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New Zero-Drift Op-Amp Achieves High Accuracy Regardless of Temperature Changes

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Operational Amplifiers (Op-Amps) are fundamental components in both industrial and consumer electronics with uses ranging from simple tasks, like basic amplification and buffering, to complex functions such as analog-to-digital conversion, audio processing, and sensor signal amplification. Despite their ubiquity, however, a persistent issue with Op-Amps is thermal drift — a phenomenon where the amplifier’s input offset voltage varies over time and with temperature fluctuation.

This drift is particularly problematic in sensitive applications where even minor deviations could result in errors or degraded performance. This article will explore the benefits of zero-drift Op-Amps for maintaining accuracy and stable performance regardless of temperature fluctuations. It will also discuss the underlying technology and advantages of ROHM’s Zero-drift Op-Amp over standard devices and potential applications in various electronic systems.

The Evolution of Op-Amps in Environmental Sensing

Environmental sensors, such as temperature, pressure, and gas detectors, produce very small electrical signals in response to changes in environmental conditions, which are too weak to be processed directly by microcontrollers. Op-Amps can be used to amplify these signals up to a manageable level while preserving the integrity of the information captured by the sensor. In automotive applications, for instance, Op-Amps can amplify signals from temperature sensors for accurate climate control. Meanwhile, in industrial settings like chemical plants, these Op-Amps boost signals from gas sensors to monitor and control pollutant levels.

Over time, Op-Amp technology has evolved with several developments aimed at enhancing the sensitivity and performance of these components. The following are some of the latest features:

  • Low-Offset and Low-Noise Solutions: Op-Amps now offer significantly reduced input offset voltage and output noise, which are ideal in environmental sensing where high accuracy measurements are crucial. Low-offset design minimizes the input offset voltage due to component mismatches inside the op-amp; low-noise design keeps noises generated by op-amps from degrading the signal.
  • Higher Bandwidth and Faster Response Times: As environmental conditions tend to fluctuate rapidly, manufacturers are focused on creating Op-Amps with higher bandwidth and fast response times These characteristics ensure that the amplifiers keep up with rapid changes in the sensor output, providing real-time, accurate readings.
  • IoT/Edge Integration: In IoT/Edge systems and smart applications, Op-Amps are being designed to integrate with digital controllers and processors, which includes features like built-in analog-to-digital converters and communication interfaces.
  • Environmental Robustness: Op-Amps integrated into industrial or automotive systems are engineered to withstand high temperatures, humidity, and mechanical stresses. This robustness ensures the reliability and longevity of these sensing systems.

The Need for Accuracy in Environmental Sensors

Temperature sensors, like thermocouples or RTD (Resistance Temperature Detectors), generate very small voltage changes in response to variations in ambient temperature. Op-Amps in these sensors are used to amplify these minute signals and often incorporate features like high CMRR (Common Mode Rejection Ratio) to filter noise and ensure precise readings. Gas sensors used to detect the concentration of various gases in the environment also rely on Op-Amps to process the signals from electrochemical or catalytic diffusion sensors, and these sensors must be highly sensitive and capable of detecting small changes in sensor output — as well as being resistant to the corrosive environments where gas detectors are utilized.

Similarly, pressure sensors for monitoring and controlling industrial processes offer a voltage output in response to pressure changes. Op-Amps used in such applications need to have high differential gain and stability to amplify the signals accurately. Low-drift amplifiers are preferred in these applications for their ability to maintain consistent performance over time and varying temperature conditions. Slight inaccuracies in signal amplification can lead to erroneous readings. This results in potential hazards, especially in industrial settings where timely detection of toxic gases, high pressures, or high temperatures is crucial. In such applications, Op-Amps must ensure that amplified signals are a precise representation of the stimulus being monitored.

Challenges of Op-Amps in Environmental Sensing

Conventional Op-Amps, which are widely used in current sensing applications, face challenges measuring very small sensor signals. These limitations are primarily due to two factors: the input offset voltage and its temperature drift. Below is a closer look at each of these challenges.

The input offset voltage of an Op-Amp is a small voltage that must be applied between the input terminals to nullify the output voltage when the inputs are ideally at the same level. This offset is due to inherent imbalances in the Op-Amp’s input stage. While negligible, this offset voltage can introduce considerable error in applications where high precision is vital. For example, in current sensing applications where the current is converted to a voltage signal at a low level, the input offset voltage causes the output voltage to change by an amount that is proportional to the non-inverting gain.

This results in inaccurate current measurements. In power control inverters, such current measurement errors might result in inefficient switching, high losses, and reduced performance. In automotive applications such as EVs, this inaccuracy can affect the vehicle’s driving range, battery health, or safety systems. Similarly, environmental sensors having skewed current measurements will provide unreliable data, leading to incorrect environmental assessments and flawed decision-making.

