MAXIM DS1620S

LE
AVAILAB
DS1620
Digital Thermometer and
Thermostat
www.maxim-ic.com
FEATURES
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PIN ASSIGNMENT
Requires no external components
Supply voltage range covers from 2.7V to
5.5V
Measures temperatures from -55°C to +125°C
in 0.5°C increments; Fahrenheit equivalent is
-67°F to +257°F in 0.9°F increments
Temperature is read as a 9-bit value
Converts temperature to digital word in 750
ms (max)
Thermostatic settings are user-definable and
nonvolatile
Data is read from/written via a 3-wire serial
interface (CLK, DQ, RST )
Applications include thermostatic controls,
industrial systems, consumer products,
thermometers, or any thermally sensitive
system
8-pin DIP or SOIC (208-mil) packages
DQ
1
8
VDD
CLK/CONV
2
7
THIGH
RST
3
6
TLOW
GND
4
5
TCOM
DS1620S 8-Pin SOIC (208-mil)
DQ
1
8
VDD
CLK/CONV
2
7
THIGH
RST
3
6
TLOW
GND
4
5
TCOM
DS1620 8-Pin DIP (300-mil)
PIN DESCRIPTION
Functional Diagrams
DQ
CLK/ CONV
RST
GND
THIGH
TLOW
TCOM
VDD
- 3-Wire Input/Output
- 3-Wire Clock Input and
Stand-alone Convert Input
- 3-Wire Reset Input
- Ground
- High Temperature Trigger
- Low Temperature Trigger
- High/Low Combination Trigger
- Power Supply Voltage (3V - 5V)
DESCRIPTION
The DS1620 Digital Thermometer and Thermostat provides 9–bit temperature readings which indicate
the temperature of the device. With three thermal alarm outputs, the DS1620 can also act as a thermostat.
THIGH is driven high if the DS1620’s temperature is greater than or equal to a user–defined temperature
TH. TLOW is driven high if the DS1620’s temperature is less than or equal to a user–defined temperature
TL. TCOM is driven high when the temperature exceeds TH and stays high until the temperature falls
below
that of TL. 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.
For pricing, delivery, and ordering information, please contact Maxim Direct
at 1-888-629-4642, or visit Maxim’s website at www.maximintegrated.com.
053105
DS1620
User–defined temperature settings are stored in nonvolatile memory, so parts can be programmed prior to
insertion in a system, as well as used in standalone applications without a CPU. Temperature settings and
temperature readings are all communicated to/from the DS1620 over a simple 3–wire interface.
ORDERING INFORMATION
PART
DS1620
DS1620+
DS1620S
DS1620S+
DS1620S/T&R
DS1620S+T&R
PACKAGE MARKING
DS1620
DS1620 (See Note)
DS1620
DS1620 (See Note)
DS1620
DS1620 (See Note)
DESCRIPTION
8-Pin DIP (300 mil)
Lead-Free 8-Pin DIP (300 mil)
8-Pin SOIC (208 mil)
Lead-Free 8-Pin SOIC (208 mil)
8-Pin SOIC (208 mil), 2000-Piece Tape-and-Reel
Lead-Free 8-Pin SOIC (208 mil), 2000-Piece
Tape-and-Reel
Note: A “+” symbol will also be marked on the package near the Pin 1 indicator
DETAILED PIN DESCRIPTION Table 1
PIN
1
2
SYMBOL
DQ
CLK/ CONV
3
4
5
RST
GND
TCOM
6
7
8
TLOW
THIGH
VDD
DESCRIPTION
Data Input/Output pin for 3-wire communication port.
Clock input pin for 3-wire communication port. When the DS1620 is used in a
stand-alone application with no 3–wire port, this pin can be used as a convert
pin. Temperature conversion will begin on the falling edge of CONV .
Reset input pin for 3-wire communication port.
Ground pin.
High/Low Combination Trigger. Goes high when temperature exceeds TH;
will reset to low when temperature falls below TL.
Low Temperature Trigger. Goes high when temperature falls below TL.
High Temperature Trigger. Goes high when temperature exceeds TH.
Supply Voltage. 2.7V – 5.5V input power pin.
Table 2. DS1620 REGISTER SUMMARY
REGISTER NAME
(USER ACCESS)
Temperature
(Read Only)
SIZE
MEMORY
TYPE
9 Bits
SRAM
TH
(Read/Write)
9 Bits
EEPROM
TL
(Read/Write)
9 Bits
EEPROM
REGISTER CONTENTS
AND POWER-UP/POR STATE
Measured Temperature (Two’s Complement)
Power-Up/POR State: -60ºC (1 1000 1000)
Upper Alarm Trip Point (Two’s Complement)
Power-Up/POR State: User-Defined.
