DS1726_技术文档

DS1626/DS1726

High-Precision 3-Wire Digital

Thermometer and Thermostat

www.maxim-ic.com

FEATURES

PIN CONFIGURATION

C Temperature Measurements Require No

External Components

8

C Measure Temperatures from -55°C to +125°C

(-67°F to +257°F)

1

2

3

V_DD

DQ

CLK/CNV

RST

7

6

5

T_HIGH

T_LOW

T_COM

C DS1626: M0.5°C Accuracy from 0°C to

+70°C

4

GND

C DS1726: M1°C Accuracy from -10°C to

+85°C

ꢀSOP

(DS1626U, DS1726U)

C Output Resolution is User-Selectable to 9, 10,

11, or 12 Bits

See Table 1 for Ordering Information

See Table 2 for Pin Descriptions

C Wide Power-Supply Range (2.7V to 5.5V)

C Convert Temperature to Digital Word in

750ms (max)

APPLICATIONS

C Stand-Alone Thermostat Capability

C Thermostatic Settings are User-Definable and

Nonvolatile (NV)

C Thermostatic Controls

C Industrial Controls

C Consumer Products

C Data is Read/Written Through a 3-Wire Serial

Interface

C Any Space-Constrained Thermally Sensitive

Application

C Available in 8-Pin ꢀMAX/ꢀSOP Package

DESCRIPTION

The DS1626 and DS1726 digital thermometers/thermostats provide temperature measurements and stand-

alone thermostat capability over a -55°C to +125°C range. The DS1626 offers ±0.5°C accuracy from 0°C to

+70°C and the DS1726 has ±1°C accuracy from -10°C to +85°C. The resolution of the measured

temperature is user-selectable from 9 to 12 bits. Communication with the DS1626 and DS1726 is achieved

through a 3-wire serial bus.

The DS1626 and DS1726 offer thermostatic functionality with three dedicated thermostat outputs (T_HIGH

,

T_LOW, and T_COM), and over-temperature (T_H) and under-temperature (T_L) user-programmable thresholds

stored in on-chip EEPROM. For stand-alone thermostat operation, T_Hand T_Lcan be programmed prior to

installation, and the DS1626/DS1726 can be configured to automatically begin taking temperature

measurements at power-up.

Pin descriptions for the DS1626 and DS1726 are provided in Table 2 and user-accessible registers are

summarized in Table 3. A functional diagram is shown in Figure 1.

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06/10/03

DS1626/DS1726

ORDERING INFORMATION

PART

PACKAGE MARKING

DESCRIPTION

DS1626U

D1626

D1726

8-Pin ꢀSOP

DS1626U/T&R

DS1726U

8-Pin ꢀSOP, 3000-Piece Tape-and-Reel

8-Pin ꢀSOP

8-Pin ꢀSOP, 3000-Piece Tape-and-Reel

DS1726U/T&R

Table 2. DETAILED PIN DESCRIPTION

PIN SYMBOL

FUNCTION

1

2

DQ

Data Input/Output Pin (Tri-State) for 3-Wire Serial Communication

Clock Input Pin for 3-Wire Serial Communication. Controls temperature

measurements when the DS1626/DS1726 is configured as a stand-alone thermostat

Reset Input Pin for 3-Wire Serial Communication

CLK/CNV

RST

GND

T_COM

T_LOW

T_HIGH

V_DD

3

4

5

6

7

8

Ground Pin

Thermostat Output Pin (Push-Pull) with Programmable Hysteresis

Thermostat Output Pin (Push-Pull) with T_LTrip Point

Thermostat Output Pin (Push-Pull) with T_HTrip Point

Supply Voltage. +2.7V to +5.5V Input Power Pin

Table 3. DS1626/DS1726 REGISTER SUMMARY

REGISTER NAME

(USER ACCESS)

Temperature

MEMORY

TYPE

REGISTER CONTENTS

AND POWER-UP/POR STATE

SIZE

Measured Temperature (Two’s Complement)

Power-Up/POR State: -60ºC (1100 0100 0000)

Upper Alarm Trip Point (Two’s Complement)

12 Bits

SRAM

(Read Only)

T_H

12 Bits

EEPROM Power-Up/POR State: User-Defined.

