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Exmor is a technology developed by Sony and implemented on some of their CMOS image sensors. It performs on-chip analog/digital signal conversion and two-step noise reduction in parallel on each column of the CMOS sensor.

Sensors from the Exmor family have become widely available in consumer technology.

History

[edit]

In October 2015, Sony Semiconductor Solutions was established as a wholly owned group company to reinforce the CMOS image sensor business and integrate the semiconductor-related business operations of Sony Group. Following the incorporation, all the Exmor sensors are designed and manufactured by the company.[1][non-primary source needed]

On 14 May 2020, the Intelligent Vision Sensor was announced with an introduction that reads: "the first image sensor in the world to be equipped with AI processing functionality". The new sensor distinguishes itself from the previous Exmor RS sensors by an AI processor and a memory storing the AI models, included in a stacked logic layer for the real-time image analysis and instant extraction of metadata from a raw image. In the release, only model numbers were identified and it was not confirmed whether the sensor bears a different name.[2]

On 29 June 2022, Xiaomi announced that it was using the IMX989, Sony's first 1-inch smartphone camera sensor, in the Xiaomi 12S Ultra.[3] However, it later emerged that it was earlier used by Sharp Aquos R7 in May 2022, albeit slightly cropped in.[4]

Versions

[edit]

Exmor R

[edit]

Exmor R is a back-illuminated version of Sony's CMOS image sensor.[5] Exmor R was announced by Sony on 11 June 2008 and was the world's first mass-produced implementation of the back-illuminated sensor technology.[6][non-primary source needed] Sony claims that Exmor R is approximately twice as sensitive as a normal front illuminated sensor.[citation needed]

This active pixel sensor is found in several Sony mobile phones and cameras as well as Apple's iPhone 4s and 5.[7] Originally, Exmor R was limited to smaller sensors for camcorders, compact cameras and mobile phones, but the Sony ILCE-7RM2 full-frame camera introduced on the 10 June 2015 features an Exmor R sensor as well.

Exmor RS

[edit]

Exmor RS was announced on 20 August 2012 and is the world's first stacked CMOS image sensor.[8][non-primary source needed] Subsequently, Sony announced the first 3-layer stacked CMOS sensor, which added DRAM cell array in the middle.[9]

From the Exmor RS line, IMX582 or IMX586 sensors are widely implemented as 48 megapixel smartphone cameras (e.g. Samsung Galaxy S20), with the sensors having almost identical specifications, but for the IMX586 supporting faster frame rates at 4K. In early 2020, the IMX586 was followed by the IMX686, enlarging the format to 1/1.72" (increasing resolution to 64 megapixels), but keeping the same pixel size.[10] Pixel binning is used to reduce the high sensor resolution to standard photographic resolutions such as 4K, overcoming some of the traditional limitations of Bayer filtering.

STARVIS

[edit]

STARVIS is a series of sensors with the Exmor RS family.[citation needed] It features high pixel sensitivity, making it suitable for low light applications. Industrial versions are finding applications in ambient-light surveillance systems. Commercial versions are finding applications in prosumer webcams with 4K HDR support, based on single exposure.

STARVIS 2

[edit]

From the second-generation STARVIS line (STARVIS 2), the IMX585 was announced on 29 June 2021,[11] featuring a large image sensor format of 1/1.2", making it suitable for low light photography. Sony designed the STARVIS 2 sensor family for AI face recognition in surveillance applications with difficult lighting conditions.[12][promotional source?] The sensor's high dynamic range assists with this task. It became available in a Razer Inc. prosumer webcam in January 2023.[13] Larger sensor form factors decrease depth of field, which is often desired for teleconferencing webcams. Sony claims near DSLR quality for some applications.[13]

Exmor T

[edit]

Sony introduced the Exmor T with the Xperia 1 V smartphone on 10 May 2023.[14]

LYTIA

[edit]

On 7 November 2022, Sony announced their LYTIA brand of CMOS image sensors for mobile devices.[15][16][17]

