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Test card

A test card, also known as a test pattern, is a static visual signal broadcast by television stations to calibrate and align transmission equipment, as well as to assist viewers in adjusting their receivers for optimal picture quality.^[1]^[2] These patterns typically feature geometric shapes, color bars, grayscale ramps, and resolution charts designed to test aspects such as signal linearity, contrast, focus, and color accuracy in analog broadcasting systems.^[3]^[4] Originating in the 1930s, test cards emerged as television technology developed, with early examples used by broadcasters like the BBC to help engineers align signals and dealers set up receivers.^[4] In the United States, the RCA Indian Head test pattern, introduced in 1939, became iconic for its depiction of a Native American headdress and was widely used for two decades to ensure proper tuning on black-and-white sets.^[2] By the mid-20th century, test cards were a staple during off-air hours, filling dead time when stations signed off—often late at night or before dawn—before the advent of 24-hour programming in the 1980s and 1990s.^[1] In Europe, including the UK and Switzerland, they played a key role in standardizing broadcasts, evolving from simple printed cards to electronic signals as color television was introduced in the 1960s.^[3]^[4] Notable test cards include the BBC's Test Card F from 1967, the first color version transmitted in the UK featuring a young girl playing noughts and crosses, which became a cultural symbol and was used until the late 1990s.^[4]^[2]^[5] The Philips PM5544, designed in 1966 by engineer Finn Hendil, offered an intricate circular pattern for precise calibration and was adopted internationally for PAL and NTSC systems.^[2] In Switzerland, test cards broadcast from 1953 onward incorporated national symbols like the Swiss cross and were managed by the postal service until the shift to continuous broadcasting around 2005.^[3] These patterns not only ensured technical reliability but also evoked nostalgia for the pre-digital era of television.^[1]

Definition and Purpose

Core Concept

A test card, also known as a test pattern, is a specialized visual signal in television broadcasting, consisting of a static or animated image designed to facilitate the testing and calibration of transmission, reception, and display equipment.^[6]^[7] These patterns provide a standardized reference that allows broadcasters and viewers to verify and adjust signal integrity across the entire chain, from studio output to home receivers.^[8] The primary purposes of test cards include aligning key parameters such as color balance, contrast and brightness levels, geometric accuracy (like aspect ratio and scanning linearity), resolution, and audio-video synchronization.^[8]^[9] For instance, elements like contrast wedges and resolution gratings enable precise adjustments to ensure optimal image quality, while accompanying audio tones help calibrate sound levels and timing relative to the video.^[8]^[9] This calibration is essential for maintaining consistent performance without relying on variable live content. Test cards function as reliable reference images that engineers and technicians use to diagnose and fine-tune broadcast systems during off-air periods or maintenance, revealing issues like signal distortion or equipment misalignment in a controlled manner.^[8]^[6] They are typically static images featuring geometric shapes, grayscale ramps, and color bars to test fundamental display properties. This allows for comprehensive testing suited to baseline alignments.

Historical Role in Broadcasting

Test cards played a crucial role in early television broadcasting by filling gaps in programming schedules during non-broadcast hours, such as overnight periods or maintenance slots, ensuring that transmitters remained active and signal integrity was preserved. In the 1950s and 1960s, when television networks like the BBC in the UK operated limited daily hours—often signing off around midnight and resuming in the morning—test cards were routinely transmitted to occupy the airwaves, preventing complete silence or "dead air" that could disrupt equipment or viewer expectations. This practice was widespread across regions; for instance, U.S. stations displayed patterns like the Indian-head test card after late-night sign-offs, maintaining a modulated signal until morning programming began, with major networks providing approximately 12-13 hours of programming per day by the 1960s.^[1]^[6] Their importance extended to standardization efforts, promoting compatibility in international broadcasting and aiding regulatory compliance by allowing engineers to verify transmission quality against established norms. In Europe, broadcasters influenced the design of test cards to ensure consistent calibration across borders, facilitating the exchange of programs between countries with varying technical setups. In the United States, while the Federal Communications Commission (FCC) did not mandate test patterns per se, stations utilized them during off-hours to align with technical operation rules, such as signal modulation requirements. This standardization was essential in the analog era, where discrepancies in alignment could render international feeds unusable.^[4] Test cards also shaped the viewer experience by providing a steady, reassuring presence on screens during quiet periods, often accompanied by audio elements like time announcements or light music that conveyed reliability and utility. For many households in the 1950s through 1980s, tuning into a test card—such as the BBC's Test Card F, broadcast daily from the late 1960s—signaled the end of the broadcast day, evoking a sense of closure while allowing families to adjust their sets for optimal viewing the next day. These patterns, sometimes featuring integrated clocks for precise timekeeping, served an educational function, informing late-night or early-morning audiences without demanding active engagement.^[6]^[3] As broadcasting evolved from analog to digital formats in the late 20th century, test cards transitioned from an essential operational tool to a supplementary or archival element, largely supplanted by 24-hour programming and automated systems. By the 1980s, with networks expanding to continuous schedules—exemplified by the BBC replacing daytime test cards with Ceefax teletext in 1983—their daily usage waned, though they persisted in maintenance roles until the early 2000s in regions like Switzerland, where full shutdowns ended around 2005. This shift reflected broader technological advancements, reducing the need for manual calibration while preserving test cards as nostalgic symbols of television's formative years.^[6]^[3]