(Read/Write)

Initial State from Factory: +15°C (0000 1111 0000)

Lower Alarm Trip Point (Two’s Complement)

EEPROM Power-Up/POR State: User-Defined.

Initial State from Factory: +10°C (0000 1010 0000)

Configuration and Status Information (Unsigned)

SRAM and 4MSbs = SRAM and 4LSbs = EEPROM

EEPROM Power-Up/POR State: 1000XXXX (XXXX = User-

Defined)

T_L

(Read/Write)

Configuration

(Various Bits are

Read/Write and Read

Only—See Table 5)

1 Byte

Figure 1. DS1626/DS1726 FUNCTIONAL DIAGRAM

V_DD

CONFIGURATION REGISTER AND CONTROL LOGIC

GND

TEMPERATURE SENSOR AND ꢀꢁ ADC

ADDRESS

and

TEMPERATURE REGISTER

I/O CONTROL

CLK/CNV

SDA

T_HREGISTER

DIGITAL

T_COM

T_HIGH

T_LOW

COMPARATOR/LOGIC

T_LREGISTER

RST

2 of 13

DS1626/DS1726

ABSOLUTE MAXIMUM RATINGS*

Voltage on Any Pin Relative to Ground

Operating Temperature Range

Storage Temperature Range

-0.5V to +6.0V

-55°C to +125°C

+260°C

Solder Dip Temperature (10s)

Reflow Oven Temperature

+220°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

(V_DD= 2.7V to 5.5V; T_A= -55°C to +125°C.)

PARAMETER

SYMBOL

CONDITIONS

MIN

TYP

MAX

UNITS

Supply Voltage

V_DD

(Note 1)

2.7

5.5

V

0°C to +70°C,

±0.5

3.0V ? V_DD? 5.5V

0°C to +70°C,

DS1626

Thermometer Error

(Note 2)

T_ERR

°C

±1.25

±2

2.7V ? V_DDꢁ 3.0V

-55°C to +125°C

-10°C to +85°C,

3.0V ? V_DD? 5.5V

-10°C to +85°C,

2.7V ? V_DDꢁ 3.0V

-55°C to +125°C

±1

DS1726

Thermometer Error

(Note 2)

T_ERR

±1.5

±2

Low-Level Input

Voltage

V_IL

V_IH

(Note 1)

-0.5

0.7 x V_DD

-10

0.3 x V_DD

V

High-Level Input

Voltage

(Note 1)

V_DD+ 0.3

Input Current each

Input Pin

0.4 < V_I/O< 0.9 x V_DD

+10

1

µA

Temperature conversion

-55°C to +85°C

Temperature conversion

+85°C to +125°C

E²write

mA

Active Supply

I_DD

R_I

Current (Note 3)

1.25

400

µA

RST to GND

Input Resistance

1

Mꢂ

DQ, CLK to V_DD

Standby Supply

Current

I_STBY

V_OH

0°C to +70°C (Note 3)

1mA source current

1.5

0.4

µA

THIGH, TLOW,

TCOM, DQ Output

Logic Voltages

(Note 1)

2.4

V

V_OL

4mA sink current

(Note 4)

Thermal Drift

±0.2

°C

3 of 13

DS1626/DS1726

EEPROM AC ELECTRICAL CHARACTERISTICS

(V_DD= 2.7V to 5.5V; T_A= -55°C to +125°C.)

