MAXIM DS18S20

LE
AVAILAB
DS18S20
High-Precision 1-Wire Digital Thermometer
FEATURES
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MAXIM
DS1820
1 2 3
N.C.
1
N.C.
2
VDD
3
DQ
4
DS1820


Unique 1-Wire Interface Requires Only One
Port Pin for Communication
Each Device has a Unique 64-Bit Serial Code
Stored in an On-Board ROM
Multidrop Capability Simplifies Distributed
Temperature Sensing Applications
Requires No External Components
Can Be Powered from Data Line. Power
Supply Range is 3.0V to 5.5V
Measures Temperatures from -55°C to
+125°C (-67°F to +257°F)
±0.5°C Accuracy from -10°C to +85°C
9-Bit Thermometer Resolution
Converts Temperature in 750ms (max)
User-Definable Nonvolatile (NV) Alarm
Settings
Alarm Search Command Identifies and
Addresses Devices Whose Temperature is
Outside Programmed Limits (Temperature
Alarm Condition)
Applications Include Thermostatic Controls,
Industrial Systems, Consumer Products,
Thermometers, or Functional
Any Thermally Diagrams
Sensitive
System
GND
DQ
VDD

PIN CONFIGURATIONS
®
8
N.C.
7
N.C.
6
N.C.
5
GND
SO (150 mils)
(DS18S20Z)
1 2 3
(BOTTOM VIEW)
TO-92
(DS18S20)
DESCRIPTION
The DS18S20 digital thermometer provides 9-bit Celsius temperature measurements and has an alarm
function with nonvolatile user-programmable upper and lower trigger points. The DS18S20
communicates over a 1-Wire bus that by definition requires only one data line (and ground) for
communication with a central microprocessor. It has an operating temperature range of –55°C to +125°C
and is accurate to ±0.5°C over the range of –10°C to +85°C. In addition, the DS18S20 can derive power
directly from the data line (“parasite power”), eliminating the need for an external power supply.
Each DS18S20 has a unique 64-bit serial code, which allows multiple DS18S20s to function on the same
1-Wire bus. Thus, it is simple to use one microprocessor to control many DS18S20s distributed over a
large area. Applications that can benefit from this feature include HVAC environmental controls,
temperature monitoring systems inside buildings, equipment, or machinery, and process monitoring and
control
systems. appear at end of data sheet.
Pin Configurations
Functional Diagrams continued at end of data sheet.
UCSP is a trademark of Maxim Integrated Products, Inc.
1-Wire is a registered trademark of Maxim Integrated Products, Inc.
For pricing, delivery, and ordering information, please contact Maxim Direct
at 1-888-629-4642, or visit Maxim’s website at www.maximintegrated.com.
19-5474; Rev 8/10
DS18S20
ORDERING INFORMATION
PART
TEMP RANGE
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
–55°C to +125°C
DS18S20
DS18S20+
DS18S20/T&R
DS18S20+T&R
DS18S20-SL/T&R
DS18S20-SL+T&R
DS18S20Z
DS18S20Z+
DS18S20Z/T&R
DS18S20Z+T&R
PIN-PACKAGE
3 TO-92
3 TO-92
3 TO-92 (2000 Piece)
3 TO-92 (2000 Piece)
3 TO-92 (2000 Piece)*
3 TO-92 (2000 Piece)*
8 SO
8 SO
8 SO (2500 Piece)
8 SO (2500 Piece)
+Denotes a lead(Pb)-free/RoHS-compliant package. A “+” appears on the top mark of lead(Pb)-free packages.
T&R = Tape and reel.
*TO-92 packages in tape and reel can be ordered with straight or formed leads. Choose “SL” for straight leads. Bulk TO-92 orders are straight
leads only.
PIN DESCRIPTION
PIN
NAME
TO-92
SO
1
5
GND
2
4
DQ
3
3
VDD
—
1, 2, 6, 7,
8
N.C.
FUNCTION
Ground
Data Input/Output. Open-drain 1-Wire interface pin. Also provides
power to the device when used in parasite power mode (see the
Powering the DS18S20 section.)
Optional VDD. VDD must be grounded for operation in parasite
power mode.
No Connection
OVERVIEW
Figure 1 shows a block diagram of the DS18S20, and pin descriptions are given in the Pin Description
table. The 64-bit ROM stores the device’s unique serial code. The scratchpad memory contains the 2-byte
temperature register that stores the digital output from the temperature sensor. In addition, the scratchpad
provides access to the 1-byte upper and lower alarm trigger registers (TH and TL). The TH and TL registers
are nonvolatile (EEPROM), so they will retain data when the device is powered down.
The DS18S20 uses Maxim’s exclusive 1-Wire bus protocol that implements bus communication using
one control signal. The control line requires a weak pullup resistor since all devices are linked to the bus
via a 3-state or open-drain port (the DQ pin in the case of the DS18S20). In this bus system, the
microprocessor (the master device) 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 covered in the 1-Wire Bus System section.
Another feature of the DS18S20 is the ability to operate without an external power supply. Power is
instead supplied through the 1-Wire pullup resistor via the DQ pin when the bus is high. The high bus
signal also charges an internal capacitor (CPP), 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.” As an
alternative, the DS18S20 may also be powered by an external supply on VDD.
