Understanding Tilt Sensors: Principles, Types, and Applications

Introduction

Tilt sensors, also known as inclinometers, measure the slope, angle or tilt of objects with respect to gravity. These sensors are widely used in various applications, including industrial automation, aerospace, buildings, automotive, and consumer electronics.

Types of Tilt Sensors

Tilt sensors can be categorized into many types, each offering different advantages depending on the application. These types include accelerometer-based for gravity detection, gyroscope-based for rotation measurement, and vibration-based for tilt via motion analysis. Other types include optical laser, capacitive, magnetic, and pendulum sensors, each suited to specific applications. These sensors differ in operating principles, accuracy, and environmental adaptability.

1. Accelerometer tilt sensors

Accelerometer tilt sensors are devices that use accelerometer technology or Microelectromechanical Systems (MEMS) technology to measure tilt angles.

Working Principle

In Microelectromechanical Systems (MEMS) technology, tiny springs or masses are suspended on a chip. When the sensor is subjected to acceleration, these small masses shift slightly.
These tiny displacements are detected and used to measure the acceleration.

Once the acceleration is obtained, by integrating the acceleration, the sensor calculates the velocity, and by integrating again, it calculates the displacement, enabling tracking of the object’s motion, including tilt angles.

Advantages

  • Accelerometer tilt sensors are typically relatively simple and have relatively low manufacturing costs.
  • These sensors utilize MEMS technology, allowing for compact size and lighter weight, making them suitable for space-constrained or lightweight applications.
  • Accelerometer tilt sensors generally have lower power consumption, making them suitable for battery-powered or long-term use.

Limitation

  • Due to the integral calculation used to derive tilt angles in accelerometer tilt sensors, they are prone to integration drift, leading to accumulated errors over time.
  • For highly dynamic applications (in vibration or high-acceleration environments) the performance of accelerometer tilt sensors may be limited. This limits their sensitivity, making them less suitable for high-precision applications, particularly with small angle variations.

Application

  • Accelerometer tilt sensors perform well in some static applications, such as building tilt monitoring and platform leveling.

2. Gyroscope tilt sensors

Gyroscope tilt sensors use gyroscope technology to measure tilt angles. They detect the rate of rotation around a specific axis to determine the tilt or orientation of an object.

Working Principle

The basic principle involves measuring the rate of rotation, or angular velocity, of an object around its axis using a gyroscope. Once the angular velocity is obtained, it can be integrated to calculate the tilt angle of the object relative to its initial position, allowing for tracking of the object’s tilt state.

Advantages

  • Gyroscope tilt sensors Perform well in dynamic applications due to their high sensitivity to angular velocity and rapid changes.
  • These sensors typically offer high accuracy, especially for tracking small or rapid angular changes.
  • Compared to accelerometer tilt sensors, Gyroscope tilt sensors are less prone to integration drift and maintain accuracy longer than accelerometer sensors. They are also more stable in vibrating environments.

Limitation

  • The manufacturing cost of gyroscope tilt sensors is relatively high, making them less economically viable for some applications.
  • Gyroscope technology is relatively complex, requiring more electronic devices and sophistication.
  • Typically requires a larger power supply, which can be a challenge in battery-powered or long-term applications.
  • Performance can be impacted by temperature variations, requiring additional compensation measures.

Application

  • Gyroscope sensors are used in vehicles and aircraft to determine orientation and provide stabilization.
  • In consumer electronics, Found in devices like smartphones and game controllers for motion sensing.

3. Vibrating tilt sensor­s

Vibrating tilt sensors are devices that measure tilt angles or change in orientation using the principle of vibration. They typically include one or more vibrating devices, such as oscillating springs or suspended masses, which vibrate when tilted due to the influence of gravity.

Working Principle

Vibrating tilt sensors often utilize sensors such as gyroscopes or accelerometers to detect the characteristics of vibration, including frequency and amplitude. When the tilt angle of the sensor changes, these vibration characteristics also change.
The sensor is usually equipped with a signal processing unit that analyzes these changes in vibration and converts them into data that represents the tilt angle.

