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Electronic switching system

An electronic switching system (ESS) is a telecommunications technology that uses solid-state electronics, including digital circuits and stored program control (SPC), to automate the routing, connection, and management of telephone calls, replacing electromechanical switches with faster, more reliable computer-controlled operations.^[1] Introduced in the mid-20th century, ESS revolutionized telephony by enabling scalable call handling for voice, data, and later multimedia services through techniques like space division switching (using fixed electronic crosspoints) and time division switching (multiplexing signals in time slots).^[2] The development of ESS began at Bell Laboratories in the late 1940s, as engineers sought to integrate transistors and electronic components into switching to address the limitations of step-by-step and crossbar electromechanical systems, which were prone to wear and slow in processing growing call volumes.^[3] Following a successful trial in Morris, Illinois, in 1960, and after over a decade of research costing approximately $500 million, the first large-scale ESS for central offices, designated No. 1 ESS, was deployed by AT&T in Succasunna, New Jersey, in May 1965, marking the transition to computer-controlled telephony with features like dual-processor redundancy for high availability and minimal downtime.^[4] Early ESS variants included the No. 101 ESS for private branch exchanges (PBXs) in 1963, the No. 1 ESS in 1965, and digital systems like No. 4 ESS introduced in 1976, which expanded capabilities to support integrated services digital network (ISDN), cellular integration, and eventually IP-based communications.^[2] Key advantages of ESS include enhanced speed for call setup (often in milliseconds), greater flexibility for advanced features like call forwarding and conference calling, and improved scalability for networks handling thousands to hundreds of thousands of lines.^[1] By the 1980s, ESS had become the backbone of global telecommunications infrastructure, facilitating the shift from analog to digital transmission and enabling common channel signaling for efficient traffic management.^[3] Today, while largely evolved into software-defined networking and VoIP systems, the principles of ESS underpin modern switching architectures in 5G and beyond.^[2]

Overview

Definition and scope

An electronic switching system (ESS) is a telephone switch that employs solid-state electronics, including digital circuits and stored program control (SPC), to interconnect telephone lines and trunks for call routing, primarily using solid-state electronics to replace traditional mechanical components.^[5] This technology automates the detection of service requests, digit interpretation, connection establishment, and disconnection, enabling efficient processing within the public switched telephone network (PSTN).^[5] The scope of ESS primarily encompasses implementations developed by the Bell System for central office applications in the PSTN, supporting both local and toll switching with scalability for varying office sizes.^[5] Internationally, analogous systems include Ericsson's AXE, a modular digital circuit-switching platform designed for flexible deployment across diverse national networks,^[6] and Northern Telecom's Digital Multiplex System (DMS), a family of carrier-class switches for wireline telephony.^[7] These systems share the core principle of electronic control to handle voice and data services, though variations exist in architecture and features tailored to regional standards. ESS emerged in the 1960s as a technological advancement to supplant earlier step-by-step and crossbar electromechanical switches, addressing demands for greater reliability, speed, and service flexibility in expanding telephone networks.^[5] At its foundation, an ESS incorporates a central processing unit for real-time control, memory units such as program store for permanent logic and call store for transient data, and interfaces to subscriber lines and trunks via scanners and distributors.^[5] Stored program control underpins this architecture, allowing software-driven adaptability without hardware reconfiguration.^[5]

Comparison to electromechanical switching

Electromechanical switching systems in telephony fundamentally relied on physical components, such as relays, uniselectors, and crossbar switches, to establish and route telephone connections based on dial pulses or signals. These systems, exemplified by step-by-step and panel configurations, involved mechanical movements to select paths, which generated electrical noise from arcing contacts and imposed physical limits on scalability due to the bulk and complexity of wiring and hardware.^[8] In contrast, electronic switching systems (ESS) utilize solid-state electronic logic circuits, replacing mechanical actions with semiconductor-based processing to achieve call switching in milliseconds rather than the hundreds of milliseconds to seconds typical of electromechanical setups. The absence of moving parts in ESS eliminates wear-related issues, substantially reducing maintenance requirements and enabling greater reliability through automated fault detection and self-diagnostics. Additionally, the programmability inherent in ESS, facilitated by stored program control, allows for flexible implementation of advanced features like call forwarding without hardware alterations, a capability absent in rigid electromechanical designs.^[5] Performance-wise, ESS supports far higher call volumes, accommodating thousands of lines per switch—up to 65,000 in large configurations—with processing speeds measured in microseconds for control cycles, compared to the slower relay-driven operations in electromechanical systems that limited capacities to around 10,000 lines in advanced crossbar setups. Failure rates in ESS are markedly lower, with electronic circuits achieving fewer than 10 failures per billion device-hours and overall system outages confined to minutes over decades of operation, whereas electromechanical systems suffer from mechanical vulnerabilities such as stuck relays or contact failures, leading to more frequent disruptions.^[5]^[8] Economically, while ESS incurred higher upfront costs due to the novelty of semiconductor technology in the mid-20th century, these were offset by long-term efficiencies in space, energy, and upkeep; ESS occupies significantly less floor area with compact frames and consumes roughly one-tenth the power of equivalent electromechanical crossbar systems, often under 1,000 watts for core controls versus higher relay-powered demands, translating to reduced operational expenses over time.^[5]

