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HomeProductsIntegrated Circuits (ICs)Data Acquisition - Digital to Analog Converters (DAC)TLV5616ID
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TLV5616ID - Texas Instruments

Manufacturer Part Number
TLV5616ID
Manufacturer
Texas Instruments
Allelco Part Number
32D-TLV5616ID
Warranty
1 Year Allelco Warranty - Find out more
Stock Status:
4,308 pcs available, New & Original
Parts Description
IC DAC 12BIT V-OUT 8SOIC
Package
8-SOIC
Data sheet
TLV5616ID.pdf

HTML Datasheet

TLV5616C, TLV5616I.pdf
RoHs Status
ROHS3 Compliant
Compare
Our certification
In stock: 4308
  • Unit Price: $3.642
  • Subtotal: $0.00

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Quantity Unit Price Ext. Price
1+ $3.642 $3.64
200+ $1.409 $281.80
500+ $1.36 $680.00
1000+ $1.335 $1,335.00
The above prices does not include taxes and freight rates, which will be calculated on the order pages.

Specifications

TLV5616ID Tech Specifications
Texas Instruments - TLV5616ID technical specifications, attributes, parameters and parts with similar specifications to Texas Instruments - TLV5616ID

Product Attribute Attribute Value
Manufacturer Texas Instruments
Voltage - Supply, Digital 2.7V ~ 3.3V, 5V
Voltage - Supply, Analog 2.7V ~ 3.3V, 5V
Supplier Device Package 8-SOIC
Settling Time 20µs
Series -
Reference Type External
Package / Case 8-SOIC (0.154", 3.90mm Width)
Package Tube
Output Type Voltage - Buffered
Product Attribute Attribute Value
Operating Temperature -40°C ~ 85°C
Number of D/A Converters 1
Number of Bits 12
Mounting Type Surface Mount
INL/DNL (LSB) ±1.9, ±0.5
Differential Output No
Data Interface SPI
Base Product Number TLV5616
Architecture String DAC

Environmental & Export Classifications

ATTRIBUTE DESCRIPTION
RoHs Status ROHS3 Compliant
Moisture Sensitivity Level (MSL) 1 (Unlimited)
REACH Status REACH Unaffected
ECCN EAR99
HTSUS 8542.39.0001

Parts Introduction

TLV5616ID Image
TLV5616ID (1)

Manufacturer Part Number

TLV5616ID

Manufacturer

Texas Instruments

Introduction

The TLV5616ID is a 12-bit digital-to-analog converter designed for easy interface to microcontrollers via its SPI interface.

Product Features and Performance

12-bit resolution

Single D/A converter channel

20μs settling time for accurate and fast data conversion

Buffered voltage output enabling direct connection to load

Serial Peripheral Interface (SPI) for digital communication

External reference voltage for flexible scaling of the output

Compatible with both 2.7V ~ 3.3V and 5V power supplies

String DAC architecture to ensure high-resolution output

Operational temperature range from -40°C to +85°C for robust performance

Product Advantages

High precision with INL/DNL of ±1.9 LSB and ±0.5 LSB, respectively

Low power consumption suitable for battery-powered devices

Small 8-SOIC package for space-saving installations

Simple digital control simplifies integration

Key Technical Parameters

Number of Bits: 12

Number of D/A Converters: 1

Settling Time: 20μs

Output Type: Voltage - Buffered

Data Interface: SPI

Reference Type: External

Voltage - Supply, Analog: 2.7V ~ 3.3V, 5V

Voltage - Supply, Digital: 2.7V ~ 3.3V, 5V

INL/DNL (LSB): ±1.9, ±0.5

Architecture: String DAC

Operating Temperature: -40°C ~ 85°C

Package / Case: 8-SOIC

Mounting Type: Surface Mount

Quality and Safety Features

Robust design to ensure reliability over a wide temperature range

Compliance with industry standards for safety and quality

Compatibility

Supports a wide range of microcontrollers with SPI interface

Versatile power supply compatibility (2.7-5V) for use with various logic levels

Application Areas

Precision signal processing

Data acquisition systems

Industrial control systems

Communication systems

Portable and battery-powered equipment

Product Lifecycle

The product status is Active

Long-term availability with no immediate discontinuation

Several Key Reasons to Choose This Product

Highly accurate conversion enhances system performance

Energy efficiency suitable for portable applications

Ease of use with standard communication protocol

Flexible for multiple power system designs

Strong support and reliability from Texas Instruments

Compact size for space-constrained applications

Frequently Asked Questions(FAQ)

