Camera Link
Camera Link is a high-speed serial communication interface standard designed specifically for machine vision applications, standardizing the connection between digital cameras and frame grabbers or processing units to enable reliable, real-time transfer of image data, camera control signals, synchronization triggers, and serial communications.[1] Developed jointly by the Automated Imaging Association (AIA, now part of A3) and the Japan Industrial Imaging Association (JIIA) and first released in October 2000, it addressed the need for a robust, interoperable protocol in industrial imaging systems where high-bandwidth, low-latency data transmission is essential.[2][3][4] The standard defines multiple configurations to accommodate varying data requirements: Base (up to 2.04 Gbps or 255 MB/s over one cable), Medium (4.08 Gbps or 510 MB/s over two cables), Full (5.44 Gbps or 680 MB/s over two cables), and Deca (6.80 Gbps or 850 MB/s over two cables), operating at pixel clock rates from 40 MHz to 85 MHz.[4] It uses dedicated MDR 26-pin, SDR/HDR 26-pin (for Mini Camera Link), or HDR 14-pin (for PoCL-Lite) connectors, with maximum cable lengths of 7–15 meters depending on the configuration and quality.[4] Key enhancements include Power over Camera Link (PoCL) for delivering up to 4 W of power through the data cable, reducing wiring complexity, and PoCL-Lite for cost-effective, compact setups in base configurations.[3][1][5] Since its inception, Camera Link has evolved through revisions, with version 1.1 in 2004 integrating support for the GenICam standard to enhance software interoperability, version 2.0 in February 2012 consolidating features like Mini Camera Link and PoCL specifications, and version 2.1 in 2014 refining connector details and adding FPGA support while mandating interoperability testing via PlugFests.[1][3] Maintained by A3 and JIIA committees, the standard remains widely adopted for its deterministic performance and backward compatibility, though it has been extended by Camera Link HS (released in 2012) to leverage serializer/deserializer (SerDes) technology for even higher speeds up to several Gbps over longer distances using off-the-shelf cables.[2][4]Overview
Definition and Purpose
Camera Link is an open standard interface specification for digital cameras, designed to enable high-bandwidth, low-latency data transfer specifically for machine vision and industrial imaging applications.[1] It standardizes the hardware connection between imaging devices and processing systems, utilizing Low-Voltage Differential Signaling (LVDS) technology to transmit serialized pixel data over dedicated cables.[5] Developed jointly by the Automated Imaging Association (AIA, now part of the Association for Advancing Automation (A3)) and the Japan Industrial Imaging Association (JIIA), this protocol extends upon National Semiconductor's Channel Link serializer/deserializer technology to ensure interoperability across vendors.[1][3] The primary purpose of Camera Link is to facilitate the reliable, real-time transmission of pixel data, control signals, and synchronization information from cameras to frame grabbers in demanding environments such as factory automation, quality inspection, and scientific research.[1] By defining a complete interface that includes provisions for data transfer, camera timing, serial communications, and real-time signaling, it minimizes integration challenges, reduces support costs, and promotes plug-and-play compatibility in vision systems.[5] A typical Camera Link setup consists of three core components: the camera serving as the data source, the frame grabber acting as the receiver and processor, and a cable assembly enabling point-to-point connections between them.[1] The standard supports bandwidths up to 850 MB/s (equivalent to 6.8 Gbps) in advanced modes, leveraging LVDS for its noise immunity, low power consumption, and ability to handle high-speed differential signaling over distances up to 10 meters.[1] Configurations such as Base, Medium, Full, and Deca provide scalable options to match varying imaging needs without altering the fundamental protocol.[5]Key Features
Camera Link distinguishes itself through its high-speed data transmission capabilities, enabling efficient handling of high-resolution imaging in machine vision applications. In Base configuration, it achieves a bandwidth of 2.04 Gbps (255 MB/s), scaling up to 4.08 Gbps (510 MB/s) in Medium mode and 5.44 Gbps (680 MB/s) in Full mode, with Deca providing up to 6.8 Gbps (850 MB/s) to support rapid frame rates for demanding scenarios like industrial inspection. This scalability, combined with deterministic latency typically under 1 microsecond due to its direct connection architecture, ensures predictable and real-time performance without buffering delays.