built-in ElectroStatic Discharge (ESD) protection.
The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the gates.
14 Characteristics
Table 31. Characteristics
Symbol
Parameter
Conditions
Ci
input capacitance
fi
input frequency
[1]
Min
Typ
Max
Unit
14.9
16.9
19.0
pF
-
13.56
-
MHz
EEPROM characteristics
tret
retention time
Tamb = 22 °C
10
-
-
year
Nendu(W)
write endurance
Tamb = 22 °C
100000
200000
-
cycle
[1]
Tamb=22°C, f=13,56Mhz, VLaLb = 1,5 V RMS
15 Wafer specification
For more details on the wafer delivery forms see Ref. 9.
Table 32. Wafer specifications MF1S50yyXDUy
Wafer
diameter
200 mm typical (8 inches)
300 mm typical (12 inches)
maximum diameter after foil expansion
210 mm (8 inches)
not applicable (12 inches)
die seperation process
laser dicing (8 inches)
blade dicing (12 inches)
thickness MF1S50yyXDUD
120 μm ± 15 μm
MF1S50yyXDUF
75 μm ± 10 μm
flatness
not applicable
Potential Good Dies per Wafer (PGDW)
64727 (8 inches)
147540 (12 inches)
Wafer backside
material
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Si
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MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
treatment
ground and stress relieve
roughness
Ra max = 0.5 μm
Rt max = 5 μm
Chip dimensions
[1]
x = 658 μm (8 inches)
x = 660 μm (12 inches)
step size
y = 713 μm (8 inches)
y = 715 μm (12 inches)
[1]
typical = 19 μm
gap between chips
minimum = 5 μm
not applicable (12 inches)
Passivation
type
sandwich structure
material
PSG / nitride
thickness
500 nm / 600 nm
Au bump (substrate connected to VSS)
material
> 99.9 % pure Au
hardness
35 to 80 HV 0.005
shear strength
> 70 MPa
height
18 μm
height uniformity
within a die = ±2 μm
within a wafer = ±3 μm
wafer to wafer = ±4 μm
flatness
minimum = ±1.5 μm
size
LA, LB, VSS, TEST
size variation
±5 μm
under bump metallization
sputtered TiW
[1]
[2]
[2]
= 66 μm × 66 μm
The step size and the gap between chips may vary due to changing foil expansion
Pads VSS and TESTIO are disconnected when wafer is sawn.
15.1 Fail die identification
Electronic wafer mapping covers the electrical test results and additionally the results of
mechanical/visual inspection. No ink dots are applied.
15.2 Package outline
For more details on the contactless modules MOA4 and MOA8 please refer to Ref. 7 and
Ref. 8.
MF1S50yyX_V1
Product data sheet
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MF1S50YYX_V1
NXP Semiconductors
MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
PLLMC: plastic leadless module carrier package; 35 mm wide tape
SOT500-2
X
D
A
detail X
0
10
scale
DIMENSIONS (mm are the original dimensions)
UNIT
A (1)
max.
D
mm
0.33
35.05
34.95
20 mm
For unspecified dimensions see PLLMC-drawing given in the subpackage code.
Note
1. Total package thickness, exclusive punching burr.
REFERENCES
OUTLINE
VERSION
IEC
JEDEC
JEITA
SOT500-2
---
---
---
EUROPEAN
PROJECTION
ISSUE DATE
03-09-17
06-05-22
Figure 23. Package outline SOT500-2
MF1S50yyX_V1
Product data sheet
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MF1S50YYX_V1
NXP Semiconductors
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PLLMC: plastic leadless module carrier package; 35 mm wide tape
SOT500-4
X
D
A
0
10
A(1)
D
max 0.26 35.05
nom
35.00
min
34.95
mm
detail X
scale
Dimensions
Unit
20 mm
For unspecified dimensions see PLLMC-drawing given in the subpackage code.
Note
1. Total package thickness, exclusive punching burr.
sot500-4_po
References
Outline
version
IEC
JEDEC
JEITA
SOT500-4
---
---
---
European
projection
Issue date
11-02-18
Figure 24. Package outline SOT500-4
MF1S50yyX_V1
Product data sheet
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MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
16 Bare die outline
For more details on the wafer delivery forms, see Ref. 9.
