General Description
The DS28E01-100 combines 1024 bits of EEPROM with
challenge-and-response authentication security imple-
mented with the ISO/IEC 10118-3 Secure Hash
Algorithm (SHA-1). The 1024-bit EEPROM array is con-
figured as four pages of 256 bits with a 64-bit scratch-
pad to perform write operations. All memory pages can
be write protected, and one page can be put in
EPROM-emulation mode, where bits can only be
changed from a 1 to a 0 state. Each DS28E01-100 has
its own guaranteed unique 64-bit ROM registration num-
ber that is factory lasered into the chip. The DS28E01-
100 communicates over the single-contact 1-Wire®bus.
The communication follows the standard 1-Wire protocol
with the registration number acting as the node address
in the case of a multidevice 1-Wire network.
Applications
Printer Cartridge Configuration and Monitoring
Medical Sensor Authentication and Calibration
System Intellectual Property Protection
Features
1024 Bits of EEPROM Memory Partitioned Into
Four Pages of 256 Bits
On-Chip 512-Bit SHA-1 Engine to Compute 160-
Bit Message Authentication Codes (MACs) and to
Generate Secrets
Write Access Requires Knowledge of the Secret
and the Capability of Computing and Transmitting
a 160-Bit MAC as Authorization
User-Programmable Page Write Protection for
Page 0, Page 3, or All Four Pages Together
User-Programmable OTP EPROM Emulation Mode
for Page 1 (“Write to 0”)
Communicates to Host with a Single Digital
Signal at 15.3kbps or 90.9kbps Using 1-Wire
Protocol
Switchpoint Hysteresis and Filtering to Optimize
Performance in the Presence of Noise
Reads and Writes Over 2.8V to 5.25V Voltage
Range from -40°C to +85°C
6-Lead TSOC and TDFN or 2-Lead TO-92 and SFN
Packages
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
Ordering Information
219-0007; Rev 8; 9/12
ABRIDGED DATA SHEET
DS28E01-100
For pricing, delivery, and ordering information, please contact Maxim Direct
at 1-888-629-4642, or visit Maxim’s website at www.maximintegrated.com.
PART TEMP RANGE
PIN-PACKAGE
DS28E01-100+
-40°C to +85°C
2 TO-92
DS28E01P-100+
-40°C to +85°C
6 TSOC
DS28E01P-100+T
-40°C to +85°C
6 TSOC
DS28E01G-100+T&R -40°C to +85°C
2 SFN
DS28E01Q-100+T&R -40°C to +85°C
6 TDFN-EP*
(2.5k pcs)
+
Denotes a lead(Pb)-free/RoHS-compliant package.
T and T&R = Tape and reel.
*
EP = Exposed pad.
IO
RPUP
VCC
μC
GND
DS28E01-100
Typical Operating Circuit
1-Wire is a registered trademark of Maxim Integrated Products, Inc.
Pin Configurations appear at end of data sheet.
Note to readers: This document is an abridged version of the full data sheet. To request the full data sheet, go to
www.maximintegrated.com/DS28E01 and click on Request Full Data Sheet.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
2 Maxim Integrated
ABSOLUTE MAXIMUM RATINGS
ELECTRICAL CHARACTERISTICS
(TA= -40°C to +85°C.) (Note 1)
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
IO Voltage Range to GND .......................................-0.5V to +6V
IO Sink Current ...................................................................20mA
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature......................................................+150°C
Storage Temperature Range .............................-55°C to +125°C
Lead Temperature (TSOC, TO-92, TDFN only;
soldering, 10s) ..............................................................+300°C
Soldering Temperature (reflow)
TSOC, TDFN .................................................................+260°C
TO-92 ............................................................................+250°C
SFN .......Refer to Application Note 4132:
Attachment Methods
for the Electro-Mechanical SFN Package
.
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
IO PIN: GENERAL DATA
1-Wire Pullup Voltage VPUP (Note 2) 2.8 5.25 V
1-Wire Pullup Resistance RPUP (Notes 2, 3) 0.3 2.2 k
Input Capacitance CIO (Notes 4, 5) 1000 pF
Input Load Current ILIO pin at VPUP 0.05 6.7 μA
High-to-Low Switching Threshold VTL (Notes 5, 6, 7) 0.46 VPUP -
1.8 V
Input Low Voltage VIL (Notes 2, 8) 0.5 V
Low-to-High Switching Threshold VTH (Notes 5, 6, 9) 1.0 VPUP -
1.1 V
Switching Hysteresis VHY (Notes 5, 6, 10) 0.21 1.70 V
Output Low Voltage VOL At 4mA current load (Note 11) 0.4 V
Standard speed, RPUP = 2.2k 5
Recovery Time
(Notes 2,12) tREC Overdrive speed, RPUP = 2.2k 5
μs
Standard speed 0.5 5.0
Rising-Edge Hold-Off Time
(Notes 5, 13) tREH Overdrive speed Not applicable (0) μs
Standard speed 65
Time Slot Duration
(Notes 2, 14) tSLOT Overdrive speed 11 μs
IO PIN: 1-Wire RESET, PRESENCE-DETECT CYCLE
Standard speed 480 640
Reset Low Time (Note 2) tRSTL Overdrive speed 48 80
μs
Standard speed 15 60
Presence-Detect High Time tPDH Overdrive speed 2 6
μs
Standard speed 60 240
Presence-Detect Low Time tPDL Overdrive speed 8 24 μs
Standard speed 60 75
Presence-Detect Sample Time
(Notes 2, 15) tMSP Overdrive speed 6 10 μs
ELECTRICAL CHARACTERISTICS (continued)
(TA= -40°C to +85°C.) (Note 1)
PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS
IO PIN: 1-Wire WRITE
Standard speed 60 120
Overdrive speed, VPUP > 4.5V 5 15.5
Write-Zero Low Time
(Notes 2, 16, 17) tW0L
Overdrive speed 6 15.5
μs
Standard speed 1 15
Write-One Low Time
(Notes 2, 17) tW1L Overdrive speed 1 2
μs
IO PIN: 1-Wire READ
Standard speed 5 15 -
Read Low Time
(Notes 2, 18) tRL Overdrive speed 1 2 - μs
Standard speed tRL + 15
Read Sample Time
(Notes 2, 18) tMSR Overdrive speed tRL + 2 μs
EEPROM
Programming Current IPROG (Notes 5, 19) 0.8 mA
Programming Time tPROG (Note 20) 10 ms
At +25°C 200k
Write/Erase Cycles (Endurance)
(Notes 21, 22) NCY At +85°C (worst case) 50k
Data Retention
(Notes 23, 24, 25) tDR At +85°C (worst case) 40 Years
SHA-1 ENGINE
Computation Current ILCSHA mA
Computation Time
(Notes 5, 26) tCSHA
ms
Note 1: Limits are 100% production tested at TA= +25°C and/or TA= +85°C. Limits over the operating temperature range and
relevant supply voltage range are guaranteed by design and characterization. Typical values are not guaranteed.
