78.D2GF2.AF10B - Apacer - Datasheet.Live

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Datasheet SHTC3

Humidity and Temperature Sensor IC

 Ultra-low power consumption

 Full battery supply voltage range (1.62 - 3.6 V)

 Small DFN package: 2 × 2 × 0.75 mm3

 Typical accuracy: ±2 %RH and ±0.2 °C

 Fully calibrated and reflow solderable

 Power-up and measurement within 1 ms

Benefits of Sensirion’s CMOSens® Technology

 High reliability and long-term stability

 Industry-proven technology with a track record of

more than 15 years

 Designed for mass production

 Optimized for lowest cost

 High signal-to-noise ratio

Contents of this Data Sheet

1 Humidity and Temperature Sensor

Specifications ............................................................ 2

2 Electrical Specifications ..................................... 3

3 Timing Specifications......................................... 4

4 Interface Specifications ..................................... 6

5 Operation and Communication .......................... 6

6 Quality ............................................................... 9

7 Packaging and Traceability ............................... 9

8 Ordering Information.......................................... 9

9 Technical Drawings ......................................... 10

10 Further Information .......................................... 11

Block diagram

Figure 1 Functional block diagram of the SHTC3.

RH sensor

T sensor

Signal conditioning

ADC

I2C interface

Calibration mem.

VDD

VSS

SDA

SCL

Data processing and system control

analog

digital

Product Summary

The SHTC3 is a digital humidity and temperature sensor

designed especially for battery-driven high-volume

consumer electronics applications. This sensor is strictly

designed to overcome conventional limits for size, power

consumption, and performance to price ratio in order to

fulfill current and future requirements. Sensirion’s

CMOSens® technology offers a complete sensor system

on a single chip, consisting of a capacitive humidity sensor,

a bandgap temperature sensor, analog and digital signal

processing, A/D converter, calibration data memory, and a

digital communication interface supporting I2C Fast Mode

Plus. The small 2 × 2 × 0.75 mm3 DFN package enables

applications in even the most limited of spaces.

The sensor covers a humidity measurement range of 0 to

100 %RH and a temperature measurement range of

- 40 °C to 125 °C with a typical accuracy of ±2 %RH and

±0.2°C. The broad supply voltage of 1.62 V to 3.6 V and

an energy budget below 1 µJ per measurement make the

SHTC3 suitable for mobile or wireless applications

powered by batteries. With the industry-proven quality and

reliability of Sensirion’s humidity and temperature sensors

and constant accuracy over a large measurement range,

the SHTC3 offers best performance-to-price ratio. Tape

and reel packaging together with suitability for standard

SMD assembly processes make the SHTC3 predestined

for high-volume applications.

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1 Humidity and Temperature Sensor Specifications

Relative Humidity

Parameter

Condition

Value

Unit

Accuracy tolerance1

Typ.

2.0

%RH

Max.

see Figure 2

%RH

Repeatability2

-

0.1

%RH

Resolution3

-

0.01

%RH

Hysteresis

-

1

%RH

Specified range4

extended5

0 to 100

%RH

Response time6

 63%

8

s

Long-term drift7

Typ.

<0.25

%RH/y

Table 1 Humidity sensor specifications.

Figure 2 Typical and maximal tolerance for relative humidity in %RH

at 25 °C.

1

For definition of typ. and max. accuracy tolerance, please refer to the document

“Sensirion Humidity Sensor Specification Statement”. Specification applies to

normal mode.

2

The stated repeatability is 3 times the standard deviation (3σ) of multiple

consecutive measurement values at constant conditions and is a measure for the

noise on the physical sensor output. Specification applies to normal mode.

3

Resolution of A/D converter. Specification applies to normal mode.

4

Specified range refers to the range for which the humidity or temperature sensor

specification is guaranteed.

5

For details about recommended humidity and temperature operating range, please

refer to section 1.2.

Temperature

Parameter

Condition

Value

Unit

Accuracy tolerance1

Typ.

