MAXIM MAX31826MUA+T

19-6264; Rev 0; 3/12
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
General Description
The MAX31826 digital thermometer provides 12-bit
temperature measurements and communicates over a
1-WireM bus that by definition requires only one data line
(and ground) for communication with a central microcontroller. It has a -55NC to +125NC operating temperature
range and is accurate to Q0.5NC over the -10NC to +85NC
range. In addition, the device can derive power directly
from the data line (“parasite power”), eliminating the
need for an external power supply.
Each device has a unique 64-bit serial code, which
allows multiple devices to function on the same 1-Wire
bus. Therefore, it is simple to use one microcontroller
(the master device) to control many devices distributed
over a large area. The device includes 128 bytes (1Kb)
of EEPROM for storage of system data. The EEPROM
can be locked to permanently prevent any further data
writes. Four location address inputs simplify mapping of
individual devices to specific locations.
Applications
Benefits and Features
SUnique 1-Wire Interface Requires Only One Port
Pin for Communication
SIntegrated Temperature Sensor and EEPROM
Reduce Component Count
Measures Temperatures from -55NC to +125NC
(-67NF to +257NF)
±0.5NC Accuracy from -10NC to +85NC
12-Bit Temperature Resolution (0.0625NC)
1Kb EEPROM Can Be Locked to Prevent Further
Writes
SMultidrop Capability Simplifies Multisensor
Systems
Each Device Has a Unique 64-Bit Serial Code
Stored in On-Board ROM
Four Pin-Programmable Bits to Uniquely
Identify Up to 16 Sensor Locations on a Bus
SCan Be Powered from Data Line (3.0V to 3.7V
Power-Supply Range)
S8-Pin µMAX® Package
Industrial Systems
System Calibration
Ordering Information appears at end of data sheet.
Building Automation
Module Identification
For related parts and recommended products to use with this part,
refer to www.maxim-ic.com/MAX31826.related.
Consumer Equipment
Block Diagram
VPU
4.7kΩ
MEMORY
CONTROL LOGIC
DQ
PARASITEPOWER
CIRCUIT
GND
CPP
VDD
POWERSUPPLY
SENSE
MAX31826
64-BIT ROM
AND
1-Wire PORT
1Kb
EEPROM
SCRATCHPAD 2
16-BIT TEMPERATURE REGISTER
SCRATCHPAD 1
8-BIT CRC GENERATOR
8-BIT CONFIGURATION REGISTER
ADDRESS PIN
INPUT LATCH
AD0 AD1 AD2 AD3
1-Wire and µMAX are registered trademarks of Maxim Integrated Products, Inc.
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For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
ABSOLUTE MAXIMUM RATINGS
Voltage Range on Any Pin Relative to Ground.....-0.5V to +4.5V
Continuous Power Dissipation (TA = +70NC)
FMAX (derate 4.5mW/NC above +70NC)......................362mW
Operating Temperature Range......................... -55NC to +125NC
Storage Temperature Range............................. -55NC to +125NC
Lead Temperature (soldering, 10s).................................+300NC
Soldering Temperature (reflow).......................................+260NC
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.
DC ELECTRICAL CHARACTERISTICS
(TA = -55°C to +125°C, unless otherwise noted.) (Note 1)
PARAMETER
SYMBOL
Supply Voltage
VDD
Pullup Supply Voltage
(Notes 2, 3)
VPU
Thermometer Error (Note 4)
TERR
Input Logic-Low
VIL
MAX
UNITS
Local power (Note 2)
CONDITIONS
+3.0
+3.7
V
Parasite power
+3.0
+3.7
Local power
+3.0
VDD
-10NC to +85NC
-0.5
-55NC to +125NC
-2
+2
-0.3
+0.8
+2.4
lower
of 3.7V
or
(VDD +
0.3V)
+3.0
lower
of 3.7V
or
(VDD +
0.3V)
(Notes 2, 5)
Local power
Input Logic-High (Notes 2, 6)
TYP
Q0.25
VIH
Parasite power
Sink Current
MIN
IL
VI/O = 0.4V (Note 2)
+0.5
4.0
V
NC
V
V
mA
Standby Current
IDDS
(Notes 7, 8)
350
1000
nA
Active Current
IDD
VDD = 3.7V (Note 9)
650
1200
FA
800
1500
FA
4
7.8
ms
+1
FA
Active Current with
Communication
POR Time
tPOR
Local or parasite power
Input Leakage Current
(AD0–AD3 Pins)
DQ Input Current
-1
IDQ
(Note 10)
5
FA
����������������������������������������������������������������� Maxim Integrated Products 2
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
AC ELECTRICAL CHARACTERISTICS
(VDD = 3.0V to 3.7V, TA = -55°C to +125°C, unless otherwise noted.) (Note 1)
MAX
UNITS
Temperature Conversion Time
PARAMETER
tCONV
12-bit resolution
150
ms
Time to Strong Pullup On
tSPON
Start Convert T command, or Copy
Scratchpad 2 command issued
10
Fs
Time Slot
tSLOT
(Note 11)
120
Fs
Recovery Time
SYMBOL
CONDITIONS
MIN
TYP
60
tREC
(Note 11)
1
Write-Zero Low Time
tLOW0
(Note 11)
60
120
Fs
Write-One Low Time
tLOW1
(Note 11)
1
15
Fs
Read Data Valid
tRDV
(Note 11)
15
Fs
Reset Time High
tRSTH
(Note 11)
480
tRSTL
Reset Time Low
Fs
Fs
(Notes 11, 12)
480
Presence-Detect High
tPDHIGH
(Note 11)
15
60
Fs
Presence-Detect Low
tPDLOW
(Note 11)
60
240
Fs
DQ Capacitance
CIN/OUT
25
pF
AD0–AD3 Capacitance
CIN_AD
50
pF
Fs
NONVOLATILE MEMORY
EEPROM Write/Erase Cycles
NEEWR
EEPROM Data Retention
tEEDR
EEPROM Write Time
tWR
At TA = +25°C
200k
At TA = +85°C (worst case)
50k
At TA = +85°C (worst case)
40
Years
20
25
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: All voltages are referenced to ground.
Note 3: The pullup supply voltage specification assumes that the pullup device is ideal, and therefore the high level of the pullup
is equal to VPU. To meet the device’s VIH specification, the actual supply rail for the strong pullup transistor must include
margin for the voltage drop across the transistor when it is turned on; thus: VPU_ACTUAL = VPU_IDEAL + VTRANSISTOR.