Note 2: System requirement.
Note 3: Maximum allowable pullup resistance is a function of the number of 1-Wire devices in the system and 1-Wire recovery times.
The specified value here applies to systems with only one device and with the minimum 1-Wire recovery times. For more
heavily loaded systems, an active pullup such as that found in the DS2482-x00, DS2480B, or DS2490 may be required.
Note 4: Maximum value represents the internal parasite capacitance when VPUP is first applied. Once the parasite capacitance is
charged, it does not affect normal communication.
Note 5: Guaranteed by design, characterization, and/or simulation only. Not production tested.
Note 6: VTL, VTH, and VHY are a function of the internal supply voltage, which is a function of VPUP, RPUP, 1-Wire timing, and
capacitive loading on IO. Lower VPUP, higher RPUP, shorter tREC, and heavier capacitive loading all lead to lower values of
VTL, VTH, and VHY.
Note 7: Voltage below which, during a falling edge on IO, a logic 0 is detected.
Note 8: The voltage on IO must be less than or equal to VILMAX at all times the master is driving IO to a logic 0 level.
Note 9: Voltage above which, during a rising edge on IO, a logic 1 is detected.
Note 10: After VTH is crossed during a rising edge on IO, the voltage on IO must drop by at least VHY to be detected as logic 0.
Note 11: The I-V characteristic is linear for voltages less than 1V.
Note 12: Applies to a single device attached to a 1-Wire line.
Note 13: The earliest recognition of a negative edge is possible at tREH after VTH has been reached on the preceding rising edge.
Note 14: Defines maximum possible bit rate. Equal to 1/(tW0LMIN + tRECMIN).
Note 15: Interval after tRSTL during which a bus master can read a logic 0 on IO if there is a DS28E01-100 present. The first presence
pulse after power-up could be outside this interval, but will be complete within 2ms after power-up.
Note 16: Numbers in bold are not in compliance with legacy 1-Wire product standards. See the
Comparison Table
.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 3
Refer to the full data sheet.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
4 Maxim Integrated
Note 17: εin Figure 12 represents the time required for the pullup circuitry to pull the voltage on IO up from VIL to VTH. The actual
maximum duration for the master to pull the line low is tW1LMAX + tF- εand tW0LMAX + tF- ε, respectively.
Note 18: δin Figure 12 represents the time required for the pullup circuitry to pull the voltage on IO up from VIL to the input-high
threshold of the bus master. The actual maximum duration for the master to pull the line low is tRLMAX + tF.
Note 19: Current drawn from IO during the EEPROM programming interval or SHA-1 computation.
Note 20:
Note 21: Write-cycle endurance is degraded as TAincreases.
Note 22: Not 100% production tested; guaranteed by reliability monitor sampling.
Note 23: Data retention is degraded as TAincreases.
Note 24: Guaranteed by 100% production test at elevated temperature for a shorter time; equivalence of this production test to the
data sheet limit at operating temperature range is established by reliability testing.
Note 25: EEPROM writes can become nonfunctional after the data-retention time is exceeded. Long-term storage at elevated tem-
peratures is not recommended; the device can lose its write capability after 10 years at +125°C or 40 years at +85°C.
Note 26:
COMPARISON TABLE
LEGACY VALUES DS28E01-100 VALUES
STANDARD SPEED
s)
OVERDRIVE SPEED
s)
STANDARD SPEED
s)
OVERDRIVE SPEED
s)
PARAMETER
MIN MAX MIN MAX MIN MAX MIN MAX
tSLOT (including tREC) 61 (undefined) 7 (undefined) 65* (undefined) 11* (undefined)
tRSTL 480 (undefined) 48 80 480 640 48 80
tPDH 15 60 2 6 15 60 2 6
tPDL 60 240 8 24 60 240 8 24
tW0L 60 120 6 16 60 120 6 15.5
*
Intentional change; longer recovery time requirement due to modified 1-Wire front-end.
Note: Numbers in bold are not in compliance with legacy 1-Wire product standards.
ELECTRICAL CHARACTERISTICS (continued)
(TA= -40°C to +85°C.) (Note 1)
Refer to the full data sheet for this note.
