MAX4075AOESA+ Equivalent & Substitute Parts

Part Overview

The MAX4075AOESA+ is a general-purpose operational amplifier manufactured by Analog Devices Inc./Maxim Integrated, configured as a dual-channel (2 circuit) rail-to-rail output device in an 8-SOIC surface mount package. This component is classified as obsolete, making equivalent and substitute parts necessary for ongoing design support and production continuity. The part operates across a 2.5V to 5.5V supply range with a 4 MHz gain bandwidth product and 0.1V/µs slew rate, suitable for general-purpose signal conditioning and amplification applications.

Key Parameters

Parameter	Value	Unit
Amplifier Type	General Purpose	—
Number of Circuits	2	—
Output Type	Rail-to-Rail	—
Gain Bandwidth Product	4	MHz
Slew Rate	0.1	V/µs
Voltage - Supply Span (Min)	2.5	V
Voltage - Supply Span (Max)	5.5	V
Operating Temperature Range	-40 to 70	°C
Package / Case	8-SOIC (0.154", 3.90mm Width)	—
Mounting Type	Surface Mount	—
Product Status	Obsolete	—

Substitute Part Grouping Explanation

Substitution of the MAX4075AOESA+ is determined by the following critical parameters:

Primary Compatibility Criteria:

Dual-channel (2 circuit) configuration
8-SOIC surface mount package (0.154", 3.90mm width)
Rail-to-rail output capability
Supply voltage range compatibility (minimum 2.5V, maximum 5.5V)
Operating temperature range support (-40°C minimum)

Secondary Performance Considerations:

Gain bandwidth product (4 MHz baseline)
Slew rate (0.1V/µs baseline)
Input bias current and offset voltage specifications
Output current capability per channel

The substitute parts are grouped into two categories based on amplifier type and performance characteristics:

Category 1: General Purpose Amplifiers (Rail-to-Rail Output)

ISL28213FBZ-T13 (Renesas Electronics)
LMV358LIDT (STMicroelectronics)
LMV358Q1MA/NOPB, LMV358Q1MAX/NOPB, LMV358Q3MA/NOPB, LMV358Q3MAX/NOPB (Texas Instruments LMV® series)
LMV722ID, LMV722IDR (Texas Instruments LMV® series, higher performance)

Category 2: Zero-Drift Amplifiers (Enhanced Precision)

LMP2022MA/NOPB, LMP2022MAX/NOPB (Texas Instruments LMP® series)

All substitute parts maintain the 8-SOIC package format, dual-channel configuration, and surface mount technology. All parts are RoHS3 compliant with MSL 1 (Unlimited) moisture sensitivity rating.

Parameter Comparison

Parameter	MAX4075AOESA+	ISL28213FBZ-T13	LMP2022MA/NOPB	LMP2022MAX/NOPB	LMV358LIDT	LMV358Q1MA/NOPB	LMV358Q1MAX/NOPB	LMV358Q3MA/NOPB	LMV358Q3MAX/NOPB	LMV722ID	LMV722IDR
Manufacturer	Analog Devices/Maxim	Renesas Electronics	Texas Instruments	Texas Instruments	STMicroelectronics	Texas Instruments	Texas Instruments	Texas Instruments	Texas Instruments	Texas Instruments	Texas Instruments
Amplifier Type	General Purpose	General Purpose	Zero-Drift	Zero-Drift	General Purpose	General Purpose	General Purpose	General Purpose	General Purpose	General Purpose	General Purpose
Number of Circuits	2	2	2	2	2	2	2	2	2	2	2
Output Type	Rail-to-Rail	Rail-to-Rail	—	—	Rail-to-Rail	Rail-to-Rail	Rail-to-Rail	Rail-to-Rail	Rail-to-Rail	Rail-to-Rail	Rail-to-Rail
Slew Rate (V/µs)	0.1	1	2.6	2.6	0.7	1	1	1	1	5.25	5.25
Gain Bandwidth Product (MHz)	4	2	5	5	1.3	1	1	1	1	10	10
Current - Input Bias (pA/nA)	0.8 pA	3 pA	25 pA	25 pA	27 nA	15 nA	15 nA	15 nA	15 nA	260 nA	260 nA
Voltage - Input Offset (µV/mV)	200 µV	500 µV	0.4 µV	0.4 µV	1 mV	1.7 mV	1.7 mV	1.7 mV	1.7 mV	80 µV	80 µV
Current - Supply (µA/mA per 2 Channels)	37 µA	90 µA	1.1 mA	1.1 mA	130 µA	210 µA	210 µA	210 µA	210 µA	1.81 mA	1.81 mA
Current - Output / Channel (mA)	22	22	50	50	70	160	160	160	160	52.6	52.6
Voltage - Supply Span (Min)	2.5 V	1.8 V	2.2 V	2.2 V	2.7 V	2.7 V	2.7 V	2.7 V	2.7 V	2.2 V	2.2 V
Voltage - Supply Span (Max)	5.5 V	5.5 V	5.5 V	5.5 V	5.5 V	5.5 V	5.5 V	5.5 V	5.5 V	5.5 V	5.5 V
Operating Temperature (°C)	-40 to 70	-40 to 125	-40 to 125	-40 to 125	-40 to 125	-40 to 125	-40 to 125	-40 to 85	-40 to 85	-40 to 105	-40 to 105
Package / Case	8-SOIC	8-SOIC	8-SOIC	8-SOIC	8-SOIC	8-SOIC	8-SOIC	8-SOIC	8-SOIC	8-SOIC	8-SOIC
Mounting Type	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount
Product Status	Obsolete	Active	Active	Active	Active	Active	Active	Active	Active	Active	Active
Grade	—	—	—	—	—	Automotive	Automotive	Automotive	Automotive	—	—
Qualification	—	—	—	—	—	AEC-Q100	AEC-Q100	AEC-Q100	AEC-Q100	—	—
RoHS Status	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant	ROHS3 Compliant
MSL Rating	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)	1 (Unlimited)