Technical Components

Visual Elements

Test cards incorporate a range of standardized visual elements to facilitate precise calibration of television systems, ensuring accurate reproduction of brightness, color, geometry, and focus. Grayscale bars, typically arranged as a multi-step staircase from black to white, enable adjustment of brightness and contrast by assessing luminance response and nonlinearity across gray levels, with steps corresponding to specific IRE units (e.g., 0 IRE for black setup and 100 IRE for peak white in NTSC).^[10] Crosshatch grids, composed of evenly spaced horizontal and vertical lines, test geometric linearity and color convergence by revealing distortions or misalignments in the display's electron beams or pixel mapping.^[10] Circular or concentric ring patterns evaluate focus and curvature, where ideally round shapes indicate proper linearity; any elongation or waviness signals issues in horizontal/vertical scanning or lens focus in projection systems.^[8] Text or numeral overlays, such as fine-printed characters or line pairs, measure horizontal and vertical resolution by determining the smallest discernible details, aiding sharpness adjustments. Color bars form a core component for hue and saturation calibration, with the SMPTE pattern—prevalent in NTSC standards—featuring eight vertical bars in descending luminance order: white (100% luminance), yellow (88%), cyan (78.7%), green (59.7%), magenta (43.4%), red (28.1%), blue (19.1%), and black (7.5% setup).^[10] These bars use 75% saturation levels to avoid overdriving the signal, allowing technicians to match chrominance gain and phase; for instance, yellow and cyan peaks should align at 100 IRE when properly adjusted.^[10] In PAL and SECAM systems, EBU color bars adopt a similar structure but with adjusted ratios for 100/0/75/0 amplitude (luma/chroma) to accommodate the phase-alternating modulation, prioritizing compatibility with Rec. 601 colorimetry.^[11] Additional elements include pluge patterns for black-level setup, consisting of a reference black background with subtle bars at super-black (below setup), setup black, and slightly elevated gray (e.g., +4 IRE), where the middle bar should be just visible to prevent crushed shadows without lifting noise.^[12] Border signals, often subtle color ramps or tints around the image periphery, verify chrominance integrity and prevent overscan clipping. Safe action areas, marked by rectangular overlays or guides (typically 90% of the active picture width and height), ensure critical content remains visible despite edge masking in consumer displays, as defined in ITU standards for widescreen productions. Element density varies by resolution to match system capabilities; for example, 480i patterns use coarser grids (e.g., 20-30 lines in crosshatch) suitable for standard-definition interlacing, while 1080i versions incorporate finer details (e.g., 50+ lines) and higher-frequency multiburst signals to test extended bandwidth without aliasing.^[10]

Generation Techniques

The generation of test card signals has evolved from mechanical approaches to advanced digital techniques, enabling precise control over visual patterns for calibration and transmission testing. Mechanical methods dominated early television, utilizing rotating discs to scan patterns and produce video signals. In mechanical television systems, a Nipkow disc—a rotating metal plate with spirally arranged apertures—scanned the subject or pattern line by line, with light passing through the holes to modulate the signal based on intensity variations.^[13] Film loops, such as 16mm continuous strips containing test card images, were also employed to generate stable patterns for alignment in telecine equipment, ensuring consistent output during pre-transmission setup.^[14] Electronic methods introduced greater precision through cathode ray tube (CRT) signal generators and digital synthesizers. CRT-based generators produced test patterns by modulating electron beams to create specific waveforms, allowing for adjustable amplitude and frequency to simulate broadcast conditions. Digital synthesizers, employing direct digital synthesis (DDS) techniques, generated accurate sinusoidal and complex waveforms for test signals, offering fine resolution (e.g., 0.23 Hz tuning) and rapid frequency switching for comprehensive system evaluation.^[15] Monoscope technology represented a specialized electronic approach, functioning as a dedicated CRT variant for fixed-image generation. The device featured an electron gun that emitted a focused beam, accelerated from a cathode at approximately -1200 V toward a metal target (typically aluminum) etched or printed with the test pattern, replacing the standard phosphor screen. As the beam scanned the target using a deflection yoke, areas of the pattern with higher secondary electron emission (0.3–0.7 μA) produced brighter signal outputs, while low-emission regions yielded darker levels; secondary electrons were collected by a final anode at +30 V to form the composite video signal. Controls for beam current, gain, and black level allowed fine-tuning, with the target connected via a central pip for output extraction. This setup delivered high-resolution patterns, such as over 450 lines, without mechanical wear.^[16] The transition to digital techniques has leveraged hardware like GPUs, FPGAs, and dedicated software for high-definition (HD) and ultra-high-definition (UHD) systems. FPGAs implement efficient test pattern generators using reconfigurable logic to produce patterns like color bars or grids in real-time, supporting formats up to 4K at 600 MHz pixel rates.^[17] GPUs enable software-based generation, such as network-controlled pattern creation for calibration, processing complex visuals at high frame rates. Signal encoding often occurs in YCbCr color space, where luma (Y) and chroma (Cb, Cr) components are subsampled (e.g., 4:2:2 or 4:2:0) to optimize bandwidth while preserving perceptual quality in video pipelines.^[18]

Historical Development

Origins in Early Television

In the pioneering era of mechanical television during the 1920s, inventors like John Logie Baird experimented with rudimentary test patterns to verify signal transmission and image formation. Baird, working from his attic workshop in Hastings, England, successfully transmitted simple outline images, including a Maltese cross, over short distances of two or three yards in April 1924 using a Nipkow disc-based system that scanned light through perforated rotating disks.^[19] These basic geometric shapes served as early calibration tools, helping to assess the mechanical scanning process amid the era's primitive technology, which relied on selenium-coated cells to convert light into electrical signals. Such patterns were essential for troubleshooting distortions in the low-resolution, flickering images produced by these systems, marking the initial steps toward standardized visual testing in television.^[20] By the 1930s, as television transitioned toward more structured broadcasts, the British Broadcasting Corporation (BBC) introduced formal tuning signals that evolved into the first recognized test cards. In 1934, during experimental 30-line transmissions using Baird's mechanical system, the BBC broadcast its inaugural tuning signal: a simple hollow black circle intersected by a horizontal line, designed to aid engineers in aligning cameras and receivers for optimal image fidelity.^[21] With the launch of the BBC's regular high-definition service from Alexandra Palace in November 1936, this evolved into a more defined tuning symbol by 1937—a circle with a vertical line and occasional "BBC Television Service" lettering—created hastily by engineer William Paffard using basic materials during a trade exhibition.^[22] These patterns drew influences from film projection testing, where physical charts were used to calibrate lenses and projectors, and from radio broadcasting's audio tone signals, adapting them to visual synchronization in the nascent medium.^[23] In the United States, adoption accelerated in the late 1930s amid pre-commercial experimentation. RCA introduced the iconic Indian-head test pattern in 1939 at its Harrison, New Jersey facility, utilizing the TK-1 monoscope—a cathode ray tube with an etched metal plate—to generate the image without a camera, featuring a Native American profile encircled by resolution wedges, grayscale bars, and geometric grids for comprehensive equipment checks.^[24] This pattern addressed similar calibration needs as its British counterparts, testing focus, linearity, and contrast in black-and-white transmissions, and became a staple for field trials broadcast from stations like W2XBS in New York.^[25] Development faced significant interruptions from pre-war uncertainties and World War II blackouts, particularly in Europe. The BBC suspended all television broadcasts on September 1, 1939—the day Germany invaded Poland—to repurpose the Alexandra Palace transmitter for jamming enemy signals and avoid aiding potential air raids, halting test card usage until a brief resumption in 1945 and full return in 1946.^[26] In the US, while wartime restrictions limited civilian programming and shifted resources to military applications, limited test transmissions continued for technical refinement, though broader adoption of patterns like the Indian-head occurred post-war as commercial television expanded.^[27] These disruptions underscored the fragility of early television infrastructure amid geopolitical tensions.