Refer to the full data sheet for this note.
Pin Description
PIN
TSOC TDFN-EP SFN TO-92 NAME FUNCTION
1321GNDGround Reference
2213 IO
1- Wi r e Bus Inter face. O p en- d r ai n si g nal that r eq ui r es an exter nal
p ul l up r esi stor .
3, 4, 5, 6 1, 4, 5, 6 2 N.C. Not Connected
———— EP
Exposed Pad (TDFN Only). Solder evenly to the board’s ground
plane for proper operation. Refer to Application Note 3273:
Exposed Pads: A Brief Introduction for additional information.
Detailed Description
The DS28E01-100 combines 1024 bits of EEPROM
organized as four 256-bit pages, a 64-bit secret, a reg-
ister page, a 512-bit SHA-1 engine, and a 64-bit ROM
registration number in a single chip. Data is transferred
serially through the 1-Wire protocol, which requires only
a single data lead and a ground return. The DS28E01-
100 has an additional memory area called the scratch-
pad that acts as a buffer when writing to the memory,
the register page, or when installing a new secret. Data
is first written to the scratchpad from where it can be
read back. After the data has been verified, a Copy
Scratchpad command transfers the data to its final
memory location, provided that the DS28E01-100
receives a matching 160-bit MAC. The computation of
the MAC involves the secret and additional data stored
in the DS28E01-100 including the device’s registration
number. Only a new secret can be loaded without pro-
viding a MAC. The SHA-1 engine is also activated to
compute 160-bit MACs when performing an authenti-
cated read of a memory page and when computing a
new secret, instead of loading it. The DS28E01-100
understands a unique command “Refresh Scratchpad.”
Proper use of a refresh sequence after a Copy
Scratchpad operation reduces the number of weak bit
failures if the device is used in a touch environment
(see the
Writing with Verification
section). The refresh
sequence also provides a means to restore functionali-
ty in a device with bits in a weak state.
The device’s 64-bit ROM registration number guaran-
tees unique identification and is used to address the
device in a multidrop 1-Wire network environment,
where multiple devices reside on a common 1-Wire bus
and operate independently of each other. Applications
of the DS28E01-100 include printer cartridge configura-
tion and monitoring, medical sensor authentication and
calibration, and system intellectual property protection.
Overview
The block diagram in Figure 1 shows the relationships
between the major control and memory sections of the
DS28E01-100. The DS28E01-100 has six main data
components: 64-bit lasered ROM, 64-bit scratchpad,
four 256-bit pages of EEPROM, register page, 64-bit
secrets memory, and a 512-bit SHA-1 engine. Figure 2
shows the hierarchic structure of the 1-Wire protocol.
The bus master must first provide one of the seven ROM
function commands: Read ROM, Match ROM, Search
ROM, Skip ROM, Resume Communication, Overdrive-
Skip ROM, or Overdrive-Match ROM. Upon completion
of an Overdrive-Skip ROM or Overdrive-Match ROM
command executed at standard speed, the device
enters overdrive mode where all subsequent communi-
cation occurs at a higher speed. The protocol required
for these ROM function commands is described in
Figure 10. After a ROM function command is success-
fully executed, the memory and SHA-1 functions
become accessible and the master can provide any
one of the 9 available function commands. The function
protocols are described in Figure 8. All data is read
and written least significant bit first.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 5
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
6 Maxim Integrated
DS28E01-100
1-Wire FUNCTION
CONTROL
1-Wire NET
PARASITE POWER
CRC-16
GENERATOR
64-BIT
LASERED ROM
64-BIT
SCRATCHPAD
512-BIT
SECURE HASH
ALGORITHM ENGINE
REGISTER
PAGE
SECRETS
MEMORY 64 BITS
DATA MEMORY
4 PAGES OF
256 BITS EACH
MEMORY AND
SHA-1 FUNCTION
CONTROL UNIT
Figure 1. Block Diagram
64-Bit Lasered ROM
Each DS28E01-100 contains a unique ROM registration
number that is 64 bits long. The first 8 bits are a 1-Wire
family code. The next 48 bits are a unique serial number.
The last 8 bits are a cyclic redundancy check (CRC) of
the first 56 bits. See Figure 3 for details. The 1-Wire CRC
is generated using a polynomial generator consisting of
a shift register and XOR gates as shown in Figure 4. The
polynomial is X8+ X5+ X4+ 1. Additional information
about the 1-Wire CRC is available in Application Note
27:
Understanding and Using Cyclic Redundancy
Checks with Maxim iButton
®
Products
.
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, the serial number is entered. After
the 48th bit of the serial number has been entered, the
shift register contains the CRC value. Shifting in the 8
bits of the CRC returns the shift register to all 0s.
Memory Access
The DS28E01-100 has four memory areas: data memo-
ry, secrets memory, register page with special function
registers and user bytes, and a volatile scratchpad. The
data memory is organized as four pages of 32 bytes.
Secret and scratchpad are 8 bytes each. The scratch-
pad acts as a buffer when writing to the data memory,
loading the initial secret, or when writing to the register
page.
