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Multiple integrated laser engagement system

The Multiple Integrated Laser Engagement System (MILES) is a laser-based simulation device designed for military force-on-force training, using eye-safe infrared lasers to replicate direct-fire weapon engagements and provide immediate casualty assessment in mock battlefield scenarios without the risks associated with live ammunition.^[1]^[2] Development of MILES began in the early 1970s under the U.S. Army's Training Support Center at Fort Eustis, Virginia, with initial prototypes tested in 1975 following experiments like the Combat Developments Experimentation Command's HELLFIRE project.^[1] In April 1976, Xerox Corporation was awarded a contract for engineering and production, leading to the system's fielding in the early 1980s as a key tool for enhancing soldier lethality through realistic, two-sided combat simulation.^[1] Over the decades, MILES has undergone multiple upgrades, including the Instrumentable-MILES (I-MILES) variant introduced around 2012, which expanded compatibility to platforms like the M4A1 carbine, M1 Abrams tank, and Bradley fighting vehicle while integrating with broader training instrumentation.^[3]^[2] At its core, MILES comprises weapon-mounted laser transmitters boresighted to the firearm's sights, photodetector sensors providing 360-degree coverage on personnel harnesses or vehicle arrays, decoder electronics to process signals, and casualty indicators such as audio tones, LED lights, or smoke emitters to denote hits, injuries, or kills.^[1]^[4] The system operates by emitting coded laser pulses that, upon detection by a target's sensors, are analyzed for validity—factoring in beam duration (e.g., 1 second for tank simulations or 9-10 seconds for anti-tank guided missiles like the TOW)—to simulate weapon-specific effects, including night operations with compatible sights and adjustments for environmental variables.^[1] These manworn and vehicle-mounted kits are modular and lightweight, enabling ergonomic use in diverse settings from homestations to urban operations training sites.^[4]^[3] MILES has been a staple for the U.S. Army, Marine Corps, and other branches, as well as allied militaries worldwide, supporting tactical exercises that cover small arms, crew-served weapons, and armored systems while promoting safe, cost-effective training.^[2]^[3] However, limitations such as incomplete coverage (e.g., only 45% of a brigade at training centers), inability to simulate indirect fires or penetrations through obstacles, and vulnerability to interference from foliage or precipitation have prompted modernization efforts.^[2] As of 2025, the U.S. Army's Program Executive Office for Simulation, Training and Instrumentation is advancing replacements like the Synthetic Training Environment-Live Training System (STE-LTS), which leverages GPS, computer vision, and augmented reality for more comprehensive, data-rich simulations. Recent advancements include the integration of haptics technology in July 2025 and the fielding of STE-LTS Mortar systems in August 2025, with full transition expected by the late 2020s.^[5]^[6]^[7]^[8]^[9]

Overview and Principles

Definition and Purpose

The Multiple Integrated Laser Engagement System (MILES) is an eye-safe, laser-based training device that simulates the effects of direct-fire weapons, such as rifles, machine guns, and anti-tank missiles, by emitting coded infrared laser pulses to represent bullets or projectiles during military exercises.^[1]^[10] This system enables participants to engage in simulated combat scenarios while using their standard weapons and vehicles, with detectors on personnel and equipment registering "hits" to assess casualties in real time.^[11] The primary purpose of MILES is to deliver realistic force-on-force training that replicates battlefield conditions, providing immediate auditory and visual feedback on engagement outcomes to reinforce effective tactics and decision-making.^[1]^[12] By substituting low-cost laser simulations for live ammunition, it significantly reduces training expenses—such as the procurement and logistics of munitions—while eliminating the safety hazards associated with real firepower, allowing for safer, more frequent exercises at scales from squad to brigade levels.^[11] Developed for the U.S. Army in the early 1970s at the Training Support Center in Fort Eustis, Virginia, MILES emerged in the post-Vietnam War era to address shortcomings in training realism for the transitioning all-volunteer force, enabling immersive force-on-force drills that better prepared troops for modern combat without live-fire risks.^[1]^[11] By 2025, the system has been adopted by armed forces in numerous countries worldwide, reflecting its proven value in global military training programs.^[13] The global MILES market, valued at $1.2 billion in 2023, is projected to reach $2.3 billion by 2032, fueled by rising demand for cost-effective, advanced simulation technologies amid increasing defense budgets.^[14]

