Multiple unit

A multiple unit (MU), also known as a multiple-unit train, is a self-propelled train composed of two or more carriages joined together, in which propulsion equipment is installed on most or all vehicles, allowing motive power to be distributed rather than concentrated in a single locomotive.^[1] This design enables centralized control from a single cab via multiple-unit train control systems, allowing efficient operation of passenger or freight trains.^[2] The multiple-unit system originated in the late 19th century as part of the advancement of electric traction in urban railways. In 1897, inventor Frank J. Sprague successfully implemented the first multiple-unit control system on the South Side Elevated Railroad in Chicago, Illinois, enabling multiple electric cars to be operated as a single unit from the leading cab.^[2] This innovation, building on Sprague's earlier work with electric elevators in 1891, revolutionized rail transport by facilitating longer trains with distributed power, and it was commercialized through the Sprague Electric Company before being acquired by General Electric in 1902.^[2] Multiple units are categorized primarily by power source, including electric multiple units (EMUs) that draw power from overhead wires or third rails for urban and suburban services, and diesel multiple units (DMUs) that use onboard diesel engines for non-electrified routes.^[3] EMUs and DMUs are prevalent in commuter rail, regional passenger services, and light rail applications worldwide, offering benefits such as faster acceleration due to distributed propulsion, lower operating costs compared to locomotive-hauled trains, and improved energy efficiency.^[4]^[5] These advantages make multiple units particularly suitable for high-frequency, medium-capacity operations in dense urban environments.^[5]

Introduction

Definition and principles

A multiple unit (MU) is a self-propelled railway trainset in which propulsion equipment is distributed across most or all cars, typically composed of one or more powered cars, which may include unpowered trailer cars semi-permanently coupled to function as a single integrated vehicle, with motive power distributed across multiple axles or bogies rather than concentrated in a separate locomotive.^[1] This design enables the entire trainset to operate without an external hauling locomotive, distinguishing MUs from traditional locomotive-hauled consists.^[1] The fundamental operating principles of multiple units revolve around distributed traction and centralized control to enhance performance. Power distribution across several powered cars improves adhesion and traction by spreading weight and motive force evenly, leading to better acceleration and up to 5-10% greater energy efficiency compared to centralized power systems.^[6] Control is centralized through electrical jumper cables connecting the cars, allowing a single operator in any driving cab to command all propulsion, braking, and auxiliary systems simultaneously via multiple-unit train control (MU control) technology.^[7] In modern implementations, wireless systems may supplement or replace cables for enhanced flexibility.^[8] Key components of a multiple unit include power cars, which house the propulsion motors, engines, or pantographs and often feature driving cabs at one or both ends for operator control; trailer cars, which provide additional passenger or freight capacity without onboard motive power; and specialized semi-permanent couplers that mechanically and electrically link cars for seamless operation.^[9] Driving cabs are typically located at the ends of the outermost power cars, equipped with controls for the entire trainset. The term "multiple unit" originated in the late 19th century from early electric railway terminology, specifically Frank J. Sprague's 1897 invention of multiple-unit train control, which adapted elevator control principles to enable synchronized operation of multiple self-propelled cars from a single point.^[2] This innovation emphasized the "multiple" motors and unified control across units, marking a shift toward integrated train designs in the early 20th century.^[2]

Classification systems

Multiple units are primarily classified by their power source, which determines their propulsion mechanism and operational suitability. Electric multiple units (EMUs) consist of self-propelled carriages that derive motive power from external electrical sources, such as overhead catenary wires or third rails, enabling efficient operation on electrified networks.^[10] Diesel multiple units (DMUs) rely on on-board diesel engines directly driving the wheels through mechanical or hydraulic transmission, offering flexibility for non-electrified routes.^[11] Diesel-electric multiple units (DEMUs) integrate diesel engines with generators to produce electricity for traction motors, combining the autonomy of diesel power with the efficiency of electric drive systems.^[12] Hybrid and battery-powered units represent further evolution, incorporating rechargeable batteries alongside diesel or electric sources to optimize energy use and reduce emissions, as seen in configurations that switch between power modes based on route conditions.^[13] Functionally, multiple units are categorized according to their service role and performance characteristics. Short-haul commuter units are designed for high-frequency urban and suburban operations, emphasizing rapid acceleration and capacity for daily passengers.^[14] Long-distance intercity units prioritize comfort and speed for regional connectivity, often featuring amenities for extended journeys.^[14] High-speed variants operate at commercial speeds of at least 250 km/h on dedicated infrastructure, as defined by the International Union of Railways (UIC), to facilitate efficient long-haul travel.^[15] Light rail and tram multiple units serve urban transit needs with lower speeds and street-running capabilities, focusing on integration with city environments.^[13] Regional standards govern multiple unit design and interoperability, reflecting variations in infrastructure and regulatory frameworks. In Europe, the UIC establishes norms for axle arrangements (e.g., using notations like 1A-A1 for powered wheelsets) and ensures compatibility on the standard 1,435 mm gauge, promoting cross-border operations. In North America, the Association of American Railroads (AAR) applies similar axle classification principles alongside specifications for self-propelled passenger cars, also on 1,435 mm gauge, to maintain safety and interchangeability across networks.^[16] These standards facilitate gauge compatibility on shared global tracks while addressing local requirements for loading, braking, and coupling. As of 2025, emerging classifications include hydrogen fuel cell multiple units, which use fuel cells to generate electricity for propulsion, exemplified by the Zero-Emission Multiple Unit (ZEMU) trainset deployed in North America for clean, non-electrified routes.^[17] Autonomous multiple units, incorporating advanced automation for driverless operation, are advancing toward commercialization, with prototypes targeting regional passenger services by the mid-2020s.^[18]

Historical development

Early innovations (1900–1945)

