Progressive Graphics File

PGF

Filename extension	`.pgf`
Magic number	`504746`h (ASCII PGF)
Developed by	xeraina GmbH
Initial release	2000 (2000)
Latest release	7.15.25 (2015 (2015))
Type of format	wavelet-based bitmapped image format
Extended from	JPEG, PNG
Open format?	LGPLv2^[1]

PGF (Progressive Graphics File) is a wavelet-based bitmapped image format that employs lossless and lossy data compression. PGF was created to improve upon and replace the JPEG format. It was developed at the same time as JPEG 2000 but with a focus on speed over compression ratio.

PGF can operate at higher compression ratios without taking more encoding/decoding time and without generating the characteristic "blocky and blurry" artifacts of the original DCT-based JPEG standard.^[2] It also allows more sophisticated progressive downloads.

Color models

PGF supports a wide variety of color models:

Grayscale with 1, 8, 16, or 31 bits per pixel
Indexed color with palette size of 256
RGB color image with 12, 16 (red: 5 bits, green: 6 bits, blue: 5 bits), 24, or 48 bits per pixel
ARGB color image with 32 bits per pixel
L*a*b color image with 24 or 48 bits per pixel
CMYK color image with 32 or 64 bits per pixel

Technical discussion

PGF claims to achieve an improved compression quality over JPEG adding or improving features such as scalability. Its compression performance is similar to the original JPEG standard. Very low and very high compression rates (including lossless compression) are also supported in PGF. The ability of the design to handle a very large range of effective bit rates is one of the strengths of PGF. For example, to reduce the number of bits for a picture below a certain amount, the advisable thing to do with the first JPEG standard is to reduce the resolution of the input image before encoding it — something that is ordinarily not necessary for that purpose when using PGF because of its wavelet scalability properties.

The PGF process chain contains the following four steps:

Color space transform (in case of color images)
Discrete Wavelet Transform
Quantization (in case of lossy data compression)
Hierarchical bit-plane run-length encoding

Color components transformation

Initially, images have to be transformed from the RGB color space to another color space, leading to three components that are handled separately. PGF uses a fully reversible modified YUV color transform. The transformation matrices are:

{\begin{bmatrix}Y_{r}\\U_{r}\\V_{r}\end{bmatrix}}={\begin{bmatrix}{\frac {1}{4}}&{\frac {1}{2}}&{\frac {1}{4}}\\1&-1&0\\0&-1&1\end{bmatrix}}{\begin{bmatrix}R\\G\\B\end{bmatrix}};\qquad \qquad {\begin{bmatrix}R\\G\\B\end{bmatrix}}={\begin{bmatrix}1&{\frac {3}{4}}&-{\frac {1}{4}}\\1&-{\frac {1}{4}}&-{\frac {1}{4}}\\1&-{\frac {1}{4}}&{\frac {3}{4}}\end{bmatrix}}{\begin{bmatrix}Y_{r}\\U_{r}\\V_{r}\end{bmatrix}}

The chrominance components can be, but do not necessarily have to be, down-scaled in resolution.

Wavelet transform

The color components are then wavelet transformed to an arbitrary depth, in contrast to JPEG 1992 which uses an 8x8 block-size discrete cosine transform. PGF uses one reversible wavelet transform: a rounded version of the biorthogonal CDF 5/3 wavelet transform. This wavelet filter bank is exactly the same as the reversible wavelet used in JPEG 2000. It uses only integer coefficients, so the output does not require rounding (quantization) and so it does not introduce any quantization noise.

Quantization

After the wavelet transform, the coefficients are scalar-quantized to reduce the amount of bits to represent them, at the expense of a loss of quality. The output is a set of integer numbers which have to be encoded bit-by-bit. The parameter that can be changed to set the final quality is the quantization step: the greater the step, the greater is the compression and the loss of quality. With a quantization step that equals 1, no quantization is performed (it is used in lossless compression). In contrast to JPEG 2000, PGF uses only powers of two, therefore the parameter value i represents a quantization step of 2ⁱ. Just using powers of two makes no need of integer multiplication and division operations.

Coding

The result of the previous process is a collection of sub-bands which represent several approximation scales. A sub-band is a set of coefficients — integer numbers which represent aspects of the image associated with a certain frequency range as well as a spatial area of the image.

The quantized sub-bands are split further into blocks, rectangular regions in the wavelet domain. They are typically selected in a way that the coefficients within them across the sub-bands form approximately spatial blocks in the (reconstructed) image domain and collected in a fixed size macroblock.

The encoder has to encode the bits of all quantized coefficients of a macroblock, starting with the most significant bits and progressing to less significant bits. In this encoding process, each bit-plane of the macroblock gets encoded in two so-called coding passes, first encoding bits of significant coefficients, then refinement bits of significant coefficients. Clearly, in lossless mode all bit-planes have to be encoded, and no bit-planes can be dropped.

Only significant coefficients are compressed with an adaptive run-length/Rice (RLR) coder, because they contain long runs of zeros. The RLR coder with parameter k (logarithmic length of a run of zeros) is also known as the elementary Golomb code of order 2^k.

Comparison with other file formats

JPEG 2000 is slightly more space-efficient in handling natural images. The PSNR for the same compression ratio is on average 3% better than the PSNR of PGF. It has a small advantage in compression ratio but longer encoding and decoding times.^[2]
PNG (Portable Network Graphics) is more space-efficient in handling images with many pixels of the same color.

