Fact-checked by Grok 2 weeks ago

Philips circle pattern

The Philips circle pattern is a family of electronically generated test cards designed for calibrating and aligning analog equipment, featuring a central circle for checks surrounded by color bars, grayscale steps, grids, and sinusoidal lines to evaluate , , , and signal integrity. Developed in the late 1960s by Danish engineer Finn Hendil at ' TV laboratory in , the pattern was first produced via the PM5544 generator, which uses TTL circuitry to output Y, R-Y, and B-Y signals for PAL systems, with variants adapted for , , and other standards. Introduced around 1970 as a successor to simpler patterns like the PM5540, the Philips circle pattern addressed the growing needs of color by providing comprehensive tests for deflection , , up to 4.8 MHz, and subcarrier locking at 4.43 MHz, enabling broadcasters and manufacturers to detect issues such as misalignment or delay inequalities through visual analysis on monitors. The pattern's layout includes a 4:3 raster with 252 vertical resolution lines, a multi-step for adjustment, and dynamic elements like moiré patterns to verify demodulator performance, making it a standard tool in TV studios, transmitters, and factories worldwide. Its electronic generation marked a shift from photographic slides to stable, repeatable signals, improving accuracy in professional settings. Widely adopted by broadcasters, the pattern influenced regional adaptations, such as the BBC's Test Card G in the UK from 1971 to the late and the Swiss SRG test card introduced in 1972, which incorporated similar grids and scales for local signal identification. Later evolutions, including the PM5644 generator from the , added features like digital ROM storage for custom text and clock overlays while maintaining the core circle design across PAL, , and variants. With the transition to , the pattern's use declined but remains iconic in analog TV history, often recreated in software for archival and educational purposes.

History and Development

Origins and Design

The circle pattern was designed by Danish engineer Finn Hendil at the TV & Test Equipment laboratory in , near , , during 1966–1967. This development occurred within ' broader efforts to advance television testing equipment amid the rapid expansion of color broadcasting in Europe. Hendil, who had a background in at including work on systems, led the project under the supervision of Erik Helmer Nielsen. The pattern's core engineering goals centered on electronic generation of test signals to evaluate key aspects of analog television systems, including color encoding accuracy, geometric alignment, and overall signal integrity. It served as an advanced alternative to earlier static test cards, enabling more precise calibration without physical slides or manual adjustments. Central to its design were circular elements, which facilitated detection of distortions, pincushion effects, and linearity issues in cathode-ray tube displays by revealing any non-uniform curvature or elongation. Complementary color bars allowed technicians to adjust chroma and luma balance, ensuring faithful reproduction of hue, saturation, and brightness across PAL, NTSC, and SECAM standards that were emerging in the mid-1960s. Fine line patterns, meanwhile, tested horizontal and vertical resolution, highlighting interlace artifacts or sharpness limitations in the broadcast chain. This design emerged in the historical context of Europe's transition to , where PAL was adopted by most Western European countries starting in 1967, following initial trials and alongside France's system. , as a leading European electronics firm, aimed to standardize testing for these incompatible yet proliferating formats, with the circle pattern's name reflecting its prominent concentric motifs that anchored the composition. Prototypes were reportedly tested internally by late 1967, building on ' prior generators like the PM5540.

Introduction and Early Adoption

The Philips circle pattern emerged as a key tool for color television calibration with the development of the PM5544 colour pattern generator by a team led by engineer Finn Hendil at Philips in 1968–1969. The PM5544, introduced in 1970 as documented in Philips' Electronic Measuring and Microwave Notes, marked the first commercially viable electronic generator for complex color test patterns, building on prior monochrome designs like the PM5540 and incorporating integrated digital techniques for precise signal output. It enabled broadcasters to produce the pattern featuring concentric circles and multibursts for geometry, resolution, and color accuracy checks. The pattern saw initial commercial installations in European PAL networks by 1970. Early adoption by public broadcasters transitioning to color included the , where the conducted trials in 1971 and implemented a modified version known as Test Card G for . Early adoption presented challenges, including compatibility with existing setups, where color elements were not fully visible, and the need for engineer training to interpret the pattern's diagnostic features for optimal calibration. The 's 1971 trials highlighted these issues, as operators learned to use the pattern for aligning decoders and monitors during the shift to color broadcasting. The PM5544 required standard mounting and integration into studio or transmitter environments.