Core Operating Principles

The Multiple Integrated Laser Engagement System (MILES) employs infrared laser technology typically operating at wavelengths around 830–904 nm, utilizing diode lasers with pulse widths around 200 ns to ensure eye safety while simulating weapon fire over tactical distances. This near-infrared spectrum is selected for its low visibility and compliance with eye-safety standards such as Class 1 or 3R per ANSI Z136.1, with a nominal ocular hazard distance of 10 meters unaided, allowing safe use in training environments without risk of retinal damage. The laser pulses are generated upon activation of the weapon's blank-firing adapter, which requires the firing of blank ammunition to trigger transmission, thereby integrating auditory and recoil feedback to mimic live-fire realism.^[15]^[16]^[17]^[18] Laser pulses are modulated to encode critical parameters including the shooter's identification, weapon type, ammunition type, range to target (derived from pulse timing or pre-set values), and fire mode, such as single shot for rifles like the M16A2 or burst mode for machine guns like the M240, which simulates 6-9 rapid pulses. This encoding follows standards like PMT 90-S002 for message structure, ensuring compatibility across system components and allowing differentiation between small arms and heavier ordnance. The modulation scheme uses a series of on-off keying patterns within the infrared beam, transmitted in a narrow cone to replicate projectile trajectory while avoiding wide-area illumination.^[17]^[10] Upon reception, target sensors—typically photodetectors sensitive to the near-infrared wavelengths—decode the incoming pulses over a detection field of 360° azimuth and ±45° elevation, assessing the hit based on signal strength, timing, and encoded data. The system calculates effective range from the pulse characteristics and applies geometric factors like incidence angle to determine hit validity, rejecting off-angle or out-of-range signals to simulate ballistic drop and dispersion. This decoding logic interfaces with internal processors to evaluate the impact against predefined hit profiles, such as a 0.2 m diameter circle within a 1.5 m × 2.5 m rectangular zone on the target.^[15]^[17] Casualty outcomes are determined through probabilistic models embedded in the system's lethality algorithms, which reference probability-of-kill (Pk) tables to simulate real-world wounding effects without physical projectiles. These tables, standardized in PMT 90-S002, factor in range-dependent lethality, weapon hierarchy, and hit location: vital area strikes (e.g., head or torso center) result in immediate incapacitation, while peripheral hits invoke statistical wounding probabilities that approximate ballistic trauma, such as 50-90% kill chance for rifle rounds at close range decreasing with distance. The models incorporate casualty assessment criteria distinguishing between immediate kills, mobility impairments, or survival states, ensuring training reflects variable combat outcomes based on physiological and tactical variables. Blank-firing adapters enforce this simulation by linking laser emission to weapon recoil, preventing "dry-fire" engagements and reinforcing fire discipline.^[10]^[17]^[11]

History and Development

Origins in the 1970s

Development of the Multiple Integrated Laser Engagement System (MILES) began in early 1973 under the U.S. Army's Training and Doctrine Command (TRADOC) at the Training Support Center, Fort Eustis, Virginia. Initial experiments, including the Combat Developments Experimentation Command's (CDEC) HELLFIRE project from 1974 to 1975, tested laser prototypes for simulating direct-fire engagements.^[1] The system emerged in the mid-1970s as part of a broader U.S. Army effort to reform training practices in the wake of the Vietnam War, which had exposed significant deficiencies in realistic combat simulation and force-on-force exercises. Post-1973 analyses by the Army's Training and Doctrine Command (TRADOC) under leaders like Maj. Gen. Paul F. Gorman highlighted the need for non-lethal, objective methods to assess tactical performance, moving away from subjective umpire judgments and live-fire risks. In November 1976, Gorman proposed concepts for advanced training centers in a key paper, laying the groundwork for laser-based systems like MILES to simulate direct-fire engagements and enhance readiness against evolving threats.^[19]^[20] In 1976, the U.S. Army awarded a development contract to Xerox Electro-Optical Systems (EOS) through its Project Manager for Training Devices (PM TRADE), tasking the company with prototyping a laser engagement system for infantry and vehicle use. PM TRADE, under TRADOC, oversaw the project to ensure integration with emerging training doctrines, including plans for the National Training Center at Fort Irwin. This collaboration focused on creating wearable laser emitters and detectors to mimic battlefield hits without ammunition, with initial prototypes emphasizing portability and compatibility across Army units.^[1]^[19] Early prototypes underwent first field tests in January 1979 at Fort Hood, Texas, where they were evaluated on tank platoons and infantry squads to assess hit detection accuracy and overall feasibility. These tests validated the system's potential for realistic simulations but revealed initial limitations, including short effective ranges constrained by environmental factors like smoke and dust, as well as vulnerability to sunlight interference that disrupted boresight alignment and sensor performance. Despite these challenges, the trials confirmed MILES' role in objective casualty assessment, paving the way for refinements before wider fielding.^[19]

Standardization and Key Milestones

The standardization of the Multiple Integrated Laser Engagement System (MILES) began under the oversight of U.S. Army training commands and materiel developers in the 1980s, transitioning to formalized management by predecessor organizations of the Program Executive Office for Simulation, Training and Instrumentation (PEO STRI) to ensure consistent integration into force-on-force exercises across units.^[21] This oversight facilitated the resolution of early prototype limitations, such as limited range and susceptibility to environmental factors, through refined encoding protocols that encoded player identification in laser pulses to prevent cheating by verifying hits between specific participants.^[22] A significant advancement occurred in 1989 when the U.S. Army Materiel Command awarded Simulaser a contract valued at approximately $35 million for the production of twelve variants of MILES equipment, enabling broader standardization and deployment for individual and crew-served weapons.^[23] During the 1980s, MILES achieved widespread deployment, particularly at the National Training Center at Fort Irwin, where it was used to simulate direct-fire engagements in realistic multi-echelon scenarios involving infantry and armored units.^[22] By the early 1990s, the system expanded to vehicle platforms, incorporating detectors and transmitters on tanks and other combat vehicles to support combined arms training and address gaps in mechanized force simulations. Key milestones included the 1991 rollout of MILES II, an upgraded version that improved hit detection accuracy and integration with training instrumentation, followed by the introduction of Simulated Area Weapons Effects (SAWE) in 1992, which used GPS and radio frequency messaging to simulate indirect fire and area munitions impacts on units and vehicles.^[24] In 2006, Lockheed Martin launched MILES XXI, a modular upgrade that enhanced compatibility with modern weapons and provided better data logging for after-action reviews, further standardizing the system under PEO STRI for 21st-century training requirements.^[25]

