AD5541A
PRODUCTION2.7 V to 5.5 V, Serial-Input, Voltage-Output, 16-/12-Bit nanoDAC™ in 8-lead 3 mm × 3 mm LFCSP
- Part Models
- 8
- 1ku List Price
- Starting From $6.69
Part Details
- 16-bit resolution
- 11.8 nV/√Hz noise spectral density
- 1 μs settling time
- 1.1 nV-sec glitch energy
- 0.05 ppm/°C temperature drift
- 5 kV HBM ESD classification
- 0.375 mW power consumption at 3 V
- 2.7 V to 5.5 V single-supply operation
- Hardware CS and LDAC functions
- 50 MHz SPI-/QSPI-/MICROWIRE-/DSP-compatible interface
- Power-on reset clears DAC output to zero scale
- Available in 3 mm × 3 mm, 8-/10-lead LFCSP and 10-lead MSOP
The AD5541A is a single, 16-bit, serial input, unbuffered voltage output digital-to-analog converter (DAC) that operate from a single 2.7 V to 5.5 V supply.
The DAC output range extends from 0 V to VREF and is guaranteed monotonic, providing ±1 LSB INL accuracy at 16 bits without adjustment over the full specified temperature range of −40°C to +125°C. The AD5541A is available in a 3 mm × 3 mm, 10-lead LFCSP and 10-lead MSOP. The AD5541A-1 is available in a 3 mm × 3 mm, 8-lead LFCSP.
Offering unbuffered outputs, the AD5541A achieves a 1 μs set-tling time with low power consumption and low offset errors. Providing low noise performance of 11.8 nV/√Hz and low glitch, the AD5541A is suitable for deployment across multiple end systems.
The AD5541A uses a versatile 3-wire interface that is compatible with a 50 MHz SPI, QSPI™, MICROWIRE™, and DSP interface standards.
PRODUCT HIGHLIGHTS
- 16-bit performance without adjustment.
- 2.7 V to 5.5 V single operation.
- Low 11.8 nV/√Hz noise spectral density.
- Low 0.05 ppm/°C temperature drift.
- 3 mm × 3 mm LFCSP and MSOP packaging.
Applications
- Automatic test equipment
- Precision Source-measure Instruments
- Data Acquisition Systems
- Medical Instrumentation
- Aerospace Instrumentation
- Communications Infrastructure equipment
- Industrial Control
Documentation
Data Sheet 1
User Guide 1
Device Drivers 5
Circuit Note 3
Solutions Bulletin & Brochure 1
Analog Dialogue 2
ADI has always placed the highest emphasis on delivering products that meet the maximum levels of quality and reliability. We achieve this by incorporating quality and reliability checks in every scope of product and process design, and in the manufacturing process as well. "Zero defects" for shipped products is always our goal. View our quality and reliability program and certifications for more information.
| Part Model | Pin/Package Drawing | Documentation | CAD Symbols, Footprints, and 3D Models |
|---|---|---|---|
| AD5541AACPZ-REEL7 | 10-Lead LFCSP (3mm x 3mm) | ||
| AD5541AARMZ | 10-Lead MSOP | ||
| AD5541AARMZ-REEL7 | 10-Lead MSOP | ||
| AD5541ABCPZ-1-RL7 | 8-Lead LFCSP (3mm x 3mm w/ EP) | ||
| AD5541ABCPZ-500RL7 | 10-Lead LFCSP (3mm x 3mm) | ||
| AD5541ABCPZ-REEL7 | 10-Lead LFCSP (3mm x 3mm) | ||
| AD5541ABRMZ | 10-Lead MSOP | ||
| AD5541ABRMZ-REEL7 | 10-Lead MSOP |
| Part Models | Product Lifecycle | PCN |
|---|---|---|
|
Aug 6, 2014 - 13_0223 Assembly and Test Transfer of Select 2x3mm and 3x3mm LFCSP Products to STATS ChipPAC China |
||
| AD5541AACPZ-REEL7 | PRODUCTION | |
| AD5541ABCPZ-1-RL7 | PRODUCTION | |
| AD5541ABCPZ-500RL7 | PRODUCTION | |
| AD5541ABCPZ-REEL7 | PRODUCTION | |
|
Oct 30, 2017 - 15_0176 Assembly Transfer of Select 8/10L MSOP Products to Amkor Philippines |
||
| AD5541AARMZ | PRODUCTION | |
| AD5541AARMZ-REEL7 | PRODUCTION | |
| AD5541ABRMZ | PRODUCTION | |
| AD5541ABRMZ-REEL7 | PRODUCTION | |
|
May 15, 2012 - 10_0006 Halogen Free Material Change for mini SOIC Products |
||
| AD5541AARMZ | PRODUCTION | |
| AD5541AARMZ-REEL7 | PRODUCTION | |
| AD5541ABRMZ | PRODUCTION | |
| AD5541ABRMZ-REEL7 | PRODUCTION | |
|
Jul 5, 2018 - 16_0235 Assembly Transfer to ASE Korea and Test Transfer to STATS ChipPAC Singapore of Select LFCSP Parts. |
||
| AD5541ABCPZ-1-RL7 | PRODUCTION | |
This is the most up-to-date revision of the Data Sheet.