Advantages

  • Vibrating tilt sensors typically have low power consumption, this is ideal for long-term operation with limited power supply.
  • These sensors use MEMS technology, making them suitable for space-constrained or weight-sensitive applications.
  • Due to their reliance on vibration principles, these sensors adapt well to dynamic environments and can handle vibration or acceleration changes.
  • They are more economical compared to high-precision tilt sensors and have good environmental resistance properties. They are typically waterproof, dustproof, and shock-resistant, suitable for harsh environments.

Limitation

  • Vibrating tilt sensors usually have lower accuracy and are not suitable for high-precision applications.
  • External vibrations may interfere with measurements, requiring additional filtering or calibration.

Application

  • Vibrating tilt sensors are used in industrial machinery, safety systems, and automotive applications to monitor tilt for proper operation, stability control, and safety.
    They are ideal for environments with vibration or heavy machinery.

4. Laser tilt sensors

Laser tilt sensors are devices that measure tilt angles using laser technology, typically based on the principle of optical interference.

Working Principle

Laser tilt sensors use laser beams to measure the tilt angle of an object with high precision. In this type of sensor, a laser beam is split into two beams, each traveling different optical paths. These two beams intersect in the sensor’s detection area, creating interference fringes.

When the sensor tilts, at least one of the optical paths changes, causing the interference fringes to move. By detecting these changes in interference fringes, the tilt angle can be calculated. The system includes optical devices such as beam splitters or mirrors to guide the laser beams and detect changes in interference fringes.

Advantages

  • Laser tilt sensors typically offer high accuracy, ideal for applications requiring precise measurement of small angle changes.
  • These sensors are very sensitive to changes in tilt angles and able to detect even small angle variations.
  • Less affected by external vibrations because changes in interference fringes are primarily influenced by changes in optical path caused by tilting.
  • Suitable for applications where mechanical contact is undesirable, reducing wear and tear.
  • Optical systems can be designed to handle varying temperature and pressure conditions.

Limitation

  • Laser tilt sensors typically more expensive due to their high accuracy and complex optical systems.
  • These are more sensitive to environmental conditions. Their performance may be affected by factors like temperature, requiring additional calibration and compensation.

Application

  • Laser tilt sensors are used for leveling in construction, machine orientation in industries, and precise tilt measurement in aerospace.

5. Capacitive tilt sensors

Capacitive tilt sensors are devices that measure tilt angles using the principle of capacitance. Capacitor refers to the charge storage between two conductors, which is determined by the distance and area between the two conductors.

Working Principle

The capacitance in capacitive tilt sensors changes as the distance or orientation between conductive plates inside the sensor varies with tilt. These sensors typically consist of two capacitive sensing elements whose relative positions shift based on the device’s tilt angle. A readout circuit detects these changes in capacitance and converts them into tilt angle data.

Advantages

  • Capacitive tilt sensors offer high accuracy, especially for small angle changes.
  • These sensors can measure angles ranging from small to large tilts.
  • They use MEMS technology, making them suitable for space-limited or lightweight applications.

Limitation

  • These sensors are temperature sensitivity and performance may vary with temperature, requiring calibration and compensation.
  • Capacitive sensors may also be susceptible to interference from external electric fields, requiring special design or shielding to minimize their impact.

Application

  • Capacitive tilt sensors are used in construction to monitor structures, in industries for machine alignment, and in gadgets like game controllers and wearables.

6. Magnetic tilt sensor

Magnetic tilt sensors are devices that measure tilt angles using the principle of magnetic induction.
These sensors use magnetometers or Hall effect devices to detect tilt by measuring changes in magnetic flux from the Earth’s magnetic field, or another external magnetic field.

Working Principle

These sensors typically contain one or more magnetic sensor devices, often magnetic field sensors such as Hall effect sensors.

These sensors utilize the Earth’s magnetic field as a reference. When the tilt sensor tilts, the relative position of the sensing device changes with respect to the Earth’s magnetic field. As the sensor tilts, the projection of the Earth’s magnetic field measured by the magnetic field sensor changes. This change can be converted into tilt angle data.

