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GENERAL DESCRIPTION
The DS2703 provides a robust cryptographic solution
to ensure the authenticity of Li-Ion battery packs for
cell phone, PDA, and portable computing devices.
The DS2703 employs the Secure Hash Algorithm
(SHA-1) specified in the Federal Information
publication 180-1 and 180-2, and ISO/IEC 10118-3.
SHA-1 is designed for authenticationjust what is
required for identifying battery packs manufactured
by authorized sources.
The device’s SHA-1 engine processes a host
transmitted challenge using its stored 64-bit secret
key and unique 64-bit ROM ID to produce a 160-bit
response word for transmission back to the host. The
secret key is securely stored on-chip and never
transmitted between the battery and the host. A
DS2703-based system produces a high degree of
authentication security between a host system and its
removable battery or other peripheral devices.
The Thermistor Multiplexer feature allows a three
contact battery pack configuration to support data
and thermistor functions. When activated through
1-Wire command, the THM pin presents the
thermistor impedance on the data contact and
disconnects internal loading from the node.
TYPICAL OPERATING CIRCUIT
FEATURES
Secure Challenge and Response Authentication
Using the SHA-1 Algorithm
Directly Powered by the Dallas 1-Wire® Interface
with 16kbps Standard and 143kbps Overdrive
Communication Modes
Unique 64-Bit Serial Number
Thermistor Multiplexer
Operates with VPULLUP as Low as 2.7V
Pb-Free 8-Pin μMAX® or 2mm x 3mm TDFN
Package
PIN CONFIGURATION
APPLICATIONS
2.5G/3G Wireless Handsets
PDAs
Handheld or Notebook Computers and Terminals
Digital Still and Video Cameras
ORDERING INFORMATION
PART TEMP RANGE PIN-PACKAGE
DS2703G+ -20°C to +70°C 2mm x 3mm TDFN
DS2703G+T&R -20°C to +70°C DS2703G+ on
Tape-and-Reel
DS2703U+ -20°C to +70°C μMAX-8
DS2703U+T&R -20°C to +70°C DS2703U+ on
Tape-and-Reel
+ Denotes lead-free package.
DS2703
SHA-1 Battery Pack
A
uthentication IC
www.maxim-ic.com
1-Wire is a registered trademark of Dallas Semiconductor.
µMAX is a registered trademark of Maxim Integrated Products.
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ABSOLUTE MAXIMUM RATINGS
Voltage Range on DQ, THM Pins Relative to Ground -0.3V to +18V
Voltage Range on VB Pin Relative to Ground -0.3V to +6V
Operating Temperature Range -40°C to +85°C
Storage Temperature Range -55°C to +125°C
Soldering Temperature See IPC/JEDEC J-STD-020A Specification
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.
RECOMMENDED DC OPERATING CONDITIONS
(TA = -20°C to +70°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
Communication Mode 0 5.5
DQ Pullup Voltage VPULLUP Computation Mode 2.7 5.5 V
DQ, THM Relative Voltage VDQ-THM (Note 1) -0.3 15 V
DQ to THM Resistor RDQ-THM (Note 2) 5 500
KΩ
DC ELECTRICAL CHARACTERISTICS
(VPULLUP = 2.7V to 5.5V, TA = -20°C to +70°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
IDQ0 Standby Mode, VDQ > VIH 1 2.5
μA
IDQ1 Communication Mode
(Note 14) 75
μA
IDQ2 Computation Mode,
SHA-1 Computation Active 0.25 mA
IDQ3 Thermistor Mux Active,
(Note 3) 1
μA
IPP 14.5 < VDQ < 15.0V
0 < t < 50 oC 10 mA
DQ Load Current
IPP-IDLE (Note 4) 60
μA
DQ Programming Voltage VPP Program Pulse, (Note 5, 6) 14.5 15.0 V
Input Logic High: DQ VIH (Note 6) 0.8 VPULLUP V
Input Logic Low: DQ VIL (Note 6) 0.5 V
Output Logic Low: DQ VOL-DQ I
OL = 4mA, (Note 6, 7) 0.4 V
Output Logic Low: THM VOL-THM I
OL = 4mA, (Note 6, 7, 8) 0.4 V
Hold-Up Current: VB pin IHU THM pin Active, VB = 2.70V 3.2 μA
DQ Capacitance CDQ (Note 9) 50 pF
EEPROM RELIABILITY SPECIFICATION
(VPULLUP = 2.7V to 5.5V, TA = -20°C to +70°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
EEPROM Write Endurance NEEC 0 < t < 50 oC (Note 10) 1000 Cycles
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AC ELECTRICAL CHARACTERISTICS
(VPULLUP = 2.7V to 5.5V, TA = -20°C to +70°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
THM Low Delay tTD (Note 11) 15 μs
Computation Delay Time tD (Note 12) 100 s
Computation Time tSHA (Note 12) 15 ms
Programming Pulse Width tPPW (Note 5) 17 ms