0.2

°C

Max.

see Figure 3

°C

Repeatability2

-

0.1

°C

Resolution3

-

0.01

°C

Specified range4

-

–40 to +125

°C

Response time8

 63%

<5 to 30

s

Long-term drift 9

Typ.

<0.02

°C/y

Table 2 Temperature sensor specifications.

Figure 3 Typical and maximal tolerance for temperature sensor in

°C.

6

Time for achieving 63% of a humidity step function, valid at 25°C and 1 m/s

airflow. Humidity response time in the application depends on the design-in of

the sensor.

7

Typical value for operation in normal RH/T operating range. Max. value is <

0.5 %RH/y. Value may be higher in environments with vaporized solvents, out-

gassing tapes, adhesives, packaging materials, etc. For more details please

refer to Handling Instructions.

8

Temperature response time depends on heat conductivity of sensor

substrate and design-in of sensor in application.

9

Max. value is < 0.04°C/y.

±0

±2

±4

±6

010 20 30 40 50 60 70 80 90 100

ΔRH [%RH]

Relative humidity [%RH]

Maximum accuracy

Typical Accuracy

±0

±0.4

±0.8

±1.2

±1.6

-40 -20 0 20 40 60 80 100 120

ΔT [C]

Temperature [°C]

Maximum Accuracy

Typical Accuracy

www.sensirion.com Version 1 – July 2018 3/13

1.1 RH Accuracy at Various Temperatures

Typical RH accuracy at 25°C is defined in Figure 2. For

other temperatures, typical accuracy has been evaluated to

be as displayed in Figure 4.

Figure 4 Typical accuracy of relative humidity measurements given

in %RH for temperatures 0°C … 80°C.

1.2 Recommended Operating Conditions

The sensor performs best when operated within the

recommended normal temperature and humidity range of 5 –

60 °C and 20 – 80 %RH, respectively. Long-term exposure to

conditions outside the normal range, especially at high

humidity, may temporarily offset the RH signal (e.g. +3%RH

after 60h at >80%RH). After returning to normal temperature

and humidity range the sensor will slowly come back to its

calibration state by itself. Prolonged exposure to extreme

conditions may accelerate ageing.

To ensure stable operation of the humidity sensor, the

conditions described in the document “SHTxx Assembly of

SMD Packages”, section “Storage and Handling Instructions”

regarding exposure to volatile organic compounds have to be

met. Please note as well that this does apply not only to

transportation and manufacturing, but also to operation of the

SHTC3.

2 Electrical Specifications

2.1 Electrical Characteristics

Default conditions of 25 °C and 3.3 V supply voltage apply to values in the table below, unless otherwise stated.

Parameter

Symbol

Conditions

Min

Typ.

Max

Units

Comments

Supply voltage

VDD

1.62

3.3

3.6

V

-

Power-up/down level

VPOR

Static power supply

1.28

1.4

1.55

V

-

Supply current

IDD

Idle state

-

45

70

µA

After power-up the sensor

remains in the idle state unless

a sleep command is issued or

other data transmission is active

Sleep Mode

-

0.3

0.6

µA

When in sleep mode, the sensor

requires a dedicated wake-up

command to enable further I2C

communication

Measurement

Normal Mode

-

430

900

µA

Average current consumption

while the sensor is measuring

Low Power M.

-

270

570

µA

Average

Normal Mode

-

4.9

-

µA

Average current consumption

(continuous operation with one

measurement per second)

Low Power M.

-

0.5

-

µA

Average current consumption

(continuous operation with one

measurement per second)

Low level input voltage

VIL

-

0.42 VDD

V

-

High level input voltage

VIH

-

0.7 VDD

-

V

-

Low level output voltage

VOL

3 mA sink current

-

0.2 VDD

V

-

Table 3 Electrical specifications.