Initial State from Factory: +15°C (0 0001 1110)
Lower Alarm Trip Point (Two’s Complement)
Power-Up/POR State: User-Defined.
Initial State from Factory: +10°C (0 0001 0100)
OPERATION-MEASURING TEMPERATURE
A block diagram of the DS1620 is shown in Figure 1.
..
2 of 12
DS1620
DS1620 FUNCTIONAL BLOCK DIAGRAM Figure 1
The DS1620 measures temperature using a bandgap-based temperature sensor. The temperature reading
is provided in a 9–bit, two’s complement reading by issuing a READ TEMPERATURE command. The
data is transmitted serially through the 3–wire serial interface, LSB first. The DS1620 can measure
temperature over the range of -55°C to +125°C in 0.5°C increments. For Fahrenheit usage, a lookup table
or conversion factor must be used.
Since data is transmitted over the 3–wire bus LSB first, temperature data can be written to/read from the
DS1620 as either a 9–bit word (taking RST low after the 9th (MSB) bit), or as two transfers of 8–bit
words, with the most significant 7 bits being ignored or set to 0, as illustrated in Table 3. After the MSB,
the DS1620 will output 0s.
Note that temperature is represented in the DS1620 in terms of a ½°C LSB, yielding the 9–bit format
shown in Figure 2.
TEMPERATURE, TH, and TL REGISTER FORMAT Figure 2
MSB
X
LSB
X
X
X
X
X
X
1
1
T = -25°C
3 of 12
1
0
0
1
1
1
0
DS1620
Table 3 describes the exact relationship of output data to measured temperature.
.
TEMPERATURE/DATA RELATIONSHIPS Table 3
TEMP
+125˚C
+25˚C
+½˚C
+0˚C
-½˚C
-25˚C
-55˚C
DIGITAL OUTPUT
(Binary)
0 11111010
0 00110010
0 00000001
0 00000000
1 11111111
1 11001110
1 10010010
DIGITAL OUTPUT
(Hex)
00FA
0032h
0001h
0000h
01FFh
01CEh
0192h
Higher resolutions may be obtained by reading the temperature, and truncating the 0.5°C bit (the LSB)
from the read value. This value is TEMP_READ. The value left in the counter may then be read by
issuing a READ COUNTER command. This value is the count remaining (COUNT_REMAIN) after the
gate period has ceased. By loading the value of the slope accumulator into the count register (using the
READ SLOPE command), this value may then be read, yielding the number of counts per degree C
(COUNT_PER_C) at that temperature. The actual temperature may be then be calculated by the user
using the following:
TEMPERATURE=TEMP_READ-0.25 +
(COUNT_PER_C - COUNT_REMAIN)
COUNT_PER_C
OPERATION–THERMOSTAT CONTROLS
Three thermally triggered outputs, THIGH, TLOW, and TCOM, are provided to allow the DS1620 to be used
as a thermostat, as shown in Figure 3. When the DS1620’s temperature meets or exceeds the value stored
in the high temperature trip register, the output THIGH becomes active (high) and remains active until the
DS1620’s measured temperature becomes less than the stored value in the high temperature register, TH.
The THIGH output can be used to indicate that a high temperature tolerance boundary has been met or
exceeded, or it can be used as part of a closed loop system to activate a cooling system and deactivate it
when the system temperature returns to tolerance.
The TLOW output functions similarly to the THIGH output. When the DS1620’s measured temperature
equals or falls below the value stored in the low temperature register, the TLOW output becomes active.
TLOW remains active until the DS1620’s temperature becomes greater than the value stored in the low
temperature register, TL. The TLOW output can be used to indicate that a low temperature tolerance
boundary has been met or exceeded, or as part of a closed loop system it can be used to activate a heating
system and deactivate it when the system temperature returns to tolerance.
The TCOM output goes high when the measured temperature meets or exceeds TH, and will stay high until
the temperature equals or falls below TL. In this way, any amount of hysteresis can be obtained.
4 of 12
DS1620
THERMOSTAT OUTPUT OPERATION Figure 3
THIGH
TLOW
TCOM
TH
TL
T(°C)
OPERATION AND CONTROL
The DS1620 must have temperature settings resident in the TH and TL registers for thermostatic
operation. A configuration/status register also determines the method of operation that the DS1620 will
use in a particular application and indicates the status of the temperature conversion operation. The
configuration register is defined as follows:
CONFIGURATION/STATUS REGISTER
DONE
THF
TLF
NVB
1
0
CPU
1SHOT
where
DONE = Conversion Done Bit. 1=conversion complete, 0=conversion in progress. The power-up/POR
state is a 1.