Programming Pulse Rise Time tPPR 0.5 5 s
Programming Pulse Fall Time tPPF 0.5 5 s
Start-up Delay Time tSTRT (Note 13) 100 ms
AC ELECTRICAL CHARACTERISTICS: 1-Wire INTERFACE
(VPULLUP = 2.7V to 5.5V, TA = -20°C to +70°C.)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
1-Wire INTERFACE REGULAR TIMING
Time Slot tSLOT 60 120 s
Recovery Time tREC 1 s
Write 0 Low Time tLOW0 60 120 s
Write 1 Low Time tLOW1 1 15 s
Read Data Valid Time tRDV 15 s
Reset Time High tRSTH 480 s
Reset Time Low tRSTL 480 960 s
Presence Detect High tPDH 15 60 s
Presence Detect Low tPDL 60 240 s
1-Wire INTERFACE OVERDRIVE TIMING
Time Slot tSLOT 6 16 s
Recovery Time tREC 1 s
Write 0 Low Time tLOW0 6 16 s
Write 1 Low Time tLOW1 1 2 s
Read Data Valid Time tRDV 2 s
Reset Time High tRSTH 48 s
Reset Time Low tRSTL 48 80 s
Presence Detect High tPDH 2 6 s
Presence Detect Low tPDL 8 24 s
Note 1: V
DQ – VTHM. The THM pin must not be driven to a higher voltage than the DQ pin.
Note 2: The application thermistor cannot exceed the RDQ-THM resistance range over operating temperature. If thermistor mode is not used in the application, it is
recommended that a 50K resistor be connected between DQ and THM pins instead.
Note 3: Maximum leakage of DQ pin while in thermistor mode.
Note 4: When performing a Lock Secret (0x6A), Set Overdrive (0x8B) or Clear Overdrive (0x8D) operation, there will be an increased operating current of IPGM-
IDLE during and after the program pulse until the next 1-Wire bus reset.
Note 5: See Figure 11 for definitionof tPPR, tPPW, and tPPF.
Note 6: All voltages referenced to VSS.
Note 7: V
DQ must be at least 3.0V when the 1-Wire bus is idle.
Note 8: Drive strength at time=0 after Activate Thermistor command is sent to the DS2703.
Note 9: Does not include capacitance referred from VB pin on initial power up.
Note 10: EEPROM data read retention is four years at +50°C
Note 11: Time from msb of Activate Thermistor command until THM pin is driven low internally.
Note 12: Time from msb of Compute Next Secret or Compute MAC command.
Note 13: Time after initial power up before the DS2703 will respond to communication. TSTRT specifications are valid only if the capacitor on VB (CVB) is 0.22µF.
Worst case 100ms delay based on maximum thermistor value of 500k.
Note 14: The average current measured in Overdrive mode with minimum bus timings while the master issues: 1-Wire Reset, Skip ROM, Write Challenge, Write
0's repeatedly unil the end of measurement.
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PIN DESCRIPTION
8-PIN
µMAX
2mm x 3mm
TDFN NAME FUNCTION
1 7 THM
Thermistor Mux. Connect a thermistor from THM to DQ. Optional. For
temperature measurements only. If a thermistor is not used in the application, It is
recommended THM be tied to DQ with a 50K resistor instead. THM should
never be left floating.
2 8 VSS Device Ground. Connect directly to the negative terminal of the battery cell.
3 1 DQ
Data Input/Output. 1-Wire data line. Open-drain output driver. Connect this pin to
the DATA terminal of the battery pack. This pin has a weak internal pulldown (1µA
Typical).
4 2 VB
Hold-up Supply Bypass Input. Internal power supply to the DS2703 while DQ is
logic low and during thermistor measurement periods. Connect a 0.22µF
capacitor from VB to VSS.
5 3 N.C. No Connection. Pin not connected internally, float or connect to VSS.
6 4 N.C. No Connection. Pin not connected internally, float or connect to VSS.
7 5 N.C. No Connection. Pin not connected internally, float or connect to VSS.
8 6 N.C. No Connection. Pin not connected internally, float or connect to VSS.
Figure 1. Block Diagram
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DETAILED DESCRIPTION
The DS2703 is comprised of a SHA-1 Authentication function and thermistor mux control that are accessed via a 1-
Wire interface. The high voltage (HV) detection circuit routes the externally supplied programming voltage to the
EEPROM array and enables the internal regulator to isolate portions of the chip from the programming voltage. The
1-Wire interface controls access by a host system to the 64-bit Net Address (ROM ID) and SHA-1 Authentication.