[5][6] Reliability is enhanced by the use of Low-Voltage Differential Signaling (LVDS), which provides robust resistance to electromagnetic interference (EMI) through differential transmission immune to common-mode noise up to ±1 V. The protocol's point-to-point topology eliminates network overhead, reducing complexity and potential failure points while maintaining high integrity in noisy industrial environments. It supports pixel depths from 8-bit to 12-bit monochrome or up to 24-bit color, accommodating a wide range of sensor outputs without requiring additional encoding layers.[5][6] A core advantage lies in its bidirectional communication framework, which integrates video data streaming with control signals over the same interface. This allows simultaneous transmission of commands such as external triggers, gain adjustments, and exposure settings via dedicated camera control lines (CC1–CC4) and serial channels operating at a minimum of 9600 baud, facilitating seamless integration without separate cabling. The non-packetized, serial nature of the protocol further simplifies implementation, promoting interoperability across compliant cameras and frame grabbers.[5][1]History and Development
Origins and Initial Release
Camera Link's development began in the late 1990s under the auspices of the Automated Imaging Association (AIA), an organization dedicated to advancing machine vision standards, which later merged into the Association for Advancing Automation (A3) in 2013. The initiative, developed jointly with the Japan Industrial Imaging Association (JIIA), stemmed from the need to create a unified interface for digital cameras and frame grabbers in industrial applications, addressing the limitations of existing analog and early digital connections. Pioneering efforts were led by an informal working group of AIA members, headed by PULNiX America, which built upon the National Semiconductor Channel Link serializer/deserializer technology for high-speed data transmission.[7] The first official specification, version 1.0, was published by AIA in October 2000, marking the standard's formal introduction.[8] Key contributors included leading camera manufacturers such as Basler, Teledyne DALSA, and EPIX, alongside frame grabber developers, who collaborated through AIA to define the protocol.[9] This partnership aimed to replace slower legacy interfaces, including analog standards like RS-170 and early parallel digital links, which struggled with the increasing demands of higher-resolution sensors in machine vision systems.[10] The motivations centered on providing greater bandwidth—up to 2.04 Gbit/s initially—to support real-time image transfer amid rising sensor resolutions, while standardizing on the existing MDR26 (Mini Delta Ribbon 26-pin) connector, originally from SCSI technology, to ensure compatibility and reduce costs.[1] By leveraging low-voltage differential signaling (LVDS), approved as ANSI/TIA/EIA-644 in 1996, the standard enabled reliable, high-speed serial data streams over shorter cable lengths.[5] Initial adoption was swift within industrial machine vision sectors, driven by the standard's interoperability and the AIA's certification program, which ensured logo-bearing products met specifications. By 2003, numerous certified cameras and frame grabbers from licensed manufacturers were available, facilitating rapid integration into automation lines for quality inspection and robotics.[1] This early uptake established Camera Link as a de facto standard, with hundreds of compliant products emerging shortly after its release, though subsequent updates would address evolving needs.[11]Evolution and Updates
The Camera Link standard underwent significant revisions following its initial release to accommodate evolving demands for higher data throughput and simplified integration in machine vision systems. Version 1.0, published in 2000 by the Automated Imaging Association (AIA), focused on the Base configuration, supporting up to 2.04 Gbps over a single cable for reliable, low-latency image transfer.[2] In 2004, version 1.1 expanded capabilities by introducing Medium and Full configurations, which scaled bandwidth to 4.08 Gbps (510 MB/s) and 5.44 Gbps (680 MB/s) respectively using dual cables, while incorporating GenICam support for standardized camera control across diverse software environments.[12] Version 1.2, released in January 2007, further advanced the protocol by adding the Deca configuration—an 80-bit mode leveraging 10 taps across multiple links to achieve up to 6.8 Gbps (850 MB/s), effectively extending capabilities for high-resolution imaging—and introducing Power over Camera Link (PoCL) to deliver up to 4 W per cable, reducing the need for separate power supplies.[13][8] The standard is jointly maintained by A3 (formerly AIA) and the Japan Industrial Imaging Association (JIIA), ensuring compatibility with broader GenICam frameworks.[6] In February 2012, the specification advanced to version 2.0, formalizing Deca as the official term for 80-bit mode and refining electrical and connector specifications, including mini Camera Link options.