DS2460S/T&R [DALLAS]
SHA-1 Coprocessor with EEPROM; SHA - 1协处理器,带有EEPROM
| 型号: | DS2460S/T&R |
| 厂家: | 
DALLAS SEMICONDUCTOR |
| 描述: | SHA-1 Coprocessor with EEPROM |
| 文件: | 总8页 (文件大小:133K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Abridged Data Sheet
DS2460
SHA-1 Coprocessor with EEPROM
www.maxim-ic.com
GENERAL DESCRIPTION
FEATURES
The DS2460 SHA-1 Coprocessor with EEPROM is a
hardware implementation of the ISO/IEC 10118-3
Secure Hash Algorithm (SHA-1), eliminating the need
to develop software to perform the complex SHA
computation required for authenticating SHA devices
and for performing the validation of digitally signed
service data. The DS2460 communicates with a
microcontroller through the popular I²C interface.
Applications include hosts of access control and
electronic payment systems for token authentication
and service data validation as well as generation of
one-time-use encryption keys for short message
encryption and decryption for messages not exceed-
ing the length of a SHA-1 result, which is 20 bytes.
Dedicated Hardware-Accelerated SHA Engine
for Generating SHA-1 MACs
112 Bytes User EEPROM for Storing End
Equipment Property Data
I²C Host Interface, Supports 100kHz and 400kHz
Communication Speeds
Three Address Inputs for I²C Address
Assignment
Single-Byte to 8-Byte EEPROM Write
Sequences
64-Bit Unique Registration Number
EEPROM Endurance: 200k Cycles per 8-Byte
Block at 25°C
10ms max EEPROM Write Cycle
Wide Operating Range: 2.7V to 5.5V,
-40°C to +85°C
APPLICATIONS
License Management
Secure Feature Control
System Authentication
Clone Prevention
Door Locks
±4kV IEC 1000-4-2 ESD Protection Level on All
Pins
8-Pin SO (150 mils) Package
ORDERING INFORMATION
PART
DS2460S
Utility Meters
TEMP RANGE
-40°C to +85°C
-40°C to +85°C
-40°C to +85°C
-40°C to +85°C
PIN-PACKAGE
8 SO (150 mils)
8 SO (150 mils)
8 SO (150 mils)
8 SO (150 mils)
DS2460S/T&R
DS2460S+
TYPICAL OPERATING CIRCUIT
DS2460S+T&R
VCC
+ Indicates lead-free compliance.
RP
RP
VCC
Request full data sheet at:
www.maxim-ic.com/fullds/DS2460
SDA
SCL
VCC
µC
SDA
SCL
AD0
AD1
AD2
PIN CONFIGURATION
GND
AD0
AD1
AD2
GND
VCC
1
2
3
4
8
7
6
5
GND
SCL
SDA
N.C.
Note: Some revisions of this device may incorporate deviations from published specifications known as errata. Multiple revisions of any device
may be simultaneously available through various sales channels. For information about device errata, click here: www.maxim-ic.com/errata.
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REV: 080807
Abridged Data Sheet
DS2460
ABSOLUTE MAXIMUM RATINGS
Voltage Range on Any Pin Relative to Ground
Maximum Current Into Any Pin
Operating Temperature Range
Junction Temperature
-0.5V, +6V
±20mA
-40°C to +85°C
+150°C
Storage Temperature Range
Soldering Temperature
-55°C to +125°C
See IPC/JEDEC J-STD-020
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only,
and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is
not implied. Exposure to the absolute maximum rating conditions for extended periods may affect device.
ELECTRICAL CHARACTERISTICS
(-40°C to +85°C, see Note 1)
PARAMETER
Supply Voltage
SYMBOL
CONDITIONS
Bus idle
MIN
TYP
MAX
UNITS
VCC
2.7
5.5
3
V
Standby Current
ICCS
µA
Bus idle, +25°C
1
Operating Current
ICCA
IPROG
ISHA
Bus active at 400kHz
250
500
500
1000
µA
µA
Programming Current
SHA-1 Computation Current
SHA-1 Engine
See full version of data sheet
See full version of data sheet
mA
SHA-1 Computation Time
tSHA
ms
ms
EEPROM
Programming Time
Endurance
tPROG
NCYCLE
tRET
10
At +25°C (Notes 2, 3)
200k
40
Data Retention
At +85°C (Notes 4, 5, 6)
years
I²C-Pins (Note 7) See Figure 6
0.3 ×
VCC
VCC +
LOW Level Input Voltage
HIGH Level Input Voltage
VIL
VIH
(Note 8)
-0.5
V
V
V
V
0.7 ×
VCC
0.05 ×
VCC
(Notes 8, 9)
(Note 9)
0.5V
Hysteresis of Schmitt Trigger
Inputs
LOW Level Output Voltage at
4mA Sink Current
Vhys
VOL
0.4
250
50
Output Fall Time from VIhmin to
20 +
0.1Cb
VILmax with a Bus Capacitance
tof
tSP
Ii
(Note 9)
ns
ns
µA
from 10pF to 400pF
Pulse Width of Spikes that are
Suppressed by the Input Filter
Input Current Each I/O Pin with
an Input Voltage Between
0.1VCCmax and 0.9VCCmax
SDA and SCL pins only
(Note 9)
(Notes 8, 10)
(Notes 8, 9)
-10
10
Input Capacitance
Ci
10
pF
SCL Clock Frequency
fSCL
0
400
kHz
Hold Time (Repeated) START
Condition. After this Period, the
First Clock Pulse is Generated.
