The precision-guided munitions market is estimated to be USD 37.24 billion in 2025 and is projected to reach USD 49.71 billion by 2030, at a CAGR of 5.9%. The evolution of precision-guided munitions is being driven by multiple strategic and operational imperatives that align with next-generation defense solutions. Military forces globally are prioritizing systems that offer higher operational efficiency, reduced logistical burden, and enhanced mission reliability. This shift reflects a growing demand for munitions that consume less energy, require minimal maintenance, and contribute to leaner, more agile force structures. Furthermore, the increasing emphasis on precision over volume, as well as the push for sustainable and intelligent warfare, aligns with broader defense modernization trends. PGMs are becoming essential for executing missions with accuracy while minimizing collateral damage and resource consumption.
Scope of the Report
Years Considered for the Study
2020-2030
Base Year
2024
Forecast Period
2025-2030
Units Considered
Value (USD Million)
Segments
By Product, System, Launch Platform, Speed, Mode of Operation, Region
Regions covered
North America, Europe, APAC, RoW
"EO/IR: The largest segment by targeting system during the forecast period" Electro-Optical/Infrared (EO/IR) guidance systems are poised to dominate the precision-guided munitions market because they can deliver real-time, high-fidelity target acquisition and terminal guidance even in highly complex operational environments. These systems allow PGMs to visually detect, track, and engage static and moving targets with pinpoint accuracy-vital for today's precision strike missions where rules of engagement frequently require positive target identification and low collateral damage.
EO/IR seekers provide a low-signature, passive guidance capacity that permits the munitions to home toward the target while radiating non-detectable signals, making the platforms very survivable against defenses predicated upon radars. The capability to provide function in bright lighting conditions at nighttime, as well as potentially in obscurant-filled areas like smoke or dust, facilitates more flexibility across all types of missions and terrains.
These systems are found more in air-to-ground bombs, loitering munitions, and autonomous missiles, where imagery in the visible or thermal infrared is employed for target identification, aim point determination, and final-course correction. Integration with onboard processors and artificial intelligence algorithms also enables sophisticated features like automatic target recognition (ATR), mid-course image-based updates, and in-flight retargeting.
"Inertial Navigation System: The fastest-growing segment by guidance & navigation system during the forecast period" Inertial Navigation Systems (INS) are positioned to dominate the precision-guided munitions market because they form the basis for providing accurate, autonomous navigation and guidance for nearly all types of precision weapons. INS technology guides by employing internal sensors-gyroscopes and accelerometers-to monitor the position, orientation, and speed of a munition without any external inputs, which makes it a central element in both standalone and hybrid guidance systems.
One of the strongest points of INS is its fault tolerance in contested environments. As opposed to GPS, which is subject to being denied or spoofed by electronic warfare systems, INS will operate reliably even when in GPS-degraded or denied environments. It is therefore the go-to navigation system for future PGMs, especially for high-threat environments where electronic countermeasures dominate. In addition, INS is a crucial part of multi-mode guidance systems, wherein it is coupled with GPS, laser seekers, radar, or imaging systems. It provides precise midcourse navigation and terminal guidance stabilization and aids precision engagement even when external cues are intermittent or missing.
Miniaturization of INS components, particularly through the evolution of microelectromechanical systems (MEMS), has seen its integration into a broad spectrum of munitions-tactical missiles and guided bombs, artillery shells, and loitering munitions. Its flexibility and comparatively low signature also facilitate platform-agnostic deployment, rendering it useful in air, land, and sea domains.
"Surface-to-Surface: The fastest-growing segment by guided rockets during the forecast period"
Surface-to-surface guided rockets will dominate the precision-guided munitions (PGM) market due to their unique combination of accuracy, range, responsiveness, and affordability. These weapons close a critical capability gap between cost-effective unguided artillery and costly tactical missiles, and they offer an attractive alternative to both large-scale military forces and emerging defense forces. One of their strongest assets is that they can perform highly precise fires at distant ranges from mobile, surface-based launchers without the requirement of air superiority. Systems like the guided multiple launch rocket system (GMLRS) and similar systems across the globe are capable of striking static and relocatable targets with short notice, and they excel at suppression of enemy air defenses (SEAD), counter-battery missions, and precision interdiction.