Note 4: Guaranteed by design. These limits represent a three sigma distribution.
Note 5: To guarantee a presence pulse under low-voltage parasite-power conditions, VILMAX might need to be reduced to as low
as 0.5V.
Note 6: Logic-high voltages are specified at a 1mA source current.
Note 7: Standby current specified up to TA = +70NC. Standby current typically is 3FA at TA = +125NC.
Note 8: To minimize IDDS, DQ should be within the following ranges: VGND P VDQ P VGND + 0.3V or VDD - 0.3V P VDQ P VDD.
Note 9: Active current refers to supply current during active temperature conversions or EEPROM writes.
Note 10:DQ line is high (high-impedance state).
Note 11:See the 1-Wire Timing Diagrams.
Note 12:Under parasite power, if tRSTL > 960Fs, a power-on reset (POR) can occur.
����������������������������������������������������������������� Maxim Integrated Products 3
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
1-Wire Timing Diagrams
1-Wire WRITE-ZERO TIME SLOT
START OF NEXT CYCLE
tSLOT
tREC
tLOW0
1-Wire READ-ZERO TIME SLOT
tSLOT
START OF NEXT CYCLE
tREC
tRDV
1-Wire RESET PULSE
RESET PULSE FROM HOST
tRSTL
tRSTH
1-Wire PRESENCE DETECT
PRESENCE DETECT
tPDHIGH
tPDLOW
����������������������������������������������������������������� Maxim Integrated Products 4
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
Typical Operating Characteristics
(VCC = 3.3V, TA = -40°C, unless otherwise noted.)
MAX31826 TYPICAL ERROR CURVE
THERMOMETER ERROR (˚C)
0.4
+3s ERROR
0.3
0.2
0.1
MAX31826 toc01
0.5
MEAN ERROR
0
-0.1
-0.2
-0.3
-3s ERROR
-0.4
-0.5
-40 -30 -20 -10 0 10 20 30 40 50 60 70 80 90
TEMPERATURE (˚C)
Pin Configuration
Pin Description
PIN
TOP VIEW
NAME
FUNCTION
VDD
Optional VDD. VDD must be grounded for
operation in parasite-power mode.
2
DQ
Data Input/Output. Open-drain 1-Wire
interface pin. Also provides power to
the device when used in parasite-power
mode (see the Parasite Power section.)
3
N.C.
No Connection. Not internally connected.
4
GND
Ground
5
AD0
Location Address Input (Least Significant
Bit)
6
AD1
Location Address Input
7
AD2
Location Address Input
8
AD3
Location Address Input (Most Significant
Bit)
1
VDD
1
DQ
2
N.C.
3
GND
4
+
MAX31826
µMAX
8
AD3
7
AD2
6
AD1
5
AD0
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MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
Detailed Description
which then supplies power to the device when the bus is
low. This method of deriving power from the 1-Wire bus
is referred to as parasite power. Alternatively, a power
supply on VDD can also power the device.
The MAX31826 digital thermometer provides 12-bit
temperature measurements and communicates over a
1-WireM bus that by definition requires only one data line
(and ground) for communication with a central microcontroller. The data line requires a weak pullup resistor since
all devices are linked to the bus through a three-state
or open-drain port (i.e., the MAX31826’s DQ pin). Four
location address inputs simplify mapping of individual
devices to specific locations.
Measuring Temperature
The device’s core functionality is its direct-to-digital temperature sensor. The resolution of the temperature sensor
is 12 bits, corresponding to a least significant bit value
of 0.0625NC. The device powers up in a low-power idle
state. To initiate a temperature measurement, the master
must issue a Convert T command. Following the conversion, the resulting thermal data is stored in the 12-bit temperature register in the Scratchpad 1 memory and the
device returns to its idle state. If the device is powered by
an external supply, the master can issue read time slots
(see the 1-Wire Bus System section) after the Convert T
command, and the device responds by transmitting 0
while the temperature conversion is in progress and 1
when the conversion is done. If the device is powered
with parasite power, this notification technique cannot be
used because the bus must be pulled high by a strong
pullup during the entire temperature conversion. The
bus requirements for parasite power are explained in the
Powering the MAX31826 section.
Each device has a unique 64-bit serial code, allowing
multiple devices to function on the same 1-Wire bus.
Therefore, it is simple to use one microcontroller to control many devices distributed over a large area. In this
bus system, the microcontroller identifies and addresses
devices on the bus using each device’s unique 64-bit
code. Because each device has a unique code, the
number of devices that can be addressed on one bus
is virtually unlimited. The 1-Wire bus protocol, including
detailed explanations of the commands and time slots, is
described in the 1-Wire Bus System section.
The Scratchpad 1 memory contains the 2-byte temperature register that stores the digital output from the
temperature sensor. An additional 128 bytes (1Kb) of
general-purpose EEPROM is included for storage of system data. The EEPROM can be locked to permanently
prevent any further data writes.
The temperature data (in NC) is stored as a 16-bit signextended two’s complement number in the temperature
register (see the Temperature Register Format). The sign
bits (S) indicate if the temperature is positive or negative;
for positive numbers S = 0 and for negative numbers
S = 1. Table 1 gives examples of digital output data and
the corresponding temperature readings.
The device can also operate without an external power
supply. Power is instead supplied through the 1-Wire
pullup resistor through DQ when the bus is high. The
high bus signal also charges an internal capacitor (CPP),
Temperature Register Format
MSB
LSB
BIT 15
BIT 14
BIT 13
BIT 12
BIT 11
BIT 10
BIT 9
BIT 8
S
S
S
S
S
26
25
24
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 0
23
22
21
20
2-1
2-2
2-3
2-4
1-Wire is a registered trademark of Maxim Integrated Products, Inc.
����������������������������������������������������������������� Maxim Integrated Products 6
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
Table 1. Temperature/Data Relationship
TEMPERATURE (NC)
DIGITAL OUTPUT (BINARY)
DIGITAL OUTPUT (HEX)
+125
0000 0111 1101 0000
07D0h
+85
0000 0101 0101 0000
0550h
+25.0625
0000 0001 1001 0001
0191h
+10.125
0000 0000 1010 0010
00A2h
+0.5
0000 0000 0000 1000
0008h
0
0000 0000 0000 0000
0000h
-0.5
1111 1111 1111 1000
FFF8h
-10.125
1111 1111 0101 1110
FF5Eh
-25.0625
1111 1110 0110 1111
FE6Fh
-55
1111 1100 1001 0000
FC90h
Powering the MAX31826
The MAX31826 can be powered by an external supply
on the VDD pin, or it can operate in “parasite power”
mode, which allows the device to function without a local
external supply. Parasite power is useful for applications
that require remote temperature sensing or those that
are very space-constrained. Figure 1 shows the device’s
parasite-power control circuitry, which “steals” power
from the 1-Wire bus through DQ when the bus is high.
