1-100456-02 - SENSIRION - Datasheet.Live

www.sensirion.com Version 1.9 – July 2015 1/10

SDP600 Series (SDP6xx/5xx)

Low-cost Digital Differential Pressure Sensor

 Accuracy better than 0.2% FS near zero

 Digital output (I2C)

 Excellent repeatability, even below 10 Pa

 Calibrated and temperature compensated

 Excellent long-term stability

 Flow measurement in bypass configuration

Product Summary

The SDP600 sensor family is Sensirion’s series of digital

differential pressure sensors designed for high-volume

applications. They measure the pressure of air and non-

aggressive gases with superb accuracy and no offset drift.

The sensors cover a pressure range of up to ±500 Pa

(±2 inch H2O / ±5 mbar) and deliver outstanding accuracy

even at the bottom end of the measuring range.

The SDP600 series operates from a 3.3V supply voltage

and features a digital 2-wire interface, which makes it easy

to connect directly to a microprocessor. The signal is

internally linearized and temperature compensated.

The outstanding performance of these sensors is based

on Sensirion’s patented CMOSens® sensor technology,

which combines the sensor element, signal processing

and digital calibration on a tiny microchip. The differential

pressure is measured by a thermal sensor element using

flow-through technology. Compared with membrane-

based sensors, the SDP600 features an extended

dynamic range, better long-term stability, and improved

repeatability, especially near zero.

The well-proven CMOS technology is perfectly suited for

high-quality mass production and is the ideal choice for

demanding and cost-sensitive OEM applications.

Applications

 Medical

 HVAC

 Automotive

 Process automation

 Burner control

OEM options

A variety of custom options can be implemented for high-

volume OEM applications. Ask us for more information.

Sensor chip

The SDP600 series features a fourth-generation silicon

sensor chip called SF04. In addition to a thermal mass

flow sensor element, the chip contains an amplifier, A/D

converter, EEPROM memory, digital signal processing

circuitry, and interface. The highly sensitive chip requires

only a minuscule amount of gas flow through the sensor.

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1. Sensor Performance

1.1 Physical specifications

Unless otherwise noted, all sensor specifications are valid at 25°C with Vdd = 3.3 V and absolute pressure = 966 mbar.

The SDP50x/SDP51x sensors can detect negative differential pressures in the range of -500 to 0Pa. A negative differential pressure is represented

by a negative value. The accuracy of the negative differential pressure is not specified and might have significant inter-sensor variation.

Please see chapter 5.3 for details.

See Application Note for response times with other resolutions, e.g. 1.3 ms with 10 bits.

With 12-bit resolution; includes repeatability and hysteresis.

Total accuracy/repeatability is a sum of zero-point and span accuracy/repeatability.

Parameter

SDP600-500Pa

SDP610-500Pa

SDP600-125Pa

SDP610-125Pa

SDP600-25Pa

SDP610-25Pa

SDP601

SDP611

SDP500

SDP510

SDP501

SDP511

Short Description

Standard

Low DP

Lowest DP

“Mass Flow”

Low cost

“Mass Flow”

Calibrated range2

– 500 Pa

to + 500 Pa

(± 2.0 in. H2O)

– 125 Pa

to + 125 Pa

(± 0.5 in. H2O)

– 25 Pa

to + 25 Pa

(± 0.1 in. H2O)

– 500 to + 500

(± 2.0 in. H2O)

0 Pa

to +500 Pa

(0 to 2.0 in. H2O)

Temperature-

compensation

yes

mass flow3

yes

mass flow3

Resolution

12 bits preset4 (adjustable from 9 to 16 bit)

Zero point accuracy5,6

0.2 Pa

0.1 Pa

0.2 Pa

Span accuracy5,6

3% of reading

4.5% of reading

Zero point

repeatability5,6

0.1 Pa

0.05 Pa

0.03 Pa

0.1 Pa

Span repeatability5,6

0.5% of reading

Offset shift due to

temperature variation

None

(less than resolution)