System Components

Weapon and Personal Transmitters

The weapon and personal transmitters in the Multiple Integrated Laser Engagement System (MILES) consist of clip-on laser modules designed to simulate direct fire from individual small arms, such as rifles, pistols, and machine guns. These transmitters emit eye-safe infrared laser pulses that encode the type of weapon and fire mode, allowing receivers on opposing personnel or equipment to register simulated hits accurately. For example, the M16 rifle transmitter uses a pulse-code modulation (PCM) scheme with a 3 kHz bit rate and 6-bit codes, transmitting sequences like 10 pulses for a single-shot kill message, while machine guns such as the M60 employ adjustable hit/miss words (up to 255) to differentiate burst fire.^[26]^[27] Pistol transmitters follow similar encoding but with shorter-range adaptations for close-quarters simulation.^[26] Personal integration of these transmitters involves mounting them directly on the user's weapon, synchronized with blank-firing adapters (BFAs) that detect the acoustic signature of blank rounds to trigger laser emission, thereby providing realistic recoil and firing feedback without live ammunition. BFAs, such as those for the M16, use microphones tuned to 142-158 dB at 10-14 Hz to ensure one-to-one correspondence between blanks and laser pulses, preventing unauthorized firing.^[26]^[27] This setup extends to broader personal gear compatibility, where transmitters interface with helmet and vest-mounted components for seamless operation during training. Detection systems respond to these encoded pulses by activating alarms or visual indicators upon hit registration.^[27] Key specifications for these transmitters emphasize portability and endurance for extended field exercises. Typical units, like the M16/M4 clip-on module, weigh approximately 1.0 lb (0.45 kg) including battery, with a 9V alkaline or lithium power source providing up to 100 hours of operation under low-drain conditions or 10,000 shots in active use.^[27]^[17] Effective direct-fire range reaches up to 550 m for rifles like the M16A2/M4 with 90-95% hit probability under standard conditions, extending to 800 m for machine guns like the M249 SAW, though theoretical maximums can approach 2.5 km in optimal scenarios.^[26]^[17] In modern Instrumented-MILES (I-MILES) variants, such as the Individual Weapons System (IWS), transmitters incorporate enhanced encoding per the MILES Communication Code (MCC97) for player identification (PID) and ammo type, improving fidelity in networked training.^[17]

Detection and Sensor Systems

The detection and sensor systems in the Multiple Integrated Laser Engagement System (MILES) are designed to receive infrared laser pulses emitted from weapon-mounted transmitters, decoding them to simulate impacts on personnel and vehicles during training. These systems convert incoming laser energy into electrical signals for processing, enabling real-time casualty assessment without live ammunition. The sensors are tuned to specific near-infrared wavelengths to ensure eye safety and compatibility with encoded signals that identify the firing weapon and engagement parameters.^[1] Personal sensor configurations typically include an H-harness vest equipped with multiple detectors positioned around the torso for broad coverage, complemented by a helmet-mounted halo band that encircles the head to provide 360-degree azimuth detection with elevation coverage of ±45 degrees off the centerline. This arrangement ensures comprehensive protection simulation for the upper body and head, with detectors converting laser hits into decoded signals that trigger immediate feedback. Upon detection, the system activates audio alerts such as a continuous tone lasting one minute for a "kill" and a one-second tone for a near miss, alongside visual indicators to notify the user of the simulated injury.^[1] For vehicle applications, MILES employs belt-mounted sensor arrays or wireless detectors affixed to armored platforms like tanks and armored personnel carriers (APCs), offering all-around detection to replicate vulnerabilities in crew-served equipment. These sensors integrate with Individual MILES (I-MILES) components worn by vehicle crew members, allowing hits on the vehicle to propagate effects to individual personnel for layered simulation of crew incapacitation. A standard vehicle kit includes six wireless sensors for distributed placement, enhancing detection reliability across the platform's surface.^[28]^[1] Key features of MILES sensors include optical filters that isolate the system's encoded infrared pulses, mitigating environmental interference from sunlight or other light sources to reduce false positives. Status is conveyed via LED indicators on the control modules, signaling operational readiness, battery levels, and hit confirmations. Additionally, detected hits interface with MILES casualty cards, which role-players use to assess and apply variable wound effects, such as mobility restrictions or medical evacuation needs, based on predefined injury probabilities.^[1]^[29]^[4]

