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Intelligent electronic device

An intelligent electronic device (IED) is any device incorporating one or more processors with the capability to receive or send or from or to an external source (e.g., electronic multifunction meters, digital relays, controllers), commonly used in systems for functions including , , metering, and . These devices integrate sensing, , and communication capabilities, enabling operation and within substations and smart grids. IEDs play a central role in modern power infrastructure, particularly in substation , where they replace traditional hardwired systems with networked, solutions that enhance reliability and efficiency. Common types include protective relays for fault detection, controllers, multifunction meters, and capacitor bank switches, all of which support protocols like for standardized communication over Ethernet networks. This standard facilitates seamless data exchange between IEDs from different manufacturers, promoting and reducing wiring complexity in high-voltage environments. Beyond core operations, IEDs contribute to advanced features such as cybersecurity measures, event recording, and , as outlined in standards like IEEE 1686, which specify functions for substation devices. Their deployment has evolved with the rise of digital substations, enabling automated reconfiguration of power networks and integration with broader grid management systems to support integration and . However, managing large fleets of IEDs requires robust tools for configuration, testing, and updates to mitigate risks like cyber vulnerabilities.

Definition and Overview

Definition

An intelligent electronic (IED) is an integrated microprocessor-based controller of power equipment, such as circuit breakers, transformers, and capacitor banks, that provides , , , and functions by inputs from sensors and issuing corresponding outputs to manage operations. More generally, an IED is a microprocessor-based capable of receiving, , and sending or signals to and from external sources. Unlike traditional electromechanical relays, which operate as single-purpose relying on mechanical components to respond to specific electrical conditions, IEDs leverage digital processing to enable multifunctionality, including advanced logic, , and communication capabilities within a single unit. In operation, an IED samples analog signals from current and voltage transformers, converts them to digital form, performs computations using embedded algorithms to analyze system conditions, and generates binary control outputs—such as trip signals—to actuate equipment like circuit breakers for fault clearance or system stabilization.

Key Characteristics

Intelligent electronic devices (IEDs) are distinguished by their multifunctionality, integrating multiple protective, , metering, and recording functions into a single unit, which eliminates the need for numerous discrete electromechanical or traditionally used in power systems. This consolidation reduces wiring complexity, panel space, and maintenance costs while enabling coordinated operations such as simultaneous fault detection, logic, and data logging. For instance, a single IED can perform distance protection, overcurrent protection, breaker failure detection, and voltage metering, providing a streamlined approach to substation . At the core of IED intelligence is digital signal processing (DSP), which relies on analog-to-digital converters (ADCs) to sample input signals from current and voltage transformers at rates typically ranging from 1 to 16 kHz, ensuring precise capture of power system waveforms for analysis. These sampling rates, often 4.8 kHz for general protection in 60 Hz systems or up to 14.4 kHz for power quality applications, allow for accurate estimation, , and transient event recording through anti-aliasing filters and Fourier transform algorithms. This digital approach surpasses analog devices by enabling high-resolution data processing without mechanical wear, supporting advanced features like synchronized measurements. IEDs offer extensive programmability and configurability through dedicated software tools, allowing engineers to implement user-defined tailored to specific grid conditions, such as custom schemes or adaptive settings. Tools like Continuous Function Chart () editors in systems such as SIPROTEC 5 enable graphical programming of logical nodes and functions, which can be uploaded to the device for execution without hardware modifications. This flexibility supports scenario-based customization, including integration with standards for logical device modeling, enhancing adaptability in dynamic power environments. Self-diagnostic capabilities are integral to IED reliability, featuring built-in monitoring systems that continuously perform self-tests on components, , and to detect faults proactively. These diagnostics can identify internal issues, such as errors or failures, and extend to external , like breaker . Event logging complements this by timestamping and storing diagnostic , waveforms, and fault records in for post-incident analysis, facilitating rapid troubleshooting and preventive maintenance.

History and Development

Origins in Power Systems

The origins of intelligent electronic devices (IEDs) in power systems trace back to the transition from analog electromechanical protective relays to technologies during the and , driven by advancements in and capabilities. In the late , conceptual foundations for emerged with proposals to sample voltages and currents using mainframe computers for fault detection, marking a shift toward centralized in substations. This period saw the initial application of in protective relaying, replacing mechanical components with integrated circuits for faster and more reliable operation. By the early , the of the , exemplified by the released in 1971, enabled compact, programmable devices capable of performing complex relaying algorithms, laying the groundwork for what would become IEDs. These early digital relays represented precursors to IEDs, focusing on protective functions through of sampled data, such as discrete Fourier transforms for processing introduced in 1972. Minicomputer-based systems, like Westinghouse's P50 series in the , were trialed for relaying, offering improved accuracy and event recording compared to electromechanical predecessors. The integration of microprocessors in the late further advanced this, with efficient 8-bit designs allowing for self-monitoring and fault location, as demonstrated in developments by researchers like Dr. E.O. Schweitzer around 1979-1980. These innovations were propelled by broader progress, including (VLSI), which reduced costs and size while enhancing computational power for . The evolution of supervisory control and data acquisition (SCADA) systems during this era significantly influenced early IED precursors, facilitating remote monitoring and control in utilities. Originating from 1960s telemetry for automated data transmission, SCADA transitioned to digital frameworks in the , enabling integration with protective relays for substation-wide oversight and reduced wiring through networked communications. Projects like the Electric Power Research Institute's (EPRI) WESPAC initiative from 1978 onward exemplified this synergy, combining digital relays with SCADA for enhanced and fault analysis. North American utilities were among the earliest adopters, experimenting with digital relays to supplant electromechanical ones for superior fault detection speeds and reliability. Pacific Gas and Electric (PG&E) installed the first operational digital relay in 1971 at its 230 kV Tesla Substation, which ran without failure until 1977, while (AEP) conducted minicomputer-based trials throughout the . These implementations highlighted the potential for faster response times and remote diagnostics, setting the stage for widespread utility adoption despite initial challenges with reliability and support.

