Evaluation Boards

Evaluation Boards - Sensors

Part Number	Description / PDF	Quantity
MAX86916EVSYS# Maxim Integrated	EVAL HEARTRATE BLOOD O2	921
AR0144CSSM00SUKAH3-GEVB Sanyo Semiconductor/ON Semiconductor	BOARD EVAL 1MP 1/4 CIS MONO 0 DE	2
EVB90393 Melexis	BOARD EVAL FOR MLX90393	4
SHUTTLE BOARD BMA423 Bosch Sensortec	EVAL BOARD FOR BMA423	22
BNO055-SHUTL Bosch Sensortec	SHUTTLE BOARD DEV KIT BNO055	0
SEN-12829 SparkFun	RGB LIGHT SENSOR - ISL29125	74
TMP108EVM Texas Instruments	EVAL MODULE FOR TMP108	4
ZMID5201MARC13001 Renesas Electronics America	EVALUATION KIT	1
MMC5983MA-B MEMSIC	DEV BOARD FOR MMC5983MA	36
EVAL-ADXRS450Z Analog Devices, Inc.	BOARD STAMP ADXRS450 SOIC	2
NNAMC2300PCEV Neonode	EVAL KIT MODULE 0 DEG 230MM	101
HRM43-GGG-PS Silicon Labs	SI1143 HRM EVAL KIT	0
AG911-07E NVE Corporation	KIT EVALUATION GMR SWITCH	11
100080101-01-EVAL Bend Labs	1-AXIS EVAL KIT	0
EVB90316-GO Melexis	BOARD EVAL FOR MLX90316-GO	2
SI7005-EVB Silicon Labs	BOARD DAUGHTER SI7005	0
ASEK-06-T-KIT-DK Allegro MicroSystems	KIT EVALUATION SENSOR	20
TMP75CEVM Texas Instruments	EVAL MODULE TMP75C	2
VL53L1X-SATEL STMicroelectronics	BREAKOUT BOARD WITH VL53L1X LONG	423
USEQDAK7128L00 KEMET	FOOD SENSOR EVALUATION KIT LINEA	1

Evaluation Boards - Sensors

1. Overview

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.

2. Major Types and Functional Classification

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

3. Structure and Components

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.

4. Key Technical Specifications

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

5. Application Areas

Industrial Automation: Predictive maintenance systems, process control
Healthcare: Wearable vital sign monitors, diagnostic equipment
Consumer Electronics: Smart home devices, mobile accessories
Automotive: Tire pressure monitoring, ADAS sensors
Aerospace: Structural health monitoring, navigation systems

6. Leading Manufacturers and Products

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

7. Selection Guidelines

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.

8. Industry Trends

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.