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DS18S20
Figure 1. DS18S20 Block Diagram
VPU
PARASITE POWER
CIRCUIT
4.7k
MEMORY CONTROL
LOGIC
DS18S20
DQ
TEMPERATURE SENSOR
INTERNAL VDD
GND
VDD
64-BIT ROM
AND
1-Wire PORT
CPP
SCRATCHPAD
ALARM HIGH TRIGGER (TH)
REGISTER (EEPROM)
ALARM LOW TRIGGER (TL)
REGISTER (EEPROM)
POWERSUPPLY
SENSE
8-BIT CRC GENERATOR
OPERATION—MEASURING TEMPERATURE
The core functionality of the DS18S20 is its direct-to-digital temperature sensor. The temperature sensor
output has 9-bit resolution, which corresponds to 0.5°C steps. The DS18S20 powers-up in a low-power
idle state; to initiate a temperature measurement and A-to-D conversion, the master must issue a Convert
T [44h] command. Following the conversion, the resulting thermal data is stored in the 2-byte
temperature register in the scratchpad memory and the DS18S20 returns to its idle state. If the DS18S20
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 DS18S20 will respond by transmitting 0 while the
temperature conversion is in progress and 1 when the conversion is done. If the DS18S20 is powered with
parasite power, this notification technique cannot be used since the bus must be pulled high by a strong
pullup during the entire temperature conversion. The bus requirements for parasite power are explained in
detail in the Powering the DS18S20 section.
The DS18S20 output data is calibrated in degrees centigrade; for Fahrenheit applications, a lookup table
or conversion routine must be used. The temperature data is stored as a 16-bit sign-extended two’s
complement number in the temperature register (see Figure 2). 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 reading.
Resolutions greater than 9 bits can be calculated using the data from the temperature, COUNT REMAIN
and COUNT PER °C registers in the scratchpad. Note that the COUNT PER °C register is hard-wired to
16 (10h). After reading the scratchpad, the TEMP_READ value is obtained by truncating the 0.5°C bit
(bit 0) from the temperature data (see Figure 2). The extended resolution temperature can then be
calculated using the following equation:
TEMPERATURE = TEMP _ READ − 0.25 +
COUNT _ PER _ C − COUNT _ REMAIN
COUNT _ PER _ C
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DS18S20
Figure 2. Temperature Register Format
LS BYTE
BIT 7
26
BIT 6
25
BIT 5
24
BIT 4
23
BIT 3
22
BIT 2
21
BIT 1
20
BIT 0
2-1
MS BYTE
BIT 15
S
BIT 14
S
BIT 13
S
BIT 12
S
BIT 11
S
BIT 10
S
BIT 9
S
BIT 8
S
S = SIGN
Table 1. Temperature/Data Relationship
TEMPERATURE
(°C)
+85.0*
+25.0
+0.5
0
-0.5
-25.0
-55.0
DIGITAL OUTPUT
(BINARY)
0000 0000 1010 1010
0000 0000 0011 0010
0000 0000 0000 0001
0000 0000 0000 0000
1111 1111 1111 1111
1111 1111 1100 1110
1111 1111 1001 0010
DIGITAL OUTPUT
(HEX)
00AAh
0032h
0001h
0000h
FFFFh
FFCEh
FF92h
*The power-on reset value of the temperature register is +85°C.
OPERATION—ALARM SIGNALING
After the DS18S20 performs a temperature conversion, the temperature value is compared to the userdefined two’s complement alarm trigger values stored in the 1-byte TH and TL registers (see Figure 3).
The sign bit (S) indicates if the value is positive or negative: for positive numbers S = 0 and for negative
numbers S = 1. The TH and TL registers are nonvolatile (EEPROM) so they will retain data when the
device is powered down. TH and TL can be accessed through bytes 2 and 3 of the scratchpad as explained
in the Memory section.
Figure 3. TH and TL Register Format
BIT 7
S
BIT 6
26
BIT 5
25
BIT 4
25
BIT 3
25
BIT 2
22
BIT 1
21
BIT 0
20
Only bits 8 through 1 of the temperature register are used in the TH and TL comparison since TH and TL
are 8-bit registers. If the measured temperature is lower than or equal to TL or higher than TH, an alarm
condition exists and an alarm flag is set inside the DS18S20. This flag is updated after every temperature
measurement; therefore, if the alarm condition goes away, the flag will be turned off after the next
temperature conversion.
The master device can check the alarm flag status of all DS18S20s on the bus by issuing an Alarm Search
[ECh] command. Any DS18S20s with a set alarm flag will respond to the command, so the master can
determine exactly which DS18S20s have experienced an alarm condition. If an alarm condition exists and
the TH or TL settings have changed, another temperature conversion should be done to validate the alarm
condition.
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DS18S20
POWERING THE DS18S20
The DS18S20 can be powered by an external supply on the VDD pin, or it can operate in “parasite power”
mode, which allows the DS18S20 to function without a local external supply. Parasite power is very
useful for applications that require remote temperature sensing or those with space constraints.
Figure 1 shows the DS18S20’s parasite-power control circuitry, which “steals” power from the 1-Wire
bus via the DQ pin when the bus is high. The stolen charge powers the DS18S20 while the bus is high,
and some of the charge is stored on the parasite power capacitor (CPP) to provide power when the bus is
low. When the DS18S20 is used in parasite power mode, the VDD pin must be connected to ground.