The early 20th century marked the beginning of multiple unit (MU) development, with pioneering self-propelled railcars emerging as alternatives to steam-hauled trains, particularly for branch lines and urban services. In the United Kingdom, the North Eastern Railway introduced the world's first petrol-electric railcars in 1903, known as autocars, featuring a 100 hp Wolseley petrol engine driving a British Westinghouse generator and 64 hp DC traction motors; these single-car units seated 50 passengers and operated until 1931 on routes to Scarborough and Harrogate.^[19] In the United States, early innovations included gas-powered railcars like the McKeen motor cars introduced by the Union Pacific in 1905, which used 4-cylinder engines to power lightweight, single-car units for short-haul services, achieving speeds up to 60 mph and influencing later diesel designs. These developments addressed the need for economical operation on low-traffic lines, where full locomotives were impractical. Key milestones in the 1930s advanced MU technology through electrification and diesel propulsion, enabling faster and more efficient services. In Europe, electrification projects led to the deployment of the first high-speed electric multiple units, while Germany pioneered diesel multiple units with the 1933 DRG Class SVT 877, dubbed the Flying Hamburger, a two-car diesel-electric trainset that reached 160 km/h on the Berlin-Hamburg route, covering 290 km in under 3 hours and setting records for non-stop diesel services.^[20] Wartime adaptations during World War II further emphasized efficiency, as resource shortages prompted railways in Europe and North America to prioritize MUs for their lower fuel consumption and smaller crews; for instance, British Railways repurposed existing diesel railcars for essential freight and passenger duties, reducing reliance on scarce steam locomotives. Early multiple units encountered significant challenges related to power distribution and reliability, limiting their widespread use. Power transmission via generators and traction motors often proved unreliable under varying loads, as seen in the 1903 North Eastern Railway autocars, where initial 85 hp engines were upgraded to 100 hp Wolseley units in 1904 due to frequent breakdowns.^[19] In the United States, the 1910 conversions of New York subway cars to improved multiple-unit control systems addressed issues with inconsistent power distribution in longer consists, enhancing synchronization across cars but highlighting the era's limitations in electrical integration for urban rapid transit. These hurdles were compounded by mechanical wear on early internal combustion engines, necessitating frequent maintenance and restricting operations to lighter duties. The global spread of multiple units during this period was concentrated in urban centers of Europe and North America, where they offered substantial cost savings over steam locomotives by integrating propulsion into passenger cars, thus eliminating separate motive power and reducing labor needs by up to 50% on short routes. Adoption began with electric MUs in subways like New York's Interborough Rapid Transit system, which opened in 1904 with 500 steel-frame cars featuring underfloor motors and third-rail collection, setting a model for efficient mass transit. By the 1940s, diesel and electric variants had proliferated in cities such as London and Chicago, prioritizing reliability improvements for commuter services amid growing electrification networks.

Post-war expansion (1946–1990)

Following World War II, the reconstruction of war-damaged rail networks in Europe and Asia drove the rapid adoption of multiple units to restore efficient passenger services on branch lines and urban routes. In the United Kingdom, British Rail introduced its first generation of diesel multiple units (DMUs) in the mid-1950s as a cost-effective alternative to steam locomotives, with the Metro-Cammell-built Class 101 entering service in 1957 to serve regional and suburban lines.^[21] Similarly, in Japan, the Japanese National Railways (JNR) accelerated electrification and deployed electric multiple units (EMUs) for intercity and urban commuting, starting with lightweight high-performance models in 1951 that reduced vehicle weight by about 25% using high-tensile steel, followed by the Kodama limited express EMU on the Tokaido Main Line in 1958.^[22] These developments addressed postwar shortages of fuel and rolling stock while supporting economic recovery and population growth in urban areas. Technological advancements in the 1960s and 1970s further standardized multiple unit operations, enabling easier formation of longer trains. In Europe, efforts in the 1960s and 1970s aimed to standardize coupling systems compatible across networks, facilitating multiple unit control through jumper cables for electrical and pneumatic connections, though full adoption varied by country. In France, the Société Nationale des Chemins de fer Français (SNCF) pioneered high-speed prototypes, including the gas turbine-powered Turbotrain TGS in 1967, which reached 252 km/h in 1971, and the TGV 001 experimental multiple unit in 1972, achieving 318 km/h during testing; the 1973 oil crisis prompted a shift to electric propulsion, leveraging nuclear-generated power for future high-speed EMUs.^[23] Economic pressures, such as declining freight volumes and the need to maintain uneconomic branch lines, spurred the transition to diesel and electric multiple units globally during the 1960s. In Australia, the South Australian Railways introduced the locally built Redhen diesel railcars in 1955, with production continuing into the 1960s, to replace aging steam-hauled suburban services around Adelaide amid rising operational costs and competition from road transport.^[24] By the 1980s, adoption peaked worldwide as networks expanded to meet surging urban demand; in India, Indian Railways deployed advanced chopper-controlled EMUs in Mumbai starting with trials in 1981 under a collaboration with the Bhabha Atomic Research Centre, transitioning to 12-car formations by 1988 to handle growing commuter traffic on the 1.5 kV DC suburban lines.^[25] In the Soviet Union, the Riga Car Building Factory mass-produced the ER2 series electric multiple units from the early 1960s onward, with ongoing builds through the 1980s supporting extensive suburban electrification and handling peak passenger loads on DC-electrified routes.^[26]

Modern advancements (1991–present)

Since the 1990s, the integration of digital signaling systems has transformed multiple unit operations, enabling higher automation and safety levels. The European Train Control System (ETCS), standardized under the European Union Agency for Railways, saw its first specifications released in 1996, with initial onboard installations in multiple units occurring in the early 2000s across Europe.^[27] By the 2010s, ETCS Level 2 was widely adopted for mainline multiple units, such as in the UK's East Coast Digital Programme, which equipped over 700 locomotives and multiple units for real-time route information and automated train protection by 2024.^[28] Complementing this, Communications-Based Train Control (CBTC) emerged in urban settings during the 2000s, utilizing radio communications for continuous train positioning and moving-block operations in multiple units. A seminal implementation was New York City's Canarsie Line in 2006, where CBTC reduced headways and increased capacity on subway multiple units by enabling automated train supervision.^[29] Sustainability initiatives gained prominence in multiple unit design from the 2000s, driven by regulatory pressures for reduced emissions. Regenerative braking systems, which recapture kinetic energy during deceleration and feed it back to the power supply, became standard in electric multiple units, achieving energy savings of 10% to 45% in metro applications depending on route profiles.^[30] This technology, integrated into traction inverters, minimizes waste heat and supports grid stability, with widespread adoption in European and Asian fleets by the 2010s. Low-emission hybrids further advanced this focus, exemplified by Alstom's Coradia iLint, the world's first hydrogen-powered passenger multiple unit, which entered commercial service in Lower Saxony, Germany, in September 2018.^[31] The iLint uses fuel cells to generate electricity from hydrogen, emitting only water vapor and enabling zero-CO2 operation on non-electrified lines up to 1,000 km, with over 200,000 km accumulated in service by 2022.^[32] High-speed multiple units evolved significantly in the 2000s, prioritizing capacity and modularity for extended consists. China's CRH (China Railway High-speed) series, launched in 2007 on the Beijing-Tianjin intercity line, marked the rapid expansion of the world's largest high-speed network, incorporating modular designs derived from international technologies like Japan's Shinkansen for efficient assembly and maintenance.^[33] By the 2010s, CRH trains operated at speeds up to 350 km/h, with standardized platforms allowing flexible coupling of up to 16 cars to meet peak demand. In Japan, the N700S Shinkansen entered service in July 2020 on the Tokaido and Sanyo lines, enhancing modularity through interchangeable components and reduced air resistance for improved energy efficiency at 300 km/h. Its silicon carbide-based traction system supports longer consists of up to 16 cars while maintaining earthquake-resistant features.^[34] Into the 2020s, battery-electric multiple units addressed electrification gaps on legacy lines, alongside AI-driven maintenance. In the UK, conversions like Vivarail's Class 230, adapted from London Underground stock, demonstrated viability for non-electrified routes, achieving a 320 km distance record in 2025 using battery power supplemented by regenerative braking.^[35] These units enable zero-emission operation at speeds up to 100 km/h, with batteries charged via overhead lines or pantographs where available. AI predictive maintenance has concurrently reduced downtime, with approximately 60% of global railway companies having implemented at least one AI use case at scale as of 2023 to analyze sensor data for fault prediction, including in multiple units.^[36]

