ATMEL AT88SC0104CA-MPTG One of a family of devices with user memories from 1kbit to 8kbit Datasheet

Atmel AT88SC0104CA
Atmel CryptoMemory
SUMMARY DATASHEET
Features
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One of a family of devices with user memories from 1Kbit to 8Kbits
1Kbit (128-byte) EEPROM user memory
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Four 256-bit (32-byte) zones
Self-timed write cycle
Single byte or 16-byte page write mode
Programmable access rights for each zone
2Kbit configuration zone
• 37-byte OTP Area for User-defined Codes
• 160-byte Area for User-defined Keys and Passwords
•
High security features
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Smart card features
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This is a summary document.
The complete document is
available on the Atmel website
at www.atmel.com.
ISO 7816 Class B (3V) operation
ISO 7816-3 asynchronous T=0 protocol (Gemplus® Patent) *
Multiple zones, key sets and passwords for multi-application use
Synchronous two-wire serial interface for faster device initialization *
Programmable 8-byte answer-to-reset register
ISO 7816-2 compliant modules
Embedded application features
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•
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•
•
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64-bit mutual authentication protocol (under license of ELVA)
Cryptographic Message Authentication Codes (MAC)
Stream encryption
Four key sets for authentication and encryption
Eight sets of two 24-bit passwords
Anti-tearing function
Voltage and frequency monitors
Low voltage supply: 2.7V – 3.6V
Secure nonvolatile storage for sensitive system or user information
Two-wire serial interface (TWI, 5V compatible)
1.0MHz compatibility for fast operation
Standard 8-lead plastic packages, green compliant (exceeds RoHS)
Same pin configuration as Atmel® AT24CXXX Serial EEPROM in SOIC and
PDIP packages
High reliability
• Endurance: 100,000 cycles
• Data retention: 10 years
• ESD protection: 2,000V min
* Note: Modules available with either T = 0 / 2-wire modes or 2-wire mode only
5200FS−CRYPTO−12/11
Table 1.
Pin Assignments
Pad
Description
ISO
Module
TWI
Module
“SOIC,
PDIP”
TSSOP
Mini-MAP
VCC
Supply Voltage
C1
C1
8
8
4
GND
Ground
C5
C5
4
1
5
SCL/CLK
Serial Clock Input
C3
C3
6
6
2
SDA/IO
Serial Data Input/Output
C7
C7
5
3
7
RST
Reset Input
C2
NC
NC
NC
NC
Figure 1.
Pin Configuration
8-lead SOIC, PDIP
ISO Smart Card Module
VCC=C1
RST=C2
SCL/CLK=C3
NC=C4
C5=GND
NC
C6=NC
NC
C7=SDA/IO
NC
C8=NC
GND
1
VCC
8
7
6
5
NC
SCL
SDA
8-lead Ultra Thin Mini-MAP (MLP 2x3)
8-lead TSSOP
GND
1
2
3
4
8
VCC
NC
2
7
NC
SDA
3
6
C LK
NC
4
5
NC
NC 8
SDA 7
NC 6
GND 5
1
2
3
4
NC
CLK
NC
VCC
Bottom View
TWI Smart Card Module
VCC=C1
C5=GND
NC=C2
C6=NC
SCL/CLK=C3
NC=C4
C7=SDA/IO
C8=NC
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
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1.
Description
The Atmel AT88SC0104CA member of the Atmel CryptoMemory® family is a high-performance secure memory providing
1Kbit of user memory with advanced security and cryptographic features built in. The user memory is divided into four 32-byte
zones, each of which may be individually set with different security access rights or effectively combined together to provide
space for one to four data files. The AT88SC0104CA features an enhanced command set that allows direct communication
with microcontroller hardware two-wire interface thereby allowing for faster firmware development with reduced code space
requirements.
1.1
Smart Card Applications
The AT88SC0104CA provides high security, low cost, and ease of implementation without the need for a microprocessor
operating system. The embedded cryptographic engine provides for dynamic, symmetric-mutual authentication between the
device and host, as well as performing stream encryption for all data and passwords exchanged between the device and host.
