The presence of unwanted electromagnetic energy in the environment that can interfere with the normal operation of electronic devices, communication systems, and other equipment is referred to as RFI (Radio Frequency Interference) . RFI can come from a variety of sources, including power lines, broadcast towers, and other electronic equipment.

The process of minimizingor removing unwanted electromagnetic energy that interferes with the correct operation of electronic devices or communication networks is referred to as RFI suppression. The purpose of RFI suppression is to ensure that the equipment functions properly and without interference from external sources of electromagnetic energy.

This guide covers topics as below:

  • How RFI is generated
  • Impact of the RFI on system
  • Identification of RFI source
  • RFI suppression techniques
  • Implementation of RFI suppression Techniques
  • Testing and validation

Many industries, including telecommunications, aerospace, and defense, rely on RFI reduction. RFI suppression is critical in telecommunications to ensure that signals are transmitted and received accurately and without interference. RFI suppression is vital in aerospace and defense for maintaining the reliability and efficacy of electronic systems such as radar and communications equipment.

RFI suppression can cover anything from a single electronic device to an entire system or network of devices. In the case of a single electronic equipment, for example, RFI suppression may entail covering the device with conductive material or using filtering techniques to remove undesired frequencies from the signal.

How RFI is generated

RFI sources can be both natural and man-made, and they are roughly classified into two types: conducted interference and radiated interference.

When electrical energy is transmitted through wires or cables that are not appropriately insulated, grounded, or filtered, conducted interference occurs. Conducted interference can be caused by a number of factors, including power lines, motors, transformers, and electronic devices. Electrical energy can be carried through wires or cables and interfere with other devices connected to the same power source if these sources are not sufficiently insulated, grounded, or filtered.

Radiated interference occurs when electromagnetic energy is emitted into the environment from a variety of sources. Radiated interference can be created by a number of different sources, including broadcast towers, cell phone towers, and other electronic devices. When these sources generate electromagnetic energy, this energy can be absorbed or reflected by items in the environment, interfering with the proper operation of other electronic equipment or communication networks.

The frequency, amplitude, and other characteristics of both conducted and radiated interference can be used to classify it. Narrowband interference, for example, is interference that is limited to a specific frequency band, whereas broadband interference encompasses a wide variety of frequencies.

Impact of the RFI on system

RFI can have a substantial impact on electrical and communication systems, causing performance degradation, malfunctions, and even total failure. The effect of RFI on a system depends on a number of parameters, including the frequency and amplitude of the interference, the sensitivity of the equipment, and the nature of the application.

One of the most noticeable effects of RFI on a system is a decrease in performance. This can appear as decreased signal strength, slower data transmission rates, or higher mistake rates. When there is interference in the environment, it might interfere with signal or data transmission, resulting in a decline in system performance.

RFI can also cause problems with electronic devices and communication networks. Interference can disturb electronic circuit activity and cause components to malfunction or fail. Temporary lockups, spontaneous reboots, and other faults that might result in data loss or system downtime are examples of malfunctions. RFI's impact on a system can be significant enough in some circumstances to necessitate equipment replacement or repair.

RFI can also be dangerous. RFI can be disastrous in applications where electronic devices regulate crucial functions, such as in the aerospace or medical industries. RFI can cause unsafe situations or even accidents if it interferes with the operation of vital systems.

Identification of RFI source

Identifying the source of RFI (Radio Frequency Interference) is an important step in reducing interference and guaranteeing the proper operation of electronic equipment or communication systems. Visual inspections, signal analysis, and electromagnetic field measurements are among the tools and techniques used to determine the source of RFI.

Visual inspections are one of the most common approaches for determining the source of RFI. Visually evaluating the environment and equipment to identify potential sources of interference, such as power lines, transmission towers, or other electrical devices, is required. Visual inspections can assist in identifying obvious possible sources of RFI, such as faulty equipment or inadequately insulated cables.

Another way for determining the source of RFI is signal analysis. This entails analyzing the signal's frequency, amplitude, and other properties to determine the source of the interference. Signal analysis can assist in identifying non-visible possible sources of RFI, such as signals generated by electrical devices or other sources of electromagnetic energy.