How does the TLV5616ID’s INL and DNL performance compare to other 12-bit voltage-output DACs when used in precision analog signal conditioning applications?
The TLV5616ID exhibits an integral nonlinearity (INL) of ±1.9 LSB and a differential nonlinearity (DNL) of ±0.5 LSB, which indicates relatively low deviation from ideal transfer characteristics. In comparison to other 12-bit string DACs operating in similar supply ranges, this level of INL suggests moderate precision suitable for many industrial control and instrumentation scenarios where absolute linearity is critical but not ultra-high. However, systems requiring sub-1 LSB INL may need calibration or alternative architectures such as R-2R ladder DACs.
What design considerations should be taken into account when interfacing the TLV5616ID with a microcontroller via SPI, especially regarding timing and noise immunity?
The TLV5616ID supports standard SPI communication with a maximum clock frequency typically limited by its internal settling time of 20 µs, implying data rates above ~50 kHz may introduce latency between updates. To ensure reliable operation, pull-up resistors on unused MISO lines and proper decoupling capacitors near the VDD pins are recommended. Additionally, layout practices such as short trace lengths between the DAC and controller and ground plane integrity help maintain signal integrity, particularly in noisy environments.
Can the TLV5616ID operate reliably across the full industrial temperature range (-40°C to 85°C), and what impact does temperature have on its output accuracy?
Yes, the TLV5616ID is specified for operation from -40°C to 85°C, making it suitable for harsh environments typical in automotive or factory automation systems. Within this range, the combined effects of reference voltage drift and internal component variation can affect output stability. For applications demanding tight gain accuracy over temperature, external trimming or using a more stable external reference becomes advisable.
How does the choice of external voltage reference affect the overall resolution and dynamic performance of the TLV5616ID in a battery-powered monitoring system?
Since the TLV5616ID uses an external reference, the output voltage swing directly scales with the reference voltage applied to the REF pin. Using a low-noise, low-drift reference like the REF5025 with 2.5V provides a full-scale output of 2.5V, yielding 0.61 mV per LSB—a reasonable balance between resolution and power consumption. Poor-quality references with high temperature coefficient or excessive noise will degrade effective resolution and introduce jitter, undermining system-level accuracy.
What are the trade-offs between using the TLV5616ID in single-supply versus dual-supply configurations, and how does this influence output swing and headroom?
The TLV5616ID accepts analog supplies from 2.7V to 3.3V or up to 5V, allowing flexibility depending on system power architecture. In single-supply mode at 3.3V, the maximum output is limited by the analog supply minus dropout; at 5V, more headroom exists for rail-to-rail driving of downstream stages. However, if the load requires bidirectional signals, a dual-supply configuration enables symmetric output around ground, which is not possible with unipolar operation.
Is the TLV5616ID suitable for driving piezoelectric actuators that require fast settling and minimal overshoot, and why or why not?
While the TLV5616ID has a settling time of 20 µs, which is acceptable for many actuator control loops, its buffered output stage lacks current drive capability necessary for direct piezoelectric load excitation. Driving such loads typically demands higher output current and faster slew rates, suggesting the use of an external op-amp buffer or dedicated driver IC rather than relying solely on the TLV5616ID’s limited sourcing ability.
How does the TLV5616ID’s architecture as a string DAC influence glitch energy compared to other topologies like delta-sigma or R-2R?
As a string DAC, the TLV5616ID generates transient currents during code transitions that result in higher glitch energy compared to R-2R or delta-sigma DACs. In switched-capacitor-based string DACs, simultaneous switching of multiple resistor strings creates brief spikes at the output during updates. This can couple into sensitive analog circuits unless careful filtering or dithering techniques are employed, especially in audio or RF applications.
When selecting between the TLV5616ID and a higher-speed 12-bit DAC for motor control applications, what factors beyond sampling rate become critical?