Evolution and Milestones

The evolution of intelligent electronic devices (IEDs) in power systems accelerated in the with the introduction of fully digital multifunction relays by leading manufacturers such as ABB and , marking a shift from electromechanical and early static relays to microprocessor-based systems capable of performing multiple protection and control functions within a single unit. These advancements enabled features like sequence-of-events recording, which provided precise timestamping of power system events for improved post-fault analysis and diagnostics, leveraging the computational power of microprocessors to log disturbances with millisecond accuracy. By the late , such IEDs reduced panel space requirements and wiring complexity while enhancing reliability through self-diagnostics and programmable logic. In the , a standardization push facilitated greater IED integration into substation systems, with protocols like emerging as a key enabler for communication between IEDs and supervisory control and (SCADA) systems. Originally developed in the late , saw widespread adoption in power utilities during this decade due to its simplicity, , and support for serial and later TCP/IP-based networks, allowing IEDs to transmit metering, status, and control efficiently. This coincided with broader substation initiatives, where utilities began deploying networked IEDs to automate and remote , laying the groundwork for more interconnected operations. The 2000s and 2010s brought transformative milestones through the widespread implementation of the IEC 61850 standard, first published in 2003, which revolutionized IED communication by enabling seamless peer-to-peer data exchange via Ethernet-based networks and protocols like GOOSE for high-speed messaging. This standard facilitated interoperability among multivendor IEDs, reducing dependency on proprietary protocols and supporting advanced automation schemes such as automatic bus transfer and breaker failure protection. Concurrently, integration with phasor measurement units (PMUs) advanced wide-area monitoring, with IEDs incorporating synchrophasor capabilities synchronized via GPS to provide real-time visibility into grid dynamics across large regions, enhancing stability assessment and disturbance detection during this period. From the 2020s to 2025, IED development has emphasized enhanced cybersecurity features to address growing vulnerabilities, including secure mechanisms, encrypted communications, and intrusion detection integrated directly into device to mitigate risks from cyberattacks on substation networks. These measures respond to incidents like remote access exploits, with manufacturers updating IED protocols to comply with standards such as for secure data exchange. Additionally, newer IED models incorporate AI-assisted fault prediction, using algorithms to analyze historical and for proactive in power electronic systems, improving and reducing outage risks.

Technical Components

Hardware Elements

Intelligent electronic devices (IEDs) rely on core hardware components to perform real-time processing and control in systems. At the heart of an IED is a , often a () or ARM-based unit, which executes protection algorithms, metering functions, and communication tasks. For instance, modern IEDs may incorporate a dual-core ARM within a system-on-chip like the Xilinx Zynq-7000, providing efficient handling of digital signals and general computations. Analog-to-digital converters (ADCs) are essential for sampling input signals, converting analog voltages and currents from sensors into digital data for processing; common configurations include 16-bit successive approximation ADCs offering 65,536 levels to ensure accurate representation of system waveforms. Digital-to-analog outputs, though less common, enable the generation of control signals for actuators or analog interfaces in specific applications. Input/output (I/O) modules form the between the and the power system, enabling sensing and actuation. Current () and voltage () interfaces condition high-energy signals—reducing currents to 5 A and voltages to 67 V or less—before feeding them to ADCs for and metering. inputs discrete statuses, such as positions or isolator states, typically through optically isolated circuits to protect against noise and voltage surges. outputs provide high-current contacts for critical actions like tripping breakers, with configurations supporting multiple outputs (e.g., up to 8 digital outputs in modular designs) to accommodate complex schemes. These modules ensure reliable interaction with field devices while isolating the internal electronics. Power supplies in IEDs emphasize redundancy and resilience to maintain operation during faults or outages. Dual redundant sources, often accepting 24–48 Vdc or 110–250 Vdc/Vac inputs, include monitoring for voltage anomalies and DC/DC converters to deliver stable power to components. Enclosures are rugged, designed for harsh substation environments with temperature ranges from –40°C to +85°C, conformal coatings for humidity protection, and certifications like ATEX/UL Class I Division 2. Compliance with IEEE C37.90 ensures electromagnetic compatibility, including tests for transient susceptibility and dielectric withstand, safeguarding against power system disturbances. Human-machine interfaces (HMIs) on IEDs facilitate local configuration and monitoring without external tools. Front panels typically feature LCD displays—such as 2x16 character screens or optional 5-inch capacitive touchscreens—for viewing status, events, and settings, alongside programmable tricolor LEDs for alarm indication and pushbuttons for navigation. Connectivity includes front-panel USB and Ethernet ports for secure engineering access, firmware updates, and integration with software tools. This hardware supports the execution of embedded software for IED functions, as detailed in subsequent sections.

Software and Processing

Intelligent electronic devices (IEDs) typically run on real-time operating systems (RTOS) to ensure deterministic execution for time-critical tasks in power systems. VxWorks, a widely deployed RTOS, is utilized in models such as ABB's Relion 670 and 650 series IEDs, providing reliable performance for embedded applications requiring security and safety. Firmware in IEDs supports these operations and is updated through secure bootloaders that verify integrity and authenticity before loading, mitigating risks from unauthorized modifications. Core algorithms enable the intelligent processing central to IED functionality. Digital filtering techniques, including discrete Fourier transforms (DFT), are employed for harmonic analysis to extract fundamental frequencies from sampled waveforms, aiding in accurate phasor estimation. Symmetrical component calculations decompose unbalanced three-phase currents and voltages into positive, negative, and zero sequences, facilitating fault type identification such as single-line-to-ground or line-to-line faults. Configuration of IEDs relies on proprietary software tools from manufacturers to define operational parameters. Schneider Electric's Easergy Studio allows users to set protection thresholds, time delays, and logic schemes via graphical interfaces compliant with standards like IEC 61850. Similarly, GE Vernova's IED Loader software streamlines parameter adjustments and system integration for devices like the D400 series. Data handling in IEDs includes event buffering for sequence-of-events recording, capturing disturbances with high-resolution timestamps. These buffers, often holding up to 1,000 events at 1 ms resolution, synchronize via GPS or IRIG-B signals for precise timing across substations.