There are several self-proclaimed advantages of PGF over the ordinary JPEG standard:^[2]

Superior compression performance: The image quality (measured in PSNR) for the same compression ratio is on average 3% better than the PSNR of JPEG. At lower bit rates (e.g. less than 0.25 bits/pixel for gray-scale images), PGF has a much more significant advantage over certain modes of JPEG: artifacts are less visible and there is almost no blocking. The compression gains over JPEG are attributed to the use of DWT.
Multiple resolution representation: PGF provides seamless compression of multiple image components, with each component carrying from 1 to 31 bits per component sample. With this feature there is no need for separately stored preview images (thumbnails).
Progressive transmission by resolution accuracy, commonly referred to as progressive decoding: PGF provides efficient codestream organizations which are progressive by resolution. This way, after a smaller part of the whole file has been received, it is possible to see a lower quality of the final picture, the quality can be improved monotonically getting more data from the source.
Lossless and lossy compression: PGF provides both lossless and lossy compression in a single compression architecture. Both lossy and lossless compression are provided by the use of a reversible (integer) wavelet transform.
Side channel spatial information: Transparency and alpha planes are fully supported
ROI extraction: Since version 5, PGF supports extraction of regions of interest (ROI) without decoding the whole image.

Available software

The author published libPGF via a SourceForge, under the GNU Lesser General Public License version 2.0.^[1] Xeraina offers a free Photoshop .8bi file format plugin, a Win32 console encoder and decoder, and PGF viewers based on WIC for 32bit and 64bit Windows platforms. Other WIC applications including Photo Gallery are able to display PGF images after installing this viewer.^[3]

References

1 2 Christoph Stamm (2015). "PGF libPGF.org". SourceForge project libpgf. Retrieved 2015-09-14. External link in |work= (help)
1 2 3 Christoph Stamm. "PGF – A new progressive file format for lossy and lossless image compression" (PDF). Retrieved 2014-03-13.
↑ "PGF download". xeraina. 2013. Retrieved 2014-03-14.

Graphics file formats

Raster	ANI ANIM APNG ART BMP BPG BSAVE CAL CIN CPC CPT DDS DPX ECW EXR FITS FLIC FLIF FPX GIF HDRi HEVC ICER ICNS ICO / CUR ICS ILBM JBIG JBIG2 JNG JPEG JPEG 2000 JPEG-LS JPEG XR KRA MNG MIFF NRRD ORA PAM PBM / PGM / PPM / PNM PCX PGF PICtor PNG PSD / PSB PSP QTVR RAS RBE JPEG-HDR Logluv TIFF SGI TGA TIFF TIFF/EP TIFF/IT UFO/ UFP WBMP WebP XBM XCF XPM XWD

Raw	CIFF DNG

Vector	AI CDR CGM DXF EVA EMF Gerber HVIF IGES PGML SVG VML WMF Xar

Compound	CDF DjVu EPS PDF PICT PS SWF XAML

Related	Exchangeable image file format (Exif) Extensible Metadata Platform (XMP)

Category Comparison

Multimedia compression and container formats

Video
compression

ISO/IEC	MJPEG Motion JPEG 2000 MPEG-1 MPEG-2 Part 2 MPEG-4 Part 2/ASP Part 10/AVC MPEG-H Part 2/HEVC

ITU-T	H.120 H.261 H.262 H.263 H.264 H.265

SMPTE	VC-1 VC-2 VC-3 VC-5

Others	Apple Video AV1 AVS Bink Cinepak Daala Dirac DV DVI FFV1 Huffyuv Indeo Lagarith Microsoft Video 1 MSU Lossless OMS Video Pixlet ProRes 422 ProRes 4444 QuickTime Animation Graphics RealVideo RTVideo SheerVideo Smacker Sorenson Video, Spark Theora Thor VP3 VP6 VP7 VP8 VP9 WMV XEB YULS

Audio
compression

ISO/IEC	MPEG-1 Layer III (MP3) MPEG-1 Layer II Multichannel MPEG-1 Layer I AAC HE-AAC AAC-LD MPEG Surround MPEG-4 ALS MPEG-4 SLS MPEG-4 DST MPEG-4 HVXC MPEG-4 CELP MPEG-D USAC MPEG-H 3D Audio

ITU-T	G.711 (A-law, µ-law) G.718 G.719 G.722 G.722.1 G.722.2 G.723 G.723.1 G.726 G.728 G.729 G.729.1

IETF	Opus iLBC

3GPP	AMR AMR-WB AMR-WB+ EVRC EVRC-B GSM-HR GSM-FR GSM-EFR

Others	ACELP AC-3 ALAC Asao ATRAC CELT Codec2 DRA DTS FLAC iSAC Monkey's Audio TTA True Audio MT9 Musepack OptimFROG OSQ QCELP RCELP RealAudio RTAudio SD2 SHN SILK Siren SMV Speex SVOPC TwinVQ VMR-WB Vorbis VSELP WavPack WMA MQA aptX

Image
compression

IEC, ISO, ITU-T, W3C, IETF	CCITT Group 4 GIF HEVC JBIG JBIG2 JPEG JPEG 2000 JPEG XR Lossless JPEG PNG TIFF TIFF/EP TIFF/IT

Others	APNG BPG DjVu EXR FLIF ICER MNG PGF QTVR WBMP WebP

Containers

ISO/IEC	MPEG-ES MPEG-PES MPEG-PS MPEG-TS ISO base media file format MPEG-4 Part 14 (MP4) Motion JPEG 2000 MPEG-21 Part 9 MPEG media transport

ITU-T	H.222.0 T.802

IETF	RTP

Others	3GP and 3G2 AMV ASF AIFF AVI AU BPG Bink Smacker BMP DivX Media Format EVO Flash Video GXF IFF M2TS Matroska WebM MXF Ogg QuickTime File Format RatDVD RealMedia RIFF WAV MOD and TOD VOB, IFO and BUP

Collaborations

See Compression methods for methods and Compression software for codecs

This article is issued from Wikipedia - version of the 7/8/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.