Technical design

Propulsion and power systems

Electric propulsion systems in multiple units primarily rely on external power sources delivered through overhead catenary or third-rail infrastructure. The overhead catenary system uses a network of wires suspended above the tracks, typically at 25 kV AC in European mainline and high-speed applications, allowing efficient transmission over long distances with reduced energy losses compared to lower-voltage systems.^[37] Pantographs, mounted on the roof of the train, maintain continuous contact with the catenary via a spring-loaded, diamond-shaped frame that adjusts to track irregularities and speeds up to 300 km/h, ensuring stable power collection while minimizing wear.^[38] In contrast, third-rail systems employ a rigid conductor rail alongside the track, energized at around 750 V DC, which is common in urban and metro networks for its lower installation costs and reduced vulnerability to weather, though it limits speeds due to mechanical contact stresses.^[37] Diesel propulsion in multiple units incorporates onboard engines, often medium-power units rated at 250–560 kW derived from truck or industrial designs, coupled with torque converters for smooth acceleration from standstill.^[39] These systems, including diesel-hydraulic variants with hydrodynamic torque converters and multi-speed transmissions, achieve peak efficiencies up to 95% in hydro-mechanical configurations, though overall fuel consumption averages 2.0–2.5 kg/km for typical regional services.^[39]^[40] Hybrid diesel-battery setups integrate lithium-ion or supercapacitor storage to capture braking energy, enabling engine shutdown during low-demand phases like station stops, which reduces fuel use by 6–13% and CO₂ emissions proportionally while operating the diesel engine in its optimal 40% efficiency range.^[39] Battery-electric multiple units (BEMUs) use onboard rechargeable batteries, typically lithium-ion packs with capacities of 1–4 MWh, to power traction motors for non-electrified routes, offering zero-emission operation over distances up to 100–200 km per charge as of 2025. These systems support fast charging at stations and regenerative braking to extend range, with examples including Stadler's FLIRT Akku trains in Europe. Hydrogen fuel cell multiple units (HMUs) employ proton exchange membrane fuel cells generating electricity from hydrogen stored in compressed tanks, achieving ranges over 600 km and refueling times under 15 minutes; the ZEMU, the first hydrogen passenger train in the US, debuted in California in September 2025, demonstrating hybrid fuel cell-battery integration for regional services.^[41]^[42] Power distribution in multiple units employs multiple traction motors, typically one per bogie, to provide even traction across the train consist, enhancing stability and adhesion.^[43] This distributed arrangement generates tractive effort F = m \times a, where F is the total pulling force, m is the train mass, and a is acceleration, with multiple motors minimizing wheel slip on gradients by equalizing torque demands and improving overall grip.^[43] Energy efficiency in these systems is quantified by the basic consumption formula E = \frac{P \times t}{\eta}, where E is energy used, P is power output, t is time, and \eta is the system efficiency factor, often ranging from 0.76 for electric traction to 0.37–0.40 for diesel variants.^[44] Distributed power elevates \eta by optimizing load sharing, reducing losses from uneven adhesion, and enabling regenerative braking recovery of up to 20–30% of input energy in hybrid configurations.^[44] To derive this, start with total energy input as P \times t, then divide by \eta (product of motor, transmission, and auxiliary efficiencies) to yield net consumption, where improvements from distribution stem from lower peak loads per motor, as validated in traction models for commuter rail.^[44]

Control and coupling mechanisms

Control systems in multiple units enable coordinated operation of propulsion, braking, and auxiliary functions across coupled vehicles, typically through master-slave configurations where the lead vehicle dictates commands to trailing ones. In traditional setups, particularly for diesel-electric locomotives and early electric multiple units in North America, this is achieved via multi-pin jumper cables that transmit electrical signals for throttle, direction, dynamic braking, and sanders. The standard Association of American Railroads (AAR) system uses 27-pin jumper cables with cast aluminum plugs, where specific pins handle functions like power reduction (pin 1, 0-74 V DC) and generator field excitation (pin 6), ensuring synchronized operation when trailing units are set to "trail" mode via pneumatic hoses for brake control. Variations exist, such as 13-pin or 15-pin configurations in some older or regional systems for simplified control in electric multiple units, while electro-pneumatic "train wires" in Australian railmotor units activate magnet valves for throttle and transmission across up to five cars, with interlocks preventing gear shifts unless at idle.^[7]^[45]^[46] Modern advancements since the 2000s have shifted toward wireless train control and monitoring systems (TCMS), reducing reliance on physical jumpers for enhanced flexibility and reduced maintenance. Radio-based TCMS, part of the Train Communication Network (TCN) evolution under initiatives like Europe's Roll2Rail project, enables bidirectional wireless communication for safety-critical functions, allowing seamless data exchange between vehicles without wired connections and supporting virtual coupling concepts for dynamic formations. These systems use protocols compliant with IEC 61375 standards, integrating with onboard diagnostics for real-time monitoring, though hybrid wired-wireless setups persist for fail-safe redundancy in high-speed multiple units.^[47] Coupling mechanisms facilitate both mechanical linkage and functional integration, with types varying by region to support multiple working. In North America, automatic couplers like the Janney (AAR Type E) or Tightlock variants are prevalent for multiple units, enabling semi-automatic shunting while incorporating electrical and pneumatic interlocks to connect brake hoses (e.g., MR and BC lines) and jumper cables, ensuring air pressure equalization and electrical continuity for unified control. European systems often employ drawbar arrangements or compact automatic couplers such as Scharfenberg (Scharfenbergprofil) on non-freight multiple units, which integrate mechanical drawbars with multi-function plugs for electrical (up to 13 contacts) and pneumatic (brake and auxiliary air) connections, allowing one-person coupling with automatic alignment for seamless operation across borders under UIC standards. These interlocks prevent uncoupling under load and verify connections before movement, enhancing safety during formation.^[48] [Note: Wikipedia not cited, but concept from PDF] Safety features are integral to control and coupling, prioritizing fail-safe operation to mitigate human error or system faults. The deadman's handle, a vigilance device requiring periodic operator acknowledgment, triggers emergency braking if released or unacknowledged, commonly integrated into multiple unit cabs since the early 20th century to monitor driver alertness across formations. Automatic Train Protection (ATP) systems enforce speed limits and movement authorities via onboard transponders or radio, automatically applying brakes if overspeed or signal violations occur, as seen in U.S. Federal Railroad Administration (FRA) guidelines for high-speed guided transport where ATP uses two-out-of-three voting logic for redundancy. Fail-safe braking logic ensures brakes engage on power loss or fault detection, with electro-pneumatic valves defaulting to applied positions and dynamic brakes supplementing friction systems for uniform deceleration, preventing propagation of failures in coupled units.^[49] Scalability allows multiple units to form longer consists, typically up to 12 cars, through standardized protocols that distribute control signals for uniform acceleration and braking. In commuter services like those on Japan's E259 series or U.S. Northeast Corridor electrics, units couple via compatible interlocks to extend to 12-car lengths, with TCMS or jumper systems propagating throttle commands to maintain consistent power output and avoid slack action, limited by traction capacity and signaling to ensure stability at speeds up to 200 km/h. These protocols, often governed by national standards like those from the International Union of Railways (UIC), enable reversible formations where any unit can lead, supporting operational flexibility without compromising safety.^[25]