PARAMETER

EEPROM Write Cycle Time

EEPROM Writes

SYMBOL CONDITIONS

MIN

TYP

MAX UNITS

t_wr

4

10

ms

Writes

Years

N_EEWR

t_EEDR

-55°C to +55°C

50k

10

EEPROM Data Retention

AC ELECTRICAL CHARACTERISTICS

(V_DD= 2.7V to 5.5V; T_A= -55°C to +125°C.)

PARAMETER

SYMBOL CONDITIONS

MIN

TYP

MAX UNITS

9-bit

93.75

10-bit

11-bit

187.5

Temperature Conversion Time

t_TC

ms

375

12-bit

750

ns

Data In to Clock Setup

Clock to Data In Hold

Clock to Data Out Delay

Clock Low/High Time

Clock Frequency

t_DC

t_CDH

t_CDD

t_CL, t_CH

f_CLK

t_R, t_F

t_RC

(Note 5)

(Notes 5, 6)

(Note 5)

(Note 7)

(Note 5)

(Note 8)

35

40

ns

150

285

0

1.75

500

MHz

ns

Clock Rise/Fall Time

RST to Clock Setup

Clock to RST Hold

RST Inactive Time

Clock High to I/O Hi-Z

RST Low to I/O Hi-Z

CNV Pulse Width

100

40

125

ns

t_CRH

t_RI

ns

t_CDZ

t_RDZ

t_CNV

C_I/O

C_I

50

500ms

ns

250ns

I/O Capacitance

Input Capacitance

10

5

pF

NOTES:

1) All voltages are referenced to ground.

2) See Figure 2 for TYPICAL OPERATING CURVES.

3) I_STBY, I_DDspecified with DQ, CLK/CNV = V_DDand RST = GND.

4) Drift data is based on a 1000hr stress test at +125°C with V_DD= 5.5V.

5) See Timing Diagrams in Figure 3. All timing is referenced to 0.7 x V_DDand 0.3 x V_DD.

6) Load capacitance = 50pF.

7) t_RImust be 10ms minimum following any write command that involves the E²memory.

8) 250ns is the guaranteed minimum pulse width for a conversion to start, however, a smaller pulse

width may start a conversion.

4 of 13

DS1626/DS1726

Figure 2. TYPICAL OPERATING CURVES

DS1626

DS1726

0.8

0.6

0.4

0.2

0

-0.2

-0.4

-0.6

-0.8

-1

0.8

0.6

0.4

0.2

0

+3ꢂ

-3ꢂ

-0.2

-0.4

-0.6

-0.8

-1

MEAN

-3ꢂ

0

10

20

30

40

50

60

70

-10

0

10 20 30 40 50 60 70 80

REFERENCE TEMPERATURE (°C)

Figure 3. TIMING DIAGRAMS

a) Read Timing

t_CRH

t_RC

b) Write Timing

t_RI

t_CRH

t_RC

5 of 13

DS1626/DS1726

OPERATION—MEASURING TEMPERATURE

The DS1626/DS1726 measure temperature using a bandgap-based temperature sensor. A delta-sigma

analog-to-digital converter (ADC) converts the measured temperature to a digital value that is

calibrated in degrees centigrade; for Fahrenheit applications a lookup table or conversion routine must

be used. Communication with the DS1626/DS1726 is achieved through a 3-wire serial interface, and

all data is transmitted LSb first.

The DS1626/DS1726 can be programmed to take continuous temperature measurements (continuous

conversion mode) or to take single temperature measurements on command (one-shot mode). The

measurement mode is programmed by the 1SHOT bit in the configuration register as explained in the

CONFIGURATION REGISTER section of this data sheet. The 1SHOT bit is stored in EEPROM, so it

can be programmed prior to installation if desired. In continuous conversion mode, when a Start

Convert T command is issued the DS1626/DS1726 perform consecutive temperature measurements

until a Stop Convert T command is issued. In one-shot mode, the Start Convert T command causes one

temperature measurement to be taken and then the DS1626/DS1726 return to a low-power idle state.

