Datasheet Texas Instruments ADS8410IRGZT

ManufacturerTexas Instruments
SeriesADS8410
Part NumberADS8410IRGZT
Datasheet Texas Instruments ADS8410IRGZT

16-Bit, Unipolar Pseudo Diff Input, 2MSPS Sampling rate, 4.75V to 5.25V ADC with LVDS Serial Interf 48-VQFN -40 to 85

Datasheets

16-Bit, 2-MSPS, LVDS Serial Interface, SAR ADC. datasheet
PDF, 999 Kb, Revision: A, File published: May 5, 2013
Extract from the document

Prices

Status

Lifecycle StatusActive (Recommended for new designs)
Manufacture's Sample AvailabilityNo

Packaging

Pin48
Package TypeRGZ
Industry STD TermVQFN
JEDEC CodeS-PQFP-N
Package QTY250
CarrierSMALL T&R
Device MarkingADS8410I
Width (mm)7
Length (mm)7
Thickness (mm).9
Pitch (mm).5
Max Height (mm)1
Mechanical DataDownload

Parametrics

# Input Channels1
Analog Voltage AVDD(Max)5.25 V
Analog Voltage AVDD(Min)4.75 V
ArchitectureSAR
Digital Supply(Max)5.25 V
Digital Supply(Min)2.7 V
INL(Max)2.5 +/-LSB
Input Range(Max)4.1 V
Input TypePseudo-Differential,Single-Ended
Integrated FeaturesDaisy-Chainable,Oscillator
InterfaceParallel
Multi-Channel ConfigurationN/A
Operating Temperature Range-40 to 85 C
Package GroupVQFN
Package Size: mm2:W x L48VQFN: 49 mm2: 7 x 7(VQFN) PKG
Power Consumption(Typ)155 mW
RatingCatalog
Reference ModeExt,Int
Resolution16 Bits
SINAD87 dB
SNR87.5 dB
Sample Rate (max)2MSPS SPS
Sample Rate(Max)2 MSPS
THD(Typ)-98 dB

Eco Plan

RoHSCompliant

Application Notes

  • Connecting ADS8410/13 With Long Cable
    PDF, 773 Kb, File published: Dec 2, 2005
    Many applications require that the analog-to-digital converter (ADC) be located near the field sensor; however, the digital processing often occurs at a distance. Therefore, the input and output signals need to travel through a long cable from the field sensor to the site where digital processing occurs. This application report is a guide for using a 1-meter cable, the Samtec EQCD Series high data
  • Using ADS8410/13 in Daisy Chain Mode
    PDF, 3.2 Mb, File published: May 22, 2006
    Many applications require multiple analog-to-digital converters (ADC) in a system. Daisy chaining multiple ADCs enables the use of a single data receiver or a small FPGA. It offers easy and minimal digital routing. This application report describes how multiple ADCs (ADS8410/13) work in a daisy-chain mode. The device offers a high-speed (200 Mbps) LVDS serial interface. This application report als
  • Using ADS8410/13 in Cascade Mode
    PDF, 2.9 Mb, File published: Jun 8, 2006
    Many applications require multiple analog-to-digital converters (ADC) in a system. Cascading multiple ADCs enables the use of a single data receiver or a small FPGA. This offers lower power consumption and independent ADC usage. This application report describes how multiple ADCs (ADS8410/13) work in a cascade mode. The ADS8410/13 integrated circuit offers a high-speed (200 Mbps) LVDS serial inter
  • Using ADS8411 in a Multiplexed Analog Input Application (Rev. A)
    PDF, 2.1 Mb, Revision: A, File published: Feb 15, 2006
    This application report is intended as a guide for using an analog multiplexer to multiplex several input signals to a single high-resolution, high-speed SAR analog-to-digital converter (ADC). The ADC and the multiplexer used were the ADS8411 and the TS5A3159/3359, respectively. This document discusses the important parameters of a multiplexer and defines a few important measurements for evaluatin
  • Determining Minimum Acquisition Times for SAR ADCs, part 1 (Rev. A)
    PDF, 227 Kb, Revision: A, File published: Nov 10, 2010
    This application report analyzes a simple method for calculating minimum acquisition times for successive-approximation register analog-to-digital converters (SAR ADCs). The input structure of the ADC is examined along with the driving circuit. The voltage on the sampling capacitor is then determined for the case when a step function is applied to the input of the driving circuit. Three different
  • Determining Minimum Acquisition Times for SAR ADCs, part 2
    PDF, 215 Kb, File published: Mar 17, 2011
    The input structure circuit of a successive-approximation register analog-to-digital converter (SAR ADC) incombination with the driving circuit forms a transfer function that can be used to determine minimum acquisition times for different types of applied input signals. This application report, which builds on Determining Minimum Acquisition Times for SAR ADCs When a Step Function is Applied to

Model Line

Series: ADS8410 (2)

Manufacturer's Classification

  • Semiconductors > Data Converters > Analog-to-Digital Converters (ADCs) > Precision ADCs (<=10MSPS)