Electromagnetic field measurements are yet another technique for determining the source of RFI. This entails utilizing specialized equipment to detect the strength of the electromagnetic field in the surroundings and locate regions with high electromagnetic energy. Electromagnetic field measurements can aid in the identification of probable RFI sources that are not apparent or detectable through signal analysis.

Once the source of the RFI has been located, different strategies for suppressing the interference can be applied. Shielding, filtering, and grounding, as well as other approaches, may be utilized based on the source of the interference and the equipment being used.

RFI suppression techniques

There are numerous approaches for suppressing RFI (Radio Frequency Interference) in electronic and communication systems. The type of approach used will be determined by the nature of the interference, the sensitivity of the equipment, and the application requirements. The following are some of the most often utilized RFI suppression strategies, along with their benefits and drawbacks:


Shielding is a technique that encloses electronic components or systems in a conductive or metallic enclosure to protect them from external sources of disturbance. This approach is effective in reducing both radiated and conducted interference and can be used at several levels, from the component to the system. Shielding is a versatile approach that may successfully minimise EMI from both external and internal sources.

Shielding can be applied at various levels, giving it a versatile solution for a wide range of applications. Shielding can improve system performance and reliability by reducing EMI from both external and internal sources.

The negative is that shielding can increase the weight, size, and expense of the equipment, which might be an issue in some applications. It might also be difficult to implement shielding in mobile devices or systems that require ventilation. If shielding is not constructed properly, it can cause thermal management challenges, resulting to overheating and other problems.


Filtering is the technique of employing a filter circuit to remove undesirable frequencies from a signal or power line. Filters can be tailor-made to target specific frequencies or frequency ranges.

Filtering can aid in the reduction of both radiated and conducted interference. Filtering can be tuned to certain frequency bands, allowing it to target specific sources of interference. This approach can also be relatively inexpensive, making it an appealing solution for a wide range of applications.

Filtering can complicate circuitry, especially if numerous filters are needed to minimise interference across a wide frequency range. This intricacy has the potential to raise design and production costs.


To lessen the effects of conducted interference, grounding entails connecting the system or equipment to a common ground reference. Grounding can be done at several levels, from the component to the system.

Grounding reduces transmitted interference, which is especially advantageous in high-frequency applications. In some situations, grounding might be relatively straightforward to achieve.

Improper grounding can cause ground loops and other problems, resulting in increased interference. Grounding may also be ineffective in reducing radiated interference, which can be a significant cause of RFI in some applications. Finally, grounding may be impractical in some situations, such as wireless communication or high-voltage systems.


Another RFI reduction technique is isolation, which involves the use of transformers or other isolation devices to disrupt the electrical connection between components or systems. Isolation can be useful in decreasing conducted interference, especially when grounding is impractical or ineffective.

In some applications, isolation may not be successful in minimizingradiated interference, which can be a significant source of RFI.


To reduce interference, materials that absorb or dampen electromagnetic energy are used. Absorption materials can be used in electrical components and system designs.

In some applications, particularly those requiring static or low-frequency transmissions, absorption materials can be quite straightforward to construct.

Absorption materials may not be viable in certain applications, particularly in high-temperature situations where the heat generated by the absorption materials may pose further problems.

Implementation of RFI suppression techniques

Here are some common RFI suppression techniques that can be implemented:

Bandpass filtering

Depending upon the application and requirements, bandpass filters can be applied in a variety of methods for RFI suppression.

A series of cascaded bandpass filters with distinct cutoff frequencies is a common approach to implement bandpass filters for RFI reduction. This method is commonly employed in radio receivers, where a narrowband filter is positioned at the receiver's front end to reduce out-of-band signals and noise prior to amplification. To further attenuate undesirable signals and noise, the output of the first filter is passed through a succession of subsequent filters with progressively narrower passbands.