The resolution of the DS1626/DS1726 digital temperature data is user-configurable to 9, 10, 11, or 12

bits, corresponding to temperature increments of 0.5LC, 0.25LC, 0.125LC, and 0.0625LC, respectively.

The resolution is set by the EEPROM R0 and R1 bits in the configuration register. Note that the

conversion time doubles for each additional bit of resolution.

After each temperature measurement and analog-to-digital conversion, the DS1626/DS1726 store the

measured temperature as a two’s complement number in the 12-bit temperature register (see Figure 4).

The sign bit (S) indicates if the temperature is positive or negative: for positive numbers S = 0 and for

negative numbers S = 1. The Read Temperature command provides user access to the temperature

register.

When the DS1626/DS1726 are configured for 12-bit resolution, all 12 bits of the temperature register

will contain temperature data. For 11-bit resolution, the 11 MSbs (bits 11 through 1) of the temperature

register will contain data and bit 0 will read out as 0. Likewise, for 10-bit resolution, the 10 MSbs (bits

11 through 2) will contain data, and for 9-bit the 9 MSbs (bits 11 through 3) will contain data, and all

unused LSbs will contain 0s. Since the DS1626/DS1726 transmit data LSb first, when reading data

from the temperature register, all 12 bits must be read in order to receive all MSbs of the measured

data, regardless of the conversion resolution. Table 4 gives examples of 12-bit resolution digital output

data and the corresponding temperatures.

Figure 4. TEMPERATURE, T_H, and T_LREGISTER FORMAT

bit 11

bit 10

bit 19

bit 8

bit 7

bit 6

bit 5

bit 4

bit 3

bit 2

bit 1

bit 0

2^-4

S

2⁶

2⁵

2⁴

2³

2²

2¹

2⁰

2^-1

2^-2

2^-3

6 of 13

DS1626/DS1726

Table 4. 12-BIT RESOLUTION TEMPERATURE/DATA RELATIONSHIP

TEMPERATURE

DIGITAL OUTPUT

(BINARY)

(HEX)

(LC)

+125

+25.0625

+10.125

+0.5

0

-0.5

-10.125

-25.0625

-55

0111 1101 0000

0001 1001 0001

0000 1010 0010

0000 0000 1000

0000 0000 0000

1111 1111 1000

1111 0101 1110

1110 0110 1111

1100 1001 0000

7D0h

191h

0A2h

008h

000h

FF8h

F5Eh

E6Fh

C90h

OPERATION—THERMOSTAT FUNCTION

The DS1626/DS1726 thermostat outputs (T_HIGH, T_LOW, and T_COM) are updated after every temperature

conversion and remain at the updated values until the next conversion completes. T_HIGHis asserted

when the measured temperature is higher than or equal to the value stored in the T_Hregister, and T_LOW

is asserted when the temperature is equal to or falls below the value in the T_Lregister (see Figure 5).

T_COMuses both T_Hand T_Lto provide programmable hysteresis: when the measured temperature equals

or exceeds T_H, T_COMis asserted and it remains asserted until the temperature falls to a value equal to or

below T_L. All three thermostat outputs are active-high outputs.

The Write TH and Write TL commands are used to program the 12-bit T_Hand T_Lregisters with user-

defined two’s complement values. The MSb (bit 11) of each register contains the two’s complement

sign bit (S). For the T_COMthermostat output to function correctly, the T_Lvalue must be less than the T_H

value. Any unused LSbs in the T_Hand T_Lregisters are forced to 0 regardless of the data written to

those bits. The unused LSbs are determined by the conversion resolution set by R1 and R0 in the

configuration register. Therefore, for 9-bit conversions bits 2 through 0 will be 0, for 10-bit

conversions bit 1 and bit 0 will be 0, and for 11-bit conversions bit 0 will be 0. All bits are used for 12-

bit conversions, so no bits are forced to 0. However, regardless of the conversion resolution, when

writing to T_Hor T_Lat least 12 bits must be sent following the Write TH or Write TL commands. The

reason is that data written to T_Hand T_Lis not saved to EEPROM until the DS1626/DS1726 have

received 12 bits, so if the operation is terminated before 12 bits have been received, the data will be

lost. Any additional bits sent after the first twelve are ignored (e.g., if two 8-bit words are written).