The stolen charge powers the device while the bus is
high, and some of the charge is stored on the parasitepower capacitor (CPP) to provide power when the bus is
low. When the device is used in parasite-power mode,
VDD must be connected to ground.
In parasite-power mode, the 1-Wire bus and CPP can provide sufficient current to the device for most operations
as long as the specified timing and voltage requirements
are met (see the DC Electrical Characteristics and the
AC Electrical Characteristics tables). However, when the
device is performing temperature conversions or copying data from the Scratchpad 2 memory to EEPROM, the
operating current can be as high as 1.5mA. This current
can cause an unacceptable voltage drop across the
weak 1-Wire pullup resistor and is more current than can
be supplied by CPP. To ensure that the device has sufficient supply current, it is necessary to provide a strong
pullup on the 1-Wire bus whenever temperature conversions are taking place or when data is being copied from
the Scratchpad 2 to EEPROM. This can be accomplished
by using a MOSFET to pull the bus directly to the rail as
shown in Figure 1. The 1-Wire bus must be switched to
the strong pullup within 10Fs (max) after a Convert T or
Copy Scratchpad 2 command is issued, and the bus
must be held high by the pullup for the duration of the
conversion (tCONV) or the duration of the EEPROM write
(tWR). No other activity can take place on the 1-Wire bus
while the pullup is enabled.
The device can also be powered by the conventional
method of connecting an external power supply to VDD,
as shown in Figure 2. The advantage of this method is
that the MOSFET pullup is not required, and the 1-Wire
bus is free to carry other traffic during the temperature
conversion period or EEPROM write time.
The use of parasite power is not recommended for temperatures above 100NC because the device may not be
able to sustain communications due to the higher leakage currents that can exist at these temperatures. For
applications in which such temperatures are likely, it is
strongly recommended that the device be powered by
an external power supply.
In some situations the bus master might not know whether
the devices on the bus are parasite powered or powered
by external supplies. The master needs this information
to determine if the strong bus pullup should be used during temperature conversions. To get this information, the
master can issue a Skip ROM command, followed by a
Read Power Supply command, followed by a read time
slot. During the read time slot, parasite-powered devices
pull the bus low, and externally powered devices let the
bus remain high. If the bus is pulled low, the master
knows that it must supply the strong pullup on the 1-Wire
bus during temperature conversions or EEPROM writes.
����������������������������������������������������������������� Maxim Integrated Products 7
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
VPU
MAX31826
GND
VPU
µP
DQ
VDD
4.7kΩ
1-Wire BUS
TO OTHER 1-Wire DEVICES
Figure 1. Supplying the Parasite-Powered MAX31826 During Temperature Conversions
MAX31826
GND
VPU
µP
DQ
VDD (EXTERNAL SUPPLY)
VDD
4.7kΩ
1-Wire BUS
TO OTHER 1-Wire DEVICES
Figure 2. Powering the MAX31826 with an External Supply
MSb
LSb
8-BIT
CRC CODE
MSb
8-BIT FAMILY CODE
(3Bh)
48-BIT SERIAL NUMBER
LSb MSb
LSb MSb
LSb
Figure 3. 64-Bit ROM Code
64-Bit ROM Code
Each device contains a unique 64-bit code stored in ROM
(Figure 3). The least significant 8 bits of the ROM code
contain the device’s 1-Wire family code, 3Bh. The next 48
bits contain a unique serial number. The most significant
8 bits contain a cyclic redundancy check (CRC) byte that
is calculated from the first 56 bits of the ROM code. See
the CRC Generation section for a detailed explanation
of the CRC bits. The 64-bit ROM code and associated
ROM function control logic allow the device to operate as
a 1-Wire device using the protocol detailed in the 1-Wire
Bus System section.
����������������������������������������������������������������� Maxim Integrated Products 8
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
SCRATCHPAD 1 (POWER-UP STATE
SHOWN IN PARENTHESES)
BYTE 0
TEMPERATURE REGISTER LSB (50h)
BYTE 1
TEMPERATURE REGISTER MSB (05h)
BYTE 2
RESERVED (FFh)
BYTE 3
RESERVED (FFh)
BYTE 4
CONFIGURATION REGISTER*
EEPROM
BYTE 5
RESERVED (FFh)
BYTES 00h−07h
BYTE 6
RESERVED (FFh)
BYTES 08h−0Fh
BYTE 7
RESERVED (FFh)
BYTES 10h−17h
BYTE 8
CRC
...
BYTES 70h−77h
SCRATCHPAD 2 (EE SCRATCHPAD)
BYTE 0
BYTE 0
BYTE 1
BYTE 1
...
...
BYTE 7
BYTE 7
BYTES 78h−7Fh
*THE LOWER 4 BITS (AD[3:0]) OF THE CONFIGURATION REGISTER ARE HARDWIRED THROUGH AD0–AD3.
Figure 4. Memory Map
Memory
The device’s memory is organized as shown in Figure 4. The
memory consists of two SRAM scratchpads (Scratchpad 1
and Scratchpad 2) and 1Kb of EEPROM, which can serve
as general-purpose nonvolatile memory until locked.
All memory commands are described in detail in the
MAX31826 Function Commands section.
Byte 0 and byte 1 of Scratchpad 1 contain the least
significant byte and the most significant byte of the temperature register, respectively. Byte 4 contains the configuration information. Bytes 2, 3, 5, 6, and 7 are reserved
for internal use by the device and cannot be overwritten;
these bytes return all ones when read.
Byte 8 of Scratchpad 1 is read-only and contains the
CRC code for bytes 0–7 of the scratchpad. The device
generates this CRC using the method described in the
CRC Generation section.
Scratchpad 2 (the EE scratchpad) is used for writing to
the EEPROM. Scratchpad 2 consists of 8 bytes; write
data to Scratchpad 2 before copying it to the EEPROM.
Configuration Register
Byte 4 of Scratchpad 1 contains the configuration register, which is organized as shown in Configuration
Register Format. The configuration register allows the
user to read the programmed value of the address pins.