They compare differently to air-launched PGMs as they are rapidly deployable, salvaged-in-mass, and can be fired from extremely mobile launcher platforms such as HIMARS or MLRS mounted on trucks, thus providing them greater battlefield survivability and tactical response capability. Being network-connected allows them to suit sensor-to-shooter, speedily precise response, and response engagements of sensitive time targets.
"The US to account for the highest market share in the precision-guided munitions market during the forecasted year"
The US will be the largest holder in the global precision-guided munitions market due to its unmatched defense budget, mature industrial base, and strategic priority on precision, networked warfare. The doctrine of the US military prioritizes the reduction of collateral damage while it sustains global strike capabilities, rendering PGMs core to both tactical and strategic force projection.
The US possesses the most advanced and diverse set of PGMs, ranging from air-to-ground bombs to guided rockets, loitering bombs, and long-range tactical missiles to precision artillery rounds. JDAM, StormBreaker, Excalibur, GMLRS, and JAGM are widely employed in all branches of the armed forces and are regularly updated through modular enhancements and software-driven revisions.
Further, the U.S. Department of Defense also gives high value to multi-domain precision fires under its modernization plans, like Long-Range Precision Fires (LRPF), Joint All-Domain Command and Control (JADC2), and Next-Generation Air Dominance (NGAD). The programs guarantee sustained investment in network-enabled, AI-integrated interoperable PGMs. On top of national needs, the US holds a dominant share in foreign military sales of PGMs, which are in high demand among NATO allies as well as Indo-Pacific partners. Its well-established network of prime contractors, including Lockheed Martin, RTX, Boeing, and Northrop Grumman, solidifies its leadership position.
Break-up of profiles of primary participants in the precision-guided munitions market: By Company Type: Tier 1 - 49%, Tier 2 - 37%, and Tier 3 - 14% By Designation: C-Level Executives - 55%, Director level - 27%, and Others - 18% By Region: North America - 32%, Europe - 32%, Asia Pacific - 16%, Middle East-10%, Rest of the world - 10%
Prominent companies in the precision-guided munitions market are Northrop Grumman (US), RTX (US), General Dynamics Corporation (US), BAE Systems (UK), Lockheed Martin Corporation (US), MBDA (France), Israel Aerospace Industries (Israel), QinetiQ (UK), Boeing (US), and Aselsan AS (Turkey), among others.
Research Coverage: The market study covers the precision-guided munitions market across segments. It aims to estimate the market size and the growth potential of this market across different segments, such as system, launch platform, product, mode of operation, speed, range, and region. The study also includes an in-depth competitive analysis of the key players in the market, along with their company profiles, key observations related to product and business offerings, recent developments, and key market strategies. Key benefits of buying this report: This report will help the market leaders/new entrants in this market with information on the closest approximations of the revenue numbers for the overall precision-guided munitions market and its subsegments. The report covers the entire ecosystem of the precision-guided munitions industry and will help stakeholders understand the competitive landscape and gain more insights to better position their businesses and plan suitable go-to-market strategies. The report will also help stakeholders understand the pulse of the market and provide them with information on key market drivers, restraints, challenges, and opportunities.
The report provides insights on the following pointers:
Analysis of Key Drivers (Increased demand for precision guided munition to minimize collateral damage, reduction in logistics burden, growing military modernization programs, change in nature of warfare) Restraints (Regulations to arms transfer, high manufacturing costs) Opportunities (Miniaturization of munitions, development of hybrid precision guided munitions), and Challenges (Storage and lifecycle challenges) that impact the growth of the precision guided munitions market.
Product Development/Innovation: Detailed insights on upcoming technologies, research & development activities, and new product & service launches in the precision-guided munitions market.