The DS2703 operates in one of four operating modes: communication, computation, programming and thermistor
access. Most operations are performed in communication mode, with the host system addressing the DS2703
using Net Address commands and then setting up an authentication exchange and retrieving the results. In
communication mode, the DQ load current is no more than IDQ0 maximum, and the DS2703 can be “parasite”
powered via the DQ pin through a high impedance pullup resistor during a communication transaction. Power
available while the 1-Wire bus is at a logic high is rectified by the on chip diode and stored in an off chip capacitor
connected to the VB pin.
In computation mode, when a SHA-1 verification is performed, the DQ load current increases up to IDQ2,
necessitating a lower impedance pullup resistor. The computation mode load current occurs after the host supplies
the required challenge data and requests the computation using the proper function commands in communication
mode. In this mode, the pullup supply and low impedance pullup resistor must be capable of keeping the DQ pin
above VPULLUP-MIN.
The third operating mode is required when programming the non-volatile memory portions of the DS2703. The
programming mode is defined by the application of a high voltage programming pulse to the DQ pin at the
appropriate point during a Compute Secret command, Load/Lock Secret or Clear/Set Overdrive Timing command.
The internal voltage regulator limits the internal voltage (VDD_INT) to isolate low voltage portions of the chip from the
HV programming pulse. Typically, programming mode is used during module or pack manufacture to configure the
DS2703 and program the 64-bit secret.
Finally, thermistor mode allows the voltage on an external thermistor to be measured from the DQ line. The
command sequence causes the DS2703 to internally disconnect its DQ interface and drive the THM pin to VSS
allowing the measurement to be made. The IC remains in this mode until the VB pin capacitor is drained causing
the DS2703 to power cycle back to communication mode.
AUTHENTICATION
Authentication is performed using a FIPS-180 compliant SHA-1 one way hash algorithm on a 512 bit message
block. The message block consists of a 64-bit secret, a 64-bit challenge and 384 bits of constant data. Optionally,
the 64-bit net address replaces 64 of the 384 bits of constant data used in the hash operation. An authentication
attempt is initiated by the host system providing a 64-bit random challenge then sending one of two compute
command sequences. The host and the DS2703 both calculate the result based on the mutually known secret. The
result data, known as the Message Authentication Code (MAC) or Message Digest, is returned by the DS2703 for
comparison to the host’s result. Note that the secret is never transmitted on the bus and thus cannot be captured
by observing bus traffic. SHA-1 based authentication is a cryptographically strong method in wide use for digitally
signing encrypted files and secure transactions such as electronic cash and password exchange protocols.
The FIPS 180 Compliant Input Block, the 512-bit message block is organized as sixteen 32-bit words, W0-W15.
The message block is initialized when a command is received to compute the MAC. Upon initialization, the 64-bit
secret is loaded, and it is important to note that the SHA-1 algorithm has access to this data, but not the serial
interface. The challenge data is received with the command just prior to the compute MAC command. The
challenge data is cleared during computation of the MAC, so the host must write new challenge data prior to
issuing each Compute MAC or Compute Next Secret command. Additionally, the A, B, C, D and E variables used
in the hash computation are initialized per FIPS 180 as shown in Table 1. Variable Initiation. Please contact the
factory for memory map details.
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Table 1. Variable Initiation
[31:0] [23:16] [15:8] [7:0]
A 67h 45h 23h 01h
B EFh CDh ABh 89h
C 98h BAh DCh FEh
D 10h 32h 54h 76h
E C3h D2h E1h F0h
The 160-bit MAC is computed per FIPS 180, including the addition of constants H0-H4. Adding H0-H4 is necessary
only to maintain compliance with FIPS 180. The computed MAC is held in the A-E register memory and then
returned as a 160-bit serial stream, beginning with the least significant bit of variable A.
Table 2. Message Authentication Code (MAC) Return Format
A[31:24] A[23:16] A[15:8] A[7:0]
B[31:24] B[23:16] B[15:8] B[7:0]
C[31:24] C[23:16] C[15:8] C[7:0]
D[31:24] D[23:16] D[15:8] D[7:0]
E[31:24] E[23:16] E[15:8] E[7:0]
SHA-1 HASH ALGORITHM
General Definitions:
This description of the SHA computation is adapted from the Secure Hash Standard SHA-1 document. The
algorithm takes as its input data 16, 32-bit words Mt (0 t 15) as shown in the SHA-1 Input Message Format
tables. The SHA computation involves six 32-bit word variables labeled A, B, C, D, E, and TMP, five 32-bit word
constants labeled H0, H1, H2, H3, and H4, a sequence of eighty 32-bit words called Wt (0 t 79), a sequence of
eighty 32-bit words called Kt (0 t 79), and a Boolean function ft(B,C,D) (0 t 79). The operations required for
the SHA computation are arithmetic addition without carry ("+"), logical inversion or 1's complement ("\"), logical
XOR (""), logical AND ("^"), logical OR ("v"), concatenation of 32-bit values (“|”), assignment (":=") and circular
shifting within a 32-bit word. The expression Sn(X) represents a circular shift of X by n positions to the left, with X
being a 32-bit word.