Structural and aerodynamic features

Multiple units (MUs) employ advanced materials to optimize structural integrity while minimizing weight, primarily using lightweight aluminum alloys and composite materials for car bodies. Aluminum extrusions and panels form the primary structure, often welded or riveted into a monocoque design that distributes loads across the shell rather than relying on a separate frame, enabling significant weight savings. For instance, the Siemens Mireo regional MU features a welded integral aluminum monocoque construction that reduces overall vehicle mass compared to traditional steel designs. Composites, such as carbon fiber reinforced polymers, are increasingly integrated in hybrid structures for further reductions; a study on electric multiple unit (EMU) car bodies using aluminum-carbon fiber hybrids achieved up to 20% weight savings through optimized material distribution. These techniques result in MUs being approximately 20-30% lighter than equivalent locomotive-hauled consists, improving energy efficiency and acceleration without sacrificing strength.^[50]^[51]^[52] Aerodynamic features in MUs focus on minimizing drag to enhance high-speed performance and reduce energy consumption, with designs emphasizing streamlined nose shapes and smooth gangway connections between cars. The nose typically incorporates rounded, tapered profiles to deflect airflow effectively, while inter-car gaps are sealed with bellows or fairings to prevent turbulence. Wind tunnel testing is standard for validating these elements, ensuring compliance with performance criteria for speeds exceeding 200 km/h. High-speed MUs like the Shinkansen series achieve drag coefficients (Cd) below 0.3 through such optimizations, with values around 0.25 for streamlined configurations, leading to drag reductions of 10-15% compared to less refined shapes. These features are particularly critical for distributed power systems, where uniform aerodynamics across the train length maintains stability.^[53]^[54] Integration of passenger amenities in MU structures prioritizes modularity to support accessibility without weakening the overall frame, allowing interiors to be reconfigured for diverse needs. Modular panels and flooring systems enable easy installation of features like wider aisles, priority seating, and wheelchair spaces, while maintaining structural rigidity through reinforced mounting points. In the United States, MUs must comply with Americans with Disabilities Act (ADA) standards, including level boarding, accessible restrooms, and securement areas for mobility aids, achieved via standardized modular kits that fit within the car's load-bearing skeleton. Examples include Alstom's Coradia series, where modular interiors provide flexible layouts for ADA-compliant spaces, such as dedicated low-floor sections, ensuring seamless passenger flow. This approach balances comfort enhancements with the integrity of the monocoque or semi-monocoque body.^[55]^[56] Durability in MUs incorporates crashworthiness standards and vibration control to protect occupants and ensure longevity under operational stresses. In Europe, EN 15227 mandates energy absorption in collision scenarios, requiring deformable front-end structures with crush zones that limit deceleration to survivable levels, applicable to both locomotives and MU driving cars. These standards classify vehicles into design categories based on service type, with high-speed MUs featuring reinforced end underframes to absorb impacts up to 36 km/h. For vibration damping, especially in distributed power configurations where motors are spread across cars, multiple dynamic vibration absorbers (DVAs) are installed on floors and bogies to mitigate resonant frequencies, reducing passenger discomfort by up to 50% at speeds over 250 km/h. Such measures enhance ride quality while preserving the lightweight composite or aluminum framework.^[57]^[58]

Operational types

Passenger multiple units

Passenger multiple units (PMUs) are self-propelled rail vehicles designed primarily for transporting passengers, emphasizing efficiency, comfort, and rapid acceleration for frequent stops in urban and regional services. These units, often electric multiple units (EMUs), integrate propulsion, passenger accommodation, and control systems within the same consist, allowing for flexible formations without separate locomotives. Configurations vary by service type, with commuter PMUs prioritizing high passenger throughput and intercity variants focusing on longer-distance travel amenities. Commuter PMUs typically feature high-capacity standing areas to accommodate peak-hour crowds, with 4 to 6 doors per car to facilitate quick boarding and alighting. For instance, modern designs like Alstom's Multilevel cars for NJ Transit commuter services include two sets of extra-wide doors per side, enabling efficient passenger flow in dense urban environments. In contrast, intercity PMUs incorporate reclining seats arranged in 2+2 or 2+1 layouts and onboard catering facilities, such as vending areas or bistro sections, to enhance journey comfort over extended routes. Comfort features in passenger multiple units have evolved to meet modern expectations, including advanced heating, ventilation, and air conditioning (HVAC) systems that maintain optimal cabin temperatures and air quality even during high occupancy. Wi-Fi integration became a standard amenity in many PMUs during the 2010s, providing passengers with reliable internet access for work or entertainment, as seen in high-speed designs like China's CRH series. Accessibility enhancements, such as automatic ramps and low-floor entry points, ensure compliance with disability regulations and inclusive travel; Japan's E5 series Shinkansen, for example, offers spacious interiors with priority seating and universal design elements for enhanced passenger experience. Capacity metrics for passenger multiple units typically range from 1,500 to 2,000 passengers per 8-car set, combining seated and standing accommodations to maximize throughput while adhering to loading gauges. The multiple doors and distributed power in PMUs contribute to dwell time reductions compared to locomotive-hauled trains, improving schedule adherence in busy corridors. Double-deck configurations, like those in Germany’s DB Regio double-deck EMUs, boost capacity with up to 1,000 passengers per 8-car set including standing, while single-level units predominate on regional lines for simpler infrastructure compatibility and lower construction costs.^[59]