Technical Operation

Signal Generation Process

The PM-series pattern generators, such as the PM5544, employ a hybrid approach combining digital timing circuits and analog linear processing to produce the circle pattern signals. The core process begins with input signals, including horizontal and vertical sync pulses, which drive digital dividers and gates to define the overall picture structure and timing. A 15 MHz master clock oscillator provides precise horizontal timing, while a 630 kHz oscillator handles vertical , ensuring compatibility with standards like PAL (625 lines) or (525 lines). These circuits generate gate signals that delineate active picture areas, including the circular boundary and internal elements, before passing them to linear amplifiers for and rise-time control. The (Y) and (R-Y, B-Y) components are derived separately to facilitate accurate color reproduction and testing. Digital gates first produce red (R), green (G), and blue (B) signals at specified contrasts (e.g., 75% for most , 100% for color bars), which are then matrixed into Y, R-Y, and B-Y using linear amplifiers. This separation allows independent adjustment and insertion of test , such as sinusoidal definition lines at frequencies of 0.8, 1.8, 2.8, 3.8, and 4.8 MHz within the circle for assessment. Color bar transitions are achieved through step changes in the components, with symmetry ensured by a one-shot introducing a precise delay of t = 0.4 \, CR (where CR is the color bar ) to avoid artifacts in block edges. The circle boundary itself is generated digitally rather than via continuous analog oscillators, using a dedicated circle generator module with X and Y coordinate registers approximating a precise circle across a 252-line vertical by 256-pixel grid, implemented via lookup for efficiency. This digital method mitigates analog drift but requires careful synchronization to prevent ellipticity anomalies indicating timing errors. Ramps for linear elements like bars and steps are created in the linear section by integrating gate pulses into smooth voltage transitions with defined slopes, typically at 75% contrast for bars. of the color subcarrier is incorporated during encoding, with the generator deriving line and field drive pulses internally from external sync inputs for compatibility in broadcast insertion. Interlacing artifacts are addressed through field-specific sequencing, where horizontal lines reverse scanning order between even and odd to verify proper de-interlacing in receivers; for PAL, this spans eight due to color burst phase cycling. Field blanking is adjustable (18-25 lines) to match regional standards, ensuring the pattern aligns with active video without overflow. Overall, these processes enable continuous, stable signal output for alignment and fault detection, with anomalies like distorted circles or signaling issues in luminance-chrominance delay or oscillator stability.

Core Pattern Elements

The Philips circle pattern features a central as its primary geometric element, designed to evaluate , , and scanning in television systems. This spans approximately 83% of the active vertical picture height, constructed from 252 horizontal scan lines for precise vertical resolution and a horizontal resolution of 256 pixels, achieving an accuracy with less than 1% error. Surrounding the are radial lines that extend inward, serving to test focus and resolution uniformity across the . These components allow engineers to identify issues such as or barrel by observing any irregularities in the 's shape or the lines' alignment. Adjacent to the central circle, the pattern incorporates six vertical color bars—, , , , , and —to assess performance, including , accuracy, and color separation. Each bar represents specific chromaticities defined at 100% and 75% , with values aligned to the BT.470 standard for conventional analogue television systems. These bars enable precise of vectorscopes and confirmation of color matrixing in broadcast chains. Complementing the bars are multi-burst signals, consisting of modulated sine waves at frequencies like 0.8 MHz, 1.8 MHz, 2.8 MHz, 3.8 MHz, and 4.8 MHz, which test the system's and limitations. Further enhancing diagnostic capabilities, a crosshatch overlays the with 14 horizontal and 19 vertical lines, each approximately 230 ns wide (±10% tolerance), to detect geometric distortions and static errors in the display. ramps, featuring six steps at 20% intervals (expandable to ten), evaluate , contrast range, and differential gain/. Identification lettering, such as " PM5544," is embedded within the for source attribution and . All core elements are proportionally scaled to the active video area, ensuring with broadcast line counts like 525 or 625 lines, and are generated electronically by combining and signals for comprehensive testing.