Another DS1626/DS1726 thermostat feature is the temperature-high flag (THF) and temperature-low

flag (TLF) in the configuration register. These bits provide a record of whether the temperature has

been greater than or equal to T_Hor less than or equal to T_Lat any time since the DS1626/DS1726 were

powered up. If the temperature is greater than or equal to the T_Hregister value, the THF bit in the

configuration register will be set to 1. If the temperature is less than or equal to the T_Lregister value,

the TLF bit in the configuration register will be set to 1. Once THF and/or TLF has been set, it will

remain set until the user overwrites it with a 0 or until the power is cycled.

7 of 13

DS1626/DS1726

CPU BIT AND STAND-ALONE THERMOSTAT OPERATION

In stand-alone thermostat mode, DS1626/DS1726 thermostat functionality can be used without

requiring a microcontroller to start/stop temperature conversions. The CPU bit in the configuration

register determines if stand-alone mode is enabled.

When CPU = 1 stand-alone mode is disabled, and the only way to start/stop temperature conversions is

by using a microcontroller to transmit Start Convert T and Stop Convert T commands, respectively.

Stand-alone mode is enabled when CPU = 0. In this mode, when RST = 0 the CLK/CNV pin operates

as a control signal to start and stop temperature measurements. Driving CLK/CNV low initiates

continuous temperature conversions that will continue until CLK/CNV is brought high again. If the

CLK/CNV pin is driven low and then returned to a high state in less than 10ms, only one temperature

conversion will be performed after which the DS1626/DS1726 will return to a low-power idle state

(i.e., one-shot operation). Note that when stand-alone mode is enabled, the 1SHOT bit in the

configuration register is ignored, and only the CLK/CNV signal determines whether continuous or

one-shot conversions take place.

Since T_H, T_L, and the CPU bit are stored in EEPROM, the DS1626/DS1726 can be preprogrammed for

stand-alone operation. If desired, the CLK/CNV and RST pin can be connected to GND so the

DS1626/DS1726 will automatically begin taking temperature measurements at power-up

Normal bus communication with the DS1626/DS1726 can still take place in stand-alone mode when

RST = 1. When communication is initiated, stand-alone conversions are automatically halted. If during

the bus communication continuous temperature conversions are started using the Start Convert T

command, they can only be stopped by issuing a Stop Convert T command.

8 of 13

DS1626/DS1726

Figure 5. THERMOSTAT OUTPUT OPERATION

T_H

T_L

LOGIC 1

T_COM

LOGIC 0

TEMP

LOGIC 1

T_HIGH

LOGIC 0

TEMP

LOGIC 1

T_LOW

LOGIC 0

CONFIGURATION REGISTER

The configuration register allows the user to customize the DS1626/DS1726 conversion and

thermostat options. It also provides information to the user about conversion status, EEPROM activity,

and thermostat activity. The configuration register is arranged as shown in Figure 6 and detailed

descriptions of each bit are provided in Table 5. This register can be accessed using the Read Config

and Write Config commands. Note that the R1, R0, CPU, and 1SHOT bits are stored in EEPROM and

all other configuration register bits are SRAM.

Figure 6. CONFIGURATION REGISTER

MSb

bit 6

bit 5

bit 4

bit 3

bit 2

bit 1

LSb

DONE THF

*NV (EEPROM)

TLF

NVB

R1*

R0*

CPU* 1SHOT*

9 of 13

DS1626/DS1726

Table 5. CONFIGURATION REGISTER BIT DESCRIPTIONS

BIT NAME

FUNCTIONAL DESCRIPTION

(USER ACCESS)

Power-up state = 1.