Up to four unique key sets may be used for these operations. The AT88SC0104CA offers the ability to communicate with
virtually any smart card reader using the asynchronous T = 0 protocol (Gemplus Patent) defined in ISO 7816-3.
1.2
Embedded Applications
Through dynamic, symmetric-mutual authentication, data encryption, and the use of cryptographic Message Authentication
Codes (MAC), the AT88SC0104CA provides a secure place for storage of sensitive information within a system. With its
tamper detection circuits, this information remains safe even under attack. A two-wire serial interface running at speeds up to
1.0MHz provides fast and efficient communications with up to 15 individually addressable devices. The AT88SC0104CA is
available in industry standard 8-lead packages with the same familiar pin configuration as AT24CXXX Serial EEPROM
devices.
Note:
Does not apply to either the TSSOP or the ultra thin mini-map pinouts
Figure 1-1. Block Diagram
VCC
GND
SCL/CLK
SDA/IO
RST
Power
Management
Authentication,
Encryption and
Certification Unit
Synchronous
Interface
Data Transfer
Asynchronous
ISO Interface
Password
Verification
Reset Block
Answer to Reset
Random
Generator
EEPROM
Atmel AT88SC0104CA [SUMMARY DATASHEET]
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2.
Connection Diagram
Figure 2-1. Connection Diagram
2.7v - 5.5v
2.7v - 3.6v
Microprocessor
CryptoMemory
SDA
SCL
3.
Pin Descriptions
3.1
Supply Voltage (VCC)
The VCC input is a 2.7V to 3.6V positive voltage supplied by the host.
3.2
Clock (SCL/CLK)
When using the asynchronous T = 0 protocol, the CLK (SCL) input provides the device with a carrier frequency f. The nominal
length of one bit emitted on I/O is defined as an “elementary time unit” (ETU) and is equal to 372/ f.
When using the synchronous protocol, data clocking is done on the positive edge of the clock when writing to the device and
on the negative edge of the clock when reading from the device.
3.3
Reset (RST)
The AT88SC0104CA provides an ISO 7816-3 compliant asynchronous Answer-To-Reset (ATR) sequence. Upon activation of
the reset sequence, the device outputs bytes contained in the 64-bit Answer-To-Reset register. An internal pull-up on the RST
input pad allows the device to operate in synchronous mode without bonding RST. The AT88SC0104CA does not support an
Answer-To-Reset sequence in the synchronous mode of operation.
3.4
Serial Data (SDA/IO)
The SDA/IO pin is bidirectional for serial data transfer. This pin is open-drain driven and may be wired with any number of
other open-drain or open-collector devices. An external pull-up resistor should be connected between SDA/IO and VCC. The
value of this resistor and the system capacitance loading the SDA/IO bus will determine the rise time of SDA/IO. This rise time
will determine the maximum frequency during read operations. Low value pull-up resistors will allow higher frequency
operations while drawing higher average power supply current. SDA/IO information applies to both asynchronous and
synchronous protocols.
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4.
*Absolute Maximum Ratings
Operating temperature.................... −40°C to +85°C
*Notice:
Storage temperature ................... −65°C to + 150°C
Voltage on any pin
with respect to ground ...............− 0.7 to VCC +0.7V
Maximum operating voltage ............................. 4.0V
DC output current ......................................... 5.0mA
Table 4-1.
Stresses beyond those listed under “Absolute
Maximum Ratings” may cause permanent damage to
the device. This is a stress rating only and functional
operation of the device at these or any other condition
beyond those indicated in the operational sections of
this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods of
time may affect device reliability.