Pattern Variations

4:3 Standard Versions

The in its original was primarily designed for the system, employing a 625-line and a 50 Hz field rate to align with broadcast standards. The base pattern, produced by the PM5544 generator, incorporates a digitally derived central circle with a of approximately 83% of the active vertical and an error margin under 1%, serving as a key element for and testing. Accompanying features include a color bar scale with standard hues (, , , , , ) at 100% and 75% gain, a with six modifiable levels (expandable to ten), and definition lines consisting of sine waves at 0.8, 1.8, 2.8, 3.8, and 4.8 MHz, alongside a 250 kHz square wave for contrast assessment. The PAL subcarrier frequency of 4.43 MHz intentionally introduces a moiré effect in the 3.8 MHz and 4.8 MHz definition lines to evaluate decoder performance. For systems, the PM5544 offered a and 60 Hz field rate adaptation, tailored to North American and some Asian broadcasts, with the subcarrier frequency set at 3.58 MHz to align with the standard. The pattern's fine details, such as the vertical and horizontal gratings, facilitated testing for dot crawl artifacts in signals, where improper chrominance-luminance separation could manifest as crawling dots along color edges; this was mitigated through built-in comb filtering assessments via the alternating color bars and high-frequency lines. Hybrid implementations included tweaks for PAL-M (used in ) and PAL-N systems, adjusting line counts to 525 while retaining PAL-like color encoding, allowing and bar elements to evaluate errors and hybrid performance in regions like . In the 1970s, the integrated elements of the PM5544 into Test Card G, adapting the 4:3 layout for PAL-I transmission with modified color bars and gratings to suit standards, while retaining the core for linearity checks and adding a girl-and-clown image for subjective quality assessment. This hybrid approach extended the pattern's use in British broadcasting until the early 1980s, emphasizing its versatility across standard definitions.

Widescreen and High-Definition Variants

The variant of the Philips circle pattern, introduced in 1991, adapted the traditional design for 16:9 aspect ratios prevalent in emerging television standards. This version featured a horizontally stretched circle and accompanying bars to test anamorphic encoding and decoding, ensuring that the pattern appeared geometrically correct on displays after proper . The PM5644 pattern generator supported generation of these 16:9 patterns for both PAL and systems, enabling broadcasters to evaluate , , and in anamorphic video workflows. High-definition implementations of the Philips circle pattern emerged in the to address the demands of and resolutions, incorporating enhanced elements for modern . These HD variants, generated via modules like the PT8633 integrated with the PT5300 sync and test , supported 16:9 aspect ratios with progressive and interlaced formats at frame rates including 50i, 60i, 50p, and 60p. The patterns included safe action and safe title area markers to verify and letterboxing compatibility, along with multiburst signals in Y, Cr, and Cb components to assess up to the full HD bandwidth of approximately 30 MHz. adjustments, such as the standard 1.422 for anamorphic video, were accounted for in the pattern layout to maintain circular on square-pixel displays. By the mid-2000s, the PM5644 evolved into HD-capable models compatible with digital interfaces, providing comprehensive diagnostics for , , and in 1080-line systems. These variants prioritized 1:1 pixel adaptations for square-pixel video applications, such as calibration, ensuring precise rendering without aspect distortion.

