投稿日:2024年12月24日

Fundamentals of noise and practical applications of noise countermeasures and their key points for electronic equipment and electronic circuit engineers

Understanding Noise in Electronic Equipment

Noise is an inevitable part of electronic systems that engineers must address to ensure optimal performance and functionality.
In simple terms, noise refers to any unwanted electrical signals that interfere with the desired operation of electronic devices and circuits.
This interference can degrade signal quality, reduce efficiency, and even cause complete malfunction of the device.

Noise can originate from several sources, including internal and external factors.
Internal noise is generated within the electronic equipment itself, such as thermal noise, which is inherent in resistors and other components due to the random motion of electrons.
External noise, on the other hand, comes from outside sources, like electromagnetic interference (EMI) from nearby devices, power lines, or radio frequency interference (RFI) from communication systems.

Types of Noise

To effectively combat noise in electronic equipment, it’s crucial to understand the different types of noise and their characteristics.

Thermal Noise

Thermal noise, also known as Johnson-Nyquist noise, is caused by the thermal agitation of electrons within conductors.
It is present in all resistive components and is proportional to the temperature and resistance of the component.
While it cannot be eliminated, it can be minimized by reducing the resistance and temperature of the circuit components.

Flicker Noise

Flicker noise, or 1/f noise, is a low-frequency noise that usually occurs in electronic devices due to imperfections in materials and manufacturing processes.
It is inversely proportional to frequency; hence it becomes significant at low frequencies.
Flicker noise can be minimized by selecting high-quality materials and ensuring proper manufacturing processes.

Shot Noise

Shot noise arises from the discrete nature of electric charge, particularly in semiconductors.
It occurs when the current crosses a potential barrier, such as a diode or a transistor junction.
Shot noise can be reduced by optimizing the operating conditions of semiconductor devices and using appropriate filtering techniques.

Electromagnetic Interference (EMI)

EMI is caused by external electromagnetic fields that interfere with the operation of electronic equipment.
It can be radiated or conducted, depending on how it enters the electronic system.
EMI can be minimized through proper shielding, grounding, and filtering techniques.

Practical Applications of Noise Countermeasures

Noise countermeasures are essential to the design and operation of electronic equipment.
By implementing effective noise reduction techniques, engineers can ensure reliable and efficient performance.

Shielding

One of the most effective ways to protect electronic devices from EMI is through shielding.
Shielding involves enclosing the electronic components in a conductive material that blocks external electromagnetic fields.
Common materials for shielding include metals like aluminum and copper.
The effectiveness of shielding is determined by the thickness and conductivity of the material used and the frequency of the interfering signal.

Grounding

Proper grounding techniques are essential to minimize noise in electronic systems.
Grounding provides a path for unwanted noise signals to dissipate safely into the ground.
By creating a single point of reference for all signals in a system, grounding helps reduce potential differences that could generate noise.

Filtering

Filters are used to remove unwanted frequencies from the signal path, allowing only the desired frequencies to pass through.
Low-pass, high-pass, band-pass, and band-stop filters are common types used in electronic circuits.
Selecting the appropriate filter depends on the specific noise characteristics and the frequency range of interest.

Design Layout and Component Selection

The physical layout of a circuit and selection of components can significantly impact noise levels.
Engineers must carefully design circuit board layouts to minimize crosstalk and other noise sources.
This includes keeping signal traces short, using twisted-pair cables, and placing power and ground planes strategically.

Choosing components with low intrinsic noise levels is another key factor.
High-quality resistors, capacitors, and inductors can reduce thermal, flicker, and shot noise.
Additionally, using differential signaling instead of single-ended signaling can help cancel out common-mode noise.

Key Points for Electronic Engineers

For electronic circuit and equipment engineers, understanding and addressing noise is a fundamental aspect of design.
Here are some key points to remember when dealing with noise:

Evaluate Noise Sources

Identify and analyze potential sources of noise in the system.
Consider both internal and external factors that could affect performance.
Use simulation tools and testing equipment to measure noise levels and identify problematic areas.

Implement Layered Countermeasures

Combining multiple noise reduction techniques often provides the best results.
For example, using both EMI shielding and proper grounding can significantly reduce interference more effectively than either technique alone.

Engage in Continuous Testing

Thorough testing is crucial to ensure noise levels remain within acceptable limits throughout the product lifecycle.
Perform regular testing, especially when changes are made to the system, such as component upgrades or new functionality introductions.

Stay Informed and Updated

Noise reduction techniques and technologies are continually evolving.
Stay informed about the latest developments and best practices in noise mitigation by attending industry conferences, engaging with professional communities, and continuing education.

Conclusion

Noise is an inherent and unavoidable challenge in the design and operation of electronic equipment.
However, with a thorough understanding of noise types and sources, and by implementing effective countermeasures, engineers can significantly improve the performance and reliability of electronic devices.
Adopting a methodical approach to noise reduction and engaging in continuous testing will ensure that noise remains within acceptable limits, paving the way for successful electronic systems and products.

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