Patent Description:
Single-pass ("pagewide") printing dramatically increases print speeds compared to traditional scanning printheads. One application of single-pass printing is in digital inkjet presses, as described in, for example, <CIT>; <CIT> and <CIT>.

In a typical color inkjet press, multiple monochrome printheads are aligned with each other along a media feed direction with each printhead printing a different color (e.g. CMYK). In principle, print speeds may be increased by increasing the number of printheads used to print each color. For example, a monochrome black printing system may double its printing speed by doubling the number of printheads printing black ink - a first printhead may print half of the dots required by a halftone image and a second downstream printhead may print the other half of the dots. It will be appreciated that print speeds may be tripled, quadrupled etc. by further increasing the number of aligned printheads.

As is well known in the art, halftone images (or bitmaps) containing discrete dots at a specified printing resolution are generated from contone images using a dithering process. For printing at double speed using two printheads, simplistically, the halftone image needs to be divided ("deinterleaved") into two portions, one for each printhead. For example, alternate lines of the halftone image may be printed by each of the two printheads - the first printhead printing odd lines of the image and the downstream second printhead printing even lines of the image or vice versa. Thus, each printhead receives a halftone image at half the resolution (in the printing direction) of the full halftone image. If, for example, the full halftone image is generated at a resolution of <NUM> x <NUM> dpi, then each printhead would receive a respective halftone image at a resolution of <NUM> x <NUM> dpi. The two halftone images are interleaved by the two printheads during printing to recreate the full halftone image at the target resolution of <NUM> x <NUM> dpi.

Printing at increased speeds using multiple high-resolution printheads in the manner described above requires excellent alignment of the printheads. Without excellent alignment of the printheads, print quality generally declines to an extent that is unacceptable to users.

Misalignment of printheads may arise from a number of sources. Firstly, mechanical placement of the printheads must be accurately controlled to within a few microns in order to avoid misalignment between a pair of printheads. The Applicant has previously described sophisticated alignment patterns (see <CIT>), which may be used to determine misalignments and allow fine correction thereof using suitable mechanical means. However, even with perfectly mechanically positioned printheads, relative misalignments are still possible due to the small differences in the conformation of individual printheads, arising from their manufacturing process. For example, in relatively long pagewide printheads, the printheads have a tendency to bow along their long axis, some more than others depending on the precise manufacturing conditions. If a relatively 'bowed' printhead is paired with a relatively 'non-bowed' printhead, then those two printheads will typically have poor alignment even with perfect mechanical positioning of the two printheads. Whilst studies by the Applicant show that only a relatively small percentage (about <NUM>%) of randomized printhead pairings are unmatched, ideally, it should be ensured that 'non-bowed' printheads are matched with similarly 'non-bowed' printheads and 'bowed' printheads are matched with similarly 'bowed' printheads in order to maximize alignment. However, printhead matching in this way is problematic in a supply chain. Users expect printheads to be replaceable with any printhead of the same type; moreover, measuring an extent of bowing and then categorizing printheads based on such measurements adds complexity and expense to the supply chain. Even with such a categorization of printheads at the factory, the extent of bowing may change due to other factors in the field. For example, a printhead nest which mechanically holds the printhead when installed in a printing system may affect the extent of bowing. Hence, characterization of printhead bowing at the factory may not be a good indicator of printhead bowing in the field.

It would therefore be desirable to provide a method of high-speed printing using upstream and downstream printheads, which optimizes print quality irrespective of the relative alignment of those printheads. In particular, it would be desirable to optimize print quality for printheads that are not perfectly aligned, either due to imperfect mechanical placement of the printheads or mismatching of printhead pairings.

<CIT> describes a method of single-pass printing using two wholly aligned printheads supplied with a same colored ink. The method analyses grayscale values (density values) of pixels and allocates printing of each pixel to either one or both printheads depending on whether the grayscale value exceeds a certain threshold.

In a first aspect, there is provided a method of single-pass printing as defined hereinbelow in the accompanying claims.

As used herein, the term "ink" is taken to mean any printing fluid, which may be printed from an inkjet printhead. The ink may or may not contain a colorant. Accordingly, the term "ink" may include conventional dye-based or pigment-based inks, infrared inks, fixatives (e.g. pre-coats and finishers), 3D printing fluids and the like. Where reference is made to fluids or printing fluids, this is not intended to limit the meaning of "ink" herein.

As used herein, the term "aligned printheads" is taken to mean a plurality of printheads that are generally aligned along a media feed direction, such that any one of the printheads is capable of printing onto a same part of the media as any other printhead. However, as will be readily apparent to the person skilled in the art, the term "aligned printheads" should not necessarily be taken to mean perfect alignment, positioning and/or matching of printheads as foreshadowed above. In one aspect, the present invention addresses the problem of small misalignments (e.g. less than <NUM> micron, less than <NUM> micron, less than <NUM> micron or less than <NUM> micron misalignments) between generally aligned printheads.

One or more embodiments of the present invention will now be described with reference to the drawings, in which:.