Chip Step (8 inches)
Chip Step (12 inches)
Bump size
LA, LB, VSS, TEST
x [µm]
y [µm]
658(1)
660
713(1)
715
60
60
typ. 19(1)
min. 5
typ. 19(1)
min. 5
238
LA
TESTIO
typ. 713(1)
633
43
VSS
LB
43
y
578
x
typ. 658(1)
aaa-012193
1. Laser dicing: The air gap and thus the step size may vary due to varying foil expansion
2. All dimensions in µm, pad locations measured from metal ring edge (see detail)
Figure 25. Bare die outline MF1S50yyXDUz/V1
17 Abbreviations
Table 33. Abbreviations and symbols
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Acronym
Description
ACK
ACKnowledge
ATQA
Answer To reQuest, Type A
CRC
Cyclic Redundancy Check
CT
Cascade Tag (value 88h) as defined in ISO/IEC 14443-3 Type A
EEPROM
Electrically Erasable Programmable Read-Only Memory
FDT
Frame Delay Time
FFC
Film Frame Carrier
IC
Integrated Circuit
LCR
L = inductance, Capacitance, Resistance (LCR meter)
LSB
Least Significant Bit
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MF1S50YYX_V1
NXP Semiconductors
MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
Acronym
Description
NAK
Not AcKnowledge
NUID
Non-Unique IDentifier
NV
Non-Volatile memory
PCD
Proximity Coupling Device (Contactless Reader)
PICC
Proximity Integrated Circuit Card (Contactless Card)
REQA
REQuest command, Type A
RID
Random ID
RF
Radio Frequency
RMS
Root Mean Square
RNG
Random Number Generator
SAK
Select AcKnowledge, type A
SECS-II
SEMI Equipment Communications Standard part 2
TiW
Titanium Tungsten
UID
Unique IDentifier
WUPA
Wake-Up Protocol type A
18 References
[1]
MIFARE (Card) Coil Design Guide
1
Application note, BU-ID Document number 0117**
[2]
MIFARE Type Identification Procedure
1
Application note, BU-ID Document number 0184**
[3]
ISO/IEC 14443-2
2001
[4]
ISO/IEC 14443-3
2001
[5]
MIFARE & I-CODE CL RC632 Multiple protocol contactless reader IC
Product data sheet
[6]
MIFARE product and handling of UIDs
1 ** ... document version number
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
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MF1S50YYX_V1
NXP Semiconductors
MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
1
Application note, BU-ID Document number 1907**
[7]
Contactless smart card module specification MOA4
1
Delivery Type Description, BU-ID Document number 0823**
[8]
Contactless smart card module specification MOA8
1
Delivery Type Description, BU-ID Document number 1636**
[9]
General specification for 8" wafer on UV-tape; delivery types
1
Delivery Type Description, BU-ID Document number 1005**
19 Revision history
Table 34. Revision history
Document ID
Release date
Data sheet status
Change notice
Supersedes
MF1S50yyX/V1 v.3.2
20180523
Product data sheet
-
MF1S50yyX/V1 v.3.1
Modifications:
• Editorial updates.
MF1S50yyX/V1 v.3.1
20171121
-
MF1S50yyX/V1 v.3.0
Modifications:
• 12 inch FFC delivery forms added
• Format updated
MF1S50yyX/V1 v.3.0
20140303
-
-
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Product data sheet
Product data sheet
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20 Legal information
20.1 Data sheet status
Document status
[1][2]
Product status
[3]
Definition
Objective [short] data sheet
Development
This document contains data from the objective specification for product
development.
Preliminary [short] data sheet
Qualification
This document contains data from the preliminary specification.
Product [short] data sheet
Production
This document contains the product specification.
[1]
[2]
[3]
Please consult the most recently issued document before initiating or completing a design.
The term 'short data sheet' is explained in section "Definitions".
The product status of device(s) described in this document may have changed since this document was published and may differ in case of multiple
devices. The latest product status information is available on the Internet at URL http://www.nxp.com.
20.2 Definitions
Draft — The document is a draft version only. The content is still under
internal review and subject to formal approval, which may result in
modifications or additions. NXP Semiconductors does not give any
representations or warranties as to the accuracy or completeness of
information included herein and shall have no liability for the consequences
of use of such information.
Short data sheet — A short data sheet is an extract from a full data sheet
with the same product type number(s) and title. A short data sheet is
intended for quick reference only and should not be relied upon to contain
detailed and full information. For detailed and full information see the
relevant full data sheet, which is available on request via the local NXP
Semiconductors sales office. In case of any inconsistency or conflict with the
short data sheet, the full data sheet shall prevail.