In parasite power mode, the 1-Wire bus and CPP can provide sufficient current to the DS18S20 for most
operations as long as the specified timing and voltage requirements are met (see the DC Electrical
Characteristics and the AC Electrical Characteristics). However, when the DS18S20 is performing
temperature conversions or copying data from the scratchpad 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 assure that the DS18S20 has sufficient
supply current, it is necessary to provide a strong pullup on the 1-Wire bus whenever temperature
conversions are taking place or data is being copied from the scratchpad to EEPROM. This can be
accomplished by using a MOSFET to pull the bus directly to the rail as shown in Figure 4. The 1-Wire
bus must be switched to the strong pullup within 10µs (max) after a Convert T [44h] or Copy Scratchpad
[48h] command is issued, and the bus must be held high by the pullup for the duration of the conversion
(tCONV) or data transfer (tWR = 10ms). No other activity can take place on the 1-Wire bus while the pullup
is enabled.
The DS18S20 can also be powered by the conventional method of connecting an external power supply to
the VDD pin, as shown in Figure 5. 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 time.
The use of parasite power is not recommended for temperatures above 100°C since the DS18S20 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 DS18S20 be
powered by an external power supply.
In some situations the bus master may not know whether the DS18S20s 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
[CCh] command followed by a Read Power Supply [B4h] command followed by a “read-time slot”.
During the read-time slot, parasite powered DS18S20s will pull the bus low, and externally powered
DS18S20s will 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.
5 of 23
DS18S20
Figure 4. Supplying the Parasite-Powered DS18S20 During Temperature Conversions
VPU
DS18S20
GND DQ VDD
VPU
µP
4.7k
TO OTHER
1-WIRE DEVICES
1-Wire BUS
Figure 5. Powering the DS18S20 with an External Supply
DS18S20
VPU
µP
VDD (EXTERNAL SUPPLY)
GND DQ VDD
4.7k
TO OTHER
1-WIRE DEVICES
1-Wire BUS
64-BIT LASERED ROM CODE
Each DS18S20 contains a unique 64-bit code (see Figure 6) stored in ROM. The least significant 8 bits of
the ROM code contain the DS18S20’s 1-Wire family code: 10h. 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. A detailed explanation of the CRC bits is provided in the CRC
Generation section. The 64-bit ROM code and associated ROM function control logic allow the
DS18S20 to operate as a 1-Wire device using the protocol detailed in the 1-Wire Bus System section.
Figure 6. 64-Bit Lasered ROM Code
8-BIT CRC
MSB
48-BIT SERIAL NUMBER
LSB
MSB
8-BIT FAMILY CODE (10h)
LSB
6 of 23
MSB
LSB
DS18S20
MEMORY
The DS18S20’s memory is organized as shown in Figure 7. The memory consists of an SRAM
scratchpad with nonvolatile EEPROM storage for the high and low alarm trigger registers (TH and TL).
Note that if the DS18S20 alarm function is not used, the TH and TL registers can serve as general-purpose
memory. All memory commands are described in detail in the DS18S20 Function Commands section.
Byte 0 and byte 1 of the scratchpad contain the LSB and the MSB of the temperature register,
respectively. These bytes are read-only. Bytes 2 and 3 provide access to TH and TL registers. Bytes 4 and
5 are reserved for internal use by the device and cannot be overwritten; these bytes will return all 1s when
read. Bytes 6 and 7 contain the COUNT REMAIN and COUNT PER ºC registers, which can be used to
calculate extended resolution results as explained in the Operation—Measuring Temperature section.
Byte 8 of the scratchpad is read-only and contains the CRC code for bytes 0 through 7 of the scratchpad.
The DS18S20 generates this CRC using the method described in the CRC Generation section.
Data is written to bytes 2 and 3 of the scratchpad using the Write Scratchpad [4Eh] command; the data
must be transmitted to the DS18S20 starting with the least significant bit of byte 2. To verify data
integrity, the scratchpad can be read (using the Read Scratchpad [BEh] command) after the data is
written. When reading the scratchpad, data is transferred over the 1-Wire bus starting with the least
significant bit of byte 0. To transfer the TH and TL data from the scratchpad to EEPROM, the master must
issue the Copy Scratchpad [48h] command.
Data in the EEPROM registers is retained when the device is powered down; at power-up the EEPROM
data is reloaded into the corresponding scratchpad locations. Data can also be reloaded from EEPROM to
2
the scratchpad at any time using the Recall E [B8h] command. The master can issue “read-time slots”
(see the 1-Wire Bus System section) following the Recall E2 command and the DS18S20 will indicate the
status of the recall by transmitting 0 while the recall is in progress and 1 when the recall is done.
Figure 7. DS18S20 Memory Map
SCRATCHPAD
(POWER-UP STATE)
Byte 0 Temperature LSB (AAh)
(85°C)
Byte 1 Temperature MSB (00h)
EEPROM
Byte 2 TH Register or User Byte 1*
TH Register or User Byte 1
Byte 3 TL Register or User Byte 2*
TL Register or User Byte 2
Byte 4 Reserved (FFh)
Byte 5 Reserved (FFh)
Byte 6 COUNT REMAIN (0Ch)
Byte 7 COUNT PER °C (10h)
Byte 8 CRC*
*Power-up state depends on value(s) stored in EEPROM.
