Towed array sonar is a passive acoustic detection system consisting of a linear array of hydrophones housed in a flexible hose or streamer, towed behind a submarine or surface ship on a deployment cable to listen for underwater sounds such as those emitted by vessels or marine life.[1][2] This configuration allows the array to be positioned away from the towing vessel's self-noise, enabling the detection of faint, low-frequency acoustic signals over long ranges, often exceeding 150 kilometers in optimal conditions.[3][1]The technology originated in rudimentary form during World War I with the U.S. Navy's "Electric Eel" system, a chain of hydrophones towed to detect submarines, but it was largely dormant until the Cold War era.[1][4] In the 1950s and 1960s, researchers at the David Taylor Model Basin (DTMB) and the Office of Naval Research (ONR), including Marvin Lasky, developed the modern towed array through experiments on the USS Albacore submarine, evolving from self-noise measurement tools into dedicated passive sonar for anti-submarine warfare (ASW).[4] By the 1970s and 1980s, systems like the U.S. Navy's TACTAS and the NATO Undersea Research Centre's early arrays (introduced in 1978) matured the technology, incorporating beamforming techniques to resolve target direction and reduce ambient noise interference.[5][2]At its core, towed array sonar operates on the principle of acoustic beamforming, where signals from multiple hydrophones—typically arranged in arrays up to several kilometers long—are processed digitally to form directional beams, distinguishing targets by their unique acoustic signatures such as propeller noise or machinery hum.[1][3] Key components include the hydrophone streamer (often 2-4 inches in diameter, filled with oil for buoyancy control), a towingcable with telemetry for signal transmission, and onboard processing units that use Fourier analysis to estimate range, bearing, and speed.[2][5] Arrays can be "thin-line" for passive listening or "fat-line" with active elements for pinging, and they are deployed at variable depths below the thermocline to optimize signal clarity while minimizing flow noise from the towingplatform.[3][2]Primarily employed in military contexts for ASW, towed array sonar equips modern submarines like the U.S. Virginia-class and UK Astute-class, as well as surface combatants such as Type 23 frigates with systems like Sonar 2087, providing passive surveillance and bistatic detection capabilities without alerting targets.[3] Beyond defense, it supports oceanographic research for ambient noise mapping, marine mammal tracking, and seismic surveys, with historical applications dating back to NATO trials in the 1970s and 1990s.[5][2] Design challenges include maintaining streamer stability against currents, reducing cable-induced strumming noise, and integrating advanced materials like fiber optics for high-speed data transfer, driving ongoing innovations for unmanned platforms and low-signature environments.[1][2]
Fundamentals
Components and Design
Towed array sonar systems consist of several core hardware components designed for underwater acoustic detection. The primary element is the hydrophone array, a linear chain of sensors typically comprising 10 to 100 hydrophones spaced 1 to 10 meters apart to capture directional sound fields effectively.[5] These hydrophones convert acoustic pressure variations into electrical signals using piezoelectric elements, which generate voltage in response to mechanical stress from sound waves.[5] The array is connected via a tow cable, engineered for neutral buoyancy and armored protection against underwater hazards, with lengths extending up to 10 km to position the sensors far from the towing vessel's noise sources.[5] The tow cable incorporates strength members such as steel wires or Kevlar fibers for mechanical support, alongside copper conductors or fiber optics for power delivery and data transmission back to the vessel.[5][1] Deployment and retrieval are managed by a specialized winch system, often featuring a large drum (up to 2 meters in diameter) with capacities exceeding 20 tons to handle the cable's weight and tension.[5] An onboard signal processing unit receives the raw electrical signals, providing initial amplification and digitization (e.g., 24-bit resolution at rates up to 24.6 Mbit/s) before further analysis.[5]Design variations in towed array sonar emphasize adaptability to operational environments, particularly in array diameter and construction materials. Thin-line arrays have diameters of 20-50 mm, offering lower drag for higher tow speeds, while fat-line arrays are larger, typically 70-100 mm, accommodating larger hydrophones for enhanced sensitivity at lower frequencies.[5] The array housing typically uses acoustic-transparent hoses made of polyurethane or similar elastomers, filled with oil or fluid to achieve neutral buoyancy, dampen internal vibrations, and protect internal components from pressure and corrosion.[5] Mechanical features include a depressor or "fish" at the array's leading end, a weighted hydrodynamic device that maintains operational depth (often 100-500 meters) and ensures proper cable tension during towing.[1] Vibration isolation modules (VIMs), positioned at the array's forward and aft sections, further isolate the hydrophones from tow cable oscillations using viscoelastic materials and fluiddamping.[6]Engineering challenges in towed array design center on maintaining performance in dynamic underwater conditions. Vibration isolation is critical, as tow cable strumming and vessel motion can introduce self-noise; VIMs, often 2-3 meters long, employ elastic hoses and internal fluids to attenuate these vibrations at low frequencies.[6] Array straightness is preserved through controlled tension, typically 1-5 tons (10,000-50,000 N), applied via the winch to counteract hydrodynamic forces and prevent bending that could distort beam patterns. Protection against biofouling—accumulation of marine growth on the cable and array—requires antifouling coatings or materials, while snag prevention involves armored sheathing and emergency cutters on the winch to avoid entanglement with underwater obstacles.[1] These features ensure reliable deployment in varied sea states, though they add complexity to the overall system mass and handling.[5]