LOW Period of the SCL Clock
HIGH Period of the SCL Clock
tHD:STA
0.6
µs
tLOW
tHIGH
1.3
0.6
µs
µs
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Abridged Data Sheet
DS2460
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
MAX
UNITS
Setup Time for a Repeated
START Condition
tSU:STA
0.6
µs
Data Hold Time
Data Setup Time
tHD:DAT
tSU:DAT
tSU:STO
(Notes 11, 12)
(Note 13)
0.9
µs
ns
µs
100
0.6
Setup Time for STOP Condition
Bus Free Time Between a
STOP and START Condition
Capacitive Load for Each Bus
Line
tBUF
CB
1.3
µs
pF
(Note 14)
400
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
Specification at -40°C is guaranteed by design and characterization only and not production tested.
Write-cycle endurance is degraded as TA increases.
Not 100% production-tested; guaranteed by reliability monitor sampling.
Data retention is degraded as TA increases.
Guaranteed by 100% production test at elevated temperature for a shorter amount of time;
equivalence of this production test to data sheet limit at operating temperature range is established by
reliability testing.
Note 6:
EEPROM writes can become nonfunctional after the data-retention time is exceeded. Long-term
storage at elevated temperatures is not recommended; the device can lose its write capability after 10
years at +125°C or 40 years at +85°C.
Note 7:
Note 8:
Note 9:
Note 10:
Note 11:
All values are referred to VIHmin and VILmax levels.
Applies to SDA, SCL, AD2, AD1, AD0.
Guaranteed by simulation only, not production tested.
I/O pins of the DS2460 do not obstruct the SDA and SCL lines if VCC is switched off.
The DS2460 provides a hold time of at least 300ns for the SDA signal (referred to the VIHmin of the SCL
signal) to bridge the undefined region of the falling edge of SCL.
Note 12:
Note 13:
The maximum tHD:DAT has only to be met if the device does not stretch the LOW period (tLOW) of the
SCL signal.
A Fast-mode I²C-bus device can be used in a standard-mode I²C-bus system, but the requirement
tSU:DAT ≥250ns must then be met. This is automatically the case if the device does not stretch the LOW
period of the SCL signal. If such a device does stretch the LOW period of the SCL signal, it must
output the next data bit to the SDA line tr max + tSU:DAT = 1000 + 250 = 1250ns (according to the
standard-mode I²C-bus specification) before the SCL line is released.
CB = total capacitance of one bus line in pF. If mixed with HS-mode devices, faster fall-times according
to I²C-Bus Specification v2.1 are allowed.
Note 14:
PIN DESCRIPTION
PIN
NAME
AD0
AD1
AD2
GND
NC
FUNCTION
1
2
3
4
I²C Address Inputs; must be tied to VCC or GND. These inputs determine the I²C slave
address of the device, see Figure 5.
Ground Reference
Not Connected
5
6
7
8
SDA
SCL
VCC
I²C Serial Data Input/Output; must be tied to VCC through a pullup resistor.
I²C Serial Clock Input; must be tied to VCC through a pullup resistor.
Power Supply Input
OVERVIEW
The block diagram in Figure 1 shows the relationships between the major control and memory sections of the
DS2460. The DS2460 communicates with a host processor through its I²C bus interface in standard-mode or in
fast-mode. The logic state of three address pins determines the I²C slave address of the DS2460, allowing up to 8
devices to operate on the same bus segment without requiring a hub. For more information (including Figure 2)
refer to the full version of the data sheet.
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Abridged Data Sheet
DS2460
Figure 1. Block Diagram
64-bit Unique
Number
MAC Output
Buffer
64-Byte Input
Buffer
SCL
2-wire
Function
Control
SDA
ADx
Command Buffer
and SHA-1
Engine Control
SHA-1
Engine
S-Secret
E-Secret1
E-Secret2
E-Secret3
8-Byte EEPROM
Write Buffer
112-Byte User
EEPROM
DETAILED REGISTER DESCRIPTION
For this section (including Figure 3) please refer to the full version of the data sheet.