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DS18S20
CRC GENERATION
CRC bytes are provided as part of the DS18S20’s 64-bit ROM code and in the 9th byte of the scratchpad
memory. 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 scratchpad CRC is calculated from the data stored in the
scratchpad, and therefore it changes when the data in the scratchpad changes. The CRCs provide the bus
master with a method of data validation when data is read from the DS18S20. To verify that data has been
read correctly, the bus master must re-calculate the CRC from the received data and then compare this
value to either the ROM code CRC (for ROM reads) or to the scratchpad 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 DS18S20 that prevents a command sequence from proceeding if the DS18S20
CRC (ROM or scratchpad) does not match the value generated by the bus master.
The equivalent polynomial function of the CRC (ROM or scratchpad) is:
CRC = X8 + X5 + X4 + 1
The bus master can re-calculate the CRC and compare it to the CRC values from the DS18S20 using the
polynomial generator shown in Figure 8. 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 shift register. After
shifting in the 56th bit from the ROM or the most significant bit of byte 7 from the scratchpad, the
polynomial generator will contain the re-calculated CRC. Next, the 8-bit ROM code or scratchpad CRC
from the DS18S20 must be shifted into the circuit. At this point, if the re-calculated CRC was correct, the
shift register will contain all 0s. Additional information about the Maxim 1-Wire cyclic redundancy check
is available in Application Note 27: Understanding and Using Cyclic Redundancy Checks with Maxim
iButton Products.
Figure 8. CRC Generator
INPUT
XOR
XOR
XOR
(MSB)
(LSB)
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DS18S20
1-WIRE BUS SYSTEM
The 1-Wire bus system uses a single bus master to control one or more slave devices. The DS18S20 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).
HARDWARE CONFIGURATION
The 1-Wire bus has by definition only a single data line. Each device (master or slave) interfaces to the
data line via an open drain or 3-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 1-Wire port of the
DS18S20 (the DQ pin) is open drain with an internal circuit equivalent to that shown in Figure 9.
The 1-Wire bus requires an external pullup resistor of approximately 5kΩ; 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 480µs,
all components on the bus will be reset.
Figure 9. Hardware Configuration
VPU
DS18S20 1-Wire PORT
4.7k
Rx
1-Wire BUS
DQ
PIN
Rx
5μA
TYP
TX
100Ω
MOSFET
Tx
Rx = RECEIVE
Tx = TRANSMIT
9 of 23
DS18S20
TRANSACTION SEQUENCE
The transaction sequence for accessing the DS18S20 is as follows:
Step 1. Initialization
Step 2. ROM Command (followed by any required data exchange)
Step 3. DS18S20 Function Command (followed by any required data exchange)
It is very important to follow this sequence every time the DS18S20 is accessed, as the DS18S20 will not
respond if any steps in the sequence are missing or out of order. Exceptions to this rule are the Search
ROM [F0h] and Alarm Search [ECh] commands. After issuing either of these ROM commands, 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 DS18S20) 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 or if any device has experienced an alarm
condition. There are five ROM commands, and each command is 8 bits long. The master device must
issue an appropriate ROM command before issuing a DS18S20 function command. A flowchart for
operation of the ROM commands is shown in Figure 14.
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
of the slave devices. If there is only one slave on the bus, the simpler Read ROM command (see below)
can be used in place of the Search ROM process. For a detailed explanation of the Search ROM
procedure, refer to the iButton® Book of Standards at www.maxim-ic.com/ibuttonbook. After every
Search ROM cycle, the bus master must return to Step 1 (Initialization) in the transaction sequence.
READ ROM [33h]
This command can only be used 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 procedure. If this command is used when there
is more than one slave present on the bus, a data collision will occur 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 will respond to the function command issued by the master; all other slaves on the
bus will wait for a reset pulse.
iButton is a registered trademark of Maxim Integrated Products, Inc.
10 of 23
DS18S20
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 DS18S20s on the bus perform
simultaneous temperature conversions by issuing a Skip ROM command followed by a Convert T [44h]
command.
Note that the Read Scratchpad [BEh] 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
command will cause a data collision on the bus if there is more than one slave since multiple devices will
attempt to transmit data simultaneously.
ALARM SEARCH [ECh]
The operation of this command is identical to the operation of the Search ROM command except that
only slaves with a set alarm flag will respond. This command allows the master device to determine if
any DS18S20s experienced an alarm condition during the most recent temperature conversion. After
every Alarm Search cycle (i.e., Alarm Search command followed by data exchange), the bus master must
return to Step 1 (Initialization) in the transaction sequence. See the Operation—Alarm Signaling section
for an explanation of alarm flag operation.
DS18S20 FUNCTION COMMANDS
After the bus master has used a ROM command to address the DS18S20 with which it wishes to
communicate, the master can issue one of the DS18S20 function commands. These commands allow the
master to write to and read from the DS18S20’s scratchpad memory, initiate temperature conversions and
determine the power supply mode. The DS18S20 function commands, which are described below, are
summarized in Table 2 and illustrated by the flowchart in Figure 15.
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 memory and the DS18S20 returns to its
low-power idle state. If the device is being used in parasite power mode, within 10µs (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 DS18S20 section. If the DS18S20 is powered by an
external supply, the master can issue read-time slots after the Convert T command and the DS18S20 will
respond 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 since the bus is pulled high by
the strong pullup during the conversion.
