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HomeProductsIntegrated Circuits (ICs)Linear - Amplifiers - Instrumentation, OP Amps, Buffer AmpsTLV2460AIDR
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TLV2460AIDR - Texas Instruments

Manufacturer Part Number
TLV2460AIDR
Manufacturer
Texas Instruments
Allelco Part Number
32D-TLV2460AIDR
Warranty
1 Year Allelco Warranty - Find out more
Stock Status:
26,404 pcs available, New & Original
Parts Description
IC OPAMP GP 1 CIRCUIT 8SOIC
Package
8-SOIC
Data sheet
TLV2460AIDR.pdf
RoHs Status
ROHS3 Compliant
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Specifications

TLV2460AIDR Tech Specifications
Texas Instruments - TLV2460AIDR technical specifications, attributes, parameters and parts with similar specifications to Texas Instruments - TLV2460AIDR

Product Attribute Attribute Value
Manufacturer Texas Instruments
Voltage - Supply Span (Min) 2.7 V
Voltage - Supply Span (Max) 6 V
Voltage - Input Offset 500 µV
Supplier Device Package 8-SOIC
Slew Rate 1.6V/µs
Series -
Package / Case 8-SOIC (0.154", 3.90mm Width)
Package Tape & Reel (TR)
Output Type Rail-to-Rail
Product Attribute Attribute Value
Operating Temperature -40°C ~ 125°C
Number of Circuits 1
Mounting Type Surface Mount
Gain Bandwidth Product 6.4 MHz
Current - Supply 550µA
Current - Output / Channel 80 mA
Current - Input Bias 1.3 nA
Base Product Number TLV2460
Amplifier Type General Purpose

Environmental & Export Classifications

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

Parts Introduction

TLV2460AIDR Image
TLV2460AIDR (1)

Manufacturer Part Number

TLV2460AIDR

Manufacturer

Texas Instruments

Introduction

The TLV2460AIDR is a high-performance, low-power operational amplifier (op-amp) designed for a wide range of instrumentation and general-purpose applications.

Product Features and Performance

Rail-to-rail input and output range

Low power consumption (550 μA supply current)

Wide supply voltage range (2.7 V to 6 V)

High gain bandwidth (6.4 MHz)

Low input offset voltage (500 μV)

Low input bias current (1.3 nA)

Fast slew rate (1.6 V/μs)

High output drive capability (80 mA)

Operates over a wide temperature range (-40°C to 125°C)

Product Advantages

Excellent performance in a small package

Versatile for a wide range of applications

Low power consumption for battery-powered devices

Reliable operation across a wide temperature range

Key Technical Parameters

Supply Voltage Range: 2.7 V to 6 V

Supply Current: 550 μA

Gain Bandwidth Product: 6.4 MHz

Input Offset Voltage: 500 μV

Input Bias Current: 1.3 nA

Slew Rate: 1.6 V/μs

Output Current: 80 mA

Quality and Safety Features

RoHS3 compliant

Meets stringent quality and reliability standards

Compatibility

Surface mount package (8-SOIC)

Compatible with a wide range of electronic systems and circuits

Application Areas

Instrumentation and measurement equipment

Data acquisition systems

Medical devices

Industrial control systems

Consumer electronics

Product Lifecycle

The TLV2460AIDR is an active product and is not nearing discontinuation.

Replacement or upgraded options may be available from Texas Instruments.

Several Key Reasons to Choose This Product

Excellent performance characteristics, including high gain bandwidth, low input offset voltage, and fast slew rate

Low power consumption and wide supply voltage range make it suitable for battery-powered applications

Versatile and compatible with a wide range of electronic systems and circuits

Reliable operation across a wide temperature range (-40°C to 125°C)

RoHS3 compliant, ensuring compliance with environmental regulations

Frequently Asked Questions(FAQ)

