24 bit lcd panel free sample

FocusLCDs.com sent me a free sample of a 4x3” TFT LCD (P/N: E43RG34827LW2M300-R) to try out. This is a color active matrix TFT (Thin Film Transistor) LCD (liquid crystal display) that uses amorphous silicon TFT as a switching device. This model is composed of a Transmissive type TFT-LCD Panel, driver circuit, backlight unit. The resolution of a 4.3” TFT-LCD contains 480x272 pixels, and can display up to 16.7M colors.

LVDS displays can vary a lot. LVDS displays are not governed by a set of well defined rules like MIPI DSI displays are. Therefore, it is up to the LCD manufacturer and the LVDS display driver IC manufacturer to use LVDS interface as they please, as long as they follow the physical interface and logic levels.

Based on this data, we can pick an LVDS transmitter IC. SN75LVDS84 from Texas Instruments is great for use with LCD displays that can be driven by an STM32.

The color range of a computer is defined by the term color depth, which is the number of colors that the equipment can display, given its hardware. The most common normal color depths you"ll see are 8-bit (256 colors), 16-bit (65,536 colors), and 24-bit (16.7 million colors) modes. True color (or 24-bit color) is the most frequently used mode as computers have attained sufficient levels to work efficiently at this color depth.

Some professional designers and photographers use a 32-bit color depth, but mainly to pad the color to get more defined tones when the project renders down to the 24-bit level.

LCD monitors struggle with color and speed. Color on an LCD has three layers of colored dots that make up the final pixel. To display a color, a current is applied to each color layer to generate the desired intensity that results in the final color. The problem is that to get the colors, the current must move the crystals on and off to the desired intensity levels. This transition from the on-to-off state is called the response time. For most screens, it rates around 8 to 12 milliseconds.

The problem with response time becomes apparent when LCD monitors display motion or video. With a high response time for transitions from off-to-on states, pixels that should have transitioned to the new color levels trail the signal and result in an effect called motion blurring. This phenomenon isn"t an issue if the monitor displays applications such as productivity software. However, with high-speed video and certain video games, it can be jarring.

Color depth was previously referred to by the total number of colors that the screen can render. When referring to LCD panels, the number of levels that each color can render is used instead.

High-speed LCD monitors typically reduce the number of bits for each color to 6 instead of the standard 8. This 6-bit color generates fewer colors than 8-bit, as we see when we do the math:

Why multiply groups of three? For computer displays, the RGB colorspace dominates. Which means that, for 8-bit color, the final image you see on the screen is a composite of one of 256 shades each of red, blue, and green.

There is another level of display that is used by professionals called a 10-bit display. In theory, it displays more than a billion colors, more than the human eye discerns.

Even though the graphics card renders upwards of a billion colors, the display"s color gamut—or range of colors it can display—is considerably less. Even the ultra-wide color gamut displays that support 10-bit color cannot render all the colors.

Professional displays often tout 10-bit color support. Once again, you have to look at the real color gamut of these displays. Most consumer displays don"t say how many they use. Instead, they tend to list the number of colors they support.

The amount of color matters to those that do professional work on graphics. For these people, the amount of color that displays on the screen is significant. The average consumer won"t need this level of color representation by their monitor. As a result, it probably doesn"t matter. People using their displays for video games or watching videos will likely not care about the number of colors rendered by the LCD but by the speed at which it can be displayed. As a result, it is best to determine your needs and base your purchase on those criteria.

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To ensure baseline compatibility between different HDMI sources and displays (as well as backward compatibility with the electrically compatible DVI standard) all HDMI devices must implement the sRGB color space at 8 bits per component.: §6.2.3 Ability to use the Y′CBCR color space and higher color depths ("deep color") is optional. HDMI permits sRGB 4:4:4 chroma subsampling (8–16 bits per component), xvYCC 4:4:4 chroma subsampling (8–16 bits per component), Y′CBCR 4:4:4 chroma subsampling (8–16 bits per component), or Y′CBCR 4:2:2 chroma subsampling (8–12 bits per component). The color spaces that can be used by HDMI are ITU-R BT.601, ITU-R BT.709-5 and IEC 61966-2-4.: §§6.5,6.7.2