Software Resources
Device Drivers 5
FPGA/HDL 3
Evaluation Software 0
Can't find the software or driver you need?
Hardware Ecosystem
| Parts | Product Life Cycle | Description |
|---|---|---|
| High Voltage Op Amps ≥12V 1 | ||
| ADA4077-2 | RECOMMENDED FOR NEW DESIGNS | 4 MHz, 7 nV/√Hz, Low Offset and Drift, High Precision Dual Amplifier |
| Low Input Bias Current Op Amps (≤100 pA) 1 | ||
| AD8628 | PRODUCTION | Zero-Drift, Single-Supply, Rail-to-Rail Input/Output Operational Amplifier |
| Positive Linear Regulators (LDO) 1 | ||
| LT3040 | RECOMMENDED FOR NEW DESIGNS | 20V, 200mA, Ultralow Noise, Ultrahigh PSRR Precision DAC/Reference Buffer |
| Precision Op Amps (Vos ≤1mV & TCVos ≤2uV/C) 3 | ||
| OP196 | PRODUCTION | Micropower, RRIO Single Op Amp |
| AD8655 | PRODUCTION | Low Noise, Precision CMOS Amplifier |
| OP1177 | PRODUCTION | Precision Low Noise, Low Input Bias Current Single Operational Amplifier |
| Series Voltage References 4 | ||
| ADR421 | PRODUCTION | Ultraprecision, Low Noise, 2.500 V XFET® Voltage References |
| ADR4525 | PRODUCTION | Ultra-Low-Noise, High-Accuracy 2.5V Voltage Reference |
| ADR425 | PRODUCTION | Ultraprecision, Low Noise, 5.00 V XFET® Voltage Reference |
| ADR4550 | PRODUCTION | Ultra-Low-Noise, High-Accuracy 5.0V Voltage Reference |
| Standard Digital Isolators 2 | ||
| ADUM1400 | PRODUCTION | Quad-Channel Digital Isolator (4/0 Channel Directionality) |
| ADuM1300 | PRODUCTION | Triple-Channel Digital Isolator |
Tools & Simulations
Precision DAC Error Budget Tool
The Precision DAC Error Budget Tool is a web application that calculates the DC Accuracy of precision DAC signal chains. It shows how the static errors accumulate throughout your signal chain to quickly evaluate the design tradeoffs. Calculations include the DC errors introduced by Voltage References, Operation Amplifiers and Precision DACs.
Open ToolIBIS Model 1
Evaluation Kits
AD5541A Evaluation Board
Resources
Software
Reference Designs
How to Achieve High Precision Voltage Level Setting Using the AD5542A/AD5541A 16-Bit Voltage Output DAC
Part Used
Precision, 16-Bit, Voltage Level Setting with Less than 5 mW Total Power Dissipation
Part Used
16-Bit Single-Supply Buffered Voltage Output Digital-to Analog Conversion with Less Than ±1 LSB Integral and Differential Nonlinearity