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Data Acquisition - Analog to Digital Converters (ADC)

Image Part Number Description / PDF Quantity Rfq
ADC1210S065HN/C1,5

ADC1210S065HN/C1,5

NXP Semiconductors

IC ADC 12BIT PIPELINED 40HVQFN

0
ADC1210S125HN/C1:5

ADC1210S125HN/C1:5

NXP Semiconductors

IC ADC 12BIT PIPELINED 40HVQFN

0
ADC1207S080HW/C1,5

ADC1207S080HW/C1,5

NXP Semiconductors

IC ADC 12BIT 48HTQFP

0
ADC1610S080HN/C1;5

ADC1610S080HN/C1;5

NXP Semiconductors

IC ADC 16BIT PIPELINED 40HVQFN

0
ADC1003S030TS/C1'1

ADC1003S030TS/C1'1

NXP Semiconductors

IC ADC 10BIT 28SSOP

0
TDA8763M/5/C4,112

TDA8763M/5/C4,112

NXP Semiconductors

IC ADC 10BIT SIGMA-DELTA 28SSOP

0
TDA8763M/5/C4,118

TDA8763M/5/C4,118

NXP Semiconductors

IC ADC 10BIT SIGMA-DELTA 28SSOP

0
ADC1411S125HN/C1:5

ADC1411S125HN/C1:5

NXP Semiconductors

IC ADC 125MHZ 32HVQFN

0
ADC1012D065HN/C1,5

ADC1012D065HN/C1,5

NXP Semiconductors

IC ADC 65MHZ SOT804-3

0
ADC1207S080HW/C1:5

ADC1207S080HW/C1:5

NXP Semiconductors

IC ADC 12BIT 48HTQFP

0
TDA8763M/4/C5,118

TDA8763M/4/C5,118

NXP Semiconductors

IC ADC 10BIT SIGMA-DELTA 28SSOP

0
ADC1012D125HN/C1,5

ADC1012D125HN/C1,5

NXP Semiconductors

IC ADC 125MHZ SOT804-3

0
ADC1207S080HW/C1,1

ADC1207S080HW/C1,1

NXP Semiconductors

IC ADC 12BIT 48HTQFP

0
TDA8763AM/5/C5,118

TDA8763AM/5/C5,118

NXP Semiconductors

IC ADC 10BIT SIGMA-DELTA 28SSOP

0
ADC1012D105HN/C1,5

ADC1012D105HN/C1,5

NXP Semiconductors

IC ADC 105MHZ SOT804-3

0
ADC1004S030TS/C1'1

ADC1004S030TS/C1'1

NXP Semiconductors

IC ADC 10BIT SIGMA-DELTA 28SSOP

0
ADC1003S050TS/C1'1

ADC1003S050TS/C1'1

NXP Semiconductors

IC ADC 10BIT 28SSOP

0
ADC1210S080HN/C1:5

ADC1210S080HN/C1:5

NXP Semiconductors

IC ADC 12BIT PIPELINED 40HVQFN

0
ADC1012D065HN/C1:5

ADC1012D065HN/C1:5

NXP Semiconductors

IC ADC 65MHZ SOT804-3

0
TDA8766G/C1,151

TDA8766G/C1,151

NXP Semiconductors

IC ADC 10BIT SIGMA-DELTA 32LQFP

0

Data Acquisition - Analog to Digital Converters (ADC)

1. Overview

Analog-to-Digital Converters (ADCs) are semiconductor devices that convert continuous analog signals into discrete digital values. This core functionality enables digital systems to process real-world signals such as temperature, pressure, audio, and sensor data. ADCs are fundamental components in modern electronics, serving critical roles in communication systems, medical equipment, industrial automation, and consumer electronics. Their performance directly impacts system accuracy, speed, and overall efficiency.

2. Main Types and Functional Classification

TypeFunctional CharacteristicsApplication Examples
Successive Approximation ADCMedium-speed, high accuracy, moderate power consumptionIndustrial control systems, precision measurement
Integrating ADCHigh noise rejection, low speed, excellent linearityDigital multimeters, weigh scales
Pipeline ADCHigh-speed operation with moderate resolutionWireless communication base stations, video processing
Delta-Sigma ( ) ADCHigh resolution, low noise, oversampling architectureAudio processing, precision sensor interfaces
Flash ADCExtremely high-speed conversion, limited resolutionRadar systems, high-speed oscilloscopes

3. Structure and Components

Typical ADC architecture includes: - Sample-and-Hold Circuit: Captures and stabilizes input signal - Quantizer: Maps analog values to discrete levels - Encoder: Converts quantized values to binary code - Reference Voltage Circuit: Provides stable voltage Modern ADCs integrate additional components like programmable gain amplifiers and digital filters. Fabricated using CMOS or BiCMOS processes, they come in packages like QFP, TSSOP, and BGA with pin counts ranging from 8 to 256.

4. Key Technical Specifications

ParameterDescriptionImportance
ResolutionNumber of digital output bitsDetermines measurement precision
Sampling RateMaximum conversion speed (SPS)Defines signal bandwidth capability
Signal-to-Noise Ratio (SNR)Dynamic range measurementImpacts signal fidelity
Integral Nonlinearity (INL)Deviation from ideal transfer functionCritical for measurement accuracy
Power ConsumptionOperating current/voltage requirementsAffects system efficiency and thermal design

5. Application Fields

  • Telecommunications: 5G base stations, optical transceivers
  • Medical Equipment: MRI scanners, patient monitoring systems
  • Industrial Automation: PLC systems, precision sensors
  • Consumer Electronics: Smartphones, wearables
  • Automotive: LiDAR systems, battery management

6. Leading Manufacturers and Products

ManufacturerRepresentative ProductKey Specifications
TI (Texas Instruments)ADS928324-bit ADC, 2MSPS, 2LSB INL
Analog DevicesAD762116-bit SAR ADC, 3MSPS, 85dB SNR
Maxim IntegratedMAX1190516-bit pipeline ADC, 125MSPS
STMicroelectronicsLTC2389-1818-bit SAR ADC, 1MSPS, rail-to-rail input

7. Selection Guidelines

Key considerations include: - Application Requirements: Match resolution/speed to system needs - Environmental Conditions: Temperature range, vibration resistance - Cost Constraints: Balance performance with budget - Supply Chain: Availability, package compatibility - Support Features: Required interfaces (SPI, I2C), calibration capabilities

8. Industry Trends

Emerging trends include: - Development of 32-bit ADCs for precision applications - Integration with AI acceleration for edge computing - Energy-efficient designs for IoT devices - High-temperature ADCs for automotive applications - Advanced packaging technologies (3D stacking) - Software-defined radio ADCs with tunable bandwidth

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