Refer to the full data sheet for this information.
iButton is a registered trademark of Maxim Integrated
Products, Inc.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 7
AVAILABLE COMMANDS: DATA FIELD AFFECTED:
READ ROM
MATCH ROM
SEARCH ROM
SKIP ROM
RESUME
OVERDRIVE-SKIP ROM
OVERDRIVE-MATCH ROM
64-BIT REG. #, RC-FLAG
64-BIT REG. #, RC-FLAG
64-BIT REG. #, RC-FLAG
RC-FLAG
RC-FLAG
RC-FLAG, OD-FLAG
64-BIT REG. #, RC-FLAG, OD-FLAG
1-Wire ROM FUNCTION COMMANDS
(SEE FIGURE 10)
DEVICE-SPECIFIC MEMORY
FUNCTION COMMANDS
(SEE FIGURE 8)
COMMAND LEVEL:
DS28E01-100
Figure 2. Hierarchic Structure for 1-Wire Protocol
MSB
8-BIT
CRC CODE 48-BIT SERIAL NUMBER
MSB MSBLSB
LSB
LSB
8-BIT FAMILY CODE
MSBLSB
Figure 3. 64-Bit Lasered ROM
1ST
STAGE
2ND
STAGE
3RD
STAGE
4TH
STAGE
7TH
STAGE
8TH
STAGE
6TH
STAGE
5TH
STAGE
X0X1X2X3X4
POLYNOMIAL = X8 + X5 + X4 + 1
INPUT DATA
X5X6X7X8
Figure 4. 1-Wire CRC Generator
Refer to the full data sheet.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 9
Figure 6. Memory Protection Matrix
Address Registers and Transfer Status
The DS28E01-100 employs three address registers:
TA1, TA2, and E/S (Figure 7). These registers are com-
mon to many other 1-Wire devices, but operate slightly
differently with the DS28E01-100. Registers TA1 and
TA2 must be loaded with the target address to which
the data is written or from which data is read. Register
E/S is a read-only transfer-status register used to verify
data integrity with write commands. Since the scratch-
pad of the DS28E01-100 is designed to accept data in
blocks of 8 bytes only, the lower 3 bits of TA1 are
forced to 0 and the lower 3 bits of the E/S register (end-
ing offset) always read 1. This indicates that all the data
in the scratchpad is used for a subsequent copying into
main memory or secret. Bit 5 of the E/S register, called
PF or partial byte flag, is a logic 1 if the number of data
bits sent by the master is not an integer multiple of
eight or if the data in the scratchpad is not valid due to
a loss of power. A valid write to the scratchpad clears
the PF bit. Bits 3, 4, and 6 have no function; they always
read 1. The partial flag supports the master checking
the data integrity after a write command. The highest
BIT # 7 6 5 4 3 2 1 0
TARGET ADDRESS (TA1) T7 T6 T5 T4 T3 T2
(0)
T1
(0)
T0
(0)
TARGET ADDRESS (TA2) T15 T14 T13 T12 T11 T10 T9 T8
ENDING ADDRESS WITH
DATA STATUS (E/S)
(READ ONLY)
AA 1 PF 1 1 E2
(1)
E1
(1)
E0
(1)
Figure 7. Address Registers
Refer to the full data sheet.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
10 Maxim Integrated
valued bit of the E/S register, called authorization
accepted (AA), acts as a flag to indicate that the data
stored in the scratchpad has already been copied to
the target memory address. Writing data to the scratch-
pad clears this flag.
Writing with Verification
To write data to the DS28E01-100, the scratchpad must
be used as intermediate storage. First, the master
issues the Write Scratchpad command, which specifies
the desired target address and the data to be written to
the scratchpad. Note that writes to data memory must
be performed on 8-byte boundaries with the three LSBs
of the target address T[2:0] equal to 000b. Therefore, if
T[2:0] are sent with nonzero values, the device sets
these bits to 0 and uses the modified address as the
target address. The master should always send eight
complete data bytes. After the 8 bytes of data have
been transmitted, the master can elect to receive an
inverted CRC-16 of the Write Scratchpad command,
the address as sent by the master, and the data as sent
by the master. The master can compare the CRC to the
value it has calculated itself to determine if the commu-
nication was successful. After the scratchpad has been
written, the master should always perform a Read
Scratchpad to verify that the intended data was in fact
written. During a Read Scratchpad, the DS28E01-100
repeats the target address TA1 and TA2 and sends the
contents of the E/S register. The partial flag (bit 5 of the
E/S register) is set to 1 if the last data byte the
DS28E01-100 received during a Write Scratchpad or
Refresh Scratchpad command was incomplete, or if
there was a loss of power since data was last written to
the scratchpad. The authorization-accepted (AA) flag
(bit 7 of the E/S register) is normally cleared by a Write
Scratchpad or Refresh Scratchpad; therefore, if it is set
to 1, it indicates that the DS28E01-100 did not under-
stand the proceeding Write (or Refresh) Scratchpad
command. In either of these cases, the master should
rewrite the scratchpad. After the master receives the
E/S register, the scratchpad data is received. The
descriptions of Write Scratchpad and Refresh
Scratchpad provide clarification of what changes can
occur to the scratchpad data under certain conditions.
An inverted CRC of the Read Scratchpad command,
target address, E/S register, and scratchpad data fol-
lows the scratchpad data. As with the Write Scratchpad
command, this CRC can be compared to the value the
master has calculated to determine if the communica-
tion was successful. After the master has verified the
data, it can send the Copy Scratchpad to copy the
scratchpad to memory. Alternatively, the Load First
Secret or Compute Next Secret command can be
issued to change the secret. See the descriptions of
these commands for more information.
Refer to the full data sheet for this information.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 11
Memory and SHA-1 Function
Commands
This section describes the commands and flowcharts
needed to use the memory and SHA-1 engine of the
device. Refer to the full data sheet for more information.
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 23
SHA-1 Computation Algorithm
This description of the SHA-1 computation is adapted
from the Secure Hash Standard SHA-1 document from the
National Institute of Standards and Technology (NIST).
