In this paper, we introduce a parallax barrier system that shows high definition autostereoscopy and holds wide viewing zone. The proposed method creates a 4-view parallax barrier system with full display resolution per view by setting aperture ratio to one quarter and using time-division quadplexing, then applies obtained 4-view to 2-view, so that the viewing zone for each eye becomes wider than that from the conventional methods. We build a prototype with two 120,Hz LCD panels and manage to achieve continuous viewing zone with common head-tracking device involved. However, moire patterns and flickers stand out, which are respectively caused by the identical alignments of the color filters on the overlaid LCD panels and a lack of refresh rate of 240,Hz. We successfully remove the moire patterns by changing the structure of the system and inserting a diffuser. We also reduce the flickers by proposing 1-pixel aperture, while stripe shaped noise due to the lack of refresh rate occurs during a blink or a saccade. The stripe noise can be effectively weakened by applying green and magenta anaglyph to the proposed system, where extra crosstalk takes place since the default RGB color filters on LCD panels share certain ranges of wavelength with each other. Although a trade-off turns out to exist between stripe noise and crosstalk from our comparison experiment, results from different settings all hold acceptable quality and show high practicability of our method. Furthermore, we propose a solution that shows possibility to satisfy both claims, where extra color filters with narrow bandwidths are required.

We propose a non-photorealistic rendering method for generating moire-picture-like color images from color photographs. The proposed method is performed in two steps. First, images with a staircasing effect are generated by a bilateral filter. Second, moire patterns are generated with an improved bilateral filter called an anti-bilateral filter. The characteristic of the anti-bilateral filter is to emphasize gradual boundaries.

Reducing moire is an important consideration in CRT design. This paper aims to investigate how the visibility of the inverse-phase raster moire, a typical pattern of the raster moire, is influenced by the distribution of the electron beam and the structure of shadow mask apertures. First, a simple model based on the luminance distribution on the CRT screen and characteristics of the human vision was used to calculate the perceived intensity of the inverse-phase raster moire. This calculation was made to examine the effect of model parameters. It showed that the inverse-phase raster moire consists of (1,1)-order moire components. It was also found that the perceived intensity increases with a decrease in electron beam diameter and with an increase in horizontal aperture pitch. In addition, a subjective evaluation test was conducted using an inverse-phase moire pattern reproduced by the image simulation. Test results agreed with the calculated results. Finally, it was revealed that when an electron beam shape having a Gauss distribution was used, most of the raster moire is the inverse-phase raster moire caused by the (1,1)-order component, while the (2,2)-order moire component was very low.

The CROMACLEAR color display tube has been developed as a display that offers attractive icon quality and highly legible characters. The color display tube is composed of a striped superfine pitch phosphor screen with slot-type shadow mask. We explain the character legibility by Fourier transform. Moreover, the electron beam shape is improved. As a result, the CROMACLEAR color display tube has achieved higher legibility and lower moire phenomenon. This CROMACLEAR color display tube is already mounted in new monitor series.

The high resolution CRT displays used for computer monitor and high performance TV often produce a pattern of bright and dark stripes on the screen called a moire pattern. The elimination of the moire is an important consideration in the CRT design. In this paper, we propose a method for evaluating a moire pattern based on the measurement data of the electron beam distribution. (1) We describe a mathematical expression of the process whereby a moire pattern is produced. By applying the electron beam measurement data into the formulae, precise value of the period and the contrast of a moire are calculated from the actual data of the electron beam profile and the distribution of apertures of the shadow mask. (2) The visibility of the moire is evaluated by plotting the calculation results on the contrastperiod plane, which consists of visible and invisible moire pattern regions based on experimental results of the psychological tests. (3) In addition to the analysis by calculation, the visibility of moire patterns can be visually examined by simulating moire patterns using the same data as above calculation. Since not only fundamental design parameters such as a shadow mask pitch and a scanning line pitch but also details of an electron beam profile such as a distortion or an asymmetry can be examined, a newly developed method contributes the efficiency of the CRT design.