The AD[3:0] bits report the pin-programmed location
information. Pins connected to DQ (in parasite power)
or VDD (when externally powered) are reported with
logic 1, and pins connected to GND are reported as
logic 0. Pins connected to DQ (in parasite power), VDD
(when externally powered), or GND through a resistor are
valid logic 1s or logic 0s if the resistor is less than 10kI.
Unconnected or high-impedance ( > 10kI) connections
are indeterminate. Bits [7:4] are reserved for internal use
and cannot be overwritten; they return a 1 when read.
Configuration Register Format
BIT 7
BIT 6
BIT 5
BIT 4
BIT 3
BIT 2
BIT 1
BIT 0
—
—
—
—
AD3
AD2
AD1
AD0
Note: Bits [3:0] are programmed through the four location programming address pins, AD3–AD0. Reading the configuration register
provides location information on up to 16 individual devices.
����������������������������������������������������������������� Maxim Integrated Products 9
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
CRC Generation
shift register. After shifting in the 56th bit from the ROM
or the most significant bit of byte 7 from the Scratchpad 1
or byte 10 from Scratchpad 2, the polynomial generator
contains the recalculated CRC. Next, the 8-bit ROM code
or scratchpad CRC from the device must be shifted into
the circuit. At this point, if the recalculated CRC was
correct, the shift register contains all zeros. Additional
information about the Maxim 1-Wire CRC is available in
Application Note 27: Understanding and Using Cyclic
Redundancy Checks with Maxim iButton® Products.
CRC bytes are provided as part of the device’s 64-bit
ROM code, in the 9th byte of Scratchpad 1, and for
Scratchpad 2 values. The ROM code CRC is calculated
from the first 56 bits of the ROM code and is contained in
the most significant byte of the ROM. The two scratchpad
CRCs are calculated from the data in each scratchpad,
and therefore changes when the data in it associated
scratchpad changes. The CRCs provide the bus master with a method of data validation when data is read
from the device. To verify that data has been read correctly, the bus master must recalculate the CRC from
the received data and then compare this value to either
the ROM code CRC (for ROM reads) or to the scratchpads’ CRC (for scratchpad reads). If the calculated CRC
matches the read CRC, the data has been received
error-free. The comparison of CRC values and the decision to continue with an operation are determined entirely
by the bus master. There is no circuitry inside the device
that prevents a command sequence from proceeding if
the device CRC (ROM or scratchpad) does not match the
value generated by the bus master.
1-Wire Bus System
The 1-Wire bus system uses a single bus master to control one or more slave devices. The MAX31826 is always
a slave. When there is only one slave on the bus, the
system is referred to as a single-drop system; the system
is multidrop if there are multiple slaves on the bus. All
data and commands are transmitted least significant bit
first over the 1-Wire bus.
The following discussion of the 1-Wire bus system is
broken down into three topics: hardware configuration,
transaction sequence, and 1-Wire signaling (signal types
and timing).
The equivalent polynomial function of the CRC (ROM or
scratchpad) is:
Hardware Configuration
The 1-Wire bus has by definition only a single data line.
Each device (master or slave) interfaces to the data line
by using an open-drain or three-state port. This allows
each device to “release” the data line when the device
is not transmitting data so the bus is available for use by
another device. The device’s 1-Wire port (DQ) is open
drain with an internal circuit equivalent to that shown in
Figure 6.
CRC = X8 + X5 + X4 + 1
The bus master can recalculate the CRC and compare it
to the CRC values from the device using the polynomial
generator shown in Figure 5. This circuit consists of a
shift register and XOR gates, and the shift register bits
are initialized to 0. Starting with the least significant bit
of the ROM code or the least significant bit of byte 0 in
the scratchpad, one bit at a time should shifted into the
POLYNOMIAL = X8 + X5 + X4 + 1
1ST
STAGE
X0
2ND
STAGE
X1
3RD
STAGE
X2
4TH
STAGE
X3
5TH
STAGE
X4
6TH
STAGE
X5
7TH
STAGE
X6
8TH
STAGE
X7
X8
INPUT DATA
Figure 5. CRC Generator
iButton is a registered trademark of Maxim Integrated Products, Inc.
���������������������������������������������������������������� Maxim Integrated Products 10
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
VPU
BUS MASTER
MAX31826 1-Wire PORT
4.7kΩ
DQ
Rx
Tx
Rx = RECEIVE
Tx = TRANSMIT
OPEN-DRAIN
PORT PIN
Rx
5µA
TYP
Tx
100Ω MOSFET
Figure 6. Hardware Configuration
The 1-Wire bus requires an external pullup resistor of
approximately 5kI; thus, the idle state for the 1-Wire bus
is high. If for any reason a transaction needs to be suspended, the bus must be left in the idle state if the transaction is to resume. Infinite recovery time can occur between
bits so long as the 1-Wire bus is in the inactive (high) state
during the recovery period. If the bus is held low for more
than 480Fs, all components on the bus are reset.
Transaction Sequence
The transaction sequence for accessing the device is as
follows:
1) Step 1: Initialization
2)Step 2: ROM Command (followed by any required
data exchange)
3)Step 3: MAX31826 Function Command (followed by
any required data exchange)
It is very important to follow this sequence every time the
device is accessed, as the device does not respond if
any steps in the sequence are missing or out of order.
An exception to this rule is the Search ROM command.
After issuing this ROM command, the master must return
to step 1 in the sequence.
Initialization
All transactions on the 1-Wire bus begin with an initialization 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 slave devices
(such as the MAX31826) are on the bus and are ready
to operate. Timing for the reset and presence pulses is
detailed in the 1-Wire Signaling section.
ROM Commands
After the bus master has detected a presence pulse, it
can issue a ROM command. These commands operate
on the unique 64-bit ROM codes of each slave device
and allow the master to single out a specific device if
many are present on the 1-Wire bus. These commands
also allow the master to determine how many and what
types of devices are present on the bus. There are four
ROM commands, and each command is 8 bits long. The
master device must issue an appropriate ROM command
before issuing a MAX31826 function command. Figure 7
shows a flowchart for operation of the ROM commands.
Search ROM [F0h]
When a system is initially powered up, the master must
identify the ROM codes of all slave devices on the
bus, which allows the master to determine the number
of slaves and their device types. The master learns
the ROM codes through a process of elimination that
requires the master to perform a Search ROM cycle (i.e.,
Search ROM command followed by data exchange) as
many times as necessary to identify all the slave devices.