Advantages

  • Magnetic tilt sensors can measure small to large tilt angles effectively.
  • Unlike optical sensors, magnetic tilt sensors are not affected by external light. They are also less susceptible to vibration, resulting in more stable performance in vibrating environments.
  • Magnetic tilt sensors have fast response times due to the absence of mechanical parts, enabling real-time tilt detection.
  • Magnetic tilt sensors have simpler manufacturing and operation, resulting in lower costs.

Limitation

  • External magnetic fields can affect accuracy, requiring shielding or compensation.

Application

Magnetic tilt sensors are used in robotics for orientation, in automotive systems for stability and alignment, and in consumer electronics like smartphones for tilt detection.

7. Pendulum tilt sensors

Pendulum tilt sensors, also known as inclinometers, are a common type of tilt sensor. They detect tilt by measuring the position of a pendulum relative to a fixed point. As the sensor tilts, the pendulum swings, and its position is used to determine the tilt angle.

Pendulum tilt sensors are divided into solid-state, liquid-based, and gas-based types.

Working Principle

Solid-state pendulum tilt sensors operate based on the principles of physics related to pendulum motion. When the pendulum arm tilts, the mass on pendulum swings, and the angle of this swing corresponds to the tilt angle, which can be determined by measuring the swing of the pendulum.

Liquid-based pendulum tilt sensors work by detecting the movement of liquid inside a container when it tilts. As the container tilts, the liquid surface forms a slope.
These sensors are typically designed with one or more pivot axes to reflect the direction and angle of tilt.

Gas-based pendulum tilt sensors use gas pressure sensing technology. These sensors typically include a gas chamber, and when tilted, the movement of gas inside the chamber changes the pressure. Sensor devices can detect this pressure change and convert it into corresponding electrical signals.
The principles and characteristics of specific gas-based pendulum tilt sensors may vary depending on the manufacturer and application. When selecting a sensor, it is advisable to consult relevant technical specifications and documentation for more detailed information.

Advantages

  • Pendulum tilt sensors have a simple design with minimal components, making them easy to implement and cost-effective.
  • Solid-state pendulum tilt sensors offer good accuracy and sensitivity in some applications, but considerations such as size, cost, and specific application requirements need to be taken into account when selecting them.
  • Liquid-based pendulum tilt sensors offer advantages such as simple mechanical structure and relatively low cost. However, their performance needs to be carefully evaluated based on specific application requirements.

Limitation

  • Pendulum tilt sensors lack high precision and may experience wear over time due to mechanical components.

Application

  • Pendulum tilt sensors are used in level indicators, safety systems, and consumer products requiring basic tilt detection.

Tilt Sensors from DigiKey

Inclinometers

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Application Characteristics of Different Tilt Sensors

Types Application Characteristics
Accelerometer tilt sensor Accelerometer tilt sensors are suitable for applications sensitive to cost and size constraints. However, in applications where high dynamic performance and precision are required, other more complex tilt sensing technologies may need to be considered.
Gyroscopic tilt sensor Gyroscopic tilt sensors excel in high accuracy and dynamic performance, making them particularly suitable for applications requiring fast and precise tilt measurements. However, considerations still need to be given to device cost, power consumption, and complexity.
Vibration tilt sensor Vibration tilt sensors are often an economical and suitable solution in certain applications, especially in scenarios where low power consumption, good dynamic performance, and low cost are required. However, it is still necessary to evaluate whether their accuracy and performance are sufficient based on the specific requirements.
Laser tilt sensor Laser tilt sensors are a high-precision, highly sensitive, and non-contact measurement technology suitable for applications requiring high measurement accuracy. However, when selecting them, cost and application requirements need to be considered, as they are limited by line-of-sight visibility and optical effects.
Capacitive tilt sensor Capacitive tilt sensors are widely used and offer stable performance, making them particularly suitable for applications requiring precise measurement of tilt angles. These applications include industrial automation, building engineering, vehicle tilt monitoring, consumer electronics, and others where there’s a high demand for tilt angle measurement and cost sensitivity.
Magnetic tilt sensor Magnetic tilt sensors are a cost-effective and widely applicable tilt sensing technology. When selecting one, it’s essential to consider the application environment and requirements to ensure the sensor can achieve the desired accuracy and stability.
Pendulum tilt sensor Pendulum tilt sensors can be further classified into solid-state, liquid-based, and gas-based types. While Pendulum tilt sensors demonstrate good accuracy and sensitivity in some applications, it’s crucial to consider factors such as size, cost, and specific application requirements when making a selection.