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Exmor

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from Grokipedia
Exmor is a proprietary CMOS image sensor technology developed by Sony Semiconductor Solutions Corporation, introduced in 2007, that integrates column-parallel analog-to-digital (A/D) conversion directly on the sensor chip to enable high-speed readout, low-noise signal processing, and superior image quality in digital cameras, camcorders, and mobile devices.[1] The original Exmor technology, first commercialized in the APS-C sized IMX021 sensor with 12.47 effective megapixels, employs a front-illuminated structure where light passes through metal wiring layers before reaching the photodiodes, paired with on-chip correlated double sampling (CDS) and programmable gain amplification (PGA) circuits to minimize noise during signal conversion.[1] This innovation allows for parallel A/D conversion across sensor columns, enabling a readout rate of 10.39 frames per second in full-pixel scan mode while maintaining 12-bit precision, marking a significant advancement over traditional CCD sensors in speed and power efficiency.[1] Building on this foundation, Sony introduced Exmor R in 2008 as a back-illuminated variant, repositioning the photodiodes above the wiring layers to capture more incident light—up to twice the sensitivity of standard front-illuminated sensors—resulting in reduced noise, higher dynamic range, and better low-light performance without increasing sensor size.[2] Exemplified in sensors like the 5-megapixel prototype with 1.75μm pixels, Exmor R enabled compact, high-resolution imaging in consumer electronics, such as mobile phones and digital still cameras.[2] Further evolution came with Exmor RS in 2012, the world's first stacked CMOS architecture that separates the pixel array (back-illuminated) from the signal processing logic on separate silicon layers, interconnected via copper-to-copper bonding for high readout speeds (up to 120 frames per second in sub-sampling modes) and integrated features like high dynamic range (HDR) imaging via RGBW color filters.[3] This design, debuting in mobile-oriented sensors like the 13.13-megapixel IMX135, laid the foundation for later enhancements supporting advanced functions such as 4K video capture, phase-detection autofocus, and electronic image stabilization, powering flagship devices in smartphones, mirrorless cameras, and professional video equipment.[3] Subsequent enhancements, including the 2016 IMX318 with built-in hybrid autofocus and 3-axis stabilization, have solidified Exmor RS as a cornerstone for high-performance, compact imaging solutions.[4] Exmor technologies have been pivotal in Sony's imaging ecosystem, often paired with the BIONZ image processing engine to deliver lifelike colors, reduced graininess, and wide dynamic range, influencing industries from consumer photography to industrial machine vision and automotive applications. As of 2025, Exmor technologies continue to evolve, including variants like Exmor T and LYTIA for enhanced performance in diverse applications.[5]

Overview

Core Technology

Exmor represents Sony's proprietary CMOS image sensor architecture, featuring integrated column-parallel analog-to-digital converters (ADCs) that enable on-chip signal digitization for each vertical column of pixels. This design facilitates high-speed readout by minimizing analog signal transmission distances, thereby reducing noise introduction during transfer.[6] The technology incorporates dual noise reduction mechanisms, applying high-precision cancellation in both the analog domain prior to A/D conversion and the digital domain afterward, to suppress fixed-pattern noise, reset noise, and other artifacts.[6] At the heart of the signal processing pipeline is on-chip amplification of the pixel's analog output, followed by parallel A/D conversion across columns, and subsequent digital correlated double sampling (DCDS). DCDS involves sampling the reset level and signal level digitally to subtract noise components, enhancing overall image fidelity without requiring off-chip processing.[7] This integrated approach allows for efficient noise handling directly on the sensor, contributing to cleaner images in varied lighting conditions. Key performance enhancements in early Exmor implementations include a dynamic range of up to 72 dB in models like the APS-C sized sensor for digital SLRs.[1] Compared to traditional charge-coupled device (CCD) sensors, Exmor's CMOS design provides superior power efficiency—consuming significantly less energy (typically 20–50 milliwatts versus 2–5 watts for CCDs) during readout—and greater integration, as the embedded ADCs obviate the need for separate external conversion hardware.[8][9] Subsequent advancements, such as back-illuminated variants, build on these foundations to further optimize light capture while retaining the core column-parallel and dual noise reduction elements.[10]