Span shift due to

temperature variation

< 0.5% of reading per 10°C

Offset stability

< 0.1 Pa/year

Response time4

4.6 ms typical at 12-bit resolution

Warm-up time for first

reliable measurement

Typ. 50 ms

(first measurement typically after 16 ms)

www.sensirion.com Version 1.9 – July 2015 3/10

1.2 Ambient conditions

Parameter

SDP5xx / SDP6xx Series

Calibrated for7

Air, N2

Media compatibility

Air, N2, O2

Calibrated temperature range

-20 °C to +80 °C

Operating temperature

-20 °C to +80 °C

Storage temperature7

-40 °C to +80 °C

Position sensitivity

Less than repeatability error

1.3 Materials

Parameter

SDP5xx / SDP6xx Series

Wetted materials

PBT (polybutylene terephthalate), glass (silicon nitride, silicon oxide), silicon, gold,

FR4, silicone as static sealing, epoxy, copper alloy, lead-free solder

REACH, RoHS

REACH and RoHS compliant

2. Electrical Specifications

Parameter

SDP5xx / SDP6xx

Operating voltage

3.0– 3.6 V

(A supply voltage of 3.3 V is recommended)

Current drain

< 6 mA typical in operation

Interface

Digital 2-wire interface (I2C)

Bus clock frequency

100 kHz typical, 400 kHz max.

Default I2C address

64 (binary: 1000 000)

Scale factor8

SDP6xx-500Pa & SDP5xx

60 Pa-1

SDP6x0-125Pa

240 Pa-1

SDP6x0-25Pa

1200 Pa-1

Scale factor to alternative

units9

For all 500 Pa versions:

6’000 mbar-1

413’686 psi-1

14’945 (inch H2O)-1

SDP 6x0-125Pa

24’000 mbar-1

1'654’744 psi-1

59’780 (inch H2O)-1

SDP6x0-25Pa

120’000 mbar-1

8’273’719 psi-1

298’900 (inch H2O)-1

Contact Sensirion for information about other gases, wider calibrated temperature ranges and higher storage temperatures.

See section 5.1. The scale factor may vary with other configurations.

Instead of the standard scale factor (to get the physical value in Pa), the sensor output may be divided by alternative scale factors to receive the physical

value in another unit.

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3. Interface Specifications

The serial interface of the SDP600 series is compatible

with I2C interfaces. For detailed specifications of the I2C

protocol, see The I2C Bus Specification (source: NXP).

3.1 Interface connection – external

components

Bi-directional bus lines are implemented by the devices

(master and slave) using open-drain output stages and a

pull-up resistor connected to the positive supply voltage.

The recommended pull-up resistor value depends on the

system setup (capacitance of the circuit or cable and bus

clock frequency). In most cases, 10 kΩ is a reasonable

choice.

The capacitive loads on SDA and SCL line have to be the

same. It is important to avoid asymmetric capacitive loads.

I2C Transmission Start Condition

SDA

SCL

VDD

master slave (SDP600)

Rp Rp

Both bus lines, SDA and SCL, are bi-directional and therefore

require an external pull-up resistor.

3.2 I2C Address

The I2C address consists of a 7-digit binary value. By

default, the I2C address is set to 64 (binary: 1000 000).

The address is always followed by a write bit (0) or read

bit (1). The default hexadecimal I2C header for read

access to the sensor is therefore h81.

3.3 Transfer sequences

Transmission START Condition (S): The START condi-

tion is a unique situation on the bus created by the master,

indicating to the slaves the beginning of a transmission

sequence (the bus is considered busy after a START).

I2C Transmission Start Condition

START condition

SDA

SCL

A HIGH to LOW transition on the SDA line while SCL is HIGH

Transmission STOP Condition (P): The STOP condition

is a unique situation on the bus created by the master,

indicating to the slaves the end of a transmission

sequence (the bus is considered free after a STOP).

I2C Transmission Stop Condition

STOP condition

SDA

SCL

A LOW to HIGH transition on the SDA line while SCL is HIGH.