Engineering Selection Recommendations

For Direct Replacement (Lowest Risk):

The ISL28213FBZ-T13 from Renesas Electronics provides the closest functional match to the MAX4075AOESA+. Both are general-purpose dual-channel rail-to-rail amplifiers in 8-SOIC packages with compatible supply voltage ranges (1.8V to 5.5V for ISL28213 encompasses the 2.5V to 5.5V requirement). The ISL28213FBZ-T13 is currently active with 985 pcs in stock and maintains ROHS3 compliance and MSL 1 rating. The slew rate is higher (1V/µs vs. 0.1V/µs), which represents improved performance without functional incompatibility.

For General Purpose Applications with Extended Temperature Range:

The LMV358 series from Texas Instruments (LMV358LIDT, LMV358Q1MA/NOPB, LMV358Q1MAX/NOPB, LMV358Q3MA/NOPB, LMV358Q3MAX/NOPB) offers active product status with high inventory availability (28,000+ pcs for LMV358LIDT). These parts maintain rail-to-rail output and 8-SOIC packaging. The LMV358Q1 and LMV358Q3 variants include automotive-grade qualification (AEC-Q100), suitable for applications requiring automotive compliance. Operating temperature ranges extend to 125°C (Q1 variants) or 85°C (Q3 variants), exceeding the MAX4075AOESA+ specification of 70°C maximum.

For Automotive Applications:

The LMV358Q1MA/NOPB, LMV358Q1MAX/NOPB, LMV358Q3MA/NOPB, and LMV358Q3MAX/NOPB are qualified to AEC-Q100 automotive standards. These parts are suitable for automotive-grade designs requiring component traceability and reliability certification.

For High-Performance Applications:

The LMV722ID and LMV722IDR from Texas Instruments provide significantly higher slew rate (5.25V/µs) and gain bandwidth product (10 MHz), with lower input offset voltage (80 µV). These parts are suitable for applications requiring faster signal conditioning or higher bandwidth performance while maintaining the 8-SOIC package and dual-channel configuration.

For Precision Applications:

The LMP2022MA/NOPB and LMP2022MAX/NOPB zero-drift amplifiers from Texas Instruments offer exceptional input offset voltage (0.4 µV) and input bias current (25 pA), suitable for precision measurement and instrumentation applications. These parts sacrifice some slew rate performance (2.6V/µs) but provide superior DC accuracy characteristics.

All recommended substitutes maintain ROHS3 compliance, MSL 1 moisture sensitivity rating, and EAR99 export classification consistent with the original MAX4075AOESA+.

Frequently Asked Questions (FAQ)

Q1: Can I directly substitute the MAX4075AOESA+ with any of the listed parts?

A: Direct substitution is possible for all listed parts within the constraints of your specific application requirements. All substitute parts share the critical compatibility parameters: dual-channel configuration, 8-SOIC surface mount package, rail-to-rail output capability, and overlapping supply voltage ranges. However, differences in slew rate, gain bandwidth product, input offset voltage, and operating temperature range may affect circuit performance. Evaluate your application's specific performance requirements before selection.