DC Characteristics
Applicable over recommended operating range from VCC = +2.7 to 3.6V, TAC = -40°C to +85°C (unless otherwise noted)
Symbol
Parameter
(1)
VCC
Supply Voltage
ICC
Supply Current
ICC
Max
Units
3.6
V
Async Read at 3.57MHz
5
mA
Supply Current
Async Write at 3.57MHz
5
mA
ICC
Supply Current
Synch Read at 1MHz
5
mA
ICC
Supply Current
Synch Write at 1MHz
5
mA
ISB
Standby Current
VIN = VCC or GND
100
µA
VIL
SDA/IO Input Low Voltage
0
VCC x 0.2
V
VIL
CLK Input Low Voltage
0
VCC x 0.2
V
VIL
RST Input Low Voltage
0
VCC x 0.2
V
VIH(1)
SDA/IO Input High Voltage
VCC x 0.7
5.5
V
(1)
VIH
SCL/CLK Input High Voltage
VCC x 0.7
5.5
V
VIH(1)
RST Input High Voltage
VCC x 0.7
5.5
V
IIL
SDA/IO Input Low Current
0 < VIL < VCC x 0.15
15
µA
IIL
SCL/CLK Input Low Current
0 < VIL < VCC x 0.15
15
µA
IIL
RST Input Low Current
0 < VIL < VCC x 0.15
50
µA
IIH
SDA/IO Input High Current
VCC x 0.7 < VIH < VCC
20
µA
IIH
SCL/CLK Input High Current
VCC x 0.7 < VIH < VCC
100
µA
IIH
RST Input High Current
VCC x 0.7 < VIH < VCC
150
µA
VOH
SDA/IO Output High Voltage
20K ohm external pull-up
VCC x 0.7
VCC
V
VOL
SDA/IO Output Low Voltage
IOL = 1mA
0
VCC x 0.15
V
IOH
SDA/IO Output High Current
VOH
20
µA
IOL
SDA/IO Output Low Current
VOL
10
mA
Note:
1.
Test Conditions
Min
2.7
Typ
To prevent latch up conditions from occurring during power up of the Atmel AT88SC0104CA, VCC must be turned
on before applying VIH. For powering down, VIH must be removed before turning VCC off
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Table 4-2.
AC Characteristics
Applicable over recommended operating range from VCC = +2.7 to 3.6V, TAC = -40°C to +85°C, CL = 30pF
(unless otherwise noted)
Symbol
Parameter
Min
Max
Units
fCLK
Async Clock Frequency
1
4
MHz
fCLK
Synch Clock Frequency
0
1
MHz
Clock Duty cycle
40
60
%
tR
“Rise Time - SDA/IO, RST”
1
µS
tF
“Fall Time - SDA/IO, RST”
1
µS
tR
Rise Time - SCL/CLK
9% x period
µS
tF
Fall Time - SCL/CLK
9% x period
µS
tAA
Clock Low to Data Out Valid
250
nS
tHD.STA
Start Hold Time
200
nS
tSU.STA
Start Set-up Time
200
nS
tHD.DAT
Data In Hold Time
10
nS
tSU.DAT
Data In Set-up Time
100
nS
tSU.STO
Stop Set-up Time
200
nS
tDH
Data Out Hold Time
20
nS
tWR
Write Cycle Time
5
5.
Device Operations for Synchronous Protocols
5.1
Clock and Data Transitions
mS
The SDA pin is normally pulled high with an external device. Data on the SDA pin may change only during SCL low time
periods (see Figure 5-3 on page 8). Data changes during SCL high periods will indicate a start or stop condition as defined
below.
5.1.1
Start Condition
A high-to-low transition of SDA with SCL high defines a start condition which must precede all commands (see Figure 5-4 on
page 8).
5.1.2
Stop Condition
A low-to-high transition of SDA with SCL high defines a stop condition. After a read sequence, the stop condition will place the
EEPROM in a standby power mode (see Figure 5-4 on page 8).
5.1.3
Acknowledge
All addresses and data words are serially transmitted to and from the EEPROM in 8-bit words. The EEPROM sends a zero to
acknowledge that it has received each word. This happens during the ninth clock cycle (see Figure 5-5 on page 8).
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5.2
Memory Reset
After an interruption in communication due protocol errors, power loss or any reason, perform "Acknowledge Polling" to
properly recover from the condition. Acknowledge polling consists of sending a start condition followed by a valid
CryptoMemory command byte and determining if the device responded with an acknowledge.