History

Early development and research

The development of electronic switching systems originated in the 1940s and 1950s at Bell Laboratories, where researchers sought alternatives to electromechanical relays plagued by mechanical wear, limited speed, and high maintenance needs.^[3] Initial experiments focused on applying electronic computing principles to telephony, leveraging vacuum tube-based calculators like the Ballistic Computer (1937) and Complex Number Calculator (1939) to explore digital control for switching functions.^[9] The pivotal breakthrough came in 1947 with the invention of the point-contact transistor by John Bardeen, Walter Brattain, and William Shockley, which promised to replace unreliable, power-hungry vacuum tubes with solid-state devices capable of reliable signal amplification and switching in telephone networks.^[10] By the mid-1950s, Bell Labs intensified efforts on transistorized systems, culminating in the 1958 experimental electronic switching system conceptualized for a trial in Morris, Illinois. This prototype employed transistors and diodes for central control logic, marking a shift toward stored-program architectures while retaining analog voice paths switched via gas-filled diodes.^[11] The design emphasized compact, low-power operation, with the control unit processing dialed digits and call setups electronically to handle up to 600 lines. Key contributors included A. E. Joel Jr., who led the Morris project and advanced semiconductor-based control, alongside teams developing transistor logic; notable among them was J. H. Vogelsong, whose work on transistor pulse amplifiers and regeneration circuits in the 1950s enabled robust digital processing for switching applications. These efforts built on broader Bell Labs initiatives, including contributions from R. W. Ketchledge and H. N. Seckler in memory and control design. The transition from vacuum tubes to transistors in the 1950s provided reliable electronic control by reducing power consumption and heat, allowing lab prototypes to be tested by 1960.^[3] Major challenges included mitigating signal noise in early transistor circuits, addressed through improved impurity diffusion and protective designs to achieve low leakage and stable amplification.^[12] Integration with existing analog phone lines required hybrid approaches, such as transistorized digital logic overseeing analog crosspoint switching, ensuring compatibility without full network overhaul.

Key deployments and milestones

The first commercial deployment of an electronic switching system occurred with the No. 1 Electronic Switching System (1ESS), installed by the Bell System in Succasunna, New Jersey, on May 30, 1965, initially serving a 4,000-line central office.^[13] This marked the transition from electromechanical to stored-program electronic control in public telephone networks, following years of laboratory development at Bell Laboratories.^[14] By the late 1960s, ESS adoption accelerated within the United States, with several No. 1 ESS offices in service by 1970, reflecting rapid expansion to handle growing urban demand for reliable switching.^[15] Internationally, the United Kingdom achieved its first production electronic exchange with the TXE2 system entering service at Ambergate, Derbyshire, on December 15, 1966, a reed-relay-based design for small to medium offices that paved the way for broader European adoption.^[16] In Japan, Nippon Electric Company (NEC) deployed the D-10 ESS, the country's first commercial electronic switching system, at the Ginza Central Office in Tokyo on June 1, 1971, supporting high-traffic urban lines and contributing to nationwide direct dialing goals.^[17] A major milestone came in 1976 with the introduction of the No. 4 ESS, the first digital time-division toll switching system, placed into service on January 17 in Chicago, Illinois, replacing older 4A crossbar offices and enabling efficient handling of up to 100,000 trunks for long-distance traffic.^[18] This deployment, part of a four-office rollout that year, integrated electronic switching into the core of the Bell System's intertoll network.^[19] The 1980s saw global proliferation of ESS technologies, with over 3,700 electronic switching offices serving more than 60 million lines worldwide by 1985.^[20] Regulatory events further shaped adoption: The Federal Communications Commission granted approvals for early ESS trials in the mid-1960s, facilitating U.S. rollout, while the AT&T divestiture on January 1, 1984, broke up the Bell monopoly, allowing regional operating companies to diversify vendors and accelerating competition in electronic switching equipment supply.^[21]