Product specification — The information and data provided in a Product
data sheet shall define the specification of the product as agreed between
NXP Semiconductors and its customer, unless NXP Semiconductors and
customer have explicitly agreed otherwise in writing. In no event however,
shall an agreement be valid in which the NXP Semiconductors product
is deemed to offer functions and qualities beyond those described in the
Product data sheet.
20.3 Disclaimers
Limited warranty and liability — Information in this document is believed
to be accurate and reliable. However, NXP Semiconductors does not
give any representations or warranties, expressed or implied, as to the
accuracy or completeness of such information and shall have no liability
for the consequences of use of such information. NXP Semiconductors
takes no responsibility for the content in this document if provided by an
information source outside of NXP Semiconductors. In no event shall NXP
Semiconductors be liable for any indirect, incidental, punitive, special or
consequential damages (including - without limitation - lost profits, lost
savings, business interruption, costs related to the removal or replacement
of any products or rework charges) whether or not such damages are based
on tort (including negligence), warranty, breach of contract or any other
legal theory. Notwithstanding any damages that customer might incur for
any reason whatsoever, NXP Semiconductors’ aggregate and cumulative
liability towards customer for the products described herein shall be limited
in accordance with the Terms and conditions of commercial sale of NXP
Semiconductors.
Right to make changes — NXP Semiconductors reserves the right to
make changes to information published in this document, including without
limitation specifications and product descriptions, at any time and without
notice. This document supersedes and replaces all information supplied prior
to the publication hereof.
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Suitability for use — NXP Semiconductors products are not designed,
authorized or warranted to be suitable for use in life support, life-critical or
safety-critical systems or equipment, nor in applications where failure or
malfunction of an NXP Semiconductors product can reasonably be expected
to result in personal injury, death or severe property or environmental
damage. NXP Semiconductors and its suppliers accept no liability for
inclusion and/or use of NXP Semiconductors products in such equipment or
applications and therefore such inclusion and/or use is at the customer’s own
risk.
Applications — Applications that are described herein for any of these
products are for illustrative purposes only. NXP Semiconductors makes
no representation or warranty that such applications will be suitable
for the specified use without further testing or modification. Customers
are responsible for the design and operation of their applications and
products using NXP Semiconductors products, and NXP Semiconductors
accepts no liability for any assistance with applications or customer product
design. It is customer’s sole responsibility to determine whether the NXP
Semiconductors product is suitable and fit for the customer’s applications
and products planned, as well as for the planned application and use of
customer’s third party customer(s). Customers should provide appropriate
design and operating safeguards to minimize the risks associated with
their applications and products. NXP Semiconductors does not accept any
liability related to any default, damage, costs or problem which is based
on any weakness or default in the customer’s applications or products, or
the application or use by customer’s third party customer(s). Customer is
responsible for doing all necessary testing for the customer’s applications
and products using NXP Semiconductors products in order to avoid a
default of the applications and the products or of the application or use by
customer’s third party customer(s). NXP does not accept any liability in this
respect.
Limiting values — Stress above one or more limiting values (as defined in
the Absolute Maximum Ratings System of IEC 60134) will cause permanent
damage to the device. Limiting values are stress ratings only and (proper)
operation of the device at these or any other conditions above those
given in the Recommended operating conditions section (if present) or the
Characteristics sections of this document is not warranted. Constant or
repeated exposure to limiting values will permanently and irreversibly affect
the quality and reliability of the device.
Terms and conditions of commercial sale — NXP Semiconductors
products are sold subject to the general terms and conditions of commercial
sale, as published at http://www.nxp.com/profile/terms, unless otherwise
agreed in a valid written individual agreement. In case an individual
agreement is concluded only the terms and conditions of the respective
agreement shall apply. NXP Semiconductors hereby expressly objects to
applying the customer’s general terms and conditions with regard to the
purchase of NXP Semiconductors products by customer.
No offer to sell or license — Nothing in this document may be interpreted
or construed as an offer to sell products that is open for acceptance or
the grant, conveyance or implication of any license under any copyrights,
patents or other industrial or intellectual property rights.
All information provided in this document is subject to legal disclaimers.
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NXP Semiconductors
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Quick reference data — The Quick reference data is an extract of the
product data given in the Limiting values and Characteristics sections of this
document, and as such is not complete, exhaustive or legally binding.
