EVAL-ADT7410EBZ_技术文档

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ꢁT74ꢀ±

FEATURES

GENERAL DESCRIPTION

13- or 16-bit user selectable temperature-to-digital converter

Temperature accuracy: 0.5°C from −40°C to +105°C

No temperature calibration/correction required by user

Power saving 1 sample per second (SPS) mode

Fast first conversion on power-up of 6 ms

I²C-compatible interface

The ADT7410 is a high accuracy digital temperature sensor

in a narrow SOIC package. It contains a band gap temperature

reference and a 13 bit ADC to monitor and digitize the temper-

ature to a 0.0625°C resolution. The ADC resolution, by default,

is set to 13 bits (0.0625°C). This can be changed to 16 bits

(0.0078°C) by setting Bit 7 in the configuration register

(Register Address 0x03).

Operating temperature: −55°C to +150°C

Operating voltage: 2.7 V to 5.5 V

The ADT7410 is guaranteed to operate over supply voltages from

2.7 V to 5.5 V. Operating at 3.3 V, the average supply current is typi-

cally 210 μA. The ADT7410 has a shutdown mode that powers

down the device and offers a shutdown current of typically 2 μA.

The ADT7410 is rated for operation over the −55°C to +150°C

temperature range.

Critical overtemperature indicator

Programmable overtemperature/undertemperature interrupt

Low power consumption: 700 μW typical at 3.3 V

Shutdown mode for lower power: 7 μW typical at 3.3 V

8-lead narrow SOIC RoHS-compliant package

APPLICATIONS

Medical equipment

Pin A0 and Pin A1 are available for address selection, giving the

ADT7410 four possible I²C® addresses. The CT pin is an open-

drain output that becomes active when the temperature exceeds

a programmable critical temperature limit. The default critical

temperature limit is 147°C. The INT pin is also an open-drain

output that becomes active when the temperature exceeds a

programmable limit. The INT and CT pins can operate in either

comparator or interrupt mode.

Environmental control systems

Computer thermal monitoring

Thermal protection

Industrial process control

Power system monitors

Hand-held applications

FUNCTIONAL BLOCK DIAGRAM

V

DD

8

TEMPERATURE

VALUE

ADT7410

REGISTER

INTERNAL

6

5

CT

OSCILLATOR

CONFIGURATION

REGISTER

T

CRIT

HIGH

LOW

INTERNAL

T

REFERENCE

CRIT

REGISTER

INT

Σ-Δ

MODULATOR

TEMPERATURE

SENSOR

T

HIGH

REGISTER

T

LOW

REGISTER

T

POINTER

REGISTER

FILTER

LOGIC

HYST

REGISTER

3

4

1

2

A0

A1

SCL

SDA

2

I C INTERFACE

7

GND

Figure 1.

Rev. 0

Information furnished by Analog Devices is believed to be accurate and reliable. However, no

responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other

rights of third parties that may result from its use. Specifications subject to change without notice. No

license is granted by implication or otherwise under any patent or patent rights of Analog Devices.

Trademarks and registeredtrademarks arethe property of their respective owners.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 781.329.4700

Fax: 781.461.3113

www.analog.com

ꢁT74ꢀ±C

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T -LECOFC°ONTENTSC

Features .............................................................................................. 1

Temperature Value Registers .................................................... 13

Status Register............................................................................. 14

Configuration Register .............................................................. 14

T_HIGHSetpoint Registers............................................................. 15

T_LOWSetpoint Registers.............................................................. 15

T_CRITSetpoint Registers.............................................................. 15

T_HYSTSetpoint Register............................................................... 16

ID Register................................................................................... 16

Serial Interface ................................................................................ 17

Serial Bus Address...................................................................... 17

Writing Data ............................................................................... 18

Reading Data............................................................................... 19

Reset............................................................................................. 19

General Call ................................................................................ 19

INT and CT Outputs...................................................................... 21

Undertemperature and Overtemperature Detection ............ 21

Applications Information.............................................................. 23

Thermal Response Time ........................................................... 23

Supply Decoupling ..................................................................... 23

Temperature Monitoring........................................................... 23

Outline Dimensions....................................................................... 24

Ordering Guide .......................................................................... 24

Applications....................................................................................... 1

General Description......................................................................... 1

Functional Block Diagram .............................................................. 1

Revision History ............................................................................... 2

Specifications..................................................................................... 3

I²C Timing Specifications............................................................ 4

Absolute Maximum Ratings............................................................ 5

ESD Caution.................................................................................. 5

Pin Configuration and Function Descriptions............................. 6

Typical Performance Characteristics ............................................. 7

Theory of Operation ........................................................................ 9

Circuit Information...................................................................... 9

Converter Details.......................................................................... 9

Temperature Measurement ......................................................... 9

One-Shot Mode .......................................................................... 10

1 SPS Mode.................................................................................. 10

Shutdown..................................................................................... 11

Fault Queue ................................................................................. 11

Temperature Data Format......................................................... 12

Temperature Conversion Formulas ......................................... 12

Registers........................................................................................... 13

Address Pointer Register ........................................................... 13

REVISION HISTORY

4/09—Revision 0: Initial Version

Rev. 0 | Page 2 of 24

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ꢁT74ꢀ±

SPE°IFI° TIONSC

T_A= −55°C to +150°C, V_DD= 2.7 V to 5.5 V, unless otherwise noted.

Table 1.

Parameter

Min

Typ

Max

Unit

Test Conditions/Comments

TEMPERATURE SENSOR AND ADC

Accuracy¹

0.ꢀ

0.7

0.ꢁ

1.0

°C

T_A= −40°C to +10ꢀ°C, V_DD= 2.7 V to 3.6 V

T_A= −ꢀꢀ°C to +1ꢀ0°C, V_DD= 2.7 V to 3.6 V

T_A= −40°C to +10ꢀ°C, V_DD= 4.ꢀ V to ꢀ.ꢀ V

T_A= −ꢀꢀ°C to +1ꢀ0°C, V_DD= 2.7 V to ꢀ.ꢀ V

ADC Resolution

13

16

Bits

Twos complement temperature value of the sign bit

plus 12 ADC bits (power-up default resolution)

Twos complement temperature value of the sign bit

plus 1ꢀ ADC bits (Bit 7 = 1 in the configuration register)

Bits

Temperature Resolution

13-Bit

16-Bit

Temperature Conversion Time

Fast Temperature ConversionTime

1 SPS Conversion Time

Temperature Hysteresis

Repeatability

0.062ꢀ

0.007ꢁ

240

6

°C

ms

°C

13-bit resolution (sign + 12-bit)

16-bit resolution (sign + 1ꢀ-bit)

Continuous conversion and one-shot conversion modes

First conversion on power-up only

Conversion time for 1 SPS mode

Temperature cycle = 2ꢀ°C to 12ꢀ°C and back to 2ꢀ°C

T_A= 2ꢀ°C

60

0.02

0.01

0.1

°C

DC PSRR

°C/V

T_A= 2ꢀ°C

DIGITAL OUTPUTS (OPEN DRAIN)