Figure 5-1. Bus Time for Two-wire Serial Communications
SCL: Serial Clock, SDA: Serial Data I/O
tHIGH
tF
tR
tLOW
SCL
tSU.STA
tLOW
tHD.STA
tSU.DAT
tHD.DAT
tSU.STO
SDA IN
tAA
tDH
tBUF
SDA OUT
Figure 5-2. Write Cycle Timing
SCL: Serial Clock, SDA: Serial Data I/O
SCL
SDA
8th BIT
ACK
WORDn
twr
STOP
CONDITION
Note:
(1)
START
CONDITION
The write cycle time twr is the time from a valid stop condition of a write sequence to the end of the internal
clear/write cycle
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Figure 5-3. Data Validity
SDA
SCL
DATA STABLE
DATA STABLE
DATA
CHANGE
ALLOWED
Figure 5-4. Start and Stop Definitions
SDA
SCL
START
STOP
Figure 5-5. Output Acknowledge
1
SCL
8
9
DATA IN
DATA OUT
START
ACKNOWLEDGE
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6.
Device Architecture
6.1
User Zones
The EEPROM user memory is divided into four zones of 256 bits each. Multiple zones allow for storage of different types of
data or files in different zones. Access to user zones is permitted only after meeting proper security requirements. These
security requirements are user definable in the configuration memory during device personalization. If the same security
requirements are selected for multiple zones, then these zones may effectively be accessed as one larger zone.
Figure 6-1. User Zones
Zone
User 0
$0
$1
$2
$3
$4
$5
$6
$7
$00
-
32 bytes
$18
User 1
$00
-
32 bytes
$18
User 2
$00
-
32 bytes
$18
User 3
$00
-
32 bytes
$18
7.
Control Logic
Access to the user zones occur only through the control logic built into the device. This logic is configurable through access
registers, key registers and keys programmed into the configuration memory during device personalization. Also implemented
in the control logic is a cryptographic engine for performing the various higher-level security functions of the device.
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8.
Configuration Memory
The configuration memory consists of 2048 bits of EEPROM memory used for storage of passwords, keys, codes, and also
used for definition of security access rights for the user zones. Access rights to the configuration memory are defined in the
control logic and are not alterable by the user after completion of personalization.
Figure 8-1. Configuration Memory
$0
$1
$2
$3
$00
$08
$4
$5
$6
$7
Answer To Reset
Fab Code
MTZ
$10
Identifitcation
Card Manufacturer Code
Lot History Code
$18
DCR
$20
AR0
Read Only
Identification Number Nc
PR0
AR1
PR1
AR2
PR2
AR3
PR3
$28
$30
Reserved
Access Control
$38
$40
Issuer Code
$48
$50
$58
$60
$68
$70
For Authentication and Encryption use
Cryptography
For Authentication and Encryption use
Secret
$78
$80
$88
$90
$98
$A0
$A8
$B0
PAC
Write 0
PAC
Read 0
$B8
PAC
Write 1
PAC
Read 1
$C0
PAC
Write 2
PAC
Read 2
$C8
PAC
Write 3
PAC
Read 3
$D0
PAC
Write 4
PAC
Read 4
$D8
PAC
Write 5
PAC
Read 5
$E0
PAC
Write 6
PAC
Read 6
$E8
PAC
Write 7
PAC
Read 7
$F0
$F8
Reserved
Password
Forbidden
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8.2
Security Fuses
There are three fuses on the device that must be blown during the device personalization process. Each fuse locks certain
portions of the configuration zone as OTP (One-Time Programmable) memory. Fuses are designed for the module
manufacturer, card manufacturer and card issuer and should be blown in sequence, although all programming of the device
and blowing of the fuses may be performed at one final step.
9.
Communication Security Modes
Communications between the device and host operate in three basic modes. Standard mode is the default mode for the
device after power-up. Authentication mode is activated by a successful authentication sequence. Encryption mode is
activated by a successful encryption activation following a successful authentication.
Table 9-1.
Communication Security Modes(1)
Mode
Configuration Data
User Data
Passwords
Data Integrity Check
Standard
Clear
Clear
Clear
MDC(1)
Authentication
Clear
Clear
Encrypted
MAC(1)
Encryption
Clear
Encrypted
Encrypted
MAC(1)
Note:
1.