WRITE SCRATCHPAD [4Eh]
This command allows the master to write 2 bytes of data to the DS18S20’s scratchpad. The first byte is
written into the TH register (byte 2 of the scratchpad), and the second byte is written into the TL register
(byte 3 of the scratchpad). Data must be transmitted least significant bit first. Both bytes MUST be
written before the master issues a reset, or the data may be corrupted.
READ SCRATCHPAD [BEh]
This command allows the master to read the contents of the scratchpad. 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 may issue a reset to terminate reading at any time if only part of the scratchpad data is
needed.
11 of 23
DS18S20
COPY SCRATCHPAD [48h]
This command copies the contents of the scratchpad TH and TL registers (bytes 2 and 3) to EEPROM. If
the device is being used in parasite power mode, within 10µs (max) after this command is issued the
master must enable a strong pullup on the 1-Wire bus for at least 10ms as described in the Powering the
DS18S20 section.
RECALL E2 [B8h]
This command recalls the alarm trigger values (TH and TL) from EEPROM and places the data in bytes 2
and 3, respectively, in the scratchpad memory. The master device can issue read-time slots following the
Recall E2 command and the DS18S20 will indicate the status of the recall by transmitting 0 while the
recall is in progress and 1 when the recall is done. The recall operation happens automatically at powerup, so valid data is available in the scratchpad as soon as power is applied to the device.
READ POWER SUPPLY [B4h]
The master device issues this command followed by a read-time slot to determine if any DS18S20s on the
bus are using parasite power. During the read-time slot, parasite powered DS18S20s will pull the bus low,
and externally powered DS18S20s will let the bus remain high. See the Powering the DS18S20 section
for usage information for this command.
Table 2. DS18S20 Function Command Set
COMMAND
Convert T
Read
Scratchpad
Write
Scratchpad
Copy
Scratchpad
Recall E
2
Read Power
Supply
Note 1:
Note 2:
Note 3:
1-Wire BUS ACTIVITY
AFTER COMMAND IS
ISSUED
TEMPERATURE CONVERSION COMMANDS
Initiates temperature
DS18S20 transmits conversion
conversion.
status to master (not applicable
44h
for parasite-powered
DS18S20s).
MEMORY COMMANDS
Reads the entire
DS18S20 transmits up to 9
scratchpad including the
BEh
data bytes to master.
CRC byte.
Writes data into
Master transmits 2 data bytes
scratchpad bytes 2 and 3
4Eh
to DS18S20.
(TH and TL).
Copies TH and TL data
None
from the scratchpad to
48h
EEPROM.
Recalls TH and TL data
DS18S20 transmits recall
from EEPROM to the
B8h
status to master.
scratchpad.
Signals DS18S20 power
DS18S20 transmits supply
supply mode to the
B4h
status to master.
master.
DESCRIPTION
PROTOCOL
NOTES
1
2
3
1
For parasite-powered DS18S20s, the master must enable a strong pullup on the 1-Wire bus during temperature
conversions and copies from the scratchpad to EEPROM. No other bus activity may take place during this time.
The master can interrupt the transmission of data at any time by issuing a reset.
Both bytes must be written before a reset is issued.
12 of 23
DS18S20
1-WIRE SIGNALING
The DS18S20 uses a strict 1-Wire communication protocol to ensure data integrity. Several signal types
are defined by this protocol: reset pulse, presence pulse, write 0, write 1, read 0, and read 1. All these
signals, with the exception of the presence pulse, are initiated by the bus master.
INITIALIZATION PROCEDURE—RESET AND PRESENCE PULSES
All communication with the DS18S20 begins with an initialization sequence that consists of a reset pulse
from the master followed by a presence pulse from the DS18S20. This is illustrated in Figure 10. When
the DS18S20 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 a minimum of 480µs. The bus master then releases the bus and goes into receive mode (RX).
When the bus is released, the 5kΩ pullup resistor pulls the 1-Wire bus high. When the DS18S20 detects
this rising edge, it waits 15µs to 60µs and then transmits a presence pulse by pulling the 1-Wire bus low
for 60µs to 240µs.
Figure 10. Initialization Timing
MASTER TX RESET PULSE
MASTER RX
480µs minimum
DS18S20 TX
presence pulse
60-240 µs
480µs minimum
VPU
DS18S20
waits 15-60 µs
1-WIRE BUS
GND
LINE TYPE LEGEND
Bus master pulling low
DS18S20 pulling low
Resistor pullup
READ/WRITE TIME SLOTS
The bus master writes data to the DS18S20 during write time slots and reads data from the DS18S20
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 1” time slots and “Write 0” time slots. The bus master
uses a Write 1 time slot to write a logic 1 to the DS18S20 and a Write 0 time slot to write a logic 0 to the
DS18S20. All write time slots must be a minimum of 60µs in duration with a minimum of a 1µs recovery
time between individual write slots. Both types of write time slots are initiated by the master pulling the
1-Wire bus low (see Figure 11).
To generate a Write 1 time slot, after pulling the 1-Wire bus low, the bus master must release the 1-Wire
bus within 15µs. When the bus is released, the 5kΩ pullup resistor will pull the bus high. To generate a
Write 0 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 60µs). The DS18S20 samples the 1-Wire bus during a window that
lasts from 15µs to 60µs after the master initiates the write time slot. If the bus is high during the sampling
window, a 1 is written to the DS18S20. If the line is low, a 0 is written to the DS18S20.