Freight multiple units

Freight multiple units (FMUs) are self-propelled rail formations designed specifically for goods transport, featuring permanently coupled cars with integrated propulsion systems to handle heavy cargo loads efficiently. Unlike traditional locomotive-hauled trains, FMUs distribute motive power across the consist, enabling better traction and control for demanding freight operations. These units address the need for reliable, high-capacity hauling in sectors like intermodal container transport and bulk goods, with adaptations focused on durability and logistics optimization. True FMUs remain niche, with historical examples including German DB Type 798 diesel railcars from the 1990s for lightweight freight.^[60] Design adaptations in FMUs emphasize structural reinforcements to support intense cargo demands, such as reinforced underframes capable of withstanding the stresses of container loading and unloading. These underframes incorporate longitudinal and transverse members to distribute weight evenly, preventing deformation under heavy payloads like stacked intermodal containers. For heavy-haul applications, distributed power configurations using multiple locomotives placed along the train improve starting traction and reduce slack action in long consists; in Australia, operators have used distributed power setups for coal and iron ore trains, enhancing performance on steep gradients.^[61] Operational advantages of such configurations include streamlined terminal handling, as fixed formations or multi-loco setups eliminate the need for locomotive repositioning during shunting, reducing turnaround times and labor requirements. This allows for quicker assembly and dispatch of freight trains, minimizing delays in busy yards. In Germany, since the 2010s, Vectron multi-system locomotives have been deployed in multiple-unit configurations for cross-border freight, enabling efficient operations without decoupling, as seen in DB Cargo's international services.^[62]^[63] FMUs or distributed power trains typically consist of 4 to 10 coupled units, optimized for specific cargo types such as well cars for double-stacked containers or flatbeds for oversized loads like machinery and lumber. Well car formations, for instance, feature depressed centers to lower the center of gravity, accommodating 40- or 45-foot containers while maintaining stability at high speeds. Emerging electric FMUs further support decarbonization efforts; Wabtec's FLXdrive battery-electric locomotives, introduced in hybrid configurations in 2023, integrate into freight consists to cut diesel use by up to 11% and reduce greenhouse gas emissions, as demonstrated in trials with Australian mining operations.^[64]^[65] Key challenges in FMU operations involve managing higher axle loads, often reaching 25 tonnes per axle to maximize payload capacity, which accelerates track wear and requires enhanced maintenance. Mitigation strategies include advanced rail profiles and lubrication systems to minimize fatigue and corrugation, ensuring long-term infrastructure integrity in heavy-haul corridors.^[66]^[67]

Specialized and hybrid units

Hybrid multiple units, also known as bi-mode units, integrate both electric and diesel propulsion systems to operate seamlessly on electrified and non-electrified track sections, enhancing flexibility in mixed infrastructure networks. The British Rail Class 800, introduced in 2017 by Hitachi Rail for operators like Great Western Railway and London North Eastern Railway, exemplifies this design; it employs electric traction under overhead wires and onboard diesel generators for unelectrified routes, achieving speeds up to 125 mph in electric mode and supporting the UK's Intercity Express Programme.^[68]^[69] Specialized multiple units serve niche applications beyond standard passenger or freight services, including maintenance and tourism. Self-propelled rail grinders, such as those from RailTechnology's ST series, function as compact multiple-unit configurations equipped with up to 24 grinding stones to restore rail profiles and remove irregularities, operating at speeds of 2-16 km/h for grinding while self-propelling at up to 70 km/h between sites.^[70] Track inspection multiple units, like modified diesel multiple units (DMUs) used by Network Rail, incorporate advanced sensors for geometry and defect monitoring; for instance, the Class 153 inspection train enables real-time visual and ultrasonic assessments without dedicated locomotives.^[71] Airport shuttle variants, such as the refurbished Class 387 electric multiple units on Heathrow Express, provide high-frequency, non-stop service between London Paddington and Heathrow Airport, featuring dedicated interiors for 374 passengers per 160-meter train and business-class seating.^[72] In tourism, Switzerland's panoramic trains operated by the Rhaetian Railway on routes like the Bernina Express offer large-windowed coaches for alpine views through UNESCO-listed landscapes.^[73] Military adaptations of multiple units have emerged in conflict zones to protect logistics and personnel. During the 2022 Russian invasion of Ukraine, both sides modified existing rail vehicles into armored trains; Ukraine adapted civilian locomotives and cars with plating for secure supply transport, while Russian forces deployed units like the Amur, a self-propelled armored train with anti-aircraft defenses for reconnaissance and repair under fire.^[74] In research, multiple-unit testbeds advance maglev technology; Japan's Central Japan Railway Company's Yamanashi test line uses superconducting maglev (SCMaglev) multiple units to validate speeds exceeding 600 km/h, with extensive sensor integration for stability and aerodynamics testing.^[75] As of 2025, future concepts explore autonomous hybrid multiple units combining freight and passenger functions to optimize shared high-speed corridors. In China, research optimizes integrated freight-passenger electric multiple units on existing lines, allowing dynamic resource allocation to reduce congestion and costs, with trials focusing on unmanned operations for efficiency.^[76] Additionally, China's first fully autonomous standard metro multiple units, debuted at MetroTrans 2025, incorporate AI for driverless navigation, paving the way for hybrid applications in mixed urban-rural networks.^[77]

