| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Roving Networks / Microchip Technology |
KIT EVAL MTOUCH CAPACTIVE |
0 |
|
 |
Roving Networks / Microchip Technology |
BOARD DEMO PICTAIL TC72 |
0 |
|
 |
Roving Networks / Microchip Technology |
BOARD DEMO PICTAIL TC77 |
0 |
|
 |
Roving Networks / Microchip Technology |
DEMO KIT FOR SAMD20 |
0 |
|
 |
Roving Networks / Microchip Technology |
BOARD EVAL PCAP FOR PIC32 |
0 |
|
 |
Roving Networks / Microchip Technology |
KIT EVALUATION PIC16F/PIC24F |
0 |
|
 |
Roving Networks / Microchip Technology |
INERTIAL ONE SENSOR BOARD |
0 |
|
 |
Roving Networks / Microchip Technology |
BOARD DEMO MOTION SENSOR |
0 |
|
 |
Roving Networks / Microchip Technology |
BOARD EVAL CAPACITIVE TOUCH |
0 |
|
 |
Roving Networks / Microchip Technology |
EVAL BOARD PCAP TOUCH MTCH6301 |
0 |
|
 |
Roving Networks / Microchip Technology |
EVAL BOARD FOR EMC1402 |
0 |
|
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Roving Networks / Microchip Technology |
BOARD EVAL FOR QT111 TOUCH SENSR |
0 |
|
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Roving Networks / Microchip Technology |
BOARD EVALUATION FOR QT60040 |
0 |
|
|
Roving Networks / Microchip Technology |
KIT EVAL FOR QT110/111/112/113 |
0 |
|
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Roving Networks / Microchip Technology |
BOARD EVALUATION FOR QT60161 |
0 |
|
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Roving Networks / Microchip Technology |
BOARD EVALUATION FOR QT60485 |
0 |
|
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Roving Networks / Microchip Technology |
SENSOR MOD TOUCH/PROXIMITY 24DIP |
0 |
|
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Roving Networks / Microchip Technology |
KIT EVAL FOR QT401-IS QSLIDE |
0 |
|
|
Roving Networks / Microchip Technology |
BOARD EVAL FOR QT511 QSLIDE |
0 |
|
|
Roving Networks / Microchip Technology |
BOARD EVALUATION FOR QT1106-ISG |
0 |
|
Evaluation boards for sensors are specialized hardware platforms designed to test, validate, and develop sensor-based applications. These boards integrate sensor elements with processing units, communication interfaces, and power management modules. They play a critical role in accelerating product development cycles in industries such as IoT, industrial automation, healthcare, and consumer electronics by enabling rapid prototyping and performance characterization.
| Type | Functional Features | Application Examples |
|---|---|---|
| Temperature Sensor Boards | High-precision thermal sensing with digital/analog outputs | Climate control systems, medical devices |
| Accelerometer Boards | 3-axis motion detection with programmable sensitivity | Vibration monitoring, fitness trackers |
| Pressure Sensor Boards | Atmospheric/differential pressure measurement | Weather stations, automotive systems |
| Environmental Sensor Boards | Multi-parameter detection (humidity, gas, light) | Smart agriculture, air quality monitors |
| Image Sensor Boards | High-resolution optical sensing with ISP integration | Surveillance cameras, machine vision |
Typical evaluation boards consist of: - Sensor element (MEMS, CMOS, or discrete transducers) - Microcontroller/SoC with ADC/DAC interfaces - Communication modules (I2C, SPI, UART, BLE/Wi-Fi) - Power management ICs and voltage regulators - Debugging interfaces (JTAG, SWD) - Auxiliary components (LED indicators, potentiometers) The PCB layout optimizes signal integrity while minimizing electromagnetic interference.
| Parameter | Description | Importance |
|---|---|---|
| Measurement Range | Minimum/maximum detectable values | Determines application suitability |
| Accuracy | Error margin vs. reference values | Impacts system reliability |
| Sampling Rate | Data acquisition frequency | Defines dynamic response capability |
| Power Consumption | Operating current/voltage requirements | Affects battery life and thermal design |
| Interface Type | Communication protocol compatibility | Dictates system integration complexity |
| Manufacturer | Representative Product | Key Features |
|---|---|---|
| STMicroelectronics | STEVAL-MKI187V1 | 6-axis IMU with advanced calibration |
| Texas Instruments | BOOSTXL-ULTRASONIC | Ultrasonic sensing for distance measurement |
| Analog Devices | EVAL-ADICUP3029 | Low-power Cortex-M4F based platform |
| NXP Semiconductors | FRDM-FXS-MULTI-B | Multi-sensor fusion for IoT applications |
Key considerations include: - Match sensor specifications to target application requirements - Verify compatibility with existing development ecosystems - Evaluate power budget and form factor constraints - Consider available software support (drivers, SDKs) - Assess calibration and certification requirements Example: For a wearable health monitor, prioritize low-power accelerometers with medical-grade accuracy.
Emerging trends include: - Integration of AI accelerators for edge computing - Development of wireless sensor nodes with energy harvesting - Advancements in MEMS fabrication for higher sensitivity - Standardization of sensor fusion algorithms - Growth of open-source hardware ecosystems Market projections indicate a 12% CAGR through 2027 driven by IoT and Industry 4.0 adoption.