Functions and Capabilities

Protection and Control

Intelligent electronic devices (IEDs) serve as the primary means for implementing protective relaying in modern power systems, detecting faults such as short circuits and abnormal conditions to prevent equipment damage and maintain system stability. These devices integrate multiple protection functions within a single unit, leveraging microprocessor-based processing to analyze voltage and current inputs from transducers. Key protection functions include , , , and directional relaying, each tailored to specific fault scenarios in transmission lines, transformers, and generators. Overcurrent protection in IEDs monitors current magnitudes to detect overloads or short-circuit faults, operating based on time or definite time characteristics to clear faults selectively. This function is essential for and protection, where excessive currents exceed predefined thresholds, triggering isolation of the affected section. Directional relaying extends this by determining fault direction through phase angle comparisons between voltage and current phasors, ensuring operation only for faults in the forward direction away from the protected bus. In complex networks like ring mains or parallel s, this prevents unnecessary tripping of healthy sections by restraining for reverse faults. Differential , a unit protection scheme, compares currents entering and exiting a protected , such as a or , using Kirchhoff's current law to identify internal faults with high sensitivity and speed. IEDs at both ends exchange synchronized current samples via communication links, calculating differential and restraint currents to stabilize against external faults, CT saturation, or capacitive charging effects. This approach provides superior selectivity over non-unit methods, particularly for high-voltage lines, by operating instantaneously for internal faults while remaining secure for through-faults. Distance relaying in IEDs estimates fault location by computing apparent impedance from measured voltage and current phasors, using the formula Z = \frac{V}{I}, where V is the voltage phasor and I is the current phasor. This impedance represents the positive-sequence to the fault under ideal conditions, plotted on the R-X plane to define protection zones based on line impedance characteristics. The relay trips if the measured Z falls within predefined mho or zones, providing stepped coverage for primary line protection and extending to backup for adjacent sections. Upon fault detection, IEDs execute control actions by issuing trip commands to circuit breakers, isolating the faulty to minimize outage duration and damage. Coordination , embedded in the IED's software, ensures time-graded or logic-based selectivity among multiple devices, avoiding nuisance operations by verifying fault persistence and direction before actuation. This automated response enhances system reliability, with trip signals generated via hardwired outputs or networked protocols. Zone protection schemes employ in primary and backup configurations to provide redundant coverage, where overlapping ensure that a primary failure activates a unit without compromising . Primary directly guard specific equipment like buses or lines, while backups—often using overreaching distance or directional —cover adjacent with delayed timing for coordination. This layered approach maintains dependability, with redundant from diverse vendors assignable to the same for during maintenance. For generator applications, IEDs implement loss-of-field by monitoring reactive flow, detecting when the absorbs vars from the due to failure, indicating asynchronous operation as an . Using offset mho characteristics or reactive calculations, the IED identifies sustained leading reactive conditions, typically tripping after a 1-second delay to avoid false operations from transient swings. This function safeguards against overheating and stability loss in synchronous s.

Monitoring and Metering

Intelligent electronic devices (IEDs) provide essential metering capabilities for real-time assessment of electrical parameters in power systems. These devices measure active power (kW), reactive power (kVAR), , and harmonics, enabling precise and billing accuracy. For instance, the SEL-735 Power Quality and Revenue Meter, an IED, calculates these values with high fidelity, supporting up to the 63rd harmonic order. Compliance with ANSI C12.20 standards ensures metering accuracy, with classes such as 0.1%, 0.2%, and 0.5% defining tolerances for electricity meters integrated into IEDs; the SEL-735 exceeds the 0.1 accuracy class over a wide current range, meeting requirements for revenue-grade applications. Monitoring features in IEDs facilitate detailed of events and disturbances. Sequence-of-events (SOE) recording captures status changes, such as breaker operations, with timestamps accurate to milliseconds, storing over 80,000 events across multiple channels in devices like the SEL-735. Disturbance recording includes oscillography, capturing voltage and current waveforms at sampling rates from 16 to 512 samples per cycle—equivalent to 1-30 kHz at 60 Hz fundamentals—allowing reconstruction of transient events. NERC PRC-002-5 mandates a minimum of 16 samples per cycle for fault and dynamic disturbance recording to reliability analysis. Quality analysis functions in IEDs detect and quantify power quality issues, aiding in system diagnostics. Voltage sag and swell detection identifies dips below 90% or rises above 110% of nominal voltage, with resolutions as fine as 4 , as implemented in the SEL-735 for IEC 61000-4-30 Class A . Frequency tracking monitors under- and over-frequency conditions, recording deviations from nominal values (e.g., 60 Hz) to capture events like load shedding triggers. Data from IED monitoring and metering is exported for reporting and post- forensics. SOE reports, including event timestamps and waveforms, are generated in or Excel formats using tools like SEL SynchroWAVE software, facilitating analysis of disturbances without . This export capability supports regulatory requirements, such as those in NERC standards, by providing accessible records for root-cause investigations.

Applications

Substation Automation

Intelligent electronic devices (IEDs) play a central role in substation automation by serving as field devices within hierarchical architectures defined by the standard, which organizes substation functions into three primary levels: the process level (interfacing with primary equipment like circuit breakers and transformers), the bay level (handling and for individual bays), and the station level (managing overall substation coordination and interfaces to wider systems). At the process level, IEDs directly acquire analog and digital signals from sensors and actuators, enabling decentralized processing that enhances reliability and reduces single points of failure. This layered approach facilitates seamless data exchange and among diverse IEDs from multiple vendors, supporting automated sequences such as fault isolation and restoration without relying on centralized controllers for every operation. A key advantage of IEDs in substation is the significant reduction in hardwiring compared to traditional point-to-point connections, which often require extensive cabling for interlocking and signaling between devices. Instead, IEDs leverage Generic Object-Oriented Substation Event () messaging over Ethernet networks for communication, allowing transmission of status changes and commands with latencies typically under 4 milliseconds to meet timing requirements. This shift minimizes installation costs, improves scalability by virtualizing inputs and outputs, and enhances system flexibility, as GOOSE enables dynamic reconfiguration without physical rewiring. IEDs integrate effectively with remote terminal units (RTUs) and human-machine interfaces (HMIs) by executing local logic, such as and sequencing, which offloads computational burdens from supervisory and (SCADA) systems focused on higher-level monitoring and remote oversight. In this setup, IEDs provide aggregated data to RTUs via standardized protocols, enabling HMIs to visualize real-time status and issue commands without direct intervention in bay-level operations, thereby improving response times and operator efficiency. A practical example of IED deployment in substation automation is the (PG&E) 500 kV upgrade, where microprocessor-based IEDs were implemented to replace aging solid-state relays across 17 lines, incorporating dedicated breaker failure schemes. Each utilized a single non-redundant IED for failure detection via current or seal-in algorithms, with independent phase to initiate backup tripping if the primary breaker failed to clear a fault. The design ensured compliance with for future GOOSE integration, underwent real-time digital simulator testing for series-compensated lines, and achieved simplified maintenance with minimal outages, demonstrating enhanced reliability and adherence to NERC standards like PRC-023-1.