For digital audio, if an HDMI device has audio, it is required to implement the baseline format: stereo (uncompressed) PCM. Other formats are optional, with HDMI allowing up to 8 channels of uncompressed audio at sample sizes of 16 bits, 20 bits, or 24 bits, with sample rates of 32kHz, 44.1kHz, 48kHz, 88.2kHz, 96kHz, 176.4kHz, or 192kHz.: §7 HDMI also carries any IEC 61937-compliant compressed audio stream, such as Dolby Digital and DTS, and up to 8 channels of one-bit DSD audio (used on Super Audio CDs) at rates up to four times that of Super Audio CD.: §7 With version 1.3, HDMI allows lossless compressed audio streams Dolby TrueHD and DTS-HD Master Audio.: §7 As with the Y′CBCR video, audio capability is optional. Audio return channel (ARC) is a feature introduced in the HDMI 1.4 standard.

The Display Data Channel (DDC) is a communication channel based on the I2C bus specification. HDMI specifically requires the device implement the Enhanced Display Data Channel (E-DDC), which is used by the HDMI source device to read the E-EDID data from the HDMI sink device to learn what audio/video formats it can take.: §§8.1,CEC-1.2–CEC-1.3 HDMI requires that the E-DDC implement I2C standard mode speed (100 kbit/s) and allows it to optionally implement fast mode speed (400 kbit/s).: §4.2.8

Both HDMI and DVI use TMDS to send 10-bit characters that are encoded using 8b/10b encoding that differs from the original IBM form for the video data period and 2b/10b encoding for the control period. HDMI adds the ability to send audio and auxiliary data using 4b/10b encoding for the data island period. Each data island period is 32 pixels in size and contains a 32-bit packet header, which includes 8 bits of BCH ECC parity data for error correction and describes the contents of the packet. Each packet contains four subpackets, and each subpacket is 64 bits in size, including 8 bits of BCH ECC parity data, allowing for each packet to carry up to 224 bits of audio data. Each data island period can contain up to 18 packets. Seven of the 15 packet types described in the HDMI 1.3a specifications deal with audio data, while the other 8 types deal with auxiliary data. Among these are the general control packet and the gamut metadata packet. The general control packet carries information on AVMUTE (which mutes the audio during changes that may cause audio noise) and color depth (which sends the bit depth of the current video stream and is required for deep color). The gamut metadata packet carries information on the color space being used for the current video stream and is required for xvYCC.: §§5.2–5.3,6.5.3,6.7.2,6.7.3

HDMI Ethernet Channel technology consolidates video, audio, and data streams into a single HDMI cable, and the HEC feature enables IP-based applications over HDMI and provides a bidirectional Ethernet communication at 100 Mbit/s.physical layer of the Ethernet implementation uses a hybrid to simultaneously send and receive attenuated 100BASE-TX-type signals through a single twisted pair.

HDMI can use HDCP to encrypt the signal if required by the source device. CSS, CPRM and AACS require the use of HDCP on HDMI when playing back encrypted DVD Video, DVD Audio, HD DVD and Blu-ray Disc. The HDCP Repeater bit controls the authentication and switching/distribution of an HDMI signal. According to HDCP Specification 1.2 (beginning with HDMI CTS 1.3a), any system that implements HDCP must do so in a fully compliant manner. HDCP testing that was previously only a requirement for optional tests such as the "Simplay HD" testing program is now part of the requirements for HDMI compliance.: §9.2

This connector is 21.2 mm × 4.45 mm and has 29 pins, carrying six differential pairs instead of three, for use with very high-resolution displays such as WQUXGA (3840×2400). It is electrically compatible with dual-link DVI-D, but as of August 2021: §§4.1.3,4.1.9.4

A new certification program was introduced in October 2015 to certify that cables work at the 18 Gbit/s maximum bandwidth of the HDMI 2.0 specification.

In conjunction with the HDMI 2.1 specification, a third category of cable was announced on January 4, 2017, called "48G".Gbit/s bandwidth of HDMI 2.1, supporting 4K, 5K, 8K and 10K at 120Hz.