Refer to the full data sheet for more information. bit
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
24 Maxim Integrated
Rx
RPUP
IL
VPUP
BUS MASTER
OPEN-DRAIN
PORT PIN 100Ω MOSFET
Tx
Rx
Tx
DATA
DS28E01-100 1-Wire PORT
Rx = RECEIVE
Tx = TRANSMIT
Figure 9. Hardware Configuration
1-Wire Bus System
The 1-Wire bus is a system that has a single bus master
and one or more slaves. In all instances the DS28E01-
100 is a slave device. The bus master is typically a
microcontroller. The discussion of this bus system is
broken down into three topics: hardware configuration,
transaction sequence, and 1-Wire signaling (signal
types and timing). The 1-Wire protocol defines bus
transactions in terms of the bus state during specific
time slots, which are initiated on the falling edge of
sync pulses from the bus master.
Hardware Configuration
The 1-Wire bus has only a single line by definition; it is
important that each device on the bus be able to drive
it at the appropriate time. To facilitate this, each device
attached to the 1-Wire bus must have open-drain or
three-state outputs. The 1-Wire port of the DS28E01-
100 is open drain with an internal circuit equivalent to
that shown in Figure 9.
A multidrop bus consists of a 1-Wire bus with multiple
slaves attached. The DS28E01-100 supports both a
standard and overdrive communication speed of
15.3kbps (max) and 90.9kbps (max), respectively. Note
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 25
that legacy 1-Wire products support a standard com-
munication speed of 16.3kbps and overdrive of
142kbps. The slightly reduced rates for the DS28E01-
100 are a result of additional recovery times, which in
turn were driven by a 1-Wire physical interface
enhancement to improve noise immunity. The value of
the pullup resistor primarily depends on the network
size and load conditions. The DS28E01-100 requires a
pullup resistor of 2.2kΩ(max) at any speed.
The idle state for the 1-Wire bus is high. If for any rea-
son a transaction needs to be suspended, the bus
must be left in the idle state if the transaction is to
resume. If this does not occur and the bus is left low for
more than 16µs (overdrive speed) or more than 120µs
(standard speed), one or more devices on the bus
could be reset.
Transaction Sequence
The protocol for accessing the DS28E01-100 through
the 1-Wire port is as follows:
Initialization
ROM Function Command
Memory/SHA-1 Function Command
Transaction/Data
Initialization
All transactions on the 1-Wire bus begin with an initial-
ization sequence. The initialization sequence consists
of a reset pulse transmitted by the bus master followed
by presence pulse(s) transmitted by the slave(s). The
presence pulse lets the bus master know that the
DS28E01-100 is on the bus and is ready to operate. For
more details, see the
1-Wire Signaling
section.
1-Wire ROM Function
Commands
Once the bus master has detected a presence, it can
issue one of the seven ROM function commands that
the DS28E01-100 supports. All ROM function com-
mands are 8 bits long. A list of these commands follows
(see the flowchart in Figure 10).
Read ROM [33h]
The Read ROM command allows the bus master to
read the DS28E01-100’s 8-bit family code, unique 48-
bit serial number, and 8-bit CRC. This command can
only be used if there is a single slave on the bus. If
more than one slave is present on the bus, a data colli-
sion occurs when all slaves try to transmit at the same
time (open drain produces a wired-AND result). The
resultant family code and 48-bit serial number result in
a mismatch of the CRC.
Match ROM [55h]
The Match ROM command, followed by a 64-bit device
registration number, allows the bus master to address a
specific DS28E01-100 on a multidrop bus. Only the
DS28E01-100 that exactly matches the 64-bit registra-
tion number responds to the subsequent memory or
SHA-1 function command. All other slaves wait for a
reset pulse. This command can be used with a single
device or multiple devices on the bus.
Search ROM [F0h]
When a system is initially brought up, the bus master
might not know the number of devices on the 1-Wire
bus or their registration numbers. By taking advantage
of the wired-AND property of the bus, the master can
use a process of elimination to identify the registration
numbers of all slave devices. For each bit of the regis-
tration number, starting with the least significant bit, the
bus master issues a triplet of time slots. On the first slot,
each slave device participating in the search outputs
the true value of its registration number bit. On the sec-
ond slot, each slave device participating in the search
outputs the complemented value of its registration num-
ber bit. On the third slot, the master writes the true
value of the bit to be selected. All slave devices that do
not match the bit written by the master stop participat-
ing in the search. If both of the read bits are zero, the
master knows that slave devices exist with both states
of the bit. By choosing which state to write, the bus
master branches in the search tree. After one complete
pass, the bus master knows the registration number of
a single device. Additional passes identify the registra-
tion numbers of the remaining devices. Refer to
Application Note 187:
1-Wire Search Algorithm
for a
detailed discussion, including an example.
Skip ROM [CCh]
This command can save time in a single-drop bus sys-
tem by allowing the bus master to access the memory
functions without providing the 64-bit registration num-
ber. If more than one slave is present on the bus and,
for example, a read command is issued following the
Skip ROM command, data collision occurs on the bus
as multiple slaves transmit simultaneously (open-drain
pulldowns produce a wired-AND result).
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
26 Maxim Integrated
DS28E01-100 Tx
PRESENCE PULSE
BUS MASTER Tx
RESET PULSE
BUS MASTER Tx ROM
FUNCTION COMMAND
DS28E01-100 Tx
CRC BYTE
DS28E01-100 Tx
FAMILY CODE
(1 BYTE)
DS28E01-100 Tx
SERIAL NUMBER
(6 BYTES)
RC = 0
MASTER Tx BIT 0
RC = 0 RC = 0 RC = 0
OD = 0
YY
Y
Y
Y
Y
Y
Y
33h
READ ROM
COMMAND?