The function ft is defined as follows:
ft(B,C,D) = (B^C)v((B\)^D) (0 t 19)
= B C D (20 t 39)
= (B^C)v(B^D)v(C^D) (40 t 59)
= B C D (60 t 79)
The sequence Kt (0 t 79) is defined as follows:
Kt := 5A827999h (0 t 19)
6ED9EBA1h (20 t 39)
8F1BBCDCh (40 t 59)
CA62C1D6h (60 t 79)
The sequence Wt (0 t 79) is defined as follows:
Wt := Mt (see table, FIPS-180 compliant input block) (0 t 15)
S
1(Wt-3 Wt-8 Wt-14 Wt-16) (16 t 79)
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SHA Computation
The variables A, B, C, D, E and constants H0, H1, H2, H3, and H4 are initialized as follows:
A := 67452301h H0 := 67452301h
B := EFCDAB89h H1 := EFCDAB89h
C := 98BADCFEh H2 := 98BADCFEh
D := 10325476h H3 := 10325476h
E := C3D2E1F0h H4 := C3D2E1F0h
The final values of variables A, B, C, D, and E are generated by looping through the following set of computations
for t = 0 to 79 (discarding any carry-out). Finally, the H0-H4 constants are added to the A-E variables respectively,
which are then concatenated to form the 160-bit MAC, ABCDE.
for ( t = 0 to 79 )
{
TMP := S5(A) + Ft(B,C,D) + Wt + Kt + E
E := D
D := C
C := S30(B)
B := A
A := TMP
}
160-bit MAC := (A+H0) | (B+H1) | (C+H2) | (D+H3) | (E+H4)
DS2703 AUTHENTICATION COMMANDS
WRITE CHALLENGE [0Ch]. This command writes 64 bits in the message block. The LSB of the 64-bit data can
begin immediately after the MSB of the command has been completed. If more than 8 bytes are written, the final
value in the challenge register will be indeterminate. The Compute MAC and Compute Next Secret (with or without
ROM ID) function commands clear the challenge value. Therefore the Write Challenge command must be issued
prior to every Compute MAC or Compute Next Secret command for reliable results.
NOTE: Immediately after power-up, a dummy Compute MAC command is required to initialize the DS2703. If the
dummy command is not issued, the first authentication attempt is computed using a challenge value of 0. When
issuing the dummy Compute MAC command, the command sequence can be terminated immediately following the
8th bit of the Compute MAC command byte. Waiting for the SHA-1 computation and reading the results back are
not required.
COMPUTE MAC WITHOUT ROM ID [36h]. This command initiates a SHA-1 computation on the 512 bit block
comprised of words W0 - W15. The 64-bit secret and the 64-bit challenge are loaded in the message block and the
space in the message reserved for the ROM ID is filled with logical 1's. The DS2703 pauses at least 100us after
receiving this command before MAC computation begins. This gives the host ample time to connect the DQ pin to
a low impedance node prior to the high current demand computation. The DQ pin must not fall below VPULLUP_MIN
during the computation period, tCOMP. The host must release the DQ pin for 1-Wire data communications (i.e.
terminate the low source impedance mode). After the DQ pin has returned to normal impedance, the host must
write eight write zero time slots and then issue 160 read time slots to get the MAC. The 32-bit registers A, B, C, D,
and E are used during every cycle of the hash algorithm and their final values at calculation cycle t=79 are added
to the values H0-H4 and stored in registers A-E. The new word ABCDE is now the MAC. After issuing the
command and waiting a minimum of tCOMP, the host reads the 20-byte MAC. This command allows the use of a
master secret and message digest response independent of the ROM ID.
COMPUTE MAC WITH ROM ID [35h]
This command is structured the same as the Compute MAC without ROM ID, except that the ROM ID is loaded to
the message block. Including the ROM ID unique to each DS2703 in the MAC computation allows the use of a
unique secret in each token and a master secret in the host device. See application note “White Paper 4”, available
at http://www.maxim-ic.com, for more information.
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SHA-1 related commands used while authenticating a battery or peripheral device are summarized in Table 3 for
convenience. Four additional commands for clearing, computing and locking of the Secret are described in detail in
the following section.
Table 3. Authentication Function Commands
COMMAND HEX FUNCTION
Write Challenge 0C Writes 64-bit challenge for SHA-1 processing. Required prior to
either Compute MAC command.
Compute MAC without ROM ID
and return MAC 36 Computes hash with logical 1’s in place of the ROM_ID
Compute MAC with ROM ID and
return MAC 35 Computes hash including the ROM_ID
SECRET MANAGEMENT FUNCTION COMMANDS
LOAD SECRET [5Ah]. This command changes the 64-bit secret to the provided 64-bit data argument value. The
host must apply a programming pulse afterwards to copy the new secret value to EEPROM.