Conclusion

Tilt sensors are essential devices used to measure the inclination or tilt of objects in relation to gravity, and they play a key role in a wide range of industries, from aerospace to consumer electronics. Each type of tilt sensor—whether accelerometer, gyroscope, vibrating, laser, capacitive, magnetic, or pendulum—offers unique advantages and limitations depending on the application. When selecting a tilt sensor, it is essential to evaluate factors such as accuracy, tilt range, environmental conditions, power consumption, cost, and maintenance needs to ensure optimal performance and reliability.
By comprehensively considering these factors, a tilt sensor that best suits the specific application requirements can be chosen, ensuring the performance and reliability of the system.
Check the below articles to select the correct tilt sensor for your application.

More article on Tilt Sensors

Selecting the Right Tilt Sensor: Key Factors and Solutions for Success

TSDA Series Tilt Sensors

Applicable Part Number
DigiKey Part Number Manufacturer Part Number
490-18218-2-ND,490-18218-1-ND,490-18218-6-ND SCL3300-D01-10
490-18217-2-ND,490-18217-1-ND,490-18217-6-ND SCL3300-D01-1
ADIS16201CCCZ-ND ADIS16201CCCZ
ADIS16203CCCZ-ND ADIS16203CCCZ
505-ADIS16209CCCZ-ND ADIS16209CCCZ
223-1777-ND G-NSDOG2-001
505-ADIS16210CMLZ-ND ADIS16210CMLZ
2131-H6MM-ND H6MM
551-1053-2-ND,551-1053-1-ND,551-1053-6-ND SCA830-D07-1
490-SCL3400-D01-10TR-ND,490-SCL3400-D01-10CT-ND,490-SCL3400-D01-10DKR-ND SCL3400-D01-10
1993-TSDA-J-IR045-HM-W-ND TSDA-J-IR045-HM-W
1993-TSDA-J-IR045-HM-C-ND TSDA-J-IR045-HM-C
1993-TSDA-J-IR025-HM-W-ND TSDA-J-IR025-HM-W
1993-TSDA-J-IR025-HM-C-ND TSDA-J-IR025-HM-C
490-SCL3400-D01-1TR-ND,490-SCL3400-D01-1CT-ND,490-SCL3400-D01-1DKR-ND SCL3400-D01-1
223-1572-ND G-NSDOG1-006
223-1576-ND G-NSDOG2-200
223-1574-ND G-NSDOG2-003
2046-INX360D-F99-I2E2-5M-ND INX360D-F99-I2E2-5M
2046-INX360D-F99-U2E2-V15-ND INX360D-F99-U2E2-V15
2046-INX360D-F99-I2E2-V15-ND INX360D-F99-I2E2-V15
2131-H6MM-CANOPEN-ND H6MM-CANOPEN
490-SCL3400-D01-004-ND SCL3400-D01-004
1882-1116334-ND 1116334
2539-Tilt-05-B1-ND Tilt-05-B1
2539-Tilt-15-S-90-A1-ND Tilt-15-S-90-A1
2539-Tilt-15-X-90-A1-ND Tilt-15-X-90-A1
2539-Tilt-30-A-4-A1-ND Tilt-30-A-4-A1