13 of 23
DS18S20
READ-TIME SLOTS
The DS18S20 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 [BEh] or Read Power
Supply [B4h] command, so that the DS18S20 can provide the requested data. In addition, the master can
generate read-time slots after issuing Convert T [44h] or Recall E2 [B8h] commands to find out the status
of the operation as explained in the DS18S20 Function Commands section.
All read-time slots must be a minimum of 60µs in duration with a minimum of a 1µs recovery time
between slots. A read-time slot is initiated by the master device pulling the 1-Wire bus low for a
minimum of 1µs and then releasing the bus (see Figure 11). After the master initiates the read-time slot,
the DS18S20 will begin transmitting a 1 or 0 on bus. The DS18S20 transmits a 1 by leaving the bus high
and transmits a 0 by pulling the bus low. When transmitting a 0, the DS18S20 will release the bus by the
end of the time slot, and the bus will be pulled back to its high idle state by the pullup resister. Output
data from the DS18S20 is valid for 15µs after the falling edge that initiated the read-time slot. Therefore,
the master must release the bus and then sample the bus state within 15µs from the start of the slot.
Figure 12 illustrates that the sum of TINIT, TRC, and TSAMPLE must be less than 15µs for a read-time slot.
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 15µs period.
Figure 11. Read/Write Time Slot Timing Diagram
START
OF SLOT
START
OF SLOT
MASTER WRITE “0” SLOT
MASTER WRITE “1” SLOT
1µs < TREC < ∞
60µs < TX “0” < 120µs
> 1µs
VPU
1-WIRE BUS
GND
DS18S20 Samples
MIN
15µs
DS18S20 Samples
TYP
15µs
MAX
MIN
15µs
30µs
MASTER READ “0” SLOT
TYP
15µs
30µs
MASTER READ “1” SLOT
1µs < TREC < ∞
VPU
1-WIRE BUS
GND
> 1 µs
Master samples
Master samples
> 1µs
15µs
MAX
45µs
15µs
LINE TYPE LEGEND
Bus master pulling low
Resistor pullup
14 of 23
DS18S20 pulling low
DS18S20
Figure 12. Detailed Master Read 1 Timing
VPU
VIH of Master
1-WIRE BUS
GND
TINT > 1µs
TRC
Master samples
15µs
Figure 13. Recommended Master Read 1 Timing
VPU
VIH of Master
1-WIRE BUS
GND
Master samples
TINT = TRC =
small small
15µs
LINE TYPE LEGEND
Bus master pulling low
Resistor pullup
15 of 23
DS18S20
Figure 14. ROM Commands Flowchart
Initialization
Sequence
MASTER TX
RESET PULSE
DS18S20 TX
PRESENCE
PULSE
MASTER TX ROM
COMMAND
33h
READ ROM
COMMAND
Y
N
55h
MATCH ROM
COMMAND
F0h
SEARCH ROM
COMMAND
N
Y
Y
N
ECh
N
ALARM SEARCH
COMMAND
Y
Y
MASTER TX
BIT 0
DS18S20 TX BIT 0
DS18S20 TX BIT 0
DS18S20 TX BIT 0
DS18S20 TX BIT 0
MASTER TX BIT 0
MASTER TX BIT 0
BIT 0
MATCH?
DEVICE(S)
WITH ALARM
FLAG SET?
DS18S20 TX
FAMILY CODE
1 BYTE
N
BIT 0
MATCH?
DS18S20 TX
SERIAL NUMBER
6 BYTES
N
Y
Y
Y
DS18S20 TX BIT 1
DS18S20 TX
CRC BYTE
MASTER TX
BIT 1
DS18S20 TX BIT 1
MASTER TX BIT 1
N
N
BIT 1
MATCH?
BIT 1
MATCH?
Y
Y
DS18S20 TX BIT 63
MASTER TX
BIT 63
DS18S20 TX BIT 63
MASTER TX BIT 63
N
BIT 63
MATCH?
Y
N
BIT 63
MATCH?
Y
MASTER TX
FUNCTION
COMMAND
(FIGURE 15)
16 of 23
CCh
SKIP ROM
COMMAND
N
N
DS18S20
Figure 15. DS18S20 Function Commands Flowchart
44h
CONVERT
TEMPERATURE
?
MASTER TX
FUNCTION
COMMAND
48h
COPY
SCRATCHPAD
?
N
Y
Y
N
PARASITE
POWER
?
DS18S20 BEGINS
CONVERSION
Y
N
DATA COPIED FROM
SCRATCHPAD TO EEPROM
B4h
READ
POWER SUPPLY
?
PARASITE
POWERED
?
N
MASTER DISABLES
STRONG PULLUP
Y
MASTER
RX “0s”
MASTER
RX “1s”
N
B8h
2
RECALL E
?
MASTER
RX “1s”
BEh
READ
SCRATCHPAD
?
N
Y
Y
N
COPY IN
PROGRESS
?
MASTER DISABLES
STRONG PULLUP
MASTER
RX “0s”
Y
MASTER ENABLES
STRONG PULL-UP ON DQ
N
Y
N
PARASITE
POWER
?
MASTER ENABLES
STRONG PULLUP ON DQ
DS18S20 CONVERTS
TEMPERATURE
DEVICE
CONVERTING
TEMPERATURE
?