Operation and Training Applications

Simulation of Combat Engagements

The Multiple Integrated Laser Engagement System (MILES) replicates battlefield dynamics in real-time during training exercises by utilizing line-of-sight infrared laser transmissions to simulate the trajectories of direct-fire weapons. Weapon-mounted transmitters emit coded laser pulses upon firing blank ammunition, projecting an invisible infrared beam aligned with the weapon's sights to mimic projectile flight paths. These pulses travel in a straight line and are detected by photosensitive receivers on personnel harnesses, helmets, or vehicle panels if they intersect the target's sensors within the designated hit zone, delivering instantaneous audio and visual cues to indicate casualties or effects. This setup allows participants to experience realistic force-on-force engagements without live ammunition, enhancing tactical decision-making under simulated combat stress.^[11]^[30] Range gating mechanisms in MILES enforce weapon-specific distances by encoding the laser pulse with data corresponding to the simulated firearm's effective range, preventing registrations of hits beyond realistic limits. For instance, pistol configurations limit engagements to about 50 meters, while rifle setups extend to 800 meters, achieved through pulse modulation that the receiving detectors interpret to validate proximity based on signal characteristics and weapon type. This integrates with core hit logic principles, where the receiver decodes the incoming signal to confirm alignment, range compliance, and lethality factors like multiple hits required for incapacitation. The result is a faithful reproduction of ballistic constraints, compelling trainees to maneuver within authentic engagement envelopes.^[31]^[1] MILES extends simulation capabilities to multi-role scenarios, supporting infantry, vehicular armor, and indirect fire through modular add-ons that expand direct-fire laser interactions into broader tactical contexts. Infantry units employ man-worn transmitters and detectors for close-quarters replication, while armor simulations use vehicle-integrated systems to model tank main guns or anti-armor missiles, registering impacts on reinforced sensor arrays. Indirect fire add-ons, such as those for mortars, incorporate geometric pairing or observer-linked coding to simulate arcing trajectories and area effects, allowing artillery teams to coordinate with laser-based ground forces. Night operations are facilitated by the infrared laser's compatibility with night vision goggles, as the pulses remain effective in darkness without visible light emission, maintaining immersion across lighting conditions.^[10]^[32] Central to MILES operations are robust safety protocols, employing eye-safe Class 1 lasers with output power limited to prevent any permanent physiological or material damage. These low-energy infrared emissions comply with laser safety standards, ensuring no risk of eye injury or equipment degradation even during prolonged, direct exposure in dynamic training environments. Operators follow procedural safeguards, such as avoiding aimed discharges at close range and using protective eyewear if needed, to uphold the system's non-lethal integrity while delivering high-fidelity combat simulation.^[33]^[16]

Data Collection and After-Action Review

The Multiple Integrated Laser Engagement System (MILES) incorporates central data systems, such as the Wireless Instrumentation Tracking System (WITS), to log engagement events including hits, participant movements, and performance scores during live training exercises. WITS, a key component of the Instrumentable-MILES (I-MILES) suite, uses wireless technology to transmit real-time casualty assessment data to command posts and centralized analysis facilities, enabling comprehensive capture of tactical interactions without interrupting the flow of training. This instrumentation integrates with broader systems like the Combat Training Center-Instrumentation System (CTC-IS) to aggregate high-fidelity engagement data for subsequent evaluation. After-action review (AAR) processes in MILES rely on dedicated software tools that facilitate detailed debriefings through replay of exercise timelines, visualization of kill chains, and analysis of key metrics such as hit percentages and response times. Cubic Corporation's Exercise Control (EXCON) and AAR software platforms, which are PC-compatible and designed for tactical engagement simulations, deliver dynamic performance feedback by processing logged data into interactive reports and simulations. These tools often feature tablet- or laptop-based interfaces for meta-tagging specific events, allowing trainers to pause, rewind, and annotate replays to highlight decision-making and outcomes. MILES data capabilities support real-time analytics via mobile applications and software extensions, providing feedback on metrics like positioning and engagement efficacy through wireless personal area networks, as of 2025. However, MILES is undergoing transition to the Synthetic Training Environment-Live Training System (STE-LTS) by the late 2020s for more advanced integrations.^[5]^[2]

Versions and Upgrades

Early MILES Systems (1978–1990s)