THF
= Temperature High Flag. This bit will be set to 1 when the temperature is greater than or equal
to the value of TH. It will remain 1 until reset by writing 0 into this location or by removing power from
the device. This feature provides a method of determining if the DS1620 has ever been subjected to
temperatures above TH while power has been applied. The power-up/POR state is a 0.
TLF
= Temperature Low Flag. This bit will be set to 1 when the temperature is less than or equal to
the value of TL. It will remain 1 until reset by writing 0 into this location or by removing power from the
device. This feature provides a method of determining if the DS1620 has ever been subjected to
temperatures below TL while power has been applied. The power-up/POR state is a 0.
NVB = Nonvolatile Memory Busy Flag. 1=write to an E2 memory cell in progress. 0=nonvolatile
memory is not busy. A copy to E2 may take up to 10 ms. The power-up/POR state is a 0.
CPU
= CPU Use Bit. If CPU=0, the CLK/ CONV pin acts as a conversion start control, when RST is
low. If CPU is 1, the DS1620 will be used with a CPU communicating to it over the 3–wire port, and the
operation of the CLK/ CONV pin is as a normal clock in concert with DQ and RST . This bit is stored in
nonvolatile E2 memory, capable of at least 50,000 writes. The DS1620 is shipped with CPU=0.
5 of 12
DS1620
1SHOT = One–Shot Mode. If 1SHOT is 1, the DS1620 will perform one temperature conversion upon
reception of the Start Convert T protocol. If 1SHOT is 0, the DS1620 will continuously perform
temperature conversion. This bit is stored in nonvolatile E2 memory, capable of at least 50,000 writes. The
DS1620 is shipped with 1SHOT=0.
For typical thermostat operation, the DS1620 will operate in continuous mode. However, for applications
where only one reading is needed at certain times or to conserve power, the one–shot mode may be used.
Note that the thermostat outputs (THIGH, TLOW, TCOM) will remain in the state they were in after the last
valid temperature conversion cycle when operating in one–shot mode.
OPERATION IN STAND–ALONE MODE
In applications where the DS1620 is used as a simple thermostat, no CPU is required. Since the
temperature limits are nonvolatile, the DS1620 can be programmed prior to insertion in the system. In
order to facilitate operation without a CPU, the CLK/ CONV pin (pin 2) can be used to initiate
conversions. Note that the CPU bit must be set to 0 in the configuration register to use this mode of
operation. Whether CPU=0 or 1, the 3–wire port is active. Setting CPU=1 disables the stand–alone mode.
To use the CLK/ CONV pin to initiate conversions, RST must be low and CLK/ CONV must be high. If
CLK/ CONV is driven low and then brought high in less than 10 ms, one temperature conversion will be
performed and then the DS1620 will return to an idle state. If CLK/ CONV is driven low and remains low,
continuous conversions will take place until CLK/ CONV is brought high again. With the CPU bit set to 0,
the CLK/ CONV will override the 1SHOT bit if it is equal to 1. This means that even if the part is set for
one–shot mode, driving CLK/ CONV low will initiate conversions.
3–WIRE COMMUNICATIONS
The 3–wire bus is comprised of three signals. These are the RST (reset) signal, the CLK (clock) signal,
and the DQ (data) signal. All data transfers are initiated by driving the RST input high. Driving the RST
input low terminates communication. (See Figures 4 and 5.) A clock cycle is a sequence of a falling edge
followed by a rising edge. For data inputs, the data must be valid during the rising edge of a clock cycle.
Data bits are output on the falling edge of the clock and remain valid through the rising edge.
When reading data from the DS1620, the DQ pin goes to a high-impedance state while the clock is high.
Taking RST low will terminate any communication and cause the DQ pin to go to a high-impedance
state.
Data over the 3–wire interface is communicated LSB first. The command set for the 3–wire interface as
shown in Table 4 is as follows.
Read Temperature [AAh]
This command reads the contents of the register which contains the last temperature conversion result.
The next nine clock cycles will output the contents of this register.
Write TH [01h]
This command writes to the TH (HIGH TEMPERATURE) register. After issuing this command the next
nine clock cycles clock in the 9–bit temperature limit which will set the threshold for operation of the
THIGH output.
6 of 12
DS1620
Write TL [02h]
This command writes to the TL (LOW TEMPERATURE) register. After issuing this command the next
nine clock cycles clock in the 9–bit temperature limit which will set the threshold for operation of the
TLOW output.
