.TH PBMTOJBG 1 "2003-06-04" .SH NAME pbmtojbg \- portable bitmap to JBIG1 file converter .SH SYNOPSIS .B pbmtojbg [ .I options ] [ .I input-file | \- [ .I output-file ]] .br .SH DESCRIPTION Reads in a portable bitmap (PBM) from a file or standard input, compresses it, and outputs the image as a .I JBIG1 bi-level image entity (BIE) file. .I JBIG1 is a highly effective lossless compression algorithm for bi-level images (one bit per pixel), which is particularly suitable for scanned document pages. A .I JBIG1 encoded image can be stored in several resolutions (progressive mode). These resolution layers can be stored all in one single BIE or they can be stored in several separate BIE files. All resolution layers except the lowest one are stored merely as differences to the next lower resolution layer, because this requires less space than encoding the full image completely every time. Each resolution layer has twice the number of horizontal and vertical pixels than the next lower layer. .I JBIG1 files can also store several bits per pixel as separate bitmap planes, and .I pbmtojbg can read a PGM file and transform it into a multi-bitplane BIE. .SH OPTIONS .TP 14 .BI \- A single hyphen instead of an input file name will cause .I pbmtojbg to read the data from standard input instead from a file. .TP .BI \-q Encode the image in one single resolution layer (sequential mode). This is usually the most efficient compression method. By default, the number of resolution layers is chosen automatically such that the lowest layer image is not larger than 640 \(mu 480 pixels. .TP .BI \-x " number" Specify the maximal horizontal size of the lowest resolution layer. The default is 640 pixels. .TP .BI \-y " number" Specify the maximal vertical size of the lowest resolution layer. The default is 480 pixels. .TP .BI \-l " number" Select the lowest resolution layer that will be written to the BIE. It is possible to store the various resolution layers of a .I JBIG1 image in progressive mode into different BIEs. Options .BI \-l and .BI \-h allow to select the resolution-layer interval that will appear in the created BIE. The lowest resolution layer has number 0 and this is also the default value. By default all layers will be written. .TP .BI \-h " number" Select the highest resolution layer that will be written to the BIE. By default all layers will be written. See also option .BI \-l. .TP .BI \-b Use binary values instead of Gray code words in order to encode pixel values in multiple bitplanes. This option has only an effect if the input is a PGM file and if more than one bitplane is produced. Note that the decoder has to make the same selection but cannot determine from the BIE, whether Gray or binary code words were used by the encoder. .TP .BI \-d " number" Specify the total number of differential resolution layers into which the input image will be split in addition to the lowest layer. Each additional layer reduces the size of layer 0 by 50 %. This option overrides options .BI \-x and .BI \-y which are usually a more comfortable way of selecting the number of resolution layers. .TP .BI \-s " number" The .I JBIG1 algorithm splits each image into a number of horizontal stripes. This option specifies that each stripe shall have .I number lines in layer 0. The default value is selected so that approximately 35 stripes will be used for the whole image. .TP .BI \-m " number" Select the maximum horizontal offset of the adaptive template pixel. The .I JBIG1 encoder uses a number of neighbour pixels in order to get statistical a priori knowledge of the probability, whether the next pixel will be black or white. One single pixel out of this template of context neighbor pixels can be moved around. Especially for dithered images it can be a significant advantage to have one neighbor pixel which has a distance large enough to cover the period of a dither function. By default, the adaptive template pixel can be moved up to 8 pixels away. This encoder supports up to 23 pixels, however as decoders are only required to support at least a distance of 16 pixels by the standard, no higher value than 16 for .I number is recommended in order to maintain interoperability with other .I JBIG1 implementations. The maximal vertical offset of the adaptive template pixel is always zero. .TP .BI \-t " number" Encode only the specified number of most significant bit planes. This option allows to reduce the depth of an input PGM file if not all bits per pixel are needed in the output. .TP .BI \-o " number" .I JBIG1 separates an image into several horizontal stripes, resolution layers and planes, were each plane contains one bit per pixel. One single stripe in one plane and layer is encoded as a data unit called stripe data entity (SDE) inside the BIE. There are 12 different possible orders in which the SDEs can be stored inside the BIE and .I number selects which one shall be used. The order of the SDEs is only relevant for applications that want to decode a .I JBIG1 file which has not yet completely arrived from e.g. a slow network connection. For instance some applications prefer that the outermost of the three loops (stripes, layers, planes) is over all layers so that all data of the lowest resolution layer is transmitted first. .br The following values for .I number select these loop arrangements for writing the SDEs (outermost loop first): 0 planes, layers, stripes .br 2 layers, planes, stripes .br 3 layers, stripes, planes .br 4 stripes, planes, layers .br 5 planes, stripes, layers .br 6 stripes, layers, planes All loops count starting with zero, however by adding 8 to the above order code, the layer loop can be reversed so that it counts down to zero and then higher resolution layers will be stored before lower layers. Default order is 3 which writes at first all planes of the first stripe and then completes layer 0 before continuing with the next layer and so on. .TP .BI \-p " number" This option allows to activate or deactivate various optional algorithms defined in the .I JBIG1 standard. Just add the numbers of the following options which you want to activate in order to get the .I number value: 4 deterministic prediction (DPON) .br 8 layer 0 typical prediction (TPBON) .br 16 diff. layer typ. pred. (TPDON) .br 64 layer 0 two-line template (LRLTWO) Except for special applications (like communication with .I JBIG1 subset implementations) and for debugging purposes you will normally not want to change anything here. The default is 28, which provides the best compression result. .TP .BI \-c Determine the adaptive template pixel movement as suggested in annex C of the standard. By default the template change takes place directly in the next line, which is most effective. However, a few conformance test examples in the standard require the adaptive template change to be delayed until the first line of the next stripe. This option selects this special behavior, which is normally not required except in order to pass some conformance tests. .TP .BI \-Y " number" A long time ago, there were fax machines that couldn't even hold a single page in memory. They had to start transmitting data before the page was scanned in completely and the length of the image was known. The authors of the standard added a rather ugly hack to the otherwise beautiful JBIG1 format to support this. The NEWLEN marker segment can override the image height stated in the BIE header anywhere later in the data stream. Normally .I pbmtojbg never generates NEWLEN marker segments, as it knows the correct image height when it outputs the header. This option is solely intended for the purpose of generating test files with NEWLEN marker segments. It can be used to specify a higher initial image height for use in the BIE header, and .I pbmtojbg will then add a NEWLEN marker segment at the latest possible opportunity to the data stream to signal the correct final height. .TP .BI \-v After the BIE has been created, a few technical details of the created file will be listed (verbose mode). .SH BUGS Using standard input and standard output for binary data works only on systems where there is no difference between binary and text streams (e.g., Unix). On other systems (e.g., MS-DOS), using standard input or standard output may cause control characters like CR or LF to be inserted or deleted and this will damage the binary data. .SH STANDARDS This program implements the .I JBIG1 image coding algorithm as specified in ISO/IEC 11544:1993 and ITU-T T.82(1993). .SH AUTHOR The .I pbmtojbg program is part of the .I JBIG-KIT package, which has been developed by Markus Kuhn. The most recent version of this portable .I JBIG1 library and tools set is available from . .SH SEE ALSO pbm(5), pgm(5), jbgtopbm(1)