Market Development: Comprehensive information about lucrative markets - the report analyzes the precision-guided munitions market across varied regions
Market Diversification: Exhaustive information about new products & services, untapped geographies, recent developments, and investments in the precision-guided munitions market
Competitive Assessment: In-depth assessment of market shares, growth strategies and service offerings of leading players, such as Northrop Grumman (US), RTX (US), General Dynamics Corporation (US), BAE Systems (UK), Lockheed Martin Corporation (US), MBDA (France), Israel Aerospace Industries (Israel), QinetiQ (UK), Boeing (US), Aselsan AS (Turkey), among others, in the precision-guided munitions market
TABLE OF CONTENTS
1 INTRODUCTION
1.1 STUDY OBJECTIVES
1.2 MARKET DEFINITION
1.3 STUDY SCOPE
1.3.1 MARKETS COVERED AND REGIONAL SCOPE
1.3.2 INCLUSIONS AND EXCLUSIONS
1.3.3 YEARS CONSIDERED
1.4 CURRENCY CONSIDERED
1.5 STAKEHOLDERS
1.6 SUMMARY OF CHANGES
2 RESEARCH METHODOLOGY
2.1 RESEARCH DATA
2.1.1 SECONDARY DATA
2.1.1.1 Key data from secondary sources
2.1.2 PRIMARY DATA
2.1.2.1 Key data from primary sources
2.1.2.2 Breakdown of primary interviews
2.2 MARKET SIZE ESTIMATION
2.2.1 BOTTOM-UP APPROACH
2.2.1.1 Precision-guided munition market, by system
2.2.1.2 Precision-guided munition market, by product
2.2.2 TOP-DOWN APPROACH
2.3 DATA TRIANGULATION
2.4 RESEARCH ASSUMPTIONS
2.5 RESEARCH LIMITATIONS
2.6 RISK ASSESSMENT
3 EXECUTIVE SUMMARY
4 PREMIUM INSIGHTS
4.1 ATTRACTIVE OPPORTUNITIES FOR PLAYERS IN PRECISION-GUIDED MUNITION MARKET
4.2 PRECISION-GUIDED MUNITION MARKET, BY SPEED
4.3 PRECISION-GUIDED MUNITION MARKET, BY MODE OF OPERATION
4.4 PRECISION-GUIDED MUNITION MARKET, BY PLATFORM
4.5 PRECISION-GUIDED MUNITION MARKET, BY COUNTRY
5 MARKET OVERVIEW
5.1 INTRODUCTION
5.2 MARKET DYNAMICS
5.2.1 DRIVERS
5.2.1.1 Elevated demand for precision-guided munitions to minimize collateral damage
5.2.1.2 Reduced logistical burden of modern warfare
5.2.1.3 Surge in military modernization programs
5.2.1.4 Evolving nature of warfare
5.2.2 RESTRAINTS
5.2.2.1 Stringent arms transfer regulations and export control frameworks
5.2.2.2 High manufacturing costs
5.2.3 OPPORTUNITIES
5.2.3.1 Miniaturization of munitions
5.2.3.2 Development of hybrid precision-guided munitions
5.2.3.3 Advent of recoverable and multi-mission munitions
5.2.3.4 Integration of AI and autonomous capabilities
5.2.4 CHALLENGES
5.2.4.1 Integration constraints associated with larger precision-guided munitions
5.2.4.2 Storage and shelf life limitations
5.3 TRENDS AND DISRUPTIONS IMPACTING CUSTOMER BUSINESS
5.4 VALUE CHAIN ANALYSIS
5.5 ECOSYSTEM ANALYSIS
5.5.1 MANUFACTURERS
5.5.2 SYSTEM INTEGRATORS
5.5.3 SOLUTION PROVIDERS
5.6 TECHNOLOGY ANALYSIS
5.6.1 KEY TECHNOLOGIES
5.6.1.1 Millimeter-wave radar seekers
5.6.1.2 Image-aided INS/GPS technology
5.6.2 COMPLEMENTARY TECHNOLOGIES