Technical principles

Stored program control

Stored program control (SPC) in electronic switching systems utilizes a general-purpose computer to store and execute the instructions for switching operations in software, rather than relying on hardwired logic as in electromechanical systems. This paradigm shift enables the control logic to be centralized and programmable, allowing the system to manage call processing, diagnostics, and maintenance through a stored program in memory. The approach originated in Bell Labs' designs for systems like the No. 1 ESS, where the program consists of over 100,000 instructions, each 44 bits long, compiled using tools like the PROCESS III assembler.^[5]^[22] Implementation centers on a central processing unit (CPU), exemplified by the custom processor in the No. 1 ESS, which features a 5.5-microsecond cycle time driven by a 2-megacycle oscillator and supports 24-bit words with 37-bit instructions augmented by Hamming error-checking bits. This CPU runs a real-time, interrupt-driven operating system with a hierarchy of 9-10 priority levels, handling tasks from high-frequency scanning (every 5 milliseconds) to longer-interval maintenance, all without gaps in execution. The program resides in semipermanent twistor memory, providing 5.8 million bits across 131,072 parallel 44-bit words, while temporary call data uses call store buffers; the entire setup occupies duplicated subsystems across four bays with approximately 2,800 printed wiring boards for fault tolerance.^[5]^[23] The call handling process begins when an incoming signal, such as an off-hook detection, interrupts the CPU, prompting it to scan line and trunk matrices via ferrod sensors in 1,024-point groups every 5-100 milliseconds and queue changes in hoppers for processing. The processor then accesses routing tables, translation data, and digit analysis programs in memory to select trunk groups and hunt for available paths, issuing orders through peripheral buffers to configure the switching network and establish connections. Throughout the call, the system monitors state via continuous scanning, match circuits comparing duplicated controls every cycle, and emergency timers (e.g., 40 milliseconds) to detect anomalies and maintain supervision.^[5] Unique advantages of SPC include the ease of implementing new features, such as call transfers or tariff adjustments, via software updates to the stored program without hardware alterations, thereby reducing costs and enhancing adaptability over the system's life. Fault-tolerant duplication of control units further ensures reliability, with parallel processors operating in match mode to identify mismatches and switch to standbys in seconds, achieving downtime of less than a few minutes per year.^[24]^[25]

Electronic switching mechanisms

In early electronic switching systems (ESS), core hardware for low-power switching consisted of ferrite reed relays, known as "remreed" crosspoints, which utilized 238A remanent reed contacts made from Remendur alloy for self-latching operation without separate magnetic plates, enabling compact design and high reliability with failure rates as low as 1.6 failures in 10^9 hours.^[26] These relays operated via differentially wound coils—64 turns for the primary and 31 for the secondary—controlled by 4-ampere pulses of 4 milliseconds to establish connections, followed by a 1-millisecond prerelease pulse for reliable opening.^[26] For analog signals, space-division multiplexing formed the basis of switching, employing metallic networks with physical path separation for channel isolation, organized into grids such as 8x8 arrays in 296C switches or concentrators with 2:1 and 4:1 ratios (e.g., 12A grids with 32 inputs to 16 outputs), reducing floor space requirements by a factor of 4 compared to electromechanical systems.^[26] The signal path in these systems relied on electronic crosspoints to connect subscriber lines and trunks, implemented as transistor matrices using PNPN switching transistors and diodes for pulse steering, with each crosspoint requiring only 5 milliamperes gate current and 16 milliamperes latch current to form unique paths in switch packages.^[26] Tip-and-ring conductors were routed via printed wiring paths on circuit boards, with inter-crosspoint spacing of 0.450 inches and maximum path lengths around 18 feet in trunk link networks to minimize crosstalk.^[26] In later digital ESS variants, time-division multiplexing replaced space-division for signal paths, using solid-state crosspoint logic gates in 256x256 arrays organized into 16x16 stages within time-multiplexed switches, supporting pulse-code modulation (PCM) at 64 kilobits per second per channel over formats like DS-1 (1.544 megabits per second, 24 channels) and DS-120 (8.192 megabits per second, 120 channels).^[27] These digital crosspoints, housed in time-slot interchange units, enabled non-blocking networks with up to 135,000 paths, converting analog signals via voiceband interfaces and multiplexing five DS-1 signals into 120-channel streams for efficient trunk handling.^[27] Interface layers managed subscriber and inter-office connections, with line scanners employing ferrod devices—such as 2A line ferrods—to detect off-hook conditions by monitoring loop current on up to 1,024 scan points, halting scanning upon detection and integrating duplicated controllers for continuous operation.^[26]^[28] Ringers for alerting subscribers were driven through these line interfaces, which applied ringing voltage to idle lines under control signals, while trunk interfaces handled inter-office links by terminating two-wire or four-wire voice-frequency trunks on digroup terminals, supporting both analog and digital carrier signals with built-in alarm detection and conversion to time-division formats via buffer interfaces to accommodate phase differences.^[27] These mechanisms operated under oversight from stored program control to establish and maintain connections. Redundancy features ensured fault tolerance through dual-path switching, with duplicated controllers in home/mate configurations for line scanners and switching fabrics, allowing automatic failover if one path fails by isolating faults and rerouting via the alternate, while modular grid designs with connectorized components permitted rapid replacement of faulty units without service interruption.^[26] Control circuits affecting more than 64 lines or trunks were fully duplicated, partitioning the fabric to limit fault impact to small segments and supporting path checks with 120-milliamperes triggers for continuity verification.^[26]