Evolution Through Analog Eras

The transition to color broadcasting in the 1950s marked a significant evolution in test card design, particularly in North America, where the NTSC standard was adopted for compatible color transmission. In 1953, the Federal Communications Commission approved the NTSC color standard, enabling the introduction of color test patterns to calibrate receivers while maintaining backward compatibility with black-and-white sets.^[28] Early color bars, developed by engineers Norbert D. Larky and David D. Holmes at RCA Laboratories and patented in 1956 (filed 1951), provided a foundational electronic pattern for aligning hue, saturation, and luminance, first appearing in broadcasts around 1954.^[29] Complementing these, the EIA 1956 Resolution Chart emerged as a key tool for assessing horizontal and vertical resolution in analog video systems, featuring wedge patterns ranging from 200 to 1000 TV lines to evaluate camera and display performance.^[30] By the 1960s and 1970s, global standardization efforts refined test cards for emerging color systems like PAL and SECAM in Europe, emphasizing precision in geometric distortion, color fidelity, and resolution. The Philips PM5544, an electronically generated pattern introduced in 1969 by Philips engineers led by Finn Hendil, became widely adopted across Europe for its comprehensive layout of circles, grids, and color ramps, facilitating transmitter and receiver alignment without physical slides. In the UK, the BBC integrated a modified PM5544 variant from 1971 alongside its iconic Test Card F (introduced 1967), while the Independent Broadcasting Authority used it initially for color setup.^[4] Paralleling this, the EBU colour bars, standardized by the European Broadcasting Union in the early 1970s, offered a simplified vertical bar sequence tailored to PAL/SECAM chrominance, promoting interoperability among international broadcasters and replacing ad-hoc patterns.^[29] Refinements in the 1980s and 1990s addressed aspect ratio changes and signal integrity as broadcasting expanded to widescreen formats and continuous operation. Widescreen adaptations, such as the BBC's Test Card W (a 16:9 version of Test Card F introduced in the late 1990s), incorporated letterboxed elements and updated color bars to test 16:9 transmissions, ensuring compatibility with emerging high-definition precursors.^[4] Concurrently, Vertical Interval Test Signals (VITS), inserted into the non-visible lines of the video signal since the late 1970s but refined in the 1980s, enabled automated monitoring of chrominance phase, luminance nonlinearity, and differential gain during transmission, reducing reliance on full-screen patterns.^[31] The shift to 24/7 programming accelerated the phase-out of visible test cards, as stations like the BBC discontinued routine broadcasts by the mid-1980s in favor of automated diagnostics.^[4] Regional variations highlighted the decline of traditional test cards, particularly in the UK, where the launch of Channel 4 in 1982 introduced the IBA's ETP-1 electronic pattern for initial trade tests but adopted a policy minimizing visible test cards to support innovative, near-continuous scheduling.^[32] This reflected broader trends toward extended hours, with test cards persisting mainly for engineering purposes in some markets until the analog-to-digital switchover, completed in the UK by 2012 but effectively ending routine analog test signals around 2009.^[4]

Key Examples and Variations

Monoscope Patterns

Monoscope patterns refer to test signals generated using monoscope tubes, specialized cathode ray tubes that produce a fixed video image without requiring a traditional camera. These devices, developed in the late 1930s, feature a metal target plate printed or etched with a persistent pattern, such as using ink or light-sensitive materials that exhibit varying secondary emission properties when scanned by an electron beam. The beam sweeps across the target, generating an electrical output current proportional to the pattern's density variations, which is then amplified into a standard television signal for broadcast testing and calibration. This photoemissive process ensures a stable, repeatable image ideal for static test cards.^[16] A prominent example is the "Indian-head" pattern generated using RCA's 2F21 monoscope tube, introduced in 1939. This black-and-white pattern centers on a stylized profile of a Native American wearing a feathered headdress, flanked by geometric elements including radial lines, circular bullseyes for focus adjustment, resolution wedges for sharpness testing, and arrow-like alignment markers to verify geometric distortion and linearity in broadcast displays. Widely adopted in the United States from the 1940s through the 1970s, it served as a benchmark for monochrome television alignment at stations, such as WABD in New York.^[33]^[34] The primary advantages of monoscope-generated patterns lay in their cost-effectiveness and simplicity for producing unchanging test images, as they bypassed the need for dedicated studio cameras, lighting, or film chains, thereby reducing equipment wear and operational expenses during off-air periods. Stations could integrate custom details like call signs into the tube's target plate for personalized use, enhancing practical alignment without additional hardware.^[34]^[16] However, monoscopes had inherent limitations, including gradual signal degradation from target aging—such as ink fading or contamination leading to shading and instability—and their inability to adapt easily to emerging color standards or dynamic testing needs. By the 1980s, these tubes were phased out in favor of electronic signal generators and synthesized patterns, which offered greater versatility; the final commercial uses in the United States occurred in the early part of that decade as analog broadcasting transitioned toward more advanced technologies.^[34]^[16]