HDMI 1.0 was released on December 9, 2002, and is a single-cable digital audio/video connector interface. The link architecture is based on DVI, using exactly the same video transmission format but sending audio and other auxiliary data during the blanking intervals of the video stream. HDMI 1.0 allows a maximum TMDS clock of 165MHz (4.95Gbit/s bandwidth per link), the same as DVI. It defines two connectors called Type A and Type B, with pinouts based on the Single-Link DVI-D and Dual-Link DVI-D connectors respectively, though the Type B connector was never used in any commercial products. HDMI 1.0 uses TMDS encoding for video transmission, giving it 3.96Gbit/s of video bandwidth (1920 × 1080 or 1920 × 1200 at 60Hz) and 8-channel LPCM/192 kHz/24-bit audio. HDMI 1.0 requires support for RGB video, with optional support for Y′CBCR 4:4:4 and 4:2:2 (mandatory if the device has support for Y′CBCR on other interfaces). Color depth of 10bpc (30bit/px) or 12bpc (36bit/px) is allowed when using 4:2:2 subsampling, but only 8bpc (24bit/px) color depth is permitted when using RGB or Y′CBCR 4:4:4. Only the Rec. 601 and Rec. 709 color spaces are supported. HDMI 1.0 allows only specific pre-defined video formats, including all the formats defined in EIA/CEA-861-B and some additional formats listed in the HDMI Specification itself. All HDMI sources/sinks must also be capable of sending/receiving native Single-Link DVI video and be fully compliant with the DVI Specification.

HDMI 1.2 was released on August 8, 2005, and added the option of One Bit Audio, used on Super Audio CDs, at up to 8 channels. To make HDMI more suitable for use on PC devices, version 1.2 also removed the requirement that only explicitly supported formats be used. It added the ability for manufacturers to create vendor-specific formats, allowing any arbitrary resolution and refresh rate rather than being limited to a pre-defined list of supported formats. In addition, it added explicit support for several new formats including 720p at 100 and 120 Hz and relaxed the pixel format support requirements so that sources with only native RGB output (PC sources) would not be required to support Y′CBCR output.: §6.2.3

HDMI 1.3 was released on June 22, 2006, and increased the maximum TMDS clock to 340MHz (10.2Gbit/s).Gbit/s (sufficient for 1920 × 1080 at 144Hz or 2560 × 1440 at 75Hz). It added support for 10bpc, 12bpc, and 16bpc color depth (30, 36, and 48bit/px), called deep color. It also added support for the xvYCC color space, in addition to the ITU-R BT.601 and BT.709 color spaces supported by previous versions, and added the ability to carry metadata defining color gamut boundaries. It also optionally allows output of Dolby TrueHD and DTS-HD Master Audio streams for external decoding by AV receivers.audio video sync) capability.MHz and Category 2 being tested up to 340 MHz.: §4.2.6 It also added the new HDMI Type C "Mini" connector for portable devices.: §4.1.1

HDMI 1.3a was released on November 10, 2006, and had cable and sink modifications for HDMI Type C, source termination recommendations, and removed undershoot and maximum rise/fall time limits. It also changed CEC capacitance limits, and CEC commands for timer control were brought back in an altered form, with audio control commands added. It also added the optional ability to stream SACD in its bitstream DST format rather than uncompressed raw DSD.

HDMI 1.4 was released on June 5, 2009, and first came to market after Q2 of 2009.×2160 at 24Hz, 3840×2160 at 24, 25, and 30Hz, and added explicit support for 1920×1080 at 120Hz with CTA-861 timings.: §6.3.2 It also added an HDMI Ethernet Channel (HEC) that accommodates a 100 Mbit/s Ethernet connection between the two HDMI connected devices so they can share an Internet connection,Adobe RGB and Adobe YCC601, and an Automotive Connection System.stereoscopic 3D formats including field alternative (interlaced), frame packing (a full resolution top-bottom format), line alternative full, side-by-side half, side-by-side full, 2D + depth, and 2D + depth + graphics + graphics depth (WOWvx).

HDMI 2.0 increases the maximum bandwidth to 18.0 Gbit/s.Rec. 2020 color space, up to 32 audio channels, up to 1536 kHz audio sample frequency, dual video streams to multiple users on the same screen, up to four audio streams, 4:2:0 chroma subsampling, 25 fps 3D formats, support for the 21:9 aspect ratio, dynamic synchronization of video and audio streams, the HE-AAC and DRA audio standards, improved 3D capability, and additional CEC functions.