Major systems

No. 1 ESS and early variants

The No. 1 Electronic Switching System (No. 1 ESS), developed by Bell Telephone Laboratories and manufactured by Western Electric Company, entered commercial service on May 30, 1965, in Succasunna, New Jersey, marking the first large-scale deployment of stored-program control for local telephone central offices. It employed duplicated central processors with a 5.5-microsecond cycle time driven by a 2-megacycle oscillator, enabling real-time call processing through electronic logic circuits and ferrite-core memory. The switching fabric consisted of an eight-stage space-division network using ferreed switches—reed relays integrated with ferrite cores for magnetic latching and nonvolatile selection—arranged in matrices to connect lines and trunks efficiently. Designed for scalability, the system supported up to 65,000 lines with 4:1 concentration, though typical installations served around 10,000 lines in urban end offices.^[5] Key operational features focused on reliable basic call handling, including digit analysis for intra-office and outgoing routing, path hunting for alternate connections, and support for both dial pulse and multifrequency (TOUCH-TONE) signaling via originating registers and scanners. Billing was managed through automatic message accounting (AMA), which recorded call details such as originating and terminating numbers, answer time, and disconnect on magnetic tape for later processing, handling up to 144,000 calls per hour per tape reel in larger configurations. The system achieved a busy-hour capacity of approximately 100,000 calls for a 10,000-line office, equivalent to about 28 calls per second, with high-priority scanning cycles every 5 milliseconds to ensure timely supervision of lines and trunks. Duplication of critical components, including processors and power supplies, provided fault tolerance, with match circuits detecting errors for automatic switching to standby units.^[5] Early variants in the 1970s extended the No. 1 ESS design to meet diverse office sizes and performance demands while retaining its analog architecture. The 1AESS, introduced in 1976 as a plug-compatible upgrade, incorporated the 1A processor—a faster central processing unit with improved instruction set and memory management—along with smaller remreed switches (replacing ferreeds for reduced size and cost) and fewer electromechanical relays, boosting overall capacity to up to 107,000 network terminations and 550,000 switched attempts per hour. This variant enhanced software flexibility for maintenance and administration, using multi-branched lists for efficient call data handling and supporting modular trunk assignments in metropolitan environments. The No. 3 ESS, also rolled out in the mid-1970s for smaller rural and suburban offices, featured a compact configuration optimized for lower traffic, accommodating up to 5,800 lines and trunks combined, with simplified peripherals and the same duplicated processor principles to minimize footprint and power requirements. Both variants remained limited to analog voice switching, lacking digital signal processing, which constrained their adaptability to emerging data services and contributed to higher upfront hardware costs due to extensive custom circuit packs and cabling.^[19]^[29]

No. 4 ESS and toll switching

The No. 4 Electronic Switching System (4ESS), introduced by AT&T in 1976, represented a pioneering advancement in digital toll and tandem switching, designed specifically for high-volume long-distance traffic in the Bell System network. Deployed initially in Chicago on January 17, 1976, it replaced older electromechanical systems like the No. 4A Crossbar with a fully digital architecture capable of handling significantly greater call volumes while reducing space and operational costs.^[19] As the first large-scale digital toll switch, the 4ESS utilized time-division multiplexing (TDM) based on pulse-code modulation (PCM) at 64 kb/s, enabling efficient switching of voice and data signals across extensive trunk networks. Its design supported up to 107,520 four-wire trunk terminations, far exceeding the capacities of prior analog systems and allowing it to process peak loads of up to 550,000 call attempts per hour.^[19] At its core, the 4ESS featured a centralized digital switch fabric composed of time-slot interchange (TSI) units and time-multiplexed switch (TMS) frames, which facilitated non-blocking connections through high-speed digital multiplexing at rates like 8.192 Mb/s for 120 channels. This architecture integrated with peripheral units for trunk interfaces and supported advanced signaling protocols, including Common Channel Interoffice Signaling (CCIS) and later upgrades to Signaling System No. 7 (SS7) for enhanced call routing, database queries, and network management.^[19] The system's stored-program control, powered by duplicated processors, ensured high reliability with automatic recovery features, while its modular design allowed for scalable growth from initial configurations of around 9,000 trunks to full capacity.^[19] Key capabilities of the 4ESS extended to handling international gateway traffic, where it supported up to eight numbering plan areas with seven-digit dialing and incorporated digital echo cancellation through signal processing to maintain call quality over long distances. In the 1980s, the system was upgradable to integrate with emerging fiber-optic transmission networks, as demonstrated by AT&T's 1983 deployment of fiber links between Washington, D.C., and New York City to interconnect 4ESS toll switches, enabling fully digital end-to-end paths with higher bandwidth and reduced latency.^[19] By the early 1990s, over 100 units of the 4ESS had been deployed across AT&T's long-distance network, with 114 switches operational as of January 1990, forming the backbone for inter-city and international call routing in the United States. These installations, primarily in major metropolitan areas, handled millions of calls daily and underscored the system's role in modernizing toll services until the rise of next-generation digital platforms.^[30]^[31]