High Output Leakage Current, I_OH

Output High Current

Output Low Voltage, V_OL

Output High Voltage, V_OH

Output Capacitance, C_OUT

DIGITAL INPUTS

0.1

ꢀ

1

0.4

μA

mA

V

pF

CT and INT pins pulled up to ꢀ.ꢀ V

V_OH= ꢀ.ꢀ V

I_OL= 2 mA @ ꢀ.ꢀ V, I_OL= 1 mA @ 3.3 V

0.7 × V_DD

3

Input Current

1

0.4

μA

V

ns

pF

V_IN= 0 V to V_DD

Input Low Voltage, V_IL

Input High Voltage, V_IH

SCL, SDA Glitch Rejection

Pin Capacitance

0.7 × V_DD

ꢀ0

ꢀ

Input filtering suppresses noise spikes of less than ꢀ0 ns

10

POWER REQUIREMENTS

Supply Voltage

2.7

ꢀ.ꢀ

V

Supply Current

At 3.3 V

At ꢀ.ꢀ V

210

230

2ꢀ0

300

μA

Peak current while converting, I²C interface inactive

1 SPS Current

At 3.3 V

At ꢀ.ꢀ V

46

6ꢀ

μA

V_DD= 3.3 V, 1 SPS mode, T_A= 2ꢀ°C

V_DD= ꢀ.ꢀ V, 1 SPS mode, T_A= 2ꢀ°C

Shutdown Current

At 3.3 V

At ꢀ.ꢀ V

Power Dissipation Normal Mode

Power Dissipation 1 SPS

2.0

4.4

700

1ꢀ0

1ꢀ

2ꢀ

μA

μW

Supply current in shutdown mode

V_DD= 3.3 V, normal mode at 2ꢀ°C

Power dissipated forV_DD= 3.3 V, T_A= 2ꢀ°C

¹Accuracy includes lifetime drift.

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I²C TIMING SPECIFICATIONS

T_A= −55°C to +150°C, V_DD= 2.7 V to 5.5 V, unless otherwise noted. All input signals are specified with rise time (t_R) = fall time (t_F) = 5 ns

(10% to 90% of V_DD) and timed from a voltage level of 1.6 V.

Table 2.

Parameter

SERIAL INTERFACE^{1, 2}

Min Typ Max

Unit

Test Conditions/Comments

See Figure 2

SCL Frequency

0

0.6

1.3

400

kHz

μs

SCL High Pulse Width, t_HIGH

SCL Low Pulse Width, t_LOW

SCL, SDA Rise Time, t_R

SCL, SDA Fall Time, t_F

Hold Time (Start Condition), t_HD;STA

Setup Time (Start Condition), t_SU;STA

Data Setup Time, t_SU;DAT

0.3

0.6

0.2ꢀ

0.3ꢀ

0.6

0

After this period, the first clock is generated

Relevant for repeated start condition

V_DD≥ 3.0 V

V_DD< 3.0 V

Setup Time (Stop Condition), t_SU;STO

Data Hold Time, t_HD;DAT(Master)

Bus-Free Time (Between Stop and Start Condition), t_BUF

1.3

¹Sample tested during initial release to ensure compliance.

²All input signals are specified with input rise/fall times = 3 ns, measured between the 10% and 90% points. Timing reference points at ꢀ0% for inputs and outputs.

Output load = 10 pF.

Timing Diagram

t_R

t_F

t_LOW

t_HD:STA

SCL

SDA

t_HIGH

t_SU:STA

t_SU:STO

t_HD:STA

t_HD:DAT

t_SU:DAT

t_BUF

S

P

S

P

Figure 2. Serial Interface Timing Diagram

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ꢁT74ꢀ±

-SOLUTECM XIMUMCR TINGSC

Table 3.

Stresses above those listed under Absolute Maximum Ratings

may cause permanent damage to the device. This is a stress

rating only; functional operation of the device at these or any

other conditions above those indicated in the operational

section of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect

device reliability.

Parameter

Rating

V_DDto GND

SDA Voltage to GND

−0.3 V to +7 V

−0.3 V to V_DD+ 0.3 V

2.0 kV

−ꢀꢀ°C to +1ꢀ0°C

−6ꢀ°C to +160°C

1ꢀ0°C

SCL Output Voltage to GND

A0 Input Voltage to GND

A1 Input Voltage to GND

CT and INT Output Voltage to GND

ESD Rating (Human Body Model)

Operating Temperature Range

Storage Temperature Range

Maximum Junction Temperature, T_JMAX

ꢁ-Lead SOIC-N (R-ꢁ)

1.2

1.0

0.8

0.6

0.4

Power Dissipation¹

Thermal Impedance³

W_MAX= (T_JMAX− T_A²)/θ_JA

θ_JA, Junction-to-Ambient (Still Air)

θ_JC, Junction-to-Case

121°C/W

ꢀ6°C/W

IR Reflow Soldering

Peak Temperature (RoHS-Compliant

Package)

220°C

260°C (0°C)

0.2

MAX PD = 3.4mW AT 150°C

0

Time at Peak Temperature

Ramp-Up Rate

Ramp-Down Rate

20 sec to 40 sec

TEMPERATURE (°C)

3°C/sec maximum

−6°C/sec maximum

ꢁ minutes maximum

Figure 3. SOIC_N Maximum Power Dissipation vs. Temperature

Time from 2ꢀ°C to Peak Temperature

ESD CAUTION

¹Values relate to package being used on a standard 2-layer PCB. This gives a

worst-case θ_JAand θ_JC. See Figure 3 for a plot of maximum power dissipation

vs. ambient temperature (T_A).

²T_A= ambient temperature.

³Junction-to-case resistance is applicable to components featuring a

preferential flow direction, for example, components mounted on a heat

sink. Junction-to-ambient is more useful for air-cooled, PCB-mounted

components.

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PINC°ONFIGUR TIONC NꢁCFUN°TIONCꢁES°RIPTIONSC

SCL

SDA

A0

1

2

3

4

8

7

6

5

V

DD

ADT7410

GND

CT

TOP VIEW

(Not to Scale)

A1

INT

Figure 4. Pin Configuration

Table 4. Pin Function Descriptions

Pin No. Mnemonic Description

1

SCL

I²C Serial Clock Input. The serial clock is used to clock in and clock out data to and from any register of the ADT7410.

Open-drain configuration. A pull-up resistor is required, typically 10 kΩ.

2

SDA

I²C Serial Data Input/Output. Serial data to and from the part is provided on this pin. Open-drain configuration. A

pull-up resistor is required, typically 10 kΩ.

3

4

ꢀ

A0

A1

INT

I²C Serial Bus Address Selection Pin. Logic input. Connect to GND or V_DDto set an I²C address.

Overtemperature and Undertemperature Indicator. Logic output. Power-up default setting is as an active low

comparator interrupt. Open-drain configuration. A pull-up resistor is required, typically 10 kΩ.

6

CT

Critical Overtemperature Indicator. Logic output. Power-up default polarity is active low. Open-drain configuration.

A pull-up resistor is required, typically 10 kΩ.

7

ꢁ

GND

V_DD

Analog and Digital Ground.

Positive Supply Voltage (2.7 V to ꢀ.ꢀ V). The supply should be decoupled with a 0.1 μF ceramic capacitor to ground.