2539-Tilt-30-A-3-A1-ND Tilt-30-A-3-A1
2539-Tilt-30-A-8-A1-ND Tilt-30-A-8-A1
2539-Tilt-30-A-U-A1-ND Tilt-30-A-U-A1
3925-BND-WILOW-HI-INC-15B-ND BND-WILOW-HI-INC-15B
3925-BND-WILOW-HI-INC-30B-ND BND-WILOW-HI-INC-30B
2539-Tilt-33-A-U-A1-ND Tilt-33-A-U-A1
2539-Tilt-33-A-8-A1-ND Tilt-33-A-8-A1
2539-Tilt-33-A-3-A1-ND Tilt-33-A-3-A1
2539-Tilt-33-A-4-A1-ND Tilt-33-A-4-A1
3925-BND-WILOW-HI-INC-30B-EHR-ND BND-WILOW-HI-INC-30B-EHR
1882-1073789-ND 1073789
2539-Tilt-50-A-U-A1-ND Tilt-50-A-U-A1
2539-Tilt-50-A-8-A1-ND Tilt-50-A-8-A1
2539-Tilt-50-A-4-A1-ND Tilt-50-A-4-A1
2539-Tilt-50-A-3-A1-ND Tilt-50-A-3-A1
3925-SK-INCLINOMETER-HI-INC-XR-30B-ND SK-INCLINOMETER-HI-INC-XR-30B
2539-Tilt-55-A-3-A1-ND Tilt-55-A-3-A1
2539-Tilt-55-A-4-A1-ND Tilt-55-A-4-A1
2539-Tilt-55-A-8-A1-ND Tilt-55-A-8-A1
2539-Tilt-55-A-U-A1-ND Tilt-55-A-U-A1
2539-Tilt-57-A-4-A1-ND Tilt-57-A-4-A1
2539-Tilt-57-A-U-A1-ND Tilt-57-A-U-A1
2539-Tilt-57-A-8-A1-ND Tilt-57-A-8-A1
2539-Tilt-57-A-3-A1-ND Tilt-57-A-3-A1
3925-BND-2.4GHZ-HI-INC-SR-10T-SCM-ND BND-2.4GHZ-HI-INC-SR-10T-SCM
3925-BND-WILOW-HI-INC-15B-EHR-ND BND-WILOW-HI-INC-15B-EHR
3925-SK-INCLINOMETER-HI-INC-30B-ND SK-INCLINOMETER-HI-INC-30B
3925-SK-INCLINOMETER-INC-30B-ND SK-INCLINOMETER-INC-30B
3925-SK-INCLINOMETER-HI-INC-SR-10T-ND SK-INCLINOMETER-HI-INC-SR-10T
3925-SK-HI-INC-SR-SCM-OUT-ND SK-HI-INC-SR-SCM-OUT
223-1573-ND G-NSDOG2-002
1993-TSDA-A-IR025-HM-W-ND TSDA-A-IR025-HM-W
1993-TSDA-A-IR045-HM-W-ND TSDA-A-IR045-HM-W
1993-TSDA-A-IR090-HM-W-ND TSDA-A-IR090-HM-W
1993-TSDA-A-IR045-HM-C-ND TSDA-A-IR045-HM-C
1993-TSDA-A-IR025-HM-C-ND TSDA-A-IR025-HM-C
1993-TSDA-A-IR090-HM-C-ND TSDA-A-IR090-HM-C
1993-TSDA-J-IR090-HM-W-ND TSDA-J-IR090-HM-W
1993-TSDA-J-IR090-HM-C-ND TSDA-J-IR090-HM-C
1993-TSDA-O-IR045-HM-W-ND TSDA-O-IR045-HM-W
1993-TSDA-O-IR025-HM-W-ND TSDA-O-IR025-HM-W
1993-TSDA-O-IR090-HM-W-ND TSDA-O-IR090-HM-W
1993-TSDA-O-IR025-HM-C-ND TSDA-O-IR025-HM-C
1993-TSDA-O-IR045-HM-C-ND TSDA-O-IR045-HM-C
1993-TSDA-O-IR090-HM-C-ND TSDA-O-IR090-HM-C
SCA830-D07-10-ND SCA830-D07-10
490-SCA830-D07-004-ND SCA830-D07-004
490-SCL3300-D01-004-ND SCL3300-D01-004
G-NSDOG2-002W/CALCERTG-NSMIS-005-ND G-NSDOG2-002 W/CAL CERT G-NSMIS-005
G-NSDOG2-001W/CALCERTG-NSMIS-005-ND G-NSDOG2-001 W/CAL CERT G-NSMIS-005