The Multiple Integrated Laser Engagement System (MILES) was first fielded by the U.S. Army around 1980, establishing a foundational laser-based simulation for direct-fire force-on-force training that resembled commercial laser tag but adapted for military use.^[1]^[34] The initial iteration employed eye-safe infrared laser transmitters mounted and boresighted to weapon sights, such as rifles or missile launchers, paired with photodetector sensors worn on personnel harnesses or affixed to vehicles for 360-degree coverage. Effective engagement ranges reached up to 3,000 meters for systems like the TOW missile, requiring sustained tracking—typically 9 seconds—for a valid "hit" registration, while small arms simulations operated effectively at shorter distances to simulate realistic battlefield dynamics. The MILES 2000 upgrade program, initiated in 1993, further improved these capabilities.^[11] Early MILES setups faced notable technical constraints, including strict line-of-sight requirements that prevented laser propagation through obscurants like smoke or vegetation, thereby limiting tactical realism in obscured environments. The system was also prone to exploitation, as "hits" merely activated audible or visual alerts without disabling the transmitter, allowing soldiers to continue firing; cheating via sensor blocking with tape, mud, or body positioning further undermined training integrity, prompting design emphases on improved feedback to deter such behavior. These vulnerabilities highlighted the analog-heavy nature of the technology, which prioritized basic hit detection over automated enforcement.^[1]^[27]^[35] Upgrades in the 1980s addressed identification and engagement tracking through integrations by Simulaser Corporation, which introduced coded laser pulses for distinguishing individual players and automating scorekeeping during exercises. In August 1989, the U.S. Army Materiel Command awarded Simulaser a $36 million contract—valued at $6 million below estimates—for producing 12 variants of MILES equipment, including enhanced transmitters and controllers to support these features across infantry units. Concurrently, MILES Plus configurations extended compatibility to crew-served weapons, such as the M249 squad automatic weapon and M240B machine gun, via specialized transmitters that simulated suppressive fire patterns and area suppression effects without requiring full weapon disassembly.^[23]^[36] Despite these advancements, core limitations persisted through the 1990s, notably the delayed full vehicle integration until the late 1980s, when dedicated kits with multiple detectors were developed for platforms like the M1 Abrams tank and M2 Bradley infantry fighting vehicle to enable combined arms scenarios. Casualty assessment relied on manual processes, where sensor activations signaled potential "wounds" based on hit location and weapon caliber, but enforcement depended on self-reporting by participants or intervention by exercise umpires to adjudicate kills, mobility restrictions, or mission impacts. These manual elements, while cost-effective, often introduced subjectivity and reduced the system's objectivity in large-scale maneuvers.^[1]^[36]

Modern Integrated Systems (2000s–Present)

The evolution of the Multiple Integrated Laser Engagement System (MILES) in the 2000s and beyond has focused on integrating digital networking, instrumentation, and expanded simulation capabilities to address the complexities of contemporary training environments. These modern systems build on earlier analog foundations by incorporating wireless communication, real-time data processing, and compatibility with broader training architectures, enabling more realistic force-on-force exercises across diverse terrains and unit types. Key advancements emphasize interoperability with vehicle platforms, enhanced detection ranges, and support for indirect fire simulations, allowing for scalable training from individual soldiers to combined arms operations. MILES XXI, developed by Lockheed Martin and fielded starting around 2006, introduced significant improvements in system modularity and performance for dismounted and mounted forces. This version comprises a family of components for infantry, vehicle, anti-tank, and independent target simulations, providing eye-safe laser-based engagement that mimics real weapon effects while supporting after-action analysis through instrumentation. It enhances training realism by integrating with area effects simulations, such as those for artillery, through compatibility with Simulated Area Weapons Effects (SAWE) modules that replicate indirect fire patterns using GPS and radio frequency messaging to designate impact zones and casualties.^[25]^[37]^[38] The Instrumentable-MILES (I-MILES) suite, evolving from the 2010s onward, further advances vehicle-centric training through systems like the Individual Weapon System 2 (IWS2) and Combat Vehicle Tactical Engagement Simulation System (CVTESS), primarily developed by Saab Training USA. IWS2 equips individual and crew-served weapons with lightweight, alignment-maintaining laser transmitters and detectors, supporting networked engagements up to several kilometers while interfacing with vehicle instrumentation for seamless soldier-vehicle interactions. CVTESS overlays tactical vehicles with shooter kits and vulnerability panels, incorporating GPS-enabled tracking for real-time positioning and data transmission during exercises, which feeds into after-action reviews via the Weapon Impact and Target System (WITS) for precise hit assessment and scenario replay. These components integrate with external simulators and range control systems, such as the Home Station Instrumentation Training System (HITS), to blend live training with virtual elements for cost-effective, high-fidelity rehearsals.^[25]^[4]^[39] In the 2020s, I-MILES has seen incremental upgrades aligned with the U.S. Army's Synthetic Training Environment (STE) initiative, incorporating data analytics for dynamic scenario generation and expanded interoperability with emerging technologies. Modern iterations support integration with unmanned systems for hybrid live-virtual training, enabling drone-assisted surveillance feeds to inform laser engagements in complex urban settings, while market expansions by contractors like Saab and Lockheed Martin emphasize modular kits for urban warfare simulations, including close-quarters battle and multi-domain operations. These developments prioritize real-time telemetry and AI-assisted debriefing to enhance decision-making under simulated stress, ensuring adaptability to evolving threats without overhauling legacy hardware. As of November 2025, while I-MILES remains in widespread use for force-on-force training, the U.S. Army is advancing replacements like the Synthetic Training Environment-Live Training System (STE-LTS), which leverages GPS, computer vision, and augmented reality for more comprehensive simulations, with full transition expected by the late 2020s.^[40]^[41]^[42]^[5]^[14]