5ESS and digital evolution

The 5ESS (Number 5 Electronic Switching System), introduced by AT&T in March 1982 with its first deployment in Seneca, Illinois, represented a significant advancement in digital switching technology through its modular architecture.^[20] This design featured three primary components: the Administrative Module (AM) for centralized control, including administration, maintenance, routing, and billing functions powered by duplicated AT&T 3B20D processors; the Communications Module (CM) for inter-module messaging and time-multiplexed switching via fiber-optic links and Intel 8086 microprocessors; and Switching Modules (SMs) for local call processing and line/trunk interfaces, each supporting up to 512 lines.^[20] The modular approach enabled scalable growth from single-module to multimodule configurations, facilitating efficient expansion in central offices.^[20] Over its evolution, the 5ESS transitioned to a fully software-defined platform capable of integrating voice and data services, supporting interfaces for Integrated Services Digital Network (ISDN) with 64-kb/s clear-channel capability, fiber-optic transmission for remote units, and wireless mobile switching center (MSC) functions compliant with digital cellular standards such as IS-54 and IS-136.^[20]^[32] These enhancements, including precursors to packet switching through simultaneous circuit- and packet-switched data handling, allowed the system to accommodate emerging telecommunications demands like end-to-end digital connectivity and T1-carrier facilities.^[20] The 5ESS-2000 variant, introduced in the 1990s, further optimized this by increasing peripheral module density and processing efficiency for mixed wireline and wireless traffic.^[33] In terms of capacity, the 5ESS could scale to handle up to 200,000 lines in large deployments, with individual SMs and Remote Switching Modules (RSMs) supporting thousands of lines each, often up to 4,000 in remote configurations located as far as 125 miles from the host.^[34] This made it suitable for both urban central offices and distributed networks, processing busy-hour call volumes exceeding 300,000.^[20] The 5ESS achieved substantial global impact through international licensing, notably to Alcatel-Lucent, enabling deployments across North and South America, Europe, and Asia for both wireline and wireless applications.^[35] By the early 2000s, it powered over 100 million operational lines worldwide, underscoring its role in the digital evolution of public switched telephone networks.^[33]

Advantages and applications

Reliability and efficiency gains

Electronic switching systems marked a substantial improvement in reliability over electromechanical predecessors like crossbar systems, primarily through redundant duplicated central controls, match circuits for fault detection, and error-correcting codes such as Hamming code in program stores. The No. 1 ESS was designed for outages limited to a few minutes over a 40-year design life through duplication and automated recovery, enabling high availability.^[5] Automatic diagnostic programs, occupying about half of the stored instructions, isolated faults to replaceable circuit packs and recovered call processing within 40 milliseconds, reducing annual downtime to less than 1%.^[5]^[36] Efficiency gains stemmed from the solid-state electronic design, which minimized mechanical components and enabled compact, high-density packaging. The No. 1 ESS required approximately one-tenth the floor space and volume of equivalent electromechanical systems, fitting into as little as 2,000 square feet for a 10,000-line office using standard 7-foot frames.^[5] Energy consumption was lowered through low-power logic circuits (37-140 mW per circuit, averaging 76 mW) and unregulated battery operation, with program stores drawing about 1,000 watts and no need for air conditioning in key components.^[5] Call setup times improved through high-speed ferreed switches and centralized processing that operated 1,000 to 10,000 times faster than relays.^[5] Maintenance was revolutionized by stored-program diagnostics, self-checking circuits, and automated recovery, allowing the system to quarantine faulty units without service interruption. Remote software updates were enabled via card writers for program stores and recent-change memory for subscriber data, with verification processes completing in 12-18 hours for a typical office.^[5] Self-healing features, including interrupt-driven scanning and exercise programs, supplemented hardware parity checks, while centralized monitoring through operations support systems (OSS) interfaces like teletypewriters provided real-time fault reporting and isolation to plug-in packs.^[5]^[36] Cost analyses demonstrated economic advantages for ESS deployments, driven by lower labor requirements for maintenance (due to automation reducing on-site interventions) and reduced parts costs from mass-produced circuit packs and fewer mechanical relays.^[5] Overall, these gains lowered operational expenses by minimizing wiring changes, enabling advance manufacturing, and supporting unattended operation in central offices.^[5]