N
N
Y
Y
MASTER TX TH BYTE
TO SCRATCHPAD
MASTER RX DATA BYTE
FROM SCRATCHPAD
Y
MASTER BEGINS DATA
2
RECALL FROM E PROM
4Eh
WRITE
SCRATCHPAD
?
MASTER TX TL BYTE
TO SCRATCHPAD
MASTER
RX “1s”
MASTER
RX “0s”
MASTER
TX RESET
?
DEVICE
BUSY RECALLING
DATA
?
N
N
N
Y
MASTER
RX “0s”
Y
MASTER
RX “1s”
HAVE 8 BYTES
BEEN READ
?
Y
MASTER RX SCRATCHPAD
CRC BYTE
RETURN TO INITIALIZATION
SEQUENCE (FIGURE 14) FOR
NEXT TRANSACTION
17 of 23
DS18S20
DS18S20 OPERATION EXAMPLE 1
In this example there are multiple DS18S20s on the bus and they are using parasite power. The bus
master initiates a temperature conversion in a specific DS18S20 and then reads its scratchpad and
recalculates the CRC to verify the data.
MASTER MODE
Tx
Rx
Tx
Tx
Tx
Tx
Rx
Tx
Tx
Tx
DATA (LSB FIRST)
Reset
Presence
55h
64-bit ROM code
44h
DQ line held high by
strong pullup
Reset
Presence
55h
64-bit ROM code
BEh
Rx
9 data bytes
Tx
COMMENTS
Master issues reset pulse.
DS18S20s respond with presence pulse.
Master issues Match ROM command.
Master sends DS18S20 ROM code.
Master issues Convert T command.
Master applies strong pullup to DQ for the duration of the
conversion (tCONV).
Master issues reset pulse.
DS18S20s respond with presence pulse.
Master issues Match ROM command.
Master sends DS18S20 ROM code.
Master issues Read Scratchpad command.
Master reads entire scratchpad including CRC. The master
then recalculates the CRC of the first eight 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.
DS18S20 OPERATION EXAMPLE 2
In this example there is only one DS18S20 on the bus and it is using parasite power. The master writes to
the TH and TL registers in the DS18S20 scratchpad and then reads the scratchpad and recalculates the
CRC to verify the data. The master then copies the scratchpad contents to EEPROM.
MASTER MODE
Tx
Rx
Tx
Tx
Tx
Tx
Rx
Tx
Tx
DATA (LSB FIRST)
Reset
Presence
CCh
4Eh
2 data bytes
Reset
Presence
CCh
BEh
Rx
9 data bytes
Tx
Rx
Tx
Tx
Reset
Presence
CCh
48h
DQ line held high by
strong pullup
Tx
COMMENTS
Master issues reset pulse.
DS18S20 responds with presence pulse.
Master issues Skip ROM command.
Master issues Write Scratchpad command.
Master sends two data bytes to scratchpad (TH and TL)
Master issues reset pulse.
DS18S20 responds with presence pulse.
Master issues Skip ROM command.
Master issues Read Scratchpad command.
Master reads entire scratchpad including CRC. The master
then recalculates the CRC of the first eight 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.
Master issues reset pulse.
DS18S20 responds with presence pulse.
Master issues Skip ROM command.
Master issues Copy Scratchpad command.
Master applies strong pullup to DQ for at least 10ms while
copy operation is in progress.
18 of 23
DS18S20
DS18S20 OPERATION EXAMPLE 3
In this example there is only one DS18S20 on the bus and it is using parasite power. The bus master
initiates a temperature conversion then reads the DS18S20 scratchpad and calculates a higher resolution
result using the data from the temperature, COUNT REMAIN and COUNT PER °C registers.
MASTER MODE
Tx
Tx
Tx
Tx
Tx
Rx
Tx
Tx
DATA (LSB FIRST)
Reset
Presence
CCh
44h
DQ line held high by
strong pullup
Reset
Presence
CCh
BEh
Rx
9 data bytes
Tx
Rx
Reset
Presence
—
—
Tx
COMMENTS
Master issues reset pulse.
DS18S20 responds with presence pulse.
Master issues Skip ROM command.
Master issues Convert T command.
Master applies strong pullup to DQ for the duration of the
conversion (tCONV).
Master issues reset pulse.
DS18S20 responds with presence pulse.
Master issues Skip ROM command.
Master issues Read Scratchpad command.
Master reads entire scratchpad including CRC. The master
then recalculates the CRC of the first eight 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. The master also calculates the
TEMP_READ value and stores the contents of the COUNT
REMAIN and COUNT PER °C registers.
Master issues reset pulse.
DS18S20 responds with presence pulse.
CPU calculates extended resolution temperature using the
equation in the Operation—Measuring Temperature section.
19 of 23
DS18S20
ABSOLUTE MAXIMUM RATINGS
Voltage Range on Any Pin Relative to Ground........................................................................................ -0.5V to +6.0V
Continuous Power Dissipation (TA = +70°C)
8-Pin SO (derate 5.9mW/°C above +70°C).......................................................................................... 470.6mW
3-Pin TO-92 (derate 6.3mW/°C above +70°C)..................................................................................... 500mW
Operating Temperature Range ................................................................................................................ -55°C to +125°C
Storage Temperature Range .................................................................................................................... -55°C to +125°C
Lead Temperature (soldering, 10s) .......................................................................................................... +260°C
Soldering Temperature (reflow)
Lead(Pb)-free ..................................................................................................................................... .+260°C
Containing lead(Pb) ............................................................................................................................ +240°C
These are stress ratings only and functional operation of the device at these or any other conditions above those indicated in the operation sections of this
specification is not implied. Exposure to absolute maximum rating conditions for extended periods of time may affect reliability.