Regional and Specialized Adaptations

The , developed in in the 1970s for 625-line PAL engineering evaluations, utilized PM5644 generators (such as the PM5644G/50 for PAL B/G) to produce its complex elements, including color bars, gratings, and PAL decoder checks, adapting the core Philips signal generation principles for rigorous technical assessments. A specialized 4:3 variant resembling the classic was embedded in the of certain PM5644 PAL generators, discovered in 2022 and intended for cultural or compatibility testing in regions transitioning from legacy monochrome standards. In , the Philips circle pattern was adapted for the PAL-N standard in the 1970s, featuring adjustments for the 625-line/50-field within a 6 MHz channel to support early color transmissions by broadcasters like América TV. Custom inserts for Middle Eastern broadcasters, such as those used by , integrated regional logos and text into the Philips circle framework, replacing elements like the Indian-head motif to align with local cultural preferences while maintaining core test functionalities.

Generation Equipment

Analog Models

The Philips PM5544 color pattern generator, introduced around 1970, employed a with analog circuits to produce Y, R-Y, and B-Y component signals for television test s. It accepted inputs including composite sync and blanking signals (2-8 Vpp, negative ) and external identification signals (0.5-2 Vpp), while providing outputs such as Y, R-Y, and B-Y (0.7 Vpp into 75 Ω) and RGB (0.7 Vpp into 75 Ω), supporting both component and formats via linear matrix amplifiers. Common operational faults involved oscillator drift, which was addressed through stabilization mechanisms but often necessitated a warm-up period of up to 30 minutes for precise timing and pattern stability. Housed in a standard 19-inch rack-mount enclosure measuring 435 mm wide by 132 mm high by 444 mm deep, the unit operated on 115/230 V AC at 50-60 Hz, drawing 45 W of power. Calibration procedures outlined in technical publications included adjustments for field blanking (18-25 lines) to ensure accurate vertical positioning of pattern elements like the central circle and convergence crosses. The PM5534, introduced in the late , featured a compact with functionality similar to the PM5544 for generating the base circle pattern in practical deployments. Analog models were gradually replaced by alternatives in the late 1980s and 1990s. These devices generated core pattern elements, such as the circular geometry and color bars, using a combination of memory for stability and analog amplification for signal output.

Digital and Successor Models

The evolution toward generation for the Philips circle pattern began in the early 1990s with hybrid designs, progressing to fully systems in the for improved precision and compatibility with broadcast workflows. The PM5644, released in 1991, marked an evolution in pattern generation with EPROM-based storage for complex patterns, including sub-models supporting the Indian-head test card and the FuBK pattern for German broadcast standards; while primarily analog, it offered switchable 4:3 aspect ratios and laid groundwork for enhancements. An HD variant of the PM5644 was developed for high-definition systems. The PT series, developed under ProTeleVision (PTV) and later DK-Technologies in the , introduced fully rack-mount units designed for broadcast environments, featuring SDI outputs for seamless integration into workflows. Models such as the PT5210 and PT5230 provided modular sync and test signal , with FPGA-based processing for accurate timing and pattern rendering, supporting both 4:3 and 16:9 aspect ratios for the Philips circle pattern. The PT5300, a high-end 1U unit weighing 6 kg, extended these capabilities with up to 8 HD-SDI outputs at 1.485 Gbit/s for formats including , , and up to 60 Hz, alongside SD-SDI at 270 Mbit/s and for HD compatibility, while including the Philips circle pattern and FuBK variants in both 525- and 625-line standards. Custom configurations of these models were tailored for specific broadcasters, such as RGB component outputs or specialized test cards like the TDC pattern for Danish networks, allowing integration with modern video switchers and systems for precise signal locking. Production of the PT series continued through the , with the PT5300 serving as the final official hardware model before discontinuation as a legacy product around 2018. In 2022, DK-Technologies open-sourced the designs, schematics, and for the PT5210, PT5230, and PT5300 series, enabling community-driven software emulations and recreations to preserve the technology for archival and purposes. This release has facilitated FPGA reimplementations on modern platforms. As of 2025, community projects continue to develop software emulations and FPGA-based recreations using the open-sourced designs, ensuring the Philips circle pattern remains accessible in digital environments without proprietary .

