Data Acquisition - Analog Front End (AFE)

Category Introduction

An Analog Front-End (AFE) is a semiconductor device that is used for signal conditioning that is comprised of analog amplifiers, op amps, filters, and integrated circuits. This configurable functional block is used to interface with a variety of sensors. The available resolution ranges are from 8 up to 42 bits, with the number of channels ranging from 1 to 256.

Product List

735 Items

Mfr Part #	Quantity Available	UnitPrice	Series	Packaging	Product Status	Number of Bits	Number of Channels	Power (Watts)	Voltage - Supply, Analog	Voltage - Supply, Digital	Mounting Type	Package / Case	Supplier Device Package
ADS1293CISQE/NOPB IC AFE 3 CHAN 24BIT 28WQFN Texas Instruments	4	$16.43		Tape & Reel (TR)	Active	24	3	-	2.7V ~ 5.5V	1.65V ~ 3.6V	Surface Mount	28-WFQFN Exposed Pad	28-WQFN (5x5)
AFE4490RHAT IC AFE 1 CHAN 22BIT 40VQFN Texas Instruments	8	$20.41		Tape & Reel (TR)	Active	22	1	-	2V ~ 3.6V	2V ~ 3.6V	Surface Mount	40-VFQFN Exposed Pad	40-VQFN (6x6)
AFE4404YZPR IC AFE 1 CHAN 24BIT 15DSBGA Texas Instruments	4	$4.22		Tape & Reel (TR)	Active	24	1	-	2V ~ 3.6V	2V ~ 3.6V	Surface Mount	15-XFBGA, DSBGA	15-DSBGA
AFE4403YZPR IC AFE 1 CHAN 22BIT 36DSBGA Texas Instruments	11	$7.84		Tape & Reel (TR)	Active	22	1	-	2V ~ 3.6V	2V ~ 3.6V	Surface Mount	36-XFBGA, DSBGA	36-DSBGA
OPT3101RHFT IC AFE 3 CHAN 16BIT 28VQFN Texas Instruments	37	$11.55		Tape & Reel (TR)	Active	16	3	-	1.7V ~ 3.6V	1.7V ~ 3.6V	Surface Mount	28-VFQFN Exposed Pad	28-VQFN (5x4)
ADA8282WBCPZ IC AFE 4 CHAN 16BIT 32LFCSP Analog Devices Inc.	4	$8.88	Automotive	Tray	Active	16	4	219 mW	3V ~ 3.6V	1.8V ~ 3.6V	Surface Mount	32-VFQFN Exposed Pad, CSP	32-LFCSP-VQ (5x5)
MCP3901A0-I/SS IC AFE 2 CHAN 24BIT 20SSOP Microchip Technology	311	$2.65		Tube	Active	24	2	-	5V	2.7V ~ 5.5V	Surface Mount	20-SSOP (0.209", 5.30mm Width)	20-SSOP
MCP3901A0-E/ML IC AFE 2 CHAN 24BIT 20QFN Microchip Technology	147	$2.76		Tube	Active	24	2	-	5V	2.7V ~ 5.5V	Surface Mount	20-VFQFN Exposed Pad	20-QFN (4x4)
AFE4404YZPT IC AFE 1 CHAN 24BIT 15DSBGA Texas Instruments	68	$5.14		Tape & Reel (TR)	Active	24	1	-	2V ~ 3.6V	2V ~ 3.6V	Surface Mount	15-XFBGA, DSBGA	15-DSBGA
TC500CPE IC AFE 1 CHAN 16BIT 16DIP Microchip Technology	246	$3.70		Tube	Active	16	1	10 mW	±4.5V ~ 7.5V	±4.5V ~ 7.5V	Through Hole	16-DIP (0.300", 7.62mm)	16-PDIP
TC510COG713 IC AFE 1 CHAN 17BIT 24SOIC Microchip Technology	71	$6.39		Tape & Reel (TR)	Active	17	1	18 mW	5V	5V	Surface Mount	24-SOIC (0.295", 7.50mm Width)	24-SOIC
DS8005-RRX+ IC AFE 2 CHAN 28SOIC Analog Devices Inc./Maxim Integrated	39	$5.93		Tube	Active	-	2	7 kW	-	2.7V ~ 6V	Surface Mount	28-SOIC (0.295", 7.50mm Width)	28-SOIC
TC510COG IC AFE 1 CHAN 17BIT 24SOIC Microchip Technology	32	$6.05		Tube	Active	17	1	18 mW	5V	5V	Surface Mount	24-SOIC (0.295", 7.50mm Width)	24-SOIC
LMP90097MHE/NOPB IC AFE 1 CHAN 24BIT 28TSSOP Texas Instruments	43	$12.97		Tape & Reel (TR)	Active	24	1	-	2.85V ~ 5.5V	2.7V ~ 5.5V	Surface Mount	28-TSSOP (0.173", 4.40mm Width)	28-TSSOP
ADS1194CZXGT IC AFE 4 CHAN 16BIT 64NFBGA Texas Instruments	48	$13.94		Tape & Reel (TR)	Active	16	4	5.7 mW	2.7V ~ 5.25V	1.65V ~ 3.6V	Surface Mount	64-LFBGA	64-NFBGA (8x8)
VSP2582RHN IC AFE 1 CHAN 12BIT 36VQFN Texas Instruments	45	$11.66		Tray	Active	12	1	85 mW	2.7V ~ 3.6V	2.7V ~ 3.6V	Surface Mount	36-VFQFN	36-VQFN (6.2x6.2)
WM8234GEFL/V IC AFE 6 CHAN 16BIT 56QFN Cirrus Logic Inc.	73	$11.61		Tray	Active	16	6	-	2.97V ~ 3.63V	2.97V ~ 3.63V	Surface Mount	56-VFQFN Exposed Pad	56-QFN (7x7)
AFE49I30YZT IC AFE 3 CHAN 24BIT Texas Instruments	19	$16.22		Tape & Reel (TR)	Active	24	4	-	-	-	Surface Mount	30-XFBGA, DSBGA	30-DSBGA
AFE5801IRGCT IC AFE 8 CHAN 12BIT 64VQFN Texas Instruments	14	$68.41		Tape & Reel (TR)	Active	12	8	636 mW	1.8V, 3.3V	-	Surface Mount	64-VFQFN Exposed Pad	64-VQFN (9x9)
MAX5864ETM+ IC AFE 4 CHAN 10BIT 48TQFN Analog Devices Inc./Maxim Integrated	27	$12.08		Tube	Active	10	4	2.1 W	2.7V ~ 3.3V	2.7V ~ 3.3V	Surface Mount	48-WFQFN Exposed Pad	48-TQFN (7x7)

