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DAC161P997CISQX/NOPB
Integrated Circuits (ICs)

FDC2214RGHT

Obsolete
Texas Instruments

4-CH, 28-BIT, CAPACITANCE TO DIGITAL CONVERTER

Deep-Dive with AI

Search across all available documentation for this part.

DocumentsCommon Inductive and Capacitive Sensing Applications (Rev. B)FDC2214 Proximity and Capacitive Touch EVM User’s Guide+18
DAC161P997CISQX/NOPB
Integrated Circuits (ICs)

FDC2214RGHT

Obsolete
Texas Instruments

4-CH, 28-BIT, CAPACITANCE TO DIGITAL CONVERTER

Deep-Dive with AI

DocumentsCommon Inductive and Capacitive Sensing Applications (Rev. B)FDC2214 Proximity and Capacitive Touch EVM User’s Guide+18

Technical Specifications

Parameters and characteristics for this part

SpecificationFDC2214RGHT
Current - Supply2.1 mA
InterfaceI2C
Mounting TypeSurface Mount
Number of Inputs4
Operating Temperature [Max]125 °C
Operating Temperature [Min]-40 °C
Package / Case16-WFQFN Exposed Pad
Proximity DetectionTrue
Resolution28 b
Supplier Device Package16-WQFN (4x4)
Voltage - Supply [Max]3.6 V
Voltage - Supply [Min]-2.7 V

Pricing

Prices provided here are for design reference only. For realtime values and availability, please visit the distributors directly

DistributorPackageQuantity$
Texas InstrumentsSMALL T&R 1$ 6.56
100$ 5.35
250$ 4.20
1000$ 3.56

Description

General part information

FDC2214-Q1 Series

Capacitive sensing is a low-power, high-resolution contactless sensing technique that can be applied to a variety of applications ranging from proximity detection to gesture recognition. The sensor in a capacitive sensing system is any metal or conductor, allowing for highly flexible system design.

The main challenge limiting sensitivity in capacitive sensing applications is noise susceptibility of the sensors. With the FDC2x1x-Q1 resonant sensing architecture, performance can be maintained even in presence of fluorescent light.

The FDC2x1x-Q1 is a multi-channel family of high-resolution, high-speed capacitance-to-digital converters for implementing capacitive sensing solutions. The devices employ an innovative narrow-band based architecture to offer high rejection of noise while providing high resolution at high speed. The devices support a wide excitation frequency range, offering flexibility in system design.

Documents

Technical documentation and resources

Common Inductive and Capacitive Sensing Applications (Rev. B)

Application note

FDC2214 Proximity and Capacitive Touch EVM User’s Guide

EVM User's guide

Capacitive Proximity Sensing Using FDC2x1y (Rev. A)

Application note

FDC2114 and FDC2214 EVM User’s Guide (Rev. A)

EVM User's guide

Power Consumption Analysis for Low Power Capacitive Sensing Applications

Application note

Accurate frost or ice detection based on capacitive sensing

Technical article

How to ensure precision in automated processes

Technical article

Capacitive sensing: which architecture should you choose?

Technical article

Reduce power consumption in your capacitive-sensing applications

Technical article

Ground Shifting in Capacitive Sensing Applications

Application note

Simulate Inductive Sensors Using FEMM (Finite Element Method Magnetics) (Rev. A)

Application note

Capacitive sensing: simple algorithm for proximity sensing

Technical article

Derivative Integration Algorithm for Proximity Sensing

Application note

How to remove the ground-shift phenomenon from your capacitive-sensing application

Technical article

Engineers do better than magicians: HMI touch through a thick glass

Technical article

Design an energy-efficient, lower-acoustic cooker hood with an elegant user interf

Technical article

Quantifying Ice and Frost Buildup Using Capacitive Sensors

Application brief

Comparing capacitive and ultrasonic kick-to-open sensing

Technical article

Capacitive Sensing: Direct vs Remote Liquid Level Sensing Performance Analysis (Rev. A)

Application note

FDC2x1x Multi-Channel, High Resolution Capacitance-to-Digital Converter for Capacitive Sensing Applications datasheet (Rev. B)

Data sheet