Rev. 0 | Page 6 of 24

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ꢁT74ꢀ±

TYPI° LCPERFORM N°EC°H R °TERISTI°SC

0.30

0.25

0.20

0.15

0.10

0.05

0

1.0

5.5V CONTINUOUS

CONVERSION

0.8

0.6

0.4

MAX ACCURACY LIMITS

3.0V CONTINUOUS

CONVERSION

0.2

0

–0.2

–0.4

–0.6

–0.8

–1.0

5.5V 1SPS

3.0V 1SPS

MAX ACCURACY LIMITS

–60 –40 –20

0

20

40

60

80 100 120 140 160

–100

–50

0

50

100

150

200

TEMPERATURE (°C)

Figure 5. Temperature Accuracy at 3 V

Figure 7. Operating Supply Current vs. Temperature

1.0

0.8

30

25

20

15

10

5

MAX ACCURACY LIMITS

0.6

0.4

0.2

0

–0.2

–0.4

–0.6

–0.8

–1.0

5.5V

5.0V

4.5V

MAX ACCURACY LIMITS

3.3V

3.0V

2.7V

3.6V

0

–100

–60 –40 –20

0

20

40

60

80 100 120 140 160

–50

0

50

100

150

200

TEMPERATURE (°C)

Figure 6. Temperature Accuracy at 5 V

Figure 8. Shutdown Current vs. Temperature

Rev. 0 | Page 7 of 24

ꢁT74ꢀ±C

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0.30

0.25

0.20

0.15

0.10

0.05

160

140

120

100

80

I

CONTINUOUS CONVERSION

DD

60

40

I

1SPS

DD

20

0

2.5

0

3.0

3.5

4.0

4.5

5.0

5.5

6.0

0

5

10

15

20

25

30

35

40

SUPPLY VOLTAGE (V)

TIME (Seconds)

Figure 9. Average Operating Supply Current vs. Supply Voltage at 25°C

Figure 11. Response to Thermal Shock

8

7

6

5

4

3

2

1

0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

6.0

SUPPLY VOLTAGE (V)

Figure 10. Shutdown Current vs. Supply Voltage at 25°C

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ꢁT74ꢀ±

THEORYCOFCOPER TIONC

CIRCUIT INFORMATION

TEMPERATURE MEASUREMENT

The ADT7410 is a 13-bit digital temperature sensor that is extend-

able to 16 bits for greater resolution. An on-board temperature

sensor generates a voltage proportional to absolute temperature,

which is compared to an internal voltage reference and input to a

precision digital modulator.

In normal mode, the ADT7410 runs an automatic conversion

sequence. During this automatic conversion sequence, a conver-

sion takes 240 ms to complete and the ADT7410 is continuously

converting. This means that as soon as one temperature conver-

sion is completed, another temperature conversion begins. Each

temperature conversion result is stored in the temperature value

registers and is available through the I²C interface. In continuous

conversion mode, the read operation provides the most recent

converted result.

The on-board temperature sensor has excellent accuracy

and linearity over the entire rated temperature range without

needing correction or calibration by the user.

The sensor output is digitized by a sigma-delta (Σ-Δ) modulator,

also known as the charge balance type analog-to-digital conver-

ter. This type of converter utilizes time-domain oversampling

and a high accuracy comparator to deliver 16 bits of resolution

in an extremely compact circuit.

On power-up, the first conversion is a fast conversion, taking

typically 6 ms. If the temperature exceeds 147°C, the CT pin

asserts low. If the temperature exceeds 64°C, the INT pin asserts

low. Fast conversion temperature accuracy is typically within 5°C.

The conversion clock for the part is generated internally.

No external clock is required except when reading from

and writing to the serial port.

Configuration register functions consist of

•

Switching between 13-bit and 16-bit resolution

Switching between normal operation and full power-down

Switching between comparator and interrupt event modes

on the INT and CT pins

The measured temperature value is compared with a critical

temperature limit (stored in the 16-bit T_CRITsetpoint read/write

register), a high temperature limit (stored in the 16-bit T_HIGHset-

point read/write register), and a low temperature limit (stored

in the 16-bit T_LOWsetpoint read/write register). If the measured

value exceeds these limits, the INT pin is activated; and if it exceeds

the T_CRITlimit, the CT pin is activated. The INT and CT pins are

programmable for polarity via the configuration register, and the

INT and CT pins are also programmable for interrupt mode via

the configuration register.

•

Setting the active polarity of the CT and INT pins

Setting the number of faults that activate CT and INT

Enabling the standard one-shot mode and 1 SPS mode

CONVERTER DETAILS

The Σ-Δ modulator consists of an input sampler, a summing

network, an integrator, a comparator, and a 1-bit DAC. This

architecture creates a negative feedback loop and minimizes the

integrator output by changing the duty cycle of the comparator

output in response to input voltage changes. The comparator

samples the output of the integrator at a much higher rate than

the input sampling frequency. This oversampling spreads the

quantization noise over a much wider band than that of the

input signal, improving overall noise performance and

increasing accuracy.

The modulated output of the comparator is encoded using

a circuit technique that results in I²C temperature data.

Σ-Δ MODULATOR

INTEGRATOR

COMPARATOR

VOLTAGE REF

AND VPTAT

1-BIT

DAC

1-BIT

TEMPERATURE

VALUE

CLOCK

GENERATOR

LPF DIGITAL

FILTER

13-BIT

REGISTER

Figure 12. Σ-Δ Modulator

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CT and INT Operation in One-Shot Mode

ONE-SHOT MODE

See Figure 13 for more information on one-shot CT pin

operation for T_CRITovertemperature events when one of the

limits is exceeded. Note that in interrupt mode, a read from

any register resets the INT and CT pins.

Setting Bit 5 to 1 and Bit 6 to 0 of the configuration register

(Register Address 0x03) enables the one-shot mode. When

this mode is enabled, the ADT7410 immediately completes a

conversion and then goes into shutdown mode.

For the INT pin in the comparator mode, if the temperature

Wait for a minimum of 240 ms after writing to the one-shot

bits before reading back the temperature from the temperature

value register. This time ensures that the ADT7410 has time to

power up and complete a conversion.

drops below the T_HIGH– T_HYSTvalue or goes above the T_LOW

+

T_HYSTvalue, a write to the one-shot bits (Bit 5 and Bit 6 of the

configuration register, Register Address 0x03) resets the INT pin.

For the CT pin in the comparator mode, if the temperature

drops below the T_CRIT– T_HYSTvalue, a write to the one-shot

bits (Bit 5 and Bit 6 of the configuration register, Register

Address 0x03) resets the CT pin. See Figure 13.

The one-shot mode is useful when one of the circuit design

priorities is to reduce power consumption.

1 SPS MODE

In this mode, the part performs one measurement per second.

A conversion takes only 60 ms, and it remains in the idle state

for the remaining 940 ms period. This mode is enabled by

writing 0 to Bit 5 and 1 to Bit 6 of the configuration register

(Register Address 0x03).

Note that when using one-shot mode, ensure that the refresh

rate is appropriate to the application being used.