Beyond raw speed, key considerations include update rate consistency, power consumption, interface complexity, and output stability under varying loads. The TLV5616ID’s SPI interface and moderate settling time may suffice for lower-speed stepper motors, whereas brushless DC motors with rapid torque demands might require faster settling and lower latency, favoring devices with parallel interfaces or integrated PWM/DAC combos.
How does Moisture Sensitivity Level (MSL) = 1 affect handling and storage of the TLV5616ID in mass production environments?
With an MSL rating of 1, the TLV5616ID is considered non-hygroscopic and can be stored indefinitely without baking prior to reflow, simplifying inventory management. This also reduces risk during wave soldering or rework operations, making it ideal for high-volume manufacturing where thermal cycling and moisture exposure must be minimized.
What precautions should be taken when cascading multiple TLV5616ID devices on a shared SPI bus to reduce pin count in compact designs?
To cascade multiple TLV5616IDs on one SPI bus, each device must have a dedicated chip-select line controlled independently by the microcontroller. Without proper isolation, contention on the DOUT pin during reads could corrupt communication. Additionally, propagation delays across devices may accumulate, so total bus length and clock stretching should be evaluated to maintain timing margins within specification.
How does the RoHS3 compliance of the TLV5616ID align with global regulatory requirements in consumer and industrial electronics markets?
RoHS3 compliance ensures the TLV5616ID meets updated restrictions on hazardous substances including lead, mercury, and cadmium, as well as new requirements for PFAS and phthalates. This facilitates market access across Europe, North America, and Asia without additional material declarations or reformulation efforts, supporting sustainable design practices and reducing supply chain audit overhead.
In what scenarios would the TLV5616ID’s lack of integrated digital filtering necessitate external signal processing, and how does this affect system cost?
Because the TLV5616ID provides only basic digital-to-analog conversion without built-in filtering, applications involving stepped outputs—such as setpoint ramping in PID controllers—may exhibit visible stair-step artifacts. Adding an RC filter or active low-pass amplifier increases bill-of-materials cost but improves perceptual smoothness and reduces electromagnetic interference susceptibility.
How does the package size and pinout of the 8-SOIC variant impact PCB routing density in space-constrained embedded systems?
The 8-pin SOIC package measures 3.9 mm width, enabling compact layouts on double-sided PCBs. Its pinout places VDD, VSS, and REF close together, facilitating local decoupling and minimizing loop inductance. However, routing the thin traces for SPI signals adjacent to analog paths requires attention to crosstalk mitigation, especially when placed near high-speed digital buses.
What role does the external reference play in determining the long-term stability and recalibration needs of systems using the TLV5616ID?
The external reference sets the fundamental scale of the TLV5616ID’s output. Over years, even high-stability references drift due to aging and temperature cycling. In precision measurement systems, periodic recalibration against a known standard may be required unless a hermetically sealed or laser-trimmed reference with <1 ppm/°C drift is selected, significantly increasing initial BOM cost.
How does the absence of a built-in power-on reset circuit in the TLV5616ID affect system startup behavior in safety-critical applications?
The TLV5616ID does not include internal POR circuitry, meaning its output state upon power-up is undefined until software initializes the SPI interface. In safety-relevant systems, this necessitates external supervisory ICs or firmware checks to ensure the DAC starts in a known safe state, adding complexity and potential failure points if not properly managed.
Can the TLV5616ID be used effectively in audio synthesis applications, and what limitations arise from its architecture and settling characteristics?
The TLV5616ID’s 20 µs settling time and string DAC structure make it unsuitable for real-time audio synthesis requiring low-latency, smooth waveforms. Audio DACs typically use delta-sigma or R-2R topologies for superior glitch performance and higher output bandwidth. The TLV5616ID may serve only in very low-fidelity, non-real-time tone generation where audible artifacts are negligible.