COMPUTE NEXT SECRET WITHOUT ROM ID [30h]. This command initiates a SHA-1 computation of the MAC
and uses a portion of the resulting MAC as the next or new secret. The MAC computation is performed with the
current 64-bit secret and the 64-bit challenge. The space in the message reserved for the ROM ID is filled with
logical 1's. Two words (64 bits) of the output MAC are used as the new secret value. The host must allow tCOMP
after issuing this command for the SHA calculation to complete, then apply a programming pulse to write the new
secret value to EEPROM.
COMPUTE NEXT SECRET WITH ROM ID [33h]. This command initiates a SHA-1 computation of the MAC and
uses a portion of the resulting MAC as the next or new secret. The MAC computation is performed with the current
64-bit secret, the 64-bit ROM ID, and the 64-bit challenge. Two words (64 bits) of the output MAC are used as the
new secret value. The host must allow tCOMP after issuing this command for the SHA calculation to complete, then
apply a programming pulse to write the new secret value to EEPROM.
Note: Please contact the factory for details about what information is used to construct the new secret in the
Compute Next Secret With ROM ID and Compute Next Secret Without ROM ID commands.
LOCK SECRET [6Ah]. This command write protects the 64-bit Secret to prevent accidental or malicious overwrite
of the secret value. The Secret value stored in EEPROM becomes "final." The host must apply a programming
pulse to write the secret lock bit to EEPROM.
Table 4. Secret Loading Function Commands
COMMAND HEX FUNCTION
Load Secret 5A Loads the Secret with 64-bit data argument
Compute Next Secret without
ROM ID 30 Generates new global secret
Compute Next Secret with
ROM ID 33 Generates new unique secret
Lock Secret 6A Sets lock bit to prevent changes to the Secret
1-Wire SPEED CONTROL FUNCTION COMMANDS
CLEAR OVERDRIVE [8Dh]. This command clears the 1-Wire Overdrive bit to select the Standard 1-Wire timings
shown in the Electrical Characteristics table. The Overdrive bit is stored in EEPROM so that the programmed
speed selection can be recalled on initial power up. The host must apply a programming pulse to complete the
command.
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SET OVERDRIVE [8Bh]. This command sets the 1-Wire Overdrive bit to select the Overdrive 1-Wire timings
shown in the Electrical Characteristics table. The Overdrive bit is stored in EEPROM so that the programmed
speed selection can be recalled on initial power up. The host must apply a programming pulse to complete the
command.
Table 5. 1-Wire Speed Control Function Commands
COMMAND HEX FUNCTION
Clear Overdrive 8D Clears the Overdrive 1-Wire Speed bit to select Standard 1-Wire
timings
Set Overdrive 8B Sets the Overdrive 1-Wire Speed bit to select Overdrive 1-Wire
timings
THERMISTOR MEASUREMENT
The DS2703’s 1-Wire interface allows a thermistor to be multiplexed on the DQ line for thermal measurements of
the cell pack without adding an additional pack connection. See the Typical Operating Circuit, Figure 5. The
thermistor is connected between the DQ and THM pins. THM is normally high impedance to prevent the thermistor
from interfering with 1-Wire communication. When an Activate THM command is received, THM is internally driven
to VSS and the DQ pin becomes high impedance allowing the thermistor resistance to be measured. See the
timing diagram in Figure 12.
Figure 2. Thermistor Mode Duration when CVB is .22µF
0
200
400
600
800
1000
2.7 3.1 3.5 3.9 4.3 4.7 5.1 5.5
Normal Mode of
Operation Restored
Worst Case Quickest
Transition Time
Worst Case Slowest
Transition
Typical Transition
Time
Valid Thermistor
Measurement Period
Time (ms)
DQ Pullup Voltage (V)
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The DS2703 will remain in thermistor measurement mode until the stored charge on the VB pin capacitor is
depleted causing the IC to power cycle back to standard mode of operation. While in thermistor measurement
mode, communication to the DS2703 is not possible. After measuring the thermistor, the host must wait until the
VB capacitor is depleted. Figure 2 shows the typical and worst case transition times over the full operating range
when using .22µF as the VB pin capacitor. Thermistor measurements should be made within the first 100ms after
issuing the command. The host system should then wait until at least 1000ms have passed before sending the next
communication sequence to the IC.
Table 6. Thermistor Function Command
COMMAND HEX FUNCTION
Activate Thermistor A9
Activates the THM output for thermistor measurement. Activation
occurs within 50μs of command completion and continues until VB
capacitor depleted.
1-Wire BUS SYSTEM
The 1-Wire bus is a system that has a single bus master and one or more slaves. A multidrop bus is a 1-Wire bus
with multiple slaves, while a single-drop bus has only one slave device. In all instances, the DS2703 is a slave
device. The bus master is typically a microprocessor in the host system. The discussion of this bus system consists
of five topics: 64-bit net address, CRC generation, hardware configuration, transaction sequence, and 1-Wire
signaling.