5.6.2.1 AI-powered mission planning
5.6.2.2 Swarming protocols
5.6.3 ADJACENT TECHNOLOGIES
5.6.3.1 Electro-optical targeting systems
5.6.3.2 Automatic target recognition algorithms
5.7 CASE STUDY ANALYSIS
5.7.1 GMLRS-ER BY LOCKHEED MARTIN
5.7.2 STORM SHADOW BY MBDA
5.7.3 SPICE 250 BY RAFAEL
5.7.4 GBU-39 SMALL DIAMETER BOMB (SDB II) BY BOEING
5.8 TRADE DATA
5.8.1 IMPORT SCENARIO (HS CODE 9306)
5.8.2 EXPORT SCENARIO (HS CODE 9306)
5.9 KEY STAKEHOLDERS AND BUYING CRITERIA
5.9.1 KEY STAKEHOLDERS IN BUYING PROCESS
5.9.2 BUYING CRITERIA
5.10 US 2025 TARIFF
5.10.1 INTRODUCTION
5.10.2 KEY TARIFF RATES
5.10.3 PRICE IMPACT ANALYSIS
5.10.4 IMPACT ON COUNTRY/REGION
5.10.4.1 US
5.10.4.2 Europe
5.10.4.3 Asia Pacific
5.10.5 IMPACT ON END USERS
5.11 REGULATORY LANDSCAPE
5.12 KEY CONFERENCES AND EVENTS, 2025-2026
5.13 INVESTMENT AND FUNDING SCENARIO
5.14 PRICING ANALYSIS
5.14.1 AVERAGE SELLING PRICE, BY PRODUCT
5.14.2 AVERAGE SELLING PRICE, BY REGION
5.15 OPERATIONAL DATA
5.16 IMPACT OF AI
5.16.1 INTRODUCTION
5.16.2 IMPACT OF AI ON DEFENSE SECTOR
5.16.3 ADOPTION OF AI IN MILITARY BY TOP COUNTRIES
5.16.4 IMPACT OF AI ON PRECISION-GUIDED MUNITION MARKET
5.17 MACROECONOMIC OUTLOOK
5.17.1 INTRODUCTION
5.17.2 NORTH AMERICA
5.17.3 EUROPE
5.17.4 ASIA PACIFIC
5.17.5 MIDDLE EAST
5.17.6 REST OF THE WORLD
5.18 BILL OF MATERIALS
5.19 TOTAL COST OF OWNERSHIP
5.20 BUSINESS MODELS
5.21 TECHNOLOGY ROADMAP
6 INDUSTRY TRENDS
6.1 INTRODUCTION
6.2 TECHNOLOGY TRENDS
6.2.1 MULTI-MODE SEEKERS
6.2.2 SWARMING MUNITIONS
6.2.3 MODULAR MUNITIONS
6.2.4 LOW-COST PRECISION STRIKE KITS
6.2.5 REAL-TIME IN-FLIGHT RETARGETING
6.2.6 DUAL-USE ISR AND STRIKE INTEGRATION
6.3 IMPACT OF MEGATRENDS
6.3.1 AI-ENABLED TARGET RECOGNITION
6.3.2 CYBER-RESILIENT GUIDANCE AND CONTROL SYSTEMS
6.3.3 INTEGRATION OF SPACE-BASED ASSETS INTO PRECISION STRIKE
6.3.4 BATTLEFIELD DIGITIZATION AND NETWORK-CENTRIC WARFARE
6.4 SUPPLY CHAIN ANALYSIS
6.5 PATENT ANALYSIS
7 PRECISION-GUIDED MUNITION MARKET, BY PRODUCT
7.1 INTRODUCTION
7.2 TACTICAL MISSILES
7.2.1 SURFACE-TO-SURFACE
7.2.1.1 Emphasis on long-range precision fires and rapid response capabilities
7.2.1.2 Use case: Brimstone by MBDA
7.2.2 AIR-TO-SURFACE
7.2.2.1 Emerging threat environments and evolving platform strategies
7.2.2.2 Use case: OpFires by DARPA-Lockheed Martin
7.3 INTERCEPTOR MISSILES
7.3.1 MOBILE AIR DEFENSE INTERCEPTORS
7.3.1.1 Rise of mobile, multi-vector aerial threats
7.3.1.2 Use case: Barak 8 by IAI, Rafael, and DRDO
7.3.2 MANPAD INTERCEPTORS
7.3.2.1 Heightened air threat landscape and elevated demand for mobile air defense solutions
7.3.2.2 Use case: Mistral 3 by MBDA
7.4 GUIDED ROCKETS
7.4.1 SURFACE-TO-SURFACE
7.4.1.1 Increased adoption due to long-range and rapidly deployable firepower
7.4.1.2 Use case: HIMARS by Lockheed Martin
7.4.2 AIR-TO-SURFACE
7.4.2.1 Need for low-cost, lightweight precision strike options
7.4.2.2 Use case: FZ275 LGR by Thales