DONE

DONE = 0. Temperature conversion is in progress.

(Read Only)

DONE = 1. Temperature conversion is complete.

Power-up state = 0.

THF

THF = 1. The measured temperature has reached or exceeded the value stored in

the T_Hregister. THF will remain a 1 until it is overwritten with a 0 by the user,

the power is cycled, or a Software POR command is issued.

Power-up state = 0.

(Read/Write)

TLF

TLF = 1. The measured temperature has equaled or dropped below the value

stored in the T_Lregister. TLF will remain a 1 until it is overwritten with a 0 by

the user, the power is cycled, or a Software POR command is issued.

Power-up state = 0.

(Read/Write)

NVB

NVB = 1. Write to an E²memory cell is in progress.

NVB = 0. NV memory is not busy.

(Read Only)

Power-up state = last value written to this bit.

R1*

Sets conversion resolution (see Table 6).

(Read/Write)

Initial state from factory = 1.

Power-up state = last value written to this bit.

R0*

Sets conversion resolution (see Table 6).

(Read/Write)

Initial state from factory = 1.

Power-up state = last value written to this bit.

CPU = 1. Stand-alone mode is disabled.

CPU*

CPU = 0. Stand-alone mode is enabled when RST = 0. See CPU BIT AND

STAND-ALONE THERMOSTAT OPERATION section for more information.

Initial state from factory = 0.

(Read/Write)

Power-up state = last value written to this bit.

1SHOT = 1: One-Shot Mode. The Start Convert T command initiates a single

temperature conversion and then the device goes into a low-power standby state.

1SHOT = 0: Continuous Conversion Mode. The Start Convert T command

initiates continuous temperature conversions.

1SHOT*

(Read/Write)

Initial state from factory = 0.

*NV (EEPROM)

Table 6. RESOLUTION CONFIGURATION

CONVERSION

TIME (MAX)

R1

R0 RESOLUTION

0

1

0

1

0

1

9-bit

10-bit

11-bit

12-bit

93.75ms

187.5ms

375ms

750ms

10 of 13

DS1626/DS1726

3-WIRE SERIAL DATA BUS

The 3-wire bus consists of three signals: RST (reset—active low), CLK (clock), and DQ (data). 3-wire

communication is controlled by the RST signal, which functions as “chip select” signal. All data is

transferred LSb first over the 3-wire bus. All communication with the DS1626/DS1726 is initiated by

driving RST high. Driving RST low terminates communications and causes DQ to go to a high-

impedance state. Note that RST must be toggled low after every communication sequence to ensure

that subsequent commands are recognized by the DS1626/DS1726.

When writing to the DS1626/DS1726, data must be valid during the rising edge of CLK. During read

operations the DS1626/DS1726 output data on DQ on the falling edge of CLK and the data remains

valid through the following rising edge, at which time the DQ pin becomes high impedance until the

next falling edge.

To communicate with the DS1626/DS1726, the master must first drive RST high and then begin

generating the CLK signal while transmitting the desired DS1626/DS1726 command byte. If the

command is a Start Convert T, Stop Convert T, or Software POR command, the transaction is finished

when the last bit of the command has been sent. Figure 7a illustrates a Start Convert T command

sequence.

When writing to the DS1626/DS1726, the master must begin transmitting data during the clock cycle

immediately following the command byte. The DS1626/DS1726 will save only the number of data bits

needed for the specific transaction. For example, for the Write TH or Write TL commands, after

twelve bits of data have been transmitted by the master, the DS1626/DS1726 will ignore any

subsequent data transmitted before RST goes low. Thus, if data is being transmitted in byte-length

segments, the DS1626/DS1726 will load the first twelve bits into the T_H/T_Lregister, and the next four

bits will be ignored. On the other hand, it is necessary to transmit at least the required number of bits

for the requested transaction (i.e., 12-bits to T_H/T_Lor 8-bits to the configuration register), because the

DS1626/DS1726 will not save data until the expected number of bits have been received. Write TH

and Write TL sequences are illustrated in Figure 7b and a Write Config sequence is shown in Figure

7c. Note that these figures assume byte-wide data transfers.