Configuration data include viewable areas of the configuration zone except the passwords:


MDC (Modification Detection Code)
MAC (Message Authentication Code)
10.
Security Options
10.1
Anti-Tearing
In the event of a power loss during a write cycle, the integrity of the device’s stored data is recoverable. This function is
optional – the host may choose to activate the anti-tearing function, depending on application requirements. When anti-tearing
is active, write commands take longer to execute, since more write cycles are required to complete them, and data is limited to
a maximum of eight bytes for each write request.
Data is written first into a buffer zone in EEPROM instead of the intended destination address, but with the same access
conditions. The data is then written in the required location. If this second write cycle is interrupted due to a power loss, the
device will automatically recover the data from the system buffer zone at the next power-up. Non-volatile buffering of the data
is done automatically by the device.
During power-up in applications using anti-tearing, the host is required to perform ACK polling in the event that the device
needs to carry out the data recovery process.
10.2
Write Lock
If a user zone is configured in the write lock mode, the lowest address byte of an 8-byte page constitutes a write access byte
for the bytes of that page.
Example:
For example, the write lock byte at $080 controls the bytes from $081 to $087.
Figure 10-1. Write Lock Example
Address
$080
$0
$1
$2
$3
$4
$5
$6
$7
11011001
xxxx xxxx
xxxx xxxx
xxxx xxxx
xxxx xxxx
xxxx xxxx
xxxx xxxx
xxxx xxxx
locked
locked
locked
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The Write-Lock byte itself may be locked by writing its least significant (rightmost) bit to “0”. Moreover, when write lock mode is
activated, the write lock byte can only be programmed – that is, bits written to “0” cannot return to “1”.
In the write lock configuration, write operations are limited to writing only one byte at a time. Attempts to write more than one
byte will result in writing of just the first byte into the device.
10.3
Password Verification
Passwords may be used to protect read and/or write access of any user zone. When a valid password is presented, it is
memorized and active until power is turned off, unless a new password is presented or RST becomes active. There are eight
password sets that may be used to protect any user zone. Only one password is active at a time.
Presenting the correct write password also grants read access privileges.
10.4
Authentication Protocol
The access to a user zone may be protected by an authentication protocol. Any one of four keys may be selected to use with a
user zone.
Authentication success is memorized and active as long as the chip is powered, unless a new authentication is initialized or
RST becomes active. If the new authentication request is not validated, the card loses its previous authentication which must
be presented again to gain access. Only the latest request is memorized.
Figure 10-2. Password and Authentication Operations
Host (Reader)
Device (Card)
AUTHENTICATION
COMPUTE Challenge A
Card Number
Challenge A
VERIFY A
COMPUTE Challenge B
VERIFY B
Challenge B
READ ACCESS
Read Password (RPW)
VERIFY RPW
DATA
Checksum (CS)
VERIFY WPW
VERIFY CS
VERIFY CS
WRITE ACCESS
Write Password (WPW)
DATA
CS
Write DATA
Note:
Authentication and password verification may be attempted at any time and in any order. Exceeding
corresponding authentication or password attempts trial limit renders subsequent authentication or password
verification attempts futile.
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10.5
Cryptographic Message Authentication Codes
AT88SC0104CA implements a data validity check function in the standard, authentication or encryption modes of operation.
In the standard mode, data validity check is done through a Modification Detection Code (MDC), in which the host may read
an MDC from the device in order to verify that the data sent was received correctly.
In authentication and encryption modes, the data validity check becomes more powerful since it provides a bidirectional data
integrity check and data origin authentication capability in the form of a Message Authentication Codes (MAC). Only the
host/device that carried out a valid authentication is capable of computing a valid MAC. While operating in the authentication
or encryption modes, the use of MAC is required. For an ingoing command, if the device calculates a MAC different from the
MAC transmitted by the host, not only is the command abandoned but the security privilege is revoked. A new authentication
and/or encryption activation will be required to reactivate the MAC.
10.6
Encryption
The data exchanged between the device and the host during read, write and verify password commands may be encrypted to
ensure data confidentiality.