Users and Global Adoption

National Military Forces

The United States military has been the primary user of the Multiple Integrated Laser Engagement System (MILES) since the late 1970s, employing it for realistic force-on-force training across various units and platforms.^[12] The system is deeply integrated into major training exercises at the National Training Center (NTC) at Fort Irwin, California, where it supports large-scale maneuver simulations, and the Joint Readiness Training Center (JRTC) at Fort Johnson, Louisiana, enabling joint and multi-domain operations practice.^[19]^[43] MILES variants are fielded to equip dismounted soldiers, vehicles, and aviation assets, supporting annual rotations at these instrumented sites.^[25] MILES has seen adoption by numerous allied and partner militaries worldwide, enhancing tactical training realism and safety.^[44] Notable users include the Canadian Armed Forces, which incorporate MILES into unit-level exercises.^[45] The Latvian National Armed Forces received MILES systems in 2019, attaching them to weapons, vehicles, and personnel for target practice and tactical data recording during engagements.^[46] Similarly, the Romanian Army has expanded its MILES inventory through contracts for individual weapon simulators, supporting force-on-force scenarios with laser emitters and blank cartridge integration.^[47] Ukraine's Armed Forces began integrating MILES into company-level tactical exercises post-2014, transitioning from basic drills to laser-based simulations alongside domestic LaserTag systems to improve combat readiness amid ongoing conflicts.^[48] National militaries often customize MILES for local needs; for instance, the German Bundeswehr employs the AGDUS (Ausbildungsgerät Duellsimulator) variant, a laser-supported duel simulator that replicates small arms and vehicle effects with enhanced hit location precision, though it remains incompatible with standard MILES for joint operations.^[49] These adaptations underscore MILES's role in scaling operational training across diverse terrains and doctrines, with global deployments emphasizing cost-effective casualty simulation over live-fire risks.^[50]

Civilian and Commercial Applications

Private firms have adapted MILES technology for law enforcement and private security training, providing realistic force-on-force simulations without live ammunition. Companies such as S&S Training Solutions offer courses utilizing MILES 2000 systems on real-steel firearms with blank rounds, enabling participants to engage in tactical scenarios like close-quarters battle and SWAT operations. Similarly, One Shepherd Leadership Institute employs MILES in its educational programs to develop leadership skills through simulated combat exercises, targeting civilians, nonprofits, and security professionals. These adaptations emphasize safety and affordability, allowing non-military users to train in dynamic environments that mimic real-world threats.^[51]^[52] Commercial expansions of MILES principles extend to entertainment and recreational sectors, including variants used in laser tag and paintball arenas for enhanced tactical gameplay. Systems inspired by MILES incorporate infrared lasers, sensors, and team coordination features to simulate weapon effects and strategy, appealing to recreational players seeking military-style immersion. By 2025, integrations with virtual reality (VR) have emerged in civilian fitness and team-building programs, combining laser detection with immersive simulations for corporate events and personal training apps that track performance metrics. Laser Ammo, for instance, provides scaled-down laser engagement kits tailored for U.S. police departments, facilitating building-clearing drills and marksmanship practice in controlled settings.^[53]^[54]^[55] The non-military segment of the MILES market, driven by law enforcement demand, contributes to overall growth projections from $1.1 billion in 2024 to $1.9 billion by 2030 at a CAGR of 8.7%, reflecting broader adoption in training simulations beyond defense applications.^[56]