Integration in Broader Power Systems

Intelligent electronic devices (IEDs) play a critical role in transmission systems by enabling line over long , where traditional methods may be insufficient due to communication challenges and fault propagation. These devices compare current phasors at both ends of a to detect internal faults rapidly, often within one to two cycles, minimizing outage durations and enhancing grid reliability. For instance, the ABB RED615 IED is specifically designed for phase-segregated two-end line in utility transmission networks. Similarly, SIPROTEC 7SL86 provides combined and for overhead lines and cables, supporting multi-ended configurations up to 765 kV. In transmission applications, integrate with phasor measurement units (PMUs) for synchronized monitoring of , using GPS or PTP time to achieve sub-microsecond accuracy in . This allows assessment of voltage angles and frequencies, enabling wide-area and early detection of oscillations or instability events. The RES670 , for example, functions as a PMU-compliant , delivering up to 32 synchronized phasors for monitoring in grids. Such supports advanced applications like dynamic , where PMU data from informs predictive models for preventing cascading failures. Recent developments include AI-enhanced for predictive fault , improving grid resilience as of 2023. In distribution networks, feeder IEDs facilitate recloser control and precise fault location, particularly in radial configurations where faults can affect large customer segments. These devices automate reclosing sequences to restore service after temporary faults, such as those caused by vegetation or wildlife, while using impedance-based or traveling-wave algorithms to pinpoint permanent fault locations within meters. The ABB REF615 IED, for instance, incorporates auto-reclose functions and fault location for overhead line feeders in medium-voltage distribution systems. SEL recloser controls, integrated as IEDs, enable fault isolation and service restoration in distribution feeders, reducing outage times through coordinated operation with fault current indicators. For renewable energy integration, IEDs in wind and solar farms ensure compliance with anti-islanding and ride-through requirements, protecting the grid from unintended energization during outages while maintaining connection during minor disturbances. Anti-islanding functions detect grid loss and trip within two seconds, as mandated by IEEE Std 1547-2018, preventing hazards to utility workers. Ride-through capabilities allow farms to withstand voltage or frequency deviations without disconnecting, supporting grid stability amid variable generation. Protective IEDs, such as those from SEL, implement these features in microgrids with renewables, including synchronization checks for safe reconnection post-islanding. In solar installations, IED-based relays monitor inverter outputs to enforce IEEE 1547 performance categories for abnormal conditions. While primarily focused on power systems, IEDs have limited extensions to industrial process applications, such as motor protection in facilities. These devices provide overload and thermal protection for asynchronous motors, integrating with process control systems to minimize . The ABB REM611 IED, for example, offers dedicated motor protection functions including overload and thermal protection for industrial environments, though its core design remains oriented toward utility-scale power applications.

Communication Protocols and Standards

Supported Protocols

Intelligent electronic devices (IEDs) support a variety of communication protocols to facilitate data exchange, commands, and within systems. These protocols enable IEDs to interact with supervisory and (SCADA) systems, remote terminal units (RTUs), and other networked components, ensuring reliable operation in substation environments. Among the most common protocols are the Distributed Network Protocol version 3 (), which operates over serial or networks for polling-based and control. DNP3 allows master stations to request status updates, measurements, and event reports from IEDs, supporting features like time-stamped sequence-of-events recording for fault analysis. Modbus, another widely adopted protocol, is primarily used for basic metering and data reading in IEDs, employing a simple request-response mechanism over serial ( RTU) or / ( ) links to retrieve parameters such as voltage, current, and energy consumption. IEC 60870-5-104 serves telecontrol functions, extending the serial-based IEC 60870-5-101 standard to / networks for remote monitoring and control of IEDs in wide-area power grids. For more efficient data handling, IEDs utilize client-server models through the protocol, which supports interactions for accessing logical device data. MMS enables report-by-exception mechanisms, where IEDs transmit updates only when values change beyond predefined thresholds, thereby minimizing network bandwidth usage compared to continuous polling. Publisher-subscriber models in , such as for fast messaging and Sampled Values for analog data, further enhance efficiency by multicasting updates without individual requests. Time synchronization is critical for coordinating IED operations across distributed networks, with protocols such as Simple Network Time Protocol (SNTP) providing millisecond-level accuracy for station-level alignment of device clocks. For higher precision in process-level applications, (PTP, IEEE 1588) achieves or synchronization, essential for timestamping events and synchronizing sampled values in real-time protection schemes. The evolution of IED protocols reflects a shift from proprietary implementations, which limited , to open standards that promote vendor-neutral communication. This transition enhances system flexibility and reduces , as seen in DNP3's subset levels: Level 1 for basic IED functions like analog and binary inputs; Level 2 adding operations and transfers; and Level 3 supporting advanced features such as unsolicited reporting and security extensions.

Interoperability Standards

Interoperability standards for intelligent electronic devices (IEDs) are essential to ensure seamless and communication in multi-vendor power system environments, minimizing proprietary dependencies and enhancing system reliability. The primary framework is provided by , an developed by the (IEC) for communication networks and systems in power utility automation. At its core, IEC 61850 employs object-oriented modeling to represent substation functions through logical nodes, such as XCBR for circuit breakers, which abstract device behaviors and enable communication that is independent of physical wiring configurations. This modeling approach allows IEDs from different manufacturers to exchange data consistently, using a hierarchical structure of logical devices, nodes, and data objects defined in parts like IEC 61850-7-4. To verify compliance and promote interoperability, the UCA International Users Group (UCAIUG) administers certification programs for IEDs under IEC 61850. These include conformance testing procedures outlined in IEC 61850-10, covering aspects like server, client, GOOSE publisher/subscriber, and sampled values functionalities, with levels such as A1 and B1 indicating tested capabilities. Certification ensures that certified IEDs adhere to the standard's abstract communication service interface (ACSI), reducing integration risks in substation automation systems. Over 1,200 certificates had been issued as of 2021, with the number continuing to grow, demonstrating widespread adoption and validation of multi-vendor compatibility. Complementing IEC 61850, other standards address specific interoperability needs in IED applications. IEEE C37.118 defines synchrophasor measurements for power systems, specifying formats for synchronized , , and rate-of-change-of-frequency data exchange between IEDs and phasor measurement units (PMUs), ensuring accurate wide-area with total error limits under steady-state and dynamic conditions. Similarly, IEEE 1815 standardizes the Distributed Network Protocol (), with enhancements like secure authentication (DNP3-SA) providing cybersecurity features such as challenge-response mechanisms to protect IED communications against unauthorized access and tampering. These standards integrate with mappings, as detailed in related sections. Global adoption of these standards is driven by regulatory frameworks, particularly in the , where mandates from the under M/490 promote for to support renewable integration and . Updates like the 2011 edition and its 2020 amendment (Edition 2.1) of -9-2 refine sampled values transmission over Ethernet for real-time analog data, specifying service mappings for process bus applications with reduced overhead compared to earlier versions. This edition facilitates digital interfaces in substations, aligning with EU directives for efficient, secure power systems. Recent developments as of 2025 include mappings of to OPC UA for enhanced integration with Industry 4.0 systems and exploration of networks to improve latency and reliability in digital substation communications, further extending in modern smart grids.