HDMI 2.1 was officially announced by the HDMI Forum on January4, 2017,Hz and 8K 120Hz. HDMI 2.1 also introduces a new HDMI cable category called Ultra High Speed (referred to as 48G during development), which certifies cables at the new higher speeds that these formats require. Ultra High Speed HDMI cables are backwards compatible with older HDMI devices, and older cables are compatible with new HDMI 2.1 devices, though the full 48Gbit/s bandwidth is only supported with the new cables.

Video formats that require more bandwidth than 18.0Gbit/s (4K 60Hz 8bpc RGB), such as 4K 60Hz 10bpc (HDR), 4K 120Hz, and 8K 60Hz, may require the new "Ultra High Speed" or "Ultra High Speed with Ethernet" cables.

The increase in maximum bandwidth is achieved by increasing both the bitrate of the data channels and the number of channels. Previous HDMI versions use three data channels (each operating at up to 6.0Gbit/s in HDMI 2.0, or up to 3.4Gbit/s in HDMI 1.4), with an additional channel for the TMDS clock signal, which runs at a fraction of the data channel speed (one tenth the speed, or up to 340MHz, for signaling rates up to 3.4Gbit/s; one fortieth the speed, or up to 150MHz, for signaling rates between 3.4 and 6.0Gbit/s). HDMI 2.1 doubles the signaling rate of the data channels to 12Gbit/s. The structure of the data has been changed to use a new packet-based format with an embedded clock signal, which allows what was formerly the TMDS clock channel to be used as a fourth data channel instead, increasing the signaling rate across that channel to 12Gbit/s as well. These changes increase the aggregate bandwidth from 18.0Gbit/s (3 × 6.0Gbit/s) to 48.0Gbit/s (4 × 12.0Gbit/s), a 2.66× improvement in bandwidth. In addition, the data is transmitted more efficiently by using a 16b/18b encoding scheme, which uses a larger percentage of the bandwidth for data rather than DC balancing compared to the TMDS scheme used by previous versions (88.8% compared to 80%). This, in combination with the 2.66× bandwidth, raises the maximum data rate of HDMI 2.1 from 14.4Gbit/s to 42.6Gbit/s. Subtracting overhead for FEC, the usable data rate is approximately 42.0Gbit/s, around 2.92× the data rate of HDMI 2.0.

The 48Gbit/s bandwidth provided by HDMI 2.1 is enough for 8K resolution at approximately 50Hz, with 8bpc RGB or Y′CBCR 4:4:4 color. To achieve even higher formats, HDMI 2.1 can use Display Stream Compression with a compression ratio of up to 3∶1. Using DSC, formats up to 8K (7680 × 4320) 120Hz or 10K (10240 × 4320) 100Hz at 8bpc RGB/4:4:4 are possible. Using Y′CBCR with 4:2:2 or 4:2:0 chroma subsampling in combination with DSC can allow for even higher formats.

Products are not required to implement all features of a version to be considered compliant with that version, as most features are optional. For example, displays with HDMI 1.4 ports do not necessarily support the full 340 MHz TMDS clock allowed by HDMI 1.4; they are commonly limited to lower speeds such as 300 MHz (1080p 120 Hz) or even as low as 165 MHz (1080p 60 Hz) at the manufacturer"s discretion, but are still considered HDMI 1.4-compliant. Likewise, features like 10 bpc (30 bit/px) color depth may also not be supported, even if the HDMI version allows it and the display supports it over other interfaces such as DisplayPort.

Total transmission bit rate is equal to the number of data channels multiplied by the bit rate per channel (binary digits transmitted per second). Each channel transmits one bit (binary digit) per signal, and signals at ten times the character rate. Therefore, the total transmission bit rate (in Mbit/s) = 10×(character rate in MHz)×(#of data channels).

Some of the transmitted bits are used for encoding purposes rather than representing data, so the rate at which video data can be transmitted across the HDMI interface is only a portion of the total bit rate.