References

[1]
[PDF] The Multiple Integrated Laser Engagement System (MILES ... - DTIC
Multiple Integrated Laser Engagement System (MILES) were tested in 1975, and in April 1976 XEROX Corp-oration , Pasa !ese ,. California, was awarded the ...
[2]
Army to Replace 'Laser Tag' System for Soldier Training
Dec 29, 2023 · The Army is looking to replace the Multiple Integrated Laser Engagement System, better known as MILES.
[3]
Army Wants to Finally Replace Decades-Old MILES Gear for More ...
Mar 18, 2021 · The current Instrumentable-Multiple Integrated Laser Engagement System, or I-MILES, is designed to work on everything from M4A1 carbines to M1 ...
[4]
Manworn Systems | Cubic
We offer a variety of portable, manworn Multiple Integrated Laser Engagement System (MILES) kits that provide effective, force-on-force engagement training.
[5]
REALITY CHECK | Article | The United States Army
Jul 1, 2025 · PEO STRI, Bahbaz said, is also investing in computer vision technology as a potential replacement for lasers currently used by the ...
[6]
PEO STRI's STE-LTS Team Demonstrates Capabilities at ... - DVIDS
Apr 7, 2025 · According to Monaghan, PM TRADE's STE-LTS will eventually replace the longstanding Multiple-Integrated Laser Engagement Systems (MILES), ...
[7]
IT2EC NEWS: U.S. Army Touts Success Fielding New Training Tech
3/25/2025 ... Also in the marksmanship realm, the PEO continues to work on a replacement for the Instrumentable Multiple Integrated Laser Engagement System, ...
[8]
[PDF] TM 23-6920-706-10
Aug 30, 2014 · The use of the Multiple Integrated Laser Engagement System (MILES) may induce violent evasive maneuvers in response to “near miss” signals.<|control11|><|separator|>
[9]
Multiple Integrated Laser Engagement System (MILES)
Aug 7, 1999 · MILES is a training system that provides a realistic battlefield environment for soldiers involved in training exercises.Missing: definition | Show results with:definition
[10]
Soldiers Use State-of-the-Art Laser Engagement System to Enhance ...
Sep 8, 2016 · He said the goal of I-MILES is to make system components lighter, more ergonomically designed, instrumentable and designed to have longer ...Missing: definition | Show results with:definition
[11]
https://man.fas.org/dod-101/sys/land/miles.htm
[12]
Multiple Integrated Laser Engagement System Market - Dataintelo
The global market size for Multiple Integrated Laser Engagement System (MILES) is projected to grow from USD 1.2 billion in 2023 to USD 2.3 billion by 2032, ...
[13]
[PDF] Control of Hazards to Health From Laser Radiation - DTIC
Jan 31, 2006 · ... (904 nm), diode laser, used in a MILES having a pulse width of 200 ns. The beam is circular, and its diameter at the exit port is 1.5 cm. The ...
[14]
[PDF] ,:,, of the MILES - OSTI
The MILES employ the Small Arms Laser Transmitter (SALT). The SALT laser is an. Infrared (IR) laser diode operated at a primary wavelength of 904 nanometers (nm) ...Missing: principles | Show results with:principles
[15]
None
Summary of each segment:
[16]
[PDF] The Origins and Development of the National Training Center, 1976
The Multiple Integrated Laser Engagement System. The Multiple Integmted Laser Engagement System, or MILES, developed by Xerox Electro-Op- tical and fielded ...
[17]
[PDF] The Army's Training Revolution, 1973-1990: An Overview
Apr 13, 1990 · Seventh Army Training Command, the Program Manager for Training. Devices (PM TRADE) and other commands and agencies, began building a ...
[18]
[PDF] SECURITY OFFICER TACTICAL TRAINING ISSUES INVOLVING ...
Laser Engagement System (MILES) equipment developed by Xerox. Electro-Optical Systems (EOS) under contract to the U.S. Army Office ... Co., Houston, TX, 1978.
[19]
History - PEO STRI
The official website for the Program Executive Office Simulation, Training and Instrumentation - PEO STRI.
[20]
30 Years of Training Excellence: | Article | The United States Army
Aug 4, 2009 · Another critical innovation has been the deployment of the Multiple Integrated Laser Engagement System (MILES). Every weapon has an encoded ...
[21]
[PDF] Annual Historical Review FY89 - DTIC
This Annual Historical Review (AHR) of the Headquarters, U.S. Army Materiel Command during fiscal year 1989 ... Long Range Plan ...<|control11|><|separator|>
[22]
[PDF] NTC Scorpions': SAWE/MILES II, (Simulated Area Weapons Effects ...
Mar 25, 1998 · BORESIGHT THE MAIN GUN. NOTE: RECORD GPS ZERO DATA FOR FUTURE REFERENCE. 1. POSITION TANK ON LEVEL GROUND, WITH GUN OVER FRONT SLOPE. 2. SET UP ...
[23]
Instrumentable-multiple Integrated Laser Engagement System (I ...
The system provides FOF training capabilities for both Tactical and Combat vehicles while implementing a component-based architecture. Additionally, VTESS ...
[24]
[PDF] Trainer Engineering Report (Final) for MILES. Volume I. Revision
Apr 22, 1981 · The key elements of the systems are the low power pulsed laser transmitters used to simulate the weapons and the inexpensive silicon ...
[25]
[PDF] Trainer Engineering Report (Final) for MILES. Volume 2. Revision
This final document reflects the As-built MILES hardware design prior to delivery to OT III in Germany (Fall 1979). It has been updated in March 1981 to include ...
[26]
[PDF] FORT DEVENS, MA - Army Garrisons
Six wireless MILES sensors are included in each kit. The vehicle commander ... Halo encircles the head providing 360 degrees coverage as a target. The ...
[27]
Improving Tactical Combat Casualty Care to save Soldiers' lives
Jan 28, 2016 · To add realism, the Army is looking at replacing the 30-year-old paper MILES Casualty Card. The cards only reflect the moment of injury, but ...Missing: compatibility | Show results with:compatibility
[28]
https://home.army.mil/devens/application/files/8016/4874/4703/211201_TSC_Devens_Catalog.pdf
[29]
Multiple Integrated Laser Engagement System (MILES) - PRC68.com