How does the TLV2460AIDR compare to other general-purpose op-amps in terms of power consumption and input offset voltage when used in battery-powered sensor conditioning circuits?
The TLV2460AIDR draws 550 µA of supply current, which is relatively low for a precision rail-to-rail output amplifier, making it suitable for energy-constrained applications. Its input offset voltage is specified at 500 µV maximum over temperature, enabling accurate signal amplification in low-level sensor interfaces. When compared to similar-class amplifiers like the MCP6001 or LPV511, the TLV2460AIDR offers better performance in terms of slew rate (1.6 V/µs) and bandwidth (6.4 MHz), though it consumes slightly more quiescent current than ultra-low-power alternatives such as the TLV9061 series. This trade-off may favor the TLV2460AIDR in designs requiring both moderate speed and reasonable accuracy without extreme power constraints.
What are the thermal implications of operating the TLV2460AIDR near its maximum junction temperature, and how should PCB layout affect this behavior in compact industrial control systems?
With an operating temperature range of -40°C to +125°C and a standard 8-SOIC package having a typical thermal resistance (θJA) of around 120°C/W, the TLV2460AIDR can experience significant self-heating under high ambient conditions or continuous output loading. For example, driving 80 mA into a load while dissipating 20 mW internally could raise the die temperature by approximately 2.4°C above ambient—still within spec—but cumulative effects from nearby components or poor copper routing may push the junction beyond safe limits. Proper thermal relief, adequate ground plane exposure, and spacing from heat sources help maintain reliability in space-constrained designs.
Can the TLV2460AIDR reliably drive capacitive loads greater than 10 nF without oscillation, and what compensation techniques apply when used in feedback networks with long traces?
The TLV2460AIDR has limited capacitive load drive capability due to its internal output stage design; driving loads significantly above 10 nF may result in instability or ringing, especially in unity-gain configurations. In such cases, adding a small series resistor (typically 10–100 Ω) at the output helps isolate the capacitor and improve phase margin. This technique is particularly relevant when using the TLV2460AIDR in sensor front-end buffers where cable capacitance or external filtering adds parasitic load. Simulation and bench testing are recommended before finalizing the layout.
Is the gain bandwidth product sufficient for amplifying 1 kHz signals with closed-loop gains up to 100 in a data acquisition system?
Yes, the TLV2460AIDR’s gain bandwidth product of 6.4 MHz allows stable operation at closed-loop gains of 100 for signals well below 64 kHz (since GBW / Gain = Bandwidth). At 1 kHz and a gain of 100, the bandwidth requirement is only 6.4 kHz, which is comfortably within the amplifier’s capabilities. Therefore, the TLV2460AIDR can handle this application without sacrificing phase margin or introducing excessive noise gain peaking, assuming proper layout and feedback network design.
How does input bias current affect DC error in high-impedance transducer interfaces when using the TLV2460AIDR?
The TLV2460AIDR has an input bias current of 1.3 nA, which introduces a small but non-negligible DC offset at high source impedances. For example, if interfacing with a 1 MΩ thermistor bridge, the resulting voltage error could be up to 1.3 mV (1.3 nA × 1 MΩ), potentially affecting measurement accuracy in precision applications. While this is acceptable for many industrial sensors, designers should consider adding guard rings, minimizing trace leakage paths, or selecting FET-input op-amps for higher impedance sources. The TLV2460AIDR’s CMOS input structure mitigates flicker noise but doesn’t eliminate bias current limitations entirely.
What precautions should be taken during soldering and storage of the TLV2460AIDR in lead-free reflow processes?
The TLV2460AIDR is RoHS3 compliant and rated for MSL 1, meaning it can withstand unlimited time at room humidity before assembly. However, during lead-free reflow soldering, peak temperatures exceeding 260°C for extended durations may degrade device performance. Standard JEDEC-compliant profiles with peak temperatures below 245°C and ramp rates controlled to avoid thermal shock are recommended. After reflow, devices should be stored in dry environments (<30% RH) if not immediately assembled to prevent moisture reabsorption, despite the MSL 1 classification.
Can the TLV2460AIDR operate from a single 3.3V supply while maintaining rail-to-rail output swing, and what load conditions might limit full swing?
Yes, the TLV2460AIDR supports single-supply operation down to 2.7V and provides true rail-to-rail output swing, meaning it can drive voltages very close to both the positive and negative rails. However, at high output currents (e.g., 80 mA), the output voltage drop increases due to internal resistance, reducing effective swing. For instance, at 550 µA supply current and 80 mA output, even small on-resistance values cause noticeable headroom loss. Thus, while the output reaches near 0V and 3.3V nominally, real-world swing may be reduced under heavy loads, especially at elevated temperatures.
Why might someone choose the TLV2460AIDR over a lower-cost alternative like the LM358 in a precision ADC driver application?