[5] Version 2.1, released in 2014, addressed ambiguities in high-dynamic-range (HDR) and standard-dynamic-range (SDR) signaling, as well as PoCL implementation details for improved power delivery reliability.[14] Post-2012 enhancements emphasized extended reach and interoperability. Camera Link HS, released in May 2012, utilizes serializer/deserializer (SerDes) technology over off-the-shelf copper or fiber optic cables, supporting bandwidths up to 16 Gbps across eight links and distances exceeding 100 meters—far surpassing traditional Camera Link limitations.[15][16] In the 2020s, minor updates integrated the GenICam Generic Data Container (GenDC) module, released in version 1.1 in June 2020, which enables flexible, packet-like data handling akin to GigE Vision over Camera Link and HS interfaces, facilitating multi-dimensional and multi-spectral image transmission.[17] Adoption milestones include the certification of Deca-capable products by 2010, marking widespread availability of high-throughput implementations, and as of November 2025, seamless integration of Camera Link HS as a robust alternative to CoaXPress for long-distance, high-speed applications.[18]Technical Protocol
Data Transmission Mechanism
Camera Link utilizes a serialized data transmission protocol leveraging Channel Link technology to transfer pixel data efficiently from the camera to the frame grabber. The core mechanism involves packaging pixel data into 28-bit frames, comprising 24 bits of actual pixel data and 4 control bits, which are then serialized and sent over multiple high-speed serial lanes. This approach enables high-bandwidth video transmission without the overhead of packet-based protocols, making it suitable for real-time imaging applications.[5] At the physical layer, the protocol employs Low-Voltage Differential Signaling (LVDS) across differential pairs for each serial lane, providing robust noise immunity and high-speed operation. Serialization follows a 7:1 ratio, where seven bits are transmitted in parallel per clock cycle, driven by a pixel clock frequency of up to 85 MHz. This configuration allows for effective data rates scaling with the number of lanes used in different configurations, such as Base, Medium, or Full modes.[5] The frame structure is defined by embedded control signals—Line Valid (LVAL), Frame Valid (FVAL), and Data Valid (DVAL)—which indicate the boundaries of active lines, frames, and data within the serialized stream. These signals facilitate synchronization and support both progressive scan and interlaced video formats, ensuring compatibility with various camera output modes.[5] The protocol prioritizes low-latency performance and does not include error detection or retransmission capabilities for video data, relying instead on the robustness of LVDS signaling for integrity in machine vision applications.[5]Signal Timing and Synchronization
Camera Link employs a pixel clock signal to synchronize data transmission, with frequencies ranging from 20 MHz to a maximum of 85 MHz in the Base configuration, ensuring precise timing for pixel data sampling on the rising edge.[19] Each transmission lane includes a serialized clock derived from the pixel clock, operating at seven times the pixel rate (up to approximately 595 MHz serialized per lane) to facilitate the 7:1 serialization used in the protocol.[5] Synchronization in Camera Link relies on three primary control signals: Frame Valid (FVAL or FV), which asserts HIGH during valid lines to delineate frame boundaries with no edge offsets; Line Valid (LVAL or LV), which asserts HIGH during valid pixels within a line; and Data Valid (DVAL or DV), which asserts HIGH only when pixel data is valid for capture.[20][5] These signals ensure accurate alignment of image data across the interface, with FVAL required on the first serializer chip and LVAL and DVAL distributed as needed per configuration. Key timing parameters include minimum setup and hold times of 2 ns for data signals relative to the clock edge, allowing reliable latching at high speeds.[21] Skew tolerances are specified with maximum intra-pair and pair-to-pair skew of 190 ps at 85 MHz pixel clock (290 ps at 66 MHz, 390 ps at 40 MHz) between pairs within data/clock groups to maintain signal integrity, with cable intra-pair skew limited to 50 ps per meter.[5][22] For legacy compatibility, Camera Link supports interlaced video formats through the synchronization signals, where odd and even fields are indicated to distinguish interlaced frames, enabling integration with traditional video systems.[5]Bit Assignments and Encoding