Advantages and Challenges

Operational Benefits

Intelligent electronic devices (IEDs) offer significant cost and space savings in power system applications by consolidating multiple , , and monitoring functions into a single unit, often replacing 5-10 traditional single-function electromechanical relays. This integration reduces the need for extensive wiring and hardware, leading to a 50% decrease in control enclosure footprint—for example, from 24 ft x 50 ft to 12 ft x 50 ft in typical substation designs—while minimizing installation and material expenses. IEDs enhance system reliability through faster fault detection and response times, achieving trip decisions in as little as 1/2 (approximately 8.33 ms at 60 Hz), compared to 5 or more cycles for traditional electromechanical relays. This rapid operation, combined with built-in redundancy features such as hot-swappable modules, minimizes and improves overall grid stability during disturbances. capabilities further bolster reliability by automatically detecting internal faults and environmental stressors in . Maintenance of IEDs is simplified via remote , diagnostics, and software-based updates, which reduce the frequency of on-site visits by enabling engineers to perform adjustments and from centralized locations. Integration with human-machine interfaces (HMIs) supports operator and without physical intervention, lowering operational costs and risks. These features streamline fleet-wide management, allowing for based on continuous data logging. Recent advancements include AI-enabled IEDs for predictive fault analysis, as introduced by manufacturers like in 2023, further enhancing these capabilities. The of IEDs facilitates scalability, supporting firmware upgrades to adapt to evolving grid requirements, such as integrating charging infrastructure or sources. This upgradability ensures long-term compatibility without full hardware replacements, promoting efficient expansion of substation across diverse power system scales. While these benefits improve reliability and efficiency, realizing them requires addressing challenges in multi-vendor environments.

Limitations and Testing Considerations

Intelligent electronic devices (IEDs) in power systems are susceptible to cybersecurity vulnerabilities due to their networked nature, which exposes them to threats similar to those targeting , such as the worm that exploited vulnerabilities to disrupt operations. These risks include unauthorized access, denial-of-service attacks, and manipulation of control commands, potentially leading to physical damage or grid instability in substations. To mitigate such threats, IEDs often incorporate encryption protocols like , which secures communications in standards such as , ensuring data integrity and confidentiality during transmission. The of IEDs presents significant challenges, as setting files for logic, metering, and communication require extensive parameterization that can take hours to days, increasing the potential for in complex substation environments. Without tools to validate configurations prior to deployment, errors in logic or parameter alignment can result in incorrect responses, such as unintended isolations or overlooked faults. Rigorous testing is essential for IED reliability, including end-to-end simulations that replicate substation conditions using relay test sets like the CMC 356 to verify functions, timing, and . Type testing according to IEC 60255 standards assesses environmental endurance, encompassing , temperature extremes, humidity, and mechanical stress to ensure operational integrity under adverse conditions. IEDs depend heavily on stable power supplies and communication networks, where disruptions can trigger failure modes such as incorrect settings or misoperations, as seen in the 2003 Northeast blackout where alarm failures and protection relay misoperations exacerbated cascading outages. These dependencies highlight the need for redundant systems and thorough validation to prevent scenarios where communication losses lead to unmonitored grid instabilities, offsetting some operational benefits through heightened maintenance demands.