7.5 GUIDED AMMUNITION
7.5.1 GUIDED MORTARS
7.5.1.1 Growing traction due to improved accuracy and operational effectiveness
7.5.1.2 Use case: XM395 by Northrop Grumman
7.5.2 GUIDED ARTILLERY SHELLS
7.5.2.1 Transformation of conventional artillery into high-precision, long-range strike systems
7.5.2.2 Use case: M982 Excalibur by RTX and BAE Systems
7.5.3 GLIDE BOMBS
7.5.3.1 Compatibility with fourth- and fifth-generation aircraft and UAVs
7.5.3.2 Use case: GBU-39/B SDB I by Boeing
7.6 TORPEDOES
7.6.1 SUBSEA-TO-SURFACE
7.6.1.1 Growing threats from surface combatants, carriers, and amphibious fleets
7.6.1.2 Use case: Black Shark by Leonardo
7.6.2 SURFACE-TO-SUBSEA
7.6.2.1 Rising proliferation of stealthy, long-endurance submarines in modern naval fleets
7.6.2.2 Use case: MU90 Impact by Thales and Naval Group
7.6.3 SURFACE-TO-SURFACE
7.6.3.1 Increasing threat of naval confrontations in coastal and enclosed sea regions
7.6.3.2 Use case: MILAS by MBDA
7.7 LOITERING MUNITIONS
7.7.1 RECOVERABLE
7.7.1.1 Excellent surveillance and precision strike capabilities in multiple-use operations
7.7.1.2 Use case: SkyStriker by Elbit Systems
7.7.2 EXPENDABLE
7.7.2.1 Extensive use in contested environments due to low cost and real-time target acquisition
7.7.2.2 Use case: Harop by IAI
8 PRECISION-GUIDED MUNITION MARKET, BY SYSTEM
8.1 INTRODUCTION
8.2 GUIDANCE & NAVIGATION SYSTEMS
8.2.1 INERTIAL NAVIGATION SYSTEMS
8.2.1.1 Prevalence of electronic warfare, spoofing, and satellite denial in contested environments
8.2.1.2 Use case: Excalibur M982 by RTX and BAE Systems
8.2.2 GLOBAL POSITIONING SYSTEMS
8.2.2.1 Need for high-precision navigation over long distances
8.2.2.2 Use case: JDAM by Boeing
8.2.3 TERRAIN CONTOUR MATCHING RADAR
8.2.3.1 Resurgence of electronic warfare and GNSS spoofing
8.2.3.2 Use case: Tomahawk by RTX
8.3 TARGET ACQUISITION SYSTEMS
8.3.1 EO/IR
8.3.1.1 Development of smaller and more efficient infrared systems for precision-guided munitions
8.3.1.2 Use case: Brimstone II by MBDA
8.3.1.3 IIR homing
8.3.1.4 IR homing
8.3.2 RADAR
8.3.2.1 Superior performance in all-weather, beyond-visual-range, and high-speed engagement scenarios
8.3.2.2 Use case: Aster 30 by MBDA
8.3.2.3 Active homing
8.3.2.4 Semi-active homing
8.3.2.5 Passive homing
8.3.3 LASER/LIDAR
8.3.3.1 Emphasis on low-collateral-damage strikes in modern warfare
8.3.3.2 Use case: GBU-53/B StormBreaker by RTX
8.3.3.3 Active
8.3.3.4 Semi-active
8.3.4 MULTI-MODE
8.3.4.1 Operational versatility and enhanced strike accuracy
8.3.4.2 GBU-53/B StormBreaker by RTX
8.4 PROPULSION SYSTEMS
8.4.1 SOLID
8.4.1.1 Wide acceptance in short-range ballistic missiles and loitering munitions
8.4.1.2 Use case: AGM-114 Hellfire by Lockheed Martin
8.4.2 LIQUID
8.4.2.1 Shift toward longer-range, high-agility, and precision strike capabilities
8.4.2.2 Use case: R-27 (AA-10 Alamo) by Soviet Union
8.4.3 HYBRID