Export control — This document as well as the item(s) described herein
may be subject to export control regulations. Export might require a prior
authorization from competent authorities.
Non-automotive qualified products — Unless this data sheet expressly
states that this specific NXP Semiconductors product is automotive qualified,
the product is not suitable for automotive use. It is neither qualified nor
tested in accordance with automotive testing or application requirements.
NXP Semiconductors accepts no liability for inclusion and/or use of nonautomotive qualified products in automotive equipment or applications. In
the event that customer uses the product for design-in and use in automotive
applications to automotive specifications and standards, customer (a) shall
use the product without NXP Semiconductors’ warranty of the product for
such automotive applications, use and specifications, and (b) whenever
customer uses the product for automotive applications beyond NXP
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Semiconductors’ specifications such use shall be solely at customer’s own
risk, and (c) customer fully indemnifies NXP Semiconductors for any liability,
damages or failed product claims resulting from customer design and use
of the product for automotive applications beyond NXP Semiconductors’
standard warranty and NXP Semiconductors’ product specifications.
Translations — A non-English (translated) version of a document is for
reference only. The English version shall prevail in case of any discrepancy
between the translated and English versions.
20.4 Trademarks
Notice: All referenced brands, product names, service names and
trademarks are the property of their respective owners.
MIFARE — is a trademark of NXP B.V.
MIFARE Classic — is a trademark of NXP B.V.
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MF1S50YYX_V1
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Tables
Tab. 1.
Tab. 2.
Tab. 3.
Tab. 4.
Tab. 5.
Tab. 6.
Tab. 7.
Tab. 8.
Tab. 9.
Tab. 10.
Tab. 11.
Tab. 12.
Tab. 13.
Tab. 14.
Tab. 15.
Tab. 16.
Tab. 17.
Quick reference data .........................................2
Ordering information ..........................................3
Pin allocation table ............................................4
Value block format example ............................10
Memory operations ..........................................10
Access conditions ........................................... 11
Access conditions for the sector trailer ............12
Access conditions for data blocks ................... 12
Command overview .........................................13
MIFARE ACK and NAK ...................................15
ATQA response of the MF1S50yyX/V1 ........... 15
SAK response of the MF1S50yyX/V1 ............. 15
Personalize UID Usage command .................. 17
Personalize UID Usage timing ........................ 17
Available activation sequences for 7-byte
UID options ..................................................... 18
Input parameter to MIFARE Classic
Authenticate .....................................................18
SET_MOD_TYPE command ........................... 19
Tab. 18.
Tab. 19.
Tab. 20.
Tab. 21.
Tab. 22.
Tab. 23.
Tab. 24.
Tab. 25.
Tab. 26.
Tab. 27.
Tab. 28.
Tab. 29.
Tab. 30.
Tab. 31.
Tab. 32.
Tab. 33.
Tab. 34.
SET_MOD_TYPE timing ................................. 19
Load Modulation Status Indication .................. 19
MIFARE Classic authentication command ...... 20
MIFARE Classic authentication timing ............ 21
MIFARE Read command ................................ 21
MIFARE Read timing ...................................... 21
MIFARE Write command ................................ 22
MIFARE Write timing .......................................23
MIFARE Increment, Decrement and Restore
command .........................................................24
MIFARE Increment, Decrement and Restore
timing ............................................................... 24
MIFARE Transfer command ............................25
MIFARE Transfer timing ..................................25
Limiting values ................................................ 25
Characteristics .................................................26
Wafer specifications MF1S50yyXDUy .............26
Abbreviations and symbols ............................. 30
Revision history ...............................................32
Figures
Fig. 1.
Fig. 2.
Fig. 3.
Fig. 4.
Fig. 5.
Fig. 6.
Fig. 7.
Fig. 8.
Fig. 9.
Fig. 10.
Fig. 11.
Fig. 12.
Fig. 13.
Contactless MIFARE product-based system ..... 1
Block diagram of MF1S50yyX/V1 ......................3
Pin configuration for SOT500-2 (MOA4) ........... 4
MIFARE Classic command flow diagram .......... 6
Memory organization .........................................8
Manufacturer block for MF1S503yX with 4byte NUID ..........................................................8
Manufacturer block for MF1S500yX with 7byte UID ............................................................ 9
Value blocks ......................................................9
Sector trailer ....................................................10
Access conditions ........................................... 11
Frame Delay Time (from PCD to PICC) and
TACK and TNAK .............................................14
Personalize UID Usage ...................................17
SET_MOD_TYPE ............................................19
MF1S50yyX_V1
Product data sheet
COMPANY PUBLIC
Fig. 14.