Acknowledge (ACK) / Not Acknowledge (NACK): Each

byte (8 bits) transmitted over the I2C bus is followed by an

acknowledge condition from the receiver. This means that

after the master pulls SCL low to complete the

transmission of the 8th bit, SDA will be pulled low by the

receiver during the 9th bit time. If after transmission of the

8th bit the receiver does not pull the SDA line low, this is

considered to be a NACK condition.

If an ACK is missing during a slave to master transmission,

the slave aborts the transmission and goes into idle mode.

I2C Acknowledge / Not Acknowledge

ACK

SCL R/_W D7 D0 ACK

SDA

not acknowledge

acknowledge

Each byte is followed by an acknowledge or a not

acknowledge, generated by the receiver

Handshake procedure (Hold Master): In a master-slave

system, the master dictates when the slaves will receive or

transmit data. However, in some situations a slave device

may need time to store received data or prepare data to

be transmitted. Therefore, a handshake procedure is

required to allow the slave to indicate termination of

internal processing.

I2C Hold Master

ACK

SCL R/_W D7 D0 ACK

SDA

Hold master:

SCK line pulled LOW data ready: SCK line released

After the SCL pulse for the acknowledge signal, the SDP600

series sensor (slave) can pull down the SCL line to force the

master into a wait state. By releasing the SCL line, the sensor

indicates that its internal processing is completed and

transmission can resume. (The bold lines indicate that the

sensor controls the SDA/SCL lines.)

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3.4 Data transfer format

Data is transferred in byte packets in the I2C protocol,

which means in 8-bit frames. Each byte is followed by an

acknowledge bit. Data is transferred with the most

significant bit (MSB) first.

A data transfer sequence is initiated by the master

generating the Start condition (S) and sending a header

byte. The I2C header consists of the 7-bit I2C device

address and the data direction bit (R/_W).

The value of the R/_W bit in the header determines the

data direction for the rest of the data transfer sequence. If

R/_W = 0 (WRITE) the direction remains master-to-slave,

while if R/_W = 1 (READ) the direction changes to slave-

to-master after the header byte.

4. Command Set and Data Transfer

Sequences

A command is represented by an 8-bit command code.

The data direction may not change after the command

byte, since the R/_W bit of the preceding I2C header has

already determined the direction to be master-to-slave. In

order to execute commands in Read mode using I2C, the

following principle is used. On successful (acknowledged)

receipt of a command byte, the sensor stores the

command nibble internally. The Read mode of this

command is then invoked by initiating an I2C data transfer

sequence with R/_W = 1.

If a correctly addressed sensor recognizes a valid

command and access to this command is granted, it

responds by pulling down the SDA line during the

subsequent SCL pulse for the acknowledge signal (ACK).

Otherwise it leaves the SDA line unasserted (NACK).

The two most important commands are described in this

data sheet, and the data transfer sequences are specified.

Contact Sensirion for advanced sensor options.

4.1 Measurement triggering

Each individual measurement is triggered by a separate

read operation.

Note that two transfer sequences are needed to perform a

measurement. First write command byte hF1 (trigger

measurement) to the sensor, and then execute a read

operation to trigger the measurement and retrieve the flow

or differential pressure information.

On receipt of a header with R/_W=1, the sensor generates

the Hold Master condition on the bus until the first

measurement is completed. After the Hold Master

condition is released, the master can read the result as

two consecutive bytes. A CRC byte follows if the master

continues clocking the SCL line after the second result

byte. The sensor checks whether the master sends an

acknowledge after each byte and aborts the transmission

if it does not.

I2C Measurement

8-bit command code: hF1

Command: Trigger differential pressure measurement

1312 18 19 2221 27

MSByte MeasData LSByte MeasData

11 14 15 16 17 20 23 24 25 26

ACK

28 3130 36

Check Byte

29 32 33 34 35

1 2 3 4 5 6 7 8

ACK

9 18

I2CAdr

ACK

123456789

Hold Master

ACK

10 11 12 13 14 15 16 17

11110001

Command

1 0 0 0 0 0 0

1000000

I2CAdr

0 1

Hatched areas indicate that the sensor controls the SDA line.

Note that the first measurement result after reset is not

valid.