References

  1. [1]
    Intelligent Electronic Device (IED) - Glossary | CSRC
    An IED is any device with processors that can receive or send data/control from or to an external source.
  2. [2]
    [PDF] A System Solution for IEDs Based on IEC 61850 - Analog Devices
    The intelligent electronic device (IED) is a basic element of the smart grid, delivering the sensing, measurement, protection, and control functionality ...
  3. [3]
    Managing intelligent electronic devices - Eaton
    In this paper, we will discuss some of the basic functions required for managing large fleets of IEDs, the solutions that have been developed to help utilities.
  4. [4]
    The key role of intelligent electronic devices (IED) in advanced ...
    It enables real-time monitoring of grid conditions for the distribution system operators and allows automatic reconfiguration of the network to optimize the ...
  5. [5]
    IEC 61850 Benefits Power & Energy Applications | UK
    Feb 2, 2022 · IEC 61850 has helped companies fully utilize Ethernet-based communications and realize gains in the performance and flexibility of power protective relays.
  6. [6]
    IEEE 1686-2007 - IEEE SA
    The functions and features to be provided in substation intelligent electronic devices (IEDs) to accommodate critical infrastructure protection programs are ...<|control11|><|separator|>
  7. [7]
    Intelligent Electronic Device-in-the-Loop: A Real-Time Simulation as ...
    Dec 9, 2024 · These IEDs can enhance power systems by providing up-to-date information to operators and ensuring proper operations of power system components.
  8. [8]
    Cyber-Attacks Related to Intelligent Electronic Devices and Their ...
    Intelligent electronic devices (IEDs) are deployed in power systems to facilitate advanced automation for controlling critical equipment. Once an IED is ...
  9. [9]
    Fundamentals of substation automation - Eaton
    An IED (Intelligent Electronic Device) is a microprocessor-based device with some processing and communication capabilities. The biggest category of IEDs in a ...
  10. [10]
    ▷ What is an IED - Intelligent Electronic Device? - iGrid Smart Guide
    An IED (Intelligent Electronic Device) is a microprocessor-based power system equipment, like circuit breakers, providing control and automation functions.
  11. [11]
    None
    ### Summary of Key Characteristics of Multifunctional Protection IEDs
  12. [12]
    Advanced Power-Line Monitoring Requires a High-Performance ...
    Sep 26, 2008 · Today 16-bit resolution at sampling rates of 16ksps, or higher, is essential. To ensure accurate 3-phase and neutral wye system current and ...
  13. [13]
    [PDF] SIPROTEC 5 Communication Protocols
    You can define the structures of logical devices by adding user-defined logical devices. ... IED, you can simply copy the user-defined function (LN) and a user- ...
  14. [14]
    IED (Intelligent Electronic Device) advanced functions that make our ...
    Mar 8, 2020 · IEDs are devices that can be connected to a LAN and communicate with other devices over the LAN and have processing capabilities. A large number ...
  15. [15]
    [PDF] SEL APPLICATION GUIDE - Schweitzer Engineering Laboratories
    Each SEL IED runs continuous self-tests to monitor the internal health of its major components. If an out-of-tolerance condition is detected, the relay ...
  16. [16]
    [PDF] Digital Protection – Past, Present, and Future - cigre usnc
    Era of the invention of the digital relay. Late 1960s – mainframe enterprise computers. ▫. Centralized processing. ▫. Office environment. ▫. A lot of support.
  17. [17]
    [PDF] UNDERSTANDING MICROPROCESSOR-BASED TECHNOLOGY ...
    In early 1960's, advances in the integration of electronic circuits made this technology suitable for use in relays. The major advantage of these relays was ...<|separator|>
  18. [18]
    A Brief History of Electric Utility Automation Systems
    Apr 3, 2010 · This general overview presents a history of Electric Utility Operational Control Systems. It spans from the early adaptation to the current era of the Smart ...
  19. [19]
    [PDF] Special Report Medium-voltage products - ABB
    Further progress led to multifunction relays in the late 1980s. This led to significantly en- hanced network protection and control. ABB took a leading role in ...
  20. [20]
    understanding microprocessor-based technology applied to relaying
    In the late 1980's Multifunction digital relays were introduced to the market [13] . These devices reduced the product and installation cost drastically and ...
  21. [21]
    [PDF] Configuration and Setting Management for Protection and Control ...
    What condition(s) should trigger a relay to record the event? • Analog channels and digital elements to be included in the report and/or oscillograph records. A ...
  22. [22]
    Relay Testing - Test Sets and Testing Technology in the 1980s
    This device allowed simple and fast check of primary relays types MU, MT and MUT at nominal currents of 300 A with testing values of up to 2000A.Missing: IED | Show results with:IED
  23. [23]
    Modbus - an overview | ScienceDirect Topics
    Modbus has been widely adopted as a de facto standard and has been enhanced over the years into several distinct variants. Modbus' success stems from its ...
  24. [24]
    IEC TR 61850-1:2003
    A technical report applicable to substation automation systems. Defines the communication between intelligent electronic devices in the substation.
  25. [25]
    [PDF] IEC 61850: What You Need to Know About Functionality and ...
    Peer-to-peer communications are accomplished through direct physical connections or via a virtual direct connection passing through multiple network connections ...
  26. [26]
    A New IED With PMU Functionalities for Electrical Substations
    Aug 6, 2025 · This paper proposes a new distributed architecture to measure synchrophasors in power substations, inspired by the standards IEC 61850.
  27. [27]
    [PDF] Integration of Substation IED Information into EMS Functionality
    • Sensing current and voltage levels by transforming power level analog signals to instrument level signals using current and voltage instrument transformers or.
  28. [28]
    A cybersecurity assessment for hybrid virtualized-physical digital ...
    The virtualization of intelligent electronic devices (IEDs) is thought to enable more flexible and agile cybersecurity software updates and patching processes ...Missing: enhancements | Show results with:enhancements
  29. [29]
    Cybersecurity tool integration challenges with IEDS in digital… - bba
    The approach is to identify gaps in tool/solution functionality, interoperability issues with Intelligent Electronic Devices (IEDs) or technology enhancements ...
  30. [30]
    Cybersecurity Enhancement of Smart Grid: Attacks, Methods, and ...
    Nov 23, 2022 · This paper focuses on providing an extensive survey on defense mechanisms that can be used to detect these types of cyberattacks and mitigate the associated ...
  31. [31]
    [PDF] Fault Prediction and Diagnosis of Power Electronic Systems in ...
    This paper has provided a comprehensive review of the fault prediction and diagnosis technologies for AI-driven power electronic systems within smart grids.
  32. [32]
    Intelligent Electronic Devices Unlocking Growth Potential: Analysis ...
    Rating 4.8 (1,980) Sep 19, 2025 · 2023: Siemens launches a new series of IEDs with enhanced AI capabilities for predictive fault analysis. · 2022: General Electric introduces ...