Fig. 15.
Fig. 16.
Fig. 17.
Fig. 18.
Fig. 19.
Fig. 20.
Fig. 21.
Fig. 22.
Fig. 23.
Fig. 24.
Fig. 25.
Byte Location of Load Modulation Status in
Block 0 / Sector 0 ........................................... 19
MIFARE Authentication part 1 .........................20
MIFARE Authentication part 2 .........................20
MIFARE Read ................................................. 21
MIFARE Write part 1 .......................................22
MIFARE Write part 2 .......................................22
MIFARE Increment, Decrement, Restore
part 1 ...............................................................23
MIFARE Increment, Decrement, Restore
part 2 ...............................................................24
MIFARE Transfer ............................................ 25
Package outline SOT500-2 ............................. 28
Package outline SOT500-4 ............................. 29
Bare die outline MF1S50yyXDUz/V1 ...............30
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MF1S50YYX_V1
NXP Semiconductors
MIFARE Classic EV1 1K - Mainstream contactless smart card IC for fast and easy solution development
Contents
1
1.1
1.2
1.3
1.4
2
2.1
3
4
5
6
7
7.1
8
8.1
8.2
8.2.1
8.2.2
8.2.3
8.2.4
8.2.5
8.3
8.4
8.5
8.6
8.6.1
8.6.2
8.6.2.1
8.6.3
8.7
8.7.1
8.7.2
8.7.3
9
9.1
9.2
9.3
9.4
10
10.1
10.1.1
10.1.2
10.1.3
10.2
10.2.1
10.2.2
11
12
12.1
12.2
12.3
12.4
12.5
General description ............................................ 1
Anticollision ........................................................ 1
Simple integration and user convenience .......... 1
Security and privacy .......................................... 1
Delivery options ................................................. 1
Features and benefits .........................................2
EEPROM ........................................................... 2
Applications .........................................................2
Quick reference data .......................................... 2
Ordering information .......................................... 3
Block diagram ..................................................... 3
Pinning information ............................................ 4
Pinning ............................................................... 4
Functional description ........................................4
Block description ............................................... 4
Communication principle ................................... 5
Request standard / all ....................................... 5
Anticollision loop ................................................ 5
Select card .........................................................5
Three pass authentication ................................. 5
Memory operations ............................................ 6
Data integrity ..................................................... 6
Three pass authentication sequence .................7
RF interface ....................................................... 7
Memory organization ......................................... 7
Manufacturer block ............................................ 8
Data blocks ........................................................9
Value blocks ...................................................... 9
Sector trailer .................................................... 10
Memory access ............................................... 10
Access conditions ............................................ 11
Access conditions for the sector trailer ............ 12
Access conditions for data blocks ................... 12
Command overview .......................................... 13
MIFARE Classic command overview ...............13
Timings ............................................................ 14
MIFARE Classic ACK and NAK .......................15
ATQA and SAK responses .............................. 15
UID Options and Handling ............................... 16
7-byte UID Operation .......................................16
Personalization Options ...................................16
Anti-collision and Selection ..............................17
Authentication .................................................. 18
4-byte UID Operation .......................................18
Anti-collision and Selection ..............................18
Authentication .................................................. 18
Load Modulation Strength Option ................... 18
MIFARE Classic commands .............................20
MIFARE Classic Authentication .......................20
MIFARE Read ................................................. 21
MIFARE Write ..................................................22
MIFARE Increment, Decrement and Restore ... 23
MIFARE Transfer .............................................25
13
14
15
15.1
15.2
16
17
18
19
20
Limiting values .................................................. 25
Characteristics .................................................. 26
Wafer specification ........................................... 26
Fail die identification ........................................ 27
Package outline ............................................... 27
Bare die outline .................................................30
Abbreviations .................................................... 30
References ......................................................... 31
Revision history ................................................ 32
Legal information .............................................. 33
Please be aware that important notices concerning this document and the product(s)
described herein, have been included in section 'Legal information'.
© NXP B.V. 2018.
All rights reserved.
For more information, please visit: http://www.nxp.com
For sales office addresses, please send an email to: salesaddresses@nxp.com
Date of release: 23 May 2018
Document identifier: MF1S50yyX_V1
Document number: 279232