Q2: What is the key difference between general-purpose and zero-drift amplifier substitutes?

A: General-purpose amplifiers (ISL28213FBZ-T13, LMV358 series, LMV722 series) are optimized for standard signal conditioning with moderate DC accuracy requirements. Zero-drift amplifiers (LMP2022 series) employ chopper-stabilization or auto-zeroing techniques to achieve extremely low input offset voltage (0.4 µV vs. 80 µV to 1.7 mV) and are designed for precision measurement applications where DC accuracy is critical. Zero-drift amplifiers typically consume more supply current and have lower slew rates.

Q3: Why do some substitute parts have higher operating temperature ranges than the MAX4075AOESA+?

A: The MAX4075AOESA+ is an obsolete product with a -40°C to 70°C operating range. Modern active substitutes (LMV358, LMV722, LMP2022 series) are designed to industrial or automotive standards with extended temperature ranges (-40°C to 125°C or -40°C to 85°C). Extended temperature range capability does not affect compatibility; it represents improved product robustness and availability for modern applications.

Q4: What does AEC-Q100 qualification mean for automotive applications?

A: AEC-Q100 is an automotive electronics council qualification standard that certifies component reliability under automotive operating conditions, including temperature cycling, vibration, and humidity stress testing. The LMV358Q1 and LMV358Q3 variants carry this qualification, making them suitable for automotive-grade designs. Non-automotive-qualified parts (ISL28213FBZ-T13, LMV722, LMP2022) may still function in automotive applications but lack formal automotive reliability certification.

Q5: How do I choose between LMV358Q1 and LMV358Q3 variants?

A: Both LMV358Q1 and LMV358Q3 are automotive-qualified general-purpose amplifiers with identical electrical specifications. The primary difference is operating temperature range: LMV358Q1 operates -40°C to 125°C, while LMV358Q3 operates -40°C to 85°C. Select LMV358Q1 for applications requiring extended high-temperature operation; select LMV358Q3 for standard automotive temperature ranges. Both are available in Tape & Reel packaging with high inventory levels.

Q6: What packaging options are available for substitute parts?

A: All substitute parts are available in 8-SOIC surface mount packages (0.154", 3.90mm width), matching the MAX4075AOESA+ package format. Packaging variants differ by delivery method: Tube (LMP2022MA/NOPB, LMV722ID), Cut Tape & Digi-Reel (LMV358LIDT, LMV722IDR), or Tape & Reel (ISL28213FBZ-T13, LMV358Q1/Q3 variants, LMP2022MAX/NOPB). Select based on your procurement and assembly requirements.

Q7: Are all substitute parts RoHS3 compliant?

A: Yes. All listed substitute parts are RoHS3 compliant with MSL 1 (Unlimited) moisture sensitivity rating, matching the MAX4075AOESA+ compliance profile. All parts are also REACH unaffected and classified as EAR99 for export purposes.

Q8: Which substitute offers the best inventory availability?

A: The LMV358LIDT from STMicroelectronics has the highest inventory level at 28,000 pcs in stock. The LMV358Q3MA/NOPB from Texas Instruments has 33,695 pcs available. Both are suitable for high-volume production requirements.

Q9: What is the significance of the -3dB bandwidth specification for the MAX4075AOESA+?

A: The -3dB bandwidth of 90 kHz indicates the frequency at which the amplifier's gain drops to 70.7% of its DC gain. This parameter is not provided for most substitute parts in the available data. However, the gain bandwidth product (4 MHz for MAX4075AOESA+) can be used to estimate -3dB bandwidth for comparison purposes. Substitute parts with higher gain bandwidth products (LMV722 at 10 MHz, LMP2022 at 5 MHz) will have proportionally higher -3dB bandwidth capabilities.

Q10: Can I use LMV722 as a substitute if my application requires higher speed performance?

A: Yes. The LMV722ID and LMV722IDR are suitable substitutes for applications requiring higher slew rate (5.25V/µs vs. 0.1V/µs) and gain bandwidth product (10 MHz vs. 4 MHz). These parts maintain the 8-SOIC package, dual-channel configuration, and rail-to-rail output. However, they consume higher supply current (1.81 mA vs. 37 µA) and have higher input bias current (260 nA vs. 0.8 pA), which may affect low-power or high-impedance circuit designs.

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