4.2 Soft reset

This command forces a sensor reset without switching the

power off and on again. On receipt of this command, the

sensor reinitializes the control/status register contents

from the EEPROM and starts operating according to these

settings.

I2C Soft Reset

8-bit command code: hFE

Command: Soft reset

1 2 3 4 5 6 7 8

ACK

system reboot

10 11 12 13 14 15 16 17

I2CAdr W

1 0 0 0 0 0 0 1 1 1 1

Command

11100

4.3 CRC-8 Redundant Data Transmission

Cyclic redundancy checking (CRC) is a popular technique

used for error detection in data transmission. The

transmitter appends an n-bit checksum to the actual data

sequence. The checksum holds redundant information

about the data sequence and allows the receiver to detect

transmission errors. The computed checksum can be

regarded as the remainder of a polynomial division, where

the dividend is the binary polynomial defined by the data

sequence and the divisor is a “generator polynomial”.

The sensor implements the CRC-8 standard based on the

generator polynomial

x8 + x5 + x4 +1.

Note that CRC protection is only used for date transmitted

from the slave to the master.

For details regarding cyclic redundancy checking, please

refer to the relevant literature.

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5. Conversion to Physical Values

5.1 Signal scaling and physical unit

The calibrated signal read from the sensor is a signed

INTEGER number (two's complement number). The

INTEGER value can be converted to the physical value by

dividing it by the scale factor (pressure = sensor output 

scale factor). The scale factor is specified in Section 2.

5.2 Temperature compensation

The SDP600 sensor series features digital temperature

compensation. The temperature is measured on the

CMOSens® chip by an on-chip temperature sensor. This

data is fed to a compensation circuit that is also integrated

on the CMOSens® sensor chip. No external temperature

compensation is necessary.

5.3 Mass flow temperature compensation

A sensor output proportional to mass flow is necessary for

measuring mass flow in a bypass configuration. Even

though the output of the SDP sensors with mass flow

temperature compensation is still differential pressure, the

temperature compensation is adapted especially for mass

flow measurements in a bypass configuration. At

calibration temperature both calibrations are equivalent.

Please find the application note “Bypass Configuration

Differential Pressure Sensor SDPxxx” on our website.

5.4 Altitude correction

The SDP600 sensor series achieves its unsurpassed

performance by using a dynamic measurement principle.

The applied differential pressure forces a small flow of gas

through the sensor, which is measured by the flow sensor

element. As a result, any variation in gas density affects

the sensor reading. While temperature effects are

compensated internally, variations in atmospheric

pressure (elevation above sea level) can be compensated

by a correction factor according to the following formula:

DPeff = DPsensor  (Pcal / Pamb)

DPeff: Effective differential pressure

DPsensor: Differential pressure indicated by the sensor

Pcal: Absolute pressure at calibration (966 mbar)

Pamb: Actual ambient absolute pressure.

Altitude correction factors:

Altitude

[meters]

Ambient pressure (Pamb)

[mbar]

Correction factor

(Pcal / Pamb)

1013

0.95

250

984

0.98

425

966

1.00

500

958

1.01

750

925

1.04

1500

842

1.15

2250

766

1.26

3000

697

1.38

Example: At 750 m above sea level and a sensor reading

of 40 Pa, the effective differential pressure is 41.8 Pa.

Note: In many HVAC applications such as air flow

measurement in a bypass configuration, the described

dependence on absolute pressure is actually welcome

because the quantity that must effectively be controlled is

the mass flow and not the volume flow. Mass flow is

dependent on differential pressure and absolute pressure.

For details please refer to our application note “Measuring

Flow in a Bypass Configuration”.

6. OEM Options

A variety of custom options can potentially be

implemented for high-volume OEM applications. Contact

Sensirion for more information.

www.sensirion.com Version 1.9 – July 2015 7/10

7. Mechanical Specifications

7.1 Mechanical concept

The SDP600 Series is designed for through-hole

technology and can be wave-soldered or hand-soldered to

a PCB.

 The SDP60x/SDP50x can be directly connected

to a manifold using two O-rings.

 The SDP61x/SDP51x sensors have ports for

connecting standard-size plastic tubes.