If there is only one slave on the bus, the simpler Read
ROM command can be used in place of the Search ROM
process. For a detailed explanation of the Search ROM
command procedure, refer to Application Note 937: Book
of iButton® Standards. After every Search ROM cycle,
the bus master must return to step 1 (initialization) in the
transaction sequence.
���������������������������������������������������������������� Maxim Integrated Products 11
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
Read ROM [33h]
This command can be used only when there is one slave
on the bus. It allows the bus master to read the slave’s
64-bit ROM code without using the Search ROM command procedure. If this command is used when there is
more than one slave present on the bus, a data collision
occurs when all the slaves attempt to respond at the
same time.
Match ROM [55h]
The Match ROM command followed by a 64-bit ROM
code sequence allows the bus master to address a
specific slave device on a multidrop or single-drop bus.
Only the slave that exactly matches the 64-bit ROM code
sequence responds to the function command issued by
the master; all other slaves on the bus wait for a reset
pulse.
Skip ROM [CCh]
The master can use this command to address all devices
on the bus simultaneously without sending out any ROM
code information. For example, the master can make all
devices on the bus perform simultaneous temperature
conversions by issuing a Skip ROM command followed
by a Convert T function command.
Note that the Read Scratchpad 1 command can follow the
Skip ROM command only if there is a single slave device
on the bus. In this case, time is saved by allowing the
master to read from the slave without sending the device’s
64-bit ROM code. A Skip ROM command followed by a
Read Scratchpad 1 command causes a data collision on
the bus if there is more than one slave because multiple
devices attempt to transmit data simultaneously.
MAX31826 Function Commands
After the bus master has used a ROM command to
address the MAX31826 with which it wishes to communicate, the master can issue one of the MAX31826 function
commands. These commands allow the master to read
from the device’s scratchpad memories, initiate temperature conversions, and determine the power-supply mode.
The MAX31826 function commands are summarized in
Table 2 and illustrated by the flowchart in Figure 8.
Convert T [44h]
This command initiates a single temperature conversion. Following the conversion, the resulting thermal
data is stored in the 2-byte temperature register in the
Scratchpad 1 memory and the device returns to its low-
power idle state. If the device is being used in parasitepower mode, within 10Fs (max) after this command is
issued, the master must enable a strong pullup on the
1-Wire bus for the duration of the conversion (tCONV) as
described in the Powering the MAX31826 section. If the
device is powered by an external supply, the master can
issue read time slots after the Convert T command, and
the device responds by transmitting 0 while the temperature conversion is in progress and 1 when the conversion
is done. In parasite-power mode, this notification technique cannot be used because the bus is pulled high by
the strong pullup during the conversion.
Read Scratchpad 1 [BEh]
This command allows the master to read the contents of
Scratchpad 1. The data transfer starts with the least significant bit of byte 0 and continues through the scratchpad until the 9th byte (byte 8, CRC) is read. The master
can issue a reset to terminate reading at any time if only
part of the scratchpad data is needed. The CRC is computed while data is read from bytes 0–7, and is shifted
out as byte 8.
Read Scratchpad 2 [AAh]
This command allows the master to read the contents of
Scratchpad 2. The command must be issued followed
by the start address to initiate a data transfer. The data
transfer always starts with the least significant bit of the
byte pointed to by the address bits [2:0], and the data
transfer continues through the scratchpad until 8 bytes
have been read. The [2:0] address bits wrap when
address [2:0] = 0x7 to [2:0] = 0x0. The master can issue
a reset to terminate reading at any time if only part of
the scratchpad data is needed. The CRC is computed
dynamically and includes the command, address, and all
the data bytes 0–7 for a total of 10 bytes. The computed
CRC is shifted out at the end of data byte 7. Because
the CRC contains the start address, the CRC value computed can vary with different start addresses.
Note: After the Read Scratchpad 2 command, an address
of 00h returns the scratchpad contents correctly. This is
true regardless of the address sent during a preceding
Write Scratchpad 2 command transaction. However, the
address used during a preceding Write Scratchpad 2
command is necessary here to ensure that future Copy
Scratchpad 2 commands are copied to the correct row.
If 00h is used instead, a future Copy Scratchpad 2 command copies the contents to address 00h as opposed to
the row addressed by the Write Scratchpad 2 command.
���������������������������������������������������������������� Maxim Integrated Products 12
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
Write Scratchpad 2 [0Fh]
This command allows the master to write 8 bytes to the EE
scratchpad. After issuing the Write Scratchpad 2 command,
the master must first provide the 1-byte address for the first
byte of the target EEPROM page, followed by the 8 bytes of
data to be written to the scratchpad for the EEPROM. The
three lower bits [2:0] of the target address byte must be set
to 0. The device automatically increments the address after
every byte it receives. The device computes the CRC of
the received data, including the command (0Fh), the target
address byte, and the 8 data bytes. After having received
a data byte for address 07h, the device shifts out (back to
the master) the computed CRC of the 10-byte stream just
received, allowing the master to verify that the data was
received correctly. Note that, because the device switches
direction from receive to transmit, writes to Scratchpad 2
must start with address bits [2:0] set to 0 and proceed from
0h–7h and not beyond.
Copy Scratchpad 2 [55h]
This command allows the master to copy the contents of
an 8-byte page of data from Scratchpad 2 to the 1Kb user
memory. The command is followed by the byte A5h. After
the master writes A5h, the device enters the programming
cycle, saving the data to nonvolatile memory, and does not
respond to further communication for the duration of the
EEPROM write time (tWR). During nonparasitic-power mode,
communication with other devices can continue. If the
device is being used in parasite-power mode, within 10Fs
(max) after A5h is issued, the master must enable a strong
pullup on the 1-Wire bus for the duration of the EEPROM
write time (tWR) as described in the Powering the MAX31826
section. No other activity can take place on the 1-Wire bus
while the strong pullup is enabled.
Changing only 1 byte of EEPROM is not natively supported
on the device. To achieve this, the master must first read the
8-byte block that contains the single byte to be changed,
and the three lower bits [2:0] of the target address byte
must be 0. The master must then modify the single byte
and write back the 8 bytes with Write Scratchpad 2 and the
same target address. Finally, the master must issue a Copy
Scratchpad 2 command.
Note: The Copy Scratchpad 2 command uses the more
recent of the two 8-bit addresses provided by either the
Write Scratchpad 2 or Read Scratchpad 2 commands as
the EEPROM destination address. The recommended procedure for writing to EEPROM starting at address 08h is as
follows:
2) Read Scratchpad 2 (address = 08h, 8 data bytes). This
reads the data correctly as expected.