Introduction of advanced features

The introduction of stored program control (SPC) in electronic switching systems (ESS) fundamentally enabled the deployment of user-oriented features that were impractical or impossible in electromechanical switches, allowing software modifications to implement services without hardware changes. Core features such as call forwarding, which permitted users to redirect incoming calls to a preselected number via a dial code, and conference calling, supporting up to four participants through switchhook operations and dialing, were realized in early trials like the No. 1 ESS Morris office in 1965. Similarly, speed dialing, or abbreviated dialing, allowed subscribers to store up to four frequently called numbers accessible via two-digit codes, reducing dialing time and enhancing usability; these were supported by the twistor memory and program store holding 5.8 million bits for call processing logic.^[37] Building on this programmability, ESS facilitated advanced services tailored for business environments, notably Centrex, which emulated private branch exchange (PBX) functionality by providing direct inward dialing to extensions, identified outward calling, and attendant features without dedicated on-site equipment. Deployed in systems like the No. 101 ESS trial, Centrex leveraged time-division switching and SPC to support multiple PBX units economically, enabling scalable corporate telephony. In the 1970s and 1980s, ESS evolutions supported integrated services like ISDN for voice and data.^[37] A key advancement was the integration of common channel signaling (CCS), which separated control signals from voice paths to improve efficiency and enable intelligent network features. In the No. 4 ESS, introduced in 1976, Common Channel Interoffice Signaling (CCIS) was implemented as an integral component, using dedicated channels for interoffice communication to support faster call setup and advanced routing; this system linked toll offices and formed the basis for broader CCS adoption. By the 5ESS era in the early 1980s, full Signaling System No. 7 (SS7) compatibility was incorporated, allowing out-of-band signaling for services like caller ID and database queries in intelligent networks, enhancing overall system intelligence and interoperability.^[38] SPC's flexibility extended to customization, where telephone operating companies could define and modify features through software updates, accommodating regional needs and service variations without physical reconfiguration. For instance, program stores in No. 1 ESS allowed operators to tailor call handling logic, such as adjusting abbreviated dialing lists or conference limits, fostering localized innovations while maintaining network-wide compatibility. This operator-definable approach, rooted in the magnetic latching relays and program organization of early ESS, marked a shift toward adaptable telecommunications infrastructure.^[37]

Legacy and transition

Phase-out in modern networks

Electronic switching systems (ESS), once central to the Public Switched Telephone Network (PSTN), reached their peak deployment in the United States during the 1990s, handling the majority of voice traffic through systems like the No. 1 ESS, No. 4 ESS, and No. 5 ESS. Widespread replacement accelerated in the 2000s as telecommunications providers adopted softswitches and IP-based architectures to support emerging voice over IP (VoIP) services. By the mid-2010s, major operators had begun systematic decommissioning, with the transition intensifying amid the global PSTN sunset initiatives. As of 2025, fewer than 10% of U.S. telephone lines remain connected to legacy ESS infrastructure, reflecting the near-complete migration to digital and packet-switched networks. The last confirmed retirements of 5ESS systems occurred in 2024, with the technology likely no longer in service worldwide as of mid-2025.^[39]^[40]^[41] The primary drivers for phasing out ESS include fundamental incompatibilities with modern protocols such as VoIP and 5G integration, which demand flexible, software-defined networking rather than rigid, hardware-centric TDM (time-division multiplexing) designs. Aging hardware exacerbates these challenges, with maintenance costs soaring due to scarce replacement parts—often sourced from secondary markets like eBay—and the expiration of vendor support contracts. For instance, AT&T declined to renew support for its remaining No. 1A ESS systems with Alcatel-Lucent in 2015, citing unsustainable economics for systems installed decades earlier. These factors have rendered ESS inefficient for handling the convergence of voice, data, and multimedia services in contemporary networks.^[40]^[39] A prominent case study is AT&T's migration to IP networks, part of its broader Project VIP initiative, which targeted completion of the IP transition by 2020. The company decommissioned its last No. 1A ESS switch in Odessa, Texas, on June 3, 2017, shifting customers to packet-based alternatives like Genband G5/G6 platforms. By the early 2010s, AT&T had trialed full IP migrations in select wire centers, retiring TDM equipment amid declining demand—over 70% of residential users in 22 states had abandoned legacy services. Internationally, confirmed deployments of ESS remain limited, primarily in legacy North American contexts, with no widespread holdouts documented in developing regions as of 2025.^[40]^[39]^[42] Despite the phase-out, select ESS installations are preserved for niche applications requiring analog POTS lines, such as elevator emergency phones, fire alarms, and legacy fax systems that cannot yet transition to digital alternatives. Additionally, historical preservation efforts have salvaged complete systems for educational and museum purposes; in June 2023, a No. 5 ESS switch was removed from a rural U.S. telephone company and relocated for posterity by the Telephone World organization, ensuring documentation of this foundational technology. These remnants underscore ESS's enduring, albeit specialized, role amid the dominance of IP-centric telecommunications.^[40]^[43]