Referring to <FIG>, there is shown schematically a printing system <NUM> comprising a first printhead <NUM> and a second printhead <NUM> positioned downstream of the first printhead relative to a media feed direction indicated by arrow F. The second printhead is aligned with the first printhead in the media feed direction insofar as both printheads are capable of printing onto a same portion of media <NUM> (e.g. cut-sheet media or a roll-to-roll fed media web). An extent of alignment between the first and second printheads <NUM> and <NUM> may vary according to individual printhead conformations, printhead placement accuracy etc, as described above.

Each of the first and second printheads <NUM> and <NUM> is a monochrome printhead supplied with a same ink so as to enable double-speed printing. For double-speed printing, each printhead prints half an image at half the target resolution (in the media direction F). For example, a full halftone image may be generated at a target resolution of <NUM> x <NUM> dpi and each of the first and second printheads <NUM> and <NUM> is configured to print at a resolution of <NUM> x <NUM> dpi. Typically, each printhead prints respective alternate lines (row) of the full halftone image. Since printheads have a maximum drop ejection frequency, it will be appreciated that halving the resolution in the media feed direction F enables printing at twice the speed that would otherwise be obtainable.

Each of the first and second printheads <NUM> and <NUM>, is typically a component of a print module, which may additionally comprise a printhead mounting structure, electronics for supply of data and power to the printhead, ink couplings, pressure regulator(s) etc. Examples of suitable print modules are described in <CIT> and <CIT>.

By way of example, and referring to <FIG>, there is shown a print engine <NUM> having four aligned print modules <NUM> as described in <CIT>. Each print module <NUM> comprises a respective printhead (not visible in <FIG>) as well as ink couplings, PCBs etc. It will be appreciated that the print engine <NUM> having four aligned printheads supplied with a same ink potentially enables quadruple-speed printing by allocating a quarter of a full halftone image to each of the four print modules <NUM>. For example, every <NUM>th line of the full halftone image may be allocated to a respective print module <NUM>, such that each printhead prints at one ¼ resolution in the media feed direction. A full halftone image generated at a resolution of <NUM> x <NUM> dpi would be printed at a resolution of <NUM> x <NUM> dpi by each printhead, thereby enabling the print engine <NUM> to print at quadruple speed compared to a single print module <NUM>.

In principle, any number of n printheads may be used to print at n times speed by allocated <NUM>/n of a full halftone image (e.g. every nth line of the halftone image) to a respective one of the n printheads.

Of course, the aligned printheads may be part of a matrix of printheads arranged for color and/or wideformat printing. <FIG> shows schematically a print engine <NUM> containing sixteen print modules <NUM> in an <NUM> × <NUM> array for full color printing. The print modules <NUM> are arranged in sets of four for printing each of four colors (KCMY). In each of the color channels (KCMY), there are two pairs of aligned print modules <NUM>, each pair of aligned print modules overlapping to print onto a different portion of the media. For example, as shown in the black channel, the pair of print modules 12A are aligned and the pair of print modules 12B are aligned along the media feed direction F. Thus, each ink (color) channel is capable of printing at double speed in the manner described above in connection with <FIG>.

Referring to <FIG>, there is shown a simple method, not according to the invention, of processing a contone image at a first resolution for high-speed printing using the first printhead <NUM> and the second printhead <NUM> shown in <FIG>. The method is performed in a raster image processor (RIP) although, for the sake of clarity, not all processing steps performed by the RIP are shown in <FIG>. The contone image is a contone (grayscale) bitmap for a single ink channel at the target printing resolution of <NUM> x <NUM> dpi. The skilled person will understand that typical upstream processing steps in the RIP (e.g. rasterizing, color space conversion, ink channel separation, calibration to the target printing resolution etc) are not shown in <FIG>.

Still referring to <FIG>, in a first step, the contone image is dithered using a conventional single dither pattern (e.g. a blue noise dither as described in <CIT> or a green noise dither as described in <CIT> etc.) to generate a full halftone image. The full halftone image is then divided into a first halftone image and a second halftone image, each at a second resolution, in a process known as "deinterleaving". Alternate rows of the full halftone image are allocated to respective printheads, such that each of the first and second halftone images resulting from the deinterleaving process has a resolution of <NUM> x <NUM> dpi. For example, the first halftone image may comprise odd lines (<NUM>, <NUM>, <NUM>, <NUM> etc.) of the full halftone image and the second halftone image may comprises even lines (<NUM>, <NUM>, <NUM>, <NUM> etc.) of the full halftone image or vice versa. The first and second halftone images are then sent to respective first and second printheads of a print engine and for printing.

In the single-pass printing process using a first printhead <NUM> and a downstream second printhead <NUM>, as shown in <FIG>, the full printed image <NUM> contains the first and second halftone images interleaved on the media <NUM> to represent the full halftone image generated from the dithering process. The half-density image <NUM> printed by the upstream first printhead <NUM> is based on the first halftone image only and is therefore printed at half density (alternate lines of the full halftone image).