Jul 14, 2010 · 1997 Contract awarded for 200 MILES 2000 systems after a successful ... , Jul 25, 1978, 434/22, 362/113 - discrete components 4352665 ...Missing: Xerox | Show results with:Xerox
[30]
PM TRADE Takes Aim at Training with Indirect Fire - USAASC
Aug 20, 2012 · These add-ons for the mortar allow Soldiers to operate their equipment and provide an opportunity to join in FOF training. (U.S. Army photos ...
[31]
Laser Safety Evaluation of the MILES and Mini MILES Laser Emitting ...
Oct 22, 2025 · The purpose, to verify that these components, not only meet the Class 1 (eye safe) laser hazard criteria of the CDRH Compliance Guide for Laser ...
[32]
US Army MILES Photodiode - Industrial Alchemy
Oct 2, 2023 · The Multiple Integrated Laser Engagement System, or MILES, was a program started in 1978 by the United States Army with the goal of using lasers for simulated ...Missing: contract | Show results with:contract
[33]
[PDF] Winning the Airland Battle with Tactical Engagement Simulation,
Mar 31, 1986 · Souza, Charles R., SFC, "MILES Cheating: Key to Failure," Army. Trainer, Vol. 4, 4, Summer 1985, pp. 3-5. 15. Stengel, Richard and Worrell ...
[34]
[PDF] MILES Catalog
The device permits firing of blank .50 caliber ammunition with the M2 machine gun. DVC# 07-59. NSN# 1005010917510. BFA 21 FOR 240C ON ...
[35]
Lockheed Martin Selected for Role on U.S. Army Simulation ...
... MILES XXI, Combat Training Center-Objective Instrumentation System and the Common Training Instrumentation Architecture. Headquartered in Bethesda, Md ...<|separator|>
[36]
[PDF] Simulation Training Strategies for Force XXI Final Technical Report
The Simulated Area. Weapons Effects (SAWE)/MILES II devices simulate the effects of the Army's indirect fire weapons, plus area effects of enemy land mines ...
[37]
US Army orders I-MILES systems - Shephard Media
Aug 1, 2016 · The system works by transmitting laser messages when blank ammunition is fired by a military weapon fitted with a small arms transmitter.Missing: battery weight pulse encoding
[38]
[PDF] Weapon Systems Handbook 2020-2021 - Army.mil
This handbook acquaints you with US Army's current and future weapon systems, including program descriptions, status, specifications, and benefits to the ...
[39]
[PDF] The Synthetic Training Environment - AUSA
Multiple Integrated Laser Engagement System attachment on the M-4 rifle. The STE cross- functional team is working to develop modern upgrades to this and ...
[40]
Saab and Lockheed Martin provide Modernized VTESS Code for the ...
... Saab will update current Instrumentable Multiple Integrated Laser Engagement System (IMILES) VTESS hardware and software to make it compatible with ...Missing: IWS2 | Show results with:IWS2
[41]
JRTC vehicles are being installed with the Multiple Integrated Laser ...
Jul 13, 2016 · More than 3,000 New York Army National Guard Soldiers deployed to Fort Polk, Louisiana for a three week exercise at the Army's Joint Readiness ...Missing: adoption 1979 NTC fielded
[42]
MILES Training System Popular in U.S. and Abroad
Mar 23, 2015 · In the U.S., MILES simulators are being acquired by the Department of Defense under a large Army program that procures devices for use in ...
[43]
Global Multiple Integrated Laser Engagement Systems (MILES)
Nov 2, 2021 · The Multiple Integrated Laser Engagement Systems (MILES) market in the U.S. is estimated at US$378.9 Million in the year 2021. The country ...
[44]
Laser simulation system MILES delivered to the National Armed ...
Mar 9, 2019 · MILES simulation system can be attached to military equipment, weapons or tactical vehicles. Troops use these systems during target practice and ...
[45]
Cubic Receives Additional $2.9 Million Training Order to Increase ...
Feb 19, 2015 · Cubic's MILES IWS is the U.S. Army's latest generation tactical engagement simulation system in use today. The system uses laser emitters that ...<|control11|><|separator|>
[46]
Ukraine's Armed Forces switching to training on MILES, LaserTag ...
Mar 2, 2021 · Thus, we have brought the laser-based tactical engagement simulation (TES) systems MILES and LaserTag into company-level tactical exercises.
[47]
Bundeswehr orders new AGDUS passive systems from Rheinmetall ...
Dec 2, 2021 · By simulating the effects of weapons fire, the laser-supported Training Device, Duel Simulator (AGDUS) enables highly realistic combat training.Missing: variant | Show results with:variant
[48]
Laser-focused training - European Security & Defence
Mar 20, 2025 · The adoption of improved laser-based tactical engagement simulation for military collective training continues to grow.
[49]
MILES Open Engagement - YouTube
Apr 22, 2020 · S&S Training Solutions presents MILES Open Engagements. The MILES ... MILES (Multiple Integrated Laser Engagement System 2000) allows users ...
[50]
All the Fun and None of the Dumb: 1 Shepherd Leadership Institute
Apr 21, 2023 · The organization uses the MILES laser system for extensive force-on-force training, allowing realistic range and accuracy with blanks in real ...<|separator|>
[51]
Multi-Integrated Laser Engagement System: Changing Laser Tag
Sep 6, 2023 · Traditional laser tag systems rely on infrared beams and simple hit sensors, but MILES takes it a step further. With the incorporation of ...Missing: lasers | Show results with:lasers
[52]
Multiple Integrated Laser Engagement System (MILES) Market Report
The global multiple integrated laser engagement system (miles) market size was USD 127.4 Billion in 2023 and is likely to reach USD 152.7 Billion by 2032.
[53]
Laser Training for Law Enforcement
Laser Ammo is offering laser-based firearms training packages tailored to the Military, Corrections and Law Enforcement agencies.Missing: MILES | Show results with:MILES
[54]
Multiple Integrated Laser Engagement Systems (MILES)
Oct 1, 2025 · The Multiple Integrated Laser Engagement Systems (MILES) market in the U.S. is estimated at US$469.1 Million in the year 2024. China, the world ...