  33. [33]
    [PDF] Testing and analysis of an intelligent electronic device (IED ...
    Nov 30, 2020 · custom peripheral (PMODs) system implementation, and a data sampling rate of. 50 kHz. 3.2.2 Peripheral Modules (PMODs). In this study, two ...
  34. [34]
    SEL-751 Feeder Protection Relay
    The SEL-751 Feeder Protection Relay is ideal for directional overcurrent, fault location, arc-flash detection, and high-impedance fault detection ...
  35. [35]
    [PDF] Firmware Analyzer of Intelligent Electronic Devices in Substations ...
    Sep 30, 2025 · This study aims to contribute to the early detection and management of security vulnerabilities in energy infrastructures via. IEDs, while also ...
  36. [36]
    Securing Firmware in IoT Devices - eInfochips
    Dec 22, 2023 · Secure Boot and Update: Secure boot is a process that ensures only trusted and digitally signed firmware can be loaded and executed on the ...<|control11|><|separator|>
  37. [37]
    [PDF] Performance Assessment of Advanced Digital Measurement and ...
    Jul 22, 2006 · Intelligent Electronic Devices (IED) are versatile computer-based devices employed in ... algorithms are. Fourier transform, Differential ...
  38. [38]
    [PDF] Performance evaluation of measurement algorithms used in IEDs
    These IEDs use a series of mathematical algorithms for fault detection and execute various protection functions. The first and essential mathematical algorithm ...
  39. [39]
    IED User software | Schneider Electric USA
    Configuration software for protective relays Simplify configuration, testing, integration, and maintenance in your electrical substations. Receive robust ...Missing: GE | Show results with:GE
  40. [40]
    [PDF] Integrated Substation Control System (iSCS) - GE Vernova
    The IED Loader configuration software leverages IEC 61850 self-description capabilities and configuration techniques to quickly and easily set up the D400 for.
  41. [41]
    [PDF] Buyer's Guide Transformer protection IED RET 670 - Electro Services
    Buffer capacity. Maximum number of events in the list. 1000. Resolution. 1 ms. Accuracy. Depending on time synchronizing. Function. Value. Buffer capacity.<|control11|><|separator|>
  42. [42]
    [PDF] Introducing Power System Event Report Data Into Plant Historian ...
    May 8, 2014 · One popular method for time synchronization is the direct connection of IEDs with Global. Positioning System (GPS) clocks using the IRIG-B ...
  43. [43]
    Line Differential Protection | Hitachi Energy
    Line differential protection measures current flowing into and out of a line, based on Kirchhoff's laws, and is unit protection. It requires high bandwidth ...
  44. [44]
    The essentials of directional overcurrent protection in electrical ...
    Feb 12, 2021 · Directional IEDs determine the direction of the fault current by measuring the voltage with a voltage transformer as well as the current with a current ...
  45. [45]
    Improvements in Line Differential Relays | PAC World
    Line differential protection provides important advantages over distance protection such as better resistive coverage; good dependability for cross-country ...
  46. [46]
    [PDF] Identifying the Proper Impedance Plane and Fault Trajectories in ...
    Conceptually, dividing the measured voltage phasor V by the measured current phasor I yields the impedance Z measured by the distance element, or apparent ...
  47. [47]
    Solving the architectural and reliability puzzle of a protection and ...
    May 27, 2019 · The zone of protection refers to that primary equipment for which faults are detected by a given protection scheme. The protection scheme is ...
  48. [48]
    Generator Protection - Types of Faults & Protection Devices
    Loss of field protection uses a relay that detects the change in reactive power flow. A typical loss of excitation protection scheme uses an Offset Mho ( ...
  49. [49]
    SEL-735 Power Quality and Revenue Meter
    The SEL-735 offers high-accuracy metering combined with detailed power quality analysis. With data available at their fingertips, operators can easily identify ...Missing: Intelligent | Show results with:Intelligent
  50. [50]
    [PDF] Metering Overview - Schweitzer Engineering Laboratories
    Achieve high-accuracy revenue metering under real- world power quality conditions. The SEL-735 Power Quality and Revenue Meter exceeds the ANSI C12.20-2015 0.1.Missing: functions SOE
  51. [51]
    ANSI C12.20-2015 - Electricity Meters - 0.1, 0.2, and 0.5 Accuracy ...
    Additional major changes to ANSI C12.20-2015 include testing under harmonic conditions, the addition of a 0.1% accuracy class, and the addition of ...
  52. [52]
    [PDF] TESLA 4000 IED Features and Applications in a Utility's Digital ...
    A digital fault recorder provides the required data for complete power system analysis in normal and abnormal conditions, including supervision of relay ...
  53. [53]
    https://library.e.abb.com/public/dc853877595c4086ae649ca29924c0ec/Paper_GOOSE%2520Utilisation%2520in%2520Protection.pdf
  54. [54]
    Toward a Substation Automation System Based on IEC 61850 - MDPI
    Jan 28, 2021 · IEC 61850 is a communication protocol for digitalizing substation automation, ensuring consistent communication between assets and intelligent ...
  55. [55]
    [PDF] Utilization of IEC 61850 GOOSE messaging in protection ... - ABB
    GOOSE communication improves reliability, reduces wiring, enables faster response times, and allows for more virtual inputs/outputs in protection applications.
  56. [56]
    [PDF] Substation Automation - The New Digital Substation - Cisco
    GOOSE uses short informational messages and GOOSE requirements specify a low probability of loss and a budget delay of only a few milliseconds. GOOSE is one of ...
  57. [57]
    Substation Automation Systems (SAS) and SCADA - OMICRON
    Remote terminal units (RTU), intelligent electronic devices (IED), and the communication network are essential systems as well. To maximize availability of the ...
  58. [58]
    None
    ### Summary of IED Implementation for Breaker Failure Protection in PG&E 500 kV Substation
  59. [59]
    [PDF] Line Differential Protection and Control RED615 Product Guide - ABB
    RED615 is a phase-segregated two-end line differential protection and control IED. (intelligent electronic device) designed for utility and industrial power ...
  60. [60]
    Line differential and distance protection – SIPROTEC 7SL86
    SIPROTEC 7SL86 is a combined phase-selective line differential and distance protection for overhead lines and cables with single-ended and multi-ended ...Missing: Intelligent | Show results with:Intelligent
  61. [61]
    RES670 - Phasor measurement unit - Hitachi Energy
    The RES670 Intelligent Electronic Device (IED) provides power system AC voltages and currents as phasors - up to 32 analog phasors in two different data ...
  62. [62]
    PMU-based dynamic state estimation for electric power systems
    This paper provides a methodology to extract the dynamic real time model of an electric power system using phasor measurement unit (PMU) data ...Missing: IED | Show results with:IED
  63. [63]
    [PDF] Feeder protection and control REF615 - ABB
    The IED also incorporates auto-reclose functions for arc fault clearance on overhead line feeders. Enhanced with optional hardware and software, the IED also.
  64. [64]