Electronic and Color Test Cards

Electronic test cards advanced beyond precursor monoscope patterns by employing electronic signal generation to produce complex, color-inclusive visuals for comprehensive system calibration. These patterns emerged in the mid-20th century as color television standards proliferated, enabling precise evaluation of chroma, luminance, and resolution in broadcast equipment. Unlike static optical slides, electronic designs allowed for standardized, repeatable tests across transmitters and receivers, facilitating international compatibility in analog color systems.^[35] The Philips PM5544, developed in 1968-1969 by Danish engineer Finn Hendil at the Philips TV & Test Equipment laboratory in Amager, Denmark, exemplifies early electronic color test patterns and became one of the most widely used in Europe for PAL systems. It consists of a central circle segmented into radial color bursts arranged in a rainbow sequence to assess chrominance response and phase accuracy, complemented by surrounding linear grayscale steps for luminance linearity and a grid of fine lines for sharpness evaluation. Additional elements, such as crosshatch patterns and frequency ramps, supported checks for geometric distortion and high-frequency response, while the overall design permitted subjective viewing to gauge picture fidelity in color television sets. Adaptations of the PM5544 were employed internationally, including variants for NTSC color signals, where it served as a test display card to calibrate broadcast chains with minor adjustments for local transmission parameters.^[2]^[3]^[36] Another notable example is the BBC's Test Card F, introduced in 1967 as the UK's first regular color test card. It depicted a young girl, Carole Hersee, playing noughts and crosses with a clown doll, accompanied by various calibration elements like color bars, grayscale ramps, and resolution charts. It was broadcast extensively until replaced in the early 1980s.^[4] The SMPTE RP 219 standard, published in 2002 by the Society of Motion Picture and Television Engineers, specifies a versatile color bar signal compatible with both high-definition and standard-definition digital video formats. This pattern features vertical bars representing 100% saturated primaries (red, green, blue), secondaries (yellow, cyan, magenta), neutral gray, and a simulated flesh tone, alongside linear ramps for testing signal clipping, gain, and differential phase. Designed primarily for digital environments, it includes provisions for subcarrier frequencies and pluge pulses to verify setup levels and black level accuracy, making it a cornerstone for professional video equipment alignment.^[35]

Regional and Standard-Specific Patterns

North American Standards

In the United States, the RCA Indian-Head test pattern marked a key milestone in early television standards, introduced in 1939 as a monoscope-based black-and-white calibration tool that remained in use by many stations until the late 1970s.^[37]^[38] This pattern featured a central image of a Native American in headdress surrounded by resolution wedges, grayscale bars, and frequency markers to adjust focus, contrast, and linearity in analog receivers.^[39] The transition to color broadcasting in the 1950s introduced the SMPTE color bars, developed as an electronic test signal to verify chrominance and luminance alignment in NTSC systems, with widespread adoption from the mid-1950s onward.^[29] These vertical bars, consisting of seven color fields at 75% saturation plus a reference white and subcarrier phase indicator, became the de facto standard for equipment setup and signal monitoring in North American studios and transmitters.^[40] With the shift to digital television under ATSC standards in 1995, test patterns evolved to include digital equivalents like extended SMPTE bars, full-field color tests, and modulated signal streams for assessing compression artifacts and error correction in ATSC 1.0 transmissions.^[41] For ATSC 3.0, introduced in 2017 and progressively deployed, regulatory test streams incorporate IP-based test content, bootstrap signals, and layered modulation patterns to evaluate mobile reception, HDR compatibility, and interference resilience during field trials.^[42] In Canada, the Canadian Broadcasting Corporation (CBC) adapted U.S. patterns for its NTSC-based system, employing EIA-standard resolution charts alongside the RCA Indian-Head monoscope in the monochrome era starting from CBC's inaugural broadcasts in 1952.^[43] The Federal Communications Commission (FCC) enforced test signal mandates during the analog era through proof-of-performance rules under 47 CFR Part 73, requiring quarterly or semi-annual transmission of specified patterns—like grayscale ramps and multiburst signals—to verify signal fidelity and compliance with technical standards.^[44] These obligations transitioned to digital with the 2009 analog shutdown, where ATSC 3.0 testing now emphasizes automated streams for spectrum efficiency and next-generation features, as outlined in FCC approvals for voluntary adoption.^[45] Notable implementations included Public Broadcasting Service (PBS) affiliates, which routinely aired SMPTE color bars or EIA resolution patterns overnight from the 1970s to the 1990s, often accompanied by tone signals during sign-off periods to facilitate engineer adjustments and maintain equipment alignment outside prime viewing hours.^[34]

European and International Variants

In Europe, test card designs evolved to support the diverse analog color standards of PAL and SECAM, with the BBC in the United Kingdom playing a pivotal role in developing a sequence of patterns for broadcast calibration and viewer adjustment. The BBC's Test Card A, introduced shortly after World War II for short daytime broadcasts, featured frequency gratings and a central circle to test resolution and linearity. ^[4] This was followed by Test Card B, which added an Ilford panchromatic test strip for contrast assessment, though no physical copies survive. Test Card C, launched in 1947 and used until the end of black-and-white television, initially had a 5:4 aspect ratio before shifting to 4:3 around 1949, incorporating various formats like cards, slides, and monoscopes, with centering arrows added in July 1958. ^[4] Test Card D debuted in 1964 for 405-line systems, featuring graduated frequency gratings and later modifications including added dots in December 1965. Test Card E, introduced the same year for the 625-line BBC2 launch, mirrored D but with finer gratings. The iconic Test Card F, rolled out in 1967 for color transmissions on 625 lines, included a color image of a girl and clown, becoming a staple on BBC1 from November 1969 and adopted by the Independent Broadcasting Authority (IBA) for its transmitters. ^[4] Test Card J, an electronic update to F introduced in 1999 and used until at least 2013, incorporated additional elements like a green square and flashing dots for enhanced digital compatibility. ^[4] ^[46] Continental European broadcasters adapted similar electronic patterns to suit SECAM and PAL systems, emphasizing crosshatch grids and color circles for signal integrity. The Philips PM5634, a specialized generator for SECAM transmissions, produced complex circle-based patterns to evaluate color separation, luminance linearity, and distortion in French and Eastern European networks during the 1970s and 1980s. ^[47] In Germany, public broadcasters ARD and ZDF employed the Telefunken FuBK pattern from the mid-1970s onward as a successor to earlier designs, featuring a central crosshatch with surrounding color bars and frequency wedges to calibrate resolution and geometric accuracy in PAL broadcasts. These patterns aligned with the European Broadcasting Union (EBU) standards, such as the EBU colour bars, which provided a baseline for 625-line PAL systems to ensure consistent color reproduction across member states. ^[48] Internationally, test cards reflected colonial and technical influences from European models, particularly in Commonwealth and developing regions. Australia's Australian Broadcasting Corporation (ABC) adopted a variant of the Philips PM5544 circle pattern in the 1970s following the 1975 color rollout, utilizing crosshatch, color circles, and station identification to facilitate PAL adjustments nationwide. ^[49] ^[50] In India, Doordarshan networks drew from UK designs, adapting BBC-style cards with grayscale ramps, color bars, and frequency gratings for their 1982 color transition under PAL-B/G, incorporating local station logos while maintaining core calibration elements. ^[51] These adaptations supported the expansion of television in post-colonial markets. Global harmonization efforts in the 1980s, led by the International Telecommunication Union (ITU), promoted standardized test signals to aid developing broadcast infrastructures, particularly through CCIR (now ITU-R) recommendations like those in the 1986 Dubrovnik assembly for insertion test signals in 625-line systems. ^[52] ITU-R BT.470 outlined characteristics for conventional analog systems, including SECAM and PAL variants, recommending uniform test patterns to minimize interference and ensure interoperability in international signal exchanges. ^[53] These guidelines facilitated adoption in emerging markets by providing scalable templates for color and monochrome testing without requiring proprietary equipment.