Principles of Operation
Towed array sonar operates primarily through passive detection, listening for acoustic emissions from underwater targets such as propeller cavitation or machinery noise generated by vessels. In passive mode, the array of hydrophones captures these radiated sounds without emitting signals, allowing for covert monitoring over long ranges. Active operation involves transmitting acoustic pings from a separate projector and receiving echoes with the towed array, though this is less common due to detectability concerns. Sound propagation in water follows spherical spreading, where intensity decreases as 1/r² (r being range), combined with frequency-dependent absorption losses primarily from molecular relaxation processes involving magnesium sulfate and boric acid, which attenuate higher frequencies more rapidly.[7][8][9]The core signal processing in towed array sonar relies on beamforming to enhance directional sensitivity. The delay-and-sum technique aligns signals from individual hydrophones by applying time delays based on the angle of arrival, then summing them to form narrow beams that amplify signals from specific directions while suppressing others. This spatial filtering rejects isotropic noise, including vessel self-noise from the towing platform, which is isolated by towing the array hundreds of meters astern. The beam pattern for a uniform linear array is given byB(\theta) = \sum_{n=1}^{N} e^{j k d n \sin\theta},where k = 2\pi f / c is the wavenumber (f frequency, c sound speed), d is element spacing, N is the number of elements, and θ is the angle from broadside; the magnitude |B(θ)| determines the directional response. For uncorrelated noise, beamforming provides an array gain improving the signal-to-noise ratio (SNR) as SNR_{array} = SNR_{single} + 10\log_{10}(N), where N is the number of elements, enabling detection of faint targets against ambient sea noise.[10][10][11]Key performance factors include the array's aperture length L, which governs angular resolution via \Delta\theta \approx \lambda / L (λ wavelength), yielding beamwidths as fine as 1° for low-frequency (e.g., 1 kHz) systems with L ≈ 75 m. Arrays are towed at speeds of 5-15 knots to balance coverage with flow noise minimization; turbulent boundary layer noise rises approximately 2 dB per knot, dominating above 200-300 Hz and degrading low-frequency detection if speeds exceed this range. To optimize propagation, arrays are deployed below the thermocline (typically 100-200 m depth), where temperature gradients are minimal, leveraging the SOFAR channel—a sound speed minimum at ~1200 m—for reduced spreading losses and enhanced long-range signal coherence via refractive ducting.[5][12][13]
History
Early Development
The origins of towed array sonar trace back to World War I, when U.S. Navy physicist Dr. Harvey C. Hayes led a team at the New London Naval Experimental Station to develop passive acoustic detection systems against German U-boats. In 1917–1918, Hayes' group created the "Electric Eel," an early towed hydrophonearray combining hull-mounted and towed elements, with the towed portions consisting of 12-element arrays approximately 300–500 feet long, deployed at about 100 feet depth and spaced 12 feet apart.[4] This system was tested aboard the destroyer USS Jouett, successfully detecting and ranging a submerged U.S. submarine (G-2) at 1,200 yards while the ship steamed at 20 knots, enabling cross-fixing for both bearing and range measurements.[4] The Electric Eel represented a pioneering effort in trailing hydrophone cables, though practical deployments were shorter due to technological limits, and it operated primarily in the audible frequency range for passive listening.[14] However, the project was discontinued after the war, as the U.S. Navy shifted focus to active echo-ranging technologies like the British ASDIC system, which offered greater effectiveness against the era's noisier submarine targets and rendered towed passive arrays less practical.[4] Influenced by ASDIC's success in anti-submarine warfare, interwar and World War II research emphasized hull-mounted and active sonars, with limited U.S. and British experiments exploring towed streamers for acoustic mine detection, such as the Royal Navy's enhanced towed hydrophones like the "Lancashire Fish" for detecting submerged submarines from surface vessels.[15]Towed array development revived in the 1950s amid Cold War submarine threats, particularly the emergence of quieter Soviet nuclear-powered vessels, prompting the U.S. Navy to adapt oil-industry seismic streamer technology for naval passive sonar.[3] Basic towed lines were adopted for surface ships and submarines, with early systems limited to 1–2 km lengths and low-frequency operations around 100–1,000 Hz to capture distant propeller and machinery noise.[16] Key challenges included hydrodynamic drag on the cable, which reduced towing speeds and stability, addressed through neutral buoyancy designs using materials like oil-filled housings to minimize tension and flow-induced noise.[4] By the early 1960s, the first dedicated passive towed arrays appeared, exemplified by the U.S. Navy's TB-16 prototype, deployed on submarines like the USS Albacore to counter Soviet threats with improved low-frequency sensitivity.