The issuer may choose to require encryption for a user zone by settings made in the configuration memory. Any one of four
keys may be selected for use with a user zone. In this case, activation of the encryption mode is required in order to read/write
data in the zone and only encrypted data will be transmitted. Even if not required, the host may still elect to activate encryption
provided the proper keys are known.
10.7
Supervisor Mode
Enabling this feature allows the holder of one specific password to gain full access to all eight password sets, including the
ability to change passwords.
10.8
Modify Forbidden
No write access is allowed in a user zone protected with this feature at any time. The user zone must be written during device
personalization prior to blowing the security fuses.
10.9
Program Only
For a user zones protected by this feature, data can only be programmed (bits change from a “1” to a “0”), but not erased (bits
change from a “0” to a “1”).
11.
Protocol Selection
The AT88SC0104CA supports two different communication protocols.
•
•
Smartcard Applications:
Smartcard applications use ISO 7816-B protocol in asynchronous T = 0 mode for compatibility and interoperability
with industry standard smartcard readers.
Embedded Applications:
A two-wire serial interface provides fast and efficient connectivity with other logic devices or microcontrollers.
The power-up sequence determines establishes the communication protocol for use within that power cycle. Protocol selection
is allowed only during power-up.
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11.1
Synchronous Two-wire Serial Interface
The synchronous mode is the default mode after power up. This is due to the presence of an internal pull-up on RST. For
embedded applications using CryptoMemory in standard plastic packages, this is the only available communication protocol.
•
•
•
Power-up VCC, RST goes high also
After stable VCC, SCL(CLK) and SDA(I/O) may be driven
Once synchronous mode has been selected, it is not possible to switch to asynchronous mode without first powering
off the device
Figure 11-1. Synchronous Two-wire Protocol
Vcc
I/O-SDA
RST
CLK-SCL
Note:
11.2
1
2
3
4
5
Five clock pulses must be sent before the first command is issued
Asynchronous T = 0 Protocol
This power-up sequence complies to ISO 7816-3 for a cold reset in smart card applications.
•
•
•
•
VCC goes high; RST, I/O (SDA) and CLK (SCL) are low
Set I/O (SDA) in receive mode
Provide a clock signal to CLK (SCL)
RST goes high after 400 clock cycles
The device will respond with a 64-bit ATR code, including historical bytes to indicate the memory density within the
CryptoMemory family.
Once asynchronous mode has been selected, it is not possible to switch to synchronous mode without first powering off the
device.
Figure 11-2. Asynchronous T = 0 Protocol (Gemplus Patent)
Vcc
I/O-SDA
ATR
RST
CLK-SCL
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12.
Initial Device Programming
Enabling the security features of CryptoMemory requires prior personalization. Personalization entails setting up of desired
access rights by zones, passwords and key values, programming these values into the configuration memory with verification
using simple write and read commands, and then blowing fuses to lock this information in place.
Gaining access to the configuration memory requires successful presentation of a secure (or transport) code. The initial
signature of the secure (transport) code for the AT88SC0104CA device is $DD 42 97. This is the same as the write seven
password. The user may elect to change the signature of the secure code anytime after successful presentation.
After writing and verifying data in the configuration memory, the security fuses must be blown to lock this information in the
device. For additional information on personalizing CryptoMemory, please see the application notes Programming
CryptoMemory for Embedded Applications and Initializing CryptoMemory for Smart Card Applications from the product page at
www.atmel.com/products/securemem.
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13.