Modern and Alternative Applications

Digital Broadcasting and Computing

In digital television broadcasting, standards such as ATSC, DVB, and ISDB employ test patterns adapted from analog eras but optimized for digital transmission, including full-field color bars to verify signal integrity, color accuracy, and luminance levels across compressed streams.^[54] These patterns, generated electronically, ensure compliance with digital encoding like MPEG-2 or HEVC, helping broadcasters maintain quality during multiplexing and modulation processes.^[55] Post-2010 advancements introduced HDR-specific test patterns, such as calibration grids for high dynamic range systems under ITU-R BT.2100, supporting formats like HDR-PQ and HDR-HLG used in ATSC 3.0, DVB-T2, and ISDB-T.^[54] For instance, BT.2111 defines color bar patterns in narrow and full ranges, with resolutions up to 8K (7680x4320), to align equipment for peak brightness exceeding 1000 nits and precise tone mapping.^[54] These grids facilitate testing of dynamic metadata in HDR10+ and Dolby Vision, ensuring consistent rendering across devices in global broadcasts.^[56] In computing contexts, test cards serve GPU stress testing and monitor calibration, with NVIDIA's control panel providing color bar patterns to adjust dynamic range (e.g., full RGB 0-255) via HDMI outputs, preventing issues like crushed blacks in video playback.^[57] Tools like DisplayCAL enable precise profiling using colorimeters, generating custom patterns for gamma, white point, and uniformity checks on PC displays.^[58] HDMI test signals, often including SMPTE-style bars, are integrated into GPU diagnostics to validate bandwidth and artifact-free rendering at resolutions up to 4K.^[59] Advancements in UHD and 8K broadcasting incorporate dynamic metadata into test patterns, as seen in generators like the Aurora TPG-8K, which outputs HDMI 2.1 signals for AV-over-IP validation and high-resolution geometry alignment.^[60] Streaming services utilize software-generated cards; Netflix's "Test Patterns" stream, available at 4K UHD, includes multipurpose charts for A/V sync, overscan detection, and coarse HDR calibration, downloadable for offline use.^[61] As of 2025, AI-driven auto-calibration integrates with test patterns to minimize manual adjustments, exemplified by Panasonic's W95B and Z95B TVs, which are Calman Ready for automated 3D LUT loading and real-time color tuning via the HCX Pro AI Processor.^[62] This reduces reliance on traditional cards by enabling device-side analysis of patterns for adaptive brightness and tone mapping, enhancing accuracy in smart ecosystems.^[62]

Non-Broadcast Uses Including Numismatics

Test patterns similar to those used in broadcasting have found applications in graphics card diagnostics, where VGA and HDMI outputs display standardized images to verify hardware functionality and signal integrity. These patterns, often including color bars, grayscale ramps, and geometric shapes, help detect issues such as pixel defects, color distortion, or sync problems in monitors and GPUs. For instance, calibration tools generate these visuals to test display connections and resolutions, ensuring proper output from graphics cards.^[63] In multi-monitor configurations, AMD's Eyefinity technology employs specific validation patterns to confirm seamless display spanning and alignment across multiple screens, aiding in hardware troubleshooting for professional setups. In printing and photography, CMYK test charts serve an analogous role to television test cards by providing benchmarks for color accuracy and reproduction fidelity during proofing processes. These charts feature arrays of color swatches, gradients, and registration marks printed in cyan, magenta, yellow, and black inks to calibrate presses and evaluate output against standardized profiles, such as those defined by ISO 12647. Photographers use similar charts, like the X-Rite ColorChecker, to profile cameras and ensure consistent color rendering in digital workflows, mirroring the precision testing of broadcast signals.^[64]^[65] In home theater systems, visual test cards are frequently paired with audio test tones to calibrate both video and sound components holistically. Discs or digital files, such as those from Dolby or streaming services, display patterns like SMPTE color bars alongside pink noise or channel-specific sweeps to balance speaker levels, verify surround sound routing, and align audio-visual synchronization. This integrated approach ensures immersive performance in consumer setups, extending the diagnostic utility of test cards to multimedia environments.^[66]^[61]

Cultural and Media References

Appearances in Popular Culture

Test cards have appeared in several British television productions as symbols of mid-20th-century broadcasting and temporal displacement. In the BBC series Life on Mars (2006–2007), the Test Card Girl, inspired by the central figure in Test Card F, manifests as a haunting, otherworldly entity that interacts with the protagonist Sam Tyler, underscoring themes of psychological torment and time travel. The character, played by Harriet Rogers in season 2, draws directly from the iconic 1967 BBC test card featuring Carole Hersee and her doll Bubbles, blending nostalgia with supernatural elements. Beyond scripted television, test cards have inspired nostalgic digital recreations and online communities, particularly on platforms like YouTube, where enthusiasts compile and remix vintage signals such as the BBC's Test Card F and the RCA Indian-head test pattern. These videos, often looping the patterns with period-appropriate music, have cultivated a cult following since the early 2010s, celebrating the downtime of analog broadcasting as a relic of pre-24-hour TV.^[6] The Indian-head pattern, introduced by RCA in 1939, features prominently in these recreations for its stark black-and-white calibration elements, symbolizing the technical rituals of early U.S. television sign-offs. In contemporary art and music, test card motifs serve as emblems of analog obsolescence and media transition. Additionally, the stage name "Test Card Girl" adopted by British singer-songwriter Catherine Burgis reflects the enduring cultural resonance of test cards. These uses highlight test cards' role in evoking the quiet intervals of pre-digital media, often symbolizing pauses in cultural consumption.