Although the LM358 is cheaper and widely available, it lacks rail-to-rail output, has higher input offset voltage (typically 7 mV), slower slew rate (~0.3 V/µs), and limited bandwidth (typically 1 MHz). In contrast, the TLV2460AIDR delivers 1.6 V/µs slew rate, 6.4 MHz bandwidth, and true rail-to-rail output, ensuring full dynamic range for ADCs powered near ground. Additionally, its 500 µV max offset voltage enables tighter linearity across the input span. These characteristics make the TLV2460AIDR preferable in systems where resolution, speed, and headroom matter more than bill-of-materials cost.
How does the package size impact high-density PCB layouts when integrating multiple TLV2460AIDR amplifiers?
The 8-SOIC package measures 4.9 mm × 3.9 mm, offering a good balance between pin count and board area. This makes the TLV2460AIDR suitable for multi-channel designs where space is at a premium, such as in sensor arrays or modular instrumentation. However, thermal coupling between adjacent ICs can increase local heating, so careful placement and via stitching under the exposed pad (if present) help manage thermal gradients. Despite its compact form, signal integrity considerations—such as minimizing trace length and avoiding crosstalk—remain critical when stacking multiple units.
Are there any known stability issues when using the TLV2460AIDR in inverting amplifier configurations with high feedback resistors?
Stability is generally maintained across common feedback ratios, but extremely large feedback resistor values (>1 MΩ) combined with high source impedances can introduce parasitic capacitances that reduce phase margin. While the TLV2460AIDR includes internal compensation for unity-gain stability, non-unity configurations with large resistances may exhibit peaking or overshoot. To mitigate this, keep feedback resistors below 500 kΩ when possible, use shielded cables for connections, and verify transient response with SPICE simulations before prototyping.
What role does the slew rate play in audio signal path applications using the TLV2460AIDR?
The TLV2460AIDR’s slew rate of 1.6 V/µs translates to a maximum undistorted sine wave amplitude of about 255 V at 100 kHz (since SR = 2πfV). This far exceeds typical audio frequencies (up to 20 kHz), ensuring no slew-induced distortion in audio preamplifier stages. Even for ultrasonic sensing or PWM filtering beyond human hearing, the amplifier maintains linear response. Thus, the TLV2460AIDR is well-suited for analog audio signal conditioning where speed, fidelity, and low noise are prioritized.
Does the TLV2460AIDR require external decoupling capacitors, and what happens if they are omitted?
External decoupling capacitors are strongly recommended—ideally a 0.1 µF ceramic capacitor placed within 5 mm of the V+ and GND pins. Without them, power supply noise coupling into the amplifier can degrade PSRR and increase output ripple. In high-impedance or precision circuits, missing decoupling may also lead to oscillations or unstable operation due to poor local regulation. The TLV2460AIDR itself does not require external compensation, but stable performance depends on clean power delivery.
How does the input common-mode range compare to supply rails when using the TLV2460AIDR in single-supply configurations?
The TLV2460AIDR features rail-to-rail input, meaning the input common-mode voltage range extends from just above the negative supply (ground in single-supply mode) up to nearly the positive rail. For example, on a 3.3V supply, inputs can safely go from 0V to 3.1V. This flexibility allows direct connection to resistive dividers or sensor outputs without level shifting, simplifying circuit topology in space-limited designs such as portable medical devices or IoT edge nodes.
Can the TLV2460AIDR drive inductive loads directly, and what protection measures are advised?
No, the TLV2460AIDR is not designed to drive inductive loads directly. Switching such loads creates back-EMF that can exceed the absolute maximum ratings (typically ±0.3 V beyond supplies), risking latch-up or permanent damage. If inductive switching is necessary, an external flyback diode must be added in parallel with the load. Alternatively, consider using a MOSFET driver stage instead of relying solely on the op-amp’s output transistor, especially in relay or solenoid control circuits employing the TLV2460AIDR.
What substitution options exist if the TLV2460AIDR becomes obsolete, and how do they differ in key parameters?
A direct substitute is the TLV2460CDR, which shares identical electrical characteristics but uses a different tape-and-reel packaging variant. Other potential substitutes include the TLV2470 series (higher bandwidth, similar topology) or OPAx336 (Texas Instruments’ newer generation with improved specs). However, the TLV2460CDR remains the most compatible drop-in replacement for the TLV2460AIDR, matching supply range, pinout, and performance envelope. Always verify package compatibility and test under actual operating conditions before migration.
How does temperature drift of input offset voltage affect calibration requirements in industrial automation using the TLV2460AIDR?
Over the full -40°C to +125°C range, the input offset voltage of the TLV2460AIDR can vary by ±1000 µV or more, depending on initial calibration. This drift introduces gain error in uncalibrated systems, particularly in 4–20 mA current loop transmitters or strain gauge bridges. While the device offers better drift than bipolar types, precision applications may still require trimming or software correction. Designers should account for this variability when specifying tolerance budgets, especially in safety-critical loops where long-term stability outweighs initial accuracy.