Third-Party and Custom Implementations

Several broadcasters developed custom modifications to Philips pattern generators to adapt the circle pattern for their specific technical and operational requirements during the analog era. The , for example, modified the PM5544 generator starting in 1971 to produce Test Card G, a variant used in conjunction with until the late 1990s for testing and calibration. These adaptations allowed integration with BBC's transmission standards, including adjustments for PAL signal handling and on-screen elements like captions. Similarly, the Independent Broadcasting Authority (IBA) in the UK initially employed a modified version of the PM5544 for its test transmissions, particularly during the early rollout of color in the 1970s. This customization ensured compatibility with the IBA's engineering specifications for independent television networks. In non-European markets, such as , national broadcasters adopted the pattern through localized hardware adaptations, often using OEM versions of Philips equipment integrated into regional broadcast chains. These implementations highlighted the pattern's versatility in diverse technical ecosystems, including compatibility with early standards converters from the 1980s to 2000s. During the transition to in the and , software-based recreations of the Philips circle pattern appeared in early digital production suites, enabling pattern generation without dedicated analog hardware. Archival footage from broadcasts, such as those preserved by and Asian broadcasters, demonstrates these custom adaptations in action, often combined with analog elements for testing.

Global Usage and Legacy

Broadcasting Applications by Region

The Philips circle pattern, generated primarily by the PM5544 equipment, found extensive application in PAL broadcast regions worldwide during the era, serving as a standard test signal for transmitter calibration, off-peak transmissions, and sign-off sequences from the through the 2000s. In , the pattern was adopted for its comprehensive testing of color separation, geometric distortion, and signal integrity under CCIR standards. The incorporated elements of the Philips circle pattern into Test Card G starting in 1971, using it alongside for engineering checks and until the early , when it was phased out in favor of updated patterns like ETP1. In , ARD affiliates such as employed a slightly modified version of the PM5544 pattern for routine broadcasts, including test cards transmitted during low-viewership hours in the and to verify and color signal paths. These European uses emphasized the pattern's utility in maintaining broadcast quality across national networks. In Africa, South Africa's South African Broadcasting Corporation (SABC) integrated the PM5544 pattern from the outset of its television service, beginning with test transmissions in 1974 on from , featuring customized text overlays like "SABC/SAUK" and "toets - testing" ahead of the full network launch in 1976. The pattern remained in use through the 1980s and 1990s for off-peak sign-offs and equipment alignment, supporting the transition to color PAL broadcasting. In and the Middle East, Singapore's Radio Television Singapore (RTS, predecessor to ) adopted the PM5544 pattern in the mid-1970s for color TV rollout, transmitting it during startup and closedown periods to calibrate national signals. Oceania saw widespread implementation in , where the Australian Broadcasting Corporation () employed the PM5544 pattern extensively from 1975 onward, coinciding with the national color TV introduction; it appeared in station IDs, test transmissions, and nightly sign-offs on channels like ABC Channel 2, aiding in signal verification across vast coverage areas through the 1980s and into the 2000s digital transition holdovers. regions showed more limited but notable adoption, particularly during transitions to PAL in . France's ORTF used similar circle-based patterns influenced by the design in the 1970s, but direct PM5544 adoption was rare due to preferences, with brief appearances during international signal tests. NTSC zones exhibited hybrid and experimental uses, reflecting the pattern's adaptability despite its PAL origins. In , Canadian broadcasters conducted limited tests with variants of the PM5544 in the 1970s and , particularly by for cross-border compatibility checks, though it was not a standard sign-off pattern. saw minimal implementation, confined to equipment calibration in studios during the analog era. In Asia, Taiwan's China Television Company (CTS) adopted an variant of the Philips circle pattern in the for broadcasts, featuring it in startup sequences until the early . Post-analog shutdowns in the led to digital recreations in some regions, but active broadcast use waned by the early .