3) Copy Scratchpad 2 (0xA5).
4) Data is copied to row 1, which is the correct destination
based on the Write Scratchpad 2 address.
Read Memory [F0h]
This command allows the master to read the contents of the
1Kb memory. The command is followed by the address of
the first byte to be read (00h–7Fh). The data transfer starts
with the least significant bit of the first byte and continues
through 7Fh. The master can issue a reset to terminate reading at any time.
Read Power Supply [B4h]
The master device issues this command followed by a read
time slot to determine if any devices on the bus are using
parasite power. During the read time slot, parasite-powered
devices pull the bus low, and externally powered devices
do not pull the bus low. See the Powering the MAX31826
section for more information.
Lock Low Memory and Lock High Memory
The Lock Low Memory and Lock High Memory routines
each lock the contents of eight pages of memory.
Lock Low Memory (bytes 00h–3Fh) as follows:
1) Initialize communication by issuing a reset and a ROM
command.
2) Send Write Scratchpad 2 command.
3) Send address 80h as the target address to be written.
4) Send data 55h.
5) Initialize and send Copy Scratchpad 2 command.
6) Issue write token A5h and wait tWR.
Locations 00–3Fh are now locked. Also, location 80h is
locked with value 55h. Location 80h cannot be changed to
alter the lock status of 00h–3Fh.
Lock High Memory (bytes 40h–7Fh) as follows:
1) Initialize communication by issuing a reset and a ROM
command.
2) Send Write Scratchpad 2 command.
3) Send address 81h as the target address to be written.
4) Send data 55h.
5) Initialize and send Copy Scratchpad 2 command.
6) Issue write token A5h and wait tWR.
1) Write Scratchpad 2 (address = 08h, 8 data bytes).
���������������������������������������������������������������� Maxim Integrated Products 13
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
Table 2. MAX31826 Function Command Set
COMMAND
DESCRIPTION
Convert T
(Note 1)
PROTOCOL
1-Wire BUS ACTIVITY AFTER COMMAND IS
ISSUED
Initiates temperature conversion.
44h
The device transmits conversion status to master
(not applicable for parasite-powered devices).
Read Scratchpad 1
(Note 2)
Reads the 9-byte scratchpad
including the CRC byte.
BEh
The device transmits up to 9 data bytes to master.
The 9th byte is the CRC byte.
Read Scratchpad 2
(Note 2)
Reads the 9-byte EE scratchpad
including the CRC byte.
AAh
The master transmits the start address. The device
transmits up to 9 data bytes to the master. The 9th
byte is the CRC byte.
Write Scratchpad 2
(Note 2)
Writes to the 8-byte EE
scratchpad.
0Fh
The master transmits the address of first byte in the
target page, and then transmits 8 data bytes. The
device then returns the CRC byte calculated from
the 10 bytes just transmitted.
55h
The master transmits token A5h. The device enters
EEPROM write mode, during which communication
is not allowed in parasitic-power mode.
Additionally, a strong pullup is also required during
parasitic-power mode.
Reads data in the 1Kb user
memory.
F0h
The master transmits the address of first byte to be
read. The device then transmits data starting with
first byte until reaching the end of the available
addresses or until the master issues a reset.
Read Power Supply
Signals the device’s power-supply
mode to the master.
B4h
The device transmits supply status to the master.
Lock Low Memory
Prevents further changes to the
lower eight pages of user memory.
—
Write 55h to byte 80h of Scratchpad 2. Copy
Scratchpad 2 to EEPROM.
Lock High Memory
Prevents further changes to the
upper eight pages of user memory.
—
Write 55h to byte 81h of Scratchpad 2. Copy
Scratchpad 2 to EEPROM.
Copy Scratchpad 2
Read Memory
(Note 2)
Writes the contents of the 8-byte
Scratchpad 2 to the EEPROM.
Note 1: For parasite-powered devices, the master must enable a strong pullup on the 1-Wire bus during temperature conversions
and copies from the Scratchpad 2 to EEPROM. No other bus activity can take place during this time.
Note 2: The master can interrupt the transmission of data at any time by issuing a reset.
���������������������������������������������������������������� Maxim Integrated Products 14
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
MASTER Tx
RESET PULSE
INITIALIZATION
SEQUENCE
MAX31826 Tx
PRESENCE PULSE
MASTER Tx
ROM COMMAND
33h
READ
ROM?
Y
N
55h
MATCH
ROM?
F0h
SEARCH
ROM?
N
Y
Y
BIT 0
MATCH?
MAX31826 Tx
CRC BYTE
N
Y
MAX31826 Tx BIT 0
MASTER Tx BIT 0
N
N
BIT 0
MATCH?
Y
MAX31826 Tx
SERIAL NUMBER
6 BYTES
CCh
SKIP
ROM?
MAX31826 Tx BIT 0
MASTER Tx
BIT 0
MAX31826 Tx
FAMILY CODE
1 BYTE
N
Y
MAX31826 Tx BIT 1
MASTER Tx
BIT 1
BIT 1
MATCH?
MAX31826 Tx BIT 1
MASTER Tx BIT 1
N
N
BIT 1
MATCH?
Y
Y
MAX31826 Tx BIT 63
MASTER Tx
BIT 63
BIT 63
MATCH?
MAX31826 Tx BIT 63
MASTER Tx BIT 63
N
N
BIT 63
MATCH?
Y
Y
MASTER Tx
FUNCTION COMMAND
Figure 7. ROM Commands Flowchart
���������������������������������������������������������������� Maxim Integrated Products 15
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
44h
CONVERT T?
MASTER Tx
FUNCTION COMMAND
55h
COPY
SCRATCHPAD 2?
N
MASTER Tx
TOKEN A5h
Y
N
N
MAX31826 CONVERTS
TEMPERATURE
N
Y
MASTER Rx
“0s”
MASTER Rx
“1s”
B4h
READ
POWER SUPPLY?
MASTER DISABLES
STRONG PULLUP
N
N
MASTER Rx
“1s”
PARASITE
POWER?
N
Y
DATA COPIED FROM
SCRATCHPAD 2 TO EEPROM
AAh
READ
SCRATCHPAD 2?
MASTER Rx DATA BYTE
FROM SCRATCHPAD 1
MASTER Tx
RESET?
Y
MASTER Tx
RESET?