Comparative analysis

Advantages

Multiple units offer significant energy efficiency advantages over traditional locomotive-hauled trains due to their distributed power systems, which minimize transmission losses and enable lighter overall designs. For instance, electric multiple units (EMUs) can achieve significant energy savings compared to equivalent diesel-electric locomotive-hauled configurations, primarily through optimized power distribution and reduced weight per seat.^[78] Diesel multiple units (DMUs) similarly demonstrate improved efficiency, with examples showing 5-10% savings in single-vehicle operations and 1-2% fleet-wide benefits from better space utilization and lower mass per passenger.^[6] Regenerative braking further enhances this, allowing recovery of 10-45% of braking energy in metro and commuter applications, which directly reduces net energy demand.^[30] Performance metrics of multiple units surpass those of locomotive-hauled trains, particularly in acceleration and gradient handling, thanks to traction motors distributed across multiple axles. This enables rates often around 0.8-1.2 m/s², compared to typical 0.3-0.5 m/s² for locomotive-hauled passenger consists where power is concentrated at the front.^[39]^[79] The multi-axle traction improves adhesion and pulling power on inclines, reducing travel times on routes with stops or elevation changes without requiring oversized locomotives.^[6]^[80] Operationally, multiple units provide gains through simplified procedures and reliability enhancements, as there is no need for locomotive-trailer coupling, leading to shorter turnaround times—often 5-10 minutes versus 30 minutes for loco-hauled setups requiring uncoupling and repositioning. This bidirectional capability and reduced interfaces also lower failure rates by eliminating mechanical junctions prone to wear.^[81] Additional benefits include even axle loads, typically 18-22 tonnes, which distribute weight uniformly and minimize track maintenance needs compared to the uneven loading from concentrated locomotive mass in hauled trains. Integrated designs further contribute to reduced noise levels, with EMUs recording interior levels as low as 73 dB during operation, benefiting passenger comfort and urban deployment.^[82]^[83]

Disadvantages

Multiple units suffer from elevated maintenance requirements owing to the distributed nature of their propulsion and control systems, which introduce greater complexity across each car compared to centralized locomotive-hauled configurations. The distributed propulsion may require more maintenance efforts on electrical and mechanical components in every car, rather than concentrating these in a single locomotive. Multiple units often have higher initial acquisition costs due to the need for propulsion systems in multiple cars.^[84] Reliability challenges arise because a failure in any single car—such as an electrical or propulsion fault—can compromise the entire trainset, necessitating the removal of the whole unit from service for repairs and potentially causing significant operational disruptions. This contrasts with locomotive-hauled trains, where issues are often isolated to the power car, allowing the rest of the consist to remain operational. Additionally, in emergencies, some multiple unit designs feature limited or restricted passages between cars to maintain structural integrity and safety, which can complicate rapid evacuation and require reliance on end doors or emergency exits.^[85] Flexibility is another limitation, as multiple units are generally built as fixed-length sets that are difficult to reconfigure by adding or removing cars to match fluctuating demand, leading to underutilized capacity on low-demand routes where powered cars run idle without contributing to revenue. This rigidity can result in inefficient resource allocation, particularly for operators serving variable traffic patterns. In certain contexts, such as high-speed corridors, multiple units face debates over potential obsolescence, with some advocates favoring dedicated locomotives for better adaptability to evolving infrastructure and performance needs, as seen in ongoing discussions within India's rail modernization efforts during the 2020s.^[86]

Global usage

Europe

In Europe, multiple units form the backbone of passenger rail services, with the United Kingdom operating one of the continent's largest fleets of electric multiple units (EMUs) and diesel multiple units (DMUs). Govia Thameslink Railway introduced 25 six-car Siemens Class 717 EMUs in 2019 for Thameslink's Great Northern suburban services from Moorgate to destinations like Stevenage and Welwyn Garden City, enhancing capacity and reliability on busy commuter routes.^[87] In France, SNCF's TGV fleet—comprising high-speed EMUs capable of 320 km/h—dominates intercity and international services, operating across a dedicated network exceeding 2,800 km of high-speed lines and serving over 100 million passengers annually.^[88] Regional variations highlight adaptations to diverse terrains and electrification levels. Germany's Deutsche Bahn and private operators rely on Alstom Coradia LINT DMUs (previously known as Talent) for non-electrified regional lines, with over 500 units in service since 2000, offering speeds up to 140 km/h and low-floor accessibility for rural connectivity.^[89] Sweden's SJ operates X2000 tilting EMUs, which achieve 200 km/h on curved conventional tracks through active tilt technology, reducing travel times on routes like Stockholm to Gothenburg by up to 30 minutes compared to non-tilting trains.^[90] In Belgium, SNCB is procuring up to 442 CAF hybrid battery-electric multiple units (BEMUs) under a €1.7 billion framework to support cross-border services, enabling seamless operation across DC and AC electrification zones into France and the Netherlands.^[91] Recent developments underscore a continent-wide shift toward sustainable operations. The European Union is advancing electrification, with 57.4% of its 201,000 km rail network electrified by 2023—up from 53.8% in 2013—and carrying 80% of rail traffic on these lines, aligning with goals for further expansion to support net-zero emissions by 2050.^[92] Ireland's DART+ program includes deploying up to 750 Alstom X'trapolis carriages, forming new EMUs and BEMUs from 2025 to extend electrified services 40 km westward and increase frequencies to 15 trains per hour on key Dublin commuter lines.^[93] Switzerland's SBB has introduced Stadler RABe 501 Giruno EMUs since 2019, optimized for alpine routes via the 57 km Gotthard Base Tunnel, achieving 250 km/h and facilitating international interoperability with Germany and Italy. Europe's multiple unit operations span over 94,000 km of rail lines within the Trans-European Transport Network (TEN-T), where Technical Specifications for Interoperability (TSIs) ensure standardized loading gauges, braking systems, and ERTMS signaling for seamless cross-border deployment.^[94] This framework supports the predominance of EMUs on electrified core corridors, enhancing efficiency across the EU's integrated passenger network.^[95]