TEMPERATURE

149°C

148°C

147°C

146°C

145°C

144°C

143°C

142°C

141°C

140°C

T

CRIT

T

– T

HYST

CRIT

CT PIN

POLARITY = ACTIVE LOW

CT PIN

POLARITY = ACTIVE HIGH

TIME

WRITE TO

BIT 5 AND BIT 6 OF BIT 5 AND BIT 6 OF BIT 5 AND BIT 6 OF

CONFIGURATION

REGISTER.*

CONFIGURATION

REGISTER.*

CONFIGURATION

REGISTER.*

*THERE IS A 240ms DELAY BETWEEN WRITING TO THE CONFIGURATION REGISTER TO START

A STANDARD ONE-SHOT CONVERSION AND THE CT PIN GOING ACTIVE. THIS IS DUE TO THE

CONVERSION TIME. THE DELAY IS 60ms IN THE CASE OF A 1 SPS CONVERSION.

Figure 13. One-Shot CT Pin

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SHUTDOWN

FAULT QUEUE

The ADT7410 can be placed in shutdown mode by writing 1

to Bit 5 and 1 to Bit 6 of the configuration register (Register

Address 0x03), in which case the entire IC is shut down and

no further conversions are initiated until the ADT7410 is

taken out of shutdown mode. The ADT7410 can be taken

out of shutdown mode by writing 0 to Bit 5 and 0 to Bit 6 in

the configuration register (Register Address 0x03). The

ADT7410 typically takes 1 ms (with a 0.1 ꢀF decoupling

capacitor) to come out of shutdown mode. The conversion

result from the last conversion prior to shutdown can still be

read from the ADT7410 even when it is in shutdown mode.

When the part is taken out of shutdown mode, the internal

clock is started and a conversion is initiated.

Bit 0 and Bit 1 of the configuration register (Register Address

0x03) are used to set up a fault queue. The queue can facilitate up

to four fault events to prevent false tripping of the INT and CT pins

when the ADT7410 is used in a noisy temperature environment.

The number of faults set in the queue must occur consecutively

to set the INT and CT outputs. For example, if the number of

faults set in the queue is four, then four consecutive temperature

conversions must occur with each result exceeding a temperature

limit in any of the limit registers before the INT and CT pins are

activated. If two consecutive temperature conversions exceed a

temperature limit and the third conversion does not, the fault

count is reset back to zero.

Rev. 0 | Page 11 of 24

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TEMPERATURE DATA FORMAT

TEMPERATURE CONVERSION FORMULAS

16-Bit Temperature Data Format

One LSB of the ADC corresponds to 0.0625°C in 13-bit mode.

The ADC can theoretically measure a temperature range of

255°C, but the ADT7410 is guaranteed to measure a low value

temperature limit of −55°C to a high value temperature limit

of +150°C. The temperature measurement result is stored in

the 16-bit temperature value register and is compared with the

high temperature limits stored in the T_CRITsetpoint register and

the T_HIGHsetpoint register. It is also compared with the low

temperature limit stored in the T_LOWsetpoint register.

Positive Temperature = ADC Code (dec)/128

Negative Temperature = (ADC Code (dec) – 65,536)/128

where ADC Code uses all 16 bits of the data byte, including the

sign bit.

Negative Temperature = (ADC Code (dec) – 32,768)/128

where Bit 15 (sign bit) is removed from the ADC code.

13-Bit Temperature Data Format

Temperature data in the temperature value register, the T_CRIT

setpoint register, the T_HIGHsetpoint register, and the T_LOW

setpoint register are represented by a 13-bit twos complement

word. The MSB is the temperature sign bit. The three LSBs, Bit 0

to Bit 2, on power-up, are not part of the temperature conver-

sion result and are flag bits for T_CRIT, T_HIGH, and T_LOW. Table 5

shows the 13-bit temperature data format without Bit 0 to Bit 2.

Positive Temperature = ADC Code (dec)/16

Negative Temperature = (ADC Code (dec) − 8192)/16

where ADC Code uses the first 13 MSBs of the data byte,

including the sign bit.

Negative Temperature = (ADC Code (dec) – 4096)/16

where Bit 15 (sign bit) is removed from the ADC code.

The number of bits in the temperature data-word can be extended

to 16 bits, twos complement, by setting Bit 7 to 1 in the confi-

guration register (Register Address 0x03). When using a 16-bit

temperature data value, Bit 0 to Bit 2 are not used as flag bits

and are, instead, the LSB bits of the temperature value. The

power-on default setting has a 13-bit temperature data value.

10-Bit Temperature Data Format

Positive Temperature = ADC Code (dec)/2

Negative Temperature = (ADC Code (dec) − 1024)/2

where ADC Code uses all 10 bits of the data byte, including the

sign bit.

Negative Temperature = (ADC Code (dec) − 512)/2

Reading back the temperature from the temperature value register

requires a 2-byte read. Designers that use a 9-bit temperature

data format can still use the ADT7410 by ignoring the last four

LSBs of the 13-bit temperature value. These four LSBs are Bit 6

to Bit 3 in Table 5.

where Bit 9 (sign bit) is removed from the ADC code.

9-Bit Temperature Data Format

Positive Temperature = ADC Code (dec)

Negative Temperature = ADC Code (dec) − 512

Table 5. 13-Bit Temperature Data Format

where ADC Code uses all nine bits of the data byte, including

the sign bit.

Digital Output

Temperature (Binary) Bits[15:3]

Digital Output (Hex)

0x1C90

0x1CE0

0x1E70

0x1FFF

0x000

0x001

0x190

0x320

−ꢀꢀ°C

−ꢀ0°C

−2ꢀ°C

−0.062ꢀ°C

0°C

+0.062ꢀ°C

+2ꢀ°C

+ꢀ0°C

+12ꢀ°C

+1ꢀ0°C

1 1100 1001 0000

1 1100 1110 0000

1 1110 0111 0000

1 1111 1111 1111

0 0000 0000 0000

0 0000 0000 0001

0 0001 1001 0000

0 0011 0010 0000

0 0111 1101 0000

0 1001 0110 0000

Negative Temperature = ADC Code (dec) − 256

where Bit 8 (sign bit) is removed from the ADC code.

0x7D0

0x960

Rev. 0 | Page 12 of 24

CC

ꢁT74ꢀ±

REGISTERSC

The ADT7410 contains 14 registers:

ADDRESS POINTER REGISTER

This register is always the first register written to during a write

to the ADT7410. It should be set to the address of the register

to which the write or read transaction is intended. Table 7

shows the register address of each register on the ADT7410.

The default value of the address pointer register is 0x00.

•

Nine temperature registers

A status register

An ID register

A configuration register

An address pointer register

A software reset

Table 7. Address Pointer Register

P7

P6

P5

P4

P3

P2

P1

P0

All registers are eight bits wide. The temperature value registers,

the status register, and the ID register are read-only. The software

reset is a write-only register. On power-up, the address pointer

register is loaded with 0x00 and points to the temperature value

register MSB.

ADD7 ADD6 ADDꢀ ADD4 ADD3 ADD2 ADD1 ADD0

TEMPERATURE VALUE REGISTERS

The temperature value most significant byte (MSB) and tem-

perature value least significant byte (LSB) registers store the

temperature measured by the internal temperature sensor.

The temperature is stored in twos complement format with

the MSB being the temperature sign bit. When reading from

these registers, the eight MSBs (Bit 7 to Bit 15) are read first

from Register Address 0x00 and then the eight LSBs (Bit 0 to

Bit 7) are read from Register Address 0x01. Only the tempera-

ture value most significant byte (Register Address 0x00) needs to

be loaded into the address pointer register as the address pointer

autoincrements to the Temperature value least significant byte

address (Register Address 0x01).