N55h
MATCH ROM
COMMAND?
BIT 0 MATCH? BIT 0 MATCH?
N
N N
N N
N N
F0h
SEARCH ROM
COMMAND?
OD
RESET PULSE?
N
N
CCh
SKIP ROM
COMMAND?
N
RC = 1
MASTER Tx BIT 1
MASTER Tx BIT 63
BIT 1 MATCH?
BIT 63 MATCH?
Y
Y
RC = 1
FROM MEMORY AND SHA-1 FUNCTION
FLOWCHART (FIGURE 8)
TO MEMORY AND SHA-1 FUNCTION
FLOWCHART (FIGURE 8)
DS28E01-100 Tx BIT 0
DS28E01-100 Tx BIT 0
MASTER Tx BIT 0
BIT 1 MATCH?
BIT 63 MATCH?
DS28E01-100 Tx BIT 1
DS28E01-100 Tx BIT 1
MASTER Tx BIT 1
DS28E01-100 Tx BIT 63
DS28E01-1001 Tx BIT 63
MASTER Tx BIT 63
Y
TO FIGURE 10b
TO FIGURE 10b
FROM FIGURE 10b
FROM FIGURE 10b
Figure 10a. ROM Functions Flowchart
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 27
RC = 0; OD = 1 RC = 0; OD = 1
N
BIT 0 MATCH?
YN
RC = 1?
Y
A5h
RESUME
COMMAND?
N
Y
3Ch
OVERDRIVE-
SKIP ROM?
N
Y
69h
OVERDRIVE-
MATCH ROM?
FROM FIGURE 10a
FROM FIGURE 10a
TO FIGURE 10a
TO FIGURE 10a
N
Y
Y
N
MASTER Tx
RESET?
Y
MASTER Tx
RESET?
NBIT 1 MATCH?
MASTER Tx BIT 0
MASTER Tx BIT 1
N
N
Y
RC = 1
BIT 63 MATCH?
MASTER Tx BIT 63
Y
Figure 10b. ROM Functions Flowchart (continued)
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
28 Maxim Integrated
Resume [A5h]
To maximize the data throughput in a multidrop environ-
ment, the Resume command is available. This command
checks the status of the RC bit and, if it is set, directly
transfers control to the memory and SHA-1 function com-
mands, similar to a Skip ROM command. The only way to
set the RC bit is through successfully executing the
Match ROM, Search ROM, or Overdrive-Match ROM
command. Once the RC bit is set, the device can repeat-
edly be accessed through the Resume command.
Accessing another device on the bus clears the RC bit,
preventing two or more devices from simultaneously
responding to the Resume command.
Overdrive-Skip ROM [3Ch]
On a single-drop bus this command can save time by
allowing the bus master to access the memory func-
tions without providing the 64-bit registration number.
Unlike the normal Skip ROM command, the Overdrive-
Skip ROM command sets the DS28E01-100 into the
overdrive mode (OD = 1). All communication following
this command must occur at overdrive speed until a
reset pulse of minimum 480µs duration resets all de-
vices on the bus to standard speed (OD = 0).
When issued on a multidrop bus, this command sets all
overdrive-supporting devices into overdrive mode. To
subsequently address a specific overdrive-supporting
device, a reset pulse at overdrive speed must be
issued followed by a Match ROM or Search ROM com-
mand sequence. This speeds up the time for the
search process. If more than one slave supporting
overdrive is present on the bus and the Overdrive-Skip
ROM command is followed by a read command, data
collision occurs on the bus as multiple slaves transmit
simultaneously (open-drain pulldowns produce a wired-
AND result).
Overdrive-Match ROM [69h]
The Overdrive-Match ROM command followed by a 64-
bit registration number transmitted at overdrive speed
allows the bus master to address a specific DS28E01-
100 on a multidrop bus and to simultaneously set it in
overdrive mode. Only the DS28E01-100 that exactly
matches the 64-bit number responds to the subsequent
memory or SHA-1 function command. Slaves already in
overdrive mode from a previous Overdrive-Skip ROM or
successful Overdrive-Match ROM command remain in
overdrive mode. All overdrive-capable slaves return to
standard speed at the next reset pulse of minimum
480µs duration. The Overdrive-Match ROM command
can be used with a single device or multiple devices on
the bus.
1-Wire Signaling
The DS28E01-100 requires strict protocols to ensure
data integrity. The protocol consists of four types of
signaling on one line: reset sequence with reset pulse
and presence pulse, write-zero, write-one, and read-
data. Except for the presence pulse, the bus master
initiates all falling edges. The DS28E01-100 can com-
municate at two different speeds: standard speed and
overdrive speed. If not explicitly set into the overdrive
mode, the DS28E01-100 communicates at standard
speed. While in overdrive mode, the fast timing applies
to all waveforms.
To get from idle to active, the voltage on the 1-Wire line
needs to fall from VPUP below the threshold VTL. To get
from active to idle, the voltage needs to rise from
VILMAX past the threshold VTH. The time it takes for the
voltage to make this rise is seen in Figure 11 as ε, and
its duration depends on the pullup resistor (RPUP) used
and the capacitance of the 1-Wire network attached.
The voltage VILMAX is relevant for the DS28E01-100
when determining a logical level, not triggering any
events.