Advantages Over Traditional Sensors

Exmor sensors provide significant advantages in noise reduction compared to traditional image sensors, primarily through the use of column-parallel analog-to-digital converters (ADCs) that process signals in close proximity to the photodiodes. This architecture minimizes the accumulation of readout noise during signal transfer, enabling superior low-light performance. In early implementations, this technology allows for clearer images in dim conditions without excessive grain.[7] The on-chip processing inherent to Exmor design further enhances speed and power efficiency over traditional charge-coupled device (CCD) sensors. By integrating analog-to-digital conversion and basic signal processing directly on the sensor chip, Exmor enables high frame rates while consuming significantly less power than equivalent CCDs. This efficiency stems from the parallel readout mechanism, which avoids the serial charge transfer bottlenecks of CCDs, resulting in faster data handling and lower energy demands during operation.[8] Beyond performance, Exmor's integrated architecture supports more compact device designs in cameras and mobile applications by handling essential image processing functions on-chip, thereby reducing or eliminating the need for separate image signal processors (ISPs). This streamlining lowers overall system complexity and size, facilitating slimmer profiles in consumer electronics. Additionally, the reduced power consumption contributes to greater energy efficiency in end devices, extending battery life and minimizing environmental impact through lower operational energy use across widespread applications.[7][8]

History

Origins and Early Development

Exmor technology originated in the mid-2000s at Sony, driven by the need to overcome persistent noise limitations in CMOS image sensors that hindered their adoption in digital cameras compared to dominant CCD sensors.[11] Sony Semiconductor spearheaded the development, focusing on innovative on-chip analog-to-digital conversion to enable high-speed readout and reduced noise, thereby enhancing low-light performance and overall image quality.[7] This effort marked a pivotal shift toward making CMOS sensors viable for consumer imaging applications, where CCDs had previously excelled in sensitivity and clarity.[12] The technology was first commercialized in 2007 through a CMOS image sensor featuring a unique column-parallel A/D conversion circuit, which achieved superior signal-to-noise ratios and processing speeds.[11] Sony announced Exmor alongside its debut product, the Alpha DSLR-A700, on September 6, 2007, positioning the 12.2-megapixel APS-C sensor as a key enabler for professional-grade low-noise imaging in a mid-range DSLR camera launched later that year.[12] The A700's integration of Exmor demonstrated immediate practical benefits, including 5 frames-per-second continuous shooting and effective noise suppression at higher ISOs, helping to accelerate the industry's transition from CCD to CMOS architectures.[13] Early implementations extended Exmor's reach beyond DSLRs, with adoption in select consumer devices to showcase its versatility in reducing read noise and improving dynamic range.[14] By 2008, expansions included higher-resolution variants for digital SLRs and video camcorders, solidifying Exmor's role in Sony's imaging ecosystem.[15] In October 2015, Sony restructured its operations by spinning off its semiconductor division into Sony Semiconductor Solutions Corporation, a move designed to sharpen focus on high-growth areas like image sensors, encompassing the Exmor lineup and supporting ongoing advancements in noise reduction and sensitivity.[16]