Table 6. ADT7410 Registers

Register

Address

Power-On

Default

Description

0x00

0x01

0x02

0x03

0x04

0x0ꢀ

0x06

0x07

0x0ꢁ

0x09

0x0A

0x0B

0x2F

Temperature value most significant byte

Temperature value least significant byte

Status

0x00

0x20 (64°C)

0x00 (64°C)

0x0ꢀ (10°C)

0x00 (10°C)

0x49 (147°C)

0xꢁ0 (147°C)

0x0ꢀ (ꢀ°C)

0xCX

Configuration

T_HIGHsetpoint most significant byte

T_HIGHsetpoint least significant byte

T_LOWsetpoint most significant byte

T_LOWsetpoint least significant byte

T_CRITsetpoint most significant byte

T_CRITsetpoint least significant byte

T_HYSTsetpoint

Bit 0 to Bit 2 are event alarm flags for T_CRIT, T_HIGH, and T_LOW. When

the ADC is configured to convert the temperature to a 16-bit

digital value then Bit 0 to Bit 2 are no longer used as flag bits

and are instead used as the LSB bits for the extended digital value.

ID

Software reset

0xXX

Table 8. Temperature Value MSB Register (Register Address 0x00)

Bit

Default Value

Type

Name

Temp

Sign

Description

[ꢁ:14]

[1ꢀ]

0000000

0

R

Temperature value in twos complement format

Sign bit, indicates if the temperature value is negative or positive

Table 9. Temperature Value LSB Register (Register Address 0x01)

Default

Value

Bit

Type Name

Description

[0]

0

R

T_LOWflag/LSB0 Flags a T_LOWevent if the configuration register, Register Address 0x03[7] = 0 (13-bit

resolution). When the temperature value is below T_LOW, this bit it set to 1.

Contains the Least Significant Bit 0 of the 1ꢀ-bit temperature value if the configuration

register, Register Address 0x03[7] = 1 (16-bit resolution).

[1]

0

T_HIGHflag/LSB1 Flags a T_HIGHevent if the configuration register, Register Address 0x03[7] = 0 (13-bit

resolution). When the temperature value is above T_HIGH, this bit it set to 1.

Contains the Least Significant Bit 1 of the 1ꢀ-bit temperature value if the configuration

register, Register Address 0x03[7] = 1 (16-bit resolution).

[2]

0

T_CRITflag/LSB2 Flags a T_CRITevent if the configuration register, Register Address 0x03[7] = 0 (13-bit

resolution). When the temperature value exceeds T_CRIT, this bit it set to 1.

Contains the Least Significant Bit 2 of the 1ꢀ-bit temperature value if the configuration

register, Register Address 0x03[7] = 1 (16-bit resolution).

[3:7]

00000

Temp

Temperature value in twos complement format.

Rev. 0 | Page 13 of 24

ꢁT74ꢀ±C

C

temperature value register. In one-shot and 1 SPS modes, the

RDY

STATUS REGISTER

bit is reset after a write to the one-shot bits.

This 8-bit read-only register reflects the status of the overtempera-

ture and undertemperature interrupts that can cause the CT and

INT pins to go active. It also reflects the status of a temperature

conversion operation. The interrupt flags in this register are

reset by a read operation to the status register and/or when

the temperature value returns within the temperature limits,

CONFIGURATION REGISTER

This 8-bit read/write register stores various configuration modes

for the ADT7410, including shutdown, overtemperature and

undertemperature interrupts, one-shot, continuous conversion,

interrupt pins polarity, and overtemperature fault queues.

RDY

including hysterisis. The

bit is reset after a read from the

Table 10. Status Register (Register Address 0x02)

Default

Bit

Value

0000

0

Type

Name

Description

[0:3]

[4]

R

Unused Reads back 0.

T_LOW

T_HIGH

T_CRIT

RDY

This bit is set to 1 when the temperature goes below the T_LOWtemperature limit. The bit clears to 0

when the status register is read and/or when the temperature measured goes back above the limit

set in the setpoint T_LOW+ T_HYSTregisters.

[ꢀ]

[6]

[7]

0

1

R

This bit is set to 1 when the temperature goes above the T_HIGHtemperature limit. The bit clears to 0

when the status register is read and/or when the temperature measured goes back below the limit

set in the setpoint T_HIGH− T_HYSTregisters.

This bit is set to 1 when the temperature goes above the T_CRITtemperature limit. This bit clears to 0

when the status register is read and/or when the temperature measured goes back below the limit

set in the setpoint T_CRIT− T_HYSTregisters.

This bit goes low when the temperature conversion result is written into the temperature value

register. It is reset to 1 when the temperature value register is read. In one-shot and 1 SPS modes,

this bit is reset after a write to the one-shot bits.

Table 11. Configuration Register (Register Address 0x03)

Default

Value

Bit

Type Name

Description

[0:1] 00

R/W

Fault queue

These two bits set the number of undertemperature/overtemperature faults that can occur before

setting the INT and CT pins. This helps to avoid false triggering due to temperature noise.

00 = 1 fault (default).

01 = 2 faults.

10 = 3 faults.

11 = 4 faults.

[2]

[3]

[4]

0

R/W

CT pin polarity

INT pin polarity

INT/CT mode

This bit selects the output polarity of the CT pin.

0 = active low.

1 = active high.

This bit selects the output polarity of the INT pin.

0 = active low.

1 = active high.

This bit selects between comparator mode and interrupt mode.

0 = interrupt mode

1 = comparator mode

[ꢀ:6] 00

Operation mode These two bits set the operational mode for the ADT7410.

00 = continuous conversion (default). When one conversion is finished, the ADT7410 starts

another.

01 = one shot. Conversion time is typically 240 ms.

10 = 1 SPS mode. Conversion time is typically 60 ms. This operational mode reduces the average

current consumption.

11 = shutdown. All circuitry except interface circuitry is powered down.

This bit sets up the resolution of the ADC when converting.

[7]

0

R/W

Resolution

0 = 13-bit resolution. Sign bit + 12 bits gives a temperature resolution of 0.062ꢀ°C.

1 = 16-bit resolution. Sign bit + 1ꢀ bits gives a temperature resolution of 0.007ꢁ°C.

Rev. 0 | Page 14 of 24

CC

ꢁT74ꢀ±

When reading from this register, the eight MSBs (Bit 15 to Bit

8) are read first from Register Address 0x06 and then the eight

LSBs (Bit 7 to Bit 0) are read from Register Address 0x07. Only

the Register Address 0x06 (T_LOWsetpoint MSB) needs to be

loaded into the address pointer register as the address pointer

autoincrements to Register Address 0x07 (T_LOWsetpoint LSB).

T_HIGHSETPOINT REGISTERS

The T_HIGHsetpoint MSB and T_HIGHsetpoint LSB registers store

the overtemperature limit value. An overtemperature event

occurs when the temperature value stored in the temperature

value register exceeds the value stored in this register. The INT

pin is activated if an overtemperature event occurs. The temper-

ature is stored in twos complement format with the MSB being

the temperature sign bit.

The default setting for the T_LOWsetpoint is 10°C.