64-BIT NET ADDRESS (ROM ID)
Each DS2703 has a unique, factory-programmed 1-Wire Net Address that is 64 bits in length. The term Net
Address is synonymous with the ROM ID or ROM Code terms used in earlier Dallas 1-Wire product documentation.
The first eight bits of the Net Address are the 1-Wire family code, (34h) for the DS2703. The next 48 bits are a
unique serial number. The last eight bits are a cyclic redundancy check (CRC) of the first 56 bits (see Figure 3.).
The 64-bit net address and the 1-Wire I/O circuitry built into the device enable the DS2703 to communicate through
the 1-Wire protocol detailed in this data sheet.
Figure 3. 1-Wire Net Address Format
8-BIT CRC 48-BIT SERIAL NUMBER 8-BIT FAMILY
CODE (34H)
MSb LSb
CRC GENERATION
The DS2703 has an 8-bit CRC stored in the most significant byte of its 1-Wire net address. To ensure error-free
transmission of the address, the host system can compute a CRC value from the first 56 bits of the address and
compare it to the 8-bit CRC from the DS2703.
The host system is responsible for verifying the CRC value and taking action as a result. The DS2703 does not
compare CRC values and does not prevent a command sequence from proceeding as a result of a CRC mismatch.
Proper use of the CRC can result in a communication channel with a very high level of integrity.
The CRC can be generated by the host using a circuit consisting of a shift register and XOR gates as shown in
Figure 4, or it can be generated in software using the polynomial X8 + X5 + X4 + 1. Additional information about the
Dallas 1-Wire CRC is available in Application Note 27: Understanding and Using Cyclic Redundancy Checks with
Dallas Semiconductor T ouch Memory Products (www.maxim-ic.com/appnoteindex).
In Figure 4, the Shift Register bits are initialized to 0. Then, starting with the least significant bit of the family code,
one bit at a time is shifted in. After the 8th bit of the family code has been entered, then the serial number is
entered. After the 48th bit of the serial number has been entered, the shift register contains the CRC value.
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Figure 4. 1-Wire CRC Generation Block Diagram
HARDWARE CONFIGURATION
The DS2703 uses an open-drain output driver as part of the bidirectional interface circuitry shown in Figure 5. If a
bidirectional pin is not available on the bus master, separate output and input pins can be connected together. For
normal communication the 1-Wire bus must have a pullup resistor at the bus-master end of the bus. For short line
lengths and/or VPULLUP 3.0V, a value of approximately 4.7kΩ is recommended. For long line lengths and/or
VPULLUP < 3.0V, a value of approximately 2kΩ is recommended. The idle state for the 1-Wire bus is high. If, for any
reason, a bus transaction must be suspended, the bus must be left in the idle state to properly resume the
transaction later. Note that if the bus is left low for more than tLOW0, slave devices on the bus begin to interpret the
low period as a reset pulse, effectively terminating the transaction.
When performing SHA-1 computations with a low pullup voltage, the DS2703 may require a stronger pullup than
4.7k to maintain the minimum VPULLUP requirement. A P-FET in parallel with the standard pullup can be switched on
during computation and then disabled to read the result. When measuring the thermistor RTHM, both the strong
pullup and standard pullup should be disabled to allow a weak pullup to form a voltage divider with the thermistor.
A voltage A/D connected directly to the 1-Wire bus can then read the voltage drop of the thermistor.
Figure 5. 1-Wire Bus Interface Circuitry
MSb
XOR
XOR LSb
XOR
INPUT
VPULLUP
Bus Master DS2703
Rx
Tx
4.7K 50K
150
RTHM
~100
MOSFET
~1µA
Rx
Tx
Activate
THM
PACK-
DQ
COMP
COMM
Voltage A/D
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TRANSACTION SEQUENCE
The protocol for accessing the DS2703 through the 1-Wire port is as follows:
Initialization
Net Address Command
Function Command(s)
Data Transfer (not all commands have data transfer)
All transactions of the 1-Wire bus begin with an initialization sequence consisting of a reset pulse transmitted by the
bus master, followed by a presence pulse simultaneously transmitted by the DS2703 and any other slaves on the
bus. The presence pulse tells the bus master that one or more devices are on the bus and ready to operate. For
more details, see the 1-Wire Signaling section below.
NET ADDRESS COMMANDS
Once the bus master has detected the presence of one or more slaves, it can issue one of the net address
commands described in the following paragraphs. The name of each Net Address command (ROM command) is
followed by the 8-bit opcode for that command in square brackets. Figure 6 presents a transaction flowchart of the
net address commands.
Read Net Address [33h]. This command allows the bus master to read the DS2703’s 1-Wire net address. This
command can only be used if there is a single slave on the bus. If more than one slave is present, a data collision
occurs when all slaves try to transmit at the same time (open drain produces a wired-AND result).