DEVICE OPERATION
The typical use of the DS2460 in an application involves writing, reading, running the SHA-1 engine, transferring
secrets and comparing MACs. All these activities are controlled through the I²C serial interface.
I²C Serial Communication Interface
General Characteristics
The I²C bus uses a data line (SDA) plus a clock signal (SCL) for communication. Both SDA and SCL are bidirec-
tional lines, connected to a positive supply voltage through a pullup resistor. When there is no communication, both
lines are HIGH. The output stages of devices connected to the bus must have an open-drain or open-collector to
perform the wired-AND function. Data on the I²C bus can be transferred at rates of up to 100kbps in the Standard-
mode, up to 400kbps in the Fast-mode. The DS2460 works in both modes.
A device that sends data on the bus is defined as a transmitter, and a device receiving data as a receiver. The
device that controls the communication is called a “master.” The devices that are controlled by the master are
“slaves.” To be individually accessed, each device must have a slave address that does not conflict with other
devices on the bus.
Data transfers may be initiated only when the bus is not busy. The master generates the serial clock (SCL),
controls the bus access, generates the START and STOP conditions, and determines the number of data bytes
transferred between START and STOP (Figure 4). Data is transferred in bytes with the most significant bit being
transmitted first. After each byte follows an acknowledge bit to allow synchronization between master and slave.
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Abridged Data Sheet
DS2460
Slave Address
The slave address to which the DS2460 responds is shown in Figure 5. The logic states at the address pins AD0,
AD1 and AD2 determine the value of the address bits A0, A2, and A4. The address pins allow the device to
respond to one of eight possible slave addresses. The slave address is part of the slave-address/control byte. The
last bit of the slave-address/control byte (R/W) defines the data direction. When set to a 0, subsequent data will
flow from master to slave (write access mode); when set to a 1, data will flow from slave to master (read access
mode).
Figure 4. I²C Protocol Overview
W
ACK
bit
ACK
bit
MS-bit
R/
SDA
Slave Address
Acknowledgment
from Receiver
Repeated if more bytes
are transferred
SCL
1
2
6
7
8
9
1
2
8
9
ACK
ACK
STOP Condition
Repeated START
Condition
START
Condition
Idle
Figure 5. DS2460 Slave Address
7-Bit Slave Address
A6
1
A5
0
A4
A3
0
A2
A1
0
A0
AD0 R/W
AD2
AD1
Most Signi-
ficant Bit
AD2, AD1, AD0
Pin States
Determines
Read or Write
I²C Definitions
The following terminology is commonly used to describe I²C data transfers. The timing references are defined in
Figure 6.
Bus Idle or Not Busy
Both, SDA and SCL, are inactive and in their logic HIGH states.
START Condition
To initiate communication with a slave, the master has to generate a START condition. A START condition is
defined as a change in state of SDA from HIGH to LOW while SCL remains HIGH. A valid slave address must be
sent by the master and acknowledged by the slave before subsequent START conditions are recognized.
STOP Condition
To end communication with a slave, the master has to generate a STOP condition. A STOP condition is defined as
a change in state of SDA from LOW to HIGH while SCL remains HIGH. A valid slave address must be sent by the
master and acknowledged by the slave before subsequent STOP conditions are recognized.
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Abridged Data Sheet
DS2460
Repeated START Condition
Repeated starts are commonly used for read accesses to select a specific data source or address to read from.
The master can use a repeated START condition at the end of a data transfer to immediately initiate a new data
transfer following the current one. A repeated START condition is generated the same way as a normal START
condition, but without leaving the bus idle after a STOP condition.
Data Valid
With the exception of the START and STOP condition, transitions of SDA may occur only during the LOW state of
SCL. The data on SDA must remain valid and unchanged during the entire high pulse of SCL plus the required
setup and hold time (tHD:DAT after the falling edge of SCL and tSU:DAT before the rising edge of SCL, see Figure 6).
There is one clock pulse per bit of data. Data is shifted into the receiving device during the rising edge of the SCL
pulse.
When finished with writing, the master must release the SDA line for a sufficient amount of setup time (minimum
tSU:DAT + tR in Figure 6) before the next rising edge of SCL to start reading. The slave shifts out each data bit on
SDA at the falling edge of the previous SCL pulse and the data bit is valid at the rising edge of the current SCL
pulse. The master generates all SCL clock pulses, including those needed to read from a slave.
Acknowledge
Usually, a receiving device, when addressed, is obliged to generate an acknowledge after the receipt of each byte.