Decline and Modern Recreations

The Philips circle pattern gradually declined in use during the 2000s and 2010s as broadcasters worldwide transitioned to digital standards like and ATSC, which reduced the need for analog-specific test signals to diagnose transmission distortions. The pattern's reliance on analog equipment became obsolete in most developed regions by the mid-2010s, with the PT5300—the final descendant in Philips's line of pattern generators—representing the end of commercial production before its designs were made available for revival. In analog holdout areas, such as parts of where terrestrial persisted longer, variations of the pattern saw limited continued application into the late , though specific instances are scarce due to incomplete documentation of test signal usage. South Africa's ongoing analog migrations, delayed until at least 31 March 2025, highlight how such patterns lingered in regions slow to adopt digital infrastructure. The pattern also influenced EBU and CCIR standards for test signals in the 1970s-1980s, promoting uniform practices globally. Modern recreations have emerged through hobbyist and open-source efforts, preserving the pattern's utility for education, calibration, and nostalgia. Software implementations include vector-based SVG reproductions on , which accurately replicate the PM5544's complex elements for digital display and analysis. Hardware recreations have proliferated on maker platforms; for instance, a 2024 Hackaday.io project aims to construct a functional Philips circle pattern generator by modifying replicas of models like the PM5544 and PT5300 using modern components. Similarly, a 2023 Hackaday article details FPGA-based recreations of analog test patterns, emphasizing hardware generation to mimic the original's precision over software approximations. The pattern features prominently in online nostalgia media, including YouTube demonstrations and retro TV stream simulations that evoke pre-digital broadcasting eras. Videos from 2016, such as a full-hour HD rendition of the PM5644 pattern, through 2023 clips showcasing PT5300 outputs, serve both technical demos and cultural tributes. These recreations often appear in simulated vintage broadcasts, like 2024 projects replicating 1980s over-the-air TV with test cards for authentic retro viewing. As of 2025, the pattern is used in educational contexts, such as simulations of analog TV history.