7.2 Mechanical characteristics

Parameter

PCB attachment

Clip-in and hand or wave soldering.

Additional mechanical attachment

depending on force requirements

Allowable

overpressure

1 bar (100 kPa, 400 inches H2O)

Rated burst pressure

> 5 bar

Gas flow through

sensor

< 150 ml/min

Weight

< 6 g

Protection rating

IP 30

7.3 SDP60x/SDP50x – Manifold connection

Figure 1: SDP60x/SDP50x manifold mount version. All

dimensions are in mm.

Sensirion recommends O-rings with the following

dimensions:

d1: 3–4 mm

d2: 2 mm

Figure 2: Cross section of recommended O-ring

7.4 SDP61x/SDP51x – Tube connection

Figure 3: SDP61x/SDP51x version with ports for tube

connection. All dimensions are in mm.

7.5 Pin assignments

Figure 4: Digital output pin assignments (bottom view).

7.6 Footprint

Figure 5: Footprint for PCB mounting. (top view = sensor side).

All dimensions in mm.

A: Overall sensor dimensions

B: Holes for additional mounting screws (optional)

www.sensirion.com Version 1.9 – July 2015 8/10

8. Instructions for Use

8.1 Soldering instructions

Standard wave soldering systems may be used for

soldering SDP600 series sensors. Reflow soldering is not

feasible and may damage the sensor.

The sensor ports must be protected from solder splash

and flux during soldering. Figure 6 shows an appropriate

temperature profile with maximum temperature values.

Figure 6: Suitable wave soldering profile.

The characteristics of wave soldering machines vary, so

any soldering setup must be tested before production use.

8.2 Sensor handling

The sensors of the SDP600 series are designed to be

robust and vibration resistant. Nevertheless, the accuracy

of the high-precision SDP600 series can be degraded by

rough handling. Sensirion does not guarantee proper

operation in case of improper handling. Note: avoid

applying any mechanical stress to the solder joints of the

sensor during or as a result of PCB assembly.

The sensor ships in an antistatic package to prevent

electrostatic discharge (ESD), which can damage the part.

To avoid such damage, ground yourself using a grounding

strap or by touching a grounded object. Furthermore store

the parts in the antistatic package when not in use.

8.3 Additional attachment

If necessary, the robustness of the sensor attachment to

the PCB can be increased by using a bracket as shown in

Figure 7.

Sensirion recommends using this additional bracket when

the sensor is fitted to a PCB. The bracket must be secured

before the pins are soldered to the PCB, as otherwise

sensor performance may be degraded by mechanical

stress.

Figure 7: Supplementary bracket for the SDP600 series.

8.4 Air flow and tubing

Due to the dynamic measurement principle, a small air

flow is required.

Figure 8: Typical air flow through the SDP600 series sensor.

Note: 1 sccm = 1 cm3/min at 0°C and 1013 mbar

(1 sccm = 0.001 standard liter).

This air flow through the sensor creates a dependence on

the tube length. The error is less than 1% with a tube

length up to 1 m (with 3/16 inch inside diameter).

-120

+120

-600

+600

Pressure difference (Pa)

Flow (ml/min)

200°C

150°C

100°C

50°C

0°C

250°C

Start

Flux zone

Preheat zone

Entrance to solder

Wave

Exit from solder

Wave

Solder Wave Peak

Temp. max. 260°C

Max 145°C

Approx. PCB

bottom-side temp.

PCB top-side

temperature

Approx.

1 min

(Time in wave < 2 s)

www.sensirion.com Version 1.9 – July 2015 9/10

9. Ordering Information

Use the part names and item numbers shown in the

following table when ordering SDP600 series differential

pressure sensors. For the latest product information and

local distributors, visit www.sensirion.com.