Modern Advancements
During the late Cold War period and extending into the 1990s, towed array sonar systems saw significant maturation, particularly with the U.S. Navy's development of the conventional thin-line TB-29 series, which addressed reliability issues in earlier designs. In parallel, there was renewed interest in fiber-optic technologies for data transmission in towed arrays, enabling real-time processing, reducing electromagnetic interference, and supporting higher data rates from large sensor arrays towed at low frequencies.[17][5] In the same decade, the Surveillance Towed Array Sensor System Low Frequency Active (SURTASS LFA) was introduced as a long-range active sonar, operating in the 100-500 Hz band to detect submarines over extended distances in open-ocean environments.[18]Entering the 2000s, active towed systems gained prominence, exemplified by Thales' CAPTAS family, with the CAPTAS-4 variant providing variable-depth operation for 360° surveillance in both deep and shallow waters, achieving detection ranges up to 60 km at low frequencies to counter stealthy threats.[19] Deployed across 18 navies, CAPTAS systems have emphasized modular designs for rapid integration and deployment on surface vessels, marking a shift toward flexible, exportable technologies.[20]In recent developments as of 2025, next-generation thin-line arrays like the L3Harris TB-29C have enhanced sensitivity and reliability over predecessors, utilizing advanced materials to detect quiet diesel-electric submarines in littoral and open-ocean settings, with production supporting U.S. Navy Virginia-class platforms.[21] Similarly, the L3Harris Model 980 ALOFTS integrates a high-powered active source in a variable-depth towed body paired with a directional array for simultaneous active and passive low-frequency operations.[22] Integration of AI-driven algorithms has advanced automated target classification, enabling real-time signal processing and threat prioritization in towed sonar data.[23] Self-noise cancellation techniques, including adaptive filtering and deep regression neural networks, have further improved signal clarity by suppressing platform-generated interference during towing.[24]Key milestones in the 2020s include a focus on countering low-signature diesel-electric submarines through enhanced low-frequency capabilities, as seen in CAPTAS variants optimized for difficult acoustic environments.[25] Environmental adaptations have also emerged, with towed arrays like SURTASS employed for passive bio-acoustic monitoring of marine mammals to mitigate operational impacts.[26] International programs, such as the widely adopted CAPTAS, underscore collaborative advancements, culminating in Thales receiving its 100th order in 2025.[20]
Types
Thin-Line Arrays
Thin-line arrays are slender, passive towed sonar systems characterized by a diameter typically under 50 mm, with lengths ranging from 1 to 3 km, optimized for detecting low-frequency acoustic signals in the 10–100 Hz range using hydrophone elements.[3] These arrays prioritize long-range passive surveillance, distinguishing them through their lightweight construction that enables deployment at tow speeds up to 15 knots while minimizing flow-induced noise via a streamlined, low-drag profile.[3] The internal hose is often oil-filled to enhance acoustic coupling between hydrophones and the surrounding water, provide buoyancy, and reduce turbulence effects during transit.[3]Introduced in the 1970s primarily for anti-submarine warfare (ASW), thin-line arrays offered a compact alternative to bulkier systems, enabling covert operations with a low acoustic signature due to their passive nature and separation from the towing platform's noise.[3] Notable examples include the U.S. Navy's TB-23 and TB-29 arrays for submarine deployment, and SEA's KraitSense system, a lightweight variant developed for integration with autonomous underwater vehicles such as the Manta XLUUV.[27][28][29] The TB-29, for instance, incorporates a sensor location system for improved array integrity, extending its effective length beyond that of the earlier TB-23.