100 ±3.5 ±3 ±3 ±3 ±3 ±3 ±3.5 ±4 ±4

90 ±3.5 ±3 ±2.5 ±2.5 ±2.5 ±2.5 ±3 ±3.5 ±4

80 ±3 ±2.5 ±2 ±2 ±2 ±2.5 ±2.5 ±3 ±3.5

70 ±3 ±2.5 ±2 ±2 ±2 ±2 ±2.5 ±2.5 ±3

60 ±2.5 ±2 ±2 ±2 ±2 ±2 ±2 ±2.5 ±2.5

50 ±2.5 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2.5

40 ±2.5 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2

30 ±2.5 ±2 ±2 ±2 ±2 ±2 ±2 ±2 ±2

20 ±2.5 ±2.5 ±2 ±2 ±2 ±2 ±2 ±2 ±2

10 ±3 ±3 ±2.5 ±2.5 ±2.5 ±2.5 ±2.5 ±2.5 ±2.5

0 ±3.5 ±3.5 ±3 ±3 ±3 ±3 ±3 ±3 ±3

010 20 30 40 50 60 70 80

Relative Humidity [%RH]

Temperature [°C]

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2.2 Absolute Maximum Ratings

Stress levels beyond the limits listed in Table 4 may cause permanent damage to the device. These are stress ratings only and

functional operation of the device at these conditions cannot be guaranteed. Exposure to the absolute maximum rating conditions

for extended periods may affect the reliability of the device. Parameters are only tested each at a time.

Parameter

Rating

Supply voltage, VDD

-0.3 to +4 V

Operating temperature range

-40 to +125 °C

Storage temperature range10

-40 to +125 °C

ESD HBM (human body model)11

-2 to 2 kV

ESD CDM (change device model)12

-500 to 500 V

Latch up, JESD78 Class II, 125°C

-100 to 100 mA

Table 4 Absolute maximum ratings.

3 Timing Specifications

3.1 Sensor System Timings

Default conditions of 25 °C and 3.3 V supply voltage apply to values the table below, unless otherwise stated. Max. values are

measured at -40 °C.

Parameter

Symbol

Conditions

Min.

Typ.

Max.

Units

Comments

Power-up time

tPU

After hard reset, VDD ≥ VPOR

-

180

240

µs

Time between VDD reaching VPU

and sensor entering the idle

state

Soft reset time

tSR

After soft reset.

-

180

240

µs

Time between ACK of soft reset

command and sensor entering

the idle state

Measurement duration

tMEAS

Average

Normal Mode

-

10.8

12.1

ms

Duration for a humidity and

temperature measurement

Low Power M.

-

0.7

0.8

Table 5 System timing specifications.

10

The recommended storage temperature range is 10-50°C. Please consult the document “SHTxx Handling Instructions” for more information.

11

According to ANSI/ESDA/JEDEC JS-001-2014; AEC-Q100-002.

12

According to ANSI/ESD S5.3.1-2009; AEC-Q100-011.

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3.2 Communication Timings

Default conditions of 25 °C and 3.3 V supply voltage apply to values in the table below, unless otherwise stated.

Parameter

Symbol

Conditions

Min.

Typ.

Max.

Units

Comments

SCL clock frequency

fSCL

-

0

-

1

MHz

-

Hold time (repeated) START

condition

tHD;STA

After this period, the first

clock pulse is generated

260

-

ns

-

LOW period of the SCL clock

tLOW

-

500

-

ns

-

HIGH period of the SCL clock

tHIGH

-

260

-

ns

-

Set-up time for a repeated

START condition

tSU;STA

-

260

-

ns

-

SDA hold time

tHD;DAT

-

0

-

SDA set-up time

tSU;DAT

-

50

-

ns

-

SCL/SDA rise time

tR

-

120

ns

-

SCL/SDA fall time

tF

-

120

ns

-

SDA valid time

tVD;DAT

-

400

ns

-

Set-up time for STOP

condition

tSU;STO

-

260

-

ns

-

Capacitive load on bus line

CB

-

550

pF

-

Table 6 Communication timing specifications. The numbers above are values according to the I2C Fast Mode Plus specification.

Figure 5 Timing diagram for digital input/output pads. SDA directions as seen from the sensor. Bold SDA lines are controlled by the sensor,

plain SDA lines are controlled by the micro-controller. Note that SDA valid read time is triggered by falling edge of preceding toggle.