G-NSDOG2-200W/CALCERTG-NSMIS-005-ND G-NSDOG2-200 W/CAL CERT G-NSMIS-005
G-NSDOG2-003W/CALCERTG-NSMIS-005-ND G-NSDOG2-003 W/CAL CERT G-NSMIS-005
1882-1118561-ND 1118561
1882-1116341-ND 1116341
1882-1116343-ND 1116343
G-NSDOG2-021W/CALCERTG-NSMIS-005-ND G-NSDOG2-021 W/CAL CERT G-NSMIS-005
1882-1121701-ND 1121701
1882-1120312-ND 1120312
1882-1116333-ND 1116333
1882-1116336-ND 1116336
1882-1116303-ND 1116303
1882-1116332-ND 1116332
1882-1123685-ND 1123685
1882-1120743-ND 1120743
1882-1116337-ND 1116337
1882-1116338-ND 1116338
1882-1124311-ND 1124311
1882-1122883-ND 1122883
1882-1116335-ND 1116335
1882-1121327-ND 1121327
1882-1073784-ND 1073784
1882-1073783-ND 1073783
1882-1073785-ND 1073785
1882-1116345-ND 1116345
1882-1116575-ND 1116575
1882-1116340-ND 1116340
1882-1120611-ND 1120611
1882-1121189-ND 1121189
1882-1120612-ND 1120612
1882-1073780-ND 1073780
1882-1073782-ND 1073782
1882-1073781-ND 1073781
1882-1116342-ND 1116342
2046-INX360D-F99-U2E2-5M-ND INX360D-F99-U2E2-5M
1882-1124499-ND 1124499
1882-1129143-ND 1129143
1882-1073788-ND 1073788
2046-INX360D-F99-I2E2-7M-ND INX360D-F99-I2E2-7M
2046-INX360D-F99-I2E2-8.5M-ND INX360D-F99-I2E2-8.5M
1882-1073786-ND 1073786
1882-1073787-ND 1073787
1882-1073794-ND 1073794
1882-1073797-ND 1073797
1882-1073795-ND 1073795
1882-1073796-ND 1073796
2046-INY360D-F99-2U2E2-V17-ND INY360D-F99-2U2E2-V17
2046-INY360D-F99-2I2E2-V17-ND INY360D-F99-2I2E2-V17
2046-INY360D-F99-2I2E2-5M-ND INY360D-F99-2I2E2-5M
2046-INY360D-F99-2U2E2-5M-ND INY360D-F99-2U2E2-5M
1882-1073802-ND 1073802
1882-1073805-ND 1073805
1882-1125894-ND 1125894
2046-INX360D-F99-B16-V15-ND INX360D-F99-B16-V15
2046-INX360D-F99-B20-V15-ND INX360D-F99-B20-V15
1882-1073792-ND 1073792
1882-1073793-ND 1073793
1882-1073791-ND 1073791
1882-1073790-ND 1073790
2046-INY030D-F99-2I2E2-5M-ND INY030D-F99-2I2E2-5M
2046-INY060D-F99-2I2E2-V17-ND INY060D-F99-2I2E2-V17
2046-INY030D-F99-2I2E2-V17-ND INY030D-F99-2I2E2-V17
2046-INY030D-F99-2U-V15-ND INY030D-F99-2U-V15
1882-1073800-ND 1073800
1882-1073798-ND 1073798
1882-1073799-ND 1073799
1882-1073801-ND 1073801
2046-INY360D-F99-B16-V15-ND INY360D-F99-B16-V15
2046-INY360D-F99-B20-V15-ND INY360D-F99-B20-V15
1882-1115732-ND 1115732
2046-INY120D-F99-B20-V15-ND INY120D-F99-B20-V15
2046-INY030D-F99-B16-V15-ND INY030D-F99-B16-V15