[27]Operationally, thin-line arrays are deployed from submarines or surface ships at depths of 100–500 m, excelling in bearing-only tracking of distant targets through beamforming techniques that leverage the large aperture for high angular resolution.[3] This configuration supports detection ranges of 50–100 km against noisy targets, such as propeller-driven submarines, by isolating faint low-frequency signatures from ambient ocean noise.[3] They are commonly integrated into platforms like the U.S. Virginia-class submarines, where forward-fit installations enhance ASW capabilities in open-ocean and littoral environments.[27]Modern iterations incorporate embedded telemetry systems, including tension sensors and strain gages wired into a Wheatstone bridge configuration, to enable real-time array shape estimation and deformation monitoring during maneuvers.[30] These advancements, as seen in the TB-29C, improve reliability and signal processing for precise target localization within 1 km at extended ranges, supporting integrated digital consoles for enhanced operator efficiency.[27][3] Recent developments include Thales' BlueSentry thin-line array, optimized for unmanned surface vessels as of 2025.[31]
Fat-Line Arrays
Fat-line arrays represent a class of towed sonar systems characterized by larger diameters, typically ranging from 80 to 100 mm, and lengths typically from 70 meters to over 1 km, designed to accommodate active sonar projectors alongside passive hydrophone sensors for enhanced detection capabilities.[32][3] Unlike narrower thin-line arrays optimized for passive listening, fat-line configurations support both active transmission and reception, enabling versatile anti-submarine warfare operations.[3] Prominent examples include the U.S. Navy's TB-16, a 89 mm diameter array approximately 73 meters long, and Thales' CAPTAS-2 and CAPTAS-4 systems, which feature an 85 mm diameter towed body for variable-depth deployment.[32][19]These arrays incorporate buoyant housings filled with neutrally buoyant fluid to maintain stability during towing, along with internal preamplifiers and electronics for real-time signal processing and amplification to counter transmission losses over distance.[2]Variable depth control is achieved through specialized winches that adjust towing tension and scope, allowing the array to be positioned at optimal depths below the thermocline for improved acoustic performance.[19] Their robust construction supports higher acoustic power levels, facilitating active pings in the low-frequency band (typically 0.5-2 kHz) for target illumination without risking structural damage.[25]Operationally, fat-line arrays excel in bistatic configurations, where the projector and receiver are spatially separated—often with the source on the towing vessel and the array as a dedicated receiver—enhancing covert detection by minimizing self-noise interference.[33] They provide effective mid-range performance, achieving detection ranges of 20-60 km in active mode through directed acoustic illumination, which reveals stealthy targets otherwise obscured in passive-only scenarios.[19] To maintain beamforming accuracy, integrated inclinometers and depth sensors monitor array shape in real time, enabling software-based corrections for curvature induced by towingdynamics or ocean currents.[1][34]Development of fat-line arrays began in the 1960s, primarily for surface ship integration to extend beyond hull-mounted sonar limitations in submarine detection.[3] The Thales CAPTAS-4 variant, for instance, delivers passive detection ranges up to 150 km, leveraging its multi-element receive array for broad-spectrum surveillance.[35] While primarily ship-towed, compact fat-line derivatives support integration with variable-depth systems compatible with helicopter operations for rapid deployment flexibility.[19]In the 2020s, advancements have focused on adapting fat-line arrays for unmanned surface vessels, enabling extended towing durations and distributed sensing networks without crewed platform risks; examples include Thales CAPTAS variants and Elbit Systems' TRAPS-USV integrated on the Seagull USV in 2020.[19][36] These integrations enhance operational reach in contested waters, supporting multistatic operations with allied assets.