SCL

70%

30%

tLOW

1/fSCL

tHIGH

tR

tF

SDA

70%

30%

tSU;DAT

tHD;DAT

DATA IN

tR

SDA

70%

30%

DATA OUT

tVD;DAT

tF

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4 Interface Specifications

The SHTC3 supports I2C Fast Mode Plus (SCL clock

frequency from 0 to 1 MHz) with clock stretching. For

detailed information on the I2C protocol, refer to NXP I2C-

bus specification and user manual UM10204, Rev. 6, April

4th, 2014.

The SHTC3 comes in a 4-pin package – see Table 7.

Name

Comments

1

VDD

Supply voltage

2

SCL

Serial clock, bidirectional

3

SDA

Serial data, bidirectional

4

VSS

Ground

Table 7 SHTC3 pin assignment (top view). The center pad is

internally connected to VSS.

Power-supply pins supply voltage (VDD) and ground (VSS)

must be decoupled with a 100 nF capacitor that shall be

placed as close to the sensor as possible – see Figure 6.

SCL is used to synchronize the communication between the

microcontroller and the sensor. The master must keep the

clock frequency within 0 to 1 MHz as specified in Table 6.

The SHTC3 may pull down the SCL line when clock

stretching is enabled.

The SDA pin is used to transfer data in and out of the

sensor. For safe communication, the timing specifications

defined in the I2C manual must be met.

To avoid signal contention, the microcontroller must only

drive SDA and SCL low. External pull-up resistors (e.g.

10 kΩ) are required to pull the signal high. For

dimensioning resistor sizes please take the bus capacity

requirements into account. Note that pull-up resistors may

be included in I/O circuits of microcontrollers.

Figure 6 Typical application circuit, including pull-up resistors RP

and decoupling of VDD and VSS by a capacitor.

For good performance of the SHTC3 in the application, the

center pad of the SHTC3 offers the best thermal contact to

13

If an immediate sensor signal is desired, sending the sensor to sleep mode

can be omitted. Not sending the sensor to sleep mode for an extended amount

of time keeps up the current consumption of the sensor.

the temperature sensor. For more information on design-in,

please refer to the document “SHTxx Design Guide”.

For mechanical reasons the center pad should be soldered.

Electrically, the center pad is internally connected to GND

and may be connected to the GND net on the PCB

additionally.

5 Operation and Communication

All commands and memory locations of the SHTC3 are

mapped to a 16-bit address space which can be accessed

via the I2C protocol.

5.1 I2C Address

The I2C device address is given Table 8:

SHTC3

Hex. Code

Bin. Code

I2C address

0x70

111’0000

Table 8 SHTC3 I2C device address.

Each transmission sequence begins with START condition

(S) and ends with an (optional) STOP condition (P) as

described in the I2C-bus specification.

5.2 Power-Up, Sleep, Wakeup

Upon VDD reaching the power-up voltage level VPOR, the

SHTC3 enters the idle state after a duration of tPU. After that,

the sensor should be set to sleep mode with the command

given in Table 9

13

.

Command

Hex. Code

Bin. Code

Sleep

0xB098

1011’0000’1001’1000

Table 9 Sleep command of the sensor.

When the sensor is in sleep mode, it requires the following

wake-up command before any further communication, see

Table 10:

Command

Hex. Code

Bin. Code

Wakeup

0x3517

0011’0101’0001’0111

Table 10 Wake-up command of the sensor.

5.3 Measurement Commands

The SHTC3 provides a clock-stretching option and the

order of the signal return can be selected. These

parameters are selected by dedicated measurement

commands as summarized in Table 11. N. B.: Each

measurement command triggers always both, a

temperature and a relative humidity measurement.

2

1

3

4

SHTC3

AXY89

SDA

SCL

GND

VDD

MCU (master)

RP

SCL OUT

SDA OUT

SDA IN

SCL IN

C = 100 nF

SHTC3

(slave)

SHTC3

AXY89

www.sensirion.com Version 1 – July 2018 7/13

Clock Stretching

Enabled

Clock Stretching

Disabled

Read T

First

Read RH

First

Read T

First

Read RH

First

Normal Mode

0x7CA2

0x5C24

0x7866

0x58E0

Low Power

M.