About Analog Front End (AFE)

What are Analog Front End (AFE)?

Analog Front End (AFE)

An Analog Front End (AFE) is a critical component in data acquisition systems, responsible for interfacing with the analog world and converting analog signals into digital data that can be processed by digital systems. AFEs typically include a variety of components such as amplifiers, filters, and analog-to-digital converters (ADCs) that work together to condition, amplify, and digitize incoming analog signals. The primary operating principle involves capturing the analog signal, often from sensors or transducers, amplifying it to a suitable level, filtering out unwanted noise, and then converting it into a digital format for further processing and analysis.

Types of Analog Front End (AFE)

1. General-Purpose AFEs

General-purpose AFEs are versatile and designed to handle a wide range of analog signals. They are typically used in applications where flexibility is key, such as in laboratory settings or multi-sensor systems. These AFEs often include programmable gain amplifiers and configurable filters to adapt to various signal types and conditions.

2. Sensor-Specific AFEs

Sensor-specific AFEs are tailored to work with particular types of sensors, such as temperature, pressure, or optical sensors. These AFEs are optimized for the specific signal characteristics of the sensor, providing enhanced performance and accuracy. They often include integrated features like sensor excitation and compensation circuits.

3. High-Speed AFEs

High-speed AFEs are designed for applications requiring rapid data acquisition, such as in telecommunications or high-frequency signal processing. These AFEs prioritize fast sampling rates and low latency, often incorporating advanced ADCs and high-bandwidth amplifiers to handle fast-changing signals effectively.

4. Low-Power AFEs

Low-power AFEs are essential in battery-operated or energy-sensitive applications, such as portable medical devices or remote sensing equipment. These AFEs are engineered to minimize power consumption while maintaining adequate performance, often using low-power components and efficient design techniques.

How to choose Analog Front End (AFE)?

When selecting an AFE, several key parameters must be considered to ensure optimal performance for the intended application:

Signal Type and Range: Identify the type of analog signal and its range to choose an AFE with appropriate input characteristics.
Sampling Rate: Determine the required sampling rate based on the application's speed and resolution needs.
Power Consumption: Consider power constraints, especially for portable or battery-operated devices.
Noise Performance: Evaluate the AFE's noise specifications to ensure signal integrity and accuracy.
Temperature Range: Ensure the AFE can operate within the environmental conditions of the application.

To assess product quality and reliability, review supplier datasheets, customer reviews, and industry certifications. Environmental factors such as temperature, humidity, and electromagnetic interference should also be considered, along with installation requirements like space constraints and connectivity options.

Applications of Analog Front End (AFE)

1. Medical Devices

In the medical industry, AFEs are used in devices such as ECG machines and blood glucose monitors. They amplify and digitize physiological signals from the human body, ensuring accurate diagnostics and monitoring.

2. Industrial Automation

AFEs play a crucial role in industrial automation by interfacing with various sensors that monitor parameters like temperature, pressure, and flow. They ensure precise data acquisition for process control and optimization.

3. Telecommunications

In telecommunications, AFEs are used in RF transceivers and base stations to process high-frequency signals. They enable efficient signal conversion and conditioning for reliable communication.

4. Automotive Systems

AFEs are integral to automotive systems, including engine control units and advanced driver-assistance systems (ADAS). They process sensor data for vehicle diagnostics and safety features.

5. Consumer Electronics

In consumer electronics, AFEs are found in devices like smartphones and audio equipment. They handle audio and video signal processing, enhancing user experience through improved sound and image quality.