Part name

Description /

Output

Calibrated range

“Mass flow“

Span accuracy

Product number

1-10xxxx-xx

SDP500

I2C, manifold

mount

0 to +500 Pa

(0 to +2 in. H2O)

4.5%

0601-02

SDP510

I2C, tube

connection

0 to +500 Pa

(0 to +2 in. H20)

4.5%

0602-02

SDP501

I2C, manifold

mount

0 to +500 Pa

(0 to +2 in. H2O)

4.5%

1314-01

SDP511

I2C, tube

connection

0 to +500 Pa

(0 to +2 in. H20)

4.5%

1315-01

SDP600-500Pa

I2C, manifold

mount

±500 Pa

( ±2 in. H2O)

0456-02

SDP610-500Pa

I2C, tube

connection

±500 Pa

( ±2 in. H20)

0455-02

SDP600-125Pa

I2C, manifold

mount

±125 Pa

(±0.5 in. H2O)

0760-02

SDP610-125Pa

I2C, tube

connection

±125 Pa

( ±0.5 in. H20)

0761-02

SDP600-25Pa

I2C, manifold

mount

±25 Pa

( ±0.1 in. H2O)

0758-02

SDP610-25Pa

I2C, tube

connection

±25 Pa

( ±0.1 in. H20)

0759-02

SDP601-500Pa

I2C, manifold

mount

±500 Pa

(±2 in. H2O)

0603-02

SDP611-500Pa

I2C, tube

connection

±500 Pa

(±2 in. H20)

0604-02

Packaging units: 80 items/tray and 480 items/box.

9.1 Packaging

Housing: The sensor housing consists of PBT. The

device is fully RoHS compliant – it is free of Pb, Cd, Hg,

Cr(6+), PBB and PBDE.

Each sensor is labeled by laser printing on the front side:

 Sensor type

 Sensirion

product number

 Serial number

Figure 9: Marking of the housing.

Traceability Information: SDPxxx are shipped in trays of

80pcs. The tray dimension is 355mm x 255mm x 21.5mm.

By piling them up, the height per tray can be considered

as 19mm. For traceability, each tray is marked with a label.

No information can be derived from the code directly,

respective data is stored at Sensirion AG and is provided

upon request.

 Sensor type

 Sensirion item

number

 Lot number

 Number of

sensors inside

tray

 Barcode of lot

number

Figure 10: Label sticking on each tray

Revision history

Date

Author

Version

Changes

Sept , 2008

PHA

V1.0

Initial release

Nov, 2008

PHA

V1.1

Small amendments (power

consumption, asymmetric lines and US

office address)

Jan, 2009

PHA

V1.2

Explanation to SDP5x0 calibration

range, media compatibility extended

Feb, 2009

PHA

V1.3

Packaging information added, sensor

handling instruction

Nov, 2009

PHA

V1.4

Zero point accuracy changed. Supply

voltage requirements and

recommendations relaxed.

January,

2011

DAT

V1.5

Introduction of low power

versions(SDP6x6) and low differential

pressure versions SDP6xx-125Pa /

SDP6xx-25Pa.

Feb, 2011

VVO

V1.6

Calibrated Temperature Range is

extended, minor corrections

Sept, 2012

ANB

V1.7

Updated Product Number.

June, 2015

ANB

V1.8

Added SDP5x1. Moved SDP6x6 to

separate datasheet. Minor updates.

July, 2015

ANB

V1.9

Fixed broken link in chapter 5.

SDPxxx 

1-10xxxx-0x 

xxxxxxxx  80 



SENSIRION

SDPxxx 

PN: 1-10xxxx-0x 

SN: xxxxxxxxxx 

www.sensirion.com Version 1.9 – July 2015 10/10

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 (including death). 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 datasheet 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 “Handling Instructions” 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 datasheet 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: +1 805 409 4900

info_us@sensirion.com

www.sensirion.com

Sensirion Japan Co. Ltd.

phone: +81 3 3444 4940

info@sensirion.co.jp

www.sensirion.co.jp

Sensirion Korea Co. Ltd.

phone: +82 31 337 7700~3

info@sensirion.co.kr

www.sensirion.co.kr

Sensirion China Co. Ltd.

phone: +86 755 8252 1501

info@sensirion.com.cn

www.sensirion.com.cn

Sensirion AG (Germany)

phone: +41 44 927 11 66

info@sensirion.com

www.sensirion.com

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