Asia

Asia's adoption of multiple units (MUs) has been marked by pioneering high-speed rail innovations and extensive urban networks to accommodate dense populations. Japan leads in high-speed applications with the Shinkansen, which has exclusively utilized electric multiple units since its inauguration in 1964 as the world's first high-speed rail line, initially operating at speeds up to 210 km/h.^[96] Subsequent advancements have pushed operational speeds beyond 300 km/h, with models like the N700 series achieving up to 320 km/h on dedicated tracks, emphasizing reliability and punctuality in a seismically active region.^[97] China has rapidly expanded its high-speed MU fleet, particularly with the CR400 Fuxing series, which operates at 350 km/h and forms one of the world's largest high-speed rail deployments, exceeding 1,100 trainsets by 2025 to support a network spanning over 48,000 km.^[98]^[99] Urban and regional MU services in Asia address massive commuter demands through efficient electric multiple units (EMUs). In South Korea, the Korea Train Express (KTX) system employs EMUs like the KTX-Eum, a domestically developed model reaching 260 km/h for intercity travel, while Seoul's subway network relies on EMUs for high-frequency urban service, carrying millions daily with advanced automation.^[100] India's Mumbai Suburban Railway operates one of the world's busiest networks, with over 2,300 daily EMU services transporting more than 7.5 million passengers across 450 km of tracks, featuring 12- to 15-car rakes designed for peak-hour intensity.^[101] In Indonesia, Kereta Api Indonesia (KAI) deploys EMUs on Java's commuter lines, including the KRL Commuterline in Greater Jakarta, where new Chinese-built sets enhance capacity on routes serving over 1 million daily riders with features like air-conditioning and regenerative braking.^[102] Emerging markets in Asia are integrating MUs to modernize rail infrastructure, often blending diesel and hybrid technologies for varied terrains. The Philippines' Philippine National Railways (PNR) operates diesel multiple units (DMUs) such as the Hyundai Rotem sets introduced in 2009 and INKA-built units since 2019, providing commuter services along the Metro Manila line with capacities for up to 300 passengers per car to alleviate urban congestion.^[103] In Thailand, the State Railway of Thailand is procuring 184 hybrid diesel-electric multiple units (Hybrid DEMUs) as part of a 24.1 billion baht modernization plan, aimed at rural and intercity routes to improve electrification access and reduce emissions in underserved areas.^[104] Asian MU operations face unique challenges, particularly overcrowding and natural hazards, prompting innovative safety measures. In Japan, Shinkansen designs incorporate seismic-resistant features, such as base isolation systems and earthquake early-warning integration, ensuring zero passenger fatalities since 1964 despite frequent tremors.^[105] To combat overcrowding on dense urban lines, widespread installation of platform screen doors (PSDs) has become standard, with over 4,000 platforms targeted for equipping by 2030 to prevent falls and enhance airflow, significantly reducing accidents in high-traffic stations.^[106]

Africa and Middle East

In Africa and the Middle East, multiple units have been adopted to address diverse challenges in expanding rail networks, including urban congestion, freight demands in arid environments, and connectivity in developing infrastructure. South Africa's Passenger Rail Agency of South Africa (PRASA) operates a significant fleet of electric multiple units (EMUs) for its Metrorail commuter services, with a major procurement of 600 six-car EMU sets—totaling 3,600 cars—under a R51 billion contract signed with Alstom in 2013 to modernize urban and suburban routes around Johannesburg and Cape Town.^[107] These units, known as X'trapolis Mega, feature advanced communications and have been progressively introduced since 2017 to replace aging rolling stock and improve reliability on electrified lines.^[108] Meanwhile, the Gautrain rapid transit system in Gauteng province utilizes 24 four-car EMU sets supplied by Bombardier (now Alstom) since its 2010 launch, serving high-capacity airport and urban links with a top speed of 160 km/h. In North Africa, Algeria has integrated diesel multiple units (DMUs) into its rail system during the 2010s to enhance urban and regional connectivity, particularly for shorter routes where electrification is limited. The first such DMUs were deployed by the Société Nationale des Transports Ferroviaires (SNTF) to support extensions of the national network, including links to Algiers' growing suburbs, as part of broader urban rail projects that also encompass the Algiers Metro's EMUs.^[109] In Egypt, the Cairo Metro and associated light rail systems rely on Chinese-manufactured EMUs to alleviate transport pressures in the densely populated capital. CRRC Sifang supplied the country's first urban EMUs in 2018 under a contract for six-car sets with a maximum speed of 120 km/h, which entered trial operations in 2022 on the interurban line from Cairo to 6th of October City and extensions to satellite cities like New Cairo, accommodating up to 2,222 passengers per train.^[110]^[111] These units incorporate energy-efficient regenerative braking and are maintained under a 12-year agreement to ensure operational continuity.^[112] The Middle East has seen the introduction of freight-oriented multiple units to bolster logistics in harsh desert conditions. In the United Arab Emirates, Etihad Rail launched its national freight network in February 2023, spanning 900 km and utilizing diesel-electric multiple units alongside heavy-haul locomotives to transport over 60 million tonnes annually, connecting ports like Khalifa to industrial hubs in Abu Dhabi and beyond.^[113]^[114] This expansion includes specialized designs for sand-prone routes, with the full passenger DMU fleet—21 units from CRRC—set for integration by 2026 to complement freight services.^[115] Operational challenges in these regions necessitate adaptations for extreme environments, particularly desert-resistant features in multiple units. Sand accumulation on tracks and equipment is mitigated through innovative designs like curved sand deflectors installed along rights-of-way and self-cleaning air intake filters on locomotives and power cars, as applied in Middle Eastern networks such as Saudi Arabia's North-South line and UAE's Etihad Rail.^[116]^[117] In sub-Saharan Africa, hybrid diesel-electric multiple units address non-electrified lines, with Kenya Railways deploying DMUs for regional services on extensions of the Standard Gauge Railway (SGR), including training programs completed in 2025 to operate these self-propelled units on diesel-powered segments from Naivasha toward Kisumu and Malaba.^[118] These hybrids provide flexibility for mixed-traffic routes amid ongoing electrification debates.^[119] Recent growth trends underscore investment in high-speed multiple units for enhanced regional connectivity. In Morocco, the Al Boraq high-speed line—Africa's first, operational since 2018 between Tangier and Casablanca—benefits from 2025 allocations of approximately $3.1 billion in national transport investments, including extensions totaling 430 km to Rabat, Marrakech, and other cities using Alstom TGV-derived EMU sets capable of 320 km/h.^[120]^[121] This funding, part of a broader 28 billion dirham infrastructure plan, aims to support events like the 2025 Africa Cup of Nations and boost economic integration across North Africa.^[122]