The TMDS character rate is the number of 10-bit TMDS characters per second transmitted across one HDMI data channel. This is sometimes informally referred to as the pixel clock or TMDS clock because these terms were once equivalent in past HDMI versions.: §4.2.2

TMDS encoding uses 10 bits of the transmission to send 8 bits of data, so only 80% of the transmission bit rate is available for data throughput. 16b/18b encoding uses 18 bits of bandwidth to send 16 bits of data, so 88.8% of the transmission bit rate is available for data throughput.

HDMI 1.0 and 1.1 are restricted to transmitting only certain video formats,: §6.1 defined in EIA/CEA-861-B and in the HDMI Specification itself.: §6.3 HDMI 1.2 and all later versions allow any arbitrary resolution and frame rate (within the bandwidth limit). Formats that are not supported by the HDMI Specification (i.e., no standardized timings defined) may be implemented as a vendor-specific format. Successive versions of the HDMI Specification continue to add support for additional formats (such as 4K resolutions), but the added support is to establish standardized timings to ensure interoperability between products, not to establish which formats are or aren"t permitted. Video formats do not require explicit support from the HDMI Specification in order to be transmitted and displayed.: §6.1

Uncompressed 8bpc (24bit/px) color depth with RGB or Y′CBCR 4:4:4 color format and CVT-R2 timing are used to calculate these data rates. Uncompressed data rate for RGB images in bits per second is calculated as bits per pixel × pixels per frame × frames per second. Pixels per frame includes blanking intervals as defined by CVT-R2.

Uncompressed 10bpc (30bit/px) color depth with RGB or Y′CBCR 4:4:4 color format and CVT-R2 timing are used to calculate these data rates. Uncompressed data rate for RGB images in bits per second is calculated as bits per pixel × pixels per frame × frames per second. Pixels per frame includes blanking intervals as defined by CVT-R2.

Display Stream Compression (DSC) is a VESA-developed video compression algorithm designed to enable increased display resolutions and frame rates over existing physical interfaces, and make devices smaller and lighter, with longer battery life.delta PCM coding and YCGCO-R color space.lossy, it meets the ISO/IEC 29170 standard for "visually lossless" compression, a form of compression in which "the user cannot tell the difference between a compressed and uncompressed image".: 18 However, the standard allows for images that "exhibit particularly strong artefacts" to be disregarded or excluded from testing, such as engineered test images.: 13, 18 Research of DSC using the ISO/IEC 29170 interleaved protocol, in which an uncompressed reference image is presented side by side with a rapidly alternating sequence of the compressed test image and uncompressed reference image,: 10 and performed with various types of images (such as people, natural and man-made scenery, text, and known challenging imagery) shows that in most images DSC satisfies the standard"s criterion for visually lossless performance, although in some trials participants were able to detect the presence of compression on certain images.

DSC compression works on a horizontal line of pixels encoded using groups of three consecutive pixels for native 4:4:4 and simple 4:2:2 formats, or six pixels (three compressed containers) for native 4:2:2 and 4:2:0 formats. If RGB encoding is used, it is first converted to reversible YCGCO. Simple conversion from 4:2:2 to 4:4:4 can add missing chroma samples by interpolating neighboring pixels. Each luma component is coded separately using three independent substreams (four substreams in native 4:2:2 mode). Prediction step is performed using one of the three modes: modified median adaptive coding (MMAP) algorithm similar to the one used by JPEG-LS, block prediction (optional for decoders due to high computational complexity, negotiated at DSC handshake), and midpoint prediction. Bit rate control algorithm tracks color flatness and buffer fullness to adjust the quantization bit depth for a pixel group in a way that minimizes compression artifacts while staying within the bitrate limits. Repeating recent pixels can be stored in 32-entry Indexed Color History (ICH) buffer, which can be referenced directly by each group in a slice; this improves compression quality of computer-generated images. Alternatively, prediction residuals are computed and encoded with entropy coding algorithm based on delta size unit-variable length coding (DSU-VLC). Encoded pixel groups are then combined into slices of various height and width; common combinations include 100% or 25% picture width, and 8-, 32-, or 108-line height.