Match Net Address [55h]. This command allows the bus master to specifically address one DS2703 on the 1-Wire
bus. Only the addressed DS2703 responds to any subsequent function command. All other slave devices ignore
the function command and wait for a reset pulse. This command can be used with one or more slave devices on
the bus.
Skip Net Address [CCh]. This command saves time when there is only one DS2703 on the bus by allowing the
bus master to issue a function command without specifying the address of the slave. If more than one slave device
is present on the bus, a subsequent function command can cause a data collision when all slaves transmit data at
the same time.
Search Net Address [F0h]. This command allows the bus master to use a process of elimination to identify the
1-Wire net addresses of all slave devices on the bus. The search process involves the repetition of a simple three-
step routine: read a bit, read the complement of the bit, then write the desired value of that bit. The bus master
performs this simple three-step routine on each bit location of the net address. After one complete pass through all
64 bits, the bus master knows the address of one device. The remaining devices can then be identified on
additional iterations of the process. See Chapter 5 of the Book of DS19xx iButton® Standards for a comprehensive
discussion of a net address search, including an actual example (www.maxim-ic.com/iButtonBook).
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Figure 6. Net Address Command Flow Chart
YES
NO
YESYES
YES
YES
NO
MASTER Tx
NET ADDRESS
COMMAND
DS2703 Tx
PRESENCE PULSE
33h
READ
55h
MATCH
F0h
SEARCH
CCh
SKIP
MASTER Tx
RESET PULSE
NO NO NO
DS2703 Tx
FAMILY CODE
1 BYTE
DS2703 Tx
SERIAL NUMBER
6 BYTES
DS2703 Tx
CRC
1 BYTE
MASTER Tx
FUNCTION
COMMAND
YES
MASTER Tx
BIT 0
YES
BIT 0
MATCH?
MASTER Tx
BIT 1
NO
YES
BIT 1
MATCH?
DS2703 Tx BIT 1
MASTER Tx BIT 1
BIT 0
MATCH?
MASTER Tx
BIT 63
BIT 63
MATCH?
DS2703 Tx BIT 1
DS2703 Tx BIT 63
MASTER Tx BIT 63
DS2703 Tx BIT 63
DS2703 Tx BIT 0
MASTER Tx BIT 0
DS2703 Tx BIT 0
MASTER Tx
FUNCTION
COMMAND
BIT 1
MATCH?
NO
NO NO
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I/O SIGNALING
The 1-Wire bus requires strict signaling protocols to ensure data integrity. The four protocols used by the DS2703
are as follows: the initialization sequence (reset pulse followed by presence pulse), write 0, write 1, and read data.
The bus master initiates all these types of signaling except the presence pulse.
The initialization sequence required to begin any communication with the DS2703 is shown in Figure 7. A presence
pulse following a reset pulse indicates that the DS2703 is ready to accept a net address command. The bus master
transmits (Tx) a reset pulse for tRSTL. The bus master then releases the line and goes into receive mode (Rx). The
1-Wire bus line is then pulled high by the pullup resistor. After detecting the rising edge on the DQ pin, the DS2703
waits for tPDH and then transmits the presence pulse for tPDL.
Figure 7. 1-Wire Initialization Sequence
WRITE-TIME SLOTS
A write-time slot is initiated when the bus master pulls the 1-Wire bus from a logic-high (inactive) level to a logic-low
level. There are two types of write-time slots: write 1 and write 0. All write-time slots must be tSLOT in duration with
a 1μs minimum recovery time, tREC, between cycles. The DS2703 samples the 1-Wire bus line between tLOW1_MAX
and tLOW0_MIN after the line falls. If the line is high when sampled, a write 1 occurs. If the line is low when sampled, a
write 0 occurs. The sample window is illustrated in Figure 8. 1-Wire Write and Read Time Slots. For the bus master
to generate a write 1 time slot, the bus line must be pulled low and then released, allowing the line to be pulled high
less than tRDV after the start of the write time slot. For the host to generate a write 0 time slot, the bus line must be
pulled low and held low for the duration of the write-time slot.
Caution: When communicating in standard mode, the number of consecutive Write 0 time slots with tLOW0 =
tLOW0_MAX and tREC = tREC_MIN is limited to 64. If more than 64 Write 0 time slots with tLOW0 = tLOW0_MAX and tREC =
tREC_MIN are issued, the internal supply (VDD_INT) can drop so low that the DS2703 resets. Increasing tREC to 5
μ
s
allows Vdd_int to recharge sufficiently each time slot.
READ-TIME SLOTS
A read-time slot is initiated when the bus master pulls the 1-Wire bus line from a logic-high level to a logic-low level.