When reading data from the DS1626/DS1726, the DS1626/DS1726 will begin sending data during the

clock cycle immediately following the command byte. After the last data byte has been sent, the

DS1626/DS1726 will transmit a 0 during each subsequent clock until RST goes low. Figure 7d

illustrates a Read Temperature sequence and a Read Config transaction is shown in Figure 7e. The

sequence for reading the T_Hor T_Lregisters is the same as the Read Temp transaction in Figure 7d

except that the Read TH or Read TL command is used.

11 of 13

DS1626/DS1726

Figure 7. 3-WIRE COMMUNICATION

a) Start Temperature Conversion

RST

CLK

DQ

1

0

1

0

1

0

Start Convert T [51h] Command

b) Write to the T_H/T_LRegisters

ꢃ ꢃ ꢃ

RST

CLK

DQ

ꢃ ꢃ ꢃ

0

C₀C₁

0

D₀D₁D₂D₃D₄D₅D₆D₇D₈D₉D₁₀

T_Hor T_LData from Master

D₁₁

Write TH [01h] or TL [02h] Command

c) Write to the Configuration Register

RST

CLK

DQ

0

1

0

D₀D₁

D₅D₆D₇

D₂D₃

D₄

Write Config [0Ch] Command

Configuration Reg. Data from Master

d) Read from the Temperature Register

ꢃ ꢃ ꢃ

RST

CLK

ꢃ ꢃ ꢃ

_DQ1

D₀D₁

0

1

0

1

0

1

0

1

D₂D₃D₄D₅D₆D₇D₈D₉

D

10

D

11

0

Read Temperature [AAh] Command

Temperature Data from DS1626/DS1726

e) Read from the Configuration Register

RST

CLK

DQ

0

1

0

1

0

1

D₀

D₁

D₅

D₇

D₂

D₃D₄

D₆

Read Config [ACh] Command

Configuration Reg. Data from DS1626/DS1726

12 of 13

DS1626/DS1726

DS1626/DS1726 COMMAND SET

The DS1626/DS1726 command set is detailed below:

Start Convert T

51h 0101 0001

Initiates temperature conversions. If the DS1626/DS1726 are in one-shot mode (1SHOT = 1), only one

conversion will be performed. If the devices are in continuous mode (1SHOT = 0), continuous

conversions will be performed until a Stop Convert T command is issued.

Stop Convert T

22h 0010 0010

Stops temperature conversions when the devices are in continuous conversion mode (1SHOT = 0).

Read Temperature AAh 1010 1010

Reads the last converted temperature value from the temperature register.

Read TH A1h 1010 0001

Reads the 12-bit T_Hregister.

Read TL

A2h 1010 0010

Reads the 12-bit T_Lregister.

Write TH*

01h 0000 0001

Writes the 12-bit T_Hregister.

Write TL*

02h 0000 0010

Writes the 12-bit T_Lregister.

Read Config

ACh 1010 1100

Reads the 1-byte configuration register.

Write Config*

0Ch 0000 1100

Writes the 1-byte configuration register.

Software POR

54h 0101 0100

Initiates a software power-on reset (POR), which stops temperature conversions and resets all registers

and logic to their power-up states. The software POR allows the user to simulate cycling the power

without actually powering down the device.

*After issuing a write command, no further writes should be requested for at least 10ms due to the

EEPROM write cycle time.

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型号：	DS1726
厂家：	DALLAS SEMICONDUCTOR
描述：	High-Precision 3-Wire Digital Thermometer and Thermostat 高精度，3线数字温度计和温度监控器监控
文件：	总13页 (文件大小：217K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

DS1726 [DALLAS]

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