In Camera Link, data transmission occurs via a 28-bit parallel frame structure prior to serialization, where bits 0 through 23 are dedicated to pixel data in various bit-depth modes, while bits 24 through 27 handle control signals.[5] This assignment ensures that up to 24 bits of image data—supporting formats such as monochrome or Bayer patterns—can be conveyed per frame cycle, with the control bits providing essential synchronization for frame grabbers.[23] The control bits are specifically mapped as follows: bit 24 to Line Valid (LVAL), which asserts high during valid pixel data within a line; bit 25 to Frame Valid (FVAL), which asserts high for valid lines within a frame; bit 26 to Data Valid (DVAL), which indicates when accompanying pixel data is reliable; and bit 27 to Spare, reserved for optional custom signals.[5][23] These signals are replicated across all active serializer channels to maintain consistency in multi-port configurations. The Spare bit, while not mandatory, allows cameras to transmit user-defined signals, such as exposure triggers or auxiliary status flags, enhancing flexibility without altering the core protocol.[5] For encoding, the Base configuration employs a 7:1 serialization ratio using Roadrunner-compatible schemes, converting the 28-bit frame (including 24 data bits and a clock) into four LVDS data streams plus a strobe for reliable high-speed transmission.[23] This process scrambles the bits across channels according to the serializer's internal mapping—such as assigning pixel bits to non-sequential inputs on Channel Link chips—to optimize signal integrity and reduce crosstalk.[5] Bit usage varies by pixel depth to accommodate 8-bit, 10-bit, and 12-bit modes, with data packed starting from bit 0 and unused bits padded with zeros or ignored. In 8-bit mode, each pixel tap occupies bits 0-7, allowing up to three taps (bits 0-23 fully utilized for 24 pixels worth of data). For 10-bit mode, each tap uses bits 0-9, supporting two taps (bits 0-19 for data, 20-23 padded). In 12-bit mode, each tap spans bits 0-11, limited to two taps (bits 0-23 covering data with partial padding). The following table illustrates representative assignments for Base configuration modes:| Mode | Tap 1 Bits | Tap 2 Bits | Tap 3 Bits | Total Data Bits | Padding/Unused |
|---|---|---|---|---|---|
| 8-bit x3 | 0-7 | 8-15 | 16-23 | 24 | None |
| 10-bit x2 | 0-9 | 10-19 | N/A | 20 | 20-23 |
| 12-bit x2 | 0-11 | 12-23 | N/A | 24 | None |
Configurations
Base Configuration
The Base Configuration of Camera Link provides the entry-level single-cable interface for connecting digital cameras to frame grabbers in machine vision systems, utilizing a 26-pin Mini Delta Ribbon (MDR26) connector to support Low-Voltage Differential Signaling (LVDS) transmission. This setup incorporates one transmit link comprising four LVDS pairs—one clock pair and three data pairs—for video signals, along with two additional LVDS pairs for bidirectional serial control communication between the camera and frame grabber. The resulting bandwidth is 2.04 Gbps, or 255 MB/s, enabling reliable transfer of up to 24 bits of video data plus four framing bits per pixel clock cycle.[24][4][5] In terms of pixel throughput, the Base Configuration supports maximum pixel clock rates of 85 MHz for 8-bit monochrome imaging in single-, dual-, or triple-tap modes, achieving full bandwidth utilization for 24-bit data output. For 12-bit imaging in dual-tap mode, it similarly accommodates up to 85 MHz pixel clocks, packing 24 bits of data while maintaining compatibility with the standard serializer architecture. These capabilities make it ideal for entry-level machine vision applications, such as monochrome sensors in automated inspection or low-resolution color cameras for basic quality control in manufacturing environments.[19][11][18] Key limitations include a maximum certified cable length of 10 meters to ensure signal integrity across all supported clock speeds, beyond which attenuation and noise may degrade performance. Additionally, the point-to-point design precludes multi-camera daisy-chaining, necessitating separate cables for each device; higher-throughput scenarios requiring expanded links are handled in Medium and Full configurations.[25][5]Medium and Full Configurations
The Medium configuration in Camera Link extends the Base setup by incorporating two serial links, effectively doubling the data bandwidth to 4.08 Gbps (510 MB/s) while utilizing two MDR 26-pin cables.[23] Data is split across these links, supporting up to 48 bits total (ports A through F), which enables configurations such as 8-bit monochrome x 6 taps, 10-bit x 4-5 taps, or 12-bit x 4 taps, allowing for higher frame rates or resolutions compared to single-link operation.[19] This setup requires frame grabbers equipped with dual ports to aggregate the streams, ensuring seamless integration without altering the core protocol.[1] The Full configuration further scales bandwidth by employing three serial links, achieving 5.44 Gbps (680 MB/s) with two MDR 26-pin cables and supporting up to 64 bits (ports A through H).[23][4] This enables demanding applications, such as 8-bit monochrome x 8 taps or 10-bit x 6 taps, facilitating high-resolution imaging like 2048 x 2048 pixels at 30 frames per second.