Accompanying Test Card Music

The music broadcast alongside test cards during off-air periods primarily served to verify the audio fidelity of television receivers, allowing technicians and viewers to adjust sound systems while filling transmission gaps with non-intrusive content. Selections were typically drawn from public domain works or licensed production music libraries to minimize costs and avoid copyright issues, often featuring light orchestral or classical arrangements designed to entertain or soothe audiences without overpowering the test signal.^[67] In the United Kingdom, the BBC paired Test Card F—used from 1967 through the 1980s—with curated tapes of classical and light music starting in the mid-1950s, including half-hour compilations of orchestral pieces sourced from international libraries, such as French recordings like "La Foule." These playlists emphasized soothing, instrumental tracks to maintain viewer engagement during extended downtime, with the BBC Radiophonic Workshop occasionally contributing electronic signatures, though conventional orchestral selections dominated.^[67] Other regions adopted similar approaches tailored to local broadcasting norms. In the United States, stations commonly played the national anthem followed by test patterns during sign-off hours from the 1950s to the 1970s, sometimes including easy listening stock music or periodic time signals. Australian Broadcasting Corporation (ABC) transmissions in the 1970s featured ambient orchestral tracks, exemplified by stereo recordings like the Rosetti Symphony in C Major on the Mace label, broadcast during evening test patterns to test both mono and stereo audio capabilities.^[67]^[68] The legacy of test card music endures through dedicated compilations, with vinyl and CD releases emerging in the 2000s via labels like Apollo Sound, such as the "Test Card Music" series volumes 6 and 7, which anthologized rare tracks from BBC and ITV archives. As of 2025, digital remasters of these collections are widely available on streaming platforms like Spotify, ensuring preservation and renewed interest in this niche of broadcast history.^[69]^[70]^[71]