Active filters, such as operational amplifier-based filters, are another technique to construct bandpass filters for RFI suppression. Active filters can be set to specific frequencies and have a sharper cutoff than passive filters. They're frequently seen in audio and signal processing applications.

Bandpass filters can be integrated into the design of an electronic circuit in some instances. In a radio transmitter, for example, a bandpass filter can be constructed to match the impedance of the antenna and prevent unwanted signals and noise from being transmitted.

Ferrite beads

Depending on the application, ferrite beads can be used in a variety of ways. To suppress RFI, one typical method is to connect them in series with a signal or power line. This is accomplished by winding the signal or power wire numerous times around the ferrite bead. The ferrite material converts the high-frequency noise picked up by the line into heat and dissipates it, whilst the low-frequency signal travels through the bead undisturbed.

To further reduce unwanted noise and interference, ferrite beads can be used in conjunction with other RFI suppression techniques such as filtering and shielding.


A balun is a device that can convert between balanced and unbalanced signals. Baluns are commonly employed in electronic circuits where signals are sent or received on unbalanced transmission lines (such as coaxial cables) but must be converted to balanced signals (such as twisted pair cables) for transmission or processing. Baluns can help to reduce RFI in these applications by decreasing common-mode noise, which is noise that is present on both the signal and the ground line.

Baluns can be implemented in a variety of methods for RFI suppression, depending on the application. To convert between balanced and unbalanced signals, a balun is commonly used at the input or output of a radio receiver or transmitter. This can aid in the suppression of RFI picked up by the unbalanced transmission line and the reduction of interference in the received signal.

Modulation techniques

RFI suppression techniques can be used in radio communication systems to reduce interference. The process of encoding information onto a carrier signal by modifying one or more of its characteristics, such as amplitude, frequency, or phase, is known as modulation. By altering these qualities, the carrier signal can be made less vulnerable to interference from other signals in the surroundings.

In radio communication systems, frequency modulation (FM) or phase modulation (PM) are two modulation techniques that can be used to suppress RFI. FM and PM are strong modulation techniques that can give considerable RFI rejection. FM encodes information onto the carrier signal by altering its frequency, whereas PM encodes information by varying its phase. Both strategies are commonly employed in radio communication systems and are capable of providing effective RFI reduction.

Spread spectrum approaches are another option to apply modulation techniques for RFI mitigation. Spread spectrum modulation spreads the energy of a signal over a wide frequency range, making it less susceptible to interference from other signals in the environment. Spread spectrum techniques are widely employed in wireless communication systems like Wi-Fi and Bluetooth to enable robust and secure connectivity even in the presence of interference.

Testing and validation

Testing and validation are crucial for ensuring that RFI suppression techniques are effective and meet the required performance standards. There are various testing and validation methods available depending on the specific RFI suppression technique and its intended application.

One effective way to test and validate RFI suppression techniques is to use an anechoic chamber. These rooms are designed to minimise external noise and reflections, making them ideal environments for testing RFI suppression techniques. In an anechoic chamber, the device or circuit being tested can be exposed to controlled RFI sources, and its performance can be evaluated by measuring its response to the interference. Shielding and filtering are two RFI suppression techniques that can be tested and validated in this way.

Another testing and validation method for RFI suppression techniques is electromagnetic compatibility (EMC) testing. This method involves subjecting the device or circuit to a range of electromagnetic interference (EMI) sources that simulate real-world environments. The device's performance is then evaluated by measuring its emissions (the amount of EMI it generates) and its susceptibility (its response to external EMI sources). EMC testing can validate RFI suppression techniques such as shielding, filtering, and grounding.

Field testing is another critical aspect of validating RFI suppression techniques. It involves installing the device or circuit in its intended location and evaluating its performance in the presence of external interference. Shielding, filtering, and modulation are RFI suppression techniques that can be validated through field testing to ensure their effectiveness in real-world applications.

Newark has partnered with many different suppliers with fixed resistors portfolio includes EMC / RFI suppression, EMI noise filters, ferrites & ferrite assortments, suppression - miscellaneous that can be used for different kind of applications in the industrial environment.


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