References

  1. [1]
    [PDF] Electronic Measuring and Microwave Notes - PM5544 - PM3400
    Further features of the PM 3400 are: rise time 200 ps; bandwidth 1700 MHz at 1 mV/cm; large display (8 x 10 cm screen); dual trace;. 60 dB isolation between ...
  2. [2]
    a socially-minded company | Philips Museum - Philips
    Testbeeld kleurentelevisie van Philips, ontwerp van Finn Hendil 1966. Philipsdorp in 1918. Education was another important focus in Philips' social policy. In ...
  3. [3]
    Television test card – distant memory of the nightly broadcast ...
    Jul 30, 2021 · Philips PM5544 colour test card, developed in the late 1960s. This test pattern presumably served as the model for the Swiss test card.
  4. [4]
    A quick look at some pattern generators (PM5631/PM5644)
    Nov 1, 2022 · All are programmed with the Philips 4:3 colour circle pattern like the below: The Philips circle pattern tests a very long list of scenarios ...
  5. [5]
    The Best TV Test Cards and Patterns of the 20th Century
    Jan 30, 2024 · Danish engineer Finn Hendil originally designed the Phillips circle pattern in something called the “Philips TV & Test Equipment laboratory” in ...
  6. [6]
    [PDF] French and German Color TV Devices in the 1960s
    The majority of West European nations chose PAL, following the example of the British (who had even tested NTSC) in spite of the campaigns by American firms and ...
  7. [7]
    First-Hand:Philips Telephone Exchanges and Denmark, 1960-1970
    Jan 13, 2015 · The AP Navigator was a brain child of one of the mobile telephony developers, Finn Hendil, who was an avid sailor. The Decca company had ...
  8. [8]
    Early Color Television
    Most of Europe adopted the PAL system, which produced better pictures than the NTSC system. France, however, adopted the SECAM system in 1967. Here is a chart ...<|control11|><|separator|>
  9. [9]
    Test Pattern History: How Color Bars Became a TV Staple - Tedium
    Jan 19, 2025 · The history of color bars, the most common television test pattern out there, and what they actually do. (Also, Netflix has some weird test programming.)
  10. [10]
    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
  11. [11]
    The history of the BBC trade test transmission (part 2/4) - Rewind
    May 24, 2020 · The other electronically generated test card In 1971, the BBC introduced a modified version of the Philips PM5544 test card. This was the ...
  12. [12]
    TCC - A Very Concise History of Test Cards
    The original version of Test Card "C" transmitted in January 1948 had an aspect ratio of 5:4, and the circle appeared smaller than in the more familiar version.
  13. [13]
    [PDF] TV Measuring Equipment - Frank's electron Tube Data sheets
    Any of the various Philips test signals can be distributed: shown here the digitally- derived circular pattern from the generator. PM 5544. Two IF modulators PM ...
  14. [14]
    [PDF] Sync generator, PT 5300 - TEquipment
    “Philips” Circle Pattern in 625 line,. 4:3 format. • A high-end Test Pattern Generator contains a very wide range of test- signals, like the “Philips” Circle.
  15. [15]
    [PDF] PT5300 - DK-Technologies
    The generator also contains the complex “Philips” Circle Pattern in both 525 and 625 lines, in 4:3 and 16:9 aspect ratios. Each generator has two parallel ...
  16. [16]
    GB/T 2097-2012 English PDF
    Oct 19, 2025 · ICS33.160 M60 National Standards of People's Republic of China Replacing GB 2097-1997 Analog color television test pattern Issued on. 2012 ...
  17. [17]
    https://hansens.dk/pages/publications/spg/PT5300/pt5300.pdf
  18. [18]
    [PDF] Wireless-World-1992-09.pdf
    Sep 24, 1992 · PHILIPS PM5134 function generator I mHz-20MHz. PHILIPS PM5534 standard pattern generator NTSC. PHILIPS PM5545 colour encoder PAL. PHILIPS ...
  19. [19]
    Philips circle pattern - Wikiwand
    The Philips circle pattern refers to a family of related electronically generated complex television station colour test cards. The content and layout of ...
  20. [20]
    https://www.itu.int/en/ITU-D/Spectrum-Broadcasting/Documents/Publications/GuidelinesAnalogueDB_2014_E.pdf
  21. [21]
    #10 - PT5300 - The last Philips pattern generator - YouTube
    Sep 11, 2023 · ... Philips pattern recordings made and uploaded to YouTube in the past two decades. And if that wasn't enough for you, one of those units is ...
  22. [22]
    DK-Technologies, Solutions in Audio and Video
    I have made all legacy DK products and the former Philips/PTV products open source for anyone to use. ... PT5300 series of products. You can find a ...
  23. [23]
    [PDF] Guidelines for the transition from analogue to digital broadcasting - ITU
    The Guidelines for the transition from analogue to digital broadcasting is intended for a global audience to provide information and recommendations on policy, ...
  24. [24]
    Analogue Switch-Off extended to 31 March 2025 - DCDT
    Dec 5, 2024 · Date : 05 December 2024. Analogue Switch-Off extended to 31 March 2025. I can confirm that the Ministry of Communications and Digital ...
  25. [25]
    timre6/svg_test_card: An svg image reproduction of Philips PM5544 ...
    This reproduction is mainly based on the information in the Wikipedia article Philips circle pattern. Challenges. Sine wave patterns below the middle of circle.
  26. [26]
    Not Found | Hackaday.io
    No readable text found in the HTML.<|separator|>
  27. [27]
    Recreating An Analog TV Test Pattern - Hackaday
    Jun 9, 2023 · The most accurate and reliable test patterns you'd need a Philips pattern generator which created the pattern with hardware instead, and you can build your own ...
  28. [28]
    FULL HD PM5644 test pattern - 1920 x 1080 60p - YouTube
    Apr 29, 2016 · ... Philips Pattern or PTV Circle. The content and layout of the pattern was designed by engineer Finn Hendil (1939-2011) in the Philips TV ...<|control11|><|separator|>
  29. [29]
    Recreating 80's broadcast TV with a Raspberry Pi - YouTube
    Sep 21, 2024 · I recreated over-the-air broadcast television the way I remember it from my childhood. In this video, I'll wax nostalgic about the old-days ...