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TCC - A Very Concise History of Test Cards
Television started in the UK in 1936, and it was quickly recognised that a test pattern to assist dealers with the setting up of receivers was necessary.Missing: definition | Show results with:definition
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The BBC test card: inside a cult YouTube obsession | Vox
Aug 28, 2016 · In the world of television broadcasting, a test card is a geometric visual that's used to adjust monitor settings and video equipment. For most ...Missing: definition | Show results with:definition
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TEST CARD | definition in the Cambridge English Dictionary
a picture or pattern that was broadcast in the past so that the quality of the television picture received could be examined and improved if necessary by ...
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The Tuning Signal, Test Card C, and Tracing Faults - Transdiffusion
Apr 17, 2017 · It is designed to give an immediate indication of the performance of the whole transmitting and receiving chain. As the performance of the ...
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Color Bars & Test Patterns - Bitstreams: The Digital Collections Blog
Jun 23, 2016 · The purpose of bars and tone is to serve as a reference or target for the calibration of color and audio levels coming from the videotape during transmission.
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TVFAQ: CRT convergence adjustment - Sci.Electronics.Repair FAQ
Convergence is set using a white crosshatch or dot test pattern. If you do not have a test pattern generator, any static scene (from a camcorder or ...
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FCC Affirms Cancellation of TV Station License for Being Dark for ...
Aug 9, 2010 · The decision characterized the test pattern as an "equipment test" as opposed to a "broadcast signal." Thus, the decision upholds the ...
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[PDF] NTSC Video Measurements - Tektronix
The SMPTE color bars signal shown in Figures 2-5 and 2-6 are 75% bars with a 75% white level. This signal also incorporates a 100% white level on some lines. ...
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[PDF] Understanding Colors and Gamut - Tektronix
Color-coded triangles (yellow for the SMPTE format, blue for. EBU/PAL/SECAM, red for NTSC 1953) in Figure 1 are specified by x, y coordinates in Table 1 ...Missing: arrangement | Show results with:arrangement
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Setting the Brightness Control, 2nd Edition - Spears & Munsil
The classic PLUGE pattern consists of a background that is set at the standard reference black level, with two rectangles on it.
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[PDF] The Mechanics of Television
It consists of a circular flat metal plate, rotating at a constant speed and containing a series of small holes or apertures arranged in one or more spiral.
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BBC Testcard C Telecine Lineup 16mm Film Loop - YouTube
Mar 28, 2015 · A special version of Test Card 'C' for telecine use. This film loop was used to adjust the 16mm telecines at the BBC before transmission.Missing: generation rotating discs
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Direct Digital Synthesis (DDS) Controls Waveforms in Test ...
Direct Digital Synthesis (DDS) produces analog waveforms by generating a digital time-varying signal, then converting it to analog. It is useful in test, ...
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[PDF] Monoscopes & Test Cards by Brian Summers G8GQS
The French tube type. TH.9500 from Thomson Houston had a long thin gun and a cylindrical body. A wide choice of standard patterns were available together with.Missing: photocathode | Show results with:photocathode
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[PDF] XAPP248 "Digital Video Test Pattern Generators" v1.0 (01/02)
Jan 7, 2002 · Summary. This application note describes methods of efficiently generating standard video test patterns in Xilinx FPGAs. Video test patterns ...Missing: card GPUs software
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Video Beginner Series 10: YCbCr Chroma subsampling/resampling
Nov 8, 2021 · Common YCbCr color format using Chroma subsampling are YCbCR422 and YCbCr420. Note that YCbCr without Chroma subsampling can be called YCbCr444.
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Early experiments: 1924-1929 - BBC
In 1924, a young Scottish engineer, John Logie Baird, developed a way of passing a beam of light through a rapidly spinning disc punched with holes.Missing: test patterns
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John Logie Baird demonstrates TV | January 26, 1926 - History.com
Feb 9, 2010 · On January 26, 1926, John Logie Baird, a Scottish inventor, gives the first public demonstration of a true television system in London.Missing: test | Show results with:test
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Sets and signals - BBC
Test Cards were designed to calibrate the fidelity of an image at both the television camera and receiver ends of the transmission process.
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Early Identities
### Summary of BBC Test Cards Origins in the 1930s
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Deciphering the Language of TV Test Patterns - PRINT Magazine
Jan 16, 2019 · These were called “test charts” and included designs that checked transmitter performance from studio to antenna and, of course, the picture ...
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Item of the Week: Indian-Head Test Card | The Sarnoff Collection
Jun 2, 2017 · These test patterns were meant to make sure that a television was properly tuned. A technician could use the test pattern broadcast onto a ...Missing: definition | Show results with:definition
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RCA's Television Field Trials and Stations W2XF/W2XK/W2XBS/WNBT
These early broadcasts consisted of objects like Felix the Cat or early test patterns and photographs. The RCA receiver in our collection was used in these ...Missing: pre- | Show results with:pre-
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Resurrection: 1946 - BBC
... Television Service closed down on 1 September 1939. Broadcasting was resumed for a further two hours at 8.30pm in the evening, featuring Geraldo and his ...
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Television During World War Two
Television transmission was suspended on the day that war was declared against Germany. The Alexandra Palace transmitter was retuned and used to jam German ...
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FEDERAL COMMUNICATIONS COMMISSION - World Radio History
NATIONAL BROADCASTING COMPANY, INC. FOR APPROVAL OF COLOR STANDARDS FOR. THE RCA COLOR TELEVISION SYSTEM. June 25, 1953.
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The History of TV Color Bars, One of the First Electronic Graphics ...
Jul 20, 2020 · What Larky and Holmes created in the early 1950s was the one of the most iconic test patterns the world has ever seen.Missing: introduction | Show results with:introduction
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[PDF] EIA1956.pdf - Beale Corner
EIA RESOLUTION +. CHART 1956. 200. 300. 400. 500. 600. -150.
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Philips circle pattern - Wikipedia
The Philips circle pattern refers to a family of related electronically generated complex television station colour test cards. The content and layout of ...Operation · Pattern variations · Physical equipment · Pattern variation gallery
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Television test patterns - CSMonitor.com
Feb 10, 2000 · If you could "roll" your TV picture, you'd see the thin Vertical Interval Test Signal, or VITS. It is how stations monitor such things as ...
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Channel 4 test card (1982) - Rewind - The TV Room
Jun 10, 2025 · It lacks the horizonal lines above and below the “IBA:CH4” text. This indicates that the source of the test card was one of the IBA Regional ...
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DuMont's "Phasmajector" monoscope tube from 1938
The aluminium signal plate with the printed image can clearly be seen. A more common image would be the American Indian Head test pattern. Photo credit; ...
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A Pattern for Testing | TV Tech - TVTechnology
Sep 16, 2010 · The Indian Head test pattern soon became a television icon and was literally moved inside RCA's monoscope camera tube. (For those not familiar ...
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Recommended Practice Index | Society of Motion Picture ... - SMPTE
A Recommended Practice is a document that states basic specifications, dimensions, or criteria that are not necessary for effective interchange and/or ...<|control11|><|separator|>
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Field Order - Who's on First? by Chris and Trish Meyer
Jan 30, 1998 · To output a field-rendered animation in After Effects, select the correct field order from the Field Render popup in the Render Settings dialog.Missing: dots | Show results with:dots
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The Indian Head Test Pattern Story! , Updated April 29, 2017
Jul 1, 2021 · The FIRST original Master copy of the Indian Head Test Pattern, hand drawn in 1939! And now, here is the story on how I got this rare ...Missing: introduction | Show results with:introduction<|separator|>
