Evaluation Boards

Evaluation Boards - Op Amps

Part Number	Description / PDF	Quantity
OPA858DSGEVM Texas Instruments	DEVELOPMENT AMPLIFIER	15
DIYAMP-SOIC-EVM Texas Instruments	AMPLIFIER CIRCUIT EVAL MOD	18
DC1192A Analog Devices, Inc.	BOARD EVAL LT6105	0
ADM00640 Roving Networks / Microchip Technology	EVALUATION BOARD MCP6N16	11
ADM00443 Roving Networks / Microchip Technology	MCP6421 EMIRR EVALUATION BOARD	0
XR1009IST5EVB MaxLinear	BOARD EVALUATION XR1009IST5	4
THS4022EVM Texas Instruments	EVAL MOD FOR THS4022	5
OPA818DRGEVM Texas Instruments	OP AMP	9
MIKROE-323 MikroElektronika	BOARD MIKROBUFFER	0
TS1001DB Touchstone Semiconductor	BOARD EVAL OPAMP TS1001	1
DC1698A-B Analog Devices, Inc.	LT1999-20 (MS8) DEMOBOARD	2
MAX40661EVKIT# Maxim Integrated	EVAL KIT MAX40661 AMP LIDAR	212
ADA4862-3YR-EBZ Analog Devices, Inc.	BOARD EVAL FOR ADA4862-3YR	16
DIFFAMP-EVM Texas Instruments	DEVELOPMENT AMPLIFIER	9
LME49710NABD Texas Instruments	BOARD EVALUATION LME49710NA	1
DC594A Analog Devices, Inc.	LT1638CDD - DUAL, OVER-THE-TOP,	2
EVAL-FDA-1RMZ-8 Analog Devices, Inc.	SINGLE DIFFERENTIAL AMP EVAL BOA	3
AD8494-EVALZ Analog Devices, Inc.	EVALUATION BOARD	2
INA228EVM Texas Instruments	INA228, INA237 INA238 EVAL	10
DC987B-D Analog Devices, Inc.	LTC6400-26 3GHZ FULLY DIFFERENTI	2

Evaluation Boards - Op Amps

1. Overview

Evaluation boards for operational amplifiers (op-amps) are specialized hardware platforms designed to test and validate the performance of op-amp integrated circuits (ICs) in various circuit configurations. These boards provide a controlled environment for engineers to assess key parameters such as gain stability, noise performance, and power efficiency. In modern electronics development, op-amp evaluation boards are critical for accelerating design cycles, reducing time-to-market, and ensuring compliance with industry standards.

2. Main Types and Functional Classification

Type	Functional Features	Application Examples
General-Purpose Op-Amp Evaluation Boards	Basic configuration support, wide supply voltage range, adjustable gain settings	Consumer electronics prototyping
High-Speed Op-Amp Evaluation Boards	Supports GHz-range signal processing, low parasitic capacitance design	Communication infrastructure testing
Low-Noise Precision Evaluation Boards	Ultra-low input-referred noise, laser-trimmed resistors	Medical imaging equipment development
Power Op-Amp Evaluation Boards	High current output capability, thermal management features	Industrial motor control systems

3. Structure and Components

Typical evaluation boards consist of:

PCB substrate with controlled impedance traces
Socketed op-amp IC for easy replacement
Onboard power management (LDO regulators, voltage references)
Standardized interface connectors (SMB, SMA, or header pins)
Adjustable compensation networks (trim pots, discrete component footprints)
Thermal vias and heatsinking structures
Calibration-grade passive components (0.1% tolerance resistors, NP0 capacitors)

4. Key Technical Specifications

Parameter	Importance
Gain Bandwidth Product (GBWP)	Determines maximum operating frequency
Slew Rate	Impacts transient response performance
Power Supply Rejection Ratio (PSRR)	Measures immunity to supply voltage variations
Input Offset Voltage	Affects DC precision accuracy
Quiescent Current	Key factor in low-power designs
Operating Temperature Range	Determines environmental robustness

5. Application Areas

Major industry applications include:

Industrial automation (sensor signal conditioning)
Telecommunications (RF front-end amplification)
Medical devices (ECG signal amplification)
Automotive (lidar sensor interfaces)
Consumer electronics (audio preamplifiers)
Aerospace (precision measurement systems)

6. Leading Manufacturers and Representative Products

Manufacturer	Product Example	Key Features
Texas Instruments	OPA847EVM	3.6GHz GBWP, voltage feedback architecture
Analog Devices	AD8021-EB	24-bit audio precision, low distortion
STMicroelectronics	STEVAL-OPA354	Low-voltage operation, rail-to-rail output
NXP Semiconductors	LM7171EVM	High-speed buffer applications

7. Selection Guidelines

Key considerations for selection:

Match board specifications to target application requirements
Verify compatibility with existing development tools (oscilloscopes, signal generators)
Evaluate available onboard calibration features
Assess documentation quality and reference designs
Consider ecosystem support (accessory boards, software tools)
Check component availability and lifecycle status

8. Industry Trends Analysis

Current trends shaping op-amp evaluation board development:

Integration of digital control interfaces (I2C, SPI)
Increased focus on energy-efficient designs for IoT applications
Development of modular evaluation systems with plug-and-play capability
Adoption of machine learning algorithms for automated performance optimization
Miniaturization for portable test equipment applications
Enhanced EMI/RFI shielding for automotive test environments