Key Milestones and Evolution

Sony introduced the Exmor R CMOS image sensor on June 11, 2008, marking the world's first back-illuminated design that doubled light sensitivity compared to conventional front-illuminated sensors while reducing noise.[17][18] This advancement significantly improved low-light performance, enabling clearer images in challenging conditions for consumer electronics.[19] On August 20, 2012, Sony unveiled the Exmor RS, the first stacked CMOS image sensor tailored for smartphones, integrating circuitry beneath the photodiodes to boost readout speeds and support high-frame-rate applications like 20 fps burst shooting.[3][20] This innovation expanded Exmor's reach into mobile devices, enhancing video capabilities and reducing motion blur.[7] In 2014, Sony debuted the STARVIS series, optimized for security cameras with enhanced low-light sensitivity through back-illuminated pixels that captured more near-infrared light for superior night vision.[21][22] These sensors prioritized surveillance applications, delivering noise-reduced images in extreme darkness.[23] Sony announced the Intelligent Vision Sensor on May 14, 2020, an AI-integrated variant of Exmor that embedded processing for on-sensor inference, enabling edge AI tasks like object detection without external hardware.[24] This development bridged imaging and computation, facilitating real-time analytics in compact systems.[25] The LYTIA brand launched on November 7, 2022, as a dedicated lineup for mobile image sensors under the Exmor umbrella, focusing on high-resolution, creative imaging for smartphones.[26] It emphasized stacked architectures for improved dynamic range and autofocus.[27] Advancements accelerated in the early 2020s, with STARVIS 2 introduced via the IMX585 sensor on June 29, 2021, offering 4K resolution and higher dynamic range for security applications through dual-gain readout.[28] In 2024, the IMX678 extended STARVIS 2 capabilities with 8MP resolution and enhanced near-infrared performance for low-light streaming.[29] Exmor T debuted in the Xperia 1 V smartphone on May 11, 2023, featuring a 2-layer transistor pixel structure for superior low-light noise reduction.[30] In September 2024, Sony released the LYT-818 under LYTIA, a 50MP sensor with advanced noise reduction achieving a record-low 0.95e- signal-to-noise ratio for mobile HDR imaging.[31] This was followed by the LYT-828 on June 26, 2025, delivering over 100 dB dynamic range—equivalent to 17 stops—for lifelike smartphone photography even during zoom.[32] The Xperia 1 VII, announced May 13, 2025, integrated Exmor T across all rear cameras, unifying high-sensitivity performance for professional mobile videography.[33] Exmor's market impact grew through widespread adoption; the iPhone 4S in 2011 featured an Exmor R-based sensor for improved mobile photography,[34] while the Xiaomi 12S Ultra in 2022 utilized the IMX989 Exmor variant for 1-inch flagship imaging.[35] Sony plans a full transition from IMX to LYTIA branding by 2026, streamlining its mobile sensor portfolio.[36]

Sensor Architectures

Front-Side Illuminated Design

The front-side illuminated (FSI) design in original Exmor sensors directs incoming light through the top layers of each pixel, where it first encounters the on-chip microlens, followed by the color filter array, and then the metal wiring layers before reaching the photodiode at the base.[37] This configuration, common in early CMOS image sensors, positions the interconnect wiring and transistors on the same side as the light entry, creating an optical path that traverses multiple opaque or semi-opaque elements.[38] As a result, a portion of the incident light is absorbed, reflected, or scattered by the wiring, leading to reduced light collection efficiency, particularly in smaller pixels where the wiring occupies a larger relative area.[39] Early Exmor pixels in FSI architecture typically featured sizes around 5.6 µm, such as the 5.49 µm square pixels in the IMX021 sensor, which incorporated microlenses to focus light onto the photodiode and mitigate some path-related losses.[1] These microlenses help concentrate photons despite the overlying structures, but the overall fill factor—the proportion of the pixel area sensitive to light—remains limited to approximately 50-60% in typical FSI designs, contributing to quantum efficiencies of about 40-50%.[39][40] For instance, the IMX021, a 12.47 effective megapixel APS-C sensor released in 2007 for digital SLR cameras, exemplified this approach with its high-resolution array but inherent constraints on light gathering.[1] While the FSI structure excels in enabling dense pixel arrays for high-resolution imaging, it introduces performance trade-offs, notably in low-light conditions where the wiring layers cast shadows and cause crosstalk, limiting sensitivity compared to unobstructed photodiode exposure.[38] These limitations, including significant light loss in sub-3 µm pixels due to elongated optical paths and reflections, underscored the need for architectural advancements to enhance photon capture without sacrificing resolution.[41]

