LMV358MX/NOPB: Features, Specs & More
In modern low-power electronic designs, engineers increasingly demand operational amplifiers that can operate reliably at low supply voltages while maintaining stable output performance. The TI LMV358MX/NOPB addresses this requirement by offering a dual-channel, low-voltage operational amplifier with rail-to-rail output capability and CMOS output architecture. In this comprehensive article, we'll delve into the intricacies of the LMV358MX/NOPB, uncovering its definition, key features, specifications, applications, and a closer look at its manufacturer.
Catalog
LMV358MX/NOPB's Overview
The LMV358MX/NOPB is a dual low-voltage operational amplifier manufactured by Texas Instruments. It operates from a single power supply ranging from 2.7 V to 5.5 V. It features rail-to-rail output performance for maximum signal swing. It is packaged in an 8-pin SOIC surface-mount format suitable for automated assembly.
Key Features
Let's delve into the standout features that make the LMV358MX/NOPB a standout in the world of electronics:
· The device supports dual independent amplifier channels on a single chip.
· The amplifier operates from a minimum single supply voltage of 2.7V.
· The amplifier supports a maximum single supply voltage of 5.5V.
· The output stage provides rail-to-rail voltage swing.
· The output structure is based on CMOS technology.
· The typical voltage gain reaches 100 dB.
· The typical gain bandwidth product is 1 MHz.
· The typical slew rate is 1 V/µs at 5V operation.
· The typical supply current is limited to 0.44 mA at 5V.
· The operating temperature range spans from -40°C to 125°C.
Specifications
Now, let's take a closer look at the technical specifications that define the capabilities of the LMV358MX/NOPB:
Type | Parameter |
Type | Low Voltage Amplifier |
Manufacturer Type | Low Voltage Amplifier |
Number of Channels per Chip | 2 |
Rail to Rail | Rail to Rail Output |
Output Type | CMOS |
Maximum Input Offset Voltage (mV) | 7@5V |
Minimum Single Supply Voltage (V) | 2.7 |
Maximum Single Supply Voltage (V) | 5.5 |
Maximum Input Offset Current (uA) | 0.05@5V |
Typical Input Bias Current (uA) | 0.015@5V |
Maximum Input Bias Current (uA) | 0.25@5V |
Maximum Supply Current (mA) | 0.44@5V |
Typical Output Current (mA) | 60 |
Power Supply Type | Single |
Typical Slew Rate (V/us) | 1@5V |
Typical Input Noise Voltage Density (nV/rtHz) | 39@5V |
Typical Voltage Gain (dB) | 100 |
Typical Noninverting Input Current Noise Density (pA/rtHz) | 0.21@5V |
Minimum PSRR (dB) | 50 |
Minimum CMRR (dB) | 50 |
Minimum CMRR Range (dB) | 50 to 60 |
Typical Gain Bandwidth Product (MHz) | 1 |
Shut Down Support | No |
Minimum Operating Temperature (°C) | -40 |
Maximum Operating Temperature (°C) | 125 |
Supplier Temperature Grade | Industrial |
Packaging | Tape and Reel |
Mounting | Surface Mount |
Package Height | 1.5(Max) |
Package Width | 3.9 |
Package Length | 4.91 |
PCB changed | 8 |
Standard Package Name | SO |
Supplier Package | SOIC |
Pin Count | 8 |
Lead Shape | Gull-wing |
Applications
The LMV358MX/NOPB is well suited for low-voltage signal conditioning circuits.
· It is commonly used in sensor amplification and signal buffering designs.
· It supports active filter implementations in embedded analog systems.
· It can be applied in battery-powered consumer electronics.
· It is suitable for industrial monitoring and control interfaces.
· It is often used in voltage follower and comparator-adjacent configurations.
LMV358MX/NOPB's Manufacturer
Texas Instruments (TI), established in 1930, is a global leader in semiconductor and technology solutions, known for its pioneering contributions to the electronics industry. Specializing in the design and manufacture of analog and digital circuits, microcontrollers, and processors, TI has played a pivotal role in shaping technological advancements across diverse sectors, including industrial, automotive, consumer electronics, and communication.
Conclusion
The TI LMV358MX/NOPB is a well-balanced dual operational amplifier optimized for low-voltage and low-power electronic designs. Its rail-to-rail output capability, compact SOIC package, and wide operating temperature range make it a reliable choice for industrial and portable applications. For designers seeking cost-effective analog performance without sacrificing efficiency, this device remains a dependable solution in modern circuit architectures.