Applications
Military Applications
Towed array sonar serves as a cornerstone of military anti-submarine warfare (ASW), enabling naval forces to detect and track quiet submarine threats over extended ranges while minimizing self-noise interference.[3] These systems are integral to both submarine and surface ship operations, providing passive acoustic surveillance that complements hull-mounted sonars by positioning hydrophones beyond the vessel's propeller baffles, where self-generated noise would otherwise obscure detections.[3] For instance, the U.S. Virginia-class attack submarines deploy the TB-29 thin-line towed array, a passive sonarreceiver designed for reliable detection of adversaries in open ocean and littoral environments.[37] Similarly, surface combatants like destroyers integrate the CAPTAS (Combined Active-Passive Towed Array Sonar) system, a variable-depth towed array that enhances low-frequency detection of diesel-electric submarines, including quiet models such as the Kilo-class.[19][38]In ASW tactics, towed arrays facilitate passive surveillance in strategic chokepoints, such as straits and coastal bottlenecks, allowing vessels to monitor submarine transits covertly without emitting signals that could reveal their position.[39] For broader open-ocean searches, active transmission modes—supported by systems like CAPTAS—enable proactive threat localization, often integrated with torpedo guidance for precision engagements.[19] These arrays also integrate with legacy networks like the Sound Surveillance System (SOSUS), forming a layered underwater surveillance architecture that fuses mobile towed data with fixed hydrophone arrays for real-time submarine tracking and reporting.[40] Such tactics have been employed in historical conflicts, including the 1982 Falklands War, underscoring the technology's tactical impact in contested waters.[41]Prominent examples include the U.S. Navy's Surveillance Towed Array Sensor System (SURTASS), a mobile passive array deployed on ocean surveillance ships for blue-water ASW operations, capable of detecting submarines at long ranges exceeding 100 kilometers in favorable conditions to support fleet-wide threat reporting.[40][42] In multinational settings, NATO exercises like REPMUS 2025 have showcased towed arrays for fleet protection, with participating forces demonstrating interoperability in joint ASW scenarios to safeguard carrier strike groups and amphibious operations.[43] Towed arrays are now standard on ASW platforms across numerous modern navies, with systems like CAPTAS equipping vessels in at least 17 nations for enhanced underwater domain awareness.[44]As of 2025, towed array applications have evolved to address emerging threats, including underwater tracking of submarines capable of launching hypersonic missiles, where passive arrays provide early warning against stealthy platforms in high-stakes environments.[45] Integration with unmanned systems further extends capabilities, as seen in partnerships like Thales and Saildrone's deployment of towed arrays on unmanned surface vessels (USVs) to form persistent monitoring swarms that create distributed acoustic barriers without risking manned assets.[46] These advancements enable scalable, low-signature ASW patrols, bolstering naval defenses against advanced adversaries.[47]
Civilian Applications
Towed array sonar systems play a central role in geophysical exploration, particularly in marine seismic surveys for oil and gas reservoirs. These systems typically involve long hydrophone streamers towed behind survey vessels, often paired with air-gun sources that generate acoustic pulses for sub-bottom profiling and imaging geological formations. Streamers can extend up to 12 kilometers in length, with configurations commonly featuring 6 to 12 parallel arrays separated by approximately 100 meters to capture wide-azimuth data for enhanced subsurface resolution.[48][49][50]Industry leaders such as PGS and SLB (formerly Schlumberger) employ advanced multi-streamer systems for these operations. PGS's GeoStreamer technology, for instance, uses multisensor towed arrays up to 7 kilometers long across 16 streamers, enabling high-fidelity imaging in complex geological settings. Similarly, SLB's Q-Marine system integrates steerable streamers for precise positioning and data quality in exploration campaigns. In sub-bottom profiling, air-gun arrays provide the impulsive energy, with reflections recorded by the towed hydrophones to map sediment layers and potential hydrocarbon traps.[51][52]Beyond geophysics, towed array sonar supports oceanographic research, including marine mammal tracking and seabed mapping. Researchers deploy these arrays to passively monitor vocalizations, enabling localization of species like beaked whales for population studies and behavioral analysis. In seabed mapping, the systems contribute to acoustic surveys that delineate bathymetric features and sediment types, often integrated with multibeam echosounders. Environmental monitoring applications focus on assessing ocean noise pollution, where towed arrays detect anthropogenic sounds from shipping and industrial activities to evaluate impacts on marine ecosystems.[53][54]Academic and research institutions utilize towed arrays for climate-related acoustics, such as studying propagation in the SOFAR channel to infer ocean temperature variations and heat content. By 2025, trends include 4D time-lapse surveys using repeated towed streamer acquisitions to monitor reservoir changes over time, improving production forecasts. Hybrid towing with autonomous underwater vehicles (AUVs) is emerging, combining traditional streamers with AUV-deployed nodes for flexible, wide-aperture coverage in challenging areas. Operations adhere to strict regulations for marine mammal protection, requiring shutdowns of air-gun sources if protected species enter exclusion zones during migrations, as mandated by frameworks like the U.S. Marine Mammal Protection Act.[55][56][57][58]