MASTER Tx 8 DATA
BYTES
Y
MASTER Rx
SCRATCHPAD 1 CRC BYTE
Y
MASTER Rx
CRC BYTE
N
N
HAVE 8 BYTES
BEEN READ?
0Fh
WRITE
SCRATCHPAD 2?
MASTER Tx EEPROM
PAGE ADDRESS
MASTER Rx DATA BYTE
FROM SCRATCHPAD 2
Y
MASTER Tx
RESET?
Y
MASTER Tx
START ADDRESS
N
N
N
Y
Y
MASTER Rx
“0s”
MASTER Rx DATA BYTE
FROM EEPROM
MASTER DISABLES
STRONG PULLUP
BEh
READ
SCRATCHPAD 1?
Y
MASTER Tx
START ADDRESS
Y
MASTER ENABLES
STRONG PULLUP ON DQ
DATA COPIED FROM
SCRATCHPAD 2 TO EEPROM
N
Y
PARASITE
POWER?
MASTER ENABLES
STRONG PULLUP ON DQ
DEVICE
CONVERTING
TEMPERATURE?
N
Y
PARASITE
POWER?
MAX31826 BEGINS
CONVERSION
F0h
READ
MEMORY?
N
N
HAVE 8 BYTES
BEEN READ?
Y
MASTER Rx
SCRATCHPAD 2 CRC BYTE
RETURN TO INITIALIZATION SEQUENCE
FOR NEXT TRANSACTION
Figure 8. MAX31826 Function Commands Flowchart
���������������������������������������������������������������� Maxim Integrated Products 16
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
SEARCH ALL
ROM IDs ON BUS
AND
STORE ROM IDs
(F0h COMMAND)
INCREMENT COUNTER
N=N+1
N > NMAX?
N
BUILDING CROSS-REFERENCE TABLE
USING ROM IDs AND 4-BIT ADDRESSES
Y
DONE
NMAX IS THE NUMBER
OF ROM IDs FOUND
MASTER Tx
NEXT ROM ID
READ SCRATCHPAD 1
(USE AD3−AD0 FROM
CONFIG REGISTER)
MATCH ROM ID TO
ADDRESS AND ADD TO
CROSS-REFERENCE
TABLE
CROSS-REFERENCE TABLE
ROM ID
ROM ID(0)
ROM ID(1)
ROM ID(2)
ROM ID(3)
AD3−AD0
0000
0001
0010
0011
ROM ID(12)
ROM ID(13)
ROM ID(14)
ROM ID(15)
1100
1101
1110
1111
NOTE: TEMPERATURE SENSORS ARE ADDRESSED
BY ROM ID, NOT BY BINARY ADDRESS.
Figure 9. Building a Cross-Reference Table
Locations 40h–7Fh are now locked. Also, location 81h is
locked with value 55h. Location 81h cannot be changed to
alter the lock status of 40h–7Fh.
Building a Cross-Reference Table
The procedure in Figure 9 uses the Search ROM command to find all MAX31826s on the 1-Wire bus (16
maximum) and then reads each configuration register to
match the ROM IDs to the hardwired addresses.
1-Wire Signaling
The device uses a strict 1-Wire communication protocol
to ensure data integrity. Several signal types are defined
by this protocol: reset pulse, presence pulse, write-zero,
write-one, read-zero, and read-one. The bus master initiates all these signals except the presence pulse.
Initialization Procedure:
Reset and Presence Pulses
All communication with the device begins with an initialization sequence that consists of a reset pulse from the
master followed by a presence pulse from the device.
This is illustrated in Figure 10. When the device sends the
presence pulse in response to the reset, it is indicating
to the master that it is on the bus and ready to operate.
During the initialization sequence, the bus master transmits (Tx) the reset pulse by pulling the 1-Wire bus low for
480Fs (min). The bus master then releases the bus and
goes into receive mode (Rx). When the bus is released,
the 5kI pullup resistor pulls the 1-Wire bus high. When
the device detects this rising edge, it waits 15Fs to 60Fs
and then transmits a presence pulse by pulling the
1-Wire bus low for 60Fs to 240Fs.
���������������������������������������������������������������� Maxim Integrated Products 17
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
MASTER Tx RESET PULSE
480µs MINIMUM
MAX31826 WAITS
15µs TO 60µs
VPU
MASTER Rx
480µs MINIMUM
MAX31826 Tx PRESENCE PULSE
60µs TO 240µs
1-Wire BUS
GND
BUS MASTER PULLING LOW
MAX31826 PULLING LOW
RESISTOR PULLUP
Figure 10. Initialization Timing
Read/Write Time Slots
The bus master writes data to the device during write
time slots and reads data from the device during read
time slots. One bit of data is transmitted over the 1-Wire
bus per time slot.
Write Time Slots
There are two types of write time slots: write-one time
slots and write-zero time slots. The bus master uses a
write-one time slot to write a logic 1 to the device and
a write-zero time slot to write a logic 0 to the device. All
write time slots must have a 60Fs (min) duration with a
1Fs (min) recovery time between individual write slots.
Both types of write time slots are initiated by the master
pulling the 1-Wire bus low (Figure 11).
To generate a write-one time slot, after pulling the 1-Wire
bus low, the bus master must release the 1-Wire bus
within 15Fs. When the bus is released, the 5kI pullup
resistor pulls the bus high. To generate a write-zero time
slot, after pulling the 1-Wire bus low, the bus master must
continue to hold the bus low for the duration of the time
slot (at least 60Fs).
The device samples the 1-Wire bus during a window that
lasts from 15Fs to 60Fs after the master initiates the write
time slot. If the bus is high during the sampling window,
a 1 is written to the device. If the line is low, a 0 is written
to the device.
Read Time Slots
The device can only transmit data to the master when
the master issues read time slots. Therefore, the master
must generate read time slots immediately after issuing
a Read Scratchpad 1 command or Read Power Supply
command, so that the device can provide the requested
data. In addition, the master can generate read time
slots after issuing a Convert T command to verify the
operation status as explained in the MAX31826 Function
Commands section.
All read time slots must be 60Fs (min) in duration with a
1Fs (min) recovery time between slots. A read time slot
is initiated by the master device pulling the 1-Wire bus
low for a minimum of 1Fs (tINIT) and then releasing the
bus (Figure 11). After the master initiates the read time
slot, the device begins transmitting a 1 or 0 on bus. The
device transmits a 1 by leaving the bus high and transmits a 0 by pulling the bus low. When transmitting a 0,
the device releases the bus by the end of the time slot,
and the pullup resistor pulls the bus back to its high idle
state. Output data from the device is valid for 15Fs after
the falling edge that initiated the read time slot. Therefore,
the master must release the bus and then sample the bus
state within 15Fs from the start of the slot.