T_CRITSETPOINT REGISTERS

When reading from this register, the eight MSBs (Bit 15 to Bit 8)

are read first from Register Address 0x04 and then the eight

LSBs (Bit 7 to Bit 0) are read from Register Address 0x05. Only

Register Address 0x04 (T_HIGHsetpoint MSB) needs to be loaded

into the address pointer register as the address pointer auto-

increments to Register Address 0x05 (T_HIGHsetpoint LSB).

The T_CRITsetpoint MSB and T_CRITsetpoint LSB registers store

the critical overtemperature limit value. A critical overtempe-

rature event occurs when the temperature value stored in the

temperature value register exceeds the value stored in this

register. The CT pin is activated if a critical overtemperature

event occurs. The temperature is stored in twos complement

format with the MSB being the temperature sign bit.

The default setting for the T_HIGHsetpoint is 64°C.

When reading from this register, the eight MSBs (Bit 15 to Bit 8)

are read first from Register Address 0x08 and then the eight

LSBs (Bit 7 to Bit 0) are read from Register Address 0x09.

Only the Register Address 0x08 (T_CRITsetpoint MSB) needs to

be loaded into the address pointer register as the address pointer

autoincrements to Register Address 0x09 (T_CRITsetpoint LSB).

T_LOWSETPOINT REGISTERS

The T_LOWsetpoint MSB and T_LOWsetpoint LSB registers store

the undertemperature limit value. An undertemperature event

occurs when the temperature value stored in the temperature

value register is less than the value stored in this register. The

INT pin is activated if an undertemperature event occurs. The

temperature is stored in twos complement format with the MSB

being the temperature sign bit.

The default setting for the T_CRITlimit is 147°C.

Table 12. T_HIGHSetpoint MSB Register (Register Address 0x04)

Bit

Default Value

Type

Name

Description

[1ꢀ:ꢁ]

0x20

R/W

T

_HIGHMSB MSBs of the overtemperature limit, stored in twos complement format.

Table 13. T_HIGHSetpoint LSB Register (Register Address 0x05)

Bit

Default Value

Type

Name

Description

[7:0]

0x00

R/W

T

_HIGHLSB

LSBs of the overtemperature limit, stored in twos complement format.

Table 14. T_LOWSetpoint MSB Register (Register Address 0x06)

Bit

Default Value

Type

Name

Description

[1ꢀ:ꢁ]

0x0ꢀ

R/W

T

_LOWMSB

MSBs of the undertemperature limit, stored in twos complement format.

Table 15. T_LOWSetpoint LSB Register (Register Address 0x07)

Bit

Default Value

Type

Name

Description

[7:0]

0x00

R/W

T

_LOWLSB

LSBs of the undertemperature limit, stored in twos complement format.

Table 16. T_CRITSetpoint MSB Register (Register Address 0x08)

Bit

Default Value

Type

Name

Description

[1ꢀ:ꢁ]

0x49

R/W

T

_CRITMSB

MSBs of the critical overtemperature limit, stored in twos complement format.

Table 17. T_CRITSetpoint LSB Register (Register Address 0x09)

Bit

Default Value

Type

Name

Description

[7:0]

0xꢁ0

R/W

T

_CRITLSB

LSBs of the critical overtemperature limit, stored in twos complement format.

Rev. 0 | Page 1ꢀ of 24

ADT7410

ID REGISTER

T_HYSTSETPOINT REGISTER

This 8-bit read-only register stores the manufacturer ID in Bit 3

to Bit 7 and the silicon revision in Bit 0 to Bit 2.

This 8-bit read/write register stores the temperature hysteresis

value for the T_HIGH, T_LOW, and T_CRITtemperature limits. The

temperature hysteresis value is stored in straight binary format

using four LSBs. Increments are possible in steps of 1°C from

0°C to 15°C. The value in this register is subtracted from the

T_HIGHand T_CRITvalues and added to the T_LOWvalue to imple-

ment hysteresis.

Table 18. T_HYSTSetpoint Register (Register Address 0x0A)

Bit

Default Value Type Name Description

[3:0]

[7:4]

0101

0000

R/W

T_HYST

N/A

Hysteresis value, from 0°C to 15°C. Stored in straight binary format. The default setting is 5°C.

Not used.

Table 19. ID Register (Register Address 0x0B)

Bit

Default Value

Type Name

Description

[2:0]

[7:3]

XXX

R

Revision ID

Manufacture ID

Contains the silicon revision identification number

Contains the manufacturer identification number

11001

R

Rev. 0 | Page 16 of 24

CC

ꢁT74ꢀ±

SERI LCINTERF °EC

PULL-UP

V

DD

V

10kΩ

0.1µF

10kΩ

DD

10kΩ

ADT7410

CT

SCL

SDA

INT

TO INTERRUPT PIN

ON MICROCONTROLLER

A0

A1

GND

Figure 14. Typical I²C Interface Connection

2. The peripheral with the address corresponding to the

transmitted address responds by pulling the data line low

during the low period before the ninth clock pulse, known

as the acknowledge bit. All other devices on the bus then

remain idle while the selected device waits for data to be

Control of the ADT7410 is carried out via the I²C-compatible

serial interface. The ADT7410 is connected to this bus as a slave

and is under the control of a master device.

Figure 14 shows a typical I²C interface connection.

W

read from or written to it. If the R/ bit is a 0, the master

SERIAL BUS ADDRESS

Like all I²C-compatible devices, the ADT7410 has a 7-bit serial

address. The five MSBs of this address for the ADT7410 are set

to 10010. Pin A1 and Pin A0 set the two LSBs. These pins can

be configured two ways, low and high, to give four different

address options. Table 20 shows the different bus address options

available. The recommended pull-up resistor value on the SDA

and SCL lines is 10 kΩ.

W

writes to the slave device. If the R/ bit is a 1, the master

reads from the slave device.

3. Data is sent over the serial bus in sequences of nine clock

pulses, eight bits of data followed by an acknowledge bit

from the receiver of data. Transitions on the data line must

occur during the low period of the clock signal and remain

stable during the high period as a low-to-high transition when

the clock is high, which can be interpreted as a stop signal.

4. When all data bytes have been read or written, stop condi-

tions are established. In write mode, the master pulls the

data line high during the 10^thclock pulse to assert a stop

condition. In read mode, the master device pulls the data

line high during the low period before the ninth clock

pulse. This is known as a no acknowledge. The master

takes the data line low during the low period before the

10^thclock pulse, then high during the 10^thclock pulse to

assert a stop condition.

Table 20. I²C Bus Address Options

Binary

A6

1

A5

0

A4

0

A3

1

A2

0

A1

0

1

A0

0

1

0

1

Hex

0x4ꢁ

0x49

0x4A

0x4B

The serial bus protocol operates as follows:

1. The master initiates data transfer by establishing a start

condition, defined as a high-to-low transition on the serial

data line, SDA, while the serial clock line, SCL, remains

high. This indicates that an address/data stream is going

to follow. All slave peripherals connected to the serial bus

respond to the start condition and shift in the next eight

bits, consisting of a 7-bit address (MSB first) plus a read/

It is not possible to mix read and write in one operation because

the type of operation is determined at the beginning and cannot

subsequently be changed without starting a new operation.

W

write (R/ ) bit. The R/ bit determines whether data is

written to, or read from, the slave device.