Back-Illuminated and Stacked Designs

The back-illuminated structure in Exmor R sensors relocates the wiring layer to the rear of the photodiodes, enabling nearly full light incidence on the light-sensitive elements without obstruction from overlying circuitry.[42] This design contrasts with front-side illuminated sensors by maximizing photon capture, resulting in approximately double the sensitivity compared to conventional front-illuminated CMOS sensors.[43] Exmor R technology was initially applied in compact cameras, such as those using 1/2.5-inch sensors, to enhance low-light performance in consumer devices.[10] Building on back-illumination, the Exmor RS series introduced stacked architectures in 2012, separating the pixel array and signal processing logic into distinct layers bonded via copper-to-copper (Cu-Cu) direct connections for improved speed and efficiency.[3][44] This stacking allows faster readout by dedicating the logic layer to processing without compromising pixel area, achieving pixel sizes as small as 1.12 µm while supporting high-resolution imaging.[3] Later iterations incorporate DRAM caching through three-layer stacking—comprising pixel, logic, and memory layers—to buffer data for ultra-high frame rates, enabling 960 fps slow-motion capture in short bursts for mobile applications.[45] This three-layer stacking technology offers advantages including doubled saturation signal quantity for better high-light details, substantially improved dynamic range and low-light performance, reduced noise allowing smaller pixels without performance loss, on-chip AI for real-time HDR and object recognition, support for high-speed 8K video and reduced focal plane distortion, and enhanced image quality in low light, dynamic range, and video stabilization.[46][47][48] Such configurations also facilitate readout speeds up to 120 fps in 4K resolution, enhancing video capabilities in stacked sensors.[49] As of 2025, these stacked designs have further evolved to support global shutter functionality and ultra-high resolutions up to 8K in professional and automotive applications.[50] Overall, back-illuminated and stacked designs in Exmor R and RS yield significantly higher quantum efficiency compared to front-side illuminated ones, primarily by reducing light loss from metal wiring.[51]

Specialized Variants

STARVIS Series

The STARVIS series represents Sony's specialized back-illuminated CMOS image sensor technology optimized for low-light surveillance applications, building on the Exmor RS architecture to enhance sensitivity in challenging lighting conditions. Introduced in August 2014, STARVIS sensors feature expanded pixel wells that increase light-gathering capacity, achieving a sensitivity of at least 2,000 mV/μm² while delivering a dynamic range of up to 88 dB in select models. This design minimizes noise in dark scenes by converting faint light signals into clear images without significant amplification artifacts, making it ideal for security cameras capturing details in environments like unlit alleys or nighttime streets.[23][22] STARVIS 2, launched in 2021, advances this foundation with innovations like dual gain ISO circuitry and super high conversion gain (SHCG), which dramatically lowers the noise floor by optimizing signal amplification paths for both bright and dim conditions. These enhancements enable near-zero noise levels in ultra-low light, supported by black level correction techniques that suppress dark current and residual signals for cleaner outputs. A flagship example is the IMX585, an 8.3-megapixel sensor in a 1/1.2-inch format capable of 4K resolution at 90 fps, incorporating AI-friendly processing for object recognition in surveillance feeds while maintaining high near-infrared sensitivity.[28][23] Recent additions to the STARVIS 2 lineup include the 8-megapixel IMX678 and 5-megapixel IMX675 sensors, both introduced around 2023 for automotive and security use, offering superior HDR performance up to 120 dB via digital overlap techniques to handle extreme contrast in dashcams and monitoring systems. STARVIS sensors enable reliable imaging in surveillance and automotive applications where visibility is critical, such as traffic monitoring or facility security.[52][53]