Influence on contemporary telecommunications

The principles of Stored Program Control (SPC) pioneered in early Electronic Switching Systems (ESS) laid the groundwork for contemporary softswitches and Software-Defined Networking (SDN) architectures in Voice over IP (VoIP) and IP Multimedia Subsystem (IMS) networks. By centralizing control logic in software rather than hardware, ESS enabled flexible call routing and resource management, a concept directly mirrored in softswitches that decouple signaling from media gateways to support scalable IP-based telephony. This evolution allows SDN controllers to dynamically orchestrate network resources, enhancing efficiency in IMS environments where multimedia sessions are managed across heterogeneous networks.^[44] The widespread deployment of ESS significantly influenced ITU-T standardization efforts for digital switching, particularly through the development of Signaling System No. 7 (SS7) protocols, which provided out-of-band signaling for reliable call setup in digital PSTNs. As ESS systems transitioned networks to fully digital operation, SS7 became essential for inter-switch communication, later evolving into SIGTRAN to transport SS7 messages over IP for hybrid circuit- and packet-switched infrastructures. These standards ensured interoperability in modern core networks, facilitating seamless migration from legacy to IP domains.^[45] ESS's digital framework was instrumental in enabling the convergence of voice and data services, allowing unified transmission over shared infrastructure and reducing the silos between circuit-switched telephony and packet-based data networks. This integration influenced the architecture of Mobile Switching Centers (MSCs) in Global System for Mobile Communications (GSM) and 4G Long-Term Evolution (LTE) networks, where MSCs employ SPC-like digital switching to handle circuit-switched voice alongside evolving packet cores for data. In rural telecommunications, hybrid configurations blending legacy ESS components with IP overlays persist to deliver cost-effective connectivity in underserved regions, maintaining reliability without full infrastructure overhauls.^[46]^[47]^[48] The software-centric ethos of ESS endures in cloud telephony platforms such as Amazon Connect, which virtualizes traditional switching functions to provide scalable, on-demand contact center services integrated with legacy systems. By emulating ESS's programmable control in a cloud-native environment, these platforms support advanced features like intelligent routing and analytics, bridging historical switching innovations with current all-IP ecosystems.^[49]