0x6458

0x44DE

0x609C

0x401A

Table 11 Measurement commands.

5.4 Measuring and Reading the Signals

Each measurement cycle contains a set of four commands,

each initiated by the I2C START condition and ended by the

I2C STOP condition:

1. Wakeup command

2. Measurement command

3. Read out command

4. Sleep command

An exemplary measurement set is shown in Figure 7

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

S

ACK

P

SHTC3 wake up

1

0

1

0

1

0

1

0

1

0

1

I2C address + write

Wakeup command MSB

Wakeup command LSB

Wakeup time see Table 5

28

29

30

31

32

33

34

35

36

38

39

40

41

42

43

44

45

46

47

48

49

50

51

52

53

54

55

ACK

P

SHTC3 measuring

S

1

0

1

0

1

0

1

0

1

0

I2C address + write

Measurement command MSB

Measurement command LSB

Measurement in progress

56

57

58

59

60

61

62

63

64

65

66

67

68

69

70

71

72

73

S

NACK

P

SHTC3 measuring

SHTC3 in idle

state

S

ACK

1

0

1

0

1

repeated I2C address + read

while meas. is in prog. (polling)

measurement cont’d

measurement

completed

I2C address + read

56

57

58

59

60

61

62

63

64

S

ACK

SHTC3 measuring,

SCL line pulled low

1

0

1

I2C address + read

while meas. is in progress

measurement continued

74

75

76

77

78

79

80

81

82

83

84

85

86

87

88

89

90

91

92

93

94

95

96

97

98

99

100

ACK

1

0

1

0

1

0

1

0

1

0

1

0

Humidity MSB

Humidity LSB

Humidity CRC checksum

101

102

103

104

105

106

107

108

109

110

111

112

113

114

115

116

117

118

119

120

121

122

123

124

125

126

127

ACK

P

0

1

0

1

0

1

0

1

0

1

0

1

Temperature MSB

Temperature LSB

Temperature CRC checksum

128

129

130

131

132

133

134

135

136

137

138

139

140

141

142

143

144

145

146

147

148

149

150

151

152

153

154

S

ACK

P

1

0

1

0

1

0

1

0

1

0

I2C address + write

Sleep command MSB

Sleep command LSB

Figure 7 Communication sequence for waking up the sensor, starting a measurement and reading measurement results displaying both

clock stretching options.

The numerical example corresponds to a read humidity-first command with clock stretching enabled. The physical values of the transmitted

measurement results are 63 %RH and 23.7 °C. Clear blocks are controlled by the microcontroller, grey blocks by the SHTC3.

clock stretching

disabled

clock

stretching enabled

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5.5 Sensor Behavior during Measurement and

Clock Stretching

In general, the sensor does not respond to any I2C activity

during measurement, i.e. I2C read and write headers are not

acknowledged (NACK). However, when clock stretching

has been enabled by using a corresponding measurement

command, the sensor responds to a read header with an

ACK and subsequently pulls down the SCL line until the

measurement is complete. As soon as the measurement is

complete, the sensor starts sending the measurement

results.

During measurement, the sensor has a current

consumption according to Table 3.

For best possible repeatability of humidity and temperature

measurements, it is recommended to avoid any

communication on the I2C bus while the SHTC3 is

measuring. For more information, see the application note

“Optimization of Repeatibility”.

5.6 Readout of Measurement Results

After a measurement command has been issued and the

sensor has completed the measurement, the master can

read the measurement results by sending a START

condition followed by an I2C read header. The sensor will

acknowledge the reception of the read header and send two

bytes of data followed by one byte CRC checksum and

another two bytes of data followed by one byte CRC

checksum. Each byte must be acknowledged by the

microcontroller with an ACK condition for the sensor to

continue sending data. If the SHTC3 does not receive an

ACK from the master after any byte of data, it will not

continue sending data.

