The Ultimate Guide to LM324 vs LM358 Op Amp ICs

In certain instances, manufacturers produce specific ICs in diverse packages, varying in the number of integrated units. While these packages may share a visual resemblance, distinct op-amps within the same IC can exhibit slight variations in their characteristics. The addition of more amplifiers onto the same IC can lead to subtle alterations in performance. Two commonly used op-amp ICs, the LM324 and LM358, have been the go-to choice for engineers and hobbyists alike. However, understanding their differences and applications can be crucial for successful circuit design. In this article, we will compare the LM324 and LM358 op-amps, exploring their features, differences, and common applications.

Overview of LM324 and LM358 Op-amp ICs

LM324 Description

The LM324 is a quad op-amp integrated circuit featuring four individual op-amps, all operating from a shared power supply. The allowable range for the differential input voltage is equivalent to the power supply voltage. It boasts an impressively low default input offset voltage, typically around 2mV in magnitude. Operating temperatures span from 0˚C to 70˚C under ambient conditions, and the maximum junction temperature can reach as high as 150˚C. Typically, op-amps are capable of executing various mathematical operations.

LM358 Description

The LM358 is essentially half of an LM324, and it offers various advantages over typical operational amplifiers, particularly in single supply scenarios. It functions effectively within a wide voltage range, spanning from 3.0 V to 32 V, with quiescent currents that are only about one-fifth of those found in the MC1741 (per amplifier). Moreover, its common-mode input range extends to the negative supply, eliminating the need for external biasing components in numerous applications. Additionally, the output voltage range covers the negative power supply voltage.

Specifications Comparison

Specification	LM324	LM358
Supply voltage	32V	32V
Power dissipation	1130mW (DIP)	830mW (DIP)
Input offset voltage	5mV	5mV
Input offset voltage drift	30µV/C (max.)	20µV/C (max.)

Features Comparison

LM324 Features

• Internally Frequency Compensated for Unity Gain

• High DC Voltage Gain of 100 dB

• Wide Bandwidth at Unity Gain (1 MHz) with Temperature Compensation

• Versatile Power Supply Range:

       -Single Supply: 3 V to 32 V

       -Dual Supplies: ±1.5 V to ±16 V

• Exceptionally Low Supply Current Drain (700 μA) - Virtually Independent of Supply Voltage

• Low Input Biasing Current: 45 nA (Temperature Compensated)

• Low Input Offset Voltage: 2 mV

• Low Offset Current: 5 nA

• Input Common-Mode Voltage Range Includes Ground

• Differential Input Voltage Range Equals the Power Supply Voltage

• Large Output Voltage Swing: From 0 V to V − 1.5 V

LM358 Features

• Outputs Protected Against Short Circuits

• Incorporates a True Differential Input Stage

• Operates on a Single Supply: 3.0 V to 32 V

• Exhibits Low Input Bias Currents

• Internal Compensation for Enhanced Performance

• Common Mode Range Extends to Negative Supply

• Compatible with Both Single and Split Supply Operation

• Equipped with ESD Clamps on Inputs for Enhanced Device Durability without Impacting Performance

• The "NCV" Prefix Indicates Suitability for Automotive and Other Applications with Unique Site and Control Change Requirements; AEC-Q100 Qualified and PPAP Capable

• These devices are Environmentally Friendly: Pb-Free, Halogen-Free/BFR-Free, and RoHS Compliant

Inside Circuitry Comparison

Analyzing the internal circuit diagram reveals that both components share an identical schematic for all amplifiers. Therefore, the potential for discrepancies lies in minor variations during semiconductor fabrication and packaging.

Absolute Maximum Ratings Comparison

LM324 Absolute Maximum Ratings

LM358 Absolute Maximum Ratings

Electrical Characteristics Comparison

LM324 Electrical Characteristics

LM358 Electrical Characteristics

Applications Comparison

LM324 Applications

• Transducer Amplifiers

• Filter Circuits

• Voltage Followers

• Integrators

• Differentiators

• Summer Circuits

• Adder Circuits

• DC Gain Blocks

• Comparators for Loop Control and Regulation

LM358 Applications

• Transducer Amplifiers

• Traditional Operational Amplifier Circuits

• Integrators, Differentiators, Summing Amplifiers, Voltage Followers, etc.

• DC Gain Blocks, Digital Multimeters, Oscilloscopes

• Comparators for Loop Control and Regulation

• Active Filters

• General Signal Conditioning and Amplification

• 4- to 20-mA Current Loop Transmitters

Datasheet PDF

LM324 Datasheet PDF

LM358 Datasheet PDF

Conclusion

Both the LM324 and LM358 operational amplifiers have their own unique features and are well-suited for various electronic applications. The choice between them depends on the specific requirements of your circuit. Understanding their differences is essential for successful circuit design.

Read More

• Top 10 Op-Amp ICs: Your Ultimate Selection Guide

• LM358N Operational Amplifier: Pinout, Datasheet, Circuit, and Uses

• Op-Amp LM358P: Pinout, Circuits, and Datasheet

• OP07 Operational Amplifier IC: Pinout, Datasheet & Its Application

• LM358 Dual Op-Amp vs LM393 Dual Comparator

• LM324 Quad OP-AMP IC Pinout, Circuit, Datasheet, and Uses

• LM741 Op-AMP IC Pinout, Circuit, Datasheet, and Uses

Vorherige: CD4017BE CMOS Counter: Circuit, Pinout and Datasheet

Nächste: The Ultimate Guide to Pull-up and Pull-down Resistor