Parts with Similar Specifications

The three parts on the right have similar specifications to Texas Instruments TLV2460AIDR

Product Attribute TLV2460AID TLV2460AQDRQ1 TLV2460AQDRG4Q1 TLV2460AQDRG4
Part Number TLV2460AID TLV2460AQDRQ1 TLV2460AQDRG4Q1 TLV2460AQDRG4
Manufacturer Texas Instruments Texas Instruments Texas Instruments Texas Instruments
Output Type - Current - Unbuffered Voltage - Buffered -
Package - Tape & Reel (TR) Tube Tape & Reel (TR)
Current - Input Bias - - - -
Supplier Device Package - 196-NFBGA (12x12) 16-PDIP 64-VQFN (9x9)
Package / Case - 196-LFBGA 16-DIP (0.300', 7.62mm) 64-VFQFN Exposed Pad
Mounting Type - Surface Mount Through Hole Surface Mount
Current - Output / Channel - - - -
Voltage - Input Offset - - - -
Slew Rate - - - -
Voltage - Supply Span (Min) - - - -
Operating Temperature - -40°C ~ 85°C 0°C ~ 70°C -40°C ~ 85°C
Number of Circuits - - - -
Series - - - -
Voltage - Supply Span (Max) - - - -
Current - Supply - - - -
Base Product Number - DAC34H84 MAX500 ADS62P42
Gain Bandwidth Product - - - -
Amplifier Type - - - -

TLV2460AIDR Datasheet PDF

Download TLV2460AIDR pdf datasheets and Texas Instruments documentation for TLV2460AIDR - Texas Instruments.

Datasheets
TLV2460-65, TLV246xA Datasheet.pdf
PCN Design/Specification
Design 25/Feb/2022.pdf Mult Devices Font 21/Apr/2018.pdf

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Customer Reviews

Evaluation: 10 Articles

  • Emil***rperTech
    Jun 23, 2026

    Works exactly as described. I used it as a USB-to-SPI bridge in a small MCU development project and communication was stable from the first setup.

  • Liam***terTech
    Jun 15, 2026

    Used this CPLD in a logic control project. Programming was straightforward and signal timing matched the design requirements.

  • 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.

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TLV2460AIDR Image

TLV2460AIDR

Texas Instruments
32D-TLV2460AIDR

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