Ordering Information
Atmel Ordering Code
Package
Voltage Range
Temperature Range
AT88SC0104CA-MJ
AT88SC0104CA-MP
AT88SC0104CA-MJTG
AT88SC0104CA-MPTG
M2 – J Module - ISO
M2 – P Module - ISO
M2 – J Module -TWI
M2 – P Module -TWI
2.7V–3.6V
Commercial (0°C to 70°C)
AT88SC0104CA-PU
AT88SC0104CA-SH
AT88SC0104CA-TH
AT88SC0104CA-Y6H-T
8P3
8S1
8X
8MA2
2.7V–3.6V
Green Compliant
(exceeds RoHS)/Industrial
(−40°C to 85°C)
7 mil wafer
2.7V–3.6V
Industrial (−40°C to 85°C)
AT88SC0104CA-WI
Package Type(1) ( 2)
M2 – J Module : ISO or TWI
M2 ISO 7816 Smart Card Module
M2 – P Module: ISO or TWI
M2 ISO 7816 Smart Card Module with Atmel® logo
8P3
8-lead, 0.300” wide, Plastic Dual Inline (PDIP)
8S1
8-lead, 0.150” wide, Plastic Gull Wing Small Outline (JEDEC SOIC)
8X
8-lead, 4.4mm body, Plastic Thin Shrink Small Outline (TSSOP)
8MA2
8-lead, 2.0 x 3.0mm body, 0.50mm pitch, Ultra Thin Mini-map, Dual No Lead (DFN), (MLP 2x3)
Note:
1.
Formal drawings may be obtained from an Atmel sales office
2.
Both the J and P module packages are used for either ISO (T=0 / two-wire mode) or TWI (two-wire mode only)
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
16
14.
Package Information
Ordering Code: MJ or MJTG
Module size: M2
Dimension*: 12.6 x 11.4 [mm]
Glob top: round – Æ 8.5 [mm]
Thickness: 0.58 [mm]
Pitch: 14.25 mm
Note:
Ordering Code: MP or MPTG
Module size: M2
Dimension*: 12.6 x 11.4 [mm]
Glob top: square – 8.8 x 8.8 [mm]
Thickness: 0.58 [mm]
Pitch: 14.25 mm
*The module dimensions listed refer to the dimensions of the exposed metal contact area. The actual dimensions
of the module after excise or punching from the carrier tape are generally 0.4mm greater in both directions (i.e., a
punched M2 module will yield 13.0 x 11.8mm).
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
17
14.1
Ordering Code: SH
8S1 – JEDEC SOIC
C
1
E
E1
L
N
Ø
TOP VIEW
END VIEW
e
b
COMMON DIMENSIONS
(Unit of Measure = mm)
A
A1
D
SIDE VIEW
Notes: This drawing is for general information only.
Refer to JEDEC Drawing MS-012, Variation AA
for proper dimensions, tolerances, datums, etc.
SYMBOL MIN
A
1.35
NOM
MAX
–
1.75
A1
0.10
–
0.25
b
0.31
–
0.51
C
0.17
–
0.25
D
4.80
–
5.05
E1
3.81
–
3.99
E
5.79
–
6.20
e
L
NOTE
1.27 BSC
0.40
–
1.27
0°
–
8°
6/22/11
TITLE
Package Drawing Contact: 8S1, 8-lead (0.150” Wide Body), Plastic Gull
[email protected] Wing Small Outline (JEDEC SOIC)
GPC
SWB
DRAWING NO.
REV.
8S1
G
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
18
14.2
Ordering Code: PU
8P3 – PDIP
E
1
E1
N
Top View
c
eA
End View
COMMON DIMENSIONS
(Unit of Measure = inches)
D
e
D1
A2 A
MIN
NOM
MAX
A2
0.115
0.130
0.195
b
0.014
0.018
0.022
5
b2
0.045
0.060
0.070
6
b3
0.030
0.039
0.045
6
c
0.008
0.010
0.014
D
0.355
0.365
0.400
D1
0.005
E
0.300
0.310
0.325
4
E1
0.240
0.250
0.280
3
SYMBOL
A
b2
b3
b
4 PLCS
Side View
L
0.210
e
Notes:
1.
2.
3.
4.
5.
6.
2
3
3
0.100 BSC
eA
L
NOTE
0.300 BSC
0.115
0.130
4
0.150
2
This drawing is for general information only; refer to JEDEC Drawing MS-001, Variation BA for additional information.
Dimensions A and L are measured with the package seated in JEDEC seating plane Gauge GS-3.
D, D1 and E1 dimensions do not include mold Flash or protrusions. Mold Flash or protrusions shall not exceed 0.010 inch.
E and eA measured with the leads constrained to be perpendicular to datum.
Pointed or rounded lead tips are preferred to ease insertion.
b2 and b3 maximum dimensions do not include Dambar protrusions. Dambar protrusions shall not exceed 0.010 (0.25 mm).