The I2C master can abort the read transfer with a NACK

condition after any data byte if it is not interested in

subsequent data, e.g. the CRC byte or the second

measurement result, in order to save time.

In case the user needs humidity and temperature data but

does not want to process CRC data, it is recommended to

read the first two bytes of data with the CRC byte (without

processing the CRC data) and abort the read transfer after

reading the second two data bytes with a NACK. This

procedure is more time efficient than starting two different

measurements and aborting the read transfer after the first

two data bytes each time.

5.7 Soft Reset

The SHTC3 provides a soft reset mechanism that forces

the system into a well-defined state without removing the

power supply. If the system is in its idle state (i.e. if no

measurement is in progress) the soft reset command can

be sent to SHTC3 according to Table 12. This triggers the

14

http://www.nxp.com/documents/user_manual/UM10204.pdf

sensor to reset all internal state machines and reload

calibration data from the memory.

Command

Hex. Code

Bin. Code

Software reset

0x805D

1000’0000’0101’1101

Table 12 Soft reset command.

5.8 Reset through General Call

Additionally, a reset of the sensor can also be generated

using the “general call” mode according to I2C-bus

specification

14

. This generates a reset which is functionally

identical to using the nReset pin. It is important to

understand that a reset generated in this way is not device

specific. All devices on the same I2C bus that support the

general call mode will perform a reset. Additionally, this

command only works when the sensor is able to process

I2C commands. The appropriate command consists of two

bytes and is shown in Table 13.

Command

Code

Address byte

0x00

Second byte

0x06

Reset command using the

general call address

0x0006

Table 13 Reset through the general call address (clear blocks are

controlled by the microcontroller, grey blocks by the sensor)

5.9 Read-out of ID Register

The SHTC3 has an ID register which contains an SHTC3-

specific product code. The read-out of the ID register can

be used to verify the presence of the sensor and proper

communication. The command to read the ID register is

shown in Table 14.

Command

Hex. Code

Bin. Code

Read ID register

0xEFC8

1110’1111’1100’1000

Table 14 Read-out command of ID register.

It needs to be sent to the SHTC3 after an I2C write header.

Once the SHTC3 has acknowledged the proper reception

of the command, the master can send an I2C read header

and the SHTC3 submits the 16-bit ID followed by 8 bits of

CRC. The structure of the ID is described in Table 15.

S

ACK

General Call Address

1 2 3 4 5 6 7 8 9

ACK

Reset Command

1 2 3 4 5 6 7 8 9

General Call 1st byte General Call 2nd byte

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16-bit ID

bits 15 to 12 & 10 to 6: unspecified info.

xxxx' 1 xxx’xx 00’0111

bits 11 & 5 to 0: SHTC3 identifier.

Table 15 Structure of the 16-bit ID. Bits 15:12 & 10:6 of the ID

contain unspecified information (marked as “x”), which may vary

from sensor to sensor, while bits 11 & 5:0 contain the SHTC3-

specific product code.

5.10 Checksum Calculation

The 8-bit CRC checksum transmitted after each data word

is generated by a CRC algorithm with the properties

displayed in Table 16. The CRC covers the contents of the

two previously transmitted data bytes.

Property

Value

Name

CRC-8

Width

8 bits

Polynomial

0x31 (x8 + x5 + x4 + 1)

Initialization

0xFF

Reflect input

False

Reflect output

False

Final XOR

0x00

Examples

CRC (0x00) = 0xAC

CRC (0xBEEF) = 0x92

Table 16 SHTC3 I2C CRC properties.

5.11 Conversion of Sensor Output

Measurement data is always transferred as 16-bit values.

These values are already linearized and temperature

compensated by the SHTC3. Humidity and temperature

values can be calculated with the formulas in given below.

Relative humidity conversion formula (result in %RH):

16

RH

2

S

100 RH 

Temperature conversion formula (result in °C):

16

T

2

S

175 45 T 

SRH and ST denote the raw sensor output (as decimal

values) for humidity and temperature, respectively.

6 Quality

6.1 Environmental Stability

Qualification of the SHTC3 is performed based on the

JEDEC JESD47 qualification test method.