Read TH [A1h]
This command reads the value of the TH (HIGH TEMPERATURE) register. After issuing this command
the next nine clock cycles clock out the 9–bit temperature limit which sets the threshold for operation of
the THIGH output.
Read TL [A2h]
This command reads the value of the TL (LOW TEMPERATURE) register. After issuing this command
the next nine clock cycles clock out the 9–bit temperature limit which sets the threshold for operation of
the TLOW output.
Read Counter [A0h]
This command reads the value of the counter byte. The next nine clock cycles will output the contents of
this register.
Read Slope [A9h]
This command reads the value of the slope counter byte from the DS1620. The next nine clock cycles
will output the contents of this register.
Start Convert T [EEh]
This command begins a temperature conversion. No further data is required. In one–shot mode the
temperature conversion will be performed and then the DS1620 will remain idle. In continuous mode this
command will initiate continuous conversions.
Stop Convert T [22h]
This command stops temperature conversion. No further data is required. This command may be used to
halt a DS1620 in continuous conversion mode. After issuing this command the current temperature
measurement will be completed and then the DS1620 will remain idle until a Start Convert T is issued to
resume continuous operation.
Write Config [0Ch]
This command writes to the configuration register. After issuing this command the next eight clock cycles
clock in the value of the configuration register.
Read Config [ACh]
This command reads the value in the configuration register. After issuing this command the next eight
clock cycles output the value of the configuration register.
7 of 12
DS1620
DS1620 COMMAND SET Table 4
INSTRUCTION
Read Temperature
Read Counter
Read Slope
Start Convert T
Stop Convert T
Write TH
Write TL
Read TH
Read TL
Write Config
Read Config
3-WIRE BUS
DATA AFTER
ISSUING
DESCRIPTION
PROTOCOL PROTOCOL
TEMPERATURE CONVERSION COMMANDS
Reads last converted temperature
AAh
<read data>
value from temperature register.
Reads value of count remaining
A0h
<read data>
from counter.
Reads value of the slope
A9h
<read data>
accumulator.
Initiates temperature conversion.
EEh
Idle
Halts temperature conversion.
22h
Idle
THERMOSTAT COMMANDS
Writes high temperature limit value
01h
<write data>
into TH register.
Writes low temperature limit value
02h
<write data>
into TL register.
Reads stored value of high
A1h
<read data>
temperature limit from TH register.
Reads stored value of low
A2h
<read data>
temperature limit from TL register.
Writes configuration data to
0Ch
<write data>
configuration register.
Reads configuration data from
ACh
<read data>
configuration register.
NOTES
1
1
2
2
2
2
2
2
NOTES:
1. In continuous conversion mode, a Stop Convert T command will halt continuous conversion. To
restart, the Start Convert T command must be issued. In one–shot mode, a Start Convert T command
must be issued for every temperature reading desired.
2. Writing to the E2 requires up to 10 ms at room temperature. After issuing a write command no further
writes should be requested for at least 10 ms.
8 of 12
DS1620
FUNCTION EXAMPLE
Example: CPU sets up DS1620 for continuous conversion and thermostatic function.
DS1620 MODE
CPU MODE
(3-WIRE)
DATA (LSB FIRST)
COMMENTS
TX
RX
0Ch
CPU issues Write Config command
TX
RX
00h
CPU sets DS1620 up for continuous
conversion
CPU issues Reset to DS1620
TX
RX
Toggle RST
TX
RX
01h
CPU issues Write TH command
TX
RX
0050h
CPU sends data for TH limit of +40˚C
TX
RX
CPU
issues Reset to DS1620
Toggle RST
TX
RX
02h
CPU issues Write TL command
TX
RX
0014h
CPU sends data for TL limit of +10˚C
TX
RX
CPU issues Reset to DS1620
Toggle RST
TX
RX
A1h
CPU issues Read TH command
RX
TX
0050h
DS1620 sends back stored value of TH for
CPU to verify
CPU issues Reset to DS1620
TX
RX
Toggle RST
TX
RX
A2h
CPU issues Read TL command
RX
TX
0014h
DS1620 sends back stored value of TL for
CPU to verify
CPU issues Reset to DS1620
TX
RX
Toggle RST
TX
RX
EEh
CPU issues Start Convert T command
TX
RX
CPU issues Reset to DS1620
Drop RST
READ DATA TRANSFER Figure 4
9 of 12
DS1620
WRITE DATA TRANSFER Figure 5
NOTE: tCL, tCH, tR, and tF apply to both read and write data transfer.