8.4.3.1 Growing complexity of mission profiles and increasing demand for agile munitions
8.4.3.2 Use case: HSTDV by DRDO
8.4.4 RAMJET
8.4.4.1 Ability to deliver sustained high-speed flight over extended ranges
8.4.4.2 Use case: Meteor by MBDA
8.4.5 SCRAMJET
8.4.5.1 Defense initiatives aimed at accelerating research and development
8.4.5.2 Use case: HAWC by DARPA
8.4.6 TURBOJET
8.4.6.1 High demand for compact, cost-effective, and extended-range strike capabilities from militaries
8.4.6.2 Use case: AGM-86B ALCM by RTX
8.4.7 ELECTRIC
8.4.7.1 Innovations in defense programs
8.4.7.2 Use case: SkyStriker by Elbit Systems and Switchblade 300 by AeroVironment
8.5 WARHEADS
8.5.1 BLAST WARHEADS
8.5.1.1 Suitable for urban operations, airfield denial, and missions requiring controlled destruction
8.5.1.2 Use case: Tomahawk Block IV by RTX
8.5.2 CONTINUOUS ROD WARHEADS
8.5.2.1 Effectiveness against fast-moving airborne targets
8.5.2.2 Use case: AIM-120 AMRAAM D by RTX
8.5.3 FRAGMENTATION WARHEADS
8.5.3.1 Deployment in urban combat, counter-insurgency missions, and air defense operations
8.5.3.2 Use case: NASAMS by RTX
8.5.4 KINETIC ENERGY PERPETRATORS
8.5.4.1 Increasing concerns about deeply buried targets and hardened enemy assets
8.5.4.2 Use case: CHAMP
8.5.5 THERMOBARIC/SHAPED CHARGE WARHEADS
8.5.5.1 Rising strategic importance due to effectiveness in engaging fortified, enclosed, and armored targets
8.5.5.2 Use case: Brimstone by MBDA
8.5.6 SMART SUBMUNITIONS
8.5.6.1 Replacement of traditional cluster munitions
8.5.6.2 Use case: CBU-105 by Textron
8.6 POWER SUPPLY SYSTEMS
8.6.1 ALTERNATORS
8.6.1.1 Focus on reducing reliance on heavy or limited-life onboard batteries
8.6.1.2 Use case: AGM-86 ALCM by Boeing
8.6.2 BATTERIES
8.6.2.1 Elevated demand for compact, high-energy, and reliable power solutions
8.6.2.2 Use case: IM-92 Stinger by RTX
9 PRECISION-GUIDED MUNITION MARKET, BY LAUNCH PLATFORM
9.1 INTRODUCTION
9.2 LAND
9.2.1 RAPID DEPLOYMENT AND REPOSITIONING CAPABILITIES IN DYNAMIC COMBAT ENVIRONMENTS
9.3 AIRBORNE
9.3.1 EXTENSIVE USE IN HIGH-PRIORITY MISSIONS
9.4 NAVAL
9.4.1 ABILITY TO MAINTAIN STRONG DEFENSE POSTURE
10 PRECISION-GUIDED MUNITION MARKET, BY MODE OF OPERATION
10.1 INTRODUCTION
10.2 AUTONOMOUS
10.2.1 FASTER RESPONSE TIMES AND HIGHER OPERATIONAL FLEXIBILITY
10.3 SEMI-AUTONOMOUS
10.3.1 REDUCED OPERATIONAL RESPONSE TIMES AND INCREASED TARGETING ACCURACY
11 PRECISION-GUIDED MUNITION MARKET, BY SPEED
11.1 INTRODUCTION
11.2 SUBSONIC
11.2.1 EXTENDED RANGE AND PRECISE TARGETING CAPABILITIES
11.3 SUPERSONIC
11.3.1 RAPID RESPONSE AND DEEP-STRIKE VERSATILITY
11.4 HYPERSONIC
11.4.1 UNMATCHED SPEED, PRECISION, AND STRATEGIC DISRUPTION
12 PRECISION-GUIDED MUNITION MARKET, BY RANGE
12.1 INTRODUCTION
12.2 SHORT RANGE
12.2.1 DEPLOYMENT OF AGILE DEFENSE SYSTEMS FOR CLOSE-RANGE THREAT NEUTRALIZATION
12.3 MEDIUM RANGE
12.3.1 GLOBAL TREND TOWARD SELF-RELIANT MISSILE MANUFACTURING
12.4 LONG RANGE