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Indian Head Test Pattern - Media College
This is the famous American black and white test pattern known as the "Indian Head". It was introduced by RCA in 1939 and became a popular icon in the 1940s.
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Broadcast Essay: TV Cigar-Store Indians: Test Patterns, Ads, and ...
Apr 17, 2023 · TV used the Indian Head test pattern, treating Native Americans as "electronic cigar-store Indians" and using non-Indigenous actors, like Iron ...Missing: DuMont | Show results with:DuMont
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Hank Mahler, Developer of the SMPTE Color Bars, Passes Away
Oct 13, 2021 · SMPTE Color Bars and was recognized by the National Academy of Television Arts and Sciences in 2002 for standardizing and building the first ...Missing: introduction | Show results with:introduction
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[PDF] ATSC 3.0 PHY Lab Performance Test Plan
Mar 31, 2022 · 2) Use ATSC 3.0 Modulator with 6 MHz bandwidth and parameters as indicated in Table 5.2 through Table 5.4 with scattered pilot patterns ...
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[PDF] ATSC Recommended Practice: ATSC 3.0 Field Test Plan
This document presents the objectives of, and general methodology for, conducting field tests of the ATSC 3.0 over-the-air (OTA) terrestrial digital television ...
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CBLT-DT - The History of Canadian Broadcasting
... Canadian Broadcasting Corporation launched CBFT-TV in Montreal. That station broadcast in English and French. The CBC would open Toronto's first station two ...
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CBC January 6, 2006 Test Card - YouTube
Sep 6, 2012 · Here's the test card used by the CBC until the Fall of 2006. This recording ... CBC sign-off, O Canada and Test Pattern from 1999 (OTTAWA).Missing: EIA | Show results with:EIA
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[PDF] Federal Communications Commission FCC 17-120
Sep 25, 2017 · Operators will still test for digital signal quality at every new installation. And operators will still be required to show compliance with the ...
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[PDF] October 7, 2025 FCC FACT SHEET∗ Authorizing Permissive Use of ...
Oct 7, 2025 · Background: Next Gen TV (which uses the “ATSC 3.0” or “3.0” standard) is the future of broadcast television. ATSC 3.0 promises to revitalize ...
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We must never forget the great john baker .as well as delia .he was ...
Nov 21, 2021 · Do remember that "Delia Derbyshire Day" is a charity, set up ... music from Ceefax/ Testcard and someone pointed me in this direction.
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Specs for obscure Philips patterns found in partial scan of PM5644 ...
Jul 1, 2024 · The specs for the SECAM test card were also recently seen for the first time with the PM5534 manual scan provided by Stan Stanger! Here's ...Missing: PM5634 | Show results with:PM5634
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Telefunken FuBK - Wikipedia
The Telefunken FuBK is an electronic analogue television test card developed by AEG-Telefunken and Bosch Fernseh in West Germany as the successor to the ...
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[PDF] TECH 3335
Although this is a photographic test card, it can also be used for testing television cameras. It comprises an array of 24 patches in four rows of six with ...
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ABC Test Pattern (Australian station ID) 1975 - YouTube
Aug 9, 2010 · ABC (Australian Broadcasting Corporation) station ID and test pattern from 1975 transferred from Philips VCR SP tape.
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TV 50 years in colour - Television.AU
Mar 1, 2025 · Some TV executives were making bold predictions that Australian TV would be in colour by January 1970. Even ABC was weighing into the debate. “ ...
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Doordarshan DD1 India Test Card (1992) - YouTube
Jul 10, 2024 · Doordarshan DD1 India Test Card (1992). 168 views · 1 year ago ...more. Msaad Al Yousif. 186. Subscribe. 0. Share. Save. Report ...
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[PDF] Recommendations and Reports of the CCIR (Dubrovnik, 1986)
UNANIMOUSLY RECOMMENDS. 1. that for the international transmission of television signals, insertion test signals in accordance with. Annex I (625-line systems) ...<|separator|>
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[PDF] BT.470-5 - Conventional television systems - ITU
NOTE 1 – Pre-1986 editions of the ex-CCIR Volumes, and in particular that of 1982, contain a complete description of system E used in France until 1984, and ...Missing: 1980s | Show results with:1980s
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None
### Summary of Colour Bar Test Pattern Specification for HDR Television Systems
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MPEG Test System - Tektronix
The MPEG Test System offers compliance testing, real-time monitoring, stream playout/recording, and detailed analysis for MPEG, DVB, ATSC, and ISDB standards.
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HDR10 UltraHD Test Patterns - Diversified Video Solutions
A comprehensive set of reference 4K UltraHD test patterns that encompass all of today's latest HDR standards. HDR10, HDR10+, HLG-HDR, and Dolby Vision.Missing: TV ATSC DVB ISDB 2010
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GeForce Garage: How To Calibrate Your Monitor
Apr 8, 2015 · Go through your monitor's menus, Windows' options, and the NVIDIA Control Panel, jotting down old settings and any changes you've made in the past.
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DisplayCAL—Display Calibration and Characterization powered by ...
DisplayCAL (formerly known as dispcalGUI) is a display calibration and profiling solution with a focus on accuracy and versatility.General Discussion · Colorimeter Corrections · What's new in this versionMissing: NVIDIA HDMI
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Correcting HDMI Colour on Nvidia and AMD GPUs - PC Monitors
Oct 11, 2022 · This article provides guidance for users with discrete desktop GPUs from Nvidia and AMD for correcting colour signal issues that can occur via both HDMI and ...
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TPG-8K - Aurora Multimedia
The TPG-8K is the first test 8K test pattern generator with analyzer to focus on AV over IP in addition to HDMI.
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Watch Test Patterns | Netflix
Multipurpose chart includes test patterns for identification of A/V sync offset, coarse monitor calibration, surround sound channel identification.Missing: dynamic metadata software- generated
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Portrait Displays and Panasonic Introduce First Calman Ready TV ...
Jan 8, 2025 · Panasonic's newly announced 2025 flagship TVs—the W95B Mini LED TV and Z95B OLED TV—are Calman Ready for fully automated color calibration.Missing: monitors | Show results with:monitors
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VGA Test Patterns - PHILSCOMPUTERLAB.COM
I use these test patterns to calibrate LCD monitors connected to VGA. The images are in these sizes: 640x480; 800x600; 1024x768; 1280x1024; 1600x1200 ...
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CMYK Color Charts and Values - Mixam
Some colors are more challenging to reproduce than others. The charts below contain a series of CMYK colors considered reliable for offset printing.
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Free CMYK test print forms
Free CMYK test forms include a 100x70cm form (cropable to 70x50cm or 50x35cm), SRA3 45x34cm forms, and a 24x24cm form for small format presses.
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Proof Strike Flying Eagle Cent (1856-1858) Value Guide
Designed by: James Barton Longacre. Issue Dates: 1856 (pattern issue) - 1858. Composition: 88% copper, 12% nickel. Diameter: 19 mm. Weight: 4.66 grams (72 ...
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https://open.spotify.com/album/6oJwNhfsMV3IACW0fJqHln
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Test Screen Glitch royalty-free images - Shutterstock
Find 4+ Thousand Test Screen Glitch stock images in HD and millions of other royalty-free stock photos, 3D objects, illustrations and vectors in the ...
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An Artist Born From the Pandemic | Test Card Girl - Sound of Life
Jul 26, 2022 · Test Card Girl's music draws inspiration from various genres, from lo-fi bedroom music to traditional folk to '80s pop.
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[PDF] A History of Test Card Music
Up until the mid eighties when 24-hour television took over, there was always the good old test card to fill in the gaps between programmes and the music that.
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ABC TV AUSTRALIA TEST PATTERN & MUSIC (1979) - YouTube
Feb 19, 2023 · ex domestic off air EIAJ open reel (pal) color recording. Get the perfect footage for your project with Australian Television Archive's ...
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https://www.discogs.com/release/6441473-Various-Test-Card-Music-6
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https://www.discogs.com/release/6443797-Various-Test-Card-Music-7
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Test Card Music, Vol. 6 - Compilation by Various Artists | Spotify
Test Card Music, Vol. 6. Various Artists. 199922 songs, 57 min 30 sec. Well, All Right · Ben Cooper & His Band · Lovely Lips · Jack Wolfe & His Music.