Performance Characteristics
Advantages
Towed array sonar systems provide superior detection range and angular resolution compared to hull-mounted alternatives, primarily due to their extended linear aperture and reduced self-noise interference. Hull-mounted sonars are typically limited to detection ranges of a few kilometers for submarines under favorable conditions, whereas towed arrays can achieve 50-150 km or more, enabling earlier threat identification in anti-submarine warfare. For instance, the UK's Sonar 2087 system demonstrates detection over 150 km in optimal environments. This extended range stems from the array's ability to operate at low frequencies with minimal propagation loss. Additionally, the long aperture—often spanning hundreds of meters—yields finer bearing accuracy of 1-2 degrees, allowing localization precision within 1 km at 50 nautical miles (approximately 93 km).[3]A primary performance benefit is enhanced noise isolation, as the towed configuration positions hydrophones far astern of the host vessel, distancing them from propeller cavitation, flow noise, and onboard machinery. This separation significantly boosts the signal-to-noise ratio (SNR), improving faint signal detection. Furthermore, towed arrays cover the 180-degree baffle region—the rear blind spot inherent to hull-mounted systems—providing 360-degree passive surveillance without compromising sensitivity.[3]Towed arrays exhibit high versatility in deployment, with adjustable towing depths that allow penetration beneath thermal layers, where sound refraction otherwise distorts propagation and hides targets from surface-based sensors. By positioning below the thermocline, arrays access clearer acoustic paths, optimizing performance in layered ocean environments. Their passive listening mode further supports stealthy operations, detecting radiated noise from submarines or other sources without transmitting pings that could reveal the platform's location.[3]Specific systems underscore these gains; the Thales CAPTAS-2 variable depth sonar achieves submarine detection ranges up to 60 km while integrating active and passive modes for comprehensive threat assessment. In geophysical applications, seismic towed hydrophone arrays facilitate greater subsurface data coverage than single-channel setups, as multiple synchronized channels capture diverse reflection paths simultaneously, enhancing imaging resolution and survey efficiency.[19]In the 2025 operational landscape, digital processing advancements have amplified these advantages, incorporating adaptive algorithms for real-time noise cancellation and multi-target tracking, which improve beamforming accuracy and handle complex acoustic scenes with multiple emitters.
Limitations
Towed array sonar systems impose significant maneuverability constraints on the towing vessel, requiring straight-line towing at speeds typically below 15 knots to maintain array stability and minimize flow-induced distortions. Sharp turns can cause the array to tangle or experience curvature-induced signal distortion, necessitating a minimum turn radius exceeding 1 km to avoid performance degradation until the array resettles. For submarines, turn rates are limited to approximately 1.5 degrees per second, while surface ships like frigates are capped at around 20 knots during deployment, further restricting tactical flexibility.[3][5]The towed cable introduces vulnerabilities that heighten operational risks, including potential snags on the seafloor, underwater obstacles, or the towingvessel's propellers, particularly in cluttered environments such as shallow coastal waters or areas with debris like oil infrastructure. Hydrodynamic drag from the array and cable increases fuel consumption at sustained towing speeds, depending on array length and vessel type, while deployment and retrieval processes require dedicated handling equipment and calm sea states. These factors not only elevate mechanical stress on the system but also complicate logistics in dynamic scenarios.[2]Environmental conditions exacerbate these limitations, with flow noise from turbulent boundary layers and cable strumming becoming dominant at speeds above 12 knots, masking low-frequency target signals and reducing detection range. In shallow waters, such as depths of 60-500 meters where the water is shallower than the array length, the risk of bottom interaction rises, while thermocline layers and the deep scattering layer further diffuse echoes and limit effectiveness.[3] Over extended deployments, marine growth on the array and cable can increase drag, necessitating periodic maintenance.In active sonar modes, towed arrays can face self-noise challenges from the system's own acoustic emissions and platform vibrations, which can overwhelm faint returns in noisy environments. Countering advanced submarine quieting technologies, such as anechoic coatings that absorb broadband sound and minimize radiated noise, remains a key hurdle, often requiring hybrid passive-active approaches.[3]Efforts to mitigate array deformation include self-measuring sensors embedded in the tow cable for real-time shape estimation and correction via adaptive beamforming algorithms, though these methods are not foolproof and struggle with severe currents or rapid maneuvers. Such techniques can partially compensate for curvature errors in hydrophone positioning but often fail to fully restore gain in non-isotropic oceannoise fields.[59]