[19] Frame grabbers for Full mode must provide two ports to handle the parallel data paths, maintaining compatibility with lower configurations through subset port usage.[26] Synchronization across multiple links in both Medium and Full configurations relies on master-slave lane alignment, where control signals such as Line Valid (LVAL), Frame Valid (FVAL), and Data Valid (DVAL) are distributed to ensure temporal coherence between serializers and deserializers.[23] These signals, transmitted via dedicated LVDS pairs, prevent skew-induced errors, with the master link dictating timing for slaves to align pixel data streams accurately.[5] Transitioning from Base to Medium or Full requires hardware supporting additional ports but preserves backward compatibility, as the extra links can operate independently or in reduced modes without protocol changes.[1] Further bandwidth extensions, such as Deca mode, build on these principles but aggregate up to ten links for even greater throughput, as detailed in extended configurations.[4]Extended Configurations (Deca and Beyond)
The Deca configuration, formally known as the 80-bit mode in Camera Link version 2.0, extends data transmission by repurposing redundant control signals for additional data paths, supporting up to 80 parallel bits over two cables with a maximum bandwidth of 850 MB/s at an 85 MHz pixel clock.[5][18] This setup enables 10-tap 8-bit or 8-tap 10-bit modes, making it suitable for high-resolution line-scan and area-scan cameras requiring ultra-high throughput beyond the standard Full configuration.[27] Introduced as a de facto industry standard around 2011 and officially adopted in the February 2012 specification release, Deca was developed to address demands for 4K+ imaging in demanding environments.[27][5] Beyond Deca, extended configurations scale bandwidth further through aggregation of multiple Camera Link interfaces, often using multi-port frame grabbers or external hubs to combine 10 or more Base-equivalent links for total throughputs exceeding 20 Gbps in custom setups.[13] These aggregations repurpose additional cables—typically 5 dual-cable assemblies for Deca-scale extensions—while maintaining compatibility with the core protocol for data transmission and synchronization.[28] Control and synchronization signals are distributed across the links via dedicated frame grabber firmware or software, ensuring coherent image reconstruction without latency penalties.[29] The Camera Link HS (CLHS) variant enhances these setups by incorporating high-speed serial protocols over fiber optic or copper cables, supporting scalable lane configurations up to 16 GB/s aggregate bandwidth and distances beyond 100 meters.[15][30] Such extended configurations are particularly vital for ultra-high-speed scientific and industrial imaging, including synchrotron X-ray experiments where real-time capture of high-resolution data streams is essential, and medical scanners requiring aggregated bandwidth for volumetric reconstruction.[31][32] In synchrotron applications, for instance, multi-link Camera Link systems facilitate the acquisition of dynamic events at rates supporting thousands of frames per second, leveraging the protocol's low-jitter timing for precise synchronization with beam pulses.Physical Layer
Cables and Length Limitations
Camera Link utilizes shielded twisted-pair copper cables consisting of 11 differential pairs for the Base configuration, along with four drain wires, to transmit high-speed serial data via low-voltage differential signaling (LVDS).[22] These cables incorporate robust shielding, including an overall braided shield with at least 80% coverage or a combination of foil and braid, and individual foil or braided shields around each pair to minimize electromagnetic interference.[5] The cables terminate in 26-pin Mini Delta Ribbon (MDR) connectors, with construction specifying 28 AWG stranded tin-plated copper conductors for optimal signal integrity and impedance of 100 ohms ±10%.[22] Power over Camera Link (PoCL) is an optional feature that delivers up to 4 watts through dedicated power conductors in the cable, enabling simplified camera powering without separate supplies, though higher configurations like Medium and Full may require up to 8 watts total across multiple cables.[5] Cable lengths are constrained by signal attenuation and integrity requirements: the maximum distance is 10 meters for the Base configuration at standard pixel clock rates, while higher-speed Medium and Full configurations limit lengths to 10 meters and 5 meters, respectively, to prevent excessive degradation.[6] Signal degradation in these copper cables arises primarily from intra-pair and inter-pair skew, as well as crosstalk, with specifications limiting intra-pair skew to 50 ps per meter and inter-pair skew similarly controlled to maintain timing alignment.