Figure 11 shows the initialization sequence required to
begin any communication with the DS28E01-100. A
reset pulse followed by a presence pulse indicates that
the DS28E01-100 is ready to receive data, given the
correct ROM and memory and SHA-1 function com-
mand. If the bus master uses slew-rate control on the
falling edge, it must pull down the line for tRSTL + tFto
compensate for the edge. A tRSTL duration of 480µs or
longer exits the overdrive mode, returning the device to
standard speed. If the DS28E01-100 is in overdrive
mode and tRSTL is no longer than 80µs, the device
remains in overdrive mode. If the device is in overdrive
mode and tRSTL is
between
80µs and 480µs, the device
resets, but the communication speed is undetermined.
After the bus master has released the line it goes into
receive mode. Now the 1-Wire bus is pulled to VPUP
through the pullup resistor or, in the case of a DS2482-
x00 or DS2480B driver, through active circuitry. When
the threshold VTH is crossed, the DS28E01-100 waits
for tPDH and then transmits a presence pulse by pulling
the line low for tPDL. To detect a presence pulse, the
master must test the logical state of the 1-Wire line at
tMSP.
The tRSTH window must be at least the sum of tPDHMAX,
tPDLMAX, and tRECMIN. Immediately after tRSTH is
expired, the DS28E01-100 is ready for data communi-
cation. In a mixed population network, tRSTH should be
extended to minimum 480µs at standard speed and
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 29
48µs at overdrive speed to accommodate other 1-Wire
devices.
Read/Write Time Slots
Data communication with the DS28E01-100 takes place
in time slots that carry a single bit each. Write time slots
transport data from bus master to slave. Read time
slots transfer data from slave to master. Figure 12 illus-
trates the definitions of the write and read time slots.
All communication begins with the master pulling the
data line low. As the voltage on the 1-Wire line falls
below the threshold VTL, the DS28E01-100 starts its
internal timing generator that determines when the data
line is sampled during a write time slot and how long
data is valid during a read time slot.
Master-to-Slave
For a write-one time slot, the voltage on the data line
must have crossed the VTH threshold before the write-
one low time tW1LMAX is expired. For a write-zero time
slot, the voltage on the data line must stay below the
VTH threshold until the write-zero low time tW0LMIN is
expired. For the most reliable communication, the volt-
age on the data line should not exceed VILMAX during
the entire tW0L or tW1L window. After the VTH threshold
has been crossed, the DS28E01-100 needs a recovery
time tREC before it is ready for the next time slot.
Slave-to-Master
A read-data time slot begins like a write-one time slot.
The voltage on the data line must remain below VTL
until the read low time tRL is expired. During the tRL
window, when responding with a 0, the DS28E01-100
starts pulling the data line low; its internal timing gener-
ator determines when this pulldown ends and the volt-
age starts rising again. When responding with a 1, the
DS28E01-100 does not hold the data line low at all, and
the voltage starts rising as soon as tRL is over.
The sum of tRL + δ(rise time) on one side and the inter-
nal timing generator of the DS28E01-100 on the other
side define the master sampling window (tMSRMIN to
tMSRMAX), in which the master must perform a read
from the data line. For the most reliable communication,
tRL should be as short as permissible, and the master
should read close to but no later than tMSRMAX. After
reading from the data line, the master must wait until
tSLOT is expired. This guarantees sufficient recovery
time tREC for the DS28E01-100 to get ready for the next
time slot. Note that tREC specified herein applies only to
a single DS28E01-100 attached to a 1-Wire line. For
multidevice configurations, tREC must be extended to
accommodate the additional 1-Wire device input
capacitance. Alternatively, an interface that performs
active pullup during the 1-Wire recovery time such as
the DS2482-x00 or DS2480B 1-Wire drivers can be
used.
RESISTOR MASTER DS28E01-100
tRSTL tPDL
tRSTH
tPDH
MASTER Tx "RESET PULSE" MASTER Rx "PRESENCE PULSE"
VPUP
VIHMASTER
VTH
VTL
VILMAX
0V
ε
tF
tREC
tMSP
Figure 11. Initialization Procedure: Reset and Presence Pulse
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
30 Maxim Integrated
RESISTOR MASTER
RESISTOR MASTER
RESISTOR MASTER DS28E01-100
ε
ε
δ
VPUP
VIHMASTER
VTH
VTL
VILMAX
0V
tF
VPUP
VIHMASTER
VTH
VTL
VILMAX
0V
tF
VPUP
VIHMASTER
VTH
VTL
VILMAX
0V
tF
tSLOT
tW1L
tREC
tSLOT
tSLOT
tW0L
tREC
MASTER
SAMPLING
WINDOW
tRL
tMSR
WRITE-ONE TIME SLOT
WRITE-ZERO TIME SLOT
READ-DATA TIME SLOT
Figure 12. Read/Write Timing Diagrams
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 31
Improved Network Behavior
(Switchpoint Hysteresis)
In a 1-Wire environment, line termination is possible
only during transients controlled by the bus master
(1-Wire driver). 1-Wire networks, therefore, are suscep-
tible to noise of various origins. Depending on the phys-
ical size and topology of the network, reflections from
end points and branch points can add up or cancel
each other to some extent. Such reflections are visible
as glitches or ringing on the 1-Wire communication line.
Noise coupled onto the 1-Wire line from external
sources can also result in signal glitching. A glitch dur-
ing the rising edge of a time slot can cause a slave
device to lose synchronization with the master and,
consequently, result in a Search ROM command com-
ing to a dead end or cause a device-specific function
command to abort. For better performance in network
applications, the DS28E01-100 uses a new 1-Wire front-
end, which makes it less sensitive to noise.