6.2 Material Contents

The device is fully RoHS, REACH and Halogen-Free

compliant, e.g. free of Pb, Cd, and Hg.

7 Packaging and Traceability

SHTC3 sensors are provided in a DFN package with an

outline of 2 × 2 × 0.75 mm3 and a terminal pitch of 1 mm.

DFN stands for dual flat no leads. The humidity sensor

opening is centered on the top side of the package.

The sensor chip is made of silicon and is mounted to a lead

frame. The latter is made of Cu plated with Ni/Pd/Au. Chip

and lead frame are overmolded by an epoxy-based mold

compound. Please note that the sidewalls of sensor are

diced and therefore these diced lead frame surfaces are not

covered with the respective plating.

The Moisture Sensitivity Level classification of the SHTC3

is MSL1, according to IPC/JEDEC J-STD-020.

All SHTC3 sensors are laser marked for easy identification

and traceability. The marking on the sensor consists of two

lines and a pin-1 indicator. The top line contains the sensor

type (SHTC3), the bottom line contains a 5-digit,

alphanumeric tracking code. The pin-1 indicator is located

in the top left corner. See Figure 8 for illustration.

Figure 8 Laser marking on SHTC3, the top line with the pin-1

indicator and the sensor type, the bottom line with the 5-digit

alphanumeric tracking code.

Reels are also labeled and provide additional traceability

information.

8 Ordering Information

The SHTC3 can be ordered in tape and reel packaging with

different sizes, see Table 17. The reels are sealed into

antistatic ESD bags. A drawing of the packaging tape with

sensor orientation is shown in Figure 11.

Quantity

Packaging

Reel Diameter

Order Number

2500

Tape & Reel

180 mm (7 inch)

3.000.047

10’000

Tape & Reel

330 mm (13 inch)

1-101681-01

Table 17 SHTC3 ordering options.

SHTC3

XXXXX

www.sensirion.com Version 1 – July 2018 10/13

9 Technical Drawings

9.1 Package Outline

Figure 9 Package outline drawing of the SHTC3. Dimensions are given in millimeters.

9.2 Metal Land Pattern

Figure 10 Recommended metal land pattern for SHTC3 (all dimensions are in mm). Recommended solder paste stencil thickness is 100µm,

pads on PCB are recommended to be non solder mask defined (NSMD).

0.75

1.6

1

0.7

0.2x45°

0.35

2

* Mold opening shows smooth transition to package surface. Therefore

this dimension is not well defined and given for reference only.

www.sensirion.com Version 1 – July 2018 11/13

9.3 Tape and Reel Package

Figure 11 Technical drawing of the packaging tape with sensor orientation in tape. Header tape is to the right and trailer tape to the left on

this drawing. Dimensions are given in millimeters.

10 Further Information

For more in-depth information on the SHTC3 and its application please consult the following documents:

Document Name

Description

Source

SHTxx Assembly of SMD

Packages

Instructions on soldering and processing of the

SHTC3 in a production environment

Available for download from the SHTC3 product

website:

www.sensirion.com/humidity-download

SHTxx Design Guide

Design guidelines for designing SHTxx humidity

sensors into applications

Available for download at the Sensirion humidity

sensors download center:

www.sensirion.com/humidity-download

SHTxx Handling Instructions

Guidelines for proper handling of SHTxx humidity

sensors

Available for download at the Sensirion humidity

sensors download center:

www.sensirion.com/humidity-download

Sensirion Humidity Sensor

Specification Statement

Definition of sensor specifications.

Available for download at the Sensirion humidity

sensors download center:

www.sensirion.com/humidity-download

Table 18 Documents containing further information relevant for the SHTC3.

www.sensirion.com Version 1 – July 2018 12/13

Revision History

Date

Version

Page(s)

Changes

July 2018

1

all

Initial version

www.sensirion.com Version 1 – July 2018 13/13

Important Notices

Warning, Personal Injury

Do not use this product as safety or emergency stop

devices or in any other application where failure of the

product could result in personal injury. Do not use this

product for applications other than its intended and

authorized use. Before installing, handling, using or

servicing this product, please consult the data sheet and

application notes. Failure to comply with these instructions

could result in death or serious injury.