Figure 12 illustrates that the sum of tINIT, tRC, and the
master sample window must be less than 15Fs for a read
time slot. tRC is the rise time due to the resistive and
capacitive characteristics of the bus. Figure 13 shows
that system timing margin is maximized by keeping tINIT
and tRC as short as possible and by locating the master
sample time during read time slots towards the end of
the 15Fs period.
���������������������������������������������������������������� Maxim Integrated Products 18
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
START
OF SLOT
START
OF SLOT
MASTER WRITE-ONE SLOT
MASTER WRITE-ZERO SLOT
1µs < tREC < ∞
60µs < Tx “0” < 120µs
> 1µs
VPU
1-Wire BUS
GND
MAX31826 SAMPLES
MAX31826 SAMPLES
MIN
15µs
TYP
15µs
MIN
MAX
30µs
15µs
MASTER READ-ZERO SLOT
TYP
15µs
MAX
30µs
MASTER READ-ONE SLOT
1µs < tREC < ∞
VPU
1-Wire BUS
GND
MASTER SAMPLES
> 1µs
MASTER SAMPLES
> 1µs
15µs
45µs
BUS MASTER PULLING LOW
15µs
MAX31826 PULLING LOW
RESISTOR PULLUP
Figure 11. Read/Write Time Slot Timing Diagram
VPU
VIH OF MASTER
1-Wire BUS
GND
tINIT > 1µs
tRC
MASTER SAMPLES
15µs
BUS MASTER PULLING LOW
RESISTOR PULLUP
Figure 12. Detailed Master Read-One Timing
���������������������������������������������������������������� Maxim Integrated Products 19
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
VPU
VIH OF MASTER
1-Wire BUS
GND
tINIT =
SMALL
MASTER SAMPLES
tRC =
SMALL
15µs
BUS MASTER PULLING LOW
RESISTOR PULLUP
Figure 13. Recommended Master Read-One Timing
Table 3. Operation Example
MASTER
MODE
DATA (LSB FIRST)
COMMENTS
Tx
Reset
Rx
Presence
Master issues reset pulse.
Devices respond with presence pulse.
Tx
F0h
Master issues Search ROM command
Tx
Reset
Rx
Presence
Tx
55h
Tx
64-bit ROM code
Master issues reset pulse.
Devices respond with presence pulse.
Master issues Match ROM command for desired address
Master sends device ROM code.
Tx
44h
Tx
DQ line held high by
strong pullup
Master issues Convert T command.
Tx
Reset
Rx
Presence
Devices respond with presence pulse.
Tx
55h
Master issues Match ROM command.
Tx
64-bit ROM code
Tx
BEh
Rx
9 data bytes
Master applies strong pullup to DQ for the duration of the conversion (tCONV).
Master issues reset pulse.
Master sends device ROM code.
Master issues Read Scratchpad 1 command.
Master reads entire Scratchpad 1 including CRC. The master then recalculates the CRC of
the first 8 data bytes from the scratchpad and compares the calculated CRC with the read
CRC (byte 9). If they match, the master continues; if not, the read operation is repeated.
Operation Example
Table 3 shows an operation example in which there
are multiple devices on the bus using parasite power.
The bus master initiates a temperature conversion in a
specific MAX31826 and then reads Scratchpad 1 and
recalculates the CRC to verify the data.
���������������������������������������������������������������� Maxim Integrated Products 20
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
1-Wire BUS
AD0
DQ
VDD
MAX31826
VDD
AD1
AD2
GND
AD3
DQ
AD0
LOCATION 0
AD0 = GND
AD1 = GND
AD2 = GND
AD3 = GND
1-Wire BUS
AD0
DQ
MAX31826
VDD
AD1
AD2
GND
AD3
DQ
AD0
LOCATION 0
AD0 = GND
AD1 = GND
AD2 = GND
AD3 = GND
VDD
MAX31826
VDD
AD1
AD2
GND
AD3
DQ
AD0
LOCATION 1
AD0 = VDD
AD1 = GND
AD2 = GND
AD3 = GND
MAX31826
VDD
AD1
AD2
GND
AD3
DQ
AD0
LOCATION 1
AD0 = DQ
AD1 = GND
AD2 = GND
AD3 = GND
VDD
MAX31826
VDD
AD1
AD2
GND
AD3
DQ
AD0
LOCATION 2
AD0 = GND
AD1 = VDD
AD2 = GND
AD3 = GND
MAX31826
VDD
AD1
AD2
GND
AD3
DQ
AD0
LOCATION 2
AD0 = GND
AD1 = DQ
AD2 = GND
AD3 = GND
VDD
MAX31826
VDD
GND
AD1
AD2
AD3
LOCATION 15
AD0 = VDD
AD1 = VDD
AD2 = VDD
AD3 = VDD
NOTE: AD3–AD0 CANNOT BE LEFT UNCONNECTED; EACH PIN MUST BE
CONNECTED TO EITHER VDD OR GND.
Figure 14. Address Programming Diagram—VDD Powered
GND
TEMP RANGE
PIN-PACKAGE
MAX31826MUA+
-55NC to +125NC
8 FMAX
MAX31826MUA+T
-55NC to +125NC
8 FMAX
+Denotes a lead(Pb)-free/RoHS-compliant package.
T = Tape and reel.
AD1
AD2
AD3
NOTE: AD3–AD0 CANNOT BE LEFT UNCONNECTED; EACH PIN MUST BE
CONNECTED TO EITHER DQ OR GND.
Figure 15. Address Programming Diagram—Parasite Powered
Ordering Information
PART
MAX31826
VDD
LOCATION 15
AD0 = DQ
AD1 = DQ
AD2 = DQ
AD3 = DQ
Package Information
For the latest package outline information and land patterns
(footprints), go to www.maxim-ic.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.
8 FMAX
U8+3
21-0036
90-0092
���������������������������������������������������������������� Maxim Integrated Products 21
MAX31826
1-Wire Digital Temperature Sensor
with 1Kb Lockable EEPROM
Revision History
REVISION
NUMBER
REVISION
DATE
0
3/12
DESCRIPTION
Initial release
PAGES
CHANGED
—
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.
Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2012
Maxim Integrated Products 22
Maxim is a registered trademark of Maxim Integrated Products, Inc.