Rev. 0 | Page 17 of 24

ꢁT74ꢀ±C

C

the same write transaction. Writing two bytes of data to these

registers requires the serial bus address, the data register address

of the MSB register written to the address pointer register,

followed by the two data bytes written to the selected data

register. This is shown in Figure 16.

WRITING DATA

It is possible to write either a single byte of data or two bytes to

the ADT7410, depending on which registers are to be written.

Writing a single byte of data requires the serial bus address, the

data register address written to the address pointer register,

followed by the data byte written to the selected data register.

This is shown in Figure 15.

If more than the required number of data bytes is written to a

register, the register ignores these extra data bytes. To write to

a different register, a start or repeated start is required.

For the T_HIGHsetpoint, T_LOWsetpoint, and T_CRITsetpoint registers,

it is possible to write to both the MSB and the LSB registers in

1

9

1

9

SCL

1

0

1

0

A1

A0

P7

P6

P5

P4

P3

P2

P1

P0

R/W

SDA

START BY

ACK. BY

ADT7410

ACK. BY

ADT7410

MASTER

FRAME 1

SERIAL BUS ADDRESS BYTE

FRAME 2

ADDRESS POINTER REGISTER BYTE

1

9

SCL (CONTINUED)

SDA (CONTINUED)

D7

D6

D5

D4

D3

D2

D1

D0

ACK. BY STOP BY

ADT7410 MASTER

FRAME 3

DATA BYTE

Figure 15. Writing to a Register Followed by a Single Byte of Data

1

9

1

9

SCL

SDA

0

1

0

A1

A0

P7

P6

P5

P4

P3

P2

P1

P0

R/W

START BY

MASTER

ACK. BY

ADT7410

ACK. BY

ADT7410

FRAME 1

FRAME 2

SERIAL BUS ADDRESS BYTE

ADDRESS POINTER REGISTER BYTE

1

9

1

9

SCL (CONTINUED)

SDA (CONTINUED)

D15

D14

D13

D12

D11 D10

D9

D8

D7

D6

D5

D4

D3

D2

D1

D0

ACK. BY STOP BY

ACK. BY

ADT7410

ADT7410 MASTER

FRAME 3

DATA BYTE

FRAME 4

DATA BYTE

Figure 16. Writing to a Register Followed by Two Bytes of Data

Rev. 0 | Page 1ꢁ of 24

CC

ꢁT74ꢀ±

RESET

READING DATA

To reset the ADT7410 without having to reset the entire I²C bus,

an explicit reset command is provided. This uses a particular

address pointer word as a command word to reset the part and

upload all default settings. The ADT7410 does not respond to

the I²C bus commands (do not acknowledge) during the default

values upload for approximately 200 ꢀs.

Reading data from the ADT7410 is done in a single data byte

operation for the configuration register, the status register,

the T_HYSTregister, and the ID register. A two data byte read

operation is needed for the temperature value register, T_HIGH

setpoint register, T_LOWsetpoint register, and the T_CRITsetpoint

register. Reading back the contents of an 8-bit register similar

to the configuration register is shown in Figure 17. Reading

back the contents of the temperature value register is shown

in Figure 18.

The reset command address word is 0x2F.

GENERAL CALL

When a master issues a slave address consisting of seven 0s with

Reading back from any register first requires a single-byte write

operation to the address pointer register to set up the address of

the register that is going to be read from. In the case of reading

back from the 2-byte registers, the address pointer automatically

increments from the MSB register address to the LSB register

address.

W

the eighth bit (R/ bit) set to 0, this is known as the general call

address. The general call address is for addressing every device

connected to the I²C bus. The ADT7410 acknowledges this address

and reads in the following data byte.

If the second byte is 0x06, the ADT7410 is reset, completely

uploading all default values. The ADT7410 does not respond

to the I²C bus commands (do not acknowledge) while the

default values upload for approximately 200 ꢀs.

To read from another register, execute another write to the

address pointer register to set up the relevant register address.

Thus, block reads are not possible, that is, there is no I²C address

pointer autoincrement except when reading back from a 16-bit

register. If the address pointer register has previously been set

up with the address of the register that is going to receive a read

command, there is no need to repeat a write operation to set up

the register address again.

The ADT7410 does not acknowledge any other general call

commands.

1

9

1

9

SCL

0

1

0

1

A1

A0

R/W

P7

P6

P5

P4

P3

P2

P1

P0

SDA

START BY

MASTER

ACK. BY

ADT7410

ACK. BY

ADT7410

FRAME 1

FRAME 2

SERIAL BUS ADDRESS

BYTE

ADDRESS POINTER REGISTER BYTE

1

9

1

9

SCL

0

1

0

A2

A0

R/W

D7

D6

D5

D4

D3

D2

D1

D0

SDA

REPEAT START

BY MASTER

ACK. BY

ADT7410

NO ACK. BY

MASTER

STOP BY

MASTER

FRAME 3

FRAME 4

SERIAL BUS ADDRESS

BYTE

DATA BYTE FROM CONFIGURATION

REGISTER

Figure 17. Reading Back Data from the Configuration Register

Rev. 0 | Page 19 of 24

ꢁT74ꢀ±C

C

1

9

1

9

SCL

SDA

R/W

A7

A6

A1

A0

1

0

1

0

A1

A0

START

ADT7410 DEVICE ADDRESS

ACK. BY

ADT7410

REGISTER ADDRESS[A7:A0]

1

ACK. BY

ADT7410

1

9

SR

SCL

SDA

D7

D6

D1

D0

D7

D6

D1

D0

R/W

1

0

A1

A0

REPEAT

START

ACK. BY

ADT7410

ACK. BY

MASTER

NO

ACK. BY

MASTER

ADT7410 DEVICE ADDRESS

TEMPERATURE REGISTER

MSB DATA

TEMPERATURE REGISTER

LSB DATA

NOTES

1. A START CONDITION AT THE BEGINNING IS DEFINED AS A HIGH-TO-LOW TRANSITION ON SDA WHILE SCLK REMAINS HIGH.

2. A STOP CONDITION AT THE END IS DEFINED AS A LOW-TO-HIGH TRANSITION ON SDA WHILE SCLK REMAINS HIGH.

3. THE MASTER GENERATES THE NO ACKNOWLEDGE AT THE END OF THE READBACK TO SIGNAL THAT IT DOES NOT WANT ADDITIONAL DATA.

4. TEMPERATURE REGISTER MSB DATA AND TEMPERATURE REGISTER LSB DATA ARE ALWAYS SEPARATED BY A LOW ACK BIT.

5. THE R/W BIT IS SET TO A1 TO INDICATE A READBACK OPERATION.

Figure 18. Reading Back Data from the Temperature Value Register

Rev. 0 | Page 20 of 24

CC

ꢁT74ꢀ±

INTC NꢁC°TCOUTPUTSC

The INT and CT pins are open-drain outputs, and both pins

Comparator Mode

require a 10 kΩ pull-up resistor to V_DD

.

In comparator mode, the INT pin returns to its inactive status

when the temperature drops below the T_HIGH− T_HYSTlimit or

rises above the T_LOW+ T_HYSTlimit.

UNDERTEMPERATURE AND OVERTEMPERATURE

DETECTION

Putting the ADT7410 into shutdown mode does not reset the

INT state in comparator mode.