The master must generate a clock pulse that is associated with this acknowledge bit. A device that acknowledges
must pull SDA LOW during the acknowledge clock pulse in such a way that SDA is stable LOW during the HIGH
period of the acknowledge-related clock pulse plus the required setup and hold time (tHD:DAT after the falling edge of
SCL and tSU:DAT before the rising edge of SCL).
Not Acknowledged by Slave
A slave device may be unable to receive or transmit data, e.g., because it is busy performing a real-time function,
such as MAC computation or EEPROM write cycle. In this case the slave device will not acknowledge its slave
address and leave the SDA line HIGH.
A slave device that is ready to communicate will acknowledge at least its slave address. However, some time later
the slave may refuse to accept data, e.g., because of an invalid command or access mode, or to signal a non-
matching MAC. In this case the slave device will not acknowledge any of the bytes that it refuses and will leave
SDA HIGH. In either case, after a slave has failed to acknowledge, the master first needs to generate a repeated
START condition or a STOP condition followed by a START condition to begin a new data transfer.
Not Acknowledged by Master
At some time when receiving data, the master must signal an end of data to the slave device. To achieve this, the
master does not acknowledge the last byte that it has received from the slave. In response, the slave releases
SDA, allowing the master to generate the STOP condition.
Figure 6. I²C Timing Diagram
SDA
tBUF
tHD:STA
tSP
tF
tLOW
SCL
tSU:STA
Spike
Suppression
tHD:STA
tR
tHIGH
tSU:STO
tHD:DAT
tSU:DAT
NOTE: Timing is referenced
to VILMAX and VIHMIN
Repeated
START
STOP START
.
6 of 8
Abridged Data Sheet
DS2460
Read and Write
This section discusses the read and write behavior of the various registers and the EEPROM. Please refer to the
full data sheet for details.
SHA-1 Engine Control
This section describes the user’s view of the SHA-1 engine and how to operate it. For details refer to the full data
sheet (includes Figures 7 to 9 and Tables 1 and 2).
SHA-1 COMPUTATION ALGORITHM
This description of the SHA computation is adapted from the Secure Hash Standard SHA-1 document that can be
downloaded from the NIST website (www.itl.nist.gov/fipspubs/fip180-1.htm). Further details are found in the full
version of the data sheet.
Application Information
SDA and SCL Pullup Resistors
SDA is an open-drain output on the DS2460 that requires a pullup resistor (Figure 10) to realize high logic levels.
Because the DS2460 uses SCL only as input (no clock stretching) the master can drive SCL either through an
open-drain/collector output with a pullup resistor or a push-pull output.
Figure 10. Application Schematic
VCC
RP
RP
VCC
To additional
2-wire devices
SDA
SCL
VCC
µC
SDA
SCL
AD0
AD1
AD2
Example
slave
address =
100 0101
GND
GND
Pullup Resistor RP Sizing
According to the I²C specification, a slave device must be able to sink at least 3mA at a VOL of 0.4V. This DC
condition determines the minimum value of the pullup resistor: RPMIN = (VCC - 0.4V)/3mA. With an operating voltage
of 5.5V, the minimum value for the pullup resistor is 1.7kΩ. The "Minimum RP" line in Figure 11 shows how the
minimum pullup resistor changes with the operating (pull-up) voltage.
For I²C systems, the rise time and fall time are measured from 30% to 70% of the pullup voltage. The maximum
bus capacitance CB is 400pF. The maximum rise time must not exceed 300ns. Assuming maximum rise time, the
maximum resistor value at any given capacitance CB is calculated as: RPMAX = 300ns/(CB*ln(7/3)). For a bus
capacitance of 400pF the maximum pullup resistor would be 885Ω.
7 of 8
Abridged Data Sheet
DS2460
Since a 885Ω pullup resistor, as would be required to meet the rise time specification at 400pF bus capacitance, is
lower than RPMIN at 5.5V, a different approach is necessary. The "Max. Load…" line in Figure 11 is generated by
first calculating the minimum pullup resistor at any given operating voltage ("Minimum RP" line) and then calculating
the respective bus capacitance that yields a rise time of 300ns.
Only for pullup voltages of 3V and lower can the maximum permissible bus capacitance of 400pF be maintained. A
reduced bus capacitance of 300pF is acceptable for pullup voltages of 4V and lower. For fast speed operation at
any pullup voltage, the bus capacitance must not exceed 200pF. The corresponding pullup resistor value at the
voltage is indicated by the "Minimum RP " line.
Figure 11. I²C Fast Speed Pullup Resistor Selection Chart
"Minimum Rp"
Max. Load at Min. Rp fast mode
2000
1600
1200
800
400
0
500
400
300
200
100
0
1
2
3
4
5
Pull-up Voltage
PACKAGE INFORMATION
(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information, go to
www.maxim-ic.com/DallasPackInfo.)
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