| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Maxim Integrated |
EVAL 8 CHANNEL IO-LINK MASTER |
34 |
|
 |
Maxim Integrated |
REFERENCE DESIGN PETALUMA |
112 |
|
 |
Maxim Integrated |
EVAL KIT FOR MAX31912 |
2 |
|
 |
Maxim Integrated |
EVAL KIT MAX16545 |
312 |
|
 |
Maxim Integrated |
BOARD EVAL RTC FOR DS3231M |
136 |
|
 |
Maxim Integrated |
EVAL MAX40203 1A IDEAL DIODE |
728 |
|
 |
Maxim Integrated |
DEMO KIT FOR MAX31856 |
28 |
|
 |
Maxim Integrated |
EVAL KIT MAX16946 |
120 |
|
 |
Maxim Integrated |
EVAL KIT FOR MAX9247 |
9 |
|
 |
Maxim Integrated |
EVALUATION KIT FOR DCDC & HOST-C |
323 |
|
 |
Maxim Integrated |
EVAL BOARD FOR MAX32010 |
34 |
|
 |
Maxim Integrated |
14-BIT GMSL DE-SERIALIZER WITH H |
114 |
|
 |
Maxim Integrated |
KIT EVAL FOR MAX4983 |
3424 |
|
 |
Maxim Integrated |
KIT EVAL FOR MAX9064 |
19 |
|
 |
Maxim Integrated |
EVALUATION KIT FOR MAX9926U |
422 |
|
 |
Maxim Integrated |
KIT FOR MAX17055 |
68 |
|
 |
Maxim Integrated |
EVAL KIT FOR MAX31914 |
17 |
|
 |
Maxim Integrated |
EVAL MAX96701 GMSL |
29 |
|
 |
Maxim Integrated |
EVAL FOR MAX14912 |
9 |
|
 |
Maxim Integrated |
EVAL KIT FOR MAX17119 |
17 |
|
Evaluation and Demonstration Boards and Kits are hardware platforms designed to facilitate the development, testing, and demonstration of electronic systems. They serve as critical tools for engineers and developers to prototype applications, validate designs, and accelerate time-to-market. These boards integrate processors, sensors, communication interfaces, and software ecosystems, enabling rapid experimentation across diverse industries such as IoT, automotive, and industrial automation.
| Type | Functional Features | Application Examples |
|---|---|---|
| Microcontroller Development Boards | Embedded CPUs, GPIOs, integrated peripherals | IoT devices, robotics |
| FPGA Evaluation Boards | Reconfigurable logic, high-speed interfaces | Communication systems, AI accelerators |
| Sensor Expansion Kits | Multi-sensor integration (temperature, motion, etc.) | Smart agriculture, environmental monitoring |
| Wireless Communication Modules | Bluetooth/Wi-Fi/LoRa protocols, antenna interfaces | Connected healthcare, smart cities |
Typical architecture includes: - Processing Units: Microcontrollers, FPGAs, or SoCs - Memory: RAM, Flash, EEPROM - Interfaces: USB, UART, SPI, I2C, Ethernet - Power Management: Regulators, battery connectors - Software Stack: SDKs, device drivers, IDEs Physical designs often feature standardized form factors (e.g., Arduino Uno, Raspberry Pi HATs) for modular expansion.
| Parameter | Description |
|---|---|
| Processor Performance (MHz/GHz) | Determines computational capability |
| Memory Capacity (RAM/Flash) | Affects program complexity and data storage |
| Interface Types | Dictates peripheral compatibility |
| Power Consumption (mW/MHz) | Critical for battery-operated devices |
| Operating Temperature (-40 C to +85 C) | Defines environmental durability |
- Internet of Things (IoT): Smart home controllers, edge AI nodes - Automotive: ADAS sensor fusion platforms - Industrial Automation: PLC controllers, predictive maintenance systems - Consumer Electronics: Wearables, AR/VR prototypes
| Manufacturer | Representative Products |
|---|---|
| STMicroelectronics | STM32 Nucleo Series, SensorTile Kit |
| Intel | Intel Edison, Movidius Neural Compute Stick |
| Xilinx | Zynq UltraScale+ MPSoC Evaluation Kit |
| Arduino | Arduino MKR Series, Nano 33 IoT |
Key considerations: 1. Match processor capabilities to application complexity 2. Verify interface compatibility with target peripherals 3. Assess software ecosystem maturity (e.g., ROS support) 4. Evaluate power budget requirements 5. Consider long-term availability and community support
- Growing adoption of RISC-V-based evaluation platforms - Integration of AI/ML accelerators in edge computing boards - Expansion of open-source hardware ecosystems - Increased focus on energy-efficient architectures for IoT - Standardization of form factors (e.g., SparkFun's Qwiic system)