2046-INY030D-F99-B20-V15-ND INY030D-F99-B20-V15
2046-INY030D-F99-2I2E2-25M-ND INY030D-F99-2I2E2-25M
1882-1094483-ND 1094483
1882-1094486-ND 1094486
1882-1094485-ND 1094485
1882-1094488-ND 1094488
1882-1098670-ND 1098670
1882-1098671-ND 1098671
1882-1098668-ND 1098668
1882-1098669-ND 1098669
2046-INX360D-F99-I2E2-V15-EX-ND INX360D-F99-I2E2-V15-EX
2046-ACX04-F99-I-V15-916070-ND ACX04-F99-I-V15-916070
2046-INY030D-F99-2I2E2-Y915743-ND INY030D-F99-2I2E2-Y915743
1724-1442-ND T-P2-15-A1-CS10
T-M1-360-A1-M12/8-ND T-M1-360-A1-M12/8
T-P1Y-60-A1-CS10-ND T-P1Y-60-A1-CS10
SCL3300-D01-ND SCL3300-D01
EG4917TR-ND,EG4917CT-ND TM1000Q
1835-1000-ND CW1300-1
1835-1156-ND AG1262-1
360-2188-ND DSBA1H
360-2187-ND DSBA1P
1835-1002-ND AG3011-77C
735-1012-ND T3-B-LS
1835-1004-ND PD5005-7TC
735-1011-ND T1-AB-JS
CKN10398-ND RB-220-07A R
CKN10375-ND RB-231X2
1835-PD6045-ND PD6045
360-2291-ND DSA01
255-5187-ND AHF21
255-5916-ND AHF23
1835-PD6045-LC-ND PD6045-LC
1835-1003-ND PD6010
1835-PD6011-NO-1-ND PD6011-NO-1
881-RBS306-TILT-HP-US-ND RBS306-TILT-HP-US
255-5186-ND AHF22
1528-173-ND 173
1568-SEN-10289-ND SEN-10289
1835-PD5000-ND PD5000
1835-PD5005-ND PD5005
1835-PD5005-74-ND PD5005-74
1835-PD5005-73-ND PD5005-73
1835-PD5004-ND PD5004
2027-1004-ND RBS101-TILT-RCZ2
1835-PD5009-ND PD5009
1835-PD6011-NC-1-ND PD6011-NC-1
1835-PD6011-NO-2-ND PD6011-NO-2
1835-PD6011-NC-2-ND PD6011-NC-2
1835-PD6000-ND PD6000
1920-08330000504-ND 08330000504
1920-08330000505-ND 08330000505
1920-08330000067-ND 08330000067
1920-08330000095-ND 08330000095
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1920-08330000500-ND 08330000500
1920-08330000501-ND 08330000501
1920-08330000066-ND 08330000066
1920-08330000080-ND 08330000080
ADIS16209/PCBZ-ND ADIS16209/PCBZ
505-EVAL-ADIS-FX3Z-ND EVAL-ADIS-FX3Z
ADIS16203/PCBZ-ND ADIS16203/PCBZ
490-SCL3300-D01-PCB-ND SCL3300-D01-PCB
EVAL-CN0189-SDPZ-ND EVAL-CN0189-SDPZ
ADIS16201/PCBZ-ND ADIS16201/PCBZ
490-MEMS-EVAL-BOARD-ND MEMS-EVAL-BOARD
551-1059-ND SCA830-D07-PCB
490-SCL3400-D01-PCB-ND SCL3400-D01-PCB
SEN0079-ND SEN0079
SEN0183-ND SEN0183
813-1028-ND DLP-TILT-G
ADIS16210/PCBZ-ND ADIS16210/PCBZ
490-8620-ND SCA100T-D01-PCB
490-8621-ND SCA100T-D02-PCB
490-8623-ND SCA103T-D04-PCB
490-8624-ND SCA103T-D05-PCB
551-1006-ND DEMO KIT