    [PDF] Distribution Feeder Fault Location Using IED and FCI Information
    This paper presents an automated fault location system for distribution networks. The system uses relays, recloser controls, and FCIs and is suitable for ...
  65. [65]
    [PDF] Using Protective Relays for Microgrid Controls
    Protective relays provide control and protection for microgrids, including islanding, reconnection, dispatch, load shedding, and are economical for smaller ...Missing: IED farms
  66. [66]
    [PDF] Impact of IEEE 1547 Standard on Smart Inverters and the ... - NREL
    This report discusses the impact of the IEEE 1547 standard on smart inverters and power systems, requested by the US DOE as part of a collaboration.
  67. [67]
    [PDF] Motor Protection and Control REM611 Product Guide - ABB
    REM611 is a motor protection and control IED for asynchronous motors, designed for protection, control, measurement and supervision. It is part of the 611 ...
  68. [68]
    Overview of DNP3 Protocol - DNP.org
    DNP3 was a (and is an ongoing) comprehensive effort to achieve open, standards-based Interoperability between substation computers, RTUs, IEDs.
  69. [69]
    https://claroty.com/team82/research/mms-under-the-microscope-examining-the-security-of-a-power-automation-standard
  70. [70]
    https://blog.nettedautomation.com/2011/01/what-are-clientserver-and.html
  71. [71]
    MMS Under the Microscope: Examining the Security of a Power ...
    Oct 8, 2024 · The MMS protocol, referenced also as ISO 9506, was developed by ISO in collaboration with IEC back in the 90's. The protocol is widely used by ...
  72. [72]
    Protocols applied for time synchronization in a digital substation ...
    May 22, 2019 · Normal standard protocols are SNTP for synchronizing IEDs at station level and IEEE 1588 PTP for synchronizing IEDs at bay and process level.
  73. [73]
    [PDF] DNP3 Intelligent Electronic Device (IED) Certification Procedure
    Sep 13, 2022 · This certification procedure is designed to determine an IED's compliance to one or all of. Subset Levels 1, 2, and 3 defined in IEEE 1815-2012.
  74. [74]
    UCAIUG Home | UCAIUG
    Welcome to the. UCA International Users Group. Enabling utility integration through open standards collaboration. Become a Member.
  75. [75]
    61850 Testing - UCA Testing
    Welcome to the IEC 61850 Testing page. This page contains public information related to the conformance testing of IEC 61850.
  76. [76]
    List of UCA IEC 61850 Certificates
    Jul 12, 2021 · The UCAIUG users group has reorganized the access to the 1200+ IEC 61850 certificates: Click HERE to freely access the certificates.
  77. [77]
    IEEE C37.118.1-2011 - IEEE Standards Association
    Dec 28, 2011 · This standard defines synchrophasors, frequency, and rate of change of frequency (ROCOF) measurement under all operating conditions.
  78. [78]
    IEEE C37.118.2-2024 - IEEE Standards Association
    Dec 13, 2024 · A method for the real-time exchange of synchronized phasor measurement data between power system equipment is defined within this standard.
  79. [79]
    DNP3 (IEEE Std 1815TM) Secure Authentication - EPRI
    Dec 22, 2014 · This report focuses on the Secure Authentication features of the standard (DNP3-SA), and provides guidelines on how utilities can best design, implement and ...Missing: IED | Show results with:IED
  80. [80]
    [PDF] Final report Standards for Smart Grids - ETSI
    ... IEC has developed a series of protocol suites that cover various sections of the smart grid landscape: IEC 61970, IEC 61968 and IEC 61850. These standards ...
  81. [81]
    Rolling the DICE on IEC 61850 - PAC World
    Using HMI and consolidating relay functions will reduce the panel space required for the control enclosure; Cutting the enclosure's footprint in half to 12 ...
  82. [82]
    Fully Utilizing the Intelligent Electronic Device Capability to Reduce Wiring in Industrial Electric Distribution Substations
    ### Summary of IEDs Reducing Wiring, Panel Space, and Cost in Substations
  83. [83]
    [PDF] Managing intelligent electronic devices | Eaton
    In this paper, we will discuss some of the basic functions required for managing large fleets of. IEDs, the solutions that have been developed to help utilities ...
  84. [84]
    Smart Grid Protection, Automation and Control: Challenges ... - MDPI
    Modular architectures allow scalability, upgrades, and improved cybersecurity. ... IRIG-B Time Code Accuracy and Connection Requirements with Comments on IED and ...
  85. [85]
    IED management software - Eaton
    Eaton's IED Manager Suite (IMS) software helps utilities manage configuration settings, passwords and firmware of the intelligent electronic devices (IEDs).
  86. [86]
    Stuxnet - SCADA malware - Palo Alto Networks
    Oct 3, 2010 · Stuxnet is the first malware in recent history that attacked industrial control systems also known as SCADA (Supervisory Control and Data Acquisition) systems.
  87. [87]
    [PDF] A Strategic Approach to Securing Intelligent Electronic Devices (IEDs)
    By proactively addressing these cybersecurity challenges, the proposed measures aim to enhance the resilience of electric dis- tribution systems, ensuring the ...Missing: enhancements | Show results with:enhancements
  88. [88]
    [PDF] — Protection and Control IED Manager PCM600 Cyber Security ...
    If the Secure Communication parameter is activated in the IED, protocols require TLS protocol based encryption method support from the clients. In case of file ...
  89. [89]
    IEC 61850 Improved Security with TLS 1.3 - MZ Automation
    Aug 16, 2024 · The adoption of TLS 1.3 in IEC 61850 and IEC 60870 protocols represents a significant advancement in the security of industrial communication systems.
  90. [90]
    [PDF] Technical Overview and Benefits of the IEC 61850 Standard for ...
    Intelligent Electronic Device (IED) and communication bandwidth is no longer a limiting factor. Substation to master communication data paths operating at ...<|control11|><|separator|>
  91. [91]
    [PDF] New Insights into IEC 61850 Interoperability and Implementation
    IEC 61850 is a standard that provides methodology and modelling of substation automation systems towards a full digital solution. Within IEC. 61850, the ...<|control11|><|separator|>
  92. [92]
    [PDF] Failure Modes in IEC 61850-Enabled Substation Automation Systems
    May 5, 2016 · Incorrect logic engineering causes the power system to incorrectly prevent or authorize requested commands. 1) Incorrect Configuration and ...
  93. [93]
    CMC 356 - Universal relay test set and commissioning tool
    Powerful six-phase relay testing and more. The CMC 356 is the universal solution for testing all generations and types of protection relays.Missing: end- end 60255
  94. [94]
    Protection Relay Testing - OMICRON
    Manufacturers of protection relays in turn test them for conformity, for example, with the IEC 60255 standard, which defines rules and requirements for the ...
  95. [95]
    IEC 60255-27 Protection Equipment EMC Compliance Testing
    The IEC 60255 test method is used to minimize the risk of fire hazards caused by electric shock or injury to the user. The product safety standard does not ...
  96. [96]
    [PDF] Final Report on the August 14, 2003 Blackout in the United States ...
    Dec 24, 2003 · The report makes clear that this blackout could have been prevented and that immediate actions must be taken in both the United States and ...<|control11|><|separator|>