If the Buyer shall purchase or use SENSIRION products for any

unintended or unauthorized application, Buyer shall defend,

indemnify and hold harmless SENSIRION and its officers,

employees, subsidiaries, affiliates and distributors against all

claims, costs, damages and expenses, and reasonable attorney

fees arising out of, directly or indirectly, any claim of personal

injury or death associated with such unintended or unauthorized

use, even if SENSIRION shall be allegedly negligent with

respect to the design or the manufacture of the product.

ESD Precautions

The inherent design of this component causes it to be sensitive

to electrostatic discharge (ESD). To prevent ESD-induced

damage and/or degradation, take customary and statutory ESD

precautions when handling this product.

See application note “ESD, Latchup and EMC” for more

information.

Warranty

SENSIRION warrants solely to the original purchaser of this

product for a period of 12 months (one year) from the date of

delivery that this product shall be of the quality, material and

workmanship defined in SENSIRION’s published specifications

of the product. Within such period, if proven to be defective,

SENSIRION shall repair and/or replace this product, in

SENSIRION’s discretion, free of charge to the Buyer, provided

that:

 notice in writing describing the defects shall be given to

SENSIRION within fourteen (14) days after their

appearance;

 such defects shall be found, to SENSIRION’s reasonable

satisfaction, to have arisen from SENSIRION’s faulty

design, material, or workmanship;

 the defective product shall be returned to SENSIRION’s

factory at the Buyer’s expense; and

 the warranty period for any repaired or replaced product

shall be limited to the unexpired portion of the original

period.

This warranty does not apply to any equipment which has not

been installed and used within the specifications recommended

by SENSIRION for the intended and proper use of the

equipment. EXCEPT FOR THE WARRANTIES EXPRESSLY

SET FORTH HEREIN, SENSIRION MAKES NO

WARRANTIES, EITHER EXPRESS OR IMPLIED, WITH

RESPECT TO THE PRODUCT. ANY AND ALL WARRANTIES,

INCLUDING WITHOUT LIMITATION, WARRANTIES OF

MERCHANTABILITY OR FITNESS FOR A PARTICULAR

PURPOSE, ARE EXPRESSLY EXCLUDED AND DECLINED.

SENSIRION is only liable for defects of this product arising

under the conditions of operation provided for in the data sheet

and proper use of the goods. SENSIRION explicitly disclaims all

warranties, express or implied, for any period during which the

goods are operated or stored not in accordance with the

technical specifications.

SENSIRION does not assume any liability arising out of any

application or use of any product or circuit and specifically

disclaims any and all liability, including without limitation

consequential or incidental damages. All operating parameters,

including without limitation recommended parameters, must be

validated for each customer’s applications by customer’s

technical experts. Recommended parameters can and do vary

in different applications.

SENSIRION reserves the right, without further notice, (i) to

change the product specifications and/or the information in this

document and (ii) to improve reliability, functions and design of

this product.

CMOSens® is a trademark of Sensirion

Headquarters and Subsidiaries

SENSIRION AG

Laubisruetistr. 50

CH-8712 Staefa ZH

Switzerland

phone: +41 44 306 40 00

fax: +41 44 306 40 30

info@sensirion.com

www.sensirion.com

Sensirion Inc. USA

phone: +1 312 690 5858

info-us@sensirion.com

www.sensirion.com

Sensirion Japan Co. Ltd.

phone: +81 3 3444 4940

info-jp@sensirion.com

www.sensirion.co.jp

Sensirion Korea Co. Ltd.

phone: +82 31 337 7700~3

info-kr@sensirion.com

www.sensirion.co.kr

Sensirion China Co. Ltd.

phone: +86 755 8252 1501

info-cn@sensirion.com

www.sensirion.com.cn/

Sensirion Taiwan Co. Ltd.

phone: +41 44 306 40 00

info@sensirion.com

To find your local representative, please visit www.sensirion.com/contact