North America

In North America, multiple units (MUs) are increasingly adopted in commuter rail systems to enhance efficiency and reduce emissions, particularly in urban corridors facing aging infrastructure. In the United States, Southern California's Metrolink has pursued conversions to zero-emission multiple units (ZEMUs) through a partnership with Los Angeles Metro, funded by a grant to transform existing rail cars into battery-electric MUs for non-electrified routes, with initial pilots in the early 2020s aimed at integrating sustainable propulsion without full electrification. Similarly, Chicago's Metra has ordered eight two-car battery-electric multiple units (BEMUs) from Stadler Rail in 2024, valued at $154 million, with options for additional sets to serve low-volume branches and replace diesel locomotives, emphasizing compact designs that seat 112 passengers per set while complying with Federal Railroad Administration (FRA) safety standards. In Canada, GO Transit, operated by Metrolinx in the Greater Toronto Area, is modernizing its bi-level fleet with mid-life overhauls of 181 cars by Alstom starting in 2026, incorporating upgrades for future bi-mode operations that blend diesel and electric capabilities to support electrification plans along key corridors.^[123]^[124]^[125]^[126] For intercity and freight applications, MUs remain limited but are evolving with high-profile upgrades. Amtrak's Acela Express, serving the Northeast Corridor, introduced NextGen trainsets—electric multiple units built by Alstom as part of the Avelia Liberty platform—in August 2025, following delays from an initial 2023 target; these 28-trainset units achieve top speeds of 160 mph, offer 25% more seating capacity than predecessors, and feature advanced amenities like ergonomic seating and onboard Wi-Fi to boost ridership on the busiest U.S. passenger route. Freight MUs are experimental and scarce due to the dominance of locomotive-hauled consists, but BNSF Railway has tested hybrid configurations, including a 2020s trial pairing an experimental battery locomotive with diesel units on a Barstow-to-Stockton route, demonstrating potential for reduced fuel use in distributed power setups without full MU integration.^[127]^[128] Regulatory frameworks shape MU deployment, with the FRA enforcing stringent crashworthiness standards under 49 CFR Part 238 to protect passengers and crew in collisions, including requirements for anti-climber devices, crash energy management, and occupant protection in Tier I and II equipment—standards that have driven designs like those in Metra's BEMUs and Acela's NextGen sets. These rules, updated in 2023 to incorporate alternatives for high-speed trainsets, prioritize structural integrity over lighter European-style MUs, influencing North American adaptations for shared freight-passenger tracks. In Mexico, the Tren Maya project launched diesel multiple units (DMUs) from Alstom's X'trapolis family in December 2023, with full 1,554 km circuit operations by December 2024; these 42 Mexican-built trains, operating at up to 160 km/h, connect tourist sites across the Yucatán Peninsula while adhering to local safety norms derived from international standards.^[129]^[130]^[131] Emerging trends highlight electrification pilots amid widespread infrastructure challenges, such as deferred maintenance on legacy diesel lines. California's Caltrain completed its $2.4 billion electrification project in 2024, deploying 19 Siemens Mireo Plus B EMUs for revenue service starting in fall 2024, which have driven a 78% ridership surge by July 2025 through faster acceleration and quieter operations on the San Francisco-to-San Jose corridor, serving as a model for transitioning from aging diesel fleets to sustainable MUs. These initiatives reflect a broader push for MUs to address capacity constraints and environmental goals, though regulatory hurdles and high costs limit widespread adoption compared to locomotive-dominated networks.^[132]^[133]

Oceania and South America

In Oceania, multiple units play a key role in addressing the region's vast distances and varied terrain, particularly in Australia where electric multiple units (EMUs) dominate urban and intercity services. Queensland Rail operates the Tilt Train, a tilting diesel multiple unit (DMU) service introduced in 2003, capable of speeds up to 160 km/h on the Brisbane to Rockhampton route, enhancing connectivity across the state's electrified and non-electrified networks.^[134] The electric variant, built by Hitachi, functions as an EMU and supports sustainable travel on the same corridor, reducing reliance on traditional locomotives. In New South Wales, Sydney Trains' Waratah series represents one of Australia's largest EMU fleets, with 78 eight-car A sets and additional B sets totaling over 600 carriages, designed for high-capacity suburban operations since 2011.^[135] These double-decker units, manufactured by a consortium including Bombardier Transportation, prioritize passenger comfort and efficiency on the densely populated Sydney network.^[136] New Zealand's adoption of multiple units remains limited, focusing on regional and scenic routes where diesel multiple units provide flexible service amid challenging geography and low population densities. The ADL/ADC class DMUs, originally acquired from Western Australia in the 1990s, served Auckland's suburban network until their retirement in 2022, offering a cost-effective alternative to locomotive-hauled trains on non-electrified lines.^[137] For scenic operations, such as those on the Main North Line, DMUs like the ADK/ADB class have been used sporadically to navigate routes with tight curves and gradients, though most tourist services rely on hauled consists.^[138] Adaptations for New Zealand's seismic activity include reinforced underframes and suspension systems in EMUs on the electrified Wellington and Auckland lines, ensuring operational continuity during earthquakes by minimizing derailment risks.^[139] In South America, multiple units are integral to urban mass transit and freight in seismically active and tropical environments, with Brazil's Companhia Paulista de Trens Metropolitanos (CPTM) operating one of the continent's largest EMU fleets in São Paulo. The CPTM network features over 1,000 carriages across various series, including the Series 7000 with 80 eight-car sets totaling 640 cars, delivered between 2009 and 2011 to handle peak-hour demands on seven lines serving 95 stations.^[140] These stainless-steel EMUs incorporate tropical climate modifications, such as enhanced anti-corrosion coatings on underbodies and electrical components to combat high humidity and salt exposure in coastal areas.^[141] In Argentina, freight multiple units are emerging to modernize logistics, with CRRC supplying 50 DMUs in 2023—the largest such order in the country's history—for Trenes Argentinos operations, enabling efficient short-haul mineral transport on broad-gauge lines without full locomotive attachments.^[142] Chile's Metro de Santiago expansions emphasize resilient EMUs tailored to frequent earthquakes, with the network incorporating over 300 new cars since 2017 for Lines 3, 6, and extensions on Lines 2 and 4. Alstom's Metropolis series trains, deployed on these lines, feature earthquake-resistant designs including flexible bogies and automatic train control systems that maintain stability during seismic events up to magnitude 8.8, as tested in the 2010 Maule earthquake.^[143] EFE Trenes de Chile has ordered 32 additional EMUs from CRRC for commuter extensions, including the 61 km Santiago-Melipilla line, with deliveries starting in 2026 to boost capacity amid urban growth.^[144] These units include base isolation mounts to absorb shocks, drawing from Chile's advanced seismic engineering standards.^[145] Recent projects highlight expanding multiple unit deployments. In Peru, the Lima Metro's Line 2, which began partial operations in 2023 and continues expanding into 2025, has introduced initial six-car EMUs from Hitachi Rail to serve the 27 km east-west corridor connecting up to 1.5 million daily passengers with earthquake-dampening suspensions adapted for the Andean region.^[146]^[147] In Papua New Guinea, proposals for mining freight multiple units are advancing under the 2023 National Railway Plan, targeting iron ore transport from remote highlands to ports via lightweight DMUs on a proposed 300 km network, though full implementation awaits funding.^[148]