The DS28E01-100’s 1-Wire front-end differs from tradi-
tional slave devices in three characteristics.
1) There is additional lowpass filtering in the circuit that
detects the falling edge at the beginning of a time
slot. This reduces the sensitivity to high-frequency
noise. This additional filtering does not apply at over-
drive speed.
2) There is a hysteresis at the low-to-high switching
threshold VTH. If a negative glitch crosses VTH but
does not go below VTH - VHY, it is not recognized
(Figure 13, Case A). The hysteresis is effective at
any 1-Wire speed.
3) There is a time window specified by the rising edge
hold-off time tREH during which glitches are ignored,
even if they extend below the VTH - VHY threshold
(Figure 13, Case B, tGL < tREH). Deep voltage droops
or glitches that appear late after crossing the VTH
threshold and extend beyond the tREH window can-
not be filtered out and are taken as the beginning of a
new time slot (Figure 13, Case C, tGL tREH).
Devices that have the parameters VHY and tREH speci-
fied in their electrical characteristics use the improved
1-Wire front-end.
CRC Generation
The DS28E01-100 uses two different types of CRCs.
One CRC is an 8-bit type that is computed at the factory
and is stored in the most significant byte of the 64-bit
registration number. The bus master can compute a
CRC value from the first 56 bits of the 64-bit registration
number and compare it to the value read from the
DS28E01-100 to determine if the registration number
has been received error-free. The equivalent polynomial
function of this CRC is X8+ X5+ X4+ 1. This 8-bit CRC
is received in the true (noninverted) form.
The other CRC is a 16-bit type, which is used for error
detection with memory and SHA-1 commands. For
details, refer to the full data sheet.
VPUP
VTH VHY
0V
tREH
tGL
tREH
tGL
CASE A CASE CCASE B
Figure 13. Noise Suppression Scheme
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim Integrated 35
TOP VIEW
N.C.
IO
GND
N.C.
N.C.
N.C.
TSOC
+
5
4
6
2
3
1
DS28E01-100
SFN
(6mm x 6mm x 0.9mm)
BOTTOM VIEW
NOTE: THE SFN PACKAGE IS QUALIFIED FOR ELECTRO-MECHANICAL
CONTACT APPLICATIONS ONLY, NOT FOR SOLDERING. FOR MORE
INFORMATION, REFER TO APPLICATION NOTE 4132:
ATTACHMENT
METHODS FOR THE ELECTRO-MECHANICAL SFN PACKAGE
.
12
IO GND
SIDE VIEW
16N.C. N.C.
25IO N.C.
34GND N.C.
TDFN
(3mm x 3mm)
TOP VIEW
DS28E01-100
2801
ymrrF
+
EP
2
3
1
3
2
1
IO
N.C.
GND
TO-92
FRONT VIEWSIDE VIEW
Pin Configurations
USER DIRECTION OF FEED
LEADS FACE UP IN ORIENTATION SHOWN ABOVE.
SFN Package Orientation on Tape and Reel
Package Information
For the latest package outline information and land patterns (footprints), go to www.maximintegrated.com/packages. Note that a
“+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the
drawing pertains to the package regardless of RoHS status.
PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO.
6 TSOC D6+1 21-0382 90-0321
2 SFN G266N+1 21-0390
6 TDFN-EP T633+2 21-0137 90-0058
2 TO-92 Q2+1 21-0249
1Kb Protected 1-Wire EEPROM
with SHA-1 Engine
ABRIDGED DATA SHEET
DS28E01-100
Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied.
Maxim reserves the right to change the circuitry and specifications without notice at any time. The parametric values (min and max limits) shown in the Electrical
Characteristics table are guaranteed. Other parametric values quoted in this data sheet are provided for guidance.
36
Maxim Integrated 160 Rio Robles, San Jose, CA 95134 USA 1-408-601-1000
© 2012 Maxim Integrated Products, Inc. The Maxim logo and Maxim Integrated are trademarks of Maxim Integrated Products, Inc.
Revision History
REVISION
NUMBER
REVISION
DATE DESCRIPTION PAGES
CHANGED
0 4/07 Initial release
1 7/07
In the SFN Pin Configuration, added the package drawing information/weblink and a note
that the SFN package is qualified for electro-mechanical contact applications only, not
for soldering. Added the SFN Package Orientation on Tape-and-Reel section. In the
Ordering Information, added note to contact factory for availability of the UCSP package
16
Removed references to the UCSP package 1, 16
2 3/08
In the SFN Pin Configuration, added reference to Application Note 4132 16
In the Ordering Information, removed the leaded TSOC packages and added the TDFN
package 1
Updated the Pin Description to include all package variants 4
3 6/08
Added the TDFN package to Pin Configurations and Package Information table 16
4 2/09 Created newer template-style data sheet All
Corrected TSOC tape-and-reel ordering part number (deleted “&R”) 1
Updated soldering temperatures 2
5 7/10
Added package codes and land pattern information 35
6 2/12
Added the 2-pin TO-92 package to the Features,Ordering Information,Absolute
Maximum Ratings,Pin Description,Pin Configurations, and Package Information.1, 2, 5, 35
7 3/12 Revised the Electrical Characteristics table notes 1, 4, and 15. 3
8 9/12
Changed Overdrive tREC from 2μs to 5μs minimum and updated overdrive speed
accordingly; deleted the Overdrive tREC specification directly prior to reset pulse;
corrected error in Electrical Characteristics table Note 14.
1–4, 24