12.4.1 IMPROVED TACTICAL AND STRATEGIC OPERATIONS WITH LONG-RANGE CAPABILITIES
12.5 EXTENDED RANGE
12.5.1 ENHANCED NATIONAL DETERRENCE THROUGH DEEP-STRIKE MISSILE TECHNOLOGIES
13 PRECISION-GUIDED MUNITION MARKET, BY REGION
13.1 INTRODUCTION
13.2 NORTH AMERICA
13.2.1 PESTLE ANALYSIS
13.2.2 DEFENSE PROGRAMS
13.2.3 US
13.2.3.1 Robust military-industrial infrastructure and strategic imperatives to drive market
13.2.4 CANADA
13.2.4.1 Emphasis on defense modernization to drive market
13.3 EUROPE
13.3.1 PESTLE ANALYSIS
13.3.2 DEFENSE PROGRAMS
13.3.3 UK
13.3.3.1 Strategic Indo-Pacific realignment to drive market
13.3.4 FRANCE
13.3.4.1 Defense industrial sovereignty and multinational collaborations to drive market
13.3.5 GERMANY
13.3.5.1 Commitment to precision-focused deterrence to drive market
13.3.6 ITALY
13.3.6.1 Expanding defense manufacturing capabilities to drive market
13.3.7 RUSSIA
13.3.7.1 Robust domestic R&D capacity to drive market
13.3.8 REST OF EUROPE
13.4 ASIA PACIFIC
13.4.1 PESTLE ANALYSIS
13.4.2 DEFENSE PROGRAMS
13.4.3 CHINA
13.4.3.1 Military modernization efforts and increased defense budget to drive market
13.4.4 INDIA
13.4.4.1 Evolving defense policies and regional security concerns to drive market
13.4.5 JAPAN
13.4.5.1 Strategic defense investments and focus on military self-sufficiency to drive market
13.4.6 SOUTH KOREA
13.4.6.1 Emphasis on strengthening defense capabilities amid growing security threats to drive market
13.4.7 AUSTRALIA
13.4.7.1 Substantial increase in defense spending to drive market
13.4.8 REST OF ASIA PACIFIC
13.5 MIDDLE EAST
13.5.1 PESTLE ANALYSIS
13.5.2 DEFENSE PROGRAMS
13.5.3 SAUDI ARABIA
13.5.3.1 Vision 2030 agenda and strategic partnerships to drive market
13.5.4 ISRAEL
13.5.4.1 Persistent asymmetric threats to drive market
13.5.5 TURKEY
13.5.5.1 Focus on indigenous innovation and robust export-oriented defense industry to drive market
13.5.6 REST OF MIDDLE EAST
13.6 REST OF THE WORLD
13.6.1 PESTLE ANALYSIS
13.6.2 DEFENSE PROGRAMS
13.6.3 LATIN AMERICA
13.6.3.1 Increasing investments in counter-insurgency and border control technologies to drive market
13.6.4 AFRICA
13.6.4.1 Increased defense modernization initiatives to drive market
14 COMPETITIVE LANDSCAPE
14.1 INTRODUCTION
14.2 KEY PLAYER STRATEGIES/RIGHT TO WIN, 2020-2024
14.3 MARKET SHARE ANALYSIS, 2024
14.4 REVENUE ANALYSIS, 2021-2024
14.5 COMPANY EVALUATION MATRIX: KEY PLAYERS, 2024
14.5.1 STARS
14.5.2 EMERGING LEADERS
14.5.3 PERVASIVE PLAYERS
14.5.4 PARTICIPANTS
14.5.5 COMPANY FOOTPRINT
14.5.5.1 Company footprint
14.5.5.2 Region footprint
14.5.5.3 Product footprint
14.5.5.4 Speed footprint
14.6 COMPANY EVALUATION MATRIX: START-UPS/SMES, 2024
14.6.1 PROGRESSIVE COMPANIES
14.6.2 RESPONSIVE COMPANIES
14.6.3 DYNAMIC COMPANIES
14.6.4 STARTING BLOCKS
14.6.5 COMPETITIVE BENCHMARKING
14.6.5.1 List of start-ups/SMEs
14.6.5.2 Competitive benchmarking of start-ups/SMEs