The bus master must keep the bus line low for at least 1μs and then release it to allow the DS2703 to present valid
data. The bus master can then sample the data tRDV from the start of the read-time slot. By the end of the read-
time slot, the DS2703 releases the bus line and allows it to be pulled high by the external pullup resistor. All read-
time slots must be tSLOT in duration with a 1μs minimum recovery time, tREC, between cycles. See Figure 8 and the
timing specifications in the Electrical Characteristics table for more information.
tR
S
TL
tPDL
tR
S
TH
tPDH
VPULLUP
GND-
LINE TYPE LEGEND:
BUS MASTER ACTIVE LOW DS2703 ACTIVE LOW
RESISTOR PULLUP
BOTH BUS MASTER AND
DS2703 ACTIVE LOW
DQ
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Figure 8. 1-Wire Write and Read Time Slots
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Table 7. All Function Commands
COMMAND HEX FUNCTION
Write Challenge 0C Writes 64-bit challenge for SHA-1 processing. Required prior to all Compute
MAC and Compute Next Secret commands.
Compute MAC
without ROM_ID and
return MAC
36 Computes hash of W0-W15 with logical 1’s in place of the ROM_ID.
Compute MAC
with ROM_ID and
return MAC
35 Computes hash of W0-W15 with the ROM_ID.
Load Secret 5A Writes the 64-bit Secret to supplied data. Requires programming voltage on
DQ.
Compute Next Secret
without ROM ID 30 Generates new global secret. Requires programming pulse.
Compute Next Secret
with ROM ID 33 Generates new unique secret. Requires programming pulse.
Lock Secret 6A Sets lock bit to prevent changes to the Secret. Requires programming pulse.
Set Overdrive 8B Sets 1-Wire interface timings to OVERDRIVE. Requires programming pulse.
Clear Overdrive 8D Sets 1-Wire interface timings to STANDARD. Requires programming pulse.
Activate Thermistor A9
Activates the THM output for thermistor measurement. Activation occurs within
50µs of command completion and continues until the VB capacitor is
discharged.
Reset BB Resets DS2703 (Software POR).
Table 8. Guide to Function Command Requirements
COMMAND STRONG PULLUP
ON DQ
ISSUE 00h
BEFORE READ
READ/WRITE
TIME SLOTS
PROGRAMMING
PULSE
Write Challenge
Write: 64
Compute MAC X X
Read: up to 160
Compute Next Secret X X
Lock Secret,
Set/Clear Overdrive X
Load Secret Write: 64 X
Reset
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LOW-IMPEDANCE DQ DURING COMPUTATION
The SHA-1 computation requires more current than the DQ pullup resistor used during normal communication can
supply. During the computation, the DQ source impedance must be reduced to maintain power to the device under
the higher load condition. The user must connect the low impedance source to the DQ line within tD of issuing any
command to perform a computation, and return the DQ source to normal settings before reading or writing to the
one-wire interface. See Figure 9.
Figure 9. Compute MAC Function Command
8 Write 0
Time Slots
Up to 160 Read Time Slots
(Read 20-Byte MAC)
SKIP ROM
Cmd
Compute
MAC
Cmd
1-Wire
Reset
Presence
Pulse
tDtSHA
Apply Low
Impedance
Pull-up
(If needed)
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PROGRAMMING PULSE
A typical programming waveform is shown in Figure 10. The user issues a 1-Wire reset followed by a Skip ROMID
command, Match ROMID plus the ROMID, Search or Read Net, the Load Secret command and then the two 32-bit
words to be loaded into EEPROM. The DQ line is then pulled to VPP for tPPW milliseconds and then returned to
nominal voltage. The fast rise and fall time requirements for the programming pulse are required to prevent
damage during the transition between normal communication mode and programming mode.
Figure 10. Lock Secret, Set/Clear Overdrive Function Commands
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COMPUTATION AND PROGRAMMING
The Compute Next Secret operation waveform is shown in Figure 11. The user issues a 1-Wire reset followed by a
Skip ROMID command, Match ROMID plus the ROMID, Search or Read Net, followed by the Compute Next Secret
command. The system host must connect the low impedance source to the DQ line within time tD and for a duration
of time tSHA. The DQ line is then pulled to VPP for tPPW milliseconds and then returned to nominal voltage. The fast
rise and fall time requirements for the programming pulse are required to prevent damage during the transition
between normal communication mode and programming mode.
Figure 11. Compute Next Secret Function Command
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HIGH-IMPEDANCE DQ FOR THERMISTOR MEASUREMENT
The user issues a 1-Wire reset followed by a Skip ROMID command, Match ROMID plus the ROMID, Search or
Read Net, followed by the Activate Thermistor command. Within the time period tTD the DS2703 disables its DQ
input and internally drives the THM pin low. Immediately following the Activate Thermistor command, the host
system should enable the weak pullup to VCC and then measure the thermistor by sampling the voltage level of
the 1-Wire bus within time tMIN. The DS2703 automatically reverts back to communication mode after tMIN. See
Figure 12.
Figure 12. Activate Thermistor Command
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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