[22] Insertion loss is a key attenuation factor, typically ranging from 0.35 dB/m at 100 MHz to 1.40 dB/m at 1 GHz for compliant cables, resulting in a maximum allowable loss of approximately 20 dB at 1 GHz over the full length to ensure reliable transmission.[22] For extended distances, fiber optic extensions via the Camera Link HS framework support active optical cables up to 100 meters, leveraging multi-mode or single-mode fiber to overcome copper limitations while maintaining compatibility with standard configurations.[15] In Medium, Full, and Deca configurations, which require multiple cables to achieve higher bandwidths (as detailed in the Configurations section), it is recommended to use cables of equal length to minimize differential skew that could disrupt synchronization across channels.[6] This equal-length recommendation ensures balanced propagation delays, with crosstalk limited to 20% near-end and far-end per industry testing standards.[5]Connectors and Pinouts
The primary connector for the Camera Link interface is the 26-pin Mini Delta Ribbon (MDR) connector produced by 3M, with a 1.27 mm pitch.[33] Cameras typically feature a female MDR connector, while cables terminate in male MDR connectors on both ends to facilitate direct mating.[22] In the Base configuration, a single 26-pin MDR connector supports multiple LVDS pairs, including five for video transmission from the camera: data pairs X0 (pins 15/2), X1 (16/3), X2 (17/4), X3 (19/6), and clock Xclk (18/5).[5] Additionally, there are LVDS pairs for serial communication: SerTC (pins 20/7, from frame grabber to camera) and SerTFG (pins 21/8, from camera to frame grabber), plus four camera control lines (CC1–CC4 on pins 9/22, 10/23, 11/24, 12/25). Inner shield grounds are on pins 1, 13, 14, and 26.[34] Power delivery in the original specification occurs via a separate subset of pins or external cabling, rated at 12 V and up to 2 A, though Power over Camera Link (PoCL) variants repurpose pins 1 and 26 for +12 V delivery with pins 13 and 14 as returns.[5] For Medium and Full configurations, two 26-pin MDR connectors are required per link, with the first handling Base signals (X0–X3, Xclk) and the second providing additional data pairs (Y0–Y3 and Yclk on pins 2/15 through 6/19 for Medium; extending to Z0–Z3 and Zclk on pins 8/21 through 12/25 for Full, with SerTFG on 7/20).[34] Extended configurations like Deca, supporting ten parallel Base links, employ multiple 26-pin MDR connectors (up to ten cables).[5] High-density variants optionally use 26-pin High-Density Ribbon (HDR) or Subminiature Delta Ribbon (SDR) connectors with a 0.8 mm pitch for space-constrained applications. For PoCL-Lite, a compact 14-pin HDR connector is used, supporting base configuration with integrated power delivery.[5][1] All LVDS signals operate with a nominal differential voltage swing of 350 mV and a common-mode voltage of 1.2 V to ensure reliable high-speed transmission.[23] Electrostatic discharge (ESD) protection is recommended for connector interfaces to safeguard against common industrial hazards.[23]| Configuration | Number of 26-pin Connectors | Key Data Pairs (Transmit from Camera) |
|---|---|---|
| Base | 1 | X0–X3, Xclk (pins 15/2, 16/3, 17/4, 19/6, 18/5) |
| Medium | 2 | X0–X3, Xclk (Connector 1); Y0–Y3, Yclk (Connector 2, pins 15/2–19/6) |
| Full | 2 | X0–X3, Xclk (Connector 1); Y0–Y3, Yclk, Z0–Z3, Zclk (Connector 2, pins 15/2–19/6, 21/8–25/12) |
| Deca | 10 | Ten independent Base sets |
Standards and Compliance
Core Specifications
The Camera Link standard is defined primarily by the Camera Link Interface Standard Specification version 2.0, published by the Automated Imaging Association (AIA) in February 2012. This document establishes the foundational framework for the interface, encompassing the communication protocol, electrical signaling characteristics, and mechanical connector requirements. It integrates prior revisions and annexes to ensure interoperability between cameras and frame grabbers in machine vision applications, including support for Mini Camera Link connectors and Power over Camera Link (PoCL).[5] Version 2.1, the current version, introduced further refinements including detailed jackscrew dimensions, documented bit positions for tap formats, support for Channel Link chip emulation in FPGAs, a new serial port API function, and mandatory interoperability testing via PlugFests, while maintaining backward compatibility.[1] Key electrical parameters include compliance with the TIA/EIA-644 standard for low-voltage differential signaling (LVDS), which employs a 350 mV differential output swing and current-mode drivers to achieve low power consumption and noise immunity up to ±1 V common-mode voltage.[5] Bandwidth capabilities vary by configuration, with maximum data throughput determined by the number of LVDS pairs and pixel clock rates up to 85 MHz:| Configuration | Data Bits | Maximum Bandwidth (Gbps) | Cables Required |
|---|---|---|---|
| Base | 24 | 2.04 | 1 |
| Medium | 48 | 4.08 | 2 |
| Full | 64 | 5.44 | 2 |
| Deca | 80 | 6.80 | 2 |