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Jan 28, 2015 · The commercial installation in Succasunna, New Jersey, was the very first of the No. 1 ESS. It initially served only 200 customers (of the ...Missing: deployment January
[14]
https://www.youtube.com/watch?v=28V4QPNCaXc
[15]
[PDF] The Post Office Electrical Engineers' Journal - World Radio History
Jan 4, 1977 · first TXE2 exchange came into service at Ambergate,. Derbyshire, in 1966, more than 800 TXE2 exchanges have been installed, and there has ...
[16]
[PDF] history-100.pdf - NEC Corporation
available commercially as the D10 electronic switching system. Nippon Electric installed the first D10 in June 1971 in the Ginza. Central Office in Tokyo. By ...
[17]
[PDF] No. 4 ESS: Prologue
In January, 1976, the first No. 4 Electronic Switching System (ESS) was placed in service in Chicago, Illinois. This culminated the largest single system ...
[18]
[PDF] Bell System Technical Journal 1977-7.pdf - World Radio History
the No. 4 Electronic Switching System. Objectives and the organization of the system are given and the overall operation is explained. I. INTRODUCTION.
[19]
[PDF] AT&T July-August 1985 Vol. 64 No.6 Part 2 - Bitsavers.org
than 3700 local electronic switching offices served more than 60 million lines ... switching system office over trunks. These controls may be activated.<|separator|>
[20]
Computer utilities and the ESS - ACM Digital Library
Once an ESS is installed, AT&T has the computer facility, the circuits to the potential customers, and the input-output devices (the Touch-Tone phones and other ...
[21]
TSPS No. 1: Stored Program Control No. 1A | Nokia.com
Dec 1, 1970 · The stored program control (SPC) No. 1A has been developed as a general purpose stored program electronic processing system to provide a ...Missing: definition | Show results with:definition
[22]
Stored Program Controlled Network: No. 1/1A ESS | Nokia.com - Nokia
Sep 1, 1982 · The No. 1 ESS was the Bell System's first major electronic switching system to provide commercial service. It went into service in 1965 and ...
[23]
Stored Program - an overview | ScienceDirect Topics
The advantages are that the variety of hardware may be minimised, so easing production and stocking problems, and that facility changes may be readily ...
[24]
[PDF] Chapter 28
requirement than a Bell System Electronic Switching System. (ESS). These systems have been designed to be out of service no more than few minutes per year ...<|control11|><|separator|>
[25]
[PDF] the bell system - technical journal - World Radio History
This paper is an introduction to a series of detailed technical articles that describe the remreed switching network for No. 1 and No. 1A ESS. The developmental ...<|separator|>
[26]
None
Below is a merged summary of all segments on Time-Division Multiplexing (TDM) and Electronic Crosspoints in the No. 4 ESS, focusing on hardware mechanisms as per the provided summaries. To retain all details in a dense and organized manner, I will use a table in CSV format for key information, followed by a concise narrative summary that integrates additional context not suitable for the table. The response avoids speculative or redundant content and sticks strictly to the provided data.
[27]
[PDF] No. 101 ESS 4A Switch Unit - vtda.org
THE BELL SYSTEM TECHNICAL JOURNAL, FEBRUARY 1969. 31. 32. LINES. 16. 15. LINE ... the line ferrods, and when an off-hook is encountered, scanning is stopped ...
[28]
[PDF] Untitled - vtda.org
2 ESS and No. 3 ESS, designed to cover suburban and rural segments of the local switching market. Today, more than. 2500 local Esss are in operation ...<|control11|><|separator|>
[29]
All Circuits are Busy Now: The 1990 AT&T Long Distance Network ...
The problem repeated iteratively throughout the 114 switches in the network, blocking over 50 million calls in the nine hours it took to stabilize the system.
[30]
PART ONE: Crashing the System </HEAD> - MIT
On January 15, 1990, AT&T's long-distance telephone switching system crashed. This was a strange, dire, huge event. Sixty thousand people lost their ...
[31]
The 5ESS® wireless mobile switching center - IEEE Xplore
AT&T's 5ESS® Switch supports the MSC function for two of the three digital wireless standards, and is an integral component of the AT&T MSC product for the ...Missing: cellular | Show results with:cellular
[32]
Overview of 5ESS-2000 switch performance - ACM Digital Library
The 5ESS-2000 Switch uses specific dynamic data relations when making the IN query and there is a SRE algorithm that determines the number of tuples needed ...
[33]
Switching Network - an overview | ScienceDirect Topics
Electronic switching systems provided the hubs for the older carrier systems such as DS-1 through DS-3 or DS-4 systems discussed in Ahamed and Lawrence ...
[34]
5ESS - Glossary - tarf.co.uk
The 5ESS is also exported internationally, and manufactured outside the US under license. The 5ESS technology was transferred to the AT&T Network Systems ...
[35]
No. 1 ESS Maintenance Plan - Downing - 1964 - Wiley Online Library
Bell System Technical Journal · Volume 43, Issue 5 pp. 1961-2019 Bell System Technical Journal. Full Access. No. 1 ESS Maintenance Plan. R. W. Downing,. R. W. ...
[36]
[PDF] the bell system - technical journal - World Radio History
the electronic switching system. He has since engaged in theoretical studies of data transmission systems. Member, IEEE; associate mem- ber, Sigma Xi ...
[37]
[PDF] Common Channel Interoffice Signaling: An Overview - vtda.org
In May of 1976, a new Common Channel Interoffice Signaling (CCIS) system linked together the last new No. 4A toll crossbar office in Mad- ison, Wisconsin and ...
[38]
Western Electric/Lucent Modern Telephone Switching Systems
Jun 19, 2023 · Electronic Switching Systems were made possible by the invention of the transistor. They apply the basic concepts of an electronic data ...Missing: definition | Show results with:definition
[39]
AT&T's All-IP Transition and the PSTN Sunset | Alianza Blog
Mar 3, 2014 · AT&T aims to complete its IP transition by 2020, sunsetting PSTN due to lack of demand, economics, and parts availability for traditional ...<|separator|>
[40]
Number One Electronic Switching System - Wikipedia
It was manufactured by Western Electric and first placed into service in Succasunna, New Jersey, in May 1965. The switching fabric was composed of a ...Missing: deployment January
[41]
https://www.facebook.com/groups/752780219227785/posts/1420689535770180/
[42]
Preserving a 5ESS Switch for Posterity - Telephone World
This #5ESS had a maximum capacity of only 5,000 customers, but it's still a #5ESS by definition. It was purchased in late 1994 and installed in early 1995. By ...
[43]
Telephone Switch - an overview | ScienceDirect Topics
This switch was primarily electromechanical in nature. Because of the software considerations, the No.1 ESS switch-based Central Office ( circa mid-1960s) was ...
[44]
ITU-T Q.3062 (09/2022) - ITU-T Recommendation database
Sep 29, 2022 · Signalling system No. 7 (SS7) is a stack of signalling protocols, which was initially developed by ITU (CCITT) in the 1980s.
[45]
[PDF] Integrated Voice/ Data Switching - People @EECS
The telephone system is gradually converting from analog to an entirely digital network because of decreasing costs, increasing data transmis- sion, and ...Missing: influence convergence
[46]
[PDF] From GSM to LTE - WordPress.com
The reasons for this and further details on virtual circuit switching can be found in Section 1.1.2. 1.1.1 Classic Circuit Switching. The GSM mobile ...
[47]
The Urban-Rural Telecommunications Divide Endures - MDPI
The above weakening is reversed when advanced features, such as digital switching and WATS lines, are available in rural areas, pointing to a much more ...
[48]
IVR modernization at your pace | Amazon Connect
Amazon Connect enables you to test, learn, and grow contact center capabilities at your own pace through seamless integration with legacy environments.