06/21/11
Package Drawing Contact:
[email protected]
TITLE
GPC
DRAWING NO.
8P3, 8-lead, 0.300” Wide Body, Plastic Dual
In-line Package (PDIP)
PTC
8P3
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
REV.
D
19
14.3
Ordering Code: TH
8X – TSSOP
C
1
Pin 1 indicator
this corner
E1
E
L1
N
L
Top View
End View
A
b
A1
e
COMMON DIMENSIONS
(Unit of Measure = mm)
A2
SYMBOL
D
Side View
Notes:
1. This drawing is for general information only.
Refer to JEDEC Drawing MO-153, Variation AA, for proper
dimensions, tolerances, datums, etc.
2. Dimension D does not include mold Flash, protrusions or gate
burrs. Mold Flash, protrusions and gate burrs shall not exceed
0.15mm (0.006in) per side.
3. Dimension E1 does not include inter-lead Flash or protrusions.
Inter-lead Flash and protrusions shall not exceed 0.25mm
(0.010in) per side.
4. Dimension b does not include Dambar protrusion.
Allowable Dambar protrusion shall be 0.08mm total in excess
of the b dimension at maximum material condition. Dambar
cannot be located on the lower radius of the foot. Minimum
space between protrusion and adjacent lead is 0.07mm.
5. Dimension D and E1 to be determined at Datum Plane H.
MIN
NOM
MAX
A
-
-
1.20
A1
0.05
-
0.15
A2
0.80
1.00
1.05
D
2.90
3.00
3.10
E
NOTE
2, 5
6.40 BSC
E1
4.30
4.40
4.50
3, 5
b
0.19
–
0.30
4
e
L
0.65 BSC
0.45
0.60
0.75
L1
1.00 REF
C
0.09
-
0.20
6/22/11
TITLE
GPC
Package Drawing Contact: 8X, 8-lead 4.4mm Body, Plastic Thin
[email protected] Shrink Small Outline Package (TSSOP)
TNR
DRAWING NO.
8X
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
REV.
D
20
14.4
Ordering Code: Y6H-T
8MA2 – Ultra Thin Mini-MAP
E
1
8
Pin 1 ID
2
7
3
6
4
5
D
C
A2
A
A1
E2
COMMON DIMENSIONS
(Unit of Measure = mm)
b (8x)
SYMBOL
8
1
7
2
MIN
NOM
D
E
Pin#1 ID
6
D2
3
5
4
e (6x)
L (8x)
K
MAX
3.00 BSC
D2
1.40
1.50
1.60
E2
1.20
1.30
1.40
A
0.50
0.55
0.60
A1
0.0
0.02
0.05
A2
–
–
0.55
C
L
NOTE
2.00 BSC
0.152 REF
0.30
0.35
e
0.40
0.50 BSC
b
0.18
0.25
0.30
K
0.20
–
–
3
7/15/11
Package Drawing Contact:
[email protected]
TITLE
8MA2, 8-pad, 2 x 3 x 0.6 mm Body, Thermally
Enhanced Plastic Ultra Thin Dual Flat No
Lead Package (UDFN)
GPC
YNZ
DRAWING NO.
8MA2
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
REV.
B
21
15.
Revision History
Doc. Rev.
Date
Comments
5200FS
12/2011
Update template
Update package drawings and
- Replace 8A2 with 8X
- Replace 8T6 with 8MA2
Change AT88SC0104CA-SU to AT88SC0104CA-SH
5200ES
08/2009
Minor edits and TWI module updates
5200DS
07/2009
Minor updates to package drawing information and ordering information
5200CS
05/2009
Added Mini-MAP column to Table 1-1 and Mini-MAP pin-out drawing
5200BS
02/2009
Connection diagram inserted; DC characteristics table updated
5200AS
07/2008
Initial document release
Atmel AT88SC0104CA [SUMMARY DATASHEET]
5200FS−CRYPTO−12/11
22
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© 2011 Atmel Corporation. All rights reserved. / Rev.: 5200FS−CRYPTO−12/11
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