The INT and CT pins have two undertemperature/overtemperature

modes: comparator mode and interrupt mode. The interrupt

mode is the default power-up overtemperature mode. The INT

output pin becomes active when the temperature is greater than

the temperature stored in the T_HIGHsetpoint register or less than

the temperature stored in the T_LOWsetpoint register. How this pin

reacts after this event depends on the overtemperature mode

selected.

Interrupt Mode

In interrupt mode, the INT pin goes inactive when any ADT7410

register is read. Once the INT pin is reset, it goes active again

only when the temperature is greater than the temperature stored

in the T_HIGHsetpoint register or less than the temperature stored

in the T_LOWsetpoint register.

Figure 19 illustrates the comparator and interrupt modes for

events exceeding the T_HIGHlimit with both pin polarity settings.

Figure 20 illustrates the comparator and interrupt modes for

events exceeding the T_LOWlimit with both pin polarity settings.

Placing the ADT7410 into shutdown mode resets the INT pin

in the interrupt mode.

TEMPERATURE

82°C

81°C

80°C

79°C

78°C

77°C

76°C

75°C

74°C

73°C

T_HIGH

T_HIGH– T_HYST

INT PIN

(COMPARATOR MODE)

POLARITY = ACTIVE LOW

INT PIN

(INTERRUPT MODE)

POLARITY = ACTIVE LOW

INT PIN

(COMPARATOR MODE)

POLARITY = ACTIVE HIGH

INT PIN

(INTERRUPT MODE)

POLARITY = ACTIVE HIGH

TIME

READ

Figure 19. INT Output Temperature Response Diagram for T_HIGHOvertemperature Events

Rev. 0 | Page 21 of 24

ꢁT74ꢀ±C

C

TEMPERATURE

–13°C

–14°C

–15°C

–16°C

–17°C

–18°C

–19°C

–20°C

–21°C

–22°C

T

_LOW+ T_HYST

T_LOW

INT PIN

(COMPARATOR MODE)

POLARITY = ACTIVE LOW

INT PIN

(INTERRUPT MODE)

POLARITY = ACTIVE LOW

INT PIN

(COMPARATOR MODE)

POLARITY = ACTIVE HIGH

INT PIN

(INTERRUPT MODE)

POLARITY = ACTIVE HIGH

TIME

READ

Figure 20. INT Output Temperature Response Diagram for T_LOWUndertemperature Events

Rev. 0 | Page 22 of 24

CC

ꢁT74ꢀ±

PPLI° TIONSCINFORM TIONC

THERMAL RESPONSE TIME

TEMPERATURE MONITORING

The time required for a temperature sensor to settle to a specified

accuracy is a function of the thermal mass of the sensor and the

thermal conductivity between the sensor and the object being

sensed. Thermal mass is often considered equivalent to capaci-

tance. Thermal conductivity is commonly specified using the

symbol, Q, and can be thought of as thermal resistance. It is

commonly specified in units of degrees per watt of power

transferred across the thermal joint. The time required for

the part to settle to the desired accuracy is dependent on the

thermal contact established in a particular application and the

equivalent power of the heat source. In most applications, it is

best to determine the settling time empirically.

The ADT7410 is ideal for monitoring the thermal environment

within electronic equipment. For example, the surface-mounted

package accurately reflects the exact thermal conditions that

affect nearby integrated circuits.

The ADT7410 measures and converts the temperature at the

surface of its own semiconductor chip. When the ADT7410 is

used to measure the temperature of a nearby heat source, the

thermal impedance between the heat source and the ADT7410

must be considered.

When the thermal impedance is determined, the temperature

of the heat source can be inferred from the ADT7410 output.

As much as 60% of the heat transferred from the heat source to

the thermal sensor on the ADT7410 die is discharged via the

copper tracks, the package pins, and the bond pads. Of the

pins on the ADT7410, the GND pin transfers most of the heat.

Therefore, to measure the temperature of a heat source, it is

recommended that the thermal resistance between the GND pin

of the ADT7410 and the GND of the heat source be reduced as

much as possible.

SUPPLY DECOUPLING

Decouple the ADT7410 with a 0.1 ꢀF ceramic capacitor

between V_DDand GND. This is particularly important when

the ADT7410 is mounted remotely from the power supply.

Precision analog products, such as the ADT7410, require a

well-filtered power source. Because the ADT7410 operates

from a single supply, it might seem convenient to tap into the

digital logic power supply. Unfortunately, the logic supply is

often a switch-mode design, which generates noise in the

20 kHz to 1 MHz range. In addition, fast logic gates can

generate glitches hundreds of millivolts in amplitude due

to wiring resistance and inductance.

If possible, the ADT7410 should be powered directly from the

system power supply. This arrangement, shown in Figure 21,

isolates the analog section from the logic switching transients.

Even if a separate power supply trace is not available, generous

supply bypassing reduces supply-line induced errors. Local

supply bypassing consisting of a 0.1 ꢀF ceramic capacitor

is critical for the temperature accuracy specifications to be

achieved. This decoupling capacitor must be placed as close

as possible to the V_DDpin of the ADT7410.

TTL/CMOS

LOGIC

CIRCUITS

0.1µF

ADT7410

POWER

SUPPLY

Figure 21. Use of Separate Traces to Reduce Power Supply Noise

Rev. 0 | Page 23 of 24

ADT7410

OUTLINE DIMENSIONS

5.00 (0.1968)

4.80 (0.1890)

8

1

5

4

6.20 (0.2441)

5.80 (0.2284)

4.00 (0.1574)

3.80 (0.1497)

0.50 (0.0196)

0.25 (0.0099)

1.27 (0.0500)

BSC

45°

1.75 (0.0688)

1.35 (0.0532)

0.25 (0.0098)

0.10 (0.0040)

8°

0°

0.51 (0.0201)

0.31 (0.0122)

COPLANARITY

0.10

1.27 (0.0500)

0.40 (0.0157)

0.25 (0.0098)

0.17 (0.0067)

SEATING

PLANE

COMPLIANT TO JEDEC STANDARDS MS-012-AA

CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS

(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR

REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.

Figure 22. 8-Lead Standard Small Outline Package [SOIC_N]

Narrow Body

(R-8)

Dimensions shown in millimeters and (inches)

ORDERING GUIDE

Model

ADT7410TRZ²

ADT7410TRZ-REEL²

ADT7410TRZ-REEL7²

EVAL-ADT7410EBZ²

Temperature Range

Temperature Accuracy¹

Package Description

8-Lead SOIC_N

Evaluation Board

Package Option

–55°C to +150°C

0.5°C

R-8

¹Maximum accuracy over the −40°C to +105°C temperature range.

²Z = RoHS Compliant Part.

Purchase of licensed I²C components of Analog Devices or one of its sublicensed Associated Companies conveys a license for the purchaser under the Philips I²C Patent

Rights to use these components in an I²C system, provided that the system conforms to the I²C Standard Specification as defined by Philips.

registered trademarks are the property of their respective owners.

D06560-0-4/09(0)

Rev. 0 | Page 24 of 24


型号：	EVAL-ADT7410EBZ
厂家：	ADI
描述：	±0.5°C Accurate, 16-Bit Digital I2C Temperature Sensor ±0.5 ° C精度， 16位数字I2C温度传感器传感器温度传感器
文件：	总24页 (文件大小：447K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

EVAL-ADT7410EBZ [ADI]

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