Blu-ray Disc and HD DVD, introduced in 2006, offer high-fidelity audio features that require HDMI for best results. HDMI 1.3 can transport Dolby Digital Plus, Dolby TrueHD, and DTS-HD Master Audio bitstreams in compressed form.: §7 This capability allows for an AV receiver with the necessary decoder to decode the compressed audio stream. The Blu-ray specification does not include video encoded with either deep color or xvYCC; thus, HDMI 1.0 can transfer Blu-ray discs at full video quality.

Blu-ray permits secondary audio decoding, whereby the disc content can tell the player to mix multiple audio sources together before final output.codecs internally and can output LPCM audio over HDMI. Multichannel LPCM can be transported over an HDMI connection, and as long as the AV receiver implements multichannel LPCM audio over HDMI and implements HDCP, the audio reproduction is equal in resolution to HDMI 1.3 bitstream output. Some low-cost AV receivers, such as the Onkyo TX-SR506, do not allow audio processing over HDMI and are labelled as "HDMI pass through" devices.

The Asus Xonar HDAV1.3 became the first HDMI sound card that implemented the Protected Audio Path and could both bitstream and decode lossless audio (Dolby TrueHD and DTS-HD MA), although bitstreaming is only available if using the ArcSoft TotalMedia Theatre software.

In September 2009, AMD announced the ATI Radeon HD 5000 series video cards, which have HDMI 1.3 output (deep color, xvYCC wide gamut capability and high bit rate audio), 8-channel LPCM over HDMI, and an integrated HD audio controller with a Protected Audio Path that allows bitstream output over HDMI for AAC, Dolby AC-3, Dolby TrueHD and DTS-HD Master Audio formats.Radeon HD 6000 Series implements HDMI 1.4a. The AMD Radeon HD 7000 Series implements HDMI 1.4b.

On September 1, 2020, Nvidia launched the GeForce RTX 30 series, the world"s first discrete graphics cards with support for the full 48Gbit/s bandwidth with Display Stream Compression 1.2 of HDMI 2.1.

DisplayPort uses a self-clocking, micro-packet-based protocol that allows for a variable number of differential LVDS lanes as well as flexible allocation of bandwidth between audio and video, and allows encapsulating multi-channel compressed audio formats in the audio stream.FreeSync), and Dual-mode LVDS/TMDS transmitters compatible with HDMI 1.2 or 1.4.Gbit/s with the new HBR3 mode featuring 8.1Gbit/s per lane; it requires Dual-mode with mandatory HDMI 2.0 compatibility and HDCP 2.2.BT.2020 color space, and HDR10 extensions from CTA-861.3, including static and dynamic metadata.

Version 1.0 supported 720p/1080i 60 Hz (RGB/4:4:4 pixel encoding) with a bandwidth of 2.25 Gbit/s. Versions 1.3 and 2.0 added support for 1080p 60 Hz (Y′CBCR 4:2:2) with a bandwidth of 3 Gbit/s in PackedPixel mode.Ultra HD (3840 × 2160) 30 Hz video, and also changed from being frame-based, like HDMI, to packet-based.

The fourth version, superMHL, increased bandwidth by operating over multiple TMDS differential pairs (up to a total of six) allowing a maximum of 36 Gbit/s.USB-C Alternate Mode (only a single lane is supported over micro-USB/HDMI). Display Stream Compression (DSC) is used to allow up to 8K Ultra HD (7680 × 4320) 120 Hz HDR video, and to support Ultra HD 60 Hz video over a single lane.

Alen Koebel (February 2003). "DVI and HDMI: Digital A/V Interfaces for A New Age". Widescreen Review (69): 64. Retrieved June 24, 2008. When HDCP is added to DVI, the result is often called "DVI+HDCP." When this is used on an HDTV, HD monitor or set-top box, a further standard is usually applied: IEA/CEA-861 (currently 861-B)...the interface is commonly known as DVI-HDTV.

"VESA Finalizes Requirements for Display Stream Compression Standard" (Press release). VESA. January 24, 2013. Archived from the original on March 21, 2018. Retrieved March 20, 2018.

"HDMI Licensing, LLC Releases Alternate Mode for USB Type-C Connector". hdmi.org (Press release). September 1, 2016. Archived from the original on December 24, 2018. Retrieved September 11, 2016.