Parts with Similar Specifications

The three parts on the right have similar specifications to Texas Instruments TLV5616ID

Product Attribute TLV5616IDR TLV5616IDGK TLV5616IDGKG4 TLV5616IDG4
Part Number TLV5616IDR TLV5616IDGK TLV5616IDGKG4 TLV5616IDG4
Manufacturer Texas Instruments Texas Instruments Luminary Micro / Texas Instruments Luminary Micro / Texas Instruments
Series - - - -
Settling Time - 10ns (Typ) 4.5µs -
INL/DNL (LSB) - ±4, ±2 ±1 (Max), ±1 (Max) -
Package / Case - 196-LFBGA 16-DIP (0.300', 7.62mm) 64-VFQFN Exposed Pad
Architecture - Current Source R-2R Pipelined
Supplier Device Package - 196-NFBGA (12x12) 16-PDIP 64-VQFN (9x9)
Reference Type - External, Internal External External, Internal
Data Interface - LVDS - Parallel I²C LVDS - Parallel, Parallel
Package - Tape & Reel (TR) Tube Tape & Reel (TR)
Differential Output - Yes No -
Number of D/A Converters - 4 4 -
Voltage - Supply, Digital - 1.14V ~ 1.26V 11.4V ~ 16.5V 1.65V ~ 3.6V
Number of Bits - 16 8 14
Voltage - Supply, Analog - 3.14V ~ 3.46V 11.4V ~ 16.5V 3V ~ 3.6V
Operating Temperature - -40°C ~ 85°C 0°C ~ 70°C -40°C ~ 85°C
Mounting Type - Surface Mount Through Hole Surface Mount
Base Product Number - DAC34H84 MAX500 ADS62P42
Output Type - Current - Unbuffered Voltage - Buffered -

TLV5616ID Datasheet PDF

Download TLV5616ID pdf datasheets and Texas Instruments documentation for TLV5616ID - Texas Instruments.

HTML Datasheet
TLV5616C, TLV5616I.pdf

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Customer Reviews

Evaluation: 10 Articles

  • Nath***rooks
    Jun 11, 2026

    Installed this power component in a converter board. Output remained stable under different load conditions and thermal performance was better than expected.

  • Dani***alkerTech
    Jun 1, 2026

    Product works, but setup took more effort than expected. Once configured the MCU ran reliably, although documentation support felt older compared with newer platforms. Fine for maintenance projects.

  • Yuki***aka88
    May 26, 2026

    信号通信プロジェクトでこのRS-485トランシーバーを使用しました。設置は簡単で、長距離ケーブルでも通信は安定していました。消費電力も、以前使用していたものより低くなっています。

  • Stev***aker
    May 20, 2026

    Solid diode for power rectification. Works well in switching circuits.

  • Bran***Lewis
    May 11, 2026

    Compact FPGA with good performance. Suitable for basic signal processing tasks.

  • Oliv***arris
    May 7, 2026

    Reliable I/O expander. Works well in embedded control applications.

  • Jess***Jones
    Apr 17, 2026

    It offers good value for the price, and the specifications match the description. I’ve been using it for two days with no issues, and I’ll definitely buy it again if I need it in the future.

  • Mich***Smith
    Apr 17, 2026

    Shipping was on time, the component pins are neatly aligned, and I tested 10 of them with a multimeter—all readings were within the specified range. Highly recommended.

  • Aman***arris
    Apr 3, 2026

    It was great—the entire process, from placing the order to receiving the package, went very smoothly. The components were consistent, the price was fair, and I had a very pleasant shopping experience.

  • Mike***nch
    Apr 3, 2026

    Better than expected! The resistance and capacitance readings were spot-on, and it passed the test on the first try. The service was reliable, and the packaging was thoughtful—I highly recommend it.

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TLV5616ID Image

TLV5616ID

Texas Instruments
32D-TLV5616ID

Want a better price? Add to Cart and Submit RFQ now, we'll contact you immediately.

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