Input offset voltage temperature drift refers to the change in input offset voltage as the ambient temperature varies — a critical issue in applications operating across a range of temperatures or in environments where temperature variation is prevalent. In power control inverters, the operating temperature can vary widely, leading to a drift in the input offset voltage, and, consequently, the accuracy of current sensing. Automotive systems operating in a wide range of temperatures also face similar issues, where fluctuating temperatures can cause input offset voltage drift, affecting current measurements in critical systems such as battery management and safety controls.

ROHM’s LMR1002F-LB Zero-Drift Op-Amp: Key Features & Applications

ROHM’s LMR1002F-LB Zero-Drift Op-Amp delivers ultra-low input offset voltage while minimizing its fluctuations over temperature. Limited to 9µV (Max.), ROHM’s LMR1002F-LB reaches a significantly lower offset voltage compared to standard products. The LMR1002F-LB achieves a temperature drift of 0.05µV/°C (Max.) across a wide operating temperature range, ensuring that performance remains consistent regardless of temperature changes.

ROHM incorporates a chopper circuit in the LMR1002F-LB for dynamic offset voltage correction. This circuit is designed to detect offset voltage generated inside the Op-Amp and automatically correct it via digital circuit control. This design cancels offset voltage by feeding back the offset voltage stored as capacitance in the circuit via a voltage-current conversion circuit.

Figure 1: LMR1002F-LB block diagram (Source: ROHM Semiconductor).
Figure 1: LMR1002F-LB block diagram (Source: ROHM Semiconductor)

Wide Supply Voltage Range and Rail-to-Rail Input/Output

The supply voltage range of 2.7V to 5.5V and rail-to-rail input/output enhances the versatility of the LMR1002F-LB Op-Amp in various power environments. This feature is critical in automotive applications, where electrical systems experience fluctuations over varying operating conditions. In industrial settings, the ability to operate over a wide voltage range is also crucial due to the diverse nature of industrial power supplies and the need for compatibility with different sensor types and interfaces.

Figure 2: LMR1002F-LB temperature drift vs. standard low-offset product (Source: ROHM Semiconductor).
Figure 2: LMR1002F-LB temperature drift vs. standard low-offset product (Source: ROHM Semiconductor)

Reduced Peripheral Components and Software Adjustments

The zero-drift feature of the LMR1002F-LB achieved through the chopper method, ensures that the input offset voltage is maintained at a low level of 9µV, which is markedly lower compared to standard low-offset Op-Amps. This drastic reduction in the offset voltage eliminates the need for additional peripheral components (including capacitors and resistors) required to counteract high offset voltages in standard Op-Amps, resulting in more streamlined and compact circuit designs. Similarly, lower input offset voltage lessens dependency on software adjustments and calibration routines employed to deal with drift issues. The LMR1002F-LB can also improve cost savings in product development and production phases. The reduced component count not only lowers the bill of materials but can simplify assembly and testing processes. For designers and engineers, this might translate into more efficient design cycles, freeing up time and resources to focus on other key aspects of system optimization.

Wide Temperature Operation

The wide operating temperature range of the LMR1002F-LB, from -40°C to +125°C, is crucial for industrial and automotive applications that often operate in harsh environmental conditions. This robustness ensures reliable performance in extreme temperatures. Such stability is essential for precise control and monitoring of industrial processes such as pharmaceutical production, where slight temperature variations can lead to significant quality issues. For automotive applications like electric and hybrid vehicles, the LMR1002F-LB’s resilience against temperature variations, ranging from cold winter conditions to heat generated under the hood, allows sensor systems to provide accurate data, contributing to the vehicle’s overall safety and efficiency.

Key Applications

The sensor signal amplification capabilities of ROHM’s LMR1002F-LB Op-Amp make it suitable for a variety of environmental and process monitoring systems. Specifically, its low offset voltage enhances the sensitivity and reliability of detection systems. For example, in a current sensing application where a sensor signal is amplified by a factor of 1000, the LMR1002F-LB’s offset voltage of 9µV ensures that the error voltage remains minimal, maintaining the accuracy of the output signal.

In temperature control applications, ROHM’s LMR1002F-LB can precisely amplify signals from RTD sensors used for industrial processes like chemical reactions, manufacturing, and food processing. In pipeline flow meters for industries like petrochemicals or pharmaceutical manufacturing, the LMR1002F-LB’s can monitor the fluid flow, which is essential for maintaining product quality and process efficiency. Additionally, ROHM’s zero-drift Op-Amp can be utilized in gas detection and monitoring systems to detect and measure low concentrations of gases, such as carbon dioxide or other toxic gases in industrial facilities.

The post New Zero-Drift Op-Amp Achieves High Accuracy Regardless of Temperature Changes appeared first on Power Electronics News.

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