With perfect alignment of the first printhead <NUM> and second printhead <NUM>, the process described in connection with <FIG> provides excellent print quality and enables double-speed printing compared to a single printhead printing the full halftone image. However, small misalignments between the first printhead <NUM> and the second printheads <NUM> (e.g. resulting from small mechanical misplacements and/or mis-matching of printhead conformations) results in a significant decline in print quality. In particular, print quality defects are exacerbated by interference effects between the first and second halftone images, which are not otherwise present when printing one color of ink from one printhead. Increasing misalignments between the first printhead <NUM> and the second printhead <NUM> result in a rapid decline in print quality, which is generally unacceptable to users.

Referring to <FIG>, there is shown a method of processing a contone image according to a first embodiment of the invention. In the method shown in <FIG>, the contone image is deinterleaved prior to dithering. Deinterleaving of the contone image is performed similarly to the deinterleaving process described above, whereby alternate lines of the full contone image are allocated to a first contone image and a second contone image. The first contone image is then dithered using a first dither pattern to generate the first halftone image and the second contone image is dithered using a second dither pattern to generate the second halftone image. Crucially, the first and second dither patterns are different.

When the first and second halftone images are printed using respective printheads, the printed image <NUM> generally has acceptable print quality. Advantageously, print quality is relatively tolerant of misalignments between the first printhead printhead <NUM> and the second printhead <NUM> compared to the method described above in connection with <FIG>. In particular, it is understood by the present inventors that using different dither patterns for the first and second halftone images results in a somewhat less rapid decline in print quality with increasing misalignments between the printheads when compared to the method described above using a single dither pattern. Nevertheless, with good alignment between the first printhead <NUM> and the second printhead <NUM>, the method according to the first embodiment produces lower print quality than the method described above.

It would be desirable for users to substitute between the two different processes described above in order to optimize print quality for different extents of alignment between printheads. For example, an initially perfect alignment between the first and second printheads <NUM> and <NUM> may change over time, or replacement of one or both printheads may result in misalignments. In this scenario, it would be desirable to change from the process shown in <FIG> to the process shown in <FIG>. However, since the two processes involve different datapaths, it is impractical to reconfigure the RIP so as to substitute between these two processes.

Referring now to <FIG>, there is shown a method of processing a contone image according to a second embodiment. The method shown in <FIG> has the same datapath as the method shown in <FIG> - that is, the ordering of processing steps is identical in each case. However, the dithering step in the method shown in <FIG> employs a combined dither pattern comprising the first dither pattern and the second dither pattern. In other words, alternate lines of the combined dither pattern (or dither mask) are based on different dither patterns. For example, odd lines of the combined dither pattern may be based on the first dither pattern and even lines of the combined dither pattern may be based on the second dither pattern, which is different than the first dither pattern.

Accordingly, dithering using the combined dither pattern results in first and second halftone images, which are identical to the first and second halftone images described above in connection with <FIG>. The method according to the second embodiment, therefore, enjoys the same advantages as the method according to the first embodiment.

Moreover, an additional advantage of the method according to the second embodiment is that the datapath uses the same sequence of processing steps as those shown in <FIG>. Therefore, by simply substituting a conventional single dither pattern applied to the full contone image with the combined dither pattern, the RIP can readily switch between these two methods in order to optimize print quality for a given scenario.

For example, a user may provide empirical qualitative feedback on print quality and the dither may be switched accordingly. Alternatively, a printhead alignment test pattern may provide quantitative printhead alignment data, which can be used to select the most appropriate dither pattern.

The dither pattern may be selected automatically based on a printhead alignment measurement relative to a predetermined threshold. For example, if the printheads are determined to be aligned to within one dot pitch or less (in the printing direction) at the resolution of the first and second halftone images (i.e. within <NUM> microns for a <NUM> x <NUM> dpi halftone image), then a single dither pattern may be employed, as shown in <FIG>. However, if the printheads are aligned only to greater than one dot pitch (in the printing direction) at the resolution of the first and second halftone images (i.e. greater than <NUM> microns for a <NUM> x <NUM> dpi halftone image), then the combined dither pattern may be employed, as shown in <FIG>. The predetermined threshold may be variable depending on printing parameters (e.g. print speed, print media type, ink type etc.). In this way, print quality can be optimized for both well-aligned and somewhat misaligned printheads.

Claim 1:
A method of single-pass printing using a printing system comprising at least first and second wholly aligned monochrome printheads supplied with a same ink, the second printhead being downstream of the first printhead, the method comprising the steps of:
receiving first and second halftone images at the first and second printheads, respectively;
printing the first halftone image from the first printhead; and
printing the second halftone image from the second printhead such that a resulting printed image contains the second halftone image interleaved with the first halftone image,
wherein:
the printed image is printed at a first resolution in a printing direction;
the first and second halftone images have a second resolution in the printing direction;
the first halftone image is based on a first dither pattern and the second halftone image is based on a second dither pattern, the first dither pattern being different than the second dither pattern,
and characterized in that:
the second resolution is less than the first resolution.