DC ELECTRICAL CHARACTERISTICS
(VDD = 3.0V to 5.5V, TA = -55°C to +125°C, unless otherwise noted.)
PARAMETER
Supply Voltage
Pullup Supply
Voltage
SYMBOL
VDD
Thermometer Error
tERR
Input Logic-Low
VIL
Input Logic-High
Sink Current
Standby Current
Active Current
DQ Input Current
Drift
VPU
CONDITIONS
Local Power
Parasite Power
Local Power
-10°C to +85°C
-55°C to +125°C
MIN
+3.0
+3.0
+3.0
TYP
-0.3
Local Power
+2.2
Parasite Power
+3.0
VI/O = 0.4V
4.0
The lower of
5.5
or
VDD + 0.3
VIH
IL
IDDS
IDD
IDQ
750
1
5
±0.2
VDD = 5V
MAX
+5.5
+5.5
VDD
±0.5
±2
+0.8
1000
1.5
UNITS
V
NOTES
1
V
1, 2
°C
3
V
1, 4, 5
V
1, 6
mA
nA
mA
µA
°C
1
7, 8
9
10
11
NOTES:
1) All voltages are referenced to ground.
2) The Pullup Supply Voltage specification assumes that the pullup device is ideal, and therefore the high level of
the pullup is equal to VPU. In order to meet the VIH spec of the DS18S20, 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.
3) See typical performance curve in Figure 16.
4) Logic-low voltages are specified at a sink current of 4mA.
5) To guarantee a presence pulse under low voltage parasite power conditions, VILMAX may have to be reduced to
as low as 0.5V.
6) Logic-high voltages are specified at a source current of 1mA.
7) Standby current specified up to +70°C. Standby current typically is 3µA at +125°C.
8) To minimize IDDS, DQ should be within the following ranges: GND ≤ DQ ≤ GND + 0.3V or
VDD – 0.3V ≤ DQ ≤ VDD.
9) Active current refers to supply current during active temperature conversions or EEPROM writes.
10) DQ line is high (“high-Z” state).
11) Drift data is based on a 1000-hour stress test at +125°C with VDD = 5.5V.
20 of 23
DS18S20
AC ELECTRICAL CHARACTERISTICS—NV MEMORY
(VDD = 3.0V to 5.5V, TA = -55°C to +100°C, unless otherwise noted.)
PARAMETER
NV Write Cycle Time
EEPROM Writes
EEPROM Data Retention
SYMBOL
tWR
NEEWR
tEEDR
CONDITIONS
MIN
-55°C to +55°C
-55°C to +55°C
TYP
2
MAX
10
50k
10
UNITS
ms
writes
years
AC ELECTRICAL CHARACTERISTICS
(VDD = 3.0V to 5.5V; TA = -55°C to +125°C, unless otherwise noted.)
PARAMETER
Temperature Conversion
Time
SYMBOL
Time to Strong Pullup On
tSPON
Time Slot
Recovery Time
Write 0 Low Time
Write 1 Low Time
Read Data Valid
Reset Time High
Reset Time Low
Presence-Detect High
Presence-Detect Low
Capacitance
tSLOT
tREC
tLOW0
tLOW1
tRDV
tRSTH
tRSTL
CONDITIONS
MIN
TYP
MAX
UNITS
NOTES
750
ms
1
10
µs
120
µs
µs
µs
µs
µs
µs
µs
µs
µs
pF
tCONV
Start Convert T
Command Issued
60
1
60
1
120
15
15
480
480
15
60
tPDHIGH
tPDLOW
CIN/OUT
60
240
25
NOTES:
1) See the timing diagrams in Figure 17.
2) Under parasite power, if tRSTL > 960µs, a power-on reset may occur.
Figure 16. Typical Performance Curve
DS18S20 Typical Error Curve
0.5
0.4
+3s Error
0.3
0.2
0.1
0
-0.1
0
10
20
30
40
50
60
-0.2
-0.3
-0.4
Mean Error
-3s Error
-0.5
Temperature (°C)
21 of 23
70
1
1
1
1
1
1
1, 2
1
1
DS18S20
Figure 17. Timing Diagrams
PACKAGE INFORMATION
For the latest package outline information and land patterns, 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
8 SO
3 TO-92
(straight leads)
3 TO-92
(formed leads)
PACKAGE CODE
S8-2
OUTLINE NO.
21-0041
LAND PATTERN NO.
90-0096
Q3-1
21-0248
—
Q3-4
21-0250
—
22 of 23
DS18S20
REVISION HISTORY
REVISION
DATE
042208
8/10
DESCRIPTION
In the Ordering Information table, added TO-92 straight-lead packages and
included a note that the TO-92 package in tape and reel can be ordered with
either formed or straight leads
Removed the Top Mark column from the Ordering Information table;
added the continuous power dissipation and lead and soldering
temperatures to the Absolute Maximum Ratings section
PAGES
CHANGED
2
2, 20
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 160 Rio Robles, San Jose, CA 95134 USA 1-408-601-1000
© Maxim Integrated
23
The Maxim logo and Maxim Integrated are trademarks of Maxim Integrated Products, Inc.