ABSOLUTE MAXIMUM RATINGS*
Voltage on Any Pin Relative to Ground
Operating Temperature
Storage Temperature
Soldering Temperature
–0.5V to +6.0V
–55°C to +125°C
–55°C to +125°C
260°C for 10 seconds
* This is a stress rating 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.
RECOMMENDED DC OPERATING CONDITIONS
PARAMETER
Supply
Logic 1
Logic 0
SYMBOL
VDD
VIH
VIL
MIN
2.7
0.7 x VDD
-0.3
TYP
10 of 12
MAX
5.5
VCC + 0.3
0.3 x VDD
UNITS
V
V
V
NOTES
1,2
1
1
DS1620
DC ELECTRICAL CHARACTERISTICS
PARAMETER
Thermometer Error
Thermometer Resolution
Logic 0 Output
Logic 1 Output
Input Resistance
Active Supply Current
Standby Supply Current
Input Current on Each
Pin
Thermal Drift
SYMBOL
TERR
VOL
VOH
RI
ICC
ISTBY
(-55°C to +125°C; VDD=2.7V to 5.5V)
CONDITION
0°C to +70°C
3.0V ≤ VDD ≤ 5.5V
0°C to +70°C
2.7V ≤ VDD < 3.0V
-55°C to +125°C
MIN
MAX
±0.5
DQ, CLK to VDD
0°C to +70°C
0°C to +70°C
0.4 < VI/O < 0.9 x VDD
NOTES
2
±1.25
±2.0
12
0.4
RST to GND
UNITS
°C
1
1.5
+10
Bits
V
V
MW
MW
mA
µA
µA
±0.2
°C
2.4
1
1
-10
4
5
6
6
7
SINGLE CONVERT TIMING DIAGRAM (STAND-ALONE MODE)
CONV
tCNV
AC ELECTRICAL CHARACTERISTICS
PARAMETERS
Temperature Conversion Time
Data to CLK Setup
CLK to Data Hold
CLK to Data Delay
CLK Low Time
CLK High Time
CLK Frequency
CLK Rise and Fall
RST to CLK Setup
CLK to RST Hold
RST Inactive Time
CLK High to I/O High-Z
RST Low to I/O High-Z
Convert Pulse Width
SYMBOL
TTC
tDC
tCDH
tCDD
tCL
tCH
fCLK
tR , tF
tCC
tCCH
tCWH
tCDZ
tRDZ
tCNV
(-55°C to +125°C; VDD=2.7V to 5.5V)
MIN
TYP
MAX
750
35
40
150
285
285
DC
1.75
500
100
40
125
250 ns
11 of 12
50
50
500 ms
UNITS
ms
ns
ns
ns
ns
ns
MHz
ns
ns
ns
ns
ns
ns
NOTES
8
8
8, 9, 10
8
8
8
8
8
8, 11
8
8
12
DS1620
AC ELECTRICAL CHARACTERISTICS
PARAMETER
Input Capacitance
I/O Capacitance
EEPROM
SYMBOL
CI
CI/O
(-55°C to +125°C; VDD=2.7V to 5.5V)
MIN
TYP
5
10
MAX
UNITS
pF
pF
NOTES
AC ELECTRICAL CHARACTERISTICS
(-55°C to +125°C; VDD=2.7V to 5.5V)
PARAMETER
EEPROM Write Cycle Time
EEPROM Writes
EEPROM Data Retention
CONDITIONS
MIN
-55°C to +55°C
-55°C to +55°C
50k
10
TYP
4
MAX
10
UNITS
Ms
Writes
Years
NOTES:
1. All voltages are referenced to ground.
2. Valid for design revisions D1 and above. The supply range for Rev. C2 and below is 4.5V < 5.5V.
3. Thermometer error reflects temperature accuracy as tested during calibration.
4. Logic 0 voltages are specified at a sink current of 4 mA
5. Logic 1 voltages are specified at a source current of 1 mA.
6. ISTBY, ICC specified with DQ, CLK/ CONV = VDD, and RST = GND.
7. Drift data is based on a 1000hr stress test at +125°C with VDD = 5.5V
8. Measured at VIH = 0.7 x VDD or VIL = 0.3 x VDD.
9. Measured at VOH = 2.4V or VOL = 0.4V.
10. Load capacitance = 50 pF.
11. tCWH must be 10 ms minimum following any write command that involves the E2 memory.
12. 250ns is the guaranteed minimum pulse width for a conversion to start; however, a smaller pulse
width may start a conversion.
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
The Maxim logo and Maxim Integrated are trademarks of Maxim Integrated Products, Inc.