Exmor T and LYTIA

Exmor T, announced by Sony in December 2021 and first commercialized in 2023, represents a significant advancement in mobile image sensor technology through its innovative 2-layer transistor pixel (2TP) structure within a stacked CMOS image sensor. This design physically separates the photodiode layer, responsible for signal accumulation, from the transistor layer, which handles amplification and readout, allowing for a larger photodiode area that enhances light sensitivity and full well capacity while reducing noise. As a result, Exmor T achieves dynamic range and low-light performance comparable to full-frame sensors in a compact mobile form factor, with approximately 2x the saturation signal level of conventional designs. The technology debuted in the Sony Xperia 1 V smartphone, where it powers the 48-megapixel main camera sensor, delivering optimized pixel architecture for enhanced light capture.[54][55][56] Building on this foundation, Sony launched the LYTIA brand in November 2022 as a dedicated lineup of advanced CMOS image sensors for mobile devices, emphasizing stacked architectures that incorporate 2-layer transistor pixels to enable creative imaging experiences with superior tonal expression, high dynamic range, and low noise. LYTIA sensors build upon back-illuminated designs to maximize light capture in slim smartphone modules. Key releases include the LYT-818, a 50-megapixel sensor with a 1/1.28-inch optical format announced in September 2024, which significantly reduces random noise in low-light conditions and supports an 86 dB dynamic range through advanced HDR processing. Following this, the LYT-828, another 50-megapixel model released in June 2025, achieves an unprecedented 17 stops of dynamic range (over 100 dB) by combining single-frame HDR via dual conversion gain with multi-frame HDR techniques, enabling natural-looking images even in high-contrast scenes like backlit portraits.[26][57][58][59][32] LYTIA's pixel-level HDR capabilities, realized through per-pixel dual conversion gain that toggles between high and low sensitivity modes without frame merging, allow for real-time preview-accurate HDR output in video and stills, preserving details in both shadows and highlights. Advancements in the series also include support for AI-enhanced features like computational bokeh effects in portrait modes, leveraging the sensors' high-fidelity data for more accurate subject isolation. Recent developments in LYTIA incorporate three-layer stacking technology, which doubles the saturation signal quantity for improved high-light details, substantially enhances dynamic range and low-light performance, reduces noise to enable smaller pixels without sacrificing performance, integrates on-chip AI for real-time HDR processing and object recognition, supports high-speed 8K video capture with reduced focal plane distortion, and improves overall image quality including low-light sensitivity, dynamic range, and video stabilization. In May 2025, the Sony Xperia 1 VII became the first smartphone to implement full Exmor T technology across all three rear lenses, extending 2TP benefits to ultra-wide and telephoto cameras for consistent low-noise performance throughout the system. Leaks from September 2025 indicate Sony is developing LYTIA sensors rivaling 200-megapixel resolutions, potentially with 1/1.11-inch formats for even greater detail in mobile photography (as of October 2025). To streamline its mobile portfolio, Sony plans to rebrand its existing IMX series sensors under the unified LYTIA name by 2026, phasing out separate designations while maintaining backward compatibility.[60][32][61][62][63][64][46]

Applications and Impact

Consumer Devices

Exmor sensors have been integral to smartphone cameras since their early adoption, enhancing image quality in compact devices. The iPhone 4S, released in 2011, featured Sony's IMX145 Exmor R back-illuminated sensor, which improved low-light performance and enabled 1080p HD video recording at 30 fps.[65][66] More recent advancements include the LYTIA series, a stacked CMOS variant of Exmor technology; for instance, the Xiaomi 14 Ultra (2024) incorporates the LYT-900 50MP 1-inch sensor, supporting 8K video and advanced night modes through high dynamic range capture and reduced noise.[67] Similarly, Motorola's Edge 50 Neo (2024) uses the LYTIA 700C 50MP sensor, facilitating 4K video at 60 fps and superior low-light imaging via dual-pixel phase detection. These integrations have allowed smartphones to achieve professional-grade features like 4K video and computational night modes, where multiple exposures are processed to minimize noise in dim conditions.[68] In digital cameras, Exmor R technology has powered Sony's Cyber-shot and Alpha series, delivering high-resolution imaging in consumer-friendly formats. Models like the Cyber-shot DSC-HX7V (2011) employ an Exmor R CMOS sensor for 16.2MP stills and Full HD video with 10x optical zoom, emphasizing low-noise performance in varied lighting.[69] The Alpha ILCE-7RM2 (2015), a full-frame mirrorless camera, utilizes a 42.4MP Exmor R back-illuminated sensor, enabling 4K video extraction from 7K oversampling and ISO up to 102,400 for low-light scenarios.[70] These sensors have contributed to the evolution of compact photography by supporting features such as optical image stabilization and high-speed burst shooting. Camcorders in the consumer space, particularly Sony's Handycam line, have benefited from Exmor since its introduction around 2009, with early models like the HDR-CX500V incorporating the back-illuminated CMOS for reduced noise and 10x optical zoom in HD recording.[71] Subsequent Handycams, such as the HDR-CX405 (2015), feature Exmor R sensors that enable 1080p video at 60 fps with clear image zoom up to 60x digitally, maintaining quality in low light.[72] The widespread adoption of Exmor in consumer devices has significantly influenced computational photography, particularly by enabling HDR stacking techniques in mobiles, where multiple short and long exposures are merged to expand dynamic range and preserve details in highlights and shadows.[68] This has democratized advanced imaging, allowing everyday users to capture balanced photos without specialized equipment. By 2023, Sony's Exmor-based image sensors powered approximately 53% of the global smartphone sensor market by revenue, underscoring their dominance in consumer electronics.[73]

Industrial and Professional Uses

Exmor technology, particularly through its STARVIS and STARVIS 2 implementations, plays a pivotal role in surveillance systems, enabling 4K IP cameras to deliver reliable 24/7 monitoring in challenging low-light conditions. These sensors capture high-sensitivity images with reduced noise, supporting applications in facility security, traffic surveillance, and urban monitoring by utilizing back-illuminated structures and super high conversion gain for near-infrared performance. For instance, the IMX585 sensor, a STARVIS 2 model with 8.3 megapixels and Clear HDR mode, facilitates internal data synthesis for wide dynamic range imaging up to 90 fps, making it suitable for professional surveillance setups including high-resolution webcams introduced in 2023.[23][74][28] In automotive applications, Exmor-based STARVIS 2 sensors enhance night visibility and safety features in dashcams and advanced driver-assistance systems (ADAS). The IMX678 sensor, with its 8-megapixel resolution and HDR capabilities, powers 4K front-facing dashcams that perform effectively in low-light environments, such as nighttime driving, by delivering clear footage with minimal distortion. Integration into ADAS involves high-dynamic-range imaging for obstacle detection and periphery monitoring, contributing to automated driving levels 3-4 through precise environmental sensing.[23][75][76] Professional broadcast equipment leverages Exmor sensors for superior 4K HDR production. The PXW-Z series, including the 2025 PXW-Z300 model, incorporates three 1/2-type 4K Exmor R CMOS sensors to achieve high-resolution video with extended dynamic range and low noise, supporting workflows in television broadcasting and live streaming via formats like XAVC and HLG. These sensors enable 17x zoom lenses and real-time processing for professional-grade clarity in diverse shooting conditions.[77][49] For industrial machine vision, Exmor global shutter variants provide distortion-free imaging essential for high-speed inspection tasks. Sony's Pregius technology, built on Exmor architecture, features sensors like the IMX927 with 105-megapixel resolution and up to 100 fps readout, allowing precise capture of moving objects in manufacturing lines for defect detection and quality control. These sensors excel in controlled environments by minimizing rolling shutter artifacts and supporting ultraviolet to infrared spectrums.[78][79] Advancements in Exmor include Intelligent Vision Sensors that integrate AI edge processing for enhanced industrial applications. Released in 2020, the IMX500 series embeds AI functionality directly on the sensor's logic chip, enabling real-time anomaly detection in settings like factory monitoring by processing data at 3.1 ms latency without external computing, thus improving efficiency and privacy. This on-chip capability supports selectable AI models for tasks such as object recognition and